Compute Isotropic Elasticity Tensor

Compute a constant isotropic elasticity tensor.

Description

The material ComputeIsotropicElasticityTensor builds the isotropic elasticity (stiffness) tensor with two user provided elastic constants.

The isotropic elasticity tensor is given, in engineering matrix notation (Malvern, 1969), as $(1)var element = document.getElementById("moose-equation-022e107e-1097-4935-adc9-9e7436441fb7");katex.render(" C_{ijkl}^{isotropic} = \\begin{bmatrix} \\lambda + 2 \\mu & \\lambda & \\lambda & 0 & 0 & 0 \\\\ \\lambda & \\lambda + 2 \\mu & \\lambda & 0 & 0 & 0 \\\\ \\lambda & \\lambda & \\lambda + 2 \\mu & 0 & 0 & 0 \\\\ 0 & 0 & 0 & \\mu & 0 & 0 \\\\ 0 & 0 & 0 & 0 & \\mu & 0 \\\\ 0 & 0 & 0 & 0 & 0 & \\mu \\end{bmatrix}", element, {displayMode:true,throwOnError:false,macros:{"\\pf":"\\frac{\\partial #1}{\\partial #2}"}});$

ComputeIsotropicElasticityTensor accepts as an argument two of five isotropic elastic constants: lambda $var element = document.getElementById("moose-equation-0e13d5f1-971e-4ee6-8525-7f21143c96e6");katex.render("\\lambda", element, {displayMode:false,throwOnError:false,macros:{"\\pf":"\\frac{\\partial #1}{\\partial #2}"}});$ , the shear modulus $var element = document.getElementById("moose-equation-dfd075f2-fda8-4bde-b558-8c22f95578c8");katex.render("\\mu", element, {displayMode:false,throwOnError:false,macros:{"\\pf":"\\frac{\\partial #1}{\\partial #2}"}});$ , the bulk modulus $var element = document.getElementById("moose-equation-323bbada-29a9-4db4-aca3-4ac11432cdb6");katex.render("K", element, {displayMode:false,throwOnError:false,macros:{"\\pf":"\\frac{\\partial #1}{\\partial #2}"}});$ , the Young's modulus $var element = document.getElementById("moose-equation-a68d3f15-ed84-4587-b3e1-ecc1bf029636");katex.render("E", element, {displayMode:false,throwOnError:false,macros:{"\\pf":"\\frac{\\partial #1}{\\partial #2}"}});$ , or the Poisson's ratio $var element = document.getElementById("moose-equation-760788ed-e27f-4b35-be2c-2077fac3d30c");katex.render("\\nu", element, {displayMode:false,throwOnError:false,macros:{"\\pf":"\\frac{\\partial #1}{\\partial #2}"}});$ . The material includes the conversions into Lame constants, see Slaughter (2012) for the conversion equations among the isotropic elastic constants.

Example Input File Syntax

[./elast_tensor]
  type = ComputeIsotropicElasticityTensor
  youngs_modulus = 1e6
  poissons_ratio = 0.25
[../]

/opt/civet/build_0/moose/modules/tensor_mechanics/test/tests/elastic_patch/elastic_patch_quadratic.i

# Patch Test for second order hex elements (HEX20)
#
# From Abaqus, Verification Manual, 1.5.2
#
# This test is designed to compute constant xx, yy, zz, xy, yz, and zx
#  stress on a set of irregular hexes.  The mesh is composed of one
#  block with seven elements.  The elements form a unit cube with one
#  internal element.  There is a nodeset for each exterior node.

# The cube is displaced on all exterior nodes using the functions,
#
#    ux = 1e-4 * (2x + y + z) / 2
#    uy = 1e-4 * (x + 2y + z) / 2
#    ux = 1e-4 * (x + y + 2z) / 2
#
#  giving uniform strains of
#
#    exx = eyy = ezz = 2*exy = 2*eyz = 2*exz = 1e-4
#
#
# Hooke's Law provides an analytical solution for the uniform stress state.
#  For example,
#
#    stress xx = lambda(exx + eyy + ezz) + 2 * G * exx
#    stress xy = 2 * G * exy
#
#   where:
#
#    lambda = (2 * G * nu) / (1 - 2 * nu)
#    G = 0.5 * E / (1 + nu)
#
# For the test below, E = 1e6 and nu = 0.25, giving lambda = G = 4e5
#
# Thus
#
#    stress xx = 4e5 * (3e-4) + 2 * 4e5 * 1e-4 = 200
#    stress xy = 2 * 4e5 * 1e-4 / 2 = 40
#
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]
[Mesh]
  file = elastic_patch_quadratic.e
[] # Mesh

[Functions]
  [./xDispFunc]
    type = ParsedFunction
    value = 5e-5*(2*x+y+z)
  [../]
  [./yDispFunc]
    type = ParsedFunction
    value = 5e-5*(x+2*y+z)
  [../]
  [./zDispFunc]
    type = ParsedFunction
    value = 5e-5*(x+y+2*z)
  [../]
[] # Functions

[Variables]
  [./disp_x]
    order = SECOND
    family = LAGRANGE
  [../]
  [./disp_y]
    order = SECOND
    family = LAGRANGE
  [../]
  [./disp_z]
    order = SECOND
    family = LAGRANGE
  [../]
[] # Variables

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_energy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./hydrostatic]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./firstinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./secondinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./thirdinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
[] # AuxVariables

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 2
    variable = stress_yz
  [../]
  [./stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 0
    variable = stress_zx
  [../]
  [./elastic_energy]
    type = ElasticEnergyAux
    variable = elastic_energy
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = VonMisesStress
    variable = vonmises
  [../]
  [./hydrostatic]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = Hydrostatic
    variable = hydrostatic
  [../]
  [./fi]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = FirstInvariant
    variable = firstinv
  [../]
  [./si]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = SecondInvariant
    variable = secondinv
  [../]
  [./ti]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = ThirdInvariant
    variable = thirdinv
  [../]
[] # AuxKernels

[BCs]
  [./all_nodes_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '1 2 3 4 6 7 8 9 10 12 15 17 18 19 20 21 23 24 25 26'
    function = xDispFunc
  [../]
  [./all_nodes_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = '1 2 3 4 6 7 8 9 10 12 15 17 18 19 20 21 23 24 25 26'
    function = yDispFunc
  [../]
  [./all_nodes_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = '1 2 3 4 6 7 8 9 10 12 15 17 18 19 20 21 23 24 25 26'
    function = zDispFunc
  [../]
[] # BCs

[Materials]
  [./elast_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[] # Materials

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-6

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 1
  end_time = 1.0
[] # Executioner

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[] # Outputs

Input Parameters

base_nameOptional parameter that allows the user to define multiple mechanics material systems on the same block, i.e. for multiple phases
C++ Type:std::string
Options:
Description:Optional parameter that allows the user to define multiple mechanics material systems on the same block, i.e. for multiple phases
blockThe list of block ids (SubdomainID) that this object will be applied
C++ Type:std::vector
Options:
Description:The list of block ids (SubdomainID) that this object will be applied
boundaryThe list of boundary IDs from the mesh where this boundary condition applies
C++ Type:std::vector
Options:
Description:The list of boundary IDs from the mesh where this boundary condition applies
bulk_modulusThe bulk modulus for the material.
C++ Type:double
Options:
Description:The bulk modulus for the material.
computeTrueWhen false, MOOSE will not call compute methods on this material. The user must call computeProperties() after retrieving the MaterialBase via MaterialBasePropertyInterface::getMaterialBase(). Non-computed MaterialBases are not sorted for dependencies.
Default:True
C++ Type:bool
Options:
Description:When false, MOOSE will not call compute methods on this material. The user must call computeProperties() after retrieving the MaterialBase via MaterialBasePropertyInterface::getMaterialBase(). Non-computed MaterialBases are not sorted for dependencies.
constant_onNONEWhen ELEMENT, MOOSE will only call computeQpProperties() for the 0th quadrature point, and then copy that value to the other qps.When SUBDOMAIN, MOOSE will only call computeSubdomainProperties() for the 0th quadrature point, and then copy that value to the other qps. Evaluations on element qps will be skipped
Default:NONE
C++ Type:MooseEnum
Options:NONE ELEMENT SUBDOMAIN
Description:When ELEMENT, MOOSE will only call computeQpProperties() for the 0th quadrature point, and then copy that value to the other qps.When SUBDOMAIN, MOOSE will only call computeSubdomainProperties() for the 0th quadrature point, and then copy that value to the other qps. Evaluations on element qps will be skipped
elasticity_tensor_prefactorOptional function to use as a scalar prefactor on the elasticity tensor.
C++ Type:FunctionName
Options:
Description:Optional function to use as a scalar prefactor on the elasticity tensor.
lambdaLame's first constant for the material.
C++ Type:double
Options:
Description:Lame's first constant for the material.
poissons_ratioPoisson's ratio for the material.
C++ Type:double
Options:
Description:Poisson's ratio for the material.
shear_modulusThe shear modulus of the material.
C++ Type:double
Options:
Description:The shear modulus of the material.
youngs_modulusYoung's modulus of the material.
C++ Type:double
Options:
Description:Young's modulus of the material.

Optional Parameters

control_tagsAdds user-defined labels for accessing object parameters via control logic.
C++ Type:std::vector
Options:
Description:Adds user-defined labels for accessing object parameters via control logic.
enableTrueSet the enabled status of the MooseObject.
Default:True
C++ Type:bool
Options:
Description:Set the enabled status of the MooseObject.
implicitTrueDetermines whether this object is calculated using an implicit or explicit form
Default:True
C++ Type:bool
Options:
Description:Determines whether this object is calculated using an implicit or explicit form
seed0The seed for the master random number generator
Default:0
C++ Type:unsigned int
Options:
Description:The seed for the master random number generator
use_displaced_meshFalseWhether or not this object should use the displaced mesh for computation. Note that in the case this is true but no displacements are provided in the Mesh block the undisplaced mesh will still be used.
Default:False
C++ Type:bool
Options:
Description:Whether or not this object should use the displaced mesh for computation. Note that in the case this is true but no displacements are provided in the Mesh block the undisplaced mesh will still be used.

Advanced Parameters

output_propertiesList of material properties, from this material, to output (outputs must also be defined to an output type)
C++ Type:std::vector
Options:
Description:List of material properties, from this material, to output (outputs must also be defined to an output type)
outputsnone Vector of output names were you would like to restrict the output of variables(s) associated with this object
Default:none
C++ Type:std::vector
Options:
Description:Vector of output names were you would like to restrict the output of variables(s) associated with this object

Outputs Parameters

Input Files

modules/tensor_mechanics/test/tests/2D_geometries/2D-RZ_finiteStrain_resid.i
modules/peridynamics/test/tests/jacobian_check/generalized_planestrain_thermomechanics_smallstrain_NOSPD.i
modules/combined/test/tests/mortar_tm/2drz/ad_frictionless_first/finite_rr.i
modules/peridynamics/test/tests/failure_tests/2D_stress_failure_NOSPD.i
modules/combined/test/tests/contact_verification/patch_tests/brick_1/brick1_aug.i
modules/tensor_mechanics/test/tests/ad_linear_elasticity/linear_elastic_material.i
modules/combined/test/tests/mortar_tm/2d/frictionless_first/small.i
modules/tensor_mechanics/test/tests/jacobian/cwp02.i
modules/combined/test/tests/beam_eigenstrain_transfer/subapp_err_3.i
modules/xfem/test/tests/solid_mechanics_basic/square_branch_quad_2d.i
modules/tensor_mechanics/test/tests/notched_plastic_block/biaxial_smooth.i
modules/combined/test/tests/solid_mechanics/LinearStrainHardening/LinearStrainHardeningRestart2.i
modules/tensor_mechanics/test/tests/ad_thermal_expansion_function/mean.i
modules/tensor_mechanics/test/tests/action/two_block.i
modules/peridynamics/test/tests/generalized_plane_strain/generalized_plane_strain_squares_OSPD.i
modules/combined/test/tests/mortar_tm/2drz/frictionless_first/finite_noaction.i
modules/tensor_mechanics/test/tests/capped_weak_plane/small_deform11.i
modules/combined/test/tests/simple_contact/simple_contact_rspherical.i
modules/tensor_mechanics/test/tests/isotropic_elasticity_tensor/lambda_shear_modulus_test.i
modules/combined/test/tests/inelastic_strain/elas_plas/elas_plas_nl1.i
modules/combined/test/tests/beam_eigenstrain_transfer/subapp1_uo_transfer.i
modules/combined/test/tests/mortar_tm/2d/ad_frictionless_sec/finite.i
modules/combined/test/tests/nodal_area/nodal_area_Hex20.i
modules/combined/test/tests/contact_verification/patch_tests/ring_3/ring3_template1.i
modules/combined/test/tests/contact_verification/patch_tests/plane_1/plane1_template1.i
modules/combined/test/tests/ad_cavity_pressure/3d.i
modules/combined/test/tests/adaptive_timestepping/adapt_tstep_function_change_restart2.i
modules/combined/test/tests/elastic_thermal_patch/elastic_thermal_patch.i
modules/tensor_mechanics/test/tests/material_limit_time_step/elas_plas/nafems_nl1_lim.i
modules/combined/test/tests/internal_volume/rz_quad8.i
modules/tensor_mechanics/test/tests/thermal_expansion_function/instantaneous.i
modules/peridynamics/test/tests/simple_tests/2D_regularD_variableH_BPD.i
modules/combined/test/tests/contact_adaptivity/contact_initial_adaptivity.i
modules/combined/test/tests/contact_verification/patch_tests/brick_4/brick4_template2.i
modules/combined/test/tests/simple_contact/simple_contact_test2.i
modules/combined/test/tests/evolving_mass_density/shear_test_tensors.i
modules/peridynamics/test/tests/simple_tests/2D_irregularD_variableH_BPD.i
modules/combined/test/tests/catch_release/catch_release.i
modules/xfem/test/tests/solid_mechanics_basic/penny_crack_cfp.i
modules/tensor_mechanics/test/tests/ad_thermal_expansion_function/dilatation.i
modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_as_2d.i
modules/combined/test/tests/contact_verification/patch_tests/brick_4/brick4_mu_0_2_pen.i
modules/combined/test/tests/mortar_tm/2d/ad_frictionless_sec/small.i
modules/tensor_mechanics/test/tests/thermal_expansion_function/finite_const.i
modules/combined/test/tests/ring_contact/ring_contact.i
modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_as_2d_topo_q_func.i
modules/xfem/test/tests/corner_nodes_cut/corner_node_cut_twice.i
modules/tensor_mechanics/test/tests/jacobian/cwp05.i
modules/combined/test/tests/contact_verification/patch_tests/plane_1/plane1_mu_0_2_pen.i
modules/combined/test/tests/mortar_tm/2d/frictionless_first/finite_rr.i
modules/combined/test/tests/solid_mechanics/Time_integration/Newmark_time_integration/Newmark_test.i
modules/combined/test/tests/sliding_block/sliding/constraint/frictionless_kinematic.i
modules/tensor_mechanics/test/tests/plane_stress/weak_plane_stress_elastic_jacobian.i
modules/tensor_mechanics/test/tests/2D_different_planes/planestrain_xz.i
modules/combined/test/tests/elastic_patch/elastic_patch_rspherical.i
modules/tensor_mechanics/test/tests/ad_action/two_coord.i
modules/tensor_mechanics/test/tests/initial_stress/except01.i
modules/tensor_mechanics/test/tests/jacobian/mc_update33.i
modules/peridynamics/test/tests/simple_tests/2D_regularD_variableH_OSPD.i
modules/combined/test/tests/ad_cavity_pressure/multiple_postprocessors.i
modules/tensor_mechanics/test/tests/smeared_cracking/cracking_plane_stress.i
modules/tensor_mechanics/test/tests/initial_stress/gravity.i
modules/combined/test/tests/contact_verification/patch_tests/ring_4/ring4_mu_0_2_pen.i
modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/frictionless_kinematic_dirac.i
modules/tensor_mechanics/test/tests/multiple_two_parameter_plasticity/dp_then_wp.i
modules/tensor_mechanics/test/tests/torque_reaction/disp_about_axis_errors.i
modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_points.i
modules/tensor_mechanics/test/tests/isotropic_elasticity_tensor/bulk_modulus_shear_modulus_test.i
modules/tensor_mechanics/test/tests/2D_different_planes/gps_jacobian_testing_xy.i
modules/combined/test/tests/elastic_patch/ad_elastic_patch_rspherical.i
modules/tensor_mechanics/test/tests/radial_disp_aux/cylinder_2d_axisymmetric.i
modules/peridynamics/test/tests/restart/2D_mesh_restartable_NOSPD.i
modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_mouth_dir.i
modules/combined/test/tests/gravity/gravity_rz_quad8.i
modules/combined/test/tests/mortar_tm/2drz/frictionless_second/finite_noaction.i
modules/tensor_mechanics/test/tests/plane_stress/3D_finite_tension_pull.i
modules/combined/test/tests/sliding_block/in_and_out/constraint/frictionless_lm.i
modules/tensor_mechanics/test/tests/generalized_plane_strain/out_of_plane_pressure.i
modules/tensor_mechanics/test/tests/ad_2D_geometries/3D-RZ_finiteStrain_test.i
modules/combined/test/tests/contact_verification/patch_tests/ring_2/ring2_mu_0_2_pen.i
modules/combined/test/tests/mortar_tm/2drz/frictionless_second/finite_rr.i
modules/combined/test/tests/solid_mechanics/hoop_stress/hoop_stress_default_yaxis.i
modules/tensor_mechanics/test/tests/generalized_plane_strain/generalized_plane_strain_finite.i
modules/peridynamics/test/tests/simple_tests/2D_small_strain_NOSPD.i
modules/combined/test/tests/contact/pressureAugLag.i
modules/combined/test/tests/fieldsplit_contact/2blocks3d.i
modules/tensor_mechanics/test/tests/domain_integral_thermal/j_integral_2d_inst_ctefunc.i
modules/tensor_mechanics/test/tests/eigenstrain/reducedOrderRZQuadratic.i
modules/xfem/test/tests/pressure_bc/edge_3d_pressure.i
modules/tensor_mechanics/test/tests/check_error/shear_modulus.i
modules/peridynamics/test/tests/jacobian_check/weak_planestress_thermomechanics_smallstrain_NOSPD.i
modules/combined/test/tests/internal_volume/rz_displaced.i
modules/combined/test/tests/contact_verification/patch_tests/brick_1/brick1_template2.i
modules/combined/test/tests/solid_mechanics/beam_pbp/beam_pbp.i
modules/tensor_mechanics/test/tests/elastic_patch/elastic_patch.i
modules/combined/test/tests/contact_verification/overclosure_removal/overclosure.i
modules/combined/test/tests/sliding_block/sliding/dirac/frictional_04_penalty.i
modules/tensor_mechanics/test/tests/ad_viscoplasticity_stress_update/gtn_single.i
modules/combined/test/tests/contact_verification/patch_tests/ring_4/ring4_template2.i
modules/combined/test/tests/frictional_contact/single_point_2d/single_point_2d.i
modules/peridynamics/test/tests/jacobian_check/thermomechanics_2D_FNOSPD.i
modules/tensor_mechanics/test/tests/multiple_two_parameter_plasticity/cycled_dp_then_wp.i
tutorials/darcy_thermo_mech/step09_mechanics/problems/step9.i
modules/combined/test/tests/solid_mechanics/Rayleigh_damping/HHT_time_integration/Rayleigh_HHT.i
modules/combined/test/tests/mortar_tm/2d/frictionless_first/finite.i
modules/combined/test/tests/elastic_patch/ad_elastic_patch_rz.i
modules/peridynamics/test/tests/jacobian_check/generalized_planestrain_smallstrain_NOSPD.i
modules/combined/test/tests/contact_verification/hertz_cyl/quart_symm_q8/hertz_cyl_qsym_1deg_template1.i
modules/tensor_mechanics/test/tests/thermal_expansion/constant_expansion_coeff.i
modules/tensor_mechanics/tutorials/basics/part_2.4.i
modules/combined/test/tests/normalized_penalty/normalized_penalty.i
modules/tensor_mechanics/test/tests/ad_linear_elasticity/thermal_expansion.i
modules/tensor_mechanics/test/tests/jacobian/mc_update7.i
modules/combined/test/tests/contact_verification/patch_tests/cyl_2/cyl2_template2.i
modules/tensor_mechanics/test/tests/1D_spherical/finiteStrain_1DSphere_hollow.i
modules/combined/test/tests/simple_contact/simple_contact_dirac_test.i
modules/tensor_mechanics/test/tests/ad_elastic/rspherical_finite_elastic-noad.i
modules/tensor_mechanics/test/tests/jacobian/mc_update12.i
modules/peridynamics/test/tests/jacobian_check/3D_mechanics_smallstrain_NOSPD.i
modules/tensor_mechanics/test/tests/stress_recovery/patch/patch_finite_stress.i
modules/combined/test/tests/solid_mechanics/spherical_shell/3D_test.i
modules/combined/test/tests/contact_verification/patch_tests/brick_3/brick3_mu_0_2_pen.i
modules/combined/test/tests/contact_verification/patch_tests/cyl_4/cyl4_template1.i
modules/xfem/test/tests/bimaterials/inclusion_bimaterials_2d.i
modules/peridynamics/test/tests/jacobian_check/2D_thermomechanics_BPD.i
modules/combined/test/tests/contact_verification/patch_tests/plane_3/plane3_mu_0_2_pen.i
modules/tensor_mechanics/test/tests/ad_elastic/rz_incremental_small_elastic-noad.i
modules/tensor_mechanics/tutorials/basics/part_2.3.i
modules/tensor_mechanics/test/tests/ad_1D_spherical/finiteStrain_1DSphere_hollow.i
modules/tensor_mechanics/test/tests/jacobian/mc_update5.i
modules/tensor_mechanics/test/tests/ad_viscoplasticity_stress_update/creep.i
modules/combined/test/tests/nodal_area/nodal_area_Hex20_3.i
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modules/xfem/test/tests/second_order_elements/square_branch_quad8_2d.i
modules/tensor_mechanics/test/tests/thermal_expansion/ad_constant_expansion_stress_free_temp.i
modules/porous_flow/test/tests/dirackernels/injection_with_plasticity.i
modules/porous_flow/examples/tutorial/11.i
modules/combined/test/tests/mortar_tm/2d/frictionless_first/finite_noaction.i
modules/tensor_mechanics/test/tests/test_jacobian/jacobian_test_planestrain.i
modules/tensor_mechanics/test/tests/jacobian/cto25.i
modules/combined/test/tests/elastic_patch/elastic_patch_rz.i
modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymm_gps_small.i
modules/combined/test/tests/contact/4ElemTensionRelease_mechanical_constraint.i
modules/combined/test/tests/gravity/gravity_hex20.i
modules/combined/test/tests/contact_verification/patch_tests/cyl_1/cyl1_template2.i
modules/combined/test/tests/contact_verification/patch_tests/plane_1/plane1_template2.i
modules/tensor_mechanics/test/tests/ad_isotropic_elasticity_tensor/bulk_modulus_shear_modulus_test.i
modules/tensor_mechanics/test/tests/generalized_plane_strain/generalized_plane_strain_small.i
modules/peridynamics/test/tests/jacobian_check/2D_mechanics_OSPD.i
modules/tensor_mechanics/test/tests/check_error/pressure_component.i
modules/tensor_mechanics/test/tests/isotropic_elasticity_tensor/youngs_modulus_poissons_ratio_test.i
modules/combined/test/tests/mortar_tm/2drz/frictionless_first/small.i
modules/tensor_mechanics/test/tests/2D_different_planes/gps_xz.i
modules/combined/test/tests/internal_volume/rz.i
modules/combined/test/tests/contact_verification/patch_tests/automatic_patch_update/sliding_update.i
modules/peridynamics/test/tests/jacobian_check/2D_mechanics_smallstrain_NOSPD.i
modules/combined/test/tests/frictional_contact/sliding_elastic_blocks_2d/sliding_elastic_blocks_2d.i
modules/combined/test/tests/gravity/gravity_rz.i
modules/tensor_mechanics/test/tests/check_error/youngs_modulus.i
modules/combined/test/tests/contact/pressurePenalty_mechanical_constraint.i
modules/tensor_mechanics/test/tests/j_integral/j_integral_2d_mouth_dir.i
modules/combined/test/tests/solid_mechanics/Wave_1_D/Newmark_time_integration/wave_bc_1d.i
modules/combined/test/tests/glued_contact/glued_contact_test.i
modules/combined/test/tests/solid_mechanics/hoop_stress/hoop_stress.i
modules/combined/test/tests/contact_verification/patch_tests/plane_4/plane4_mu_0_2_pen.i
modules/tensor_mechanics/tutorials/basics/part_2.2.i
modules/combined/test/tests/axisymmetric_2d3d_solution_function/3dy.i
modules/tensor_mechanics/test/tests/jacobian/mc_update14.i
modules/tensor_mechanics/test/tests/ad_elastic/rspherical_small_elastic-noad.i
modules/tensor_mechanics/test/tests/check_error/poissons_ratio.i
modules/combined/test/tests/sliding_block/in_and_out/constraint/frictional_02_penalty.i
modules/tensor_mechanics/test/tests/ad_elastic/rspherical_finite_elastic.i
modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymmetric_gps_finite.i
modules/combined/test/tests/evolving_mass_density/expand_compress_test_tensors.i
modules/combined/test/tests/contact_verification/patch_tests/brick_2/brick2_template2.i
modules/combined/test/tests/contact_verification/hertz_cyl/half_symm_q4/hertz_cyl_half_1deg_template3.i
modules/tensor_mechanics/test/tests/jacobian/cwp11.i
modules/porous_flow/examples/tidal/earth_tide_fullsat.i
modules/tensor_mechanics/test/tests/ad_elastic/rz_finite_elastic.i
modules/tensor_mechanics/test/tests/torque_reaction/torque_reaction_tm.i
modules/combined/test/tests/beam_eigenstrain_transfer/subapp_err_2.i
modules/combined/test/tests/solid_mechanics/HHT_time_integrator/one_element_b_0_3025_g_0_6_cubic.i
modules/combined/test/tests/contact_verification/patch_tests/plane_3/plane3_template2.i
modules/combined/test/tests/contact_verification/patch_tests/brick_2/brick2_mu_0_2_pen.i
modules/tensor_mechanics/test/tests/eigenstrain/reducedOrderRZLinear.i
modules/tensor_mechanics/test/tests/capped_mohr_coulomb/small_deform22.i
modules/combined/test/tests/sliding_block/in_and_out/dirac/frictional_04_penalty.i
modules/tensor_mechanics/test/tests/smeared_cracking/cracking_rotation.i
modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_mouth_dir_end_dir_vec.i
modules/tensor_mechanics/test/tests/radial_disp_aux/cylinder_2d_cartesian.i
modules/tensor_mechanics/test/tests/stickyBC/push_down.i
modules/combined/test/tests/power_law_creep/power_law_creep_restart1.i
modules/tensor_mechanics/test/tests/line_material_rank_two_sampler/rank_two_sampler.i
modules/tensor_mechanics/test/tests/stress_recovery/patch/patch.i
modules/tensor_mechanics/test/tests/ad_action/two_block_no_action.i
modules/tensor_mechanics/test/tests/temperature_dependent_hardening/temp_dep_hardening.i
modules/combined/test/tests/mortar_tm/2d/frictionless_second/small.i
modules/combined/test/tests/contact_verification/patch_tests/brick_1/brick1_template1.i
modules/peridynamics/test/tests/auxkernels/boundary_offset_node_area_2D.i
modules/tensor_mechanics/test/tests/capped_drucker_prager/small_deform2_inner_edge.i
modules/tensor_mechanics/test/tests/radial_disp_aux/sphere_2d_axisymmetric.i
modules/combined/test/tests/contact/pressurePenalty.i
modules/tensor_mechanics/test/tests/dynamics/prescribed_displacement/3D_QStatic_1_Ramped_Displacement_with_gravity.i
modules/xfem/test/tests/solid_mechanics_basic/sm/test_crack_counter.i
modules/tensor_mechanics/test/tests/ad_2D_geometries/2D-RZ_test.i
modules/tensor_mechanics/test/tests/2D_different_planes/planestrain_jacobian_testing_yz.i
modules/tensor_mechanics/examples/bridge/bridge.i
modules/combined/test/tests/frictional_contact/sliding_elastic_blocks_2d/sliding_elastic_blocks_2d_tp.i
modules/tensor_mechanics/test/tests/interaction_integral_benchmark/input.i
modules/tensor_mechanics/test/tests/ad_elastic/rz_small_elastic-noad.i
modules/combined/test/tests/contact_verification/patch_tests/ring_2/ring2_template2.i
modules/tensor_mechanics/test/tests/capped_mohr_coulomb/small_deform9.i
modules/tensor_mechanics/test/tests/ad_1D_spherical/smallStrain_1DSphere.i
modules/combined/test/tests/internal_volume/rz_displaced_quad8.i
modules/combined/test/tests/simplest_contact/simplest_contact_skew_test.i
modules/tensor_mechanics/test/tests/ad_elastic/finite_elastic.i
modules/tensor_mechanics/test/tests/truss/truss_hex_action.i
modules/xfem/test/tests/moving_interface/moving_bimaterial.i
modules/peridynamics/test/tests/auxkernels/boundary_offset_node_volume_3D.i
modules/tensor_mechanics/test/tests/j_integral/j_integral_2d_topo_q_func.i
modules/tensor_mechanics/test/tests/t_stress/t_stress_crack_infinite_plate_2d.i
modules/tensor_mechanics/test/tests/jacobian/tensile_update6.i
modules/tensor_mechanics/test/tests/rom_stress_update/verification.i
modules/tensor_mechanics/test/tests/domain_integral_thermal/j_integral_2d_mean_ctefunc.i
modules/tensor_mechanics/test/tests/ad_elastic/rspherical_incremental_small_elastic.i
modules/tensor_mechanics/test/tests/elastic_patch/elastic_patch_quadratic.i
modules/combined/test/tests/sliding_block/sliding/constraint/frictionless_aug.i
modules/tensor_mechanics/test/tests/j_integral/j_integral_2d.i
modules/tensor_mechanics/test/tests/smeared_cracking/cracking_rz.i
modules/xfem/test/tests/moment_fitting/solid_mechanics_moment_fitting.i
modules/tensor_mechanics/test/tests/generalized_plane_strain/plane_strain_prescribed.i
modules/tensor_mechanics/test/tests/plane_stress/weak_plane_stress_small.i
modules/tensor_mechanics/test/tests/j_integral_vtest/j_int_surfbreak_ellip_crack_sym_mm_cfp.i
modules/tensor_mechanics/test/tests/2D_geometries/2D-RZ_test.i
modules/tensor_mechanics/test/tests/ad_thermal_expansion_function/finite_const.i
modules/tensor_mechanics/test/tests/action/no_block.i
modules/tensor_mechanics/test/tests/jacobian/cwp07.i
modules/tensor_mechanics/test/tests/jacobian/tensile_update5.i
modules/combined/test/tests/sliding_block/sliding/constraint/frictionless_penalty.i
modules/combined/test/tests/contact_verification/patch_tests/single_pnt_2d/single_point_2d_frictional.i
modules/tensor_mechanics/test/tests/plane_stress/weak_plane_stress_incremental.i
modules/tensor_mechanics/test/tests/ad_elastic/finite_elastic-noad.i
modules/tensor_mechanics/test/tests/finite_strain_elastic/finite_strain_stress_errorcheck.i
modules/tensor_mechanics/test/tests/inclined_bc/inclined_bc_action.i
modules/tensor_mechanics/test/tests/jacobian/mc_update8.i
modules/tensor_mechanics/test/tests/jacobian/cwp08.i
modules/tensor_mechanics/test/tests/combined_creep_plasticity/combined_creep_plasticity_start_time.i
modules/combined/test/tests/mortar_tm/2drz/ad_frictionless_second/small.i
modules/combined/test/tests/ad_power_law_creep/power_law_creep_smallstrain.i
modules/peridynamics/test/tests/restart/2D_mesh_restartable_NOSPD_second.i
modules/combined/test/tests/contact_verification/patch_tests/cyl_3/cyl3_template2.i
modules/tensor_mechanics/test/tests/material_limit_time_step/damage/scalar_material_damage_timestep_limit.i
modules/tensor_mechanics/test/tests/material_limit_time_step/creep/nafems_test5a_lim.i
modules/tensor_mechanics/test/tests/combined_creep_plasticity/combined_stress_relaxation.i
modules/combined/test/tests/elastic_patch/ad_elastic_patch_rz_nonlinear.i
modules/combined/test/tests/inelastic_strain/creep/creep_nl1.i
modules/tensor_mechanics/test/tests/recompute_radial_return/affine_plasticity.i
modules/tensor_mechanics/test/tests/2D_different_planes/planestrain_xy.i
modules/combined/test/tests/contact/4ElemTensionRelease.i
modules/tensor_mechanics/test/tests/thermal_expansion/ad_constant_expansion_coeff.i
modules/combined/test/tests/simple_contact/merged.i
modules/tensor_mechanics/test/tests/truss/truss_hex.i
modules/peridynamics/test/tests/simple_tests/2D_irregularD_variableH_OSPD.i
modules/tensor_mechanics/test/tests/volumetric_eigenstrain/volumetric_mechanical.i
modules/combined/test/tests/power_law_creep/power_law_creep_restart2.i
modules/combined/test/tests/sliding_block/sliding/constraint/frictional_02_aug.i
modules/tensor_mechanics/tutorials/basics/part_3_1.i
modules/tensor_mechanics/test/tests/domain_integral_thermal/interaction_integral_2d_rot.i
modules/tensor_mechanics/test/tests/jacobian/mc_update34.i
modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/frictionless_kinematic.i
modules/combined/test/tests/sliding_block/in_and_out/constraint/frictional_lm.i
modules/tensor_mechanics/test/tests/strain_energy_density/incr_model.i
modules/combined/test/tests/cavity_pressure/3d.i
modules/combined/test/tests/contact_verification/patch_tests/plane_4/plane4_template2.i
modules/tensor_mechanics/tutorials/basics/part_2.1.i
modules/tensor_mechanics/test/tests/combined_creep_plasticity/combined_creep_plasticity.i
modules/tensor_mechanics/test/tests/2D_geometries/2D-RZ_finiteStrain_test.i
modules/tensor_mechanics/examples/bridge/bridge_large_strain.i
modules/tensor_mechanics/test/tests/jacobian/mc_update24.i
modules/combined/test/tests/internal_volume/hex8.i
modules/combined/test/tests/elastic_thermal_patch/elastic_thermal_weak_plane_stress_jacobian.i
modules/combined/test/tests/solid_mechanics/Wave_1_D/Rayleigh_Newmark/wave_bc_1d.i
modules/tensor_mechanics/test/tests/jacobian/cwp03.i
modules/porous_flow/examples/tidal/atm_tides_open_hole.i
modules/tensor_mechanics/test/tests/ad_2D_geometries/2D-RZ_centerline_VLC.i
modules/tensor_mechanics/test/tests/smeared_cracking/cracking_exponential_deprecated.i
modules/tensor_mechanics/test/tests/generalized_plane_strain/plane_strain.i
modules/tensor_mechanics/test/tests/ad_elastic/rspherical_small_elastic.i
modules/xfem/test/tests/solid_mechanics_basic/penny_crack.i
modules/tensor_mechanics/test/tests/notched_plastic_block/biaxial_abbo.i
modules/xfem/test/tests/pressure_bc/edge_2d_pressure.i
modules/tensor_mechanics/test/tests/plane_stress/weak_plane_stress_finite_tension_pull.i
modules/combined/test/tests/sliding_block/sliding/dirac/frictionless_penalty.i
modules/tensor_mechanics/test/tests/line_material_rank_two_sampler/rank_two_scalar_sampler.i
modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/glued_kinematic.i
modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_topo_q_func.i
modules/tensor_mechanics/test/tests/jacobian/mc_update17.i
modules/combined/test/tests/gravity/gravity.i
modules/combined/test/tests/gap_heat_transfer_convex/gap_heat_transfer_convex.i
modules/combined/test/tests/contact_verification/patch_tests/brick_2/brick2_aug.i
modules/tensor_mechanics/test/tests/ad_2D_geometries/2D-RZ_finiteStrain_test.i
modules/combined/test/tests/adaptive_timestepping/adapt_tstep_function_change_restart1.i
modules/tensor_mechanics/test/tests/t_stress/t_stress_ellip_crack_3d.i
modules/tensor_mechanics/test/tests/j_integral/j_integral_2d_small_strain.i
modules/combined/test/tests/beam_eigenstrain_transfer/subapp2_uo_transfer.i
modules/combined/test/tests/cavity_pressure/multiple_postprocessors.i
modules/peridynamics/test/tests/simple_tests/2D_regularD_constH_BPD.i
modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/frictionless_penalty_dirac.i
modules/tensor_mechanics/test/tests/thermal_expansion/constant_expansion_coeff_restart.i
modules/tensor_mechanics/test/tests/domain_integral_thermal/j_integral_2d_ctefunc.i
modules/tensor_mechanics/test/tests/generalized_plane_strain/generalized_plane_strain_increment.i
modules/combined/test/tests/mortar_tm/2drz/ad_frictionless_second/finite_rr.i
modules/tensor_mechanics/test/tests/jacobian/cto26.i
modules/peridynamics/test/tests/simple_tests/2D_regularD_constH_OSPD.i
modules/combined/test/tests/solid_mechanics/pressure/pressure_rz_test.i
modules/combined/test/tests/contact_verification/patch_tests/plane_2/plane2_mu_0_2_pen.i
modules/tensor_mechanics/test/tests/capped_mohr_coulomb/random5.i
modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymm_plane_strain_finite.i
modules/combined/test/tests/normalized_penalty/normalized_penalty_kin.i
modules/combined/test/tests/contact_verification/hertz_cyl/half_symm_q8/hertz_cyl_half_1deg_template1.i
modules/combined/test/tests/ad_power_law_creep/power_law_creep_restart2.i
modules/combined/test/tests/solid_mechanics/Wave_1_D/Rayleigh_HHT/wave_bc_1d.i
modules/tensor_mechanics/test/tests/jacobian/mc_update22.i
modules/tensor_mechanics/test/tests/j_integral_vtest/j_int_surfbreak_ellip_crack_sym_mm.i
modules/combined/test/tests/solid_mechanics/spherical_shell/2D-RZ_test.i
modules/tensor_mechanics/test/tests/radial_disp_aux/sphere_3d_cartesian.i
modules/combined/test/tests/contact_verification/patch_tests/brick_4/brick4_template1.i
modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymm_gps_incremental.i
modules/combined/test/tests/gravity/gravity_qp_select.i
modules/combined/test/tests/contact_verification/patch_tests/brick_2/brick2_template1.i
modules/combined/test/tests/contact_verification/patch_tests/brick_3/brick3_template2.i
modules/porous_flow/examples/thm_example/2D.i
modules/combined/test/tests/cavity_pressure/negative_volume.i
modules/tensor_mechanics/test/tests/jacobian/cto24.i
modules/combined/test/tests/evolving_mass_density/rz_tensors.i
modules/tensor_mechanics/test/tests/jacobian/cwp06.i
modules/tensor_mechanics/test/tests/jacobian/mc_update13.i
modules/peridynamics/test/tests/plane_stress/conventional_planestress_OSPD.i
modules/tensor_mechanics/test/tests/torque_reaction/torque_reaction_cylinder.i
modules/combined/test/tests/beam_eigenstrain_transfer/subapp_err_4.i
modules/tensor_mechanics/test/tests/notched_plastic_block/biaxial_planar.i
modules/tensor_mechanics/test/tests/rom_stress_update/3d.i
modules/combined/test/tests/contact_verification/patch_tests/cyl_3/cyl3_mu_0_2_pen.i
modules/porous_flow/test/tests/thm_rehbinder/fixed_outer_rz.i
modules/peridynamics/test/tests/jacobian_check/generalized_planestrain_thermomechanics_OSPD.i
modules/combined/test/tests/contact_verification/patch_tests/cyl_4/cyl4_template2.i
modules/combined/test/tests/normalized_penalty/normalized_penalty_kin_Q8.i
modules/xfem/test/tests/solid_mechanics_basic/elliptical_crack.i
modules/combined/test/tests/internal_volume/hex20.i
modules/combined/test/tests/nodal_area/nodal_area_Hex27.i
modules/combined/test/tests/mortar_tm/2drz/frictionless_first/finite.i
modules/tensor_mechanics/test/tests/stickyBC/push_up.i
modules/combined/test/tests/contact_verification/patch_tests/cyl_2/cyl2_mu_0_2_pen.i
modules/tensor_mechanics/test/tests/jacobian/tensile_update7.i
modules/combined/test/tests/power_law_creep/power_law_creep_smallstrain.i
modules/tensor_mechanics/test/tests/2D_different_planes/gps_jacobian_testing_xz.i
modules/combined/examples/xfem/xfem_mechanics_prescribed_growth.i
modules/porous_flow/test/tests/actions/basicthm_thm.i
modules/tensor_mechanics/test/tests/j_integral_vtest/j_int_surfbreak_ellip_crack_sym_mm_cfp_cm.i
modules/tensor_mechanics/test/tests/check_error/bulk_modulus.i
modules/combined/test/tests/reference_residual/group_variables.i
modules/tensor_mechanics/test/tests/domain_integral_thermal/j_integral_2d.i
modules/tensor_mechanics/test/tests/ad_linear_elasticity/extra_stresses.i
modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymm_plane_strain_incremental.i
modules/tensor_mechanics/test/tests/2D_different_planes/gps_yz.i
modules/combined/test/tests/axisymmetric_2d3d_solution_function/2d.i
modules/tensor_mechanics/test/tests/smeared_cracking/cracking_function.i
modules/combined/test/tests/glued_contact_constraint/glued_contact_constraint.i
modules/tensor_mechanics/test/tests/ad_action/two_block_new.i
modules/combined/test/tests/mortar_tm/2d/ad_frictionless_sec/finite_rr.i
modules/tensor_mechanics/test/tests/thermal_expansion/multiple_thermal_eigenstrains.i
modules/combined/test/tests/contact_verification/patch_tests/plane_2/plane2_template1.i
modules/porous_flow/test/tests/poro_elasticity/vol_expansion_poroperm.i
modules/combined/test/tests/simple_contact/simple_contact_rspherical_dirac.i
modules/tensor_mechanics/test/tests/interaction_integral/interaction_integral_3d.i
modules/combined/test/tests/contact_verification/patch_tests/brick_3/brick3_template1.i
modules/tensor_mechanics/test/tests/2D_different_planes/planestrain_jacobian_testing_xz.i
modules/tensor_mechanics/test/tests/ad_2D_geometries/2D-RZ_finiteStrain_resid.i
modules/xfem/test/tests/corner_nodes_cut/corner_node_cut.i
modules/tensor_mechanics/test/tests/thermal_expansion_function/mean.i

modules/tensor_mechanics/test/tests/2D_geometries/2D-RZ_finiteStrain_resid.i

# This tests the save_in_disp residual aux-variables for
# ComputeAxisymmetricRZFiniteStrain, which is generated through the use of the
# TensorMechanics MasterAction. The GeneratedMesh is 1x1, rotated via axisym to
# create a cylinder of height 1, radius 1.
#
# PostProcessor force_z plots the force on the top surface of the cylinder.
#
# Displacement of 0.1 is applied to top of cylinder while other surfaces are
# constrained. Plotting force_z vs stress_z will show a slope of 3.14159 (pi),
# consistent with formula for normal stress:
#
# Stress = force / area
#
# where area is A = pi * r^2 for a circle.

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 5
  ny = 5
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Problem]
  coord_type = RZ
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    save_in = 'force_r force_z'
  [../]
[]

[AuxVariables]
  [./stress_r]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_r]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_z]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_z]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./force_r]
    order = FIRST
    family = LAGRANGE
  [../]
  [./force_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxKernels]
  [./stress_r]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_r
    execute_on = timestep_end
  [../]
  [./strain_r]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 0
    index_j = 0
    variable = strain_r
    execute_on = timestep_end
  [../]
  [./stress_z]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_z
    execute_on = timestep_end
  [../]
  [./strain_z]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 1
    index_j = 1
    variable = strain_z
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./_elastic_strain]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[BCs]
  [./no_disp_r_left]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0.0
  [../]
  [./no_disp_r_right]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.0
  [../]
  [./no_disp_z_bottom]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]
  [./top]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = top
    function = 't'
  [../]
[]

[Debug]
    show_var_residual_norms = true
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50

  start_time = 0.0
  end_time = 0.1
  dt = 0.01
[]

[Postprocessors]
  [./strainR]
    type = ElementAverageValue
    variable = strain_r
  [../]
  [./stressR]
    type = ElementAverageValue
    variable = stress_r
  [../]
  [./strainZ]
    type = ElementAverageValue
    variable = strain_z
  [../]
  [./stressZ]
    type = ElementAverageValue
    variable = stress_z
  [../]
  [./force_r]
    type = NodalSum
    variable = force_r
    boundary = top
  [../]
  [./force_z]
    type = NodalSum
    variable = force_z
    boundary = top
  [../]
[]

[Outputs]
  exodus = true
  #csv = true
  print_linear_residuals = false
  perf_graph = true
[]

modules/peridynamics/test/tests/jacobian_check/generalized_planestrain_thermomechanics_smallstrain_NOSPD.i


# NOTE: this jacobian test for the coupled thermomechanical model must use displaced mesh, otherwise the difference for the first step is huge

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
  scalar_out_of_plane_strain = scalar_strain_zz
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./temp]
  [../]

  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConductionBPD
    variable = temp
  [../]
[]

[Modules/Peridynamics/Mechanics]
  [./Master]
    [./all]
      formulation = NONORDINARY_STATE
      eigenstrain_names = thermal
    [../]
  [../]
  [./GeneralizedPlaneStrain]
    [./all]
      formulation = NONORDINARY_STATE
      eigenstrain_names = thermal
    [../]
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./strain]
    type = ComputePlaneSmallStrainNOSPD
    eigenstrain_names = thermal
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-5
    stress_free_temperature = 0.5
    eigenstrain_name = thermal
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]

  [./thermal_mat]
    type = ThermalConstantHorizonMaterialBPD
    thermal_conductivity = 1.0
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

modules/combined/test/tests/mortar_tm/2drz/ad_frictionless_first/finite_rr.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'finite_rr'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    use_automatic_differentiation = true
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
    extra_vector_tags = 'ref'
  [../]
  [./plank]
    use_automatic_differentiation = true
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
    extra_vector_tags = 'ref'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ADComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
  nl_abs_tol = 1e-12
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/peridynamics/test/tests/failure_tests/2D_stress_failure_NOSPD.i


[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3
  cracks_start = '0.25 0.5 0'
  cracks_end = '0.75 0.5 0'

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 8
    ny = 8
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./damage]
  [../]
  [./intact_bonds_num]
  [../]
  [./critical_stress]
    family = MONOMIAL
    order = CONSTANT
  [../]
[]

[AuxKernels]
  [./bond_status]
    type = RankTwoBasedFailureCriteriaNOSPD
    variable = bond_status
    rank_two_tensor = stress
    critical_variable = critical_stress
    failure_criterion = VonMisesStress
  [../]
[]

[UserObjects]
  [./damage]
    type = NodalDamageIndexPD
    variable = damage
  [../]
  [./intact_bonds]
    type = NodalNumIntactBondsPD
    variable = intact_bonds_num
  [../]
[]

[ICs]
  [./critical_stretch]
    type = ConstantIC
    variable = critical_stress
    value = 150
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1002
    value = 0.0
  [../]
  [./bottom_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1000
    function = '-0.001*t'
  [../]

  [./rbm_x]
    type = RBMPresetOldValuePD
    variable = disp_x
    boundary = 999
  [../]
  [./rbm_y]
    type = RBMPresetOldValuePD
    variable = disp_y
    boundary = 999
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.33
  [../]
  [./strain]
    type = ComputeSmallStrainNOSPD
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none
  start_time = 0
  dt = 0.5
  end_time = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

[Outputs]
  file_base = 2D_stress_failure_NOSPD
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_1/brick1_aug.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick1_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  maximum_lagrangian_update_iterations = 100
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_x
  [../]
  [./disp_x13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_x
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_y
  [../]
  [./disp_y13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_y
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_x8 disp_x13 disp_x16 disp_y5 disp_y8 disp_y13 disp_y16 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    tangential_tolerance = 1e-3
    formulation = augmented_lagrange
    system = constraint
    normalize_penalty = true
    penalty = 1e8
    model = frictionless
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/tensor_mechanics/test/tests/ad_linear_elasticity/linear_elastic_material.i

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 10
  xmax = 50
  ymax = 50
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./diffused]
     [./InitialCondition]
      type = RandomIC
     [../]
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = SMALL
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  use_automatic_differentiation = true
[]

[Kernels]
  [./diff]
    type = ADDiffusion
    variable = diffused
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
[]

[BCs]
  [./bottom]
    type = ADDirichletBC
    variable = diffused
    boundary = 'right'
    value = 1
  [../]
  [./top]
    type = ADDirichletBC
    variable = diffused
    boundary = 'top'
    value = 0
  [../]
  [./disp_x_BC]
    type = ADDirichletBC
    variable = disp_x
    boundary = 'bottom top'
    value = 0.5
  [../]
  [./disp_x_BC2]
    type = ADDirichletBC
    variable = disp_x
    boundary = 'left right'
    value = 0.01
  [../]
  [./disp_y_BC]
    type = ADDirichletBC
    variable = disp_y
    boundary = 'bottom top'
    value = 0.8
  [../]
  [./disp_y_BC2]
    type = ADDirichletBC
    variable = disp_y
    boundary = 'left right'
    value = 0.02
  [../]
[]

[Executioner]
  type = Steady
  solve_type = 'NEWTON'

  nl_rel_tol = 1e-12
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/mortar_tm/2d/frictionless_first/small.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'small'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeLinearElasticStress
    block = 'plank block'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/jacobian/cwp02.i

# Capped weak-plane plasticity
# checking jacobian for tensile failure
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 2
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 0.5
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.05
    rate = 1
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 1
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningConstant
    value = 100
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 0  0 0 0  0 0 2'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 1
    smoothing_tol = 2
    yield_function_tol = 1E-10
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    #petsc_options = '-snes_test_display'
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/beam_eigenstrain_transfer/subapp_err_3.i

# SubApp with 2D model to test multi app vectorpostprocessor to aux var transfer

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 5
  xmin = 0.0
  xmax = 0.5
  ymin = 0.0
  ymax = 0.150080
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./temp]
  [../]
  [./axial_strain]
    order = FIRST
    family = MONOMIAL
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t*(500.0)+300.0
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        strain = SMALL
        incremental = true
        add_variables = true
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
  [../]
  [./axial_strain]
    type = RankTwoAux
    variable = axial_strain
    rank_two_tensor = total_strain
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 298
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  l_tol = 1e-9

  start_time = 0.0
  end_time = 0.075
  dt = 0.0125
  dtmin = 0.0001
[]

[Outputs]
  csv = true
  exodus = true
[]

[VectorPostprocessors]
  [./axial_str]
    type = LineValueSampler
    start_point = '0.5 0.0 0.0'
    end_point = '0.5 0.150080 0.0'
    variable = axial_strain
    num_points = 21
    sort_by = 'y'
  [../]
[]

[Postprocessors]
  [./end_disp]
    type = PointValue
    variable = disp_y
    point = '0.5 0.150080 0.0'
  [../]
[]

modules/xfem/test/tests/solid_mechanics_basic/square_branch_quad_2d.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 10
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[UserObjects]
  [./line_seg_cut_uo0]
    type = LineSegmentCutUserObject
    cut_data = '-1.0000e-10   6.6340e-01   6.6340e-01  -1.0000e-10'
    time_start_cut = 0.0
    time_end_cut = 1.0
  [../]
  [./line_seg_cut_uo1]
    type = LineSegmentCutUserObject
    cut_data = '3.3120e-01   3.3200e-01   1.0001e+00   3.3200e-01'
    time_start_cut = 1.0
    time_end_cut = 2.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    planar_formulation = PLANE_STRAIN
    add_variables = true
  [../]
[]

[Functions]
  [./right_disp_x]
    type = PiecewiseLinear
    x = '0  1.0    2.0   3.0'
    y = '0  0.005  0.01  0.01'
  [../]
  [./top_disp_y]
    type = PiecewiseLinear
    x = '0  1.0    2.0   3.0'
    y = '0  0.005  0.01  0.01'
  [../]
[]

[BCs]
  [./right_x]
    type = FunctionDirichletBC
    boundary = 1
    variable = disp_x
    function = right_disp_x
  [../]
  [./top_y]
    type = FunctionDirichletBC
    boundary = 2
    variable = disp_y
    function = top_disp_y
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 0
    variable = disp_y
    value = 0.0
  [../]
  [./left_x]
    type = DirichletBC
    boundary = 3
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-16
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 2.2
  num_steps = 5000
[]

[Outputs]
  file_base = square_branch_quad_2d_out
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/notched_plastic_block/biaxial_smooth.i

# Uses a multi-smooted version of Mohr-Coulomb (via CappedMohrCoulombStressUpdate and ComputeMultipleInelasticStress) to simulate the following problem.
# A cubical block is notched around its equator.
# All of its outer surfaces have roller BCs, but the notched region is free to move as needed
# The block is initialised with a high hydrostatic tensile stress
# Without the notch, the BCs do not allow contraction of the block, and this stress configuration is admissible
# With the notch, however, the interior parts of the block are free to move in order to relieve stress, and this causes plastic failure
# The top surface is then pulled upwards (the bottom is fixed because of the roller BCs)
# This causes more failure
[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 9
    ny = 9
    nz = 9
    xmin = 0
    xmax = 0.1
    ymin = 0
    ymax = 0.1
    zmin = 0
    zmax = 0.1
  []
  [block_to_remove_xmin]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 -0.01 0.045'
    top_right = '0.01 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = generated_mesh
  []
  [block_to_remove_xmax]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '0.09 -0.01 0.045'
    top_right = '0.11 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_xmin
  []
  [block_to_remove_ymin]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 -0.01 0.045'
    top_right = '0.11 0.01 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_xmax
  []
  [block_to_remove_ymax]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 0.09 0.045'
    top_right = '0.11 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_ymin
  []
  [remove_block]
    type = BlockDeletionGenerator
    block_id = 1
    input = block_to_remove_ymax
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress stress_zz'
    eigenstrain_names = ini_stress
  [../]
[]

[Postprocessors]
  [./uz]
    type = PointValue
    point = '0 0 0.1'
    use_displaced_mesh = false
    variable = disp_z
  [../]
  [./s_zz]
    type = ElementAverageValue
    use_displaced_mesh = false
    variable = stress_zz
  [../]
  [./num_res]
    type = NumResidualEvaluations
  [../]
  [./nr_its] # num_iters is the average number of NR iterations encountered per element in this timestep
    type = ElementAverageValue
    variable = num_iters
  [../]
  [./max_nr_its] # max_num_iters is the maximum number of NR iterations encountered in the element during the whole simulation
    type = ElementExtremeValue
    variable = max_num_iters
  [../]
  [./runtime]
    type = PerfGraphData
    data_type = TOTAL
    section_name = 'Root'
  [../]
[]

[BCs]
  # back=zmin, front=zmax, bottom=ymin, top=ymax, left=xmin, right=xmax
  [./xmin_xzero]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./xmax_xzero]
    type = DirichletBC
    variable = disp_x
    boundary = right
    value = 0.0
  [../]
  [./ymin_yzero]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./ymax_yzero]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.0
  [../]
  [./zmin_zzero]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = '0'
  [../]
  [./zmax_disp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = '1E-6*max(t,0)'
  [../]
[]

[AuxVariables]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./num_iters]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./max_num_iters]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./num_iters_auxk]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = num_iters
  [../]
  [./max_num_iters_auxk]
    type = MaterialRealAux
    property = max_plastic_NR_iterations
    variable = max_num_iters
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 6
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E16
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 5E6
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 10
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 16E9
    poissons_ratio = 0.25
  [../]
  [./mc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = ts
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    smoothing_tol = 0.2E6
    yield_function_tol = 1E-5
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    perform_finite_strain_rotations = false
  [../]
  [./strain_from_initial_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '6E6 0 0  0 6E6 0  0 0 6E6'
    eigenstrain_name = ini_stress
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  start_time = -1
  end_time = 10
  dt = 1
  solve_type = NEWTON
  type = Transient

  l_tol = 1E-2
  nl_abs_tol = 1E-5
  nl_rel_tol = 1E-7
  l_max_its = 200
  nl_max_its = 400

  petsc_options_iname = '-pc_type -pc_asm_overlap -sub_pc_type -ksp_type -ksp_gmres_restart'
  petsc_options_value = ' asm      2              lu            gmres     200'
[]


[Outputs]
  file_base = biaxial_smooth
  perf_graph = true
  exodus = false
  csv = true
[]

modules/combined/test/tests/solid_mechanics/LinearStrainHardening/LinearStrainHardeningRestart2.i

#

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = LinearStrainHardening_test.e
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]


[AuxVariables]

  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_mag]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]


[Functions]
  [./top_pull]
    type = ParsedFunction
    value = t/5.0
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]


[AuxKernels]

  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]

  [./plastic_strain_xx]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]

  [./plastic_strain_yy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]

  [./plastic_strain_zz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]

  [./plastic_strain_mag]
    type = MaterialRealAux
    property = effective_plastic_strain
    variable = plastic_strain_mag
  [../]

 []


[BCs]

  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = top_pull
  [../]

  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]

  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]

  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]

[]


[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'isoplas'
    block = '1'
  [../]
  [./isoplas]
    type = IsotropicPlasticityStressUpdate
    yield_stress = 2.4e2
    hardening_constant = 1206
    relative_tolerance = 1e-25
    absolute_tolerance = 1e-5
  [../]
[]



[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'


  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'


  line_search = 'none'


  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9
  start_time = 6e-3
  end_time = 0.0105
#  num_steps = 100
  dt = 1.5e-3
[]

[Outputs]
  exodus = true
  csv = true
[]

[Problem]
  restart_file_base = LinearStrainHardeningRestart1_out_cp/0004
[]

modules/tensor_mechanics/test/tests/ad_thermal_expansion_function/mean.i

# This test checks the thermal expansion calculated via a mean thermal expansion coefficient.
# The coefficient is selected so as to result in a 1e-4 strain in the x-axis, and to cross over
# from positive to negative strain.

[Mesh]
  [./gen]
    type = GeneratedMeshGenerator
    dim = 3
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
    use_automatic_differentiation = true
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    function = '1 + t'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ADComputeMeanThermalExpansionFunctionEigenstrain
    thermal_expansion_function = cte_func_mean
    thermal_expansion_function_reference_temperature = 1.2
    stress_free_temperature = 1.5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_func_mean]
    type = ParsedFunction
    vars = 'T T_stress_free T_ref end_strain'
    vals = '2 1.5           1.2   1e-4'
    value = 'end_strain / (T - T_stress_free - end_strain * (T_stress_free - T_ref))'
  [../]
[]

[Postprocessors]
  [./disp_x_max]
    type = SideAverageValue
    variable = disp_x
    boundary = right
  [../]
  [./temp_avg]
    type = ElementAverageValue
    variable = temp
  [../]
[]

[Executioner]
  type = Transient

  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/tensor_mechanics/test/tests/action/two_block.i

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  []
  [block1]
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 0 0'
    top_right = '0.5 1 0'
    input = generated_mesh
  []
  [block2]
    type = SubdomainBoundingBoxGenerator
    block_id = 2
    bottom_left = '0.5 0 0'
    top_right = '1 1 0'
    input = block1
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Modules/TensorMechanics/Master]
  [./block1]
    strain = FINITE
    add_variables = true
    #block = 1
  [../]
  [./block2]
    strain = SMALL
    add_variables = true
    block = 2
  [../]
[]

[AuxVariables]
  [./stress_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_theta]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_theta
    execute_on = timestep_end
  [../]
  [./strain_theta]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 2
    index_j = 2
    variable = strain_theta
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./_elastic_stress1]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./_elastic_stress2]
    type = ComputeLinearElasticStress
    block = 2
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    boundary = 'left'
    variable = disp_x
    value = 0.0
  [../]
  [./top]
    type = DirichletBC
    boundary = 'top'
    variable = disp_y
    value = 0.0
  [../]
  [./right]
    type = DirichletBC
    boundary = 'right'
    variable = disp_x
    value = 0.01
  [../]
  [./bottom]
    type = DirichletBC
    boundary = 'bottom'
    variable = disp_y
    value = 0.01
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Executioner]
  type = Steady

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50
[]

[Outputs]
  exodus = true
[]

modules/peridynamics/test/tests/generalized_plane_strain/generalized_plane_strain_squares_OSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./fmg]
    type = FileMeshGenerator
    file = squares.e
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = fmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./scalar_strain_zz1]
    order = FIRST
    family = SCALAR
  [../]
  [./scalar_strain_zz2]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]

  [./stress_zz1]
    order = FIRST
    family = LAGRANGE
  [../]
  [./stress_zz2]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/Peridynamics/Mechanics]
  [./Master]
    [./block1]
      formulation = ORDINARY_STATE
      block = 1001
    [../]
    [./block2]
      formulation = ORDINARY_STATE
      block = 1002
    [../]
  [../]
  [./GeneralizedPlaneStrain]
    [./block1]
      formulation = ORDINARY_STATE
      scalar_out_of_plane_strain = scalar_strain_zz1
      out_of_plane_stress_variable = stress_zz1
      block = 1001
    [../]
    [./block2]
      formulation = ORDINARY_STATE
      scalar_out_of_plane_strain = scalar_strain_zz2
      out_of_plane_stress_variable = stress_zz2
      block = 1002
    [../]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]

  [./stress_zz1]
    type = NodalRankTwoPD
    variable = stress_zz1
    rank_two_tensor = stress
    scalar_out_of_plane_strain = scalar_strain_zz1

    poissons_ratio = 0.3
    youngs_modulus = 1e6
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5

    output_type = component
    index_i = 2
    index_j = 2
    block = 1001
  [../]

  [./stress_zz2]
    type = NodalRankTwoPD
    variable = stress_zz2
    scalar_out_of_plane_strain = scalar_strain_zz2

    poissons_ratio = 0.3
    youngs_modulus = 1e6
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5

    rank_two_tensor = stress
    output_type = component
    index_i = 2
    index_j = 2
    block = 1002
  [../]
[]

[Postprocessors]
  [./react_z1]
    type = NodalVariableIntegralPD
    variable = stress_zz1
    block = 1001
  [../]
  [./react_z2]
    type = NodalVariableIntegralPD
    variable = stress_zz2
    block = 1002
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottom1_x]
    type = DirichletBC
    boundary = 1001
    variable = disp_x
    value = 0.0
  [../]
  [./bottom1_y]
    type = DirichletBC
    boundary = 1001
    variable = disp_y
    value = 0.0
  [../]

  [./bottom2_x]
    type = DirichletBC
    boundary = 1002
    variable = disp_x
    value = 0.0
  [../]
  [./bottom2_y]
    type = DirichletBC
    boundary = 1002
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
    block = '1001 1002'
  [../]

  [./force_density1]
    type = ComputeSmallStrainVariableHorizonMaterialOSPD
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    scalar_out_of_plane_strain = scalar_strain_zz1
    block = 1001
  [../]
  [./force_density2]
    type = ComputeSmallStrainVariableHorizonMaterialOSPD
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    scalar_out_of_plane_strain = scalar_strain_zz2
    block = 1002
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  l_tol = 1e-8
  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
  file_base = generalized_plane_strain_squares_OSPD
[]

modules/combined/test/tests/mortar_tm/2drz/frictionless_first/finite_noaction.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'finite_noaction'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]

  [./slave]
    input = block_sidesets
    type = LowerDBlockFromSidesetGenerator
    sidesets = 'block_left'
    new_block_id = '30'
    new_block_name = 'frictionless_slave_subdomain'
  [../]
  [./master]
    input = slave
    type = LowerDBlockFromSidesetGenerator
    sidesets = 'plank_right'
    new_block_id = '20'
    new_block_name = 'frictionless_master_subdomain'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./frictionless_normal_lm]
    order = ${order}
    block = 'frictionless_slave_subdomain'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
  [../]
  [./plank]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
  [../]
[]

[Constraints]
  [./lm]
    type = NormalNodalLMMechanicalContact
    slave = block_left
    master = plank_right
    variable = frictionless_normal_lm
    master_variable = disp_x
    disp_y = disp_y
    ncp_function_type = min
    use_displaced_mesh = true
  [../]
  [./normal_x]
    type = NormalMortarMechanicalContact
    master_boundary = plank_right
    slave_boundary = block_left
    master_subdomain = frictionless_master_subdomain
    slave_subdomain = frictionless_slave_subdomain
    variable = frictionless_normal_lm
    slave_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
  [../]
  [./normal_y]
    type = NormalMortarMechanicalContact
    master_boundary = plank_right
    slave_boundary = block_left
    master_subdomain = frictionless_master_subdomain
    slave_subdomain = frictionless_slave_subdomain
    variable = frictionless_normal_lm
    slave_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/capped_weak_plane/small_deform11.i

# use an initial stress, then apply a shear deformation and tensile stretch to observe all hardening.
# Here p_trial=12, q_trial=2*Sqrt(20)
# MOOSE yields:
# q_returned = 1.696
# p_returned = 0.100
# intnl_shear = 1.81
# intnl_tens = 0.886
# These give, at the returned point
# cohesion = 1.84
# tanphi = 0.513
# tanpsi = 0.058
# tensile = 0.412
# This means that
# f_shear = -0.0895
# f_tensile = -0.312
# Note that these are within smoothing_tol (=1) of each other
# Hence, smoothing must be used:
# ismoother = 0.0895
# (which gives the yield function value = 0)
# smoother = 0.328
# This latter gives dg/dq = 0.671, dg/dp = 0.368
# for the flow directions.  Finally ga = 2.70, and
# the returned point satisfies the normality conditions.
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    eigenstrain_names = ini_stress
    generate_output = 'stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz plastic_strain_xx plastic_strain_xy plastic_strain_xz plastic_strain_yy plastic_strain_yz plastic_strain_zz strain_xx strain_xy strain_xz strain_yy strain_yz strain_zz'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    variable = disp_x
    boundary = back
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    variable = disp_y
    boundary = back
    value = 0.0
  [../]
  [./bottomz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]

  [./topx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = front
    function = '0.5*t'
  [../]
  [./topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = front
    function = 't'
  [../]
  [./topz]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = '0.5*t'
  [../]
[]


[AuxVariables]
  [./f_shear]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f_tensile]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f_compressive]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl_shear]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl_tensile]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./ls]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./f_shear]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f_shear
  [../]
  [./f_tensile]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f_tensile
  [../]
  [./f_compressive]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f_compressive
  [../]
  [./intnl_shear]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 0
    variable = intnl_shear
  [../]
  [./intnl_tensile]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 1
    variable = intnl_tensile
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./ls]
    type = MaterialRealAux
    property = plastic_linesearch_needed
    variable = ls
  [../]
[]

[Postprocessors]
  [./stress_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./stress_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./stress_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./stress_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./stress_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./stress_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./strainp_xx]
    type = PointValue
    point = '0 0 0'
    variable = plastic_strain_xx
  [../]
  [./strainp_xy]
    type = PointValue
    point = '0 0 0'
    variable = plastic_strain_xy
  [../]
  [./strainp_xz]
    type = PointValue
    point = '0 0 0'
    variable = plastic_strain_xz
  [../]
  [./strainp_yy]
    type = PointValue
    point = '0 0 0'
    variable = plastic_strain_yy
  [../]
  [./strainp_yz]
    type = PointValue
    point = '0 0 0'
    variable = plastic_strain_yz
  [../]
  [./strainp_zz]
    type = PointValue
    point = '0 0 0'
    variable = plastic_strain_zz
  [../]
  [./straint_xx]
    type = PointValue
    point = '0 0 0'
    variable = strain_xx
  [../]
  [./straint_xy]
    type = PointValue
    point = '0 0 0'
    variable = strain_xy
  [../]
  [./straint_xz]
    type = PointValue
    point = '0 0 0'
    variable = strain_xz
  [../]
  [./straint_yy]
    type = PointValue
    point = '0 0 0'
    variable = strain_yy
  [../]
  [./straint_yz]
    type = PointValue
    point = '0 0 0'
    variable = strain_yz
  [../]
  [./straint_zz]
    type = PointValue
    point = '0 0 0'
    variable = strain_zz
  [../]
  [./f_shear]
    type = PointValue
    point = '0 0 0'
    variable = f_shear
  [../]
  [./f_tensile]
    type = PointValue
    point = '0 0 0'
    variable = f_tensile
  [../]
  [./f_compressive]
    type = PointValue
    point = '0 0 0'
    variable = f_compressive
  [../]
  [./intnl_shear]
    type = PointValue
    point = '0 0 0'
    variable = intnl_shear
  [../]
  [./intnl_tensile]
    type = PointValue
    point = '0 0 0'
    variable = intnl_tensile
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
  [./ls]
    type = PointValue
    point = '0 0 0'
    variable = ls
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 2
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 0.5
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.05
    rate = 1
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 0
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningConstant
    value = 1E8
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 4.0
    shear_modulus = 4.0
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 2 0 0 4 2 4 6'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = stress
    perform_finite_strain_rotations = false
  [../]
  [./stress]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 0
    smoothing_tol = 1
    yield_function_tol = 1E-3
    perfect_guess = false
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform11
  [./csv]
    type = CSV
  [../]
[]

modules/combined/test/tests/simple_contact/simple_contact_rspherical.i

#
# This is similar to the patch test for 1D spherical elements with the
#   addition of a contact interface.
#
# The 1D mesh is pinned at x=0.  The displacement at the outer node is set to
#   -3e-3*X where X is the x-coordinate of that node.  That gives a strain of
#   -3e-3 for the x, y, and z directions.
#
# Young's modulus is 1e6, and Poisson's ratio is 0.25.  This gives:
#
# Stress xx, yy, zz = E/(1+nu)/(1-2nu)*strain*((1-nu) + nu + nu) = -6000
#

[Problem]
  coord_type = RSPHERICAL
[]

[Mesh]
  file = simple_contact_rspherical.e
  construct_side_list_from_node_list = true
[]

[GlobalParams]
  displacements = 'disp_x'
[]

[Functions]
  [./ur]
    type = ParsedFunction
    value = '-3e-3*x'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz'
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '1 4'
    function = ur
  [../]
[]

[Contact]
  [./fred]
    master = 2
    slave = 3
    system = constraint
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2 3'
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2 3'
  [../]
[]


[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'lu       101'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-11

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 1
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/isotropic_elasticity_tensor/lambda_shear_modulus_test.i

[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./stress_11]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
  [../]
[]

[AuxKernels]
  [./stress_11]
    type = RankTwoAux
    variable = stress_11
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
  [../]
[]

[BCs]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.001
  [../]
[]

[Materials]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 113636
    shear_modulus = 454545
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady
  l_max_its = 20
  nl_max_its = 10
  solve_type = NEWTON
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/inelastic_strain/elas_plas/elas_plas_nl1.i

#
# Test for effective strain calculation.
# Boundary conditions from NAFEMS test NL1
#
# This is not a verification test. The boundary conditions are applied such
# that the first step generates only elastic stresses. The second and third
# steps generate plastic deformation and the effective strain should be
# increasing throughout the run.
#
[GlobalParams]
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = one_elem2.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./pressure]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./eff_plastic_strain]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = VonMisesStress
    execute_on = timestep_end
  [../]
  [./pressure]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = pressure
    scalar_type = Hydrostatic
    execute_on = timestep_end
  [../]
  [./elastic_strain_xx]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./elastic_strain_yy]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./elastic_strain_zz]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./plastic_strain_xx]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./plastic_strain_yy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./plastic_strain_zz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./tot_strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = tot_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./tot_strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = tot_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./tot_strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = tot_strain_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./eff_plastic_strain]
    type = MaterialRealAux
    property = effective_plastic_strain
    variable = eff_plastic_strain
  [../]
[]

[Functions]
  [./appl_dispy]
    type = PiecewiseLinear
    x = '0     1.0     2.0     3.0'
    y = '0.0 0.208e-4 0.50e-4 1.00e-4'
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 101
    value = 0.0
  [../]
  [./origin_x]
    type = DirichletBC
    variable = disp_x
    boundary = 103
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 102
    value = 0.0
  [../]
  [./origin_y]
    type = DirichletBC
    variable = disp_y
    boundary = 103
    value = 0.0
  [../]
  [./top_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = appl_dispy
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    youngs_modulus = 250e9
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputePlaneFiniteStrain
    block = 1
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'isoplas'
    block = 1
  [../]
  [./isoplas]
    type = IsotropicPlasticityStressUpdate
    yield_stress = 5e6
    hardening_constant = 0.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-12
  l_tol = 1e-4
  l_max_its = 100
  nl_max_its = 20

  dt = 1.0
  start_time = 0.0
  num_steps = 100
  end_time = 3.0
[] # Executioner

[Postprocessors]
  [./stress_xx]
    type = ElementAverageValue
    variable = stress_xx
  [../]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./stress_xy]
    type = ElementAverageValue
    variable = stress_xy
  [../]
  [./vonmises]
    type = ElementAverageValue
    variable = vonmises
  [../]
  [./pressure]
    type = ElementAverageValue
    variable = pressure
  [../]
  [./el_strain_xx]
    type = ElementAverageValue
    variable = elastic_strain_xx
  [../]
  [./el_strain_yy]
    type = ElementAverageValue
    variable = elastic_strain_yy
  [../]
  [./el_strain_zz]
    type = ElementAverageValue
    variable = elastic_strain_zz
  [../]
  [./pl_strain_xx]
    type = ElementAverageValue
    variable = plastic_strain_xx
  [../]
  [./pl_strain_yy]
    type = ElementAverageValue
    variable = plastic_strain_yy
  [../]
  [./pl_strain_zz]
    type = ElementAverageValue
    variable = plastic_strain_zz
  [../]
  [./eff_plastic_strain]
    type = ElementAverageValue
    variable = eff_plastic_strain
  [../]
  [./tot_strain_xx]
    type = ElementAverageValue
    variable = tot_strain_xx
  [../]
  [./tot_strain_yy]
    type = ElementAverageValue
    variable = tot_strain_yy
  [../]
  [./tot_strain_zz]
    type = ElementAverageValue
    variable = tot_strain_zz
  [../]
  [./disp_x1]
    type = NodalVariableValue
    nodeid = 0
    variable = disp_x
  [../]
  [./disp_x4]
    type = NodalVariableValue
    nodeid = 3
    variable = disp_x
  [../]
  [./disp_y1]
    type = NodalVariableValue
    nodeid = 0
    variable = disp_y
  [../]
  [./disp_y4]
    type = NodalVariableValue
    nodeid = 3
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
[]

[Outputs]
  exodus = true
  csv = true
  [./console]
    type = Console
    output_linear = true
  [../]
[] # Outputs

modules/combined/test/tests/beam_eigenstrain_transfer/subapp1_uo_transfer.i

# SubApp with 2D model to test multi app vectorpostprocessor to aux var transfer

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 5
  xmin = 0.0
  xmax = 0.5
  ymin = 0.0
  ymax = 0.150080
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./temp]
  [../]
  [./axial_strain]
    order = FIRST
    family = MONOMIAL
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t*(500.0)+300.0
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        strain = SMALL
        incremental = true
        add_variables = true
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
  [../]
  [./axial_strain]
    type = RankTwoAux
    variable = axial_strain
    rank_two_tensor = total_strain
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 298
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  l_tol = 1e-9

  start_time = 0.0
  end_time = 0.075
  dt = 0.0125
  dtmin = 0.0001
[]

[Outputs]
  csv = true
  exodus = true
[]

[VectorPostprocessors]
  [./axial_str]
    type = LineValueSampler
    start_point = '0.5 0.0 0.0'
    end_point = '0.5 0.150080 0.0'
    variable = 'axial_strain'
    num_points = 21
    sort_by = 'id'
  [../]
[]

[Postprocessors]
  [./end_disp]
    type = PointValue
    variable = disp_y
    point = '0.5 0.150080 0.0'
  [../]
[]

modules/combined/test/tests/mortar_tm/2d/ad_frictionless_sec/finite.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'finite'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
    use_automatic_differentiation = true
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = ADFunctionDirichletBC
    variable = disp_x
    preset = false
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/combined/test/tests/nodal_area/nodal_area_Hex20.i

[Mesh]
  file = nodal_area_Hex20.e
[]

[GlobalParams]
  order = SECOND
  displacements = 'displ_x displ_y displ_z'
[]

[Functions]
  [./disp]
    type = PiecewiseLinear
    x = '0     1'
    y = '0  20e-6'
  [../]
[]

[Variables]
  [./displ_x]
  [../]
  [./displ_y]
  [../]
  [./displ_z]
  [../]
[]

[AuxVariables]
  [./react_x]
  [../]
  [./react_y]
  [../]
  [./react_z]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    incremental = true
    save_in = 'react_x react_y react_z'
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx'
  [../]
[]

[BCs]
  [./move_right]
    type = FunctionDirichletBC
    boundary = '1'
    variable = displ_x
    function = disp
  [../]

  [./fixed_x]
    type = DirichletBC
    boundary = '3 4'
    variable = displ_x
    value = 0
  [../]

  [./fixed_y]
    type = DirichletBC
    boundary = 10
    variable = displ_y
    value = 0
  [../]

  [./fixed_z]
    type = DirichletBC
    boundary = 11
    variable = displ_z
    value = 0
  [../]
[]

[Contact]
  [./dummy_name]
    master = 3
    slave = 2
    penalty = 1e7
    tangential_tolerance = 1e-5
    system = Constraint
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'
  nl_rel_tol = 1e-9
  l_tol = 1e-4
  l_max_its = 40

  start_time = 0.0
  dt = 1.0
  end_time = 1.0

  [./Quadrature]
    order = THIRD
  [../]
[]

[Postprocessors]
  [./react_x]
    type = NodalSum
    variable = react_x
    boundary = 1
    execute_on = 'initial timestep_end'
  [../]
  [./total_area]
    type = NodalSum
    variable = nodal_area_dummy_name
    boundary = 2
    execute_on = 'initial timestep_end'
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_3/ring3_template1.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring3_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'
  petsc_options = '-mat_superlu_dist_iterrefine -mat_superlu_dist_replacetinypivot'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-9
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x11 disp_y11 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/plane_1/plane1_template1.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane1_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-9
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x7 disp_y7 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/combined/test/tests/ad_cavity_pressure/3d.i

#
# Cavity Pressure Test
#
# This test is designed to compute an internal pressure based on
#   p = n * R * T / V
# where
#   p is the pressure
#   n is the amount of material in the volume (moles)
#   R is the universal gas constant
#   T is the temperature
#   V is the volume
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total
#   initial volume is 7.
# The test adjusts n, T, and V in the following way:
#   n => n0 + alpha * t
#   T => T0 + beta * t
#   V => V0 + gamma * t
# with
#   alpha = n0
#   beta = T0 / 2
#   gamma = - (0.003322259...) * V0
#   T0 = 240.54443866068704
#   V0 = 7
#   n0 = f(p0)
#   p0 = 100
#   R = 8.314472 J * K^(-1) * mol^(-1)
#
# So, n0 = p0 * V0 / R / T0 = 100 * 7 / 8.314472 / 240.544439
#        = 0.35
#
# The parameters combined at t = 1 gives p = 301.
#

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = 3d.e
[]

[Functions]
  [./displ_positive]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.0029069767441859684'
  [../]
  [./displ_negative]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 -0.0029069767441859684'
  [../]
  [./temp1]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1.5'
    scale_factor = 240.54443866068704
  [../]
  [./material_input_function]
    type = PiecewiseLinear
    x = '0    1'
    y = '0 0.35'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./temp]
    initial_condition = 240.54443866068704
  [../]
  [./material_input]
  [../]
[]

[AuxVariables]
  [./pressure_residual_x]
  [../]
  [./pressure_residual_y]
  [../]
  [./pressure_residual_z]
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zx]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    use_automatic_differentiation = true
  [../]
  [./heat]
    type = ADDiffusion
    variable = temp
    use_displaced_mesh = true
  [../]
  [./material_input_dummy]
    type = ADDiffusion
    variable = material_input
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 2
    variable = stress_yz
  [../]
  [./stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 0
    variable = stress_zx
  [../]
[]

[BCs]
  [./no_x_exterior]
    type = DirichletBC
    variable = disp_x
    boundary = '7 8'
    value = 0.0
  [../]
  [./no_y_exterior]
    type = DirichletBC
    variable = disp_y
    boundary = '9 10'
    value = 0.0
  [../]
  [./no_z_exterior]
    type = DirichletBC
    variable = disp_z
    boundary = '11 12'
    value = 0.0
  [../]
  [./prescribed_left]
    type = ADFunctionDirichletBC
    variable = disp_x
    boundary = 13
    function = displ_positive
  [../]
  [./prescribed_right]
    type = ADFunctionDirichletBC
    variable = disp_x
    boundary = 14
    function = displ_negative
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = '15 16'
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = '17 18'
    value = 0.0
  [../]
  [./no_x_interior]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./no_y_interior]
    type = DirichletBC
    variable = disp_y
    boundary = '3 4'
    value = 0.0
  [../]
  [./no_z_interior]
    type = DirichletBC
    variable = disp_z
    boundary = '5 6'
    value = 0.0
  [../]
  [./temperatureInterior]
    type = ADFunctionDirichletBC
    boundary = 100
    function = temp1
    variable = temp
  [../]
  [./MaterialInput]
    type = ADFunctionDirichletBC
    boundary = '100 13 14 15 16'
    function = material_input_function
    variable = material_input
  [../]
  [./CavityPressure]
    [./1]
      boundary = 100
      initial_pressure = 100
      material_input = materialInput
      R = 8.314472
      temperature = aveTempInterior
      volume = internalVolume
      startup_time = 0.5
      output = ppress
      save_in = 'pressure_residual_x pressure_residual_y pressure_residual_z'
      use_automatic_differentiation = true
    [../]
  [../]
[]

[Materials]
  [./elast_tensor1]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e1
    poissons_ratio = 0
    block = 1
  [../]
  [./strain1]
    type = ADComputeFiniteStrain
    block = 1
  [../]
  [./stress1]
    type = ADComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./elast_tensor2]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0
    block = 2
  [../]
  [./strain2]
    type = ADComputeFiniteStrain
    block = 2
  [../]
  [./stress2]
    type = ADComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'NEWTON'

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_rel_tol = 1e-12
  l_tol = 1e-12

  l_max_its = 20

  dt = 0.5
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 100
    execute_on = 'initial linear'
  [../]
  [./aveTempInterior]
    type = SideAverageValue
    boundary = 100
    variable = temp
    execute_on = 'initial linear'
  [../]
  [./materialInput]
    type = SideAverageValue
    boundary = '7 8 9 10 11 12'
    variable = material_input
    execute_on = linear
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/adaptive_timestepping/adapt_tstep_function_change_restart2.i

# This is a test designed to evaluate the cabability of the
# IterationAdaptiveDT TimeStepper to adjust time step size according to
# a function.  For example, if the power input function for a BISON
# simulation rapidly increases or decreases, the IterationAdaptiveDT
# TimeStepper should take time steps small enough to capture the
# oscillation.

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  order = FIRST
  family = LAGRANGE
  block = 1
[]

[Mesh]
  file = 1hex8_10mm_cube.e
[]

[Functions]
  [./Fiss_Function]
    type = PiecewiseLinear
    x = '0 1e6  2e6  2.001e6 2.002e6'
    y = '0 3e8  3e8  12e8    0'
  [../]
[]

[Variables]
  [./disp_x]
  [../]

  [./disp_y]
  [../]

  [./disp_z]
  [../]

  [./temp]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    volumetric_locking_correction = true
    incremental = true
    eigenstrain_names = thermal_expansion
    decomposition_method = EigenSolution
    add_variables  = true
    generate_output = 'vonmises_stress'
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]

  [./heat_ie]
    type = HeatConductionTimeDerivative
    variable = temp
  [../]

  [./heat_source]
     type = HeatSource
     variable = temp
     value = 1.0
     function = Fiss_Function
  [../]
[]

[BCs]
 [./bottom_temp]
   type = DirichletBC
   variable = temp
   boundary = 1
   value = 300
 [../]
 [./top_bottom_disp_x]
   type = DirichletBC
   variable = disp_x
   boundary = '1'
   value = 0
 [../]
 [./top_bottom_disp_y]
   type = DirichletBC
   variable = disp_y
   boundary = '1'
   value = 0
 [../]
 [./top_bottom_disp_z]
   type = DirichletBC
   variable = disp_z
   boundary = '1'
   value = 0
 [../]
[]

[Materials]
 [./thermal]
    type = HeatConductionMaterial
    temp = temp
    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 300e6
    poissons_ratio = .3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 5e-6
    stress_free_temperature = 300.0
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]

  [./density]
    type = Density
    density = 10963.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  verbose = true
  nl_abs_tol = 1e-10
  num_steps = 50000
  end_time = 2.002e6
  [./TimeStepper]
    type = IterationAdaptiveDT
    timestep_limiting_function = Fiss_Function
    max_function_change = 3e7
    dt = 1e6
  [../]
[]

[Postprocessors]
  [./Temperature_of_Block]
    type = ElementAverageValue
    variable = temp
    execute_on = 'timestep_end'
  [../]

  [./vonMises]
    type = ElementAverageValue
    variable = vonmises_stress
    execute_on = 'timestep_end'
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 10
  [../]
[]

[Problem]
  restart_file_base = adapt_tstep_function_change_restart1_checkpoint_cp/0065
[]

modules/combined/test/tests/elastic_thermal_patch/elastic_thermal_patch.i

# Patch Test

# This test is designed to compute constant xx, yy, zz, xy, yz, and zx
#  stress on a set of irregular hexes.  The mesh is composed of one
#  block with seven elements.  The elements form a unit cube with one
#  internal element.  There is a nodeset for each exterior node.

# The cube is displaced by 1e-6 units in x, 2e-6 in y, and 3e-6 in z.
#  The faces are sheared as well (1e-6, 2e-6, and 3e-6 for xy, yz, and
#  zx).  This gives a uniform strain/stress state for all six unique
#  tensor components.

# With Young's modulus at 1e6 and Poisson's ratio at 0, the shear
#  modulus is 5e5 (G=E/2/(1+nu)).  Therefore, for the mechanical strain,
#
#  stress xx = 1e6 * 1e-6 = 1
#  stress yy = 1e6 * 2e-6 = 2
#  stress zz = 1e6 * 3e-6 = 3
#  stress xy = 2 * 5e5 * 1e-6 / 2 = 0.5
#             (2 * G   * gamma_xy / 2 = 2 * G * epsilon_xy)
#  stress yz = 2 * 5e5 * 2e-6 / 2 = 1
#  stress zx = 2 * 5e5 * 3e-6 / 2 = 1.5

# However, we must also consider the thermal strain.
# The temperature moves 100 degrees, and the coefficient of thermal
#  expansion is 1e-8.  Therefore, the thermal strain (and the displacement
#  since this is a unit cube) is 1e-6.

# Therefore, the overall effect is (at time 1, with a 50 degree delta):
#
#  stress xx = 1e6 * (1e-6-0.5e-6) = 0.5
#  stress yy = 1e6 * (2e-6-0.5e-6) = 1.5
#  stress zz = 1e6 * (3e-6-0.5e-6) = 2.5
#  stress xy = 2 * 5e5 * 1e-6 / 2 = 0.5
#             (2 * G   * gamma_xy / 2 = 2 * G * epsilon_xy)
#  stress yz = 2 * 5e5 * 2e-6 / 2 = 1
#  stress zx = 2 * 5e5 * 3e-6 / 2 = 1.5
#
# At time 2:
#
#  stress xx = 1e6 * (1e-6-1e-6) = 0
#  stress yy = 1e6 * (2e-6-1e-6) = 1
#  stress zz = 1e6 * (3e-6-1e-6) = 2
#  stress xy = 2 * 5e5 * 1e-6 / 2 = 0.5
#             (2 * G   * gamma_xy / 2 = 2 * G * epsilon_xy)
#  stress yz = 2 * 5e5 * 2e-6 / 2 = 1
#  stress zx = 2 * 5e5 * 3e-6 / 2 = 1.5

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  temperature = temp
[]

[Mesh]
  file = elastic_thermal_patch_test.e
[]

[Functions]
  [./rampConstant1]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 1e-6
  [../]
  [./rampConstant2]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 2e-6
  [../]
  [./rampConstant3]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 3e-6
  [../]
  [./rampConstant4]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 4e-6
  [../]
  [./rampConstant6]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 6e-6
  [../]
  [./tempFunc]
    type = PiecewiseLinear
    x = '0. 2.'
    y = '117.56 217.56'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]

  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules/TensorMechanics/Master/All]
  add_variables = true
  strain = FINITE
  eigenstrain_names = eigenstrain
  generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./node1_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./node1_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = rampConstant2
  [../]
  [./node1_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 1
    function = rampConstant3
  [../]

  [./node2_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 2
    function = rampConstant1
  [../]
  [./node2_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 2
    function = rampConstant2
  [../]
  [./node2_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 2
    function = rampConstant6
  [../]

  [./node3_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 3
    function = rampConstant1
  [../]
  [./node3_y]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]
  [./node3_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 3
    function = rampConstant3
  [../]

  [./node4_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]
  [./node4_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
  [./node4_z]
    type = DirichletBC
    variable = disp_z
    boundary = 4
    value = 0.0
  [../]

  [./node5_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 5
    function = rampConstant1
  [../]
  [./node5_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = rampConstant4
  [../]
  [./node5_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 5
    function = rampConstant3
  [../]

  [./node6_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 6
    function = rampConstant2
  [../]
  [./node6_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 6
    function = rampConstant4
  [../]
  [./node6_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 6
    function = rampConstant6
  [../]

  [./node7_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 7
    function = rampConstant2
  [../]
  [./node7_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 7
    function = rampConstant2
  [../]
  [./node7_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 7
    function = rampConstant3
  [../]

  [./node8_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 8
    function = rampConstant1
  [../]
  [./node8_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 8
    function = rampConstant2
  [../]
  [./node8_z]
    type = DirichletBC
    variable = disp_z
    boundary = 8
    value = 0.0
  [../]

  [./temp]
    type = FunctionDirichletBC
    variable = temp
    boundary = '10 12'
    function = tempFunc
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 0.333333333333333e6
    shear_modulus = 0.5e6
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 117.56
    thermal_expansion_coeff = 1e-8
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./heat]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]

  [./density]
    type = Density
    density = 1.0
    disp_x = disp_x
    disp_y = disp_y
    disp_z = disp_z
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-12

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/material_limit_time_step/elas_plas/nafems_nl1_lim.i

#
# Tests material model IsotropicPlasticity with material based time stepper
# Boundary conditions from NAFEMS test NL1
#
[GlobalParams]
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]#Comment
  file = one_elem2.e
[] # Mesh

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[] # Variables

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_strain_eff]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
[] # AuxVariables

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = VonMisesStress
    execute_on = timestep_end
  [../]
  [./elastic_strain_yy]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./plastic_strain_eff]
    type = MaterialRealAux
    property = effective_plastic_strain
    variable = plastic_strain_eff
  [../]
  [./tot_strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = tot_strain_yy
    index_i = 1
    index_j = 1
  [../]
[] # AuxKernels

[Functions]
  [./appl_dispx]
    type = PiecewiseLinear
    x = '0   1.0   2.0   3.0  4.0   5.0  6.0  7.0  8.0'
    y = '0.0 0.25e-4 0.50e-4 0.50e-4 0.50e-4 0.25e-4 0.0 0.0 0.0'
  [../]
  [./appl_dispy]
    type = PiecewiseLinear
    x = '0   1.0   2.0   3.0  4.0   5.0  6.0  7.0  8.0'
    y = '0.0 0.0  0.0 0.25e-4 0.50e-4 0.50e-4 0.50e-4  0.25e-4 0.0 '
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 101
    value = 0.0
  [../]
  [./origin_x]
    type = DirichletBC
    variable = disp_x
    boundary = 103
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 102
    value = 0.0
  [../]
  [./origin_y]
    type = DirichletBC
    variable = disp_y
    boundary = 103
    value = 0.0
  [../]
  [./top_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = appl_dispy
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 2
    function = appl_dispx
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    youngs_modulus = 250e9
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputePlaneFiniteStrain
    block = 1
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'isoplas'
    block = 1
  [../]
  [./isoplas]
    type = IsotropicPlasticityStressUpdate
    yield_stress = 5e6
    hardening_constant = 0.0
    relative_tolerance = 1e-20
    absolute_tolerance = 1e-8
    max_inelastic_increment = 0.000001
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-12
  l_tol = 1e-4
  l_max_its = 100
  nl_max_its = 20

  [./TimeStepper]
    type = IterationAdaptiveDT
    dt = 0.1
    time_t = '1.0  2.0  3.0  4.0  5.0  6.0  7.0  8.0'
    time_dt = '0.1 0.1  0.1  0.1  0.1  0.1  0.1  0.1'
    optimal_iterations = 30
    iteration_window = 9
    growth_factor = 2.0
    cutback_factor = 0.5
    timestep_limiting_postprocessor = matl_ts_min
  [../]

  start_time = 0.0
  num_steps = 1000
  end_time = 8.0
[] # Executioner

[Postprocessors]
  [./matl_ts_min]
    type = MaterialTimeStepPostprocessor
  [../]
  [./stress_xx]
    type = ElementAverageValue
    variable = stress_xx
  [../]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./vonmises]
    type = ElementAverageValue
    variable = vonmises
  [../]
  [./el_strain_yy]
    type = ElementAverageValue
    variable = elastic_strain_yy
  [../]
  [./plas_strain_eff]
    type = ElementAverageValue
    variable = plastic_strain_eff
  [../]
  [./tot_strain_yy]
    type = ElementAverageValue
    variable = tot_strain_yy
  [../]
  [./disp_x1]
    type = NodalVariableValue
    nodeid = 0
    variable = disp_x
  [../]
  [./disp_x4]
    type = NodalVariableValue
    nodeid = 3
    variable = disp_x
  [../]
  [./disp_y1]
    type = NodalVariableValue
    nodeid = 0
    variable = disp_y
  [../]
  [./disp_y4]
    type = NodalVariableValue
    nodeid = 3
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
[]

[Outputs]
  exodus = true
  csv = true
  [./console]
    type = Console
    output_linear = true
  [../]
[] # Outputs

modules/combined/test/tests/internal_volume/rz_quad8.i

#
# Internal Volume Test
#
# This test is designed to compute the internal volume of a space considering
#   an embedded volume inside.
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total volume
#   is 7.
#

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = meshes/rz_quad8.e
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 1e4
  [../]
[]

[Variables]
  [./disp_x]
    order = SECOND
    family = LAGRANGE
  [../]

  [./disp_y]
    order = SECOND
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    incremental = true
    strain = FINITE
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  [../]

  [./Pressure]
    [./the_pressure]
      boundary = 3
      function = pressure
      disp_x = disp_x
      disp_y = disp_y
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK

  start_time = 0.0
  dt = 1.0
  end_time = 1.0

  [./Quadrature]
    order = THIRD
  [../]
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 2
    execute_on = 'initial timestep_end'
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/thermal_expansion_function/instantaneous.i

# This test checks the thermal expansion calculated via a instantaneous thermal expansion coefficient.
# The coefficient is selected so as to result in a 1e-4 strain in the x-axis, and to cross over
# from positive to negative strain.

[Mesh]
  [./gen]
    type = GeneratedMeshGenerator
    dim = 3
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    function = '1 + t'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeInstantaneousThermalExpansionFunctionEigenstrain
    thermal_expansion_function = 4e-4
    stress_free_temperature = 1.5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Postprocessors]
  [./disp_x_max]
    type = SideAverageValue
    variable = disp_x
    boundary = right
  [../]
  [./temp_avg]
    type = ElementAverageValue
    variable = temp
  [../]
[]

[Executioner]
  type = Transient

  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/peridynamics/test/tests/simple_tests/2D_regularD_variableH_BPD.i

# Test for bond-based peridynamic formulation
# for regular grid from generated mesh with varying bond constants

# Square plate with Dirichlet boundary conditions applied
# at the left, top and bottom edges

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1002
    value = 0.0
  [../]
  [./bottom_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1000
    function = '-0.001*t'
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = BOND
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.33
  [../]

  [./force_density]
    type = ComputeSmallStrainVariableHorizonMaterialBPD
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none
  start_time = 0
  end_time = 1
[]

[Outputs]
  file_base = 2D_regularD_variableH_BPD
  exodus = true
[]

modules/combined/test/tests/contact_adaptivity/contact_initial_adaptivity.i

# This is a test of the usage of initial adaptivity with contact.
# It ensures that contact is enforced on the new nodes that are
# created due to refinement on the slave side of the interface.

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = 2blocks.e
  patch_size = 80
  parallel_type = replicated
[]

[AuxVariables]
  [./penetration]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Functions]
  [./negramp]
    type = ParsedFunction
    value = -t/10
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  []
[]

[AuxKernels]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = negramp
  [../]
  [./right_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+6
    system = constraint
    normal_smoothing_distance = 0.1
  [../]
[]

[Adaptivity]
  steps = 0
  marker = box
  max_h_level = 2
  initial_steps = 2
  [./Markers]
    [./box]
      type = BoxMarker
      bottom_left = '0.5 -2.0 0.0'
      top_right = '0.75 2.0 0.0'
      inside = refine
      outside = do_nothing
    [../]
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu       superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.2
  end_time = 1.0
  l_tol = 1e-6
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-9
[]

[Outputs]
  exodus = true
  console = true
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_4/brick4_template2.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick4_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_x
  [../]
  [./disp_x64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_x
  [../]
  [./disp_y59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_y
  [../]
  [./disp_y64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x59 disp_y59 disp_x64 disp_y64 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/combined/test/tests/simple_contact/simple_contact_test2.i

[Mesh]
  file = contact.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx'
  [../]
[]

[Contact]
  [./dummy_name]
    master = 3
    slave = 2
    penalty = 5e6
    formulation = penalty
    system = constraint
    master_slave_jacobian = false
    normalize_penalty = true
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./left_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.0001
  [../]

  [./right_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]

  [./right_z]
    type = DirichletBC
    variable = disp_z
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre    boomeramg      101'

  line_search = 'none'

  nl_abs_tol = 1e-8

  l_max_its = 100
  nl_max_its = 10
  dt = 1.0
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/evolving_mass_density/shear_test_tensors.i

#  Element mass tests

#  This series of tests is designed to compute the mass of elements based on
#  an evolving mass density calculation.  The tests consist of expansion and compression
#  of the elastic patch test model along each axis, uniform expansion and compression,
#  and shear in each direction.  The expansion and compression tests change the volume of
#  the elements.  The corresponding change in density should compensate for this so the
#  mass remains constant.  The shear tests should not result in a volume change, and this
#  is checked too.  The mass calculation is done with the post processor called Mass.

#  The tests/file names are as follows:

#  Expansion and compression along a single axis
#  expand_compress_x_test_out.e
#  expand_compress_y_test_out.e
#  expand_compress_z_test_out.e

#  Volumetric expansion and compression
#  uniform_expand_compress_test.i

#  Zero volume change shear along each axis
#  shear_x_test_out.e
#  shear_y_test_out.e
#  shear_z_test_out.e

#  The resulting mass calculation for these tests should always be = 1.

# This test is a duplicate of the uniform_expand_compress_test.i test for solid mechanics, and the
#   output of this tensor mechanics test is compared to the original
#   solid mechanics output.  The duplication is necessary to test the
#   migrated tensor mechanics version while maintaining tests for solid mechanics.


[Mesh]
  file = elastic_patch.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./rampConstant1]
    type = PiecewiseLinear
    x = '0.00 1.00  2.0   3.00'
    y = '0.00 0.25  0.0  -0.25'
    scale_factor = 1
  [../]
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./bot_x]
    type = DirichletBC
    variable = disp_x
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    value = 0
  [../]
  [./bot_z]
    type = DirichletBC
    variable = disp_z
    value = 0
  [../]

  [./top_x]
    variable = disp_x
    preset = false
  [../]
  [./top_y]
    variable = disp_y
    preset = false
  [../]
  [./top_z]
    variable = disp_z
    preset = false
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2 3 4 5 6 7'
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]

  [./small_strain]
    type = ComputeSmallStrain
    block = ' 1 2 3 4 5 6 7'
  [../]

  [./elastic_stress]
    type = ComputeLinearElasticStress
    block = '1 2 3 4 5 6 7'
  [../]
[]

[Executioner]

  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10
  l_max_its = 20
  start_time = 0.0
  dt = 1.0
  num_steps = 3
  end_time = 3.0
[] # Executioner

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[] # Outputs

[Postprocessors]
  [./Mass]
    type = Mass
    variable = disp_x
    execute_on = 'initial timestep_end'
  [../]
[]

modules/peridynamics/test/tests/simple_tests/2D_irregularD_variableH_BPD.i

# Test for bond-based peridynamic formulation
# for irregular grid from file mesh with varying bond constants

# Square plate with Dirichlet boundary conditions applied
# at the left, top and bottom edges

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./fmg]
    type = FileMeshGenerator
    file = square.e
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = fmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1001
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1004
    value = 0.0
  [../]
  [./bottom_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1002
    function = '-0.001*t'
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = BOND
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.33
  [../]

  [./force_density]
    type = ComputeSmallStrainVariableHorizonMaterialBPD
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none
  start_time = 0
  end_time = 1
[]

[Outputs]
  file_base = 2D_irregularD_variableH_BPD
  exodus = true
[]

modules/combined/test/tests/catch_release/catch_release.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = catch_release.e
[]

[Functions]
  [./up]
    type = PiecewiseLinear
    x = '0 1 2.00 3 4'
    y = '0 1 1.01 1 0'
    scale_factor = 0.5
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_yy'
  []
[]

[Contact]
  [./dummy_name]
    master = 2
    slave = 3
    penalty = 1e6
    model = frictionless
    system = Constraint
  [../]
[]

[BCs]
  [./lateral]
    type = DirichletBC
    variable = disp_x
    boundary = '1 4'
    value = 0.0
  [../]

  [./bottom_up]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = 1
    function = up
  [../]

  [./out]
    type = DirichletBC
    variable = disp_z
    boundary = '1 4'
    value = 0.0
  [../]

  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuffStress]
    type = ComputeFiniteStrainElasticStress
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  #petsc_options_iname = '-pc_type -snes_type -snes_ls -snes_linesearch_type -ksp_gmres_restart'
  #petsc_options_value = 'ilu      ls         basic    basic                    101'
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre    boomeramg      101'

  line_search = 'none'

  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-4
  l_tol = 1e-4

  l_max_its = 100
  nl_max_its = 20
  dt = 1.0
  end_time = 4.0
[]

[Outputs]
  exodus = true
[]

modules/xfem/test/tests/solid_mechanics_basic/penny_crack_cfp.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 3
  ny = 3
  nz = 3
  xmin = -1.1
  xmax = 1.1
  ymin = -1.1
  ymax = 1.1
  zmin = -1.1
  zmax = 1.1
  elem_type = HEX8
  displacements = 'disp_x disp_y disp_z'
[]

[UserObjects]
  [./circle_cut_uo]
    type = CircleCutUserObject
    cut_data = '0  0 0
                0 -0.5 0
                -0.5 0 0'
  [../]
[]

[AuxVariables]
  [./SED]
   order = CONSTANT
    family = MONOMIAL
  [../]
[]

[DomainIntegral]
  integrals = 'Jintegral'
  disp_x = disp_x
  disp_y = disp_y
  disp_z = disp_z
  crack_direction_method = CurvedCrackFront
  radius_inner = '0.3'
  radius_outer = '0.6'
  poissons_ratio = 0.3
  youngs_modulus = 207000
  block = 0
  crack_front_points_provider = circle_cut_uo
  number_points_from_provider = 10
  convert_J_to_K = true
  closed_loop = true
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
    block = 0
  [../]
[]

[Functions]
  [./top_trac_z]
    type = ConstantFunction
    value = 10
  [../]
[]


[BCs]
  [./top_z]
    type = FunctionNeumannBC
    boundary = front
    variable = disp_z
    function = top_trac_z
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = back
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = back
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    boundary = back
    variable = disp_z
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  execute_on = timestep_end
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/ad_thermal_expansion_function/dilatation.i

# This test checks the thermal expansion calculated via an dilatation function.
# The coefficient is selected so as to result in a 1e-4 strain in the x-axis, and to cross over
# from positive to negative strain.

[Mesh]
  [./gen]
    type = GeneratedMeshGenerator
    dim = 3
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
    use_automatic_differentiation = true
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    function = '1 + t'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ADComputeDilatationThermalExpansionFunctionEigenstrain
    dilatation_function = cte_dilatation
    stress_free_temperature = 1.5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_dilatation]
    type = PiecewiseLinear
    x = '1 2'
    y = '-1e-4 1e-4'
  [../]
[]

[Postprocessors]
  [./disp_x_max]
    type = SideAverageValue
    variable = disp_x
    boundary = right
  [../]
  [./temp_avg]
    type = ElementAverageValue
    variable = temp
  [../]
[]

[Executioner]
  type = Transient

  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_as_2d.i

#This tests the J-Integral evaluation capability.
#This is a 3d extrusion of a 2d plane strain model with one element
#through the thickness, and calculates the J-Integrals using options
#to treat it as 2d.
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack_3d_as_2d.e
  partitioner = centroid
  centroid_partitioner_direction = z
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  radius_inner = '4.0 4.5 5.0 5.5 6.0'
  radius_outer = '4.5 5.0 5.5 6.0 6.5'
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 500
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]

   type = Transient
  # Two sets of linesearch options are for petsc 3.1 and 3.3 respectively
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 20
   nl_abs_tol = 1e-5
   l_tol = 1e-2

   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1
[]

[Outputs]
  file_base = j_integral_3d_as_2d_out
  exodus = true
  csv = true
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_4/brick4_mu_0_2_pen.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick4_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
  [./tang_force_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_x
  [../]
  [./disp_x64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_x
  [../]
  [./disp_y59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_y
  [../]
  [./disp_y64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  file_base = brick4_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = brick4_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x59 disp_y59 disp_x64 disp_y64 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+6
  [../]
[]

modules/combined/test/tests/mortar_tm/2d/ad_frictionless_sec/small.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'small'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
    use_automatic_differentiation = true
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = ADFunctionDirichletBC
    variable = disp_x
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
    block = 'plank block'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/thermal_expansion_function/finite_const.i

# This tests the thermal expansion coefficient function using both
# options to specify that function: mean and instantaneous.  There
# two blocks, each containing a single element, and these use the
# two variants of the function.

# In this test, the instantaneous CTE function has a constant value,
# while the mean CTE function is an analytic function designed to
# give the same response.  If \bar{alpha}(T) is the mean CTE function,
# and \alpha(T) is the instantaneous CTE function,

# \bar{\alpha}(T) = 1/(T-Tref) \intA^{T}_{Tsf} \alpha(T) dT

# where Tref is the reference temperature used to define the mean CTE
# function, and Tsf is the stress-free temperature.

# This version of the test uses finite deformation theory.
# The two models produce very similar results.  There are slight
# differences due to the large deformation treatment.

[Mesh]
  file = 'blocks.e'
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    block = '1 2'
    function = temp_func
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain1]
    type = ComputeMeanThermalExpansionFunctionEigenstrain
    block = 1
    thermal_expansion_function = cte_func_mean
    thermal_expansion_function_reference_temperature = 0.5
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
  [./thermal_expansion_strain2]
    type = ComputeInstantaneousThermalExpansionFunctionEigenstrain
    block = 2
    thermal_expansion_function = cte_func_inst
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_func_mean]
    type = ParsedFunction
    vars = 'tsf tref scale' #stress free temp, reference temp, scale factor
    vals = '0.0 0.5  1e-4'
    value = 'scale * (t - tsf) / (t - tref)'
  [../]
  [./cte_func_inst]
    type = PiecewiseLinear
    xy_data = '0 1.0
               2 1.0'
    scale_factor = 1e-4
  [../]

  [./temp_func]
    type = PiecewiseLinear
    xy_data = '0 1
               1 2'
  [../]
[]

[Postprocessors]
  [./disp_1]
    type = NodalMaxValue
    variable = disp_x
    boundary = 101
  [../]

  [./disp_2]
    type = NodalMaxValue
    variable = disp_x
    boundary = 102
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  l_max_its = 100
  l_tol = 1e-4
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/ring_contact/ring_contact.i

#
# A test of contact with quadratic (Hex20) elements
#
# A stiff ring is pushed into a soft base.  The base shows a circular impression.
#

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = false
[]

[Mesh]
  file = ring_contact.e
[]

[Functions]
  [./ring_y]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 1'
    scale_factor = -0.2
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[Contact]
  [./dummy_name]
    master = 3
    slave = 2
    penalty = 1e3
    tension_release = -1
    system = Constraint
  [../]
[]

[BCs]
  [./plane]
    type = DirichletBC
    variable = disp_z
    boundary = 10
    value = 0.0
  [../]

  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./ring_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]

  [./ring_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = ring_y
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e3
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]  # Materials

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'lu       101'
  line_search = 'none'
  nl_rel_tol = 1.e-10
  l_max_its = 100
  nl_max_its = 10
  dt = 0.1
  end_time = 0.5

  [./Quadrature]
    order = THIRD
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_as_2d_topo_q_func.i

#This tests the J-Integral evaluation capability.
#This is a 3d extrusion of a 2d plane strain model with one element
#through the thickness, and calculates the J-Integrals using options
#to treat it as 2d.
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack_3d_as_2d.e
  partitioner = centroid
  centroid_partitioner_direction = z
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  q_function_type = Topology
  ring_first = 1
  ring_last = 3
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 500
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]

   type = Transient
  # Two sets of linesearch options are for petsc 3.1 and 3.3 respectively
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 20
   nl_abs_tol = 1e-5
   l_tol = 1e-2

   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1
[]

[Outputs]
  file_base = j_integral_3d_as_2d_topo_q_func_out
  exodus = true
  csv = true
[]

modules/xfem/test/tests/corner_nodes_cut/corner_node_cut_twice.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '-0.0 0.3 1.0 0.7'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 4
  ny = 10
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
  [../]
[]

[BCs]
  [./top_x]
    type = DirichletBC
    boundary = 2
    variable = disp_x
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    boundary = 2
    variable = disp_y
    value = 0.1
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 0
    variable = disp_y
    value = -0.1
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = 0
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-16
  nl_abs_tol = 1e-9

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/cwp05.i

# Capped weak-plane plasticity
# checking jacobian for shear failure
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 1
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 1.0
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.1
    rate = 1
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 100
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningConstant
    value = 100
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 1  0 0 10  1 10 0'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 0
    smoothing_tol = 2
    yield_function_tol = 1E-10
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    #petsc_options = '-snes_test_display'
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/contact_verification/patch_tests/plane_1/plane1_mu_0_2_pen.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane1_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = plane1_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = plane1_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x7 disp_y7 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+9
  [../]
[]

modules/combined/test/tests/mortar_tm/2d/frictionless_first/finite_rr.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'finite_rr'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
    extra_vector_tags = 'ref'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
  nl_abs_tol = 1e-7
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/combined/test/tests/solid_mechanics/Time_integration/Newmark_time_integration/Newmark_test.i

# Test for  Newmark time integration
#
# The test is for an 1-D bar element of unit length fixed on one end
# with a ramped pressure boundary condition applied to the other end.
# beta and gamma are Newmark time integration parameters The equation
# of motion in terms of matrices is:
#
# M*accel + K*disp = P*Area
#
# Here M is the mass matrix, K is the stiffness matrix, P is the applied pressure
#
# This equation is equivalent to:
#
# density*accel + Div Stress = P
#
# The first term on the left is evaluated using the Inertial force
# kernel The last term on the left is evaluated using StressDivergence
# Kernel The residual due to Pressure is evaluated using Pressure
# boundary condition
[GlobalParams]
  volumetric_locking_correction = false
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = 0.0
  xmax = 0.1
  ymin = 0.0
  ymax = 1.0
  zmin = 0.0
  zmax = 0.1
[]

[AuxVariables]
  [./vel_x]
  [../]
  [./accel_x]
  [../]
  [./vel_y]
  [../]
  [./accel_y]
  [../]
  [./vel_z]
  [../]
  [./accel_z]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_yy strain_yy'
  []
[]

[Kernels]

  [./inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    beta = 0.25
    gamma = 0.5
  [../]
[]

[AuxKernels]
  [./accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_z]
    type = NewmarkAccelAux
    variable = accel_z
    displacement = disp_z
    velocity = vel_z
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_z]
    type = NewmarkVelAux
    variable = vel_z
    acceleration = accel_z
    gamma = 0.5
    execute_on = timestep_end
  [../]
[]


[BCs]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value=0.0
  [../]
  [./top_x]
   type = DirichletBC
    variable = disp_x
    boundary = top
    value=0.0
  [../]
  [./top_z]
    type = DirichletBC
    variable = disp_z
    boundary = top
    value=0.0
  [../]
  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = bottom
    value=0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value=0.0
  [../]
  [./Pressure]
    [./Side1]
    boundary = bottom
    function = pressure
    factor = 1
    [../]
  [../]
[]

[Materials]
  [./elastic]
    type = ComputeIsotropicElasticityTensor
    block = '0'
    youngs_modulus = 210e+09
    poissons_ratio = 0
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
    block = '0'
  [../]
  [./density]
    type = GenericConstantMaterial
    block = 0
    prop_names = 'density'
    prop_values = '7750'
  [../]
[]

[Executioner]

  type = Transient
  start_time = 0
  end_time = 2
  dtmax = 0.1
  dtmin = 0.1
  [./TimeStepper]
    type = ConstantDT
    dt = 0.1
  [../]

[]


[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0.0 0.1 0.2 1.0 2.0 5.0'
    y = '0.0 0.1 0.2 1.0 1.0 1.0'
    scale_factor = 1e9
  [../]
  [./vel_ic]
    type = PiecewiseLinear
    x = '0.0 0.5 1.0'
    y = '0.1 0.1 0.1'
    scale_factor = 1
  [../]
[]

[Postprocessors]
   [./_dt]
     type = TimestepSize
   [../]
   [./disp]
     type = NodalMaxValue
     variable = disp_y
     boundary = bottom
   [../]
   [./vel]
     type = NodalMaxValue
     variable = vel_y
     boundary = bottom
   [../]
   [./accel]
     type = NodalMaxValue
     variable = accel_y
     boundary = bottom
   [../]
   [./stress_yy]
      type = ElementAverageValue
      variable = stress_yy
   [../]
   [./strain_yy]
      type = ElementAverageValue
      variable = strain_yy
   [../]

[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/sliding_block/sliding/constraint/frictionless_kinematic.i

#  This is a benchmark test that checks constraint based frictionless
#  contact using the kinematic method.  In this test a constant
#  displacement is applied in the horizontal direction to simulate
#  a small block come sliding down a larger block.
#
#  The gold file is run on one processor
#  and the benchmark case is run on a minimum of 4 processors to ensure no
#  parallel variability in the contact pressure and penetration results.
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]

  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./left_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -sub_pc_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm     lu    20    101'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 15
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-6
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+6
    system = constraint
    normal_smoothing_distance = 0.1
  [../]
[]

modules/tensor_mechanics/test/tests/plane_stress/weak_plane_stress_elastic_jacobian.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  out_of_plane_strain = strain_zz
[]

[Mesh]
  file = square.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./strain_zz]
  [../]
[]

[Modules/TensorMechanics/Master]
  [plane_stress]
    planar_formulation = WEAK_PLANE_STRESS
    strain = SMALL
  []
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.0
    youngs_modulus = 1
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON

  petsc_options_iname = '-ksp_type -pc_type -snes_type'
  petsc_options_value = 'bcgs bjacobi test'

  end_time = 1.0
[]

modules/tensor_mechanics/test/tests/2D_different_planes/planestrain_xz.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = square_xz_plane.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./plane_strain]
    block = 1
    strain = SMALL
    out_of_plane_direction = y
    planar_formulation = PLANE_STRAIN
    eigenstrain_names = 'eigenstrain'
    generate_output = 'stress_xx stress_xz stress_yy stress_zz strain_xx strain_xz strain_yy strain_zz'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 3
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 3
    variable = disp_z
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_stress]
    type = ComputeLinearElasticStress
    block = 1
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
[]

[Postprocessors]
  [./react_y]
    type = MaterialTensorIntegral
    use_displaced_mesh = false
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-10

# controls for nonlinear iterations
  nl_max_its = 10
  nl_rel_tol = 1e-12

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  file_base = planestrain_xz_small_out
  exodus = true
[]

modules/combined/test/tests/elastic_patch/elastic_patch_rspherical.i

#
# Patch test for 1D spherical elements
#
# The 1D mesh is pinned at x=0.  The displacement at the outer node is set to
#   3e-3*X where X is the x-coordinate of that node.  That gives a strain of
#   3e-3 for the x, y, and z directions.
#
# Young's modulus is 1e6, and Poisson's ratio is 0.25.  This gives:
#
# Stress xx, yy, zz = E/(1+nu)/(1-2nu)*strain*((1-nu) + nu + nu) = 6000
#

[GlobalParams]
  displacements = 'disp_x'
  temperature = temp
[]

[Problem]
  coord_type = RSPHERICAL
[]

[Mesh]
  file = elastic_patch_rspherical.e
[]

[Variables]
  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = SMALL
  incremental = true
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_zz'
[]

[Kernels]
  [./heat]
    type = TimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '1 2'
    function = '3e-3*x'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]

  [./density]
    type = Density
    density = 0.283
    outputs = all
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_action/two_coord.i

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 16
    ny = 8
    xmin = -1
    xmax = 1
  []
  [block1]
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '-1 0 0'
    top_right = '0 1 0'
    input = generated_mesh
  []
  [block2]
    type = SubdomainBoundingBoxGenerator
    block_id = 2
    bottom_left = '0 0 0'
    top_right = '1 1 0'
    input = block1
  []
[]

[Problem]
  coord_type = 'XYZ RZ'
  block      = '1   2'
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Modules/TensorMechanics/Master]
  active = 'block1 block2'
  [./error]
    strain = SMALL
    add_variables = true
  [../]
  [./block1]
    strain = SMALL
    add_variables = true
    block = 1
    use_automatic_differentiation = true
  [../]
  [./block2]
    strain = SMALL
    add_variables = true
    block = 2
    use_automatic_differentiation = true
  [../]
[]

[AuxVariables]
  [./vmstress]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./vmstress]
    type = RankTwoScalarAux
    rank_two_tensor = total_strain
    variable = vmstress
    scalar_type = VonMisesStress
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./_elastic_stress]
    type = ADComputeLinearElasticStress
    block = '1 2'
  [../]
[]

[BCs]
  [./topx]
    type = DirichletBC
    boundary = 'top'
    variable = disp_x
    value = 0.0
  [../]
  [./topy]
    type = DirichletBC
    boundary = 'top'
    variable = disp_y
    value = 0.0
  [../]
  [./bottomx]
    type = DirichletBC
    boundary = 'bottom'
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 'bottom'
    variable = disp_y
    value = 0.05
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Preconditioning]
  [./full]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/initial_stress/except01.i

# Exception test: the incorrect number of initial stress functions are supplied

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 10
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -10
  zmax = 0
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '1 0 1'
    eigenstrain_name = ini_stress
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]


[Executioner]
  num_steps = 1
  solve_type = NEWTON
  type = Transient
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update33.i

# MC update version, with only MohrCoulomb, cohesion=40, friction angle = 35deg, psi = 5deg, smoothing_tol = 0.5
# Compressive strength = 1MPa
# Lame lambda = 1E3.  Lame mu = 1.3E3

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 4E1
  [../]
  [./phi]
    type = TensorMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./psi]
    type = TensorMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 0.5
    shear_modulus = 1.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-10 -12 14  -12 -5 -20  14 -20 -8'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = phi
    dilation_angle = psi
    smoothing_tol = 0.5
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/peridynamics/test/tests/simple_tests/2D_regularD_variableH_OSPD.i

# Test for ordinary state-based peridynamic formulation
# for regular grid from generated mesh with varying bond constants
# partial Jacobian
# Jacobian from bond-based formulation is used for preconditioning

# Square plate with Dirichlet boundary conditions applied
# at the left, top and bottom edges

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1002
    value = 0.0
  [../]
  [./bottom_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1000
    function = '-0.001*t'
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = ORDINARY_STATE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.0
  [../]

  [./force_density]
    type = ComputeSmallStrainVariableHorizonMaterialOSPD
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none
  start_time = 0
  end_time = 1
[]

[Outputs]
  file_base = 2D_regularD_variableH_OSPD
  exodus = true
[]

modules/combined/test/tests/ad_cavity_pressure/multiple_postprocessors.i

#
# Cavity Pressure Test (Volume input as a vector of postprocessors)
#
# This test is designed to compute an internal pressure based on
#   p = n * R * T / V
# where
#   p is the pressure
#   n is the amount of material in the volume (moles)
#   R is the universal gas constant
#   T is the temperature
#   V is the volume
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total
#   initial volume is 7.
# The test adjusts n, T, and V in the following way:
#   n => n0 + alpha * t
#   T => T0 + beta * t
#   V => V0 + gamma * t
# with
#   alpha = n0
#   beta = T0 / 2
#   gamma = - (0.003322259...) * V0
#   T0 = 240.54443866068704
#   V0 = 7
#   n0 = f(p0)
#   p0 = 100
#   R = 8.314472 J * K^(-1) * mol^(-1)
#
# So, n0 = p0 * V0 / R / T0 = 100 * 7 / 8.314472 / 240.544439
#        = 0.35
#
# In this test the internal volume is calculated as the sum of two Postprocessors
# internalVolumeInterior and internalVolumeExterior.  This sum equals the value
# reported by the internalVolume postprocessor.
#
# The parameters combined at t = 1 gives p = 301.
#

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = 3d.e
[]

[Functions]
  [./displ_positive]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.0029069767441859684'
  [../]
  [./displ_negative]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 -0.0029069767441859684'
  [../]
  [./temp1]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1.5'
    scale_factor = 240.54443866068704
  [../]
  [./material_input_function]
    type = PiecewiseLinear
    x = '0    1'
    y = '0 0.35'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./temp]
    initial_condition = 240.54443866068704
  [../]
  [./material_input]
  [../]
[]

[AuxVariables]
  [./pressure_residual_x]
  [../]
  [./pressure_residual_y]
  [../]
  [./pressure_residual_z]
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zx]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    use_automatic_differentiation = true
  [../]
  [./heat]
    type = ADDiffusion
    variable = temp
    use_displaced_mesh = true
  [../]
  [./material_input_dummy]
    type = ADDiffusion
    variable = material_input
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 2
    variable = stress_yz
  [../]
  [./stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 0
    variable = stress_zx
  [../]
[]

[BCs]
  [./no_x_exterior]
    type = DirichletBC
    variable = disp_x
    boundary = '7 8'
    value = 0.0
  [../]
  [./no_y_exterior]
    type = DirichletBC
    variable = disp_y
    boundary = '9 10'
    value = 0.0
  [../]
  [./no_z_exterior]
    type = DirichletBC
    variable = disp_z
    boundary = '11 12'
    value = 0.0
  [../]
  [./prescribed_left]
    type = ADFunctionDirichletBC
    variable = disp_x
    boundary = 13
    function = displ_positive
  [../]
  [./prescribed_right]
    type = ADFunctionDirichletBC
    variable = disp_x
    boundary = 14
    function = displ_negative
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = '15 16'
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = '17 18'
    value = 0.0
  [../]
  [./no_x_interior]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./no_y_interior]
    type = DirichletBC
    variable = disp_y
    boundary = '3 4'
    value = 0.0
  [../]
  [./no_z_interior]
    type = DirichletBC
    variable = disp_z
    boundary = '5 6'
    value = 0.0
  [../]
  [./temperatureInterior]
    type = ADFunctionDirichletBC
    boundary = 100
    function = temp1
    variable = temp
  [../]
  [./MaterialInput]
    type = ADFunctionDirichletBC
    boundary = '100 13 14 15 16'
    function = material_input_function
    variable = material_input
  [../]
  [./CavityPressure]
    [./1]
      boundary = 100
      initial_pressure = 100
      material_input = materialInput
      R = 8.314472
      temperature = aveTempInterior
      volume = 'internalVolumeInterior internalVolumeExterior'
      startup_time = 0.5
      output = ppress
      save_in = 'pressure_residual_x pressure_residual_y pressure_residual_z'
      use_automatic_differentiation = true
    [../]
  [../]
[]

[Materials]
  [./elast_tensor1]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e1
    poissons_ratio = 0
    block = 1
  [../]
  [./strain1]
    type = ADComputeFiniteStrain
    block = 1
  [../]
  [./stress1]
    type = ADComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./elast_tensor2]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0
    block = 2
  [../]
  [./strain2]
    type = ADComputeFiniteStrain
    block = 2
  [../]
  [./stress2]
    type = ADComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'NEWTON'

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_rel_tol = 1e-12
  l_tol = 1e-12

  l_max_its = 20

  dt = 0.5
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 100
    execute_on = 'initial linear'
  [../]
  [./aveTempInterior]
    type = SideAverageValue
    boundary = 100
    variable = temp
    execute_on = 'initial linear'
  [../]
  [./internalVolumeInterior]
    type = InternalVolume
    boundary = '1 2 3 4 5 6'
    execute_on = 'initial linear'
  [../]
  [./internalVolumeExterior]
    type = InternalVolume
    boundary = '13 14 15 16 17 18'
    execute_on = 'initial linear'
  [../]
  [./materialInput]
    type = SideAverageValue
    boundary = '7 8 9 10 11 12'
    variable = material_input
    execute_on = linear
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking_plane_stress.i

################################################################################
#
# 1x1x1 cube, single element
# simulate plane stress
# pull in +y direction on right surface to produce shear strain
#
#
#
#          ____________
#         /|          /|
#        / |  5      / |                       -X  Left   1
#       /__________ /  |                       +X  Right  4
#      |   |    3  |   |                       +Y  Top    5
#      | 1 |       | 4 |                       -Y  Bottom 2
#      |   |_6_____|___|           y           +Z  Front  6
#      |  /        |  /            ^           -Z  Back   3
#      | /    2    | /             |
#      |/__________|/              |
#                                  ----> x
#                                 /
#                                /
#                               z
#
#
#
#################################################################################

[Mesh]
  file = cube.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./displ]
    type = PiecewiseLinear
    x = '0 0.1 0.2 0.3 0.4'
    y = '0 0.0026 0 -0.0026 0'
  [../]
  [./pressure]
    type = PiecewiseLinear
    x = '0 0.1 0.2 0.3 0.4'
    y = '0 0   0    0   0'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[BCs]
  [./pull_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = displ
  [../]
  [./pin_x]
    type = DirichletBC
    variable = disp_x
    boundary = '1  4'
    value = 0.0
  [../]
  [./pin_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = '3'
    value = 0.0
  [../]
  [./front]
    type = Pressure
    variable = disp_z
    component = 2
    boundary = 6
    function = pressure
    factor   = 1.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 200.0e3
    poissons_ratio = .3
  [../]
  [./elastic_stress]
    type = ComputeSmearedCrackingStress
    cracking_stress = 120
    shear_retention_factor = 0.1
    softening_models = exponential_softening
  [../]
  [./exponential_softening]
    type = ExponentialSoftening
    residual_stress = 0.1
    beta = 0.1
  [../]
[]

[Executioner]
  type = Transient
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-ksp_gmres_restart -pc_type -sub_pc_type'
  petsc_options_value = '101                asm      lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-8
  l_tol = 1e-5
  start_time = 0.0
  end_time = 0.4
  dt = 0.04
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/initial_stress/gravity.i

# Apply an initial stress that should be
# exactly that caused by gravity, and then
# do a transient step to check that nothing
# happens

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 10
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -10
  zmax = 0
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./weight]
    type = BodyForce
    variable = disp_z
    value = -0.5 # this is density*gravity
  [../]
[]


[BCs]
  # back = zmin
  # front = zmax
  # bottom = ymin
  # top = ymax
  # left = xmin
  # right = xmax
  [./x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left right'
    value = 0
  [../]
  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom top'
    value = 0
  [../]
  [./z]
    type = DirichletBC
    variable = disp_z
    boundary = 'back'
    value = 0
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
[]


[Functions]
  [./weight]
    type = ParsedFunction
    value = '0.5*z' # initial stress that should result from the weight force
  [../]
  [./kxx]
    type = ParsedFunction
    value = '0.4*z' # some arbitrary xx and yy stress that should not affect the result
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeSmallStrain
    eigenstrain_names = ini_stress
  [../]
  [./strain_from_initial_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = 'kxx 0 0  0 kxx 0  0 0 weight'
    eigenstrain_name = ini_stress
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]


[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]


[Executioner]
  end_time = 1.0
  dt = 1.0
  solve_type = NEWTON
  type = Transient

  nl_abs_tol = 1E-8
  nl_rel_tol = 1E-12
  l_tol = 1E-3
  l_max_its = 200
  nl_max_its = 400

  petsc_options_iname = '-pc_type -pc_asm_overlap -sub_pc_type -ksp_type -ksp_gmres_restart'
  petsc_options_value = ' asm      2              lu            gmres     200'
[]



[Outputs]
  file_base = gravity
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_4/ring4_mu_0_2_pen.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring4_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 100
  nl_max_its = 1000
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = ring4_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = ring4_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x9 disp_y9 disp_x16 disp_y16 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/frictionless_kinematic_dirac.i

# This is a dirac (contact formulation) version of frictionless_kinematic.i
[Mesh]
  file = blocks_2d.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    #Initial gap is 0.01
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  [../]
  [./right]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]


[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.01
  end_time = 0.1
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-8
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    master = 2
    slave = 3
    model = frictionless
    penalty = 1e+6
    system = diracKernel
  [../]
[]

modules/tensor_mechanics/test/tests/multiple_two_parameter_plasticity/dp_then_wp.i

# Use ComputeMultipleInelasticStress with two inelastic models: CappedDruckerPrager and CappedWeakPlane.
# The relative_tolerance and absolute_tolerance parameters are set very large so that
# only one iteration is performed.  This is the algorithm that FLAC uses to model
# jointed rocks, only Capped-Mohr-Coulomb is used instead of CappedDruckerPrager
#
# initial_stress = diag(1E3, 1E3, 1E3)
# The CappedDruckerPrager has tensile strength 3E2 and large cohesion,
# so the stress initially returns to diag(1E2, 1E2, 1E2)
# The CappedWeakPlane has tensile strength zero and large cohesion,
# so the stress returns to diag(1E2 - v/(1-v)*1E2, 1E2 - v/(1-v)*1E2, 0)
# where v=0.2 is the Poisson's ratio

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    eigenstrain_names = ini_stress
    generate_output = 'stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz'
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = 0
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = 0
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = 0
  [../]
[]

[AuxVariables]
  [./yield_fcn_dp]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn_wp]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_dp_auxk]
    type = MaterialStdVectorAux
    index = 1    # this is the tensile yield function - it should be zero
    property = cdp_plastic_yield_function
    variable = yield_fcn_dp
  [../]
  [./yield_fcn_wp_auxk]
    type = MaterialStdVectorAux
    index = 1    # this is the tensile yield function - it should be zero
    property = cwp_plastic_yield_function
    variable = yield_fcn_wp
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f_dp]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn_dp
  [../]
  [./f_wp]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn_wp
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 300
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 20
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 0
  [../]
  [./dp]
    type = TensorMechanicsPlasticDruckerPrager
    mc_cohesion = mc_coh
    mc_friction_angle = mc_phi
    mc_dilation_angle = mc_psi
    internal_constraint_tolerance = 1 # irrelevant here
    yield_function_tolerance = 1      # irrelevant here
  [../]
  [./wp_coh]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
  [./wp_tanphi]
    type = TensorMechanicsHardeningConstant
    value = 0.5
  [../]
  [./wp_tanpsi]
    type = TensorMechanicsHardeningConstant
    value = 0.1111077
  [../]
  [./wp_t_strength]
    type = TensorMechanicsHardeningConstant
    value = 0
  [../]
  [./wp_c_strength]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.2
    youngs_modulus = 1E7
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '1E3 0 0  0 1E3 0  0 0 1E3'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    relative_tolerance = 1E4
    absolute_tolerance = 2
    inelastic_models = 'cdp cwp'
    perform_finite_strain_rotations = false
  [../]
  [./cdp]
    type = CappedDruckerPragerStressUpdate
    base_name = cdp
    DP_model = dp
    tensile_strength = ts
    compressive_strength = cs
    yield_function_tol = 1E-5
    tip_smoother = 1E3
    smoothing_tol = 1E3
  [../]
  [./cwp]
    type = CappedWeakPlaneStressUpdate
    base_name = cwp
    cohesion = wp_coh
    tan_friction_angle = wp_tanphi
    tan_dilation_angle = wp_tanpsi
    tensile_strength = wp_t_strength
    compressive_strength = wp_c_strength
    tip_smoother = 1E3
    smoothing_tol = 1E3
    yield_function_tol = 1E-5
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = dp_then_wp
  csv = true
[]

modules/tensor_mechanics/test/tests/torque_reaction/disp_about_axis_errors.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]


[AuxVariables]
  [./stress_xx]      # stress aux variables are defined for output; this is a way to get integration point variables to the output file
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]


[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 1.
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./vonmises]
    type =  RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = VonMisesStress
    execute_on = timestep_end
  [../]
[]

[BCs]

  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = bottom
    value = 0.0
  [../]

  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]

  [./top_x]
    type = DisplacementAboutAxis
    boundary = top
    function = rampConstant
    angle_units = degrees
    axis_origin = '0. 0. 0.'
    axis_direction = '0. 0. 1.'
    component = 0
    variable = disp_x
  [../]

  [./top_y]
    type = DisplacementAboutAxis
    boundary = top
    function = rampConstant
    angle_units = degrees
    axis_origin = '0. 0. 0.'
    variable = disp_y
  [../]

[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]


[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 30
  nl_max_its = 20
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-12
  l_tol = 1e-8

  start_time = 0.0
  dt = 0.1
  dtmin = 0.1 # die instead of cutting the timestep

  end_time = 0.5
[]


[Outputs]
  file_base = disp_about_axis_errors_out
  exodus = true
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_points.i

#This tests the J-Integral evaluation capability.
#This is a 3d extrusion of a 2d plane strain model with 2 elements
#through the thickness, and calculates the J-Integrals using options
#to treat it as 3d.
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack3d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  crack_front_points = '0 -10 .5
                        0 -10 0
                        0 -10 -.5'
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  radius_inner = '4.0 5.5'
  radius_outer = '5.5 7.0'
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 500
    value = 0.0
  [../]
  [./no_z2]
    type = DirichletBC
    variable = disp_z
    boundary = 510
    value = 0.0
  [../]

  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]

  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]

[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]


[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = j_integral_3d_points_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/isotropic_elasticity_tensor/bulk_modulus_shear_modulus_test.i

[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./stress_11]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
  [../]
[]

[AuxKernels]
  [./stress_11]
    type = RankTwoAux
    variable = stress_11
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
  [../]
[]

[BCs]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.001
  [../]
[]

[Materials]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 416666
    shear_modulus = 454545
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady
  l_max_its = 20
  nl_max_its = 10
  solve_type = NEWTON
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/2D_different_planes/gps_jacobian_testing_xy.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = square_xy_plane.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[Modules/TensorMechanics/Master]
  [./generalized_plane_strain]
    block = 1
    strain = SMALL
    scalar_out_of_plane_strain = scalar_strain_zz
    out_of_plane_direction = z
    planar_formulation = GENERALIZED_PLANE_STRAIN
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.0
    youngs_modulus = 1
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  petsc_options_iname = '-ksp_type -pc_type -snes_type'
  petsc_options_value = 'bcgs bjacobi test'

  end_time = 1.0
[]

modules/combined/test/tests/elastic_patch/ad_elastic_patch_rspherical.i

#
# Patch test for 1D spherical elements
#
# The 1D mesh is pinned at x=0.  The displacement at the outer node is set to
#   3e-3*X where X is the x-coordinate of that node.  That gives a strain of
#   3e-3 for the x, y, and z directions.
#
# Young's modulus is 1e6, and Poisson's ratio is 0.25.  This gives:
#
# Stress xx, yy, zz = E/(1+nu)/(1-2nu)*strain*((1-nu) + nu + nu) = 6000
#

[GlobalParams]
  displacements = 'disp_x'
  temperature = temp
[]

[Problem]
  coord_type = RSPHERICAL
[]

[Mesh]
  file = elastic_patch_rspherical.e
[]

[Variables]
  [./disp_x]
  [../]

  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = SMALL
  incremental = true
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_zz'
[]

[Kernels]
  [./heat]
    type = TimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '1 2'
    function = '3e-3*x'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]
[]

[Materials]
  [./density]
    type = ADDensity
    density = 0.283
    outputs = all
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/radial_disp_aux/cylinder_2d_axisymmetric.i

# The purpose of this set of tests is to check the values computed
# by the RadialDisplacementAux AuxKernel. They should match the
# radial component of the displacment for a cylindrical or spherical
# model.
# This particular model is of a cylinder subjected to uniform thermal
# expansion represented using a 2D axisymmetric model.

[Mesh]
  type = GeneratedMesh
  dim = 2
  elem_type = QUAD8
  nx = 4
  ny = 4
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[AuxVariables]
  [./temp]
  [../]
  [./rad_disp]
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t+300.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    eigenstrain_names = eigenstrain
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
    use_displaced_mesh = false
  [../]
  [./raddispaux]
    type = RadialDisplacementCylinderAux
    variable = rad_disp
  [../]
[]

[BCs]
  [./x]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom top'
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 300
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '51'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  start_time = 0.0
  end_time = 1
  dt = 1
  dtmin = 1
[]

[Outputs]
 csv = true
 exodus = true
[]

#[Postprocessors]
#  [./strain_xx]
#    type = SideAverageValue
#    variable =
#    block = 0
#  [../]
#[]

modules/peridynamics/test/tests/restart/2D_mesh_restartable_NOSPD.i


[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1003
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1001
    value = 0.001
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e8
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputePlaneSmallStrainNOSPD
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  start_time = 0
  end_time = 1
  # num_steps = 2

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

[Outputs]
  file_base = 2D_mesh_restartable_NOSPD_out
  exodus = true
  checkpoint = true
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_mouth_dir.i

#This tests the J-Integral evaluation capability.
#This is a 3d extrusion of a 2d plane strain model with 2 elements
#through the thickness, and calculates the J-Integrals using options
#to treat it as 3d.
#Crack direction is defined using the crack mouth coordinates.
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack3d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackMouth
  crack_mouth_boundary = 900
  radius_inner = '4.0 5.5'
  radius_outer = '5.5 7.0'
  output_variable = 'disp_x'
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 500
    value = 0.0
  [../]
  [./no_z2]
    type = DirichletBC
    variable = disp_z
    boundary = 510
    value = 0.0
  [../]

  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]

  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]

[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]


[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Postprocessors]
  [./disp_x_centercrack]
    type = CrackFrontData
    crack_front_definition = crackFrontDefinition
    variable = disp_x
    crack_front_point_index = 1
  [../]
[]

[Outputs]
  file_base = j_integral_3d_mouth_dir_out
  exodus = true
  csv = true
[]

modules/combined/test/tests/gravity/gravity_rz_quad8.i

# Gravity Test
#
# This test is designed to exercise the gravity body force rz kernel.
#
# The mesh for this problem is a rectangle 10 units by 1 unit.
#
# The boundary conditions for this problem are as follows.  The
#   displacement is zero at the top.  The acceleration of gravity is 20.
#
# The material has a Young's modulus of 1e6 and a density of 2.
#
# The analytic solution for the displacement along the bar is:
#
# u(y) = -b*y^2/(2*E)+b*L*y/E
#
# The displacement at y=L is b*L^2/(2*E) = 2*20*10*10/(2*1e6) = 0.002.
#
# The analytic solution for the stress along the bar assuming linear
#   elasticity is:
#
# S(y) = b*(L-y)
#
# The stress at x=0 is b*L = 2*20*10 = 400.
#
# Note:  The simulation does not measure stress at y=0.  The stress
#   is reported at element centers.  The element closest to y=0 sits
#   at y = 1/4 and has a stress of 390.  This matches the linear
#   stress distribution that is expected.  The same situation applies
#   at y = L where the stress is zero analytically.  The nearest
#   element is at y=9.75 where the stress is 10.
#
[GlobalParams]
  displacements = 'disp_x disp_y'
  order = SECOND
  family = LAGRANGE
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = gravity_rz_quad8_test.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_xy'
[]

[Kernels]
  [./gravity]
    type = Gravity
    variable = disp_y
    value = 20
  [../]
[]

[BCs]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    shear_modulus = 0.5e6
    lambda = 0.0
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./density]
    type = Density
    density = 2
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  start_time = 0.0
  end_time = 1.0

  [./Quadrature]
    order = THIRD
  [../]
[]

[Outputs]
  file_base = gravity_rz_quad8_out
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/combined/test/tests/mortar_tm/2drz/frictionless_second/finite_noaction.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'finite_noaction'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]

  [./slave]
    input = block_sidesets
    type = LowerDBlockFromSidesetGenerator
    sidesets = 'block_left'
    new_block_id = '30'
    new_block_name = 'frictionless_slave_subdomain'
  [../]
  [./master]
    input = slave
    type = LowerDBlockFromSidesetGenerator
    sidesets = 'plank_right'
    new_block_id = '20'
    new_block_name = 'frictionless_master_subdomain'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./frictionless_normal_lm]
    order = ${order}
    block = 'frictionless_slave_subdomain'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
  [../]
  [./plank]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
  [../]
[]

[Constraints]
  [./lm]
    type = NormalNodalLMMechanicalContact
    slave = block_left
    master = plank_right
    variable = frictionless_normal_lm
    master_variable = disp_x
    disp_y = disp_y
    ncp_function_type = min
    use_displaced_mesh = true
  [../]
  [./normal_x]
    type = NormalMortarMechanicalContact
    master_boundary = plank_right
    slave_boundary = block_left
    master_subdomain = frictionless_master_subdomain
    slave_subdomain = frictionless_slave_subdomain
    variable = frictionless_normal_lm
    slave_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
  [../]
  [./normal_y]
    type = NormalMortarMechanicalContact
    master_boundary = plank_right
    slave_boundary = block_left
    master_subdomain = frictionless_master_subdomain
    slave_subdomain = frictionless_slave_subdomain
    variable = frictionless_normal_lm
    slave_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/plane_stress/3D_finite_tension_pull.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
[]

[Problem]
  extra_tag_vectors = 'ref'
[]

[Mesh]
  [gmg]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 1
    ny = 1
    nz = 1
  []
[]

[AuxVariables]
  [react_x]
  []
[]

[Postprocessors]
  [react_x]
    type = NodalSum
    variable = 'react_x'
    boundary = 'right'
  []
  [stress_xx]
    type = ElementalVariableValue
    variable = 'stress_xx'
    elementid = 0
  []
  [strain_zz]
    type = ElementalVariableValue
    variable = 'strain_zz'
    elementid = 0
  []
[]

[Modules/TensorMechanics/Master]
  [plane_stress]
    strain = FINITE
    extra_vector_tags = 'ref'
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy strain_zz'
    add_variables = true
  []
[]

[AuxKernels]
  [react_x]
    type = TagVectorAux
    vector_tag = 'ref'
    v = 'disp_x'
    variable = 'react_x'
  []
[]

[BCs]
  [leftx]
    type = DirichletBC
    boundary = left
    variable = disp_x
    value = 0.0
  []
  [bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  []
  [backz]
    type = DirichletBC
    boundary = back
    variable = disp_z
    value = 0.0
  []
  [rightx]
    type = FunctionDirichletBC
    boundary = right
    variable = disp_x
    function = 't'
  []
[]

[Materials]
  [elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
  []
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10

  # time control
  start_time = 0.0
  dt = 0.01
  dtmin = 0.01
  end_time = 0.2
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/sliding_block/in_and_out/constraint/frictionless_lm.i

[Mesh]
  patch_size = 80
  [file]
    type = FileMeshGenerator
    file = sliding_elastic_blocks_2d.e
  []
  [slave]
    input = file
    type = LowerDBlockFromSidesetGenerator
    sidesets = '3'
    new_block_id = '30'
  []
  [master]
    input = slave
    type = LowerDBlockFromSidesetGenerator
    sidesets = '2'
    new_block_id = '20'
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    block = '1 2'
  [../]
[]

[Variables]
  [normal_lm]
    block = '30'
  []
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_ksp_ew'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 15
  dt = 0.1
  dtmin = 0.01
  l_max_its = 30
  nl_max_its = 20
  line_search = 'none'
  timestep_tolerance = 1e-6
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  sync_times = '1 2 3 4 5 6 7 8 9 10 11 12 13 14 15'
  [out]
    type = Exodus
    sync_only = true
  []
  [dof]
    execute_on = 'initial'
    type = DOFMap
  []
  [csv]
    type = CSV
    execute_on = 'nonlinear timestep_end'
  []
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
  [./horizontal_movement]
    type = ParsedFunction
    value = -0.04*sin(4*t)+0.02
  [../]
[]

[Constraints]
  [./lm]
    type = NormalNodalLMMechanicalContact
    slave = 3
    master = 2
    variable = normal_lm
    master_variable = disp_x
    disp_y = disp_y
    ncp_function_type = min
    use_displaced_mesh = true
  [../]
  [normal_x]
    type = NormalMortarMechanicalContact
    master_boundary = '2'
    slave_boundary = '3'
    master_subdomain = '20'
    slave_subdomain = '30'
    variable = normal_lm
    slave_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
  []
  [normal_y]
    type = NormalMortarMechanicalContact
    master_boundary = '2'
    slave_boundary = '3'
    master_subdomain = '20'
    slave_subdomain = '30'
    variable = normal_lm
    slave_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
  []
[]

[Postprocessors]
  [./num_nl]
    type = NumNonlinearIterations
  [../]
  [lin]
    type = NumLinearIterations
  []
  [contact]
    type = ContactDOFSetSize
    variable = normal_lm
    subdomain = '30'
    execute_on = 'nonlinear timestep_end'
  []
[]

modules/tensor_mechanics/test/tests/generalized_plane_strain/out_of_plane_pressure.i

# Tests for application of out-of-plane pressure in generalized plane strain.

[Mesh]
  file = square.e
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./saved_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./GeneralizedPlaneStrain]
      [./gps]
        use_displaced_mesh = true
        displacements = 'disp_x disp_y'
        scalar_out_of_plane_strain = scalar_strain_zz
        out_of_plane_pressure = traction_function
        factor = 1e5
      [../]
    [../]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = false
    displacements = 'disp_x disp_y'
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]

  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_xy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xy
    index_i = 0
    index_j = 1
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Functions]
  [./traction_function]
    type = PiecewiseLinear
    x = '0  2'
    y = '0  1'
  [../]
[]

[BCs]
  [./leftx]
    type = DirichletBC
    boundary = 4
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./strain]
    type = ComputePlaneSmallStrain
    displacements = 'disp_x disp_y'
    scalar_out_of_plane_strain = scalar_strain_zz
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-4

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-11

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
  num_steps = 5000
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_2D_geometries/3D-RZ_finiteStrain_test.i

# Considers the mechanics solution for a thick spherical shell that is uniformly
# pressurized on the inner and outer surfaces, using 3D geometry.
#
# From Roark (Formulas for Stress and Strain, McGraw-Hill, 1975), the radially-dependent
# circumferential stress in a uniformly pressurized thick spherical shell is given by:
#
# S(r) = [ Pi[ri^3(2r^3+ro^3)] - Po[ro^3(2r^3+ri^3)] ] / [2r^3(ro^3-ri^3)]
#
#   where:
#          Pi = inner pressure
#          Po = outer pressure
#          ri = inner radius
#          ro = outer radius
#
# The tests assume an inner and outer radii of 5 and 10, with internal and external
# pressures of 100000 and 200000 at t = 1.0, respectively. The resulting compressive
# tangential stress is largest at the inner wall and, from the above equation, has a
# value of -271429.
#
# RESULTS are below. Since stresses are average element values, values for the
# edge element and one-element-in are used to extrapolate the stress to the
# inner surface. The vesrion of the tests that are checked use the coarsest meshes.
#
#  Mesh    Radial elem   S(edge elem)  S(one elem in)  S(extrap to surf)
# 1D-SPH
# 2D-RZ        12 (x10)    -265004      -254665        -270174
#  3D          12 (6x6)    -261880      -252811        -266415
#
# 1D-SPH
# 2D-RZ        48 (x10)    -269853      -266710        -271425
#  3D          48 (10x10)  -268522      -265653        -269957
#
# The numerical solution converges to the analytical solution as the mesh is
# refined.

[Mesh]
  file = 3D_mesh.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    block = 1
    use_displaced_mesh = true
    use_automatic_differentiation = true
  [../]
[]

[AuxVariables]
  [./stress_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_theta]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_theta
    execute_on = timestep_end
  [../]
  [./strain_theta]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 2
    index_j = 2
    variable = strain_theta
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
    block = 1
  [../]

  [./elastic_strain]
    type = ADComputeFiniteStrainElasticStress
    block = 1
  [../]
[]

[BCs]
# pin particle along symmetry planes
  [./no_disp_x]
    type = ADDirichletBC
    variable = disp_x
    boundary = xzero
    value = 0.0
  [../]

  [./no_disp_y]
    type = ADDirichletBC
    variable = disp_y
    boundary = yzero
    value = 0.0
  [../]

  [./no_disp_z]
    type = ADDirichletBC
    variable = disp_z
    boundary = zzero
    value = 0.0
  [../]

# exterior and internal pressures
  [./exterior_pressure_x]
    type = ADPressure
    variable = disp_x
    boundary = outer
    component = 0
    function = '200000*t'
  [../]

 [./exterior_pressure_y]
    type = ADPressure
    variable = disp_y
    boundary = outer
    component = 1
    function = '200000*t'
  [../]

[./exterior_pressure_z]
    type = ADPressure
    variable = disp_z
    boundary = outer
    component = 2
    function = '200000*t'
  [../]

  [./interior_pressure_x]
    type = ADPressure
    variable = disp_x
    boundary = inner
    component = 0
    function = '100000*t'
  [../]

  [./interior_pressure_y]
    type = ADPressure
    variable = disp_y
    boundary = inner
    component = 1
    function = '100000*t'
  [../]

  [./interior_pressure_z]
    type = ADPressure
    variable = disp_z
    boundary = inner
    component = 2
    function = '100000*t'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50

  start_time = 0.0
  end_time = 0.2
  dt = 0.1

[]

[Postprocessors]
  [./strainTheta]
    type = ElementAverageValue
    variable = strain_theta
  [../]
  [./stressTheta]
    type = ElementAverageValue
    variable = stress_theta
  [../]
  [./stressTheta_pt]
    type = PointValue
    point = '5.0 0.0 0.0'
    #bottom inside edge for comparison to theory; use csv = true
    variable = stress_theta
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_2/ring2_mu_0_2_pen.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring2_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = ring2_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = ring2_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x5 disp_y5 disp_x9 disp_y9 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/combined/test/tests/mortar_tm/2drz/frictionless_second/finite_rr.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'finite_rr'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
    extra_vector_tags = 'ref'
  [../]
  [./plank]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
    extra_vector_tags = 'ref'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
  nl_abs_tol = 1e-12
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/combined/test/tests/solid_mechanics/hoop_stress/hoop_stress_default_yaxis.i

#
# Hoop stress
#
# This test checks that hoop stress is calculated correctly for the default orientation.
# It calculates the hoop stress for a hoop cenetered at (-25,0,0) with the default vector (0,1,0).
# The hoop has a radius = 20, t = 1.
#
# Hoop stress should be P*r/t -> 1e3*20/1 = 20e3
#
# The output hoop stress is close to this value (nonlinear geometry is on) for all
# elements.
#

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  order = FIRST
  family = LAGRANGE
[]

[Mesh]
  file = hoop_default_yaxis.e
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 1e3
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]

  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./hoop2]
    order = CONSTANT
    family = MONOMIAL
    block = 2
  [../]
  [./radial2]
    order = CONSTANT
    family = MONOMIAL
    block = 2
  [../]
  [./axial2]
    order = CONSTANT
    family = MONOMIAL
    block = 2
  [../]

[] # AuxVariables

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
    execute_on = timestep_end
  [../]
  [./stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zx
    index_i = 2
    index_j = 0
    execute_on = timestep_end
  [../]
  [./hoop2]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = HoopStress
    variable = hoop2
    block = 2
    execute_on = timestep_end
  [../]
  [./radial2]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = RadialStress
    variable = radial2
    block = 2
    execute_on = timestep_end
  [../]
  [./axial2]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = AxialStress
    variable = axial2
    block = 2
    execute_on = timestep_end
  [../]

[] # AuxKernels

[BCs]

  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = '11'
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = '200'
    value = 0
  [../]
  [./fix_z]
    type = DirichletBC
    variable = disp_z
    boundary = '13'
    value = 0
  [../]

  [./Pressure]
    [./internal_pressure]
      disp_x = disp_x
      disp_y = disp_y
      disp_z = disp_z
      boundary = 1
      function = pressure
    [../]
  [../]

[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 2
    youngs_modulus = 1e6
    poissons_ratio = 0.35
  [../]
  [./small_strain]
    type = ComputeIncrementalSmallStrain
    block = 2
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[Executioner]

  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'


  petsc_options = '-ksp_gmres_modifiedgramschmidt'
  petsc_options_iname = '-ksp_gmres_restart -pc_type  -pc_hypre_type'
  petsc_options_value = '201                 hypre     boomeramg     '


  line_search = 'none'

  l_tol = 1e-8
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-14

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 1
  end_time = 1.0
[] # Executioner

[Outputs]
  exodus = true
  file_base = hoop_stress_default_yaxis_out
[] # Outputs

modules/tensor_mechanics/test/tests/generalized_plane_strain/generalized_plane_strain_finite.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  block = 1
[]

[Mesh]
  file = square.e
[]

[Variables]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy strain_zz'
    planar_formulation = GENERALIZED_PLANE_STRAIN
    eigenstrain_names = eigenstrain
    scalar_out_of_plane_strain = scalar_strain_zz
    temperature = temp
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-4

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-5

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
  num_steps = 5000
[]

[Outputs]
  exodus = true
[]

modules/peridynamics/test/tests/simple_tests/2D_small_strain_NOSPD.i


[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 8
    ny = 8
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1003
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 1001
    function = '0.001*t'
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e8
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeSmallStrainNOSPD
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none
  start_time = 0
  end_time = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

[Outputs]
  file_base = 2D_small_strain_NOSPD
  exodus = true
[]

modules/combined/test/tests/contact/pressureAugLag.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = false
[]

[Mesh]
  file = pressure.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_yy'
  []
[]

[Contact]
  [./m20_s10]
    master = 20
    slave = 10
    penalty = 1e7
    formulation = augmented_lagrange
    al_penetration_tolerance = 1e-8
    tangential_tolerance = 1e-3
    system = Constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]

  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./z]
    type = DirichletBC
    variable = disp_z
    boundary = 5
    value = 0.0
  [../]

  [./Pressure]
    [./press]
      boundary = 7
      factor = 1e3
    [../]
  [../]

  [./down]
    type = DirichletBC
    variable = disp_y
    boundary = 8
    value = -2e-3
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.0
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Dampers]
  [./limitX]
    type = MaxIncrement
    max_increment = 1e-5
    variable = disp_x
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  #petsc_options_iname = '-pc_type -pc_hypre_type -snes_type -snes_ls -snes_linesearch_type -ksp_gmres_restart'
  #petsc_options_value = 'hypre    boomeramg      ls         basic    basic                    101'
  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'lu       101'

  line_search = 'none'

  nl_rel_tol = 1e-5
  nl_abs_tol = 1e-6

  l_tol = 1e-8

  l_max_its = 100
  nl_max_its = 20
  dt = 1.0
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/fieldsplit_contact/2blocks3d.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = 2blocks3d.e
  patch_size = 5
[]

[Problem]
  error_on_jacobian_nonzero_reallocation = true
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
  [../]
[]

[AuxVariables]
  [./penetration]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Functions]
  [./horizontal_movement]
    type = ParsedFunction
    value = t/10.0
  [../]
[]

[AuxKernels]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 2
    paired_boundary = 3
    order = FIRST
  [../]
[]

[BCs]
  [./push_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 1
    function = horizontal_movement
  [../]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = '1 4'
    value = 0.0
  [../]
  [./fix_z]
    type = DirichletBC
    variable = disp_z
    boundary = '1 4'
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor_left]
    type = ComputeIsotropicElasticityTensor
    block = 1
    youngs_modulus = 1.0e6
    poissons_ratio = 0.3
  [../]
  [./stress_left]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]

  [./elasticity_tensor_right]
    type = ComputeIsotropicElasticityTensor
    block = 2
    youngs_modulus = 1.0e6
    poissons_ratio = 0.3
  [../]
  [./stress_right]
    type = ComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[Contact]
  [./leftright]
    slave = 2
    master = 3
    model = frictionless
    penalty = 1e+6
    normalize_penalty = true
    formulation = kinematic
    system = constraint
    normal_smoothing_distance = 0.1
  [../]
[]

[Preconditioning]
  [./FSP]
    type = FSP
    # It is the starting point of splitting
    topsplit = 'contact_interior' # 'contact_interior' should match the following block name
    [./contact_interior]
      splitting          = 'contact interior'
      splitting_type     = multiplicative
    [../]
    [./interior]
      type = ContactSplit
      vars = 'disp_x disp_y disp_z'
      uncontact_master   = '3'
      uncontact_slave    = '2'
      uncontact_displaced = '1'
      blocks              = '1 2'
      include_all_contact_nodes = 1
      petsc_options_iname = '-ksp_type -ksp_max_it -ksp_rtol -ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter -pc_hypre_strong_threshold'
      petsc_options_value = ' preonly 10 1e-4 201                hypre    boomeramg      1                            0.25'
    [../]
    [./contact]
      type = ContactSplit
      vars = 'disp_x disp_y disp_z'
      contact_master   = '3'
      contact_slave    = '2'
      contact_displaced = '1'
      include_all_contact_nodes = 1
      petsc_options_iname = '-ksp_type -ksp_max_it -pc_type -pc_asm_overlap -sub_pc_type   -pc_factor_levels'
      petsc_options_value = '  preonly 10 asm  1 lu 0'
    [../]
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  dt = 0.1
  dtmin = 0.1
  end_time = 0.1

  l_tol = 1e-4
  l_max_its = 100

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-6
  nl_max_its = 100
[]

[Outputs]
  file_base = 2blocks3d_out
  [./exodus]
    type = Exodus
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

modules/tensor_mechanics/test/tests/domain_integral_thermal/j_integral_2d_inst_ctefunc.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack2d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = 10.0*(2*x/504)
  [../]
  [./cte_func_inst]
    type = PiecewiseLinear
    xy_data = '-10 -10
                10  10'
    scale_factor = 1e-6
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  radius_inner = '60.0 80.0 100.0 120.0'
  radius_outer = '80.0 100.0 120.0 140.0'
  temperature = temp
  incremental = true
  eigenstrain_names = thermal_expansion
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
    eigenstrain_names = thermal_expansion
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    block = 1
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 400
    value = 0.0
  [../]

  [./no_x1]
    type = DirichletBC
    variable = disp_x
    boundary = 900
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeInstantaneousThermalExpansionFunctionEigenstrain
    block = 1
    thermal_expansion_function = cte_func_inst
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart -sub_ksp_type -sub_pc_type -pc_asm_overlap'
  petsc_options_value = 'asm         31   preonly   lu      1'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 40

  nl_rel_step_tol= 1e-10
  nl_rel_tol = 1e-10

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  csv = true
  execute_on = 'timestep_end'
[]

[Preconditioning]
  [./smp]
    type = SMP
    pc_side = left
    ksp_norm = preconditioned
    full = true
  [../]
[]

modules/tensor_mechanics/test/tests/eigenstrain/reducedOrderRZQuadratic.i

#
# This test checks whether the ComputeReducedOrderEigenstrain is functioning properly.
#
# If instead of 'reduced_order_eigenstrain', 'thermal_eigenstrain' is given to
# eigenstrain_names in the Modules/TensorMechanics/Master/all block, the output will be
# quite different.
#
# Open the reducedOrderRZQuadratic_out_hydro_0001.csv file and plot the hydro variables as
# a function of x.
#

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 1
  xmax = 3
  xmin = 1
  ymax = 1
  ymin = 0
  second_order = true
[]

[Functions]
  [./tempLinear]
    type = ParsedFunction
    value = '715-5*x'
  [../]
  [./tempQuadratic]
    type = ParsedFunction
    vars = 'Tc Te'
    vals = '701 700'
    value = '(Te-Tc)/4.0*x*x+(Tc-Te)/2.0*x+Te+3.0*(Tc-Te)/4.0'
  [../]
  [./tempCubic]
    type = ParsedFunction
    value = '-1.25*x*x*x+11.25*x*x-33.75*x+733.75'
  [../]
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
    initial_condition = 295.0
  [../]
[]

[AuxVariables]
  [./hydro_constant]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./hydro_first]
    order = FIRST
    family = MONOMIAL
  [../]
  [./hydro_second]
    order = SECOND
    family = MONOMIAL
  [../]
  [./sxx_constant]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./sxx_first]
    order = FIRST
    family = MONOMIAL
  [../]
  [./sxx_second]
    order = SECOND
    family = MONOMIAL
  [../]
  [./szz_constant]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./szz_first]
    order = FIRST
    family = MONOMIAL
  [../]
  [./szz_second]
    order = SECOND
    family = MONOMIAL
  [../]
  [./thermal_constant]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./thermal_first]
    order = FIRST
    family = MONOMIAL
  [../]
  [./thermal_second]
    order = SECOND
    family = MONOMIAL
  [../]
  [./reduced_constant]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./reduced_first]
    order = FIRST
    family = MONOMIAL
  [../]
  [./reduced_second]
    order = SECOND
    family = MONOMIAL
  [../]
  [./temp2]
    order = SECOND
    family = LAGRANGE
    initial_condition = 700
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        add_variables = true
        strain = SMALL
        incremental = true
        temperature = temp2
        #eigenstrain_names = thermal_eigenstrain
        eigenstrain_names = reduced_order_eigenstrain
      [../]
    [../]
  [../]
[]

[Kernels]
  [./heat]
    type = Diffusion
    variable = temp
  [../]
[]

[AuxKernels]
  [./hydro_constant_aux]
    type = RankTwoScalarAux
    variable = hydro_constant
    rank_two_tensor = stress
    scalar_type = Hydrostatic
    execute_on = timestep_end
  [../]
  [./hydro_first_aux]
    type = RankTwoScalarAux
    variable = hydro_first
    rank_two_tensor = stress
    scalar_type = Hydrostatic
    execute_on = timestep_end
  [../]
  [./hydro_second_aux]
    type = RankTwoScalarAux
    variable = hydro_second
    rank_two_tensor = stress
    scalar_type = Hydrostatic
    execute_on = timestep_end
  [../]
  [./sxx_constant_aux]
    type = RankTwoAux
    variable = sxx_constant
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./sxx_first_aux]
    type = RankTwoAux
    variable = sxx_first
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./sxx_second_aux]
    type = RankTwoAux
    variable = sxx_second
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./szz_constant_aux]
    type = RankTwoAux
    variable = szz_constant
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./szz_first_aux]
    type = RankTwoAux
    variable = szz_first
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./szz_second_aux]
    type = RankTwoAux
    variable = szz_second
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./thermal_constant_aux]
    type = RankTwoAux
    variable = thermal_constant
    rank_two_tensor = thermal_eigenstrain
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./thermal_first_aux]
    type = RankTwoAux
    variable = thermal_first
    rank_two_tensor = thermal_eigenstrain
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./thermal_second_aux]
    type = RankTwoAux
    variable = thermal_second
    rank_two_tensor = thermal_eigenstrain
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./reduced_constant_aux]
    type = RankTwoAux
    variable = reduced_constant
    rank_two_tensor = reduced_order_eigenstrain
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./reduced_first_aux]
    type = RankTwoAux
    variable = reduced_first
    rank_two_tensor = reduced_order_eigenstrain
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./reduced_second_aux]
    type = RankTwoAux
    variable = reduced_second
    rank_two_tensor = reduced_order_eigenstrain
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./temp2]
    type = FunctionAux
    variable = temp2
    function = tempQuadratic
    execute_on = timestep_begin
  [../]
[]

[BCs]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom #'bottom top'
    value = 0.0
  [../]

  [./temp_right]
    type = DirichletBC
    variable = temp
    boundary = right
    value = 700
  [../]
  [./temp_left]
    type = DirichletBC
    variable = temp
    boundary = left
    value = 710
  [../]
[]


[Materials]
  [./fuel_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e8
    poissons_ratio = 0
  [../]
  [./fuel_thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-6
    temperature = temp2
    stress_free_temperature = 295.0
    eigenstrain_name = 'thermal_eigenstrain'
  [../]
  [./reduced_order_eigenstrain]
    type = ComputeReducedOrderEigenstrain
    input_eigenstrain_names = 'thermal_eigenstrain'
    eigenstrain_name = 'reduced_order_eigenstrain'
  [../]
[]


[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew '
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type'
  petsc_options_value = '70 hypre boomeramg'

  num_steps = 1
  nl_rel_tol = 1e-8
[]

[Postprocessors]
  [./_dt]
    type = TimestepSize
  [../]
[]

[VectorPostprocessors]
  [./hydro]
    type = LineValueSampler
    num_points = 50
    start_point = '1 0.07e-3 0'
    end_point = '3 0.07e-3 0'
    sort_by = x
    variable = 'temp2 disp_x disp_y hydro_constant hydro_first hydro_second sxx_constant sxx_first sxx_second szz_constant szz_first szz_second thermal_constant thermal_first thermal_second reduced_constant reduced_first reduced_second'
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/xfem/test/tests/pressure_bc/edge_3d_pressure.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = false
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 9
  nz = 10
  xmin = -0.1
  xmax = 0.1
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
  elem_type = HEX8
[]

[UserObjects]
  [./square_planar_cut_uo]
    type = RectangleCutUserObject
    cut_data = '-0.2  0.0 -0.5
                -0.2  0.0  0.0
                 0.2  0.0  0.0
                 0.2  0.0 -0.5'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz'
  [../]
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0 2.0 4.0 6.0 8.0'
    y = '0 1000 0 1000 0'
  [../]
[]

[DiracKernels]
  [./p_x]
    type = XFEMPressure
    variable = disp_x
    component = 0
    function = pressure
  [../]
  [./p_y]
    type = XFEMPressure
    variable = disp_y
    component = 1
    function = pressure
  [../]
  [./p_z]
    type = XFEMPressure
    variable = disp_z
    component = 2
    function = pressure
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    boundary = 'bottom top'
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 'bottom top'
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    boundary = 'bottom top'
    variable = disp_z
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-12

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 2.0
[]

[Outputs]
  file_base = edge_3d_pressure_out
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/check_error/shear_modulus.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = cube.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./2_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./2_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./2_z]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    shear_modulus = -10.0
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[]

[Outputs]
  file_base = out
  exodus = true
[]

modules/peridynamics/test/tests/jacobian_check/weak_planestress_thermomechanics_smallstrain_NOSPD.i


[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
  out_of_plane_strain = strain_zz
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./strain_zz]
  [../]

  [./temp]
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
    eigenstrain_names = thermal_strain
  [../]
[]

[Kernels]
  [./strain_zz]
    type = WeakPlaneStressNOSPD
    variable = strain_zz
    eigenstrain_names = thermal_strain
  [../]

  [./heat_conduction]
    type = HeatConductionBPD
    variable = temp
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputePlaneSmallStrainNOSPD
    eigenstrain_names = thermal_strain
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-5
    stress_free_temperature = 0.5
    eigenstrain_name = thermal_strain
  [../]

  [./stress]
    type = ComputeLinearElasticStress
  [../]

  [./thermal]
    type = ThermalConstantHorizonMaterialBPD
    thermal_conductivity = 1.0
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

modules/combined/test/tests/internal_volume/rz_displaced.i

#
# Volume Test
#
# This test is designed to compute the volume of a space when displacements
#   are imposed.
#
# The mesh is composed of one block (1) with two elements.  The mesh is
#   such that the initial volume is 1.  One element face is displaced to
#   produce a final volume of 2.
#
#     r1
#   +----+   -
#   |    |   |
#   +----+   h    V1 = pi * h * r1^2
#   |    |   |
#   +----+   -
#
#   becomes
#
#   +----+
#   |     \
#   +------+      v2 = pi * h/2 * ( r2^2 + 1/3 * ( r2^2 + r2*r1 + r1^2 ) )
#   |      |
#   +------+
#      r2
#
#   r1 = 1
#   r2 = 1.5380168369562588
#   h  = 1/pi
#
#  Note:  Because the InternalVolume PP computes cavity volumes as positive,
#         the volumes reported are negative.
#

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = meshes/rz_displaced.e
  # This test uses ElementalVariableValue postprocessors on specific
  # elements, so element numbering needs to stay unchanged
  allow_renumbering = false
[]

[Functions]
  [./disp_x]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 0.5380168369562588'
  [../]
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./volumetric_strain]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    volumetric_locking_correction = false
    decomposition_method = EigenSolution
    incremental = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./fred]
    type = RankTwoScalarAux
    rank_two_tensor = total_strain
    variable = volumetric_strain
    scalar_type = VolumetricStrain
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]

  [./x]
    type = FunctionDirichletBC
    boundary = 3
    variable = disp_x
    function = disp_x
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK

  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 2
    execute_on = 'initial timestep_end'
  [../]
  [./volStrain0]
    type = ElementalVariableValue
    elementid = 0
    variable = volumetric_strain
  [../]
  [./volStrain1]
    type = ElementalVariableValue
    elementid = 1
    variable = volumetric_strain
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_1/brick1_template2.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick1_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_x
  [../]
  [./disp_x13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_x
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_y
  [../]
  [./disp_y13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_y
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_x8 disp_x13 disp_x16 disp_y5 disp_y8 disp_y13 disp_y16 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 5e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/combined/test/tests/solid_mechanics/beam_pbp/beam_pbp.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  block = 1
  volumetric_locking_correction = false
[]

[Mesh]
  file = beam_pbp.e
[]

[Functions]
  [./press]
    type = ParsedFunction
    value = '100*t*x*z*z*z'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  []
[]

[BCs]
  [./x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = 10
    value = 0.0
  [../]

  [./z]
    type = DirichletBC
    variable = disp_z
    boundary = 3
    value = 0.0
  [../]

  [./Pressure]
    [./the_pressure]
      boundary = 2
      function = press
    [../]
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[] # Materials

[Preconditioning]
  [./PBP]
    type = PBP
    solve_order = 'disp_x disp_y disp_z'
    preconditioner = 'amg amg amg'
    off_diag_row = 'disp_y disp_z disp_z'
    off_diag_column = 'disp_x disp_x disp_y'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = JFNK

  nl_abs_tol = 1e-8

  l_max_its = 100
  nl_max_its = 10
  dt = 1.0
  num_steps = 2
[] # Executioner

[Postprocessors]
  [./nonlnrits]
    type = NumNonlinearIterations
  [../]
[] # Postprocessors

[Outputs]
  exodus = true
[] # Outputs

modules/tensor_mechanics/test/tests/elastic_patch/elastic_patch.i

# Patch Test

# This test is designed to compute constant xx, yy, zz, xy, yz, and zx
#  stress on a set of irregular hexes.  The mesh is composed of one
#  block with seven elements.  The elements form a unit cube with one
#  internal element.  There is a nodeset for each exterior node.

# The cube is displaced by 1e-6 units in x, 2e-6 in y, and 3e-6 in z.
#  The faces are sheared as well (1e-6, 2e-6, and 3e-6 for xy, yz, and
#  zx).  This gives a uniform strain/stress state for all six unique
#  tensor components.

# With Young's modulus at 1e6 and Poisson's ratio at 0, the shear
#  modulus is 5e5 (G=E/2/(1+nu)).  Therefore,
#
#  stress xx = 1e6 * 1e-6 = 1
#  stress yy = 1e6 * 2e-6 = 2
#  stress zz = 1e6 * 3e-6 = 3
#  stress xy = 2 * 5e5 * 1e-6 / 2 = 0.5
#             (2 * G   * gamma_xy / 2 = 2 * G * epsilon_xy)
#  stress yz = 2 * 5e5 * 2e-6 / 2 = 1
#  stress zx = 2 * 5e5 * 3e-6 / 2 = 1.5

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  block = '1 2 3 4 5 6 7'
[]

[Mesh]#Comment
  file = elastic_patch.e
[] # Mesh

[Functions]
  [./rampConstant1]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 1e-6
  [../]
  [./rampConstant2]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 2e-6
  [../]
  [./rampConstant3]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 3e-6
  [../]
  [./rampConstant4]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 4e-6
  [../]
  [./rampConstant6]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 6e-6
  [../]
[] # Functions

[Variables]

  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]

[] # Variables

[AuxVariables]

  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_energy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./hydrostatic]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./firstinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./secondinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./thirdinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./maxprincipal]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./midprincipal]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./minprincipal]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./direction]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./max_shear]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./sint]
    order = CONSTANT
    family = MONOMIAL
  [../]

[] # AuxVariables

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]

  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zx
    index_i = 2
    index_j = 0
  [../]
  [./elastic_energy]
    type = ElasticEnergyAux
    variable = elastic_energy
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = vonmisesStress
  [../]
  [./hydrostatic]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = hydrostatic
    scalar_type = hydrostatic
  [../]
  [./fi]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = firstinv
    scalar_type = firstinvariant
  [../]
  [./si]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = secondinv
    scalar_type = secondinvariant
  [../]
  [./ti]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = thirdinv
    scalar_type = thirdinvariant
  [../]
  [./maxprincipal]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = maxprincipal
    scalar_type = MaxPRiNCIpAl
  [../]
  [./midprincipal]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = midprincipal
    scalar_type = MidPRiNCIpAl
  [../]
  [./minprincipal]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = minprincipal
    scalar_type = MiNPRiNCIpAl
  [../]
  [./direction]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = direction
    scalar_type = direction
    direction = '1 1 1'
  [../]
  [./max_shear]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = max_shear
    scalar_type = MaxShear
  [../]
  [./sint]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = sint
    scalar_type = StressIntensity
  [../]


[] # AuxKernels

[BCs]

  [./node1_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./node1_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = rampConstant2
  [../]
  [./node1_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 1
    function = rampConstant3
  [../]

  [./node2_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 2
    function = rampConstant1
  [../]
  [./node2_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 2
    function = rampConstant2
  [../]
  [./node2_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 2
    function = rampConstant6
  [../]

  [./node3_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 3
    function = rampConstant1
  [../]
  [./node3_y]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]
  [./node3_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 3
    function = rampConstant3
  [../]

  [./node4_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]
  [./node4_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
  [./node4_z]
    type = DirichletBC
    variable = disp_z
    boundary = 4
    value = 0.0
  [../]

  [./node5_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 5
    function = rampConstant1
  [../]
  [./node5_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = rampConstant4
  [../]
  [./node5_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 5
    function = rampConstant3
  [../]

  [./node6_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 6
    function = rampConstant2
  [../]
  [./node6_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 6
    function = rampConstant4
  [../]
  [./node6_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 6
    function = rampConstant6
  [../]

  [./node7_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 7
    function = rampConstant2
  [../]
  [./node7_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 7
    function = rampConstant2
  [../]
  [./node7_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 7
    function = rampConstant3
  [../]

  [./node8_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 8
    function = rampConstant1
  [../]
  [./node8_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 8
    function = rampConstant2
  [../]
  [./node8_z]
    type = DirichletBC
    variable = disp_z
    boundary = 8
    value = 0.0
  [../]


[] # BCs

[Materials]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]

  [./strain]
    type = ComputeFiniteStrain
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

[] # Materials

[Executioner]

  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[] # Executioner

[Outputs]
  exodus = true
[] # Outputs

modules/combined/test/tests/contact_verification/overclosure_removal/overclosure.i

# ---------------------------------------------------------------------------------------------------------
# REGRESSION TEST FOR OVERCLOSURE REMOVAL
# =======================================
# THIS TEST DEMONSTRATES THAT THE CODE IS CAPABLE OF REMOVING A SIZEABLE OVERCLOSURE IN A SINGLE TIME-STEP
# --------------------------------------------------------------------------------------------------------


[Mesh]
  file = oc_mesh.e
[]

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./penetration]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
    use_finite_deform_jacobian = true
  [../]
[]

[AuxKernels]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side1_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = 5
    value = 0.0
  [../]
  [./top_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1001    #nodeset 1001 top central node
    value = 0.0
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    decomposition_method = EigenSolution
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]

  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e5
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    decomposition_method = EigenSolution
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-7
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  dtmin = 1.0
  l_tol = 1e-3

[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 4
    disp_y = disp_y
    disp_x = disp_x
    master = 3
    system = constraint
    model = frictionless
    formulation = penalty
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/combined/test/tests/sliding_block/sliding/dirac/frictional_04_penalty.i

#  This is a benchmark test that checks Dirac based frictional
#  contact using the penalty method.  In this test a constant
#  displacement is applied in the horizontal direction to simulate
#  a small block come sliding down a larger block.
#
#  A friction coefficient of 0.4 is used.  The gold file is run on one processor
#  and the benchmark case is run on a minimum of 4 processors to ensure no
#  parallel variability in the contact pressure and penetration results.
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./stiffStuff]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]  # Materials

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  l_max_its = 200
  nl_max_its = 1000
  dt = 0.05
  end_time = 10
  num_steps = 1000
  nl_rel_tol = 1e-6
  dtmin = 0.01
  l_tol = 1e-6

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+7
    formulation = penalty
    friction_coefficient = 0.4
    normal_smoothing_distance = 0.1
    system = DiracKernel
  [../]
[]

modules/tensor_mechanics/test/tests/ad_viscoplasticity_stress_update/gtn_single.i

# This test provides an example of an individual GTN viscoplasticity model

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 1
  ny = 1
  xmax = 0.002
  ymax = 0.002
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  add_variables = true
  base_name = 'total'
  generate_output = 'strain_xx strain_yy strain_xy hydrostatic_stress vonmises_stress'
  use_automatic_differentiation = true
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x = '0 0.1'
    y = '0 1e-5'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.3
    base_name = 'total'
  [../]
  [./stress]
    type = ADComputeMultiplePorousInelasticStress
    inelastic_models = gtn
    initial_porosity = 0.1
    outputs = all
    base_name = 'total'
  [../]

  [./gtn]
    type = ADViscoplasticityStressUpdate
    total_strain_base_name = 'total'
    coefficient = 'coef'
    power = 3
    viscoplasticity_model = GTN
    outputs = all
    relative_tolerance = 1e-11
  [../]
  [./coef]
    type = ParsedMaterial
    f_name = coef
    # Example of creep power law
    function = '1e-18 * exp(-4e4 / 1.987 / 1200)'
  [../]
[]

[BCs]
  [./no_disp_x]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./no_disp_y]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./pull_disp_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = top
    function = pull
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  dt = 0.01
  end_time = 0.12
[]

[Postprocessors]
  [./disp_x]
    type = SideAverageValue
    variable = disp_x
    boundary = right
  [../]
  [./disp_y]
    type = SideAverageValue
    variable = disp_y
    boundary = top
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = total_hydrostatic_stress
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = total_vonmises_stress
  [../]
  [./dt]
    type = TimestepSize
  [../]
  [./num_lin]
    type = NumLinearIterations
    outputs = console
  [../]
  [./num_nonlin]
    type = NumNonlinearIterations
    outputs = console
  [../]
  [./eff_creep_strain]
    type = ElementAverageValue
    variable = effective_viscoplasticity
  [../]
  [./porosity]
    type = ElementAverageValue
    variable = porosity
  [../]
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_4/ring4_template2.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring4_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x9 disp_y9 disp_x16 disp_y16 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/combined/test/tests/frictional_contact/single_point_2d/single_point_2d.i

[Mesh]
  file = single_point_2d.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./horizontal_movement]
    type = ParsedFunction
    value = t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    save_in = 'saved_x saved_y'
    diag_save_in = 'diag_saved_x diag_saved_y'
  [../]
[]


[AuxKernels]
  [./incslip_x]
    type = PenetrationAux
    variable = inc_slip_x
    quantity = incremental_slip_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./incslip_y]
    type = PenetrationAux
    variable = inc_slip_y
    quantity = incremental_slip_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./botx]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./boty]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./botx2]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./boty2]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./topx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./topy]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = -0.005
  [../]
[]

[Materials]
  [./bottom]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1.0e9
    poissons_ratio = 0.3
  [../]
  [./top]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu    superlu_dist'
  petsc_options = '-mat_superlu_dist_iterrefine -mat_superlu_dist_replacetinypivot'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 200
  dt = 0.001
  end_time = 0.01
  num_steps = 1000
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  dtmin = 0.001
  l_tol = 1e-3
[]

[Outputs]
  exodus = true
  print_linear_residuals = true
  perf_graph = true
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    master = 2
    slave = 3
    model = coulomb
    system = constraint
    friction_coefficient = '0.25'
  [../]
[]

[Dampers]
  [./contact_slip]
    type = ContactSlipDamper
    master = '2'
    slave = '3'
  [../]
[]

modules/peridynamics/test/tests/jacobian_check/thermomechanics_2D_FNOSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./temp]
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
    stabilization = FORCE
    eigenstrain_names = thermal
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConductionBPD
    variable = temp
  [../]
[]

[Materials]
  [./linelast]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeForceStabilizedSmallStrainNOSPD
    eigenstrain_names = thermal
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = thermal
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]

  [./thermal]
    type = ThermalConstantHorizonMaterialBPD
    thermal_conductivity = 1.0
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

modules/tensor_mechanics/test/tests/multiple_two_parameter_plasticity/cycled_dp_then_wp.i

# Use ComputeMultipleInelasticStress with two inelastic models: CappedDruckerPrager and CappedWeakPlane.
# The relative_tolerance and absolute_tolerance parameters are set very large so that
# only one iteration is performed.  This is the algorithm that FLAC uses to model
# jointed rocks, only Capped-Mohr-Coulomb is used instead of CappedDruckerPrager
#
# In this test "cycle_models=true" so that in the first timestep only
# CappedDruckerPrager is used, while in the second timestep only
# CappedWeakPlane is used.
#
# initial_stress = diag(1E3, 1E3, 1E3)
# The CappedDruckerPrager has tensile strength 3E2 and large cohesion,
# so the stress initially returns to diag(1E2, 1E2, 1E2)
# The CappedWeakPlane has tensile strength zero and large cohesion,
# so the stress returns to diag(1E2 - v/(1-v)*1E2, 1E2 - v/(1-v)*1E2, 0)
# where v=0.2 is the Poisson's ratio

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    eigenstrain_names = ini_stress
    generate_output = 'stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz'
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = 0
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = 0
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = 0
  [../]
[]

[AuxVariables]
  [./yield_fcn_dp]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn_wp]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tensile_cdp]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tensile_cwp]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_dp_auxk]
    type = MaterialStdVectorAux
    index = 1    # this is the tensile yield function - it should be zero
    property = cdp_plastic_yield_function
    variable = yield_fcn_dp
  [../]
  [./yield_fcn_wp_auxk]
    type = MaterialStdVectorAux
    index = 1    # this is the tensile yield function - it should be zero
    property = cwp_plastic_yield_function
    variable = yield_fcn_wp
  [../]
  [./tensile_cdp]
    type = MaterialStdVectorAux
    index = 1
    property = cdp_plastic_internal_parameter
    variable = tensile_cdp
  [../]
  [./tensile_cwp]
    type = MaterialStdVectorAux
    index = 1
    property = cwp_plastic_internal_parameter
    variable = tensile_cwp
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./i_cdp]
    type = PointValue
    point = '0 0 0'
    variable = tensile_cdp
  [../]
  [./i_cwp]
    type = PointValue
    point = '0 0 0'
    variable = tensile_cwp
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 300
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 20
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 0
  [../]
  [./dp]
    type = TensorMechanicsPlasticDruckerPrager
    mc_cohesion = mc_coh
    mc_friction_angle = mc_phi
    mc_dilation_angle = mc_psi
    internal_constraint_tolerance = 1 # irrelevant here
    yield_function_tolerance = 1      # irrelevant here
  [../]
  [./wp_coh]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
  [./wp_tanphi]
    type = TensorMechanicsHardeningConstant
    value = 0.5
  [../]
  [./wp_tanpsi]
    type = TensorMechanicsHardeningConstant
    value = 0.1111077
  [../]
  [./wp_t_strength]
    type = TensorMechanicsHardeningConstant
    value = 0
  [../]
  [./wp_c_strength]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.2
    youngs_modulus = 1.0
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '1E3 0 0  0 1E3 0  0 0 1E3'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    relative_tolerance = 1E4
    absolute_tolerance = 2
    inelastic_models = 'cdp cwp'
    perform_finite_strain_rotations = false
    cycle_models = true
  [../]
  [./cdp]
    type = CappedDruckerPragerStressUpdate
    base_name = cdp
    DP_model = dp
    tensile_strength = ts
    compressive_strength = cs
    yield_function_tol = 1E-5
    tip_smoother = 1E3
    smoothing_tol = 1E3
  [../]
  [./cwp]
    type = CappedWeakPlaneStressUpdate
    base_name = cwp
    cohesion = wp_coh
    tan_friction_angle = wp_tanphi
    tan_dilation_angle = wp_tanpsi
    tensile_strength = wp_t_strength
    compressive_strength = wp_c_strength
    tip_smoother = 1E3
    smoothing_tol = 1E3
    yield_function_tol = 1E-5
  [../]
[]


[Executioner]
  end_time = 2
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = cycled_dp_then_wp
  csv = true
[]

tutorials/darcy_thermo_mech/step09_mechanics/problems/step9.i

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  ny = 200
  nx = 10
  ymax = 0.304 # Length of test chamber
  xmax = 0.0257 # Test chamber radius
[]

[MeshModifiers]
  [bottom]
    type = SubdomainBoundingBox
    location = inside
    bottom_left = '0 0 0'
    top_right = '0.01285 0.304 0'
    block_id = 1
  []
[]

[Variables]
  [pressure]
  []
  [temperature]
    initial_condition = 300 # Start at room temperature
  []
[]

[AuxVariables]
  [velocity]
    order = CONSTANT
    family = MONOMIAL_VEC
  []
[]

[Modules/TensorMechanics/Master]
  [all]
    # This block adds all of the proper Kernels, strain calculators, and Variables
    # for TensorMechanics in the correct coordinate system (autodetected)
    add_variables = true
    strain = FINITE
    eigenstrain_names = eigenstrain
    use_automatic_differentiation = true
    generate_output = 'vonmises_stress elastic_strain_xx elastic_strain_yy strain_xx strain_yy'
  []
[]

[Kernels]
  [darcy_pressure]
    type = DarcyPressure
    variable = pressure
  []
  [heat_conduction]
    type = ADHeatConduction
    variable = temperature
  []
  [heat_conduction_time_derivative]
    type = ADHeatConductionTimeDerivative
    variable = temperature
  []
  [heat_convection]
    type = DarcyAdvection
    variable = temperature
    pressure = pressure
  []
[]

[AuxKernels]
  [velocity]
    type = DarcyVelocity
    variable = velocity
    execute_on = timestep_end
    pressure = pressure
  []
[]

[BCs]
  [inlet]
    type = DirichletBC
    variable = pressure
    boundary = bottom
    value = 4000 # (Pa) From Figure 2 from paper.  First data point for 1mm spheres.
  []
  [outlet]
    type = DirichletBC
    variable = pressure
    boundary = top
    value = 0 # (Pa) Gives the correct pressure drop from Figure 2 for 1mm spheres
  []
  [inlet_temperature]
    type = FunctionDirichletBC
    variable = temperature
    boundary = bottom
    function = 'if(t<0,350+50*t,350)'
  []
  [outlet_temperature]
    type = HeatConductionOutflow
    variable = temperature
    boundary = top
  []
  [hold_inlet]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0
  []
  [hold_center]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  []
  [hold_outside]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0
  []
[]

[Materials]
  viscosity_file = data/water_viscosity.csv
  density_file = data/water_density.csv
  thermal_conductivity_file = data/water_thermal_conductivity.csv
  specific_heat_file = data/water_specific_heat.csv
  thermal_expansion_file = data/water_thermal_expansion.csv

  [column_top]
    type = PackedColumn
    block = 0
    temperature = temperature
    radius = 1.15
    fluid_viscosity_file = ${viscosity_file}
    fluid_density_file = ${density_file}
    fluid_thermal_conductivity_file = ${thermal_conductivity_file}
    fluid_specific_heat_file = ${specific_heat_file}
    fluid_thermal_expansion_file = ${thermal_expansion_file}
  []
  [column_bottom]
    type = PackedColumn
    block = 1
    temperature = temperature
    radius = 1
    fluid_viscosity_file = ${viscosity_file}
    fluid_density_file = ${density_file}
    fluid_thermal_conductivity_file = ${thermal_conductivity_file}
    fluid_specific_heat_file = ${specific_heat_file}
    fluid_thermal_expansion_file = ${thermal_expansion_file}
  []

  [elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 200e9 # (Pa) from wikipedia
    poissons_ratio = .3 # from wikipedia

  []
  [elastic_stress]
    type = ADComputeFiniteStrainElasticStress
  []
  [thermal_strain]
    type = ADComputeThermalExpansionEigenstrain
    stress_free_temperature = 300
    eigenstrain_name = eigenstrain
    temperature = temperature
    thermal_expansion_coeff = 1e-5 # TM modules doesn't support material property, but it will
  []
[]

[Postprocessors]
  [average_temperature]
    type = ElementAverageValue
    variable = temperature
  []
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Executioner]
  type = Transient
  start_time = -1
  end_time = 200
  steady_state_tolerance = 1e-7
  steady_state_detection = true
  dt = 0.25
  solve_type = PJFNK
  automatic_scaling = true
  compute_scaling_once = false
  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'
  #petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  #petsc_options_value = 'hypre boomeramg 500'
  line_search = none
  [TimeStepper]
    type = FunctionDT
    function = 'if(t<0,0.1,0.25)'
  []
[]

[Outputs]
  [out]
    type = Exodus
    elemental_as_nodal = true
  []
[]

modules/combined/test/tests/solid_mechanics/Rayleigh_damping/HHT_time_integration/Rayleigh_HHT.i

# Test for rayleigh damping implemented using HHT time integration
#
# The test is for an 1-D bar element of unit length fixed on one end
# with a ramped pressure boundary condition applied to the other end.
# zeta and eta correspond to the stiffness and mass proportional
# rayleigh damping alpha, beta and gamma are HHT time integration
# parameters The equation of motion in terms of matrices is:
#
# M*accel + (eta*M+zeta*K)*[(1+alpha)vel-alpha vel_old]
#   + alpha*(K*disp - K*disp_old) + K*disp = P(t+alpha dt)*Area
#
# Here M is the mass matrix, K is the stiffness matrix, P is the applied pressure
#
# This equation is equivalent to:
#
# density*accel + eta*density*[(1+alpha)vel-alpha vel_old] +
#   zeta*[(1+alpha)*d/dt(Div stress)- alpha*d/dt(Div stress_old)] +
#   alpha *(Div stress - Div stress_old) +Div Stress= P(t+alpha dt)
#
# The first two terms on the left are evaluated using the Inertial
# force kernel The next three terms on the left involving zeta and
# alpha are evaluated using the StressDivergence Kernel The residual
# due to Pressure is evaluated using Pressure boundary condition
#
# The system will come to steady state slowly after the pressure
# becomes constant.  Alpha equal to zero will result in Newmark
# integration.
[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
  order = FIRST
  family = LAGRANGE
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = 0.0
  xmax = 0.1
  ymin = 0.0
  ymax = 1.0
  zmin = 0.0
  zmax = 0.1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./vel_x]
  [../]
  [./accel_x]
  [../]
  [./vel_y]
  [../]
  [./accel_y]
  [../]
  [./vel_z]
  [../]
  [./accel_z]
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

[]

[Kernels]

  [./DynamicTensorMechanics]
    use_automatic_differentiation = true
    alpha = 0.11
    zeta = 0.1
  [../]
  [./inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    eta=0.1
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    eta=0.1
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    beta = 0.25
    gamma = 0.5
    eta = 0.1
  [../]

[]

[AuxKernels]
  [./accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_z]
    type = NewmarkAccelAux
    variable = accel_z
    displacement = disp_z
    velocity = vel_z
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_z]
    type = NewmarkVelAux
    variable = vel_z
    acceleration = accel_z
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./stress_yy]
     type = RankTwoAux
     variable = stress_yy
     rank_two_tensor = stress
     index_i = 1
     index_j = 1
  [../]
  [./strain_yy]
     type = RankTwoAux
     variable = strain_yy
     rank_two_tensor = total_strain
     index_i = 1
     index_j = 1
  [../]

[]


[BCs]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value=0.0
  [../]
  [./top_x]
   type = DirichletBC
    variable = disp_x
    boundary = top
    value=0.0
  [../]
  [./top_z]
    type = DirichletBC
    variable = disp_z
    boundary = top
    value=0.0
  [../]
  [./right_x]
   type = DirichletBC
    variable = disp_x
    boundary = right
    value=0.0
  [../]
  [./right_z]
    type = DirichletBC
    variable = disp_z
    boundary = right
    value=0.0
  [../]
  [./left_x]
   type = DirichletBC
    variable = disp_x
    boundary = left
    value=0.0
  [../]
  [./left_z]
    type = DirichletBC
    variable = disp_z
    boundary = left
    value=0.0
  [../]
  [./front_x]
   type = DirichletBC
    variable = disp_x
    boundary = front
    value=0.0
  [../]
  [./front_z]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value=0.0
  [../]
  [./back_x]
   type = DirichletBC
    variable = disp_x
    boundary = back
    value=0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value=0.0
  [../]
  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = bottom
    value=0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value=0.0
  [../]
  [./Pressure]
    [./Side1]
    boundary = bottom
    function = pressure
    factor = 1
    alpha = 0.11
    [../]
  [../]
[]

[Materials]
  [./elastic]
    type = ComputeIsotropicElasticityTensor
    block = '0'
    youngs_modulus = 210e+09
    poissons_ratio = 0
  [../]
  [./elastic_strain]
    type= ComputeFiniteStrain
    block = '0'
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
    block = '0'
  [../]
  [./density]
    type = GenericConstantMaterial
    block = 0
    prop_names = 'density'
    prop_values = '7750'
  [../]
[]

[Executioner]

  type = Transient
  start_time = 0
  end_time = 2
  dtmax = 0.1
  dtmin = 0.1
  [./TimeStepper]
    type = ConstantDT
    dt = 0.1
  [../]

[]


[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0.0 0.1 0.2 1.0 2.0 5.0'
    y = '0.0 0.1 0.2 1.0 1.0 1.0'
    scale_factor = 1e9
  [../]
  [./vel_ic]
    type = PiecewiseLinear
    x = '0.0 0.5 1.0'
    y = '0.1 0.1 0.1'
    scale_factor = 1
  [../]
[]

[Postprocessors]
   [./_dt]
     type = TimestepSize
   [../]
   [./disp]
     type = NodalMaxValue
     variable = disp_y
     boundary = bottom
   [../]
   [./vel]
     type = NodalMaxValue
     variable = vel_y
     boundary = bottom
   [../]
   [./accel]
     type = NodalMaxValue
     variable = accel_y
     boundary = bottom
   [../]
   [./stress_yy]
      type = ElementAverageValue
      variable = stress_yy
   [../]
   [./strain_yy]
      type = ElementAverageValue
      variable = strain_yy
   [../]

[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/mortar_tm/2d/frictionless_first/finite.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'finite'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    preset = false
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/combined/test/tests/elastic_patch/ad_elastic_patch_rz.i

#
# This problem is taken from the Abaqus verification manual:
#   "1.5.4 Patch test for axisymmetric elements"
# The stress solution is given as:
#   xx = yy = zz = 2000
#   xy = 400
#
# Since the strain is 1e-3 in all three directions, the new density should be
#   new_density = original_density * V_0 / V
#   new_density = 0.283 / (1 + 1e-3 + 1e-3 + 1e-3) = 0.282153

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = elastic_patch_rz.e
[]

[Variables]
  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = SMALL
  incremental = true
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
[]

[Kernels]
  [./body]
    type = BodyForce
    variable = disp_y
    value = 1
    function = '-400/x'
  [../]

  [./heat]
    type = TimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 10
    function = '1e-3*x'
  [../]
  [./uz]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 10
    function = '1e-3*(x+y)'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]
[]

[Materials]
  [./density]
    type = ADDensity
    density = 0.283
    outputs = all
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  end_time = 1.0
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/peridynamics/test/tests/jacobian_check/generalized_planestrain_smallstrain_NOSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  scalar_out_of_plane_strain = scalar_strain_zz
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[Modules/Peridynamics/Mechanics]
  [./Master]
    [./all]
      formulation = NONORDINARY_STATE
    [../]
  [../]
  [./GeneralizedPlaneStrain]
    [./all]
      formulation = NONORDINARY_STATE
    [../]
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./strain]
    type = ComputePlaneSmallStrainNOSPD
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

modules/combined/test/tests/contact_verification/hertz_cyl/quart_symm_q8/hertz_cyl_qsym_1deg_template1.i

[GlobalParams]
  order = SECOND
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_qsym_1deg_q8.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_zero]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 0.0 0.0'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 4
    paired_boundary = 3
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./disp_x281]
    type = NodalVariableValue
    nodeid = 280
    variable = disp_x
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 3'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2 3'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = disp_ramp_vert
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 50
  nl_max_its = 100

  start_time = 0.0
  dt = 0.1
  dtmin = 0.1
  num_steps = 10
  end_time = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '4'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x281 top_react_x top_react_y x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    master = 3
    slave = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+11
  [../]
[]

modules/tensor_mechanics/test/tests/thermal_expansion/constant_expansion_coeff.i

# This test involves only thermal expansion strains on a 2x2x2 cube of approximate
# steel material.  An initial temperature of 25 degrees C is given for the material,
# and an auxkernel is used to calculate the temperature in the entire cube to
# raise the temperature each time step.  After the first timestep,in which the
# temperature jumps, the temperature increases by 6.25C each timestep.
# The thermal strain increment should therefore be
#     6.25 C * 1.3e-5 1/C = 8.125e-5 m/m.

# This test is also designed to be used to identify problems with restart files

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t*(500.0)+300.0
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        strain = SMALL
        incremental = true
        add_variables = true
        eigenstrain_names = eigenstrain
        generate_output = 'strain_xx strain_yy strain_zz'
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
  [../]
[]

[BCs]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 298
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  end_time = 0.075
  dt = 0.0125
  dtmin = 0.0001
[]

[Outputs]
  csv = true
  exodus = true
  checkpoint = true
[]

[Postprocessors]
  [./strain_xx]
    type = ElementAverageValue
    variable = strain_xx
  [../]
  [./strain_yy]
    type = ElementAverageValue
    variable = strain_yy
  [../]
  [./strain_zz]
    type = ElementAverageValue
    variable = strain_zz
  [../]
  [./temperature]
    type = AverageNodalVariableValue
    variable = temp
  [../]
[]

modules/tensor_mechanics/tutorials/basics/part_2.4.i

#Tensor Mechanics tutorial: the basics
#Step 2, part 4
#2D axisymmetric RZ simulation of uniaxial tension with J2 plasticity with
#hardening

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = necking_quad4.e
  uniform_refine = 0
  second_order = true
[]

[Modules/TensorMechanics/Master]
  [./block1]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_yy strain_yy vonmises_stress'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeMultiPlasticityStress
    ep_plastic_tolerance = 1e-9
    plastic_models = J2
  [../]
[]

[UserObjects]
  [./hardening]
    type = TensorMechanicsHardeningCubic
    value_0 = 2.4e2
    value_residual = 3.0e2
    internal_0 = 0
    internal_limit = 0.005
  [../]
  [./J2]
    type = TensorMechanicsPlasticJ2
    yield_strength = hardening
    yield_function_tolerance = 1E-9
    internal_constraint_tolerance = 1E-9
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]
  [./top]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = top
    function = '0.0007*t'
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.25
  end_time = 20

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -sub_pc_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm lu 1 101'
[]

[Postprocessors]
  [./ave_stress_bottom]
    type = SideAverageValue
    variable = stress_yy
    boundary = bottom
  [../]
  [./ave_strain_bottom]
    type = SideAverageValue
    variable = strain_yy
    boundary = bottom
  [../]
[]

[Outputs]
  exodus = true
  perf_graph = true
  csv = true
  print_linear_residuals = false
[]

modules/combined/test/tests/normalized_penalty/normalized_penalty.i

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = normalized_penalty.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Functions]
  [./left_x]
    type = PiecewiseLinear
    x = '0 1 2'
    y = '0 0.02 0'
  [../]
[]

[AuxVariables]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx'
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  []
[]

[Contact]
  [./m3_s2]
    master = 3
    slave = 2
    penalty = 1e10
    normalize_penalty = true
    formulation = penalty
    tangential_tolerance = 1e-3
    system = Constraint
  [../]
[]

[BCs]
  [./left_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 1
    function = left_x
  [../]

  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2 3 4'
    value = 0.0
  [../]

  [./right]
    type = DirichletBC
    variable = disp_x
    boundary = '3 4'
    value = 0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2 3 4 1000'
    youngs_modulus = 3e8
    poissons_ratio = 0.0
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2 3 4 1000'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'lu       101'

  line_search = 'none'

  nl_rel_tol = 1e-12
  nl_abs_tol = 5e-8

  l_max_its = 100
  nl_max_its = 10
  dt = 0.5
  num_steps = 4
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_linear_elasticity/thermal_expansion.i

# This input file is designed to test the RankTwoAux and RankFourAux
# auxkernels, which report values out of the Tensors used in materials
# properties.
# Materials properties into AuxVariables - these are elemental variables, not nodal variables.

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 2
  xmax = 2
  ymax = 2
[]

[Modules/TensorMechanics/Master/All]
  strain = SMALL
  eigenstrain_names = eigenstrain
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_xy'
  use_automatic_differentiation = true
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
  [./eigenstrain]
    type = ADComputeEigenstrain
    eigen_base = '1e-4'
    eigenstrain_name = eigenstrain
  [../]
[]

[BCs]
  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady
  solve_type = 'NEWTON'

  nl_rel_tol = 1e-14
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update7.i

# MC update version, with only Tensile with tensile strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.
# Returns to close to the edge of tensile yield

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0.5
    internal_limit = 2E-2
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-1 0.1 0.2  0.1 15 -0.3  0.2 -0.3 14'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_2/cyl2_template2.i

#
# This input file is a template for both the frictionless and glued test
# variations for the current problem geometry. In order to create an input
# file to run outside the runtest framework, look at the tests file and add the
# appropriate input file lines from the cli_args line.
#

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl2_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 1000
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_y5 disp_x9 disp_y9 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/tensor_mechanics/test/tests/1D_spherical/finiteStrain_1DSphere_hollow.i

# This simulation models the mechanics solution for a hollow sphere under
# pressure, applied on the outer surfaces, using 1D spherical symmetry
# assumpitions.  The inner radius of the sphere, r = 4mm, is pinned to prevent
# rigid body movement of the sphere.
#
# From Bower (Applied Mechanics of Solids, 2008, available online at
# solidmechanics.org/text/Chapter4_1/Chapter4_1.htm), and applying the outer
# pressure and pinned displacement boundary conditions set in this simulation,
# the radial displacement is given by:
#
# u(r) = \frac{P(1 + v)(1 - 2v)b^3}{E(b^3(1 + v) + 2a^3(1-2v))} * (\frac{a^3}{r^2} - r)
#
# where P is the applied pressure, b is the outer radius, a is the inner radius,
# v is Poisson's ration, E is Young's Modulus, and r is the radial position.
#
# The radial stress is given by:
#
# S(r) = \frac{Pb^3}{b^3(1 + v) + 2a^3(1 - 2v)} * (\frac{2a^3}{r^3}(2v - 1) - (1 + v))
#
# The test assumes an inner radius of 4mm, and outer radius of 9 mm,
# zero displacement at r = 4mm, and an applied outer pressure of 2MPa.
# The radial stress is largest in the inner most element and, at an assumed
# mid element coordinate of 4.5mm, is equal to -2.545MPa.
[Mesh]
  type = GeneratedMesh
  dim = 1
  xmin = 4
  xmax = 9
  nx = 5
[]

[GlobalParams]
  displacements = 'disp_r'
[]

[Problem]
  coord_type = RSPHERICAL
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
  [../]
[]

[AuxVariables]
  [./stress_rr]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Postprocessors]
  [./stress_rr]
    type = ElementAverageValue
    variable = stress_rr
  [../]
[]

[AuxKernels]
  [./stress_rr]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_rr
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./innerDisp]
    type = DirichletBC
    boundary = left
    variable = disp_r
    value = 0.0
  [../]
  [./outerPressure]
    type = Pressure
    boundary = right
    variable = disp_r
    component = 0
    factor = 2
  [../]
[]

[Materials]
  [./Elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.345
    youngs_modulus = 1e4
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none


# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-8

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-5

# time control
  start_time = 0.0
  dt = 0.25
  dtmin = 0.0001
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/simple_contact/simple_contact_dirac_test.i

# Note: Run merged.i to generate a solution to compare to that doesn't use contact.
# This version of the test uses DiracKernel based contact

[Mesh]
  file = contact.e
  # PETSc < 3.5.0 requires the iteration patch_update_strategy to
  # avoid PenetrationLocator warnings, which are currently treated as
  # errors by the TestHarness.
  patch_update_strategy = 'iteration'
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx'
  [../]
[]

[Contact]
  [./dummy_name]
    master = 3
    slave = 2
    penalty = 1e5
    formulation = kinematic
    system = DiracKernel
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./left_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.0001
  [../]

  [./right_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]

  [./right_z]
    type = DirichletBC
    variable = disp_z
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre    boomeramg      101'

  line_search = 'none'

  nl_abs_tol = 1e-8

  l_max_its = 100
  nl_max_its = 10
  dt = 1.0
  num_steps = 1
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/tensor_mechanics/test/tests/ad_elastic/rspherical_finite_elastic-noad.i

[Mesh]
  type = GeneratedMesh
  dim = 1
  nx = 5
[]

[Problem]
  coord_type = RSPHERICAL
[]

[GlobalParams]
  displacements = 'disp_r'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = StressDivergenceRSphericalTensors
    component = 0
    variable = disp_r
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./center]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
  [./strain]
    type = ComputeRSphericalFiniteStrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = rspherical_finite_elastic_out
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update12.i

# MC update version, with only compressive with compressive strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Return to the stress_I = stress_II ~1 edge

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-2 0 0  0 0 0  0 0 -2.01'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/peridynamics/test/tests/jacobian_check/3D_mechanics_smallstrain_NOSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 2

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 3
    ny = 3
    nz = 3
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeSmallStrainNOSPD
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

modules/tensor_mechanics/test/tests/stress_recovery/patch/patch_finite_stress.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 2
  elem_type = QUAD4
[]

[Variables]
  [disp_x]
    order = FIRST
    family = LAGRANGE
  []
  [disp_y]
    order = FIRST
    family = LAGRANGE
  []
[]

[AuxVariables]
  [stress_xx]
    order = FIRST
    family = MONOMIAL
  []
  [stress_yy]
    order = FIRST
    family = MONOMIAL
  []
  [stress_xx_recovered]
    order = FIRST
    family = LAGRANGE
  []
  [stress_yy_recovered]
    order = FIRST
    family = LAGRANGE
  []
[]

[AuxKernels]
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = 'timestep_end'
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = 'timestep_end'
  []
  [stress_xx_recovered]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_recovered
    index_i = 0
    index_j = 0
    execute_on = 'timestep_end'
  []
  [stress_yy_recovered]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy_recovered
    index_i = 1
    index_j = 1
    execute_on = 'timestep_end'
  []
[]

[Kernels]
  [solid_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
  []
  [solid_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
  []
[]

[Materials]
  [strain]
    type = ComputeFiniteStrain
  []
  [Cijkl]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 2.1e+5
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
  []
[]

[BCs]
  [top_xdisp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'top'
    function = 0
  []
  [top_ydisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'top'
    function = t
  []
  [bottom_xdisp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'bottom'
    function = 0
  []
  [bottom_ydisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'bottom'
    function = 0
  []
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
    ksp_norm = default
  []
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  petsc_options_iname = '-ksp_type -pc_type'
  petsc_options_value = 'preonly   lu'
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-8
  l_max_its = 100
  nl_max_its = 30
  dt = 0.01
  dtmin = 1e-11
  start_time = 0
  end_time = 0.05
[]

[Outputs]
  exodus = true
  print_linear_residuals = false
[]

modules/combined/test/tests/solid_mechanics/spherical_shell/3D_test.i

# Considers the mechanics solution for a thick spherical shell that is uniformly
# pressurized on the inner and outer surfaces. Three versions of the test are
# provided, assuming 1D spherical geometry (1D-SPH), 2D axisymmetic geometry
# (2D-RZ), and 3D geometry (3D). The tests demonstrate that all three geometric
# approaches produce the same correct solution.
#
# From Roark (Formulas for Stress and Strain, McGraw-Hill, 1975), the radially-dependent
# circumferential stress in a uniformly pressurized thick spherical shell is given by:
#
# S(r) = [ Pi[ri^3(2r^3+ro^3)] - Po[ro^3(2r^3+ri^3)] ] / [2r^3(ro^3-ri^3)]
#
#   where:
#          Pi = inner pressure
#          Po = outer pressure
#          ri = inner radius
#          ro = outer radius
#
# The tests assume an inner and outer radii of 5 and 10, with internal and external
# pressures of 100000 and 200000, respectively. The resulting compressive tangential
# stress is largest at the inner wall and, from the above equation, has a value
# of -271429.
#
# RESULTS are below. Since stresses are average element values, values for the
# edge element and one-element-in are used to extrapolate the stress to the
# inner surface. The vesrion of the tests that are checked use the coarsest meshes.
#
#  Mesh    Radial elem   S(edge elem)  S(one elem in)  S(extrap to surf)
# 1D-SPH       12          -264842      -254419        -270053
# 2D-RZ        12          -265007      -254668        -270177
#  3D          12 (4x4)    -258922      -251099        -262834
#  3D          12 (6x6)    -262194      -252969        -266807
#
# 1D-SPH       48          -269679      -266390        -271323
# 2D-RZ        48          -269723      -266470        -271350
#  3D          48          -268617      -265717        -270067
#
# 1D-SPH      100          -270580      -268932        -271404
# 2D-RZ       100          -270587      -268946        -271408
#
# The numerical solution converges to the analytical solution as the mesh is
# refined.

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = 3D_mesh.e
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    additional_generate_output = 'stress_zz'
  []
[]

[BCs]
# pin particle along symmetry planes
  [./no_disp_x]
    type = DirichletBC
    variable = disp_x
    boundary = xzero
    value = 0.0
  [../]

  [./no_disp_y]
    type = DirichletBC
    variable = disp_y
    boundary = yzero
    value = 0.0
  [../]

  [./no_disp_z]
    type = DirichletBC
    variable = disp_z
    boundary = zzero
    value = 0.0
  [../]

# exterior and internal pressures
  [./exterior_pressure_x]
    type = Pressure
    variable = disp_x
    boundary = outer
    component = 0
    factor = 200000
  [../]

 [./exterior_pressure_y]
    type = Pressure
    variable = disp_y
    boundary = outer
    component = 1
    factor = 200000
  [../]

[./exterior_pressure_z]
    type = Pressure
    variable = disp_z
    boundary = outer
    component = 2
    factor = 200000
  [../]

  [./interior_pressure_x]
    type = Pressure
    variable = disp_x
    boundary = inner
    component = 0
    factor = 100000
  [../]

  [./interior_pressure_y]
    type = Pressure
    variable = disp_y
    boundary = inner
    component = 1
    factor = 100000
  [../]

[./interior_pressure_z]
    type = Pressure
    variable = disp_z
    boundary = inner
    component = 2
    factor = 100000
  [../]
[]

[Materials]
  [./elastic]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1.0e10
    poissons_ratio = 0.345
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
[]

[Debug]
    show_var_residual_norms = true
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50

   start_time = 0.0
   end_time = 1
   num_steps = 1000

  dtmax = 5e6
  dtmin = 1
  [./TimeStepper]
    type = IterationAdaptiveDT
    dt = 1
    optimal_iterations = 6
    iteration_window = 0
    linear_iteration_ratio = 100
  [../]

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

#  [./Quadrature]
#    order = THIRD
#  [../]
[]

[Postprocessors]
  [./dt]
    type = TimestepSize
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_3/brick3_mu_0_2_pen.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick3_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
  [./tang_force_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_x
  [../]
  [./disp_x33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_x
  [../]
  [./disp_y28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_y
  [../]
  [./disp_y33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  file_base = brick3_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = brick3_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x28 disp_y28 disp_x33 disp_y33 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+6
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_4/cyl4_template1.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl4_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 1000
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x9 disp_y9 disp_x16 disp_y16 stress_yy stress_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/xfem/test/tests/bimaterials/inclusion_bimaterials_2d.i

# This test is for a matrix-inclusion composite materials
# The global stress is determined by switching the stress based on level set values
# The inclusion geometry is marked by a level set function
# The matrix and inclusion are glued together

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[UserObjects]
  [./level_set_cut_uo]
    type = LevelSetCutUserObject
    level_set_var = ls
  [../]
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 11
  ny = 11
  xmin = 0.0
  xmax = 5.
  ymin = 0.0
  ymax = 5.
  elem_type = QUAD4
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./ls]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxKernels]
  [./ls_function]
    type = FunctionAux
    variable = ls
    function = ls_func
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Functions]
  [./ls_func]
    type = ParsedFunction
    value = 'sqrt((y-2.5)*(y-2.5) + (x-2.5)*(x-2.5)) - 1.5'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./a_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./a_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./a_strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./b_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./b_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./b_strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  [../]
  [./a_strain_xx]
    type = RankTwoAux
    rank_two_tensor = A_total_strain
    index_i = 0
    index_j = 0
    variable = a_strain_xx
  [../]
  [./a_strain_yy]
    type = RankTwoAux
    rank_two_tensor = A_total_strain
    index_i = 1
    index_j = 1
    variable = a_strain_yy
  [../]
  [./a_strain_xy]
    type = RankTwoAux
    rank_two_tensor = A_total_strain
    index_i = 0
    index_j = 1
    variable = a_strain_xy
  [../]
  [./b_strain_xx]
    type = RankTwoAux
    rank_two_tensor = B_total_strain
    index_i = 0
    index_j = 0
    variable = b_strain_xx
  [../]
  [./b_strain_yy]
    type = RankTwoAux
    rank_two_tensor = B_total_strain
    index_i = 1
    index_j = 1
    variable = b_strain_yy
  [../]
  [./b_strain_xy]
    type = RankTwoAux
    rank_two_tensor = B_total_strain
    index_i = 0
    index_j = 1
    variable = b_strain_xy
  [../]
[]

[Constraints]
  [./dispx_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_x
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  [../]
  [./dispy_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_y
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./topx]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_x
    function = '0.03*t'
  [../]
  [./topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = '0.03*t'
  [../]
[]

[Materials]
  [./elasticity_tensor_A]
    type = ComputeIsotropicElasticityTensor
    base_name = A
    youngs_modulus = 1e9
    poissons_ratio = 0.3
  [../]
  [./strain_A]
    type = ComputeSmallStrain
    base_name = A
  [../]
  [./stress_A]
    type = ComputeLinearElasticStress
    base_name = A
  [../]
  [./elasticity_tensor_B]
    type = ComputeIsotropicElasticityTensor
    base_name = B
    youngs_modulus = 1e5
    poissons_ratio = 0.3
  [../]
  [./strain_B]
    type = ComputeSmallStrain
    base_name = B
  [../]
  [./stress_B]
    type = ComputeLinearElasticStress
    base_name = B
  [../]
  [./combined_stress]
    type = LevelSetBiMaterialRankTwo
    levelset_positive_base = 'A'
    levelset_negative_base = 'B'
    level_set_var = ls
    prop_name = stress
  [../]
  [./combined_dstressdstrain]
    type = LevelSetBiMaterialRankFour
    levelset_positive_base = 'A'
    levelset_negative_base = 'B'
    level_set_var = ls
    prop_name = Jacobian_mult
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

# controls for linear iterations
  l_max_its = 20
  l_tol = 1e-3

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-7

# time control
  start_time = 0.0
  dt = 0.5
  end_time = 1.0
  num_steps = 2

  max_xfem_update = 1
[]

[Outputs]
  exodus = true
  execute_on = timestep_end
  csv = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/peridynamics/test/tests/jacobian_check/2D_thermomechanics_BPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./temp]
    initial_condition = 0.5
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = BOND
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConductionBPD
    variable = temp
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.33
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialBPD
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
  [../]

  [./thermal]
    type = ThermalConstantHorizonMaterialBPD
    thermal_conductivity = 1.0
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1
[]

modules/combined/test/tests/contact_verification/patch_tests/plane_3/plane3_mu_0_2_pen.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane3_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-7
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = plane3_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = plane3_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x11 disp_y11 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/ad_elastic/rz_incremental_small_elastic-noad.i

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 3
  ny = 3
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = StressDivergenceRZTensors
    component = 0
    variable = disp_r
  [../]
  [./stress_z]
    type = StressDivergenceRZTensors
    component = 1
    variable = disp_z
  [../]
[]

[BCs]
  [./bottom]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0
  [../]
  [./axial]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
  [./strain]
    type = ComputeAxisymmetricRZIncrementalStrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = rz_incremental_small_elastic_out
[]

modules/tensor_mechanics/tutorials/basics/part_2.3.i

#Tensor Mechanics tutorial: the basics
#Step 2, part 3
#2D axisymmetric RZ simulation of uniaxial tension with J2 plasticity with no
#hardening

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = necking_quad4.e
  uniform_refine = 0
  second_order = true
[]

[Modules/TensorMechanics/Master]
  [./block1]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_yy strain_yy' #use the yy option to get the zz component in axisymmetric coords
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeMultiPlasticityStress
    ep_plastic_tolerance = 1e-9
    plastic_models = J2
  [../]
[]

[UserObjects]
  [./str]
    type = TensorMechanicsHardeningConstant
    value = 2.4e2
  [../]
  [./J2]
    type = TensorMechanicsPlasticJ2
    yield_strength = str
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]
  [./top]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = top
    function = '0.0007*t'
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.25
  end_time = 20

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -sub_pc_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm lu 1 101'
[]

[Postprocessors]
  [./ave_stress_bottom]
    type = SideAverageValue
    variable = stress_yy
    boundary = bottom
  [../]
  [./ave_strain_bottom]
    type = SideAverageValue
    variable = strain_yy
    boundary = bottom
  [../]
[]

[Outputs]
  exodus = true
  perf_graph = true
  csv = true
  print_linear_residuals = false
[]

modules/tensor_mechanics/test/tests/ad_1D_spherical/finiteStrain_1DSphere_hollow.i

# This simulation models the mechanics solution for a hollow sphere under
# pressure, applied on the outer surfaces, using 1D spherical symmetry
# assumpitions.  The inner radius of the sphere, r = 4mm, is pinned to prevent
# rigid body movement of the sphere.
#
# From Bower (Applied Mechanics of Solids, 2008, available online at
# solidmechanics.org/text/Chapter4_1/Chapter4_1.htm), and applying the outer
# pressure and pinned displacement boundary conditions set in this simulation,
# the radial displacement is given by:
#
# u(r) = \frac{P(1 + v)(1 - 2v)b^3}{E(b^3(1 + v) + 2a^3(1-2v))} * (\frac{a^3}{r^2} - r)
#
# where P is the applied pressure, b is the outer radius, a is the inner radius,
# v is Poisson's ration, E is Young's Modulus, and r is the radial position.
#
# The radial stress is given by:
#
# S(r) = \frac{Pb^3}{b^3(1 + v) + 2a^3(1 - 2v)} * (\frac{2a^3}{r^3}(2v - 1) - (1 + v))
#
# The test assumes an inner radius of 4mm, and outer radius of 9 mm,
# zero displacement at r = 4mm, and an applied outer pressure of 2MPa.
# The radial stress is largest in the inner most element and, at an assumed
# mid element coordinate of 4.5mm, is equal to -2.545MPa.
[Mesh]
  type = GeneratedMesh
  dim = 1
  xmin = 4
  xmax = 9
  nx = 5
[]

[GlobalParams]
  displacements = 'disp_r'
[]

[Problem]
  coord_type = RSPHERICAL
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    use_automatic_differentiation = true
  [../]
[]

[AuxVariables]
  [./stress_rr]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Postprocessors]
  [./stress_rr]
    type = ElementAverageValue
    variable = stress_rr
  [../]
[]

[AuxKernels]
  [./stress_rr]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_rr
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./innerDisp]
    type = ADDirichletBC
    boundary = left
    variable = disp_r
    value = 0.0
  [../]
  [./outerPressure]
    type = ADPressure
    boundary = right
    variable = disp_r
    component = 0
    constant = 2
  [../]
[]

[Materials]
  [./Elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.345
    youngs_modulus = 1e4
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none


# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-8

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-5

# time control
  start_time = 0.0
  dt = 0.25
  dtmin = 0.0001
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update5.i

# MC update version, with only Tensile with tensile strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.
# Returns to close to the tip of the yield function.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0.5
    internal_limit = 2E-2
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '15 1 0.2  1 10 -0.3  -0.3 0.2 8'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/ad_viscoplasticity_stress_update/creep.i

# This test is provided as a check to ensure ADComputeMultiplePorousInelasticStress

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 2
  xmax = 0.002
  ymax = 0.002
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  add_variables = true
  base_name = 'total'
  generate_output = 'strain_xx strain_yy strain_xy hydrostatic_stress vonmises_stress'
  use_automatic_differentiation = true
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x = '0 0.1'
    y = '0 1e-5'
  [../]
[]

[Materials]
  active='elasticity_tensor porous_stress creep'
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.3
    base_name = 'total'
  [../]
  [./porous_stress]
    type = ADComputeMultiplePorousInelasticStress
    inelastic_models = creep
    initial_porosity = 0.1
    outputs = all
    base_name = 'total'
  [../]
  [./regular_stress]
    type = ADComputeMultipleInelasticStress
    inelastic_models = creep
    outputs = all
    base_name = 'total'
  [../]
  [./porosity]
    type = GenericConstantMaterial
    prop_names = porosity
    prop_values = 0.1
    outputs = all
  [../]
  [./creep]
    type = ADPowerLawCreepStressUpdate
    activation_energy = 4e4
    temperature = 1200
    coefficient = 1e-18
    gas_constant = 1.987
    n_exponent = 3
    base_name = 'creep'
    outputs = all
  [../]
[]

[BCs]
  [./no_disp_x]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./no_disp_y]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./pull_disp_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = top
    function = pull
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  dt = 0.01
  end_time = 0.12
[]

[Postprocessors]
  [./disp_x]
    type = SideAverageValue
    variable = disp_x
    boundary = right
  [../]
  [./disp_y]
    type = SideAverageValue
    variable = disp_y
    boundary = top
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = total_hydrostatic_stress
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = total_vonmises_stress
  [../]
  [./dt]
    type = TimestepSize
  [../]
  [./num_lin]
    type = NumLinearIterations
    outputs = console
  [../]
  [./num_nonlin]
    type = NumNonlinearIterations
    outputs = console
  [../]
  [./eff_creep_strain]
    type = ElementAverageValue
    variable = creep_effective_creep_strain
  [../]
  [./porosity]
    type = ElementAverageValue
    variable = porosity
  [../]
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/nodal_area/nodal_area_Hex20_3.i

[Mesh]
  file = nodal_area_Hex20.e
[]

[GlobalParams]
  order = SECOND
  displacements = 'displ_x displ_y displ_z'
[]

[Functions]
  [./disp]
    type = PiecewiseLinear
    x = '0     1'
    y = '0  20e-6'
  [../]
[]

[Variables]
  [./displ_x]
  [../]
  [./displ_y]
  [../]
  [./displ_z]
  [../]
[]

[AuxVariables]
  [./react_x]
  [../]
  [./react_y]
  [../]
  [./react_z]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    incremental = true
    save_in = 'react_x react_y react_z'
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx'
  [../]
[]

[BCs]
  [./move_right]
    type = FunctionDirichletBC
    boundary = '1'
    variable = displ_x
    function = disp
  [../]

  [./fixed_x]
    type = DirichletBC
    boundary = '3 4'
    variable = displ_x
    value = 0
  [../]

  [./fixed_y]
    type = DirichletBC
    boundary = 10
    variable = displ_y
    value = 0
  [../]

  [./fixed_z]
    type = DirichletBC
    boundary = 11
    variable = displ_z
    value = 0
  [../]
[]

[Contact]
  [./dummy_name]
    master = 3
    slave = 2
    formulation = penalty
    penalty = 1e9
    tangential_tolerance = 1e-5
    system = Constraint
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'
  nl_rel_tol = 1e-7
  l_tol = 1e-4
  l_max_its = 40
  nl_max_its = 10

  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 1.0

  [./Quadrature]
    order = THIRD
  [../]
[]

[Postprocessors]
  [./react_x]
    type = NodalSum
    variable = react_x
    boundary = 1
  [../]
  [./total_area]
    type = NodalSum
    variable = nodal_area_dummy_name
    boundary = 2
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_viscoplasticity_stress_update/lps_dual.i

# This test provides an example of combining two LPS viscoplasticity models with different stress
# exponents.

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 1
  ny = 1
  xmax = 0.002
  ymax = 0.002
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  add_variables = true
  generate_output = 'strain_xx strain_yy strain_xy hydrostatic_stress vonmises_stress'
  use_automatic_differentiation = true
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x = '0 0.1'
    y = '0 1e-5'
  [../]
  [./tot_effective_viscoplasticity]
    type = ParsedFunction
    vals = 'lps_1_eff_creep_strain lps_3_eff_creep_strain'
    vars = 'lps_1_eff_creep_strain lps_3_eff_creep_strain'
    value = 'lps_1_eff_creep_strain+lps_3_eff_creep_strain'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ADComputeMultiplePorousInelasticStress
    inelastic_models = 'one two'
    initial_porosity = 0.1
    outputs = all
  [../]

  [./one]
    type = ADViscoplasticityStressUpdate
    coefficient = 'coef_3'
    power = 3
    base_name = 'lps_1'
    outputs = all
    relative_tolerance = 1e-11
  [../]
  [./two]
    type = ADViscoplasticityStressUpdate
    coefficient = 1e-10
    power = 1
    base_name = 'lps_3'
    outputs = all
    relative_tolerance = 1e-11
  [../]
  [./coef]
    type = ParsedMaterial
    f_name = coef_3
    # Example of creep power law
    function = '0.5e-18 * exp(-4e4 / 1.987 / 1200)'
  [../]
[]

[BCs]
  [./no_disp_x]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./no_disp_y]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./pull_disp_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = top
    function = pull
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  dt = 0.01
  end_time = 0.12
[]

[Postprocessors]
  [./disp_x]
    type = SideAverageValue
    variable = disp_x
    boundary = right
  [../]
  [./disp_y]
    type = SideAverageValue
    variable = disp_y
    boundary = top
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
  [../]
  [./dt]
    type = TimestepSize
  [../]
  [./num_lin]
    type = NumLinearIterations
    outputs = console
  [../]
  [./num_nonlin]
    type = NumNonlinearIterations
    outputs = console
  [../]
  [./lps_1_eff_creep_strain]
    type = ElementAverageValue
    variable = lps_1_effective_viscoplasticity
  [../]
  [./lps_3_eff_creep_strain]
    type = ElementAverageValue
    variable = lps_3_effective_viscoplasticity
  [../]
  [./lps_1_gauge_stress]
    type = ElementAverageValue
    variable = lps_1_gauge_stress
  [../]
  [./lps_3_gauge_stress]
    type = ElementAverageValue
    variable = lps_3_gauge_stress
  [../]
  [./eff_creep_strain_tot]
    type = FunctionValuePostprocessor
    function = tot_effective_viscoplasticity
  [../]
  [./porosity]
    type = ElementAverageValue
    variable = porosity
  [../]
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/combined_plasticity_temperature/ad_plasticity_temperature_dep_yield.i

#
# This is a test of the piece-wise linear strain hardening model using the
# small strain formulation.  This test exercises the temperature-dependent
# yield stress.
#
# Test procedure:
# 1. The element is pulled to and then beyond the yield stress for a given
# temperature.
# 2. The displacement is then constant while the temperature increases and
# the yield stress decreases.  This results in a lower stress with more
# plastic strain.
# 3. The temperature decreases beyond its original value giving a higher
# yield stress.  The displacement increases, causing increases stress to
# the new yield stress.
# 4. The temperature and yield stress are constant with increasing
# displacement giving a constant stress and more plastic strain.
#
# Plotting total_strain_yy on the x axis and stress_yy on the y axis shows
# the stress history in a clear way.
#
#  s |
#  t |            *****
#  r |           *
#  e |   *****  *
#  s |  *    * *
#  s | *     *
#    |*
#    +------------------
#           total strain
#

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy plastic_strain_xx plastic_strain_yy plastic_strain_zz'
    use_automatic_differentiation = true
  [../]
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1     2    4    5    6'
    y = '0 0.025 0.05 0.05 0.06 0.085'
  [../]
  [./yield]
    type = PiecewiseLinear
    x = '400 500 600'
    y = '6e3 5e3 4e3'
  [../]
  [./temp]
    type = PiecewiseLinear
    x = '0   1   2   3   4'
    y = '500 500 500 600 400'
  [../]
[]

[Kernels]
  [./heat]
    type = ADHeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = top_pull
  [../]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp]
    type = FunctionDirichletBC
    variable = temp
    function = temp
    boundary = left
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 2.0e5
    poissons_ratio = 0.3
  [../]
  [./creep_plas]
    type = ADComputeMultipleInelasticStress
    block = 0
    inelastic_models = 'plasticity'
    max_iterations = 50
    absolute_tolerance = 1e-05
  [../]
  [./plasticity]
    type = ADIsotropicPlasticityStressUpdate
    block = 0
    hardening_constant = 0
    yield_stress_function = yield
    temperature = temp
  [../]
  [./heat_conduction]
    type = HeatConductionMaterial
    block = 0
    specific_heat = 1
    thermal_conductivity = 1
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  end_time = 6
  dt = 0.1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/capped_mohr_coulomb/small_deform_hard22.i

# Mohr-Coulomb only
# apply stretches in x direction and smaller stretches in the y direction
# to observe return to the MC plane
# This tests uses hardening of the friction and dilation angles.  The returned configuration
# should obey
# 0 = 0.5 * (Smax - Smin) + 0.5 * (Smax + Smin) * sin(phi) - C cos(phi)
# which allows inference of phi.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress'
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0.4E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.17E-6*y*t'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl_tensile]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 6
    property = plastic_yield_function
    variable = yield_fcn
  [../]
  [./iter_auxk]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./intnl_auxk]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 0
    variable = intnl
  [../]
  [./intnl_tensile]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 1
    variable = intnl_tensile
  [../]
[]

[Postprocessors]
  [./s_max]
    type = PointValue
    point = '0 0 0'
    variable = max_principal_stress
  [../]
  [./s_mid]
    type = PointValue
    point = '0 0 0'
    variable = mid_principal_stress
  [../]
  [./s_min]
    type = PointValue
    point = '0 0 0'
    variable = min_principal_stress
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
  [./intnl]
    type = PointValue
    point = '0 0 0'
    variable = intnl
  [../]
  [./intnl_tensile]
    type = PointValue
    point = '0 0 0'
    variable = intnl_tensile
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningCubic
    value_residual = 0.524 # 30deg
    value_0 = 0.174 # 10deg
    internal_limit = 4E-6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1E7
    poissons_ratio = 0.0
  [../]
  [./mc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = ts
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_phi
    smoothing_tol = 0
    yield_function_tol = 1.0E-9
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    perform_finite_strain_rotations = false
  [../]
[]


[Executioner]
  end_time = 9
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform_hard22
  csv = true
[]

modules/tensor_mechanics/test/tests/thermal_expansion_function/small_linear.i

# This tests the thermal expansion coefficient function using both
# options to specify that function: mean and instantaneous.  There
# two blocks, each containing a single element, and these use the
# two variants of the function.

# In this test, the instantaneous CTE function is a linear function
# while the mean CTE function is an analytic function designed to
# give the same response.  If \bar{alpha}(T) is the mean CTE function,
# and \alpha(T) is the instantaneous CTE function,

# \bar{\alpha}(T) = 1/(T-Tref) \intA^{T}_{Tsf} \alpha(T) dT

# where Tref is the reference temperature used to define the mean CTE
# function, and Tsf is the stress-free temperature.

# This version of the test uses small deformation theory.  The results
# from the two models are identical.

[Mesh]
  file = 'blocks.e'
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    block = '1 2'
    function = temp_func
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeLinearElasticStress
  [../]
  [./thermal_expansion_strain1]
    type = ComputeMeanThermalExpansionFunctionEigenstrain
    block = 1
    thermal_expansion_function = cte_func_mean
    thermal_expansion_function_reference_temperature = 0.5
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
  [./thermal_expansion_strain2]
    type = ComputeInstantaneousThermalExpansionFunctionEigenstrain
    block = 2
    thermal_expansion_function = cte_func_inst
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_func_mean]
    type = ParsedFunction
    vars = 'tsf tref scale' #stress free temp, reference temp, scale factor
    vals = '0.0 0.5  1e-4'
    value = 'scale * (0.5 * t^2 - 0.5 * tsf^2) / (t - tref)'
  [../]
  [./cte_func_inst]
    type = PiecewiseLinear
    xy_data = '0 0.0
               2 2.0'
    scale_factor = 1e-4
  [../]

  [./temp_func]
    type = PiecewiseLinear
    xy_data = '0 1
               1 2'
  [../]
[]

[Postprocessors]
  [./disp_1]
    type = NodalMaxValue
    variable = disp_x
    boundary = 101
  [../]

  [./disp_2]
    type = NodalMaxValue
    variable = disp_x
    boundary = 102
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  l_max_its = 100
  l_tol = 1e-4
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/tensor_mechanics/test/tests/generalized_plane_strain/generalized_plane_strain_ref_resid.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = square.e
[]

[Problem]
  type = ReferenceResidualProblem
  reference_vector = 'ref'
  extra_tag_vectors = 'ref'
  group_variables = 'disp_x disp_y'
[]

[Variables]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy strain_zz'
    planar_formulation = GENERALIZED_PLANE_STRAIN
    eigenstrain_names = eigenstrain
    scalar_out_of_plane_strain = scalar_strain_zz
    temperature = temp
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
  [./saved_x]
    type = TagVectorAux
    variable = 'saved_x'
    vector_tag = 'ref'
    v = 'disp_x'
    execute_on = timestep_end
  [../]
  [./saved_y]
    type = TagVectorAux
    variable = 'saved_y'
    vector_tag = 'ref'
    execute_on = timestep_end
    v = 'disp_y'
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-4

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-5

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
  num_steps = 5000
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/jacobian_damper/cube_load.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  displacements = 'disp_x disp_y disp_z'
  # This test uses ElementalVariableValue postprocessors on specific
  # elements, so element numbering needs to stay unchanged
  allow_renumbering = false
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./total_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1     2'
    y = '0 0.025 0.05'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]

  [./total_strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = total_strain_yy
    index_i = 1
    index_j = 1
  [../]
[]


[BCs]
  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 3
    function = top_pull
  [../]

  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]

  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = 0
    value = 0.0
  [../]
[]

[Postprocessors]
  [./stress_yy_el]
    type = ElementalVariableValue
    variable = stress_yy
    elementid = 0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 2e5
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Dampers]
  [./disp_x_damp]
    type = ElementJacobianDamper
    max_increment = 0.002
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  end_time = 2
  dt = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/capped_mohr_coulomb/small_deform_hard21.i

# Mohr-Coulomb only
# apply stretches in x direction and smaller stretches in the y direction
# to observe return to the MC plane
# This tests uses hardening of the cohesion.  The returned configuration
# should obey
# 0 = 0.5 * (Smax - Smin) + 0.5 * (Smax + Smin) * sin(phi) - C cos(phi)
# which allows inference of C.
# The tensile internal parameter is recorded, to check that it is zero

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz'
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0.4E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.1E-6*y*t'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl_tensile]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 6
    property = plastic_yield_function
    variable = yield_fcn
  [../]
  [./iter_auxk]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./intnl_auxk]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 0
    variable = intnl
  [../]
  [./intnl_tensile]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 1
    variable = intnl_tensile
  [../]
[]

[Postprocessors]
  [./s_max]
    type = PointValue
    point = '0 0 0'
    variable = max_principal_stress
  [../]
  [./s_mid]
    type = PointValue
    point = '0 0 0'
    variable = mid_principal_stress
  [../]
  [./s_min]
    type = PointValue
    point = '0 0 0'
    variable = min_principal_stress
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
  [./intnl]
    type = PointValue
    point = '0 0 0'
    variable = intnl
  [../]
  [./intnl_tensile]
    type = PointValue
    point = '0 0 0'
    variable = intnl_tensile
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningCubic
    value_0 = 10
    value_residual = 20
    internal_limit = 5E-6
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1E7
    poissons_ratio = 0.3
  [../]
  [./mc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = ts
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    smoothing_tol = 0
    yield_function_tol = 1.0E-9
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    perform_finite_strain_rotations = false
  [../]
[]


[Executioner]
  end_time = 10
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform_hard21
  csv = true
[]

modules/tensor_mechanics/test/tests/torque_reaction/disp_about_axis_axial_motion.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[GlobalParams]
  volumetric_locking_correction=true
[]

[AuxVariables]
  [./stress_xx]      # stress aux variables are defined for output; this is a way to get integration point variables to the output file
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]


[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 1.
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./vonmises]
    type =  RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = VonMisesStress
    execute_on = timestep_end
  [../]
[]

[BCs]

  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = bottom
    value = 0.0
  [../]

  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]

  [./top_x]
    type = DisplacementAboutAxis
    boundary = top
    function = rampConstant
    angle_units = degrees
    axis_origin = '0. 0. 0.'
    axis_direction = '0. 0. 1.'
    component = 0
    variable = disp_x
  [../]

  [./top_y]
    type = DisplacementAboutAxis
    boundary = top
    function = rampConstant
    angle_units = degrees
    axis_origin = '0. 0. 0.'
    axis_direction = '0. 0. 1.'
    component = 1
    variable = disp_y
  [../]

# Because want to keep the rotation fixed about the z axis,
# do not apply a DisplacementAboutAxis BC on the disp_z
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]


[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 30
  nl_max_its = 20
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-12
  l_tol = 1e-8

  start_time = 0.0
  dt = 0.1
  dtmin = 0.1 # die instead of cutting the timestep

  end_time = 0.5
[]

[Postprocessors]
  [./_dt]
    type = TimestepSize
  [../]
[]


[Outputs]
  file_base = disp_about_axis_axial_motion_out
  exodus = true
[]

modules/combined/test/tests/mortar_tm/2d/frictionless_second/finite.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'finite'

[Mesh]
  patch_size = 80
  patch_update_strategy = iteration
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    preset = false
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
  l_max_its = 30
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/combined/test/tests/mortar_tm/2drz/frictionless_second/small.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'small'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./corner]
    type = ExtraNodesetGenerator
    input = block_rename
    coord = '0 -10.0'
    new_boundary = point
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = corner
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
  [../]
  [./plank]
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeLinearElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/tutorials/basics/part_1.2.i

#Tensor Mechanics tutorial: the basics
#Step 1, part 2
#2D simulation of uniaxial tension with linear elasticity with visualized stress

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = necking_quad4.e
  uniform_refine = 1
[]

[Modules/TensorMechanics/Master]
  [./block1]
    strain = SMALL
    add_variables = true
    generate_output = 'stress_xx vonmises_stress' #automatically creates the auxvariables and auxkernels
                                                  #needed to output these stress quanities
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.0035
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady

  solve_type = 'NEWTON'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -sub_pc_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm lu 1 101'
[]

[Outputs]
  exodus = true
  perf_graph = true
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update1.i

# MC update version, with only Tensile with tensile strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Return to the stress_I = 1 plane

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2 0 0  0 0 0  0 0 -2'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/simple_contact/simple_contact_test.i

# Note: Run merged.i to generate a solution to compare to that doesn't use contact.

[Mesh]
  file = contact.e
  # PETSc < 3.5.0 requires the iteration patch_update_strategy to
  # avoid PenetrationLocator warnings, which are currently treated as
  # errors by the TestHarness.
  patch_update_strategy = 'iteration'
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx'
  [../]
[]

[Contact]
  [./dummy_name]
    master = 3
    slave = 2
    penalty = 1e5
    formulation = kinematic
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./left_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.0001
  [../]

  [./right_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]

  [./right_z]
    type = DirichletBC
    variable = disp_z
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]


[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre    boomeramg      101'

  line_search = 'none'

  nl_abs_tol = 1e-8

  l_max_its = 100
  nl_max_its = 10
  dt = 1.0
  num_steps = 1
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/combined/test/tests/simplest_contact/simplest_contact_test.i

[Mesh]
  file = simplest_contact.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  []
[]

[AuxKernels]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 2
    paired_boundary = 3
  [../]
[]

[Constraints]
  [./contact_x]
    type = MultiDContactConstraint
    variable = disp_x
    master_variable = disp_x
    component = 0
    slave = 2
    master = 3
    penalty = 1e6
  [../]

  [./contact_y]
    type = MultiDContactConstraint
    variable = disp_y
    master_variable = disp_y
    component = 1
    slave = 2
    master = 3
    penalty = 1e6
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.0001
  [../]

  [./right_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
[] # BCs

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
[]  # Materials

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre    boomeramg      101'


  line_search = 'none'
  nl_abs_tol = 1e-8

  l_max_its = 100
  nl_max_its = 10
  dt = 1.0
  num_steps = 1
[] # Executioner

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[] # Output

modules/xfem/test/tests/solid_mechanics_basic/square_branch_tri_2d.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 10
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = TRI3
[]

[UserObjects]
  [./line_seg_cut_uo0]
    type = LineSegmentCutUserObject
    cut_data = '-1.0000e-10   6.6340e-01   6.6340e-01  -1.0000e-10'
    time_start_cut = 0.0
    time_end_cut = 1.0
  [../]
  [./line_seg_cut_uo1]
    type = LineSegmentCutUserObject
    cut_data = '3.3120e-01   3.3200e-01   1.0001e+00   3.3200e-01'
    time_start_cut = 1.0
    time_end_cut = 2.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    planar_formulation = PLANE_STRAIN
    add_variables = true
  [../]
[]

[Functions]
  [./right_disp_x]
    type = PiecewiseLinear
    x = '0  1.0    2.0   3.0'
    y = '0  0.005  0.01  0.01'
  [../]
  [./top_disp_y]
    type = PiecewiseLinear
    x = '0  1.0    2.0   3.0'
    y = '0  0.005  0.01  0.01'
  [../]
[]

[BCs]
  [./right_x]
    type = FunctionDirichletBC
    boundary = 1
    variable = disp_x
    function = right_disp_x
  [../]
  [./top_y]
    type = FunctionDirichletBC
    boundary = 2
    variable = disp_y
    function = top_disp_y
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 0
    variable = disp_y
    value = 0.0
  [../]
  [./left_x]
    type = DirichletBC
    boundary = 3
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-16
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 2.2
  num_steps = 5000
[]

[Outputs]
  file_base = square_branch_tri_2d_out
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/combined/test/tests/generalized_plane_strain_tm_contact/out_of_plane_pressure.i

# Tests for application of out-of-plane pressure in generalized plane strain.

[Mesh]
  type = GeneratedMesh
  nx = 2
  ny = 2
  dim = 2
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./saved_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_zz]
    order = FIRST
    family = SCALAR
  [../]

  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./GeneralizedPlaneStrain]
      [./gps]
        displacements = 'disp_x disp_y'
        scalar_out_of_plane_strain = scalar_strain_zz
        out_of_plane_pressure = traction_function
        factor = 1e5
      [../]
    [../]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    displacements = 'disp_x disp_y'
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxScalarKernels]
  [./gps_ref_res]
    type = GeneralizedPlaneStrainReferenceResidual
    variable = saved_zz
    generalized_plane_strain = gps_GeneralizedPlaneStrainUserObject
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]

  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_xy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xy
    index_i = 0
    index_j = 1
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Functions]
  [./traction_function]
    type = PiecewiseLinear
    x = '0  2'
    y = '0  1'
  [../]
[]

[BCs]
  [./leftx]
    type = DirichletBC
    boundary = left
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./strain]
    type = ComputePlaneSmallStrain
    displacements = 'disp_x disp_y'
    scalar_out_of_plane_strain = scalar_strain_zz
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-4

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-11

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
  num_steps = 5000
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_1/ring1_template2.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring1_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-8
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x7 disp_y7 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/tensor_mechanics/test/tests/1D_spherical/smallStrain_1DSphere.i

# This simulation models the mechanics solution for a solid sphere under
# pressure, applied on the outer surfaces, using 1D spherical symmetry
# assumpitions.  The inner center of the sphere, r = 0, is pinned to prevent
# movement of the sphere.
#
# From Bower (Applied Mechanics of Solids, 2008, available online at
# solidmechanics.org/text/Chapter4_1/Chapter4_1.htm), and applying the outer
# pressure and pinned displacement boundary conditions set in this simulation,
# the radial displacement is given by:
#
# u(r) = \frac{- P * (1 - 2 * v) * r}{E}
#
# where P is the applied pressure, v is Poisson's ration, E is Young's Modulus,
# and r is the radial position.
#
# The test assumes a radius of 4, zero displacement at r = 0mm, and an applied
# outer pressure of 1MPa.  Under these conditions in a solid sphere, the radial
# stress is constant and has a value of -1 MPa.
[Mesh]
  type = GeneratedMesh
  dim = 1
  xmin = 0
  xmax = 4
  nx = 4
[]

[GlobalParams]
  displacements = 'disp_r'
[]

[Problem]
  coord_type = RSPHERICAL
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    save_in = residual_r
  [../]
[]

[AuxVariables]
  [./stress_rr]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./residual_r]
  [../]
[]

[Postprocessors]
  [./stress_rr]
    type = ElementAverageValue
    variable = stress_rr
  [../]
  [./residual_r]
    type = NodalSum
    variable = residual_r
    boundary = right
  [../]
[]

[AuxKernels]
  [./stress_rr]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_rr
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./innerDisp]
    type = DirichletBC
    boundary = left
    variable = disp_r
    value = 0.0
  [../]
  [./outerPressure]
    type = Pressure
    boundary = right
    variable = disp_r
    component = 0
    factor = 1
  [../]
[]

[Materials]
  [./Elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.345
    youngs_modulus = 1e4
  [../]
  [./stress]
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-8

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-5

# time control
  start_time = 0.0
  dt = 0.25
  dtmin = 0.0001
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/strain_energy_density/tot_model.i

# Single element test to check the strain energy density calculation

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 1
  ny = 1
  xmin = 0
  xmax = 1
  ymin = 0
  ymax = 2
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstantUp]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -100
  [../]
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = SMALL
    add_variables = true
    incremental = false
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress strain_xx strain_yy strain_zz'
    planar_formulation = PLANE_STRAIN
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0.0
  [../]
  [./Pressure]
    [./top]
      boundary = 'top'
      function = rampConstantUp
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 30e+6
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeLinearElasticStress
  [../]
  [./strain_energy_density]
    type = StrainEnergyDensity
    incremental = false
  [../]
[]

[Executioner]
   type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 20
   nl_abs_tol = 3e-7
   nl_rel_tol = 1e-12
   l_tol = 1e-2

   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1
[]

[Postprocessors]
  [./epxx]
    type = ElementalVariableValue
    variable = strain_xx
    elementid = 0
  [../]
  [./epyy]
    type = ElementalVariableValue
    variable = strain_yy
    elementid = 0
  [../]
  [./epzz]
    type = ElementalVariableValue
    variable = strain_zz
    elementid = 0
  [../]
  [./sigxx]
    type = ElementAverageValue
    variable = stress_xx
  [../]
  [./sigyy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigzz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./SED]
    type = ElementAverageValue
    variable = SED
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/2D_geometries/planestrain.i

# This test uses the strain calculator ComputePlaneSmallStrain,
# which is generated through the use of the TensorMechanics MasterAction.

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = square.e
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    planar_formulation = PLANE_STRAIN
    add_variables = true
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy strain_zz'
  [../]
[]

[Functions]
  [./pull]
    type = ParsedFunction
    value ='0.01 * t'
  [../]
[]

[BCs]
  [./leftx]
    type = DirichletBC
    boundary = 2
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
  [./pull]
    type = FunctionDirichletBC
    boundary = 3
    variable = disp_y
    function = pull
  [../]
[]

[Materials]
  [./linear_stress]
    type = ComputeLinearElasticStress
    block = 1
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  l_max_its = 100
  l_tol = 1e-10
  nl_max_its = 15
  nl_rel_tol = 1e-12

  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 5.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update21.i

# MC update version, with only MohrCoulomb, cohesion=10, friction angle = 60, psi = 5, smoothing_tol = 1
# Lame lambda = 0.5.  Lame mu = 1

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./phi]
    type = TensorMechanicsHardeningConstant
    value = 60
    convert_to_radians = true
  [../]
  [./psi]
    type = TensorMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 0.5
    shear_modulus = 1.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '3 0 0  0 3 0  0 0 1.5'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = phi
    dilation_angle = psi
    smoothing_tol = 1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/xfem/test/tests/pressure_bc/2d_pressure_displaced_mesh.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 4
  ny = 5
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '0.0 0.5 1.0 0.5'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    planar_formulation = PLANE_STRAIN
    generate_output = 'stress_xx stress_yy'
  [../]
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0 1.0'
    y = '500 500'
  [../]
  [./bc_func_tx]
    type = ParsedFunction
    value = '0.5-(0.5-x)*cos(pi*t/2.0)-x'
  [../]
  [./bc_func_ty]
    type = ParsedFunction
    value = '(0.5-x)*sin(pi*t/2.0)+0.5'
  [../]
[]

[BCs]
  [./bottom_y]
    type = DirichletBC
    boundary = 0
    preset = false
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = 0
    preset = false
    variable = disp_x
    value = 0.0
  [../]
  [./top_right_y]
    type = FunctionDirichletBC
    boundary = 2
    preset = false
    variable = disp_y
    function = bc_func_ty
  [../]
  [./top_right_x]
    type = FunctionDirichletBC
    boundary = 2
    preset = false
    variable = disp_x
    function = bc_func_tx
  [../]
[]

[DiracKernels]
  [./pressure_x]
    type = XFEMPressure
    variable = disp_x
    component = 0
    function = pressure
    use_displaced_mesh = true
  [../]
  [./pressure_y]
    type = XFEMPressure
    variable = disp_y
    component = 1
    function = pressure
    use_displaced_mesh = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-14

# time control
  start_time = 0.0
  dt = 0.1
  end_time = 1.0
[]

[Outputs]
  file_base = 2d_pressure_displaced_mesh_out
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/check_error/num_constants.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = cube.e
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./2_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./2_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./2_z]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 1e6
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[]

[Outputs]
  file_base = out
  exodus = true
[]

modules/combined/test/tests/sliding_block/sliding/constraint/frictional_02_penalty.i

#  This is a benchmark test that checks constraint based frictional
#  contact using the penalty method.  In this test a constant
#  displacement is applied in the horizontal direction to simulate
#  a small block come sliding down a larger block.
#
#  A friction coefficient of 0.2 is used.  The gold file is run on one processor
#  and the benchmark case is run on a minimum of 4 processors to ensure no
#  parallel variability in the contact pressure and penetration results.
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]


[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 15
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-6
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = coulomb
    penalty = 1e+7
    friction_coefficient = 0.2
    formulation = penalty
    system = constraint
    normal_smoothing_distance = 0.1
  [../]
[]

modules/tensor_mechanics/test/tests/material_limit_time_step/mult_inelastic/no_inelastic_model_timestep_limit.i

# This is a basic test of the material time step computed by the
# ComputeMultipleInelasticStress model. If no inelastic models
# are defined, the material time step should be the maximum
# value representable by a real number.

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  elem_type = HEX8
[]

[AuxVariables]
  [damage_index]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Modules/TensorMechanics/Master]
  [all]
    strain = SMALL
    incremental = true
    add_variables = true
    generate_output = 'stress_xx strain_xx'
  []
[]

[BCs]
  [symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  []
  [symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  []
  [symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  []
  [axial_load]
    type = DirichletBC
    variable = disp_x
    boundary = right
    value = 0.01
  []
[]

[Materials]
  [stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = ''
  []
  [elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.2
    youngs_modulus = 10e9
  []
[]

[Postprocessors]
  [stress_xx]
    type = ElementAverageValue
    variable = stress_xx
  []
  [strain_xx]
    type = ElementAverageValue
    variable = strain_xx
  []
  [time_step_limit]
    type = MaterialTimeStepPostprocessor
  []
[]

[Executioner]
  type = Transient

  l_max_its  = 50
  l_tol      = 1e-8
  nl_max_its = 20
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-8

  dt = 0.1
  dtmin = 0.001
  end_time = 1.1
  [TimeStepper]
    type = IterationAdaptiveDT
    dt = 0.1
    growth_factor = 2.0
    cutback_factor = 0.5
    timestep_limiting_postprocessor = time_step_limit
  []
[]

[Outputs]
  csv=true
[]

modules/tensor_mechanics/test/tests/scalar_material_damage/combined_scalar_damage.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  elem_type = HEX8
[]

[AuxVariables]
  [damage_index]
    order = CONSTANT
    family = MONOMIAL
  []
  [damage_index_a]
    order = CONSTANT
    family = MONOMIAL
  []
  [damage_index_b]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Modules/TensorMechanics/Master]
  [all]
    strain = SMALL
    incremental = true
    add_variables = true
    generate_output = 'stress_xx strain_xx'
  []
[]

[AuxKernels]
  [damage_index]
    type = MaterialRealAux
    variable = damage_index
    property = damage_index
    execute_on = timestep_end
  []
  [damage_index_a]
    type = MaterialRealAux
    variable = damage_index_a
    property = damage_index_a
    execute_on = timestep_end
  []
  [damage_index_b]
    type = MaterialRealAux
    variable = damage_index_b
    property = damage_index_b
    execute_on = timestep_end
  []
[]

[BCs]
  [symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  []
  [symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  []
  [symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  []
  [axial_load]
    type = DirichletBC
    variable = disp_x
    boundary = right
    value = 0.01
  []
[]

[Functions]
  [damage_evolution_a]
    type = PiecewiseLinear
    xy_data = '0.0   0.0
               0.1   0.0
               2.1   2.0'
  []
  [damage_evolution_b]
    type = PiecewiseLinear
    xy_data = '0.0   0.2
               0.1   0.2
               2.1   0.7'
  []
[]

[Materials]
  [damage_index_a]
    type = GenericFunctionMaterial
    prop_names = damage_index_prop_a
    prop_values = damage_evolution_a
  []
  [damage_index_b]
    type = GenericFunctionMaterial
    prop_names = damage_index_prop_b
    prop_values = damage_evolution_b
  []
  [damage_a]
    type = ScalarMaterialDamage
    damage_index = damage_index_prop_a
    damage_index_name = damage_index_a
  []
  [damage_b]
    type = ScalarMaterialDamage
    damage_index = damage_index_prop_b
    damage_index_name = damage_index_b
  []
  [damage]
    type = CombinedScalarDamage
    damage_models = 'damage_a damage_b'
  []
  [stress]
    type = ComputeDamageStress
    damage_model = damage
  []
  [elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.2
    youngs_modulus = 10e9
  []
[]

[Postprocessors]
  [stress_xx]
    type = ElementAverageValue
    variable = stress_xx
  []
  [strain_xx]
    type = ElementAverageValue
    variable = strain_xx
  []
  [damage_index]
    type = ElementAverageValue
    variable = damage_index
  []
  [damage_index_a]
    type = ElementAverageValue
    variable = damage_index_a
  []
  [damage_index_b]
    type = ElementAverageValue
    variable = damage_index_b
  []
[]

[Executioner]
  type = Transient

  l_max_its  = 50
  l_tol      = 1e-8
  nl_max_its = 20
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-8

  dt = 0.1
  dtmin = 0.1
  end_time = 1.1
[]

[Outputs]
  csv=true
[]

modules/tensor_mechanics/test/tests/interaction_integral/interaction_integral_2d_rot.i

#This tests the Interaction-Integral evaluation capability.
#This is a 2d nonlinear-plane strain model

[GlobalParams]
  order = FIRST
#  order = SECOND
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack2d_rot.e
  displacements = 'disp_x disp_y'
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = 'InteractionIntegralKI InteractionIntegralKII InteractionIntegralKIII'
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '0 1 0'
  2d = true
  axis_2d = 2
  radius_inner = '4.0 4.5 5.0 5.5 6.0'
  radius_outer = '4.5 5.0 5.5 6.0 6.5'
  block = 1
  youngs_modulus = 207000
  poissons_ratio = 0.3
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_x
    boundary = 100
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_y
    boundary = 700
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = interaction_integral_2d_rot_out
  exodus = true
  csv = true
[]

modules/combined/test/tests/ad_power_law_creep/power_law_creep_restart1.i

# 1x1x1 unit cube with uniform pressure on top face

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
    initial_condition = 1000.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy creep_strain_xx creep_strain_yy creep_strain_zz elastic_strain_yy'
    use_automatic_differentiation = true
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1'
  [../]
[]

[Kernels]
  [./heat]
    type = ADHeatConduction
    variable = temp
  [../]
  [./heat_ie]
    type = ADHeatConductionTimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./u_top_pull]
    type = ADPressure
    variable = disp_y
    component = 1
    boundary = top
    constant = -10.0e6
    function = top_pull
  [../]
  [./u_bottom_fix]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = ADDirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp_fix]
    type = DirichletBC
    variable = temp
    boundary = 'bottom top'
    value = 1000.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e11
    poissons_ratio = 0.3
  [../]
  [./radial_return_stress]
    type = ADComputeMultipleInelasticStress
    inelastic_models = 'power_law_creep'
  [../]
  [./power_law_creep]
    type = ADPowerLawCreepStressUpdate
    coefficient = 1.0e-15
    n_exponent = 4
    activation_energy = 3.0e5
    temperature = temp
  [../]

  [./thermal]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 100.
  [../]
  [./density]
    type = ADDensity
    density = 1.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 20
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-6
  l_tol = 1e-5
  start_time = 0.0
  end_time = 1.0
  num_steps = 6
  dt = 0.1
[]

[Outputs]
  exodus = true
  csv = true
  [./out]
    type = Checkpoint
    num_files = 1
  [../]
[]

modules/combined/test/tests/thermo_mech/thermo_mech_smp.i

[GlobalParams]
  temperature = temp
  volumetric_locking_correction = true
[]

[Mesh]
  file = cube.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]

  [./temp]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]

  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./bottom_temp]
    type = DirichletBC
    variable = temp
    boundary = 1
    value = 10.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1.0
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = eigenstrain
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 0.0
    thermal_expansion_coeff = 1e-5
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]

  [./heat]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]

  [./density]
    type = Density
    density = 1.0
    disp_x = disp_x
    disp_y = disp_y
    disp_z = disp_z
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  nl_rel_tol = 1e-14
  l_tol = 1e-3

  l_max_its = 100

  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  file_base = thermo_mech_smp_out
  [./exodus]
    type = Exodus
    execute_on = 'initial timestep_end nonlinear'
    nonlinear_residual_dt_divisor = 100
  [../]
[]

modules/tensor_mechanics/test/tests/ad_elastic/green-lagrange.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 3
  ny = 3
  nz = 4
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./stress_x]
    type = ADStressDivergenceTensors
    component = 0
    variable = disp_x
  [../]
  [./stress_y]
    type = ADStressDivergenceTensors
    component = 1
    variable = disp_y
  [../]
  [./stress_z]
    type = ADStressDivergenceTensors
    component = 2
    variable = disp_z
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = back
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = back
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.3
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.45
    youngs_modulus = 1
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeGreenLagrangeStrain
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady
  solve_type = 'NEWTON'
[]

[Outputs]
  execute_on = 'FINAL'
  exodus = true
[]

modules/xfem/test/tests/second_order_elements/square_branch_tri6_2d.i

[GlobalParams]
  order = SECOND
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 10
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = TRI6
[]

[UserObjects]
  [./line_seg_cut_set_uo]
    type = LineSegmentCutSetUserObject
    cut_data = '-1.0000e-10   6.6340e-01   6.6340e-01  -1.0000e-10  0.0  1.0
                 3.3120e-01   3.3200e-01   1.0001e+00   3.3200e-01  1.0  2.0'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
  [../]
[]

[Functions]
  [./right_disp_x]
    type = PiecewiseLinear
    x = '0  1.0    2.0   3.0'
    y = '0  0.005  0.01  0.01'
  [../]
  [./top_disp_y]
    type = PiecewiseLinear
    x = '0  1.0    2.0   3.0'
    y = '0  0.005  0.01  0.01'
  [../]
[]

[BCs]
  [./right_x]
    type = FunctionDirichletBC
    boundary = 1
    variable = disp_x
    function = right_disp_x
  [../]
  [./top_y]
    type = FunctionDirichletBC
    boundary = 2
    variable = disp_y
    function = top_disp_y
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 0
    variable = disp_y
    value = 0.0
  [../]
  [./left_x]
    type = DirichletBC
    boundary = 3
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-16
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 2.2
  num_steps = 5000
[]

[Outputs]
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/generalized_plane_strain/generalized_plane_strain_squares.i

[Mesh]
  file = 2squares.e
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./scalar_strain_zz1]
    order = FIRST
    family = SCALAR
  [../]
  [./scalar_strain_zz2]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./aux_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Postprocessors]
  [./react_z1]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    block = 1
  [../]
  [./react_z2]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    block = 2
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./GeneralizedPlaneStrain]
      [./gps1]
        use_displaced_mesh = true
        displacements = 'disp_x disp_y'
        scalar_out_of_plane_strain = scalar_strain_zz1
        block = '1'
      [../]
      [./gps2]
        use_displaced_mesh = true
        displacements = 'disp_x disp_y'
        scalar_out_of_plane_strain = scalar_strain_zz2
        block = '2'
      [../]
    [../]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = false
    displacements = 'disp_x disp_y'
    temperature = temp
    save_in = 'saved_x saved_y'
    block = '1 2'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]

  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_xy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xy
    index_i = 0
    index_j = 1
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./aux_strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = aux_strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottom1x]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottom1y]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
  [./bottom2x]
    type = DirichletBC
    boundary = 2
    variable = disp_x
    value = 0.0
  [../]
  [./bottom2y]
    type = DirichletBC
    boundary = 2
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
    block = '1 2'
  [../]
  [./strain1]
    type = ComputePlaneSmallStrain
    displacements = 'disp_x disp_y'
    scalar_out_of_plane_strain = scalar_strain_zz1
    block = 1
    eigenstrain_names = eigenstrain
  [../]
  [./strain2]
    type = ComputePlaneSmallStrain
    displacements = 'disp_x disp_y'
    scalar_out_of_plane_strain = scalar_strain_zz2
    block = 2
    eigenstrain_names = eigenstrain
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    block = '1 2'
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-10

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
  num_steps = 5000
[]

[Outputs]
  exodus = true
[]

modules/xfem/test/tests/solid_mechanics_basic/edge_crack_3d_propagation.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[XFEM]
  geometric_cut_userobjects = 'cut_mesh'
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 5
  ny = 5
  nz = 2
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  zmin = 0.0
  zmax = 0.2
  elem_type = HEX8
[]

[UserObjects]
  [./cut_mesh]
    type = MeshCut3DUserObject
    mesh_file = mesh_edge_crack.xda
    size_control = 0.1
    n_step_growth = 1
    function_x = growth_func_x
    function_y = growth_func_y
    function_z = growth_func_z
  [../]
[]

[Functions]
  [./growth_func_x]
    type = ParsedFunction
    value = 1
  [../]
  [./growth_func_y]
    type = ParsedFunction
    value = 0
  [../]
  [./growth_func_z]
    type = ParsedFunction
    value = 0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[Functions]
  [./top_trac_y]
    type = ConstantFunction
    value = 10
  [../]
[]


[BCs]
  [./top_y]
    type = FunctionNeumannBC
    boundary = top
    variable = disp_y
    function = top_trac_y
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    boundary = bottom
    variable = disp_z
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
    block = 0
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 5.0
  max_xfem_update = 1
[]

[Outputs]
  file_base = edge_crack_3d_propagation_out
  execute_on = 'timestep_end'
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/combined/test/tests/elastic_thermal_patch/elastic_thermal_jacobian_rz_smp.i

# This problem is intended to exercise the Jacobian for coupled RZ
# problems.  Only two iterations should be needed.

[GlobalParams]
  temperature = temp
  volumetric_locking_correction = true
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = elastic_thermal_patch_rz_test.e
[]

[Functions]
  [./ur]
    type = ParsedFunction
    value = '0'
  [../]
  [./uz]
    type = ParsedFunction
    value = '0'
  [../]
  [./body]
    type = ParsedFunction
    value = '-400/x'
  [../]
  [./temp]
    type = ParsedFunction
    value = '117.56+100*t'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules]
    [TensorMechanics]
        [Master]
            displacements = 'disp_x disp_y'
            [All]
                displacements = 'disp_x disp_y'
                add_variables = true
                strain = SMALL
                incremental = true
                eigenstrain_names = eigenstrain
                generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
            [../]
        [../]
    [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 1
    function = ur
  [../]
  [./uz]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 2
    function = uz
  [../]

  [./temp]
    type = FunctionDirichletBC
    variable = temp
    boundary = 10
    function = temp
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 117.56
    thermal_expansion_coeff = 1e-6
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]

  [./heat]
    type = HeatConductionMaterial
    specific_heat = 0.116
    thermal_conductivity = 4.85e-4
  [../]

  [./density]
    type = Density
    density = 0.283
    disp_r = disp_x
    disp_z = disp_y
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-12

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 1
  end_time = 1.0
[]

[Outputs]
  file_base = elastic_thermal_jacobian_rz_smp_out
  [./exodus]
    type = Exodus
    execute_on = 'initial timestep_end nonlinear'
    nonlinear_residual_dt_divisor = 100
  [../]
[]

modules/combined/test/tests/sliding_block/in_and_out/constraint/frictionless_kinematic.i

#  This is a benchmark test that checks constraint based frictionless
#  contact using the kinematic method.  In this test a sinusoidal
#  displacement is applied in the horizontal direction to simulate
#  a small block come in and out of contact as it slides down a larger block.
#
#  The sinusoid is of the form 0.4sin(4t)+0.2. The gold file is run
#  on one processor and the benchmark
#  case is run on a minimum of 4 processors to ensure no parallel variability
#  in the contact pressure and penetration results.  Further documentation can
#  found in moose/modules/contact/doc/sliding_block/
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
  [./horizontal_movement]
    type = ParsedFunction
    value = -0.04*sin(4*t)+0.02
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -sub_pc_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm     lu    20    101'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 15
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-6
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+6
    system = constraint
    normal_smoothing_distance = 0.1
  [../]
[]

modules/combined/test/tests/glued_contact/glued_contact_mechanical_constraint_test.i

# This is a mechanical constraint (contact formulation) version of glued_contact_mechanical_constraint.i
[Mesh]
  file = glued_contact_test.e
[]

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./up]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.5001'
  [../]

  [./lateral]
    type = PiecewiseLinear
    x = '0 1 2 3'
    y = '0 0 1 0'
    scale_factor = 0.5
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[Contact]
  [./dummy_name]
    master = 2
    slave = 3
    penalty = 1e6
    model = glued
    formulation = kinematic
    system = constraint
  [../]
[]

[BCs]

  [./bottom_lateral]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 1
    function = lateral
  [../]

  [./bottom_up]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = up
  [../]

  [./bottom_out]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff1_strain]
    type= ComputeFiniteStrain
    block = '1'
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]

  [./stiffStuff2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff2_strain]
    type= ComputeFiniteStrain
    block = '2'
  [../]
  [./stiffStuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  #petsc_options_iname = '-pc_type -pc_hypre_type -snes_type -snes_ls -snes_linesearch_type -ksp_gmres_restart'
  #petsc_options_value = 'hypre    boomeramg      ls         basic    basic                    101'
  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'ilu      101'

  line_search = 'none'

  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-8
  l_tol = 1e-4

  l_max_its = 100
  nl_max_its = 10
  dt = 0.1
  num_steps = 30

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Postprocessors]
  active = ''
  [./resid]
    type = Residual
  [../]
  [./iters]
    type = NumNonlinearIterations
  [../]
[]

[Outputs]
  file_base = mechanical_constraint_out
  exodus = true
[]

modules/tensor_mechanics/test/tests/creep_tangent_operator/creep.i

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 2
  second_order = true
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x = '0 10'
    y = '0 1e-3'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    use_displaced_mesh = true
    use_finite_deform_jacobian = true
    generate_output = 'hydrostatic_stress'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.3
  [../]

  [./elastic_strain]
    type = ComputeMultipleInelasticStress
    # inelastic_models = ''
    tangent_operator = nonlinear
  [../]

  [./creep_ten]
    type = PowerLawCreepStressUpdate
    coefficient = 10e-24
    n_exponent = 4
    activation_energy = 0
    base_name = creep_ten
  [../]
  [./creep_ten2]
    type = PowerLawCreepStressUpdate
    coefficient = 10e-24
    n_exponent = 4
    activation_energy = 0
    base_name = creep_ten2
  [../]
  [./creep_one]
    type = PowerLawCreepStressUpdate
    coefficient = 1e-24
    n_exponent = 4
    activation_energy = 0
    base_name = creep_one
  [../]
  [./creep_nine]
    type = PowerLawCreepStressUpdate
    coefficient = 9e-24
    n_exponent = 4
    activation_energy = 0
    base_name = creep_nine
  [../]
  [./creep_zero]
    type = PowerLawCreepStressUpdate
    coefficient = 0e-24
    n_exponent = 4
    activation_energy = 0
    base_name = creep_zero
  [../]
[]

[BCs]
  [./no_disp_x]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]

  [./no_disp_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./pull_disp_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = pull
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'
  line_search = 'none'
  nl_rel_tol = 1e-5

  num_steps = 5
  dt = 1e-1
[]

[Postprocessors]
  [./max_disp_x]
    type = ElementExtremeValue
    variable = disp_x
  [../]
  [./max_disp_y]
    type = ElementExtremeValue
    variable = disp_y
  [../]
  [./max_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
  [../]
  [./dt]
    type = TimestepSize
  [../]
  [./num_lin]
    type = NumLinearIterations
    outputs = console
  [../]
  [./num_nonlin]
    type = NumNonlinearIterations
    outputs = console
  [../]
[]

[Outputs]
  csv = true
  perf_graph = true
[]

[Debug]
  show_var_residual_norms = true
[]

modules/xfem/test/tests/solid_mechanics_basic/mesh_grow.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[XFEM]
  geometric_cut_userobjects = 'cut_mesh'
  output_cut_plane = true
  qrule = volfrac
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 5
  ny = 5
  nz = 5
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  zmin = -0.4
  zmax = 0.6
  elem_type = HEX8
[]

[UserObjects]
  [./cut_mesh]
    type = MeshCut3DUserObject
    mesh_file = mesh_grow.xda
    function_x = growth_func_x
    function_y = growth_func_y
    function_z = growth_func_z
# The current gold file does not grow the cutting mesh, but this is something
# that needs to be tested more in the future.
#    size_control = 0.05
#    n_step_growth = 50
  [../]
[]

[Functions]
  [./growth_func_x]
    type = ParsedFunction
    value = 5*(x-0.3)+z
  [../]
  [./growth_func_y]
    type = ParsedFunction
    value = 5*(y-0.5)+(z+x)/2
  [../]
  [./growth_func_z]
    type = ParsedFunction
    value = 5*(z-0.1)+x
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[Functions]
  [./top_trac_y]
    type = ConstantFunction
    value = 10
  [../]
[]


[BCs]
  [./top_y]
    type = FunctionNeumannBC
    boundary = top
    variable = disp_y
    function = top_trac_y
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    boundary = bottom
    variable = disp_z
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  file_base = mesh_grow
  execute_on = 'timestep_end'
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/stress_recovery/stress_concentration/stress_concentration.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = FileMesh
  file = geo.msh
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
[]

[AuxVariables]
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xx_recovered]
  []
  [stress_yy_recovered]
  []
[]

[AuxKernels]
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = 'timestep_end'
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = 'timestep_end'
  []
  [stress_xx_recovered]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_recovered
    patch_polynomial_order = SECOND
    index_i = 0
    index_j = 0
    execute_on = 'timestep_end'
  []
  [stress_yy_recovered]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy_recovered
    patch_polynomial_order = SECOND
    index_i = 1
    index_j = 1
    execute_on = 'timestep_end'
  []
[]

[Kernels]
  [solid_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
  []
  [solid_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
  []
[]

[Materials]
  [strain]
    type = ComputeSmallStrain
  []
  [Cijkl]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 2.1e+5
  []
  [stress]
    type = ComputeLinearElasticStress
  []
[]

[BCs]
  [top_xdisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'top'
    function = 0
  []
  [top_ydisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'top'
    function = 0.01
  []
  [bottom_xdisp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'bottom'
    function = 0
  []
  [bottom_ydisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'bottom'
    function = 0
  []
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
    ksp_norm = default
  []
[]

[Executioner]
  type = Steady
  solve_type = NEWTON
  petsc_options_iname = '-ksp_type -pc_type'
  petsc_options_value = 'preonly   lu'
  nl_rel_tol = 1e-14
  l_max_its = 100
  nl_max_its = 30
[]

[Outputs]
  interval = 1
  exodus = true
  print_linear_residuals = false
[]

modules/tensor_mechanics/test/tests/action/two_coord.i

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 16
    ny = 8
    xmin = -1
    xmax = 1
  []
  [block1]
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '-1 0 0'
    top_right = '0 1 0'
    input = generated_mesh
  []
  [block2]
    type = SubdomainBoundingBoxGenerator
    block_id = 2
    bottom_left = '0 0 0'
    top_right = '1 1 0'
    input = block1
  []
[]

[Problem]
  coord_type = 'XYZ RZ'
  block      = '1   2'
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Modules/TensorMechanics/Master]
  active = 'block1 block2'
  [./error]
    strain = SMALL
    add_variables = true
  [../]
  [./block1]
    strain = SMALL
    add_variables = true
    block = 1
  [../]
  [./block2]
    strain = SMALL
    add_variables = true
    block = 2
  [../]
[]

[AuxVariables]
  [./vmstress]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./vmstress]
    type = RankTwoScalarAux
    rank_two_tensor = total_strain
    variable = vmstress
    scalar_type = VonMisesStress
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./_elastic_stress]
    type = ComputeLinearElasticStress
    block = '1 2'
  [../]
[]

[BCs]
  [./topx]
    type = DirichletBC
    boundary = 'top'
    variable = disp_x
    value = 0.0
  [../]
  [./topy]
    type = DirichletBC
    boundary = 'top'
    variable = disp_y
    value = 0.0
  [../]
  [./bottomx]
    type = DirichletBC
    boundary = 'bottom'
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 'bottom'
    variable = disp_y
    value = 0.05
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Executioner]
  type = Steady

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/sliding_block/sliding/constraint/frictional_04_penalty.i

#  This is a benchmark test that checks constraint based frictional
#  contact using the penalty method.  In this test a constant
#  displacement is applied in the horizontal direction to simulate
#  a small block come sliding down a larger block.
#
#  A friction coefficient of 0.4 is used.  The gold file is run on one processor
#  and the benchmark case is run on a minimum of 4 processors to ensure no
#  parallel variability in the contact pressure and penetration results.
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]


[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 14.99999
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-6
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = coulomb
    penalty = 1e+7
    friction_coefficient = 0.4
    formulation = penalty
    system = constraint
    normal_smoothing_distance = 0.1
  [../]
[]

modules/tensor_mechanics/test/tests/dynamics/prescribed_displacement/3D_QStatic_1_Ramped_Displacement_ti.i

# One 3D element under ramped displacement loading.
#
# loading:
# time : 0.0 0.1  0.2  0.3
# disp : 0.0 0.0 -0.01 -0.01

# This displacement loading is applied using the PresetDisplacement boundary condition.

# Here, the given displacement time history is converted to an acceleration
# time history using Backward Euler time differentiation. Then, the resulting
# acceleration is integrated using Newmark time integration to obtain a
# displacement time history which is then applied to the boundary.

# This is done because if the displacement is applied using Dirichlet BC, the
# resulting acceleration is very noisy.

# Boundaries:
# x = 0 left
# x = 1 right
# y = 0 bottom
# y = 1 top
# z = 0 back
# z = 1 front

# Result: The displacement at the top node in the z direction should match
# the prescribed displacement. Also, the z acceleration should
# be two triangular pulses, one peaking at 0.1 and another peaking at
# 0.2.


[Mesh]
  type = GeneratedMesh
  dim = 3 # Dimension of the mesh
  nx = 1 # Number of elements in the x direction
  ny = 1 # Number of elements in the y direction
  nz = 1 # Number of elements in the z direction
  xmin = 0.0
  xmax = 1
  ymin = 0.0
  ymax = 1
  zmin = 0.0
  zmax = 1
  allow_renumbering = false # So NodalVariableValue can index by id
[]

[Variables] # variables that are solved
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables] # variables that are calculated for output
  [./accel_x]
  [../]
  [./vel_x]
  [../]
  [./accel_y]
  [../]
  [./vel_y]
  [../]
  [./accel_z]
  [../]
  [./vel_z]
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./DynamicTensorMechanics] # zeta*K*vel + K * disp
    displacements = 'disp_x disp_y disp_z'
    zeta = 0.000025
  [../]
  [./inertia_x] # M*accel + eta*M*vel
    type = InertialForce
    variable = disp_x
    eta = 19.63
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    eta = 19.63
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    eta = 19.63
  [../]
[]

[AuxKernels]
  [./accel_x] # These auxkernels are only to check output
    type = TestNewmarkTI
    displacement = disp_x
    variable = accel_x
    first = false
  [../]
  [./accel_y]
    type = TestNewmarkTI
    displacement = disp_y
    variable = accel_y
    first = false
  [../]
  [./accel_z]
    type = TestNewmarkTI
    displacement = disp_z
    variable = accel_z
    first = false
  [../]
  [./vel_x]
    type = TestNewmarkTI
    displacement = disp_x
    variable = vel_x
  [../]
  [./vel_y]
    type = TestNewmarkTI
    displacement = disp_y
    variable = vel_y
  [../]
  [./vel_z]
    type = TestNewmarkTI
    displacement = disp_z
    variable = vel_z
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Functions]
  [./displacement_front]
    type = PiecewiseLinear
    data_file = 'displacement.csv'
    format = columns
  [../]
[]

[BCs]
  [./Preset_displacement]
    type = PresetDisplacement
    variable = disp_z
    function = displacement_front
    boundary = front
    beta = 0.25
    velocity = vel_z
    acceleration = accel_z
  [../]
  [./anchor_x]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./anchor_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./anchor_z]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    youngs_modulus = 325e6 #Pa
    poissons_ratio = 0.3
    type = ComputeIsotropicElasticityTensor
    block = 0
  [../]
  [./strain]
    #Computes the strain, assuming small strains
    type = ComputeSmallStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    #Computes the stress, using linear elasticity
    type = ComputeLinearElasticStress
    block = 0
  [../]
  [./density]
    type = GenericConstantMaterial
    block = 0
    prop_names = density
    prop_values = 2000 #kg/m3
  [../]
[]

[Executioner]
  type = Transient
  start_time = 0
  end_time = 3.0
  l_tol = 1e-6
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-6
  dt = 0.1
  timestep_tolerance = 1e-6

  # Time integrator scheme
  scheme = "newmark-beta"
[]

[Postprocessors] # These quantites are printed to a csv file at every time step
  [./_dt]
    type = TimestepSize
  [../]
  [./accel_6x]
    type = NodalVariableValue
    nodeid = 6
    variable = accel_x
  [../]
  [./accel_6y]
    type = NodalVariableValue
    nodeid = 6
    variable = accel_y
  [../]
  [./accel_6z]
    type = NodalVariableValue
    nodeid = 6
    variable = accel_z
  [../]
  [./vel_6x]
    type = NodalVariableValue
    nodeid = 6
    variable = vel_x
  [../]
  [./vel_6y]
    type = NodalVariableValue
    nodeid = 6
    variable = vel_y
  [../]
  [./vel_6z]
    type = NodalVariableValue
    nodeid = 6
    variable = vel_z
  [../]
  [./disp_6x]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_6y]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./disp_6z]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_z
  [../]
[]

[Outputs]
  file_base = "3D_QStatic_1_Ramped_Displacement_out"
  exodus = true
  csv = true
  perf_graph = true
[]

modules/tensor_mechanics/test/tests/2D_different_planes/gps_jacobian_testing_yz.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = square_yz_plane.e
[]

[Variables]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./scalar_strain_xx]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./disp_x]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./generalized_plane_strain]
    block = 1
    strain = SMALL
    scalar_out_of_plane_strain = scalar_strain_xx
    out_of_plane_direction = x
    planar_formulation = GENERALIZED_PLANE_STRAIN
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.0
    youngs_modulus = 1
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  petsc_options_iname = '-ksp_type -pc_type -snes_type'
  petsc_options_value = 'bcgs bjacobi test'

  end_time = 1.0
[]

modules/combined/test/tests/contact_verification/patch_tests/plane_3/plane3_template1.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane3_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'asm'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-8
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x11 disp_y11 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/porous_flow/test/tests/actions/basicthm_hm.i

# PorousFlowBasicTHM action with coupling_type = HydroMechanicalGenerator

[Mesh]
  [gen]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 10
    ny = 3
    xmax = 10
    ymax = 3
  []
  [./aquifer]
    input = gen
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 1 0'
    top_right = '10 2 0'
  [../]
  [./injection_area]
    type = SideSetsAroundSubdomainGenerator
    block = 1
    new_boundary = 'injection_area'
    normal = '-1 0 0'
    input = 'aquifer'
  [../]
  [./outflow_area]
    type = SideSetsAroundSubdomainGenerator
    block = 1
    new_boundary = 'outflow_area'
    normal = '1 0 0'
    input = 'injection_area'
  [../]
  [./rename]
    type = RenameBlockGenerator
    old_block_id = '0 1'
    new_block_name = 'caprock aquifer'
    input = 'outflow_area'
  [../]
[]

[GlobalParams]
  PorousFlowDictator = dictator
  displacements = 'disp_x disp_y'
  biot_coefficient = 1.0
[]

[Variables]
  [./porepressure]
    initial_condition = 1e6
  [../]
  [./disp_x]
    scaling = 1e-10
  [../]
  [./disp_y]
    scaling = 1e-10
  [../]
[]

[AuxVariables]
  [./temperature]
    initial_condition = 293
  [../]
[]

[PorousFlowBasicTHM]
  porepressure = porepressure
  temperature = temperature
  coupling_type = HydroMechanical
  gravity = '0 0 0'
  fp = simple_fluid
  use_displaced_mesh = false
  add_stress_aux = false
[]

[BCs]
  [./constant_injection_porepressure]
    type = DirichletBC
    variable = porepressure
    value = 1.5e6
    boundary = injection_area
  [../]
  [./constant_outflow_porepressure]
    type = PorousFlowPiecewiseLinearSink
    variable = porepressure
    boundary = outflow_area
    pt_vals = '0 1e9'
    multipliers = '0 1e9'
    flux_function = 1e-6
    PT_shift = 1e6
  [../]
  [./top_bottom]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = 'top bottom'
  [../]
  [./right]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = right
  [../]
[]

[Modules]
  [./FluidProperties]
    [./simple_fluid]
      type = SimpleFluidProperties
    [../]
  [../]
[]

[Materials]
  [./porosity]
    type = PorousFlowPorosity
    porosity_zero = 0.1
  [../]
  [./biot_modulus]
    type = PorousFlowConstantBiotModulus
    solid_bulk_compliance = 2e-7
    fluid_bulk_modulus = 1e7
  [../]
  [./permeability_aquifer]
    type = PorousFlowPermeabilityConst
    block = aquifer
    permeability = '1e-13 0 0   0 1e-13 0   0 0 1e-13'
  [../]
  [./permeability_caprock]
    type = PorousFlowPermeabilityConst
    block = caprock
    permeability = '1e-15 0 0   0 1e-15 0   0 0 1e-15'
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 5e9
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./basic]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  end_time = 1e4
  dt = 1e3
  nl_abs_tol = 1e-14
  nl_rel_tol = 1e-14
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/plane_2/plane2_template2.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane2_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  maximum_lagrangian_update_iterations = 200
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-7
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_y5 disp_x9 disp_y9 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/combined/test/tests/inelastic_strain/elas_plas/elas_plas_nl1_cycle.i

#
# Test for effective strain calculation.
# Boundary conditions from NAFEMS test NL1
#
#
# This is not a verification test. The boundary conditions are applied such
# that the first step generates only elastic stresses. The rest of the load
# steps generate cycles of tension and compression in the axial (i.e., y-axis)
# direction. The axial stresses and strains also cycle, however the effective
# plastic strain increases in value throughout the analysis.
#
[GlobalParams]
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = one_elem2.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./pressure]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./eff_plastic_strain]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = VonMisesStress
    execute_on = timestep_end
  [../]
  [./pressure]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = pressure
    scalar_type = Hydrostatic
    execute_on = timestep_end
  [../]
  [./elastic_strain_xx]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./elastic_strain_yy]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./elastic_strain_zz]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./plastic_strain_xx]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./plastic_strain_yy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./plastic_strain_zz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./tot_strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = tot_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./tot_strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = tot_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./tot_strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = tot_strain_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./eff_plastic_strain]
    type = MaterialRealAux
    property = effective_plastic_strain
    variable = eff_plastic_strain
  [../]
[]

[Functions]
  [./appl_dispy]
    type = PiecewiseLinear
    x = '0     1.0     2.0     3.0     4.0     5.0      6.0    7.0     8.0    9.0     10.0      11.0     12.0'
    y = '0.0 0.208e-4 0.50e-4 1.00e-4 0.784e-4 0.50e-4  0.0  0.216e-4 0.5e-4 1.0e-4 0.785e-4  0.50e-4  0.0'
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 101
    value = 0.0
  [../]
  [./origin_x]
    type = DirichletBC
    variable = disp_x
    boundary = 103
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 102
    value = 0.0
  [../]
  [./origin_y]
    type = DirichletBC
    variable = disp_y
    boundary = 103
    value = 0.0
  [../]
  [./top_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = appl_dispy
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    youngs_modulus = 250e9
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputePlaneFiniteStrain
    block = 1
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'isoplas'
    block = 1
  [../]
  [./isoplas]
    type = IsotropicPlasticityStressUpdate
    yield_stress = 5e6
    hardening_constant = 0.0
    relative_tolerance = 1e-20
    absolute_tolerance = 1e-8
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-12
  l_tol = 1e-4
  l_max_its = 100
  nl_max_its = 20

  dt = 1.0
  start_time = 0.0
  num_steps = 100
  end_time = 12.0
[]

[Postprocessors]
  [./stress_xx]
    type = ElementAverageValue
    variable = stress_xx
  [../]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./stress_xy]
    type = ElementAverageValue
    variable = stress_xy
  [../]
  [./vonmises]
    type = ElementAverageValue
    variable = vonmises
  [../]
  [./pressure]
    type = ElementAverageValue
    variable = pressure
  [../]
  [./el_strain_xx]
    type = ElementAverageValue
    variable = elastic_strain_xx
  [../]
  [./el_strain_yy]
    type = ElementAverageValue
    variable = elastic_strain_yy
  [../]
  [./el_strain_zz]
    type = ElementAverageValue
    variable = elastic_strain_zz
  [../]
  [./pl_strain_xx]
    type = ElementAverageValue
    variable = plastic_strain_xx
  [../]
  [./pl_strain_yy]
    type = ElementAverageValue
    variable = plastic_strain_yy
  [../]
  [./pl_strain_zz]
    type = ElementAverageValue
    variable = plastic_strain_zz
  [../]
  [./eff_plastic_strain]
    type = ElementAverageValue
    variable = eff_plastic_strain
  [../]
  [./tot_strain_xx]
    type = ElementAverageValue
    variable = tot_strain_xx
  [../]
  [./tot_strain_yy]
    type = ElementAverageValue
    variable = tot_strain_yy
  [../]
  [./tot_strain_zz]
    type = ElementAverageValue
    variable = tot_strain_zz
  [../]
  [./disp_x1]
    type = NodalVariableValue
    nodeid = 0
    variable = disp_x
  [../]
  [./disp_x4]
    type = NodalVariableValue
    nodeid = 3
    variable = disp_x
  [../]
  [./disp_y1]
    type = NodalVariableValue
    nodeid = 0
    variable = disp_y
  [../]
  [./disp_y4]
    type = NodalVariableValue
    nodeid = 3
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
[]

[Outputs]
  exodus = true
  csv = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/combined/test/tests/sliding_block/in_and_out/dirac/frictionless_kinematic.i

#  This is a benchmark test that checks Dirac based frictionless
#  contact using the kinematic method.  In this test a sinusoidal
#  displacement is applied in the horizontal direction to simulate
#  a small block come in and out of contact as it slides down a larger block.
#
#  The sinusoid is of the form 0.4sin(4t)+0.2. The gold file is run
#  on one processor and the benchmark
#  case is run on a minimum of 4 processors to ensure no parallel variability
#  in the contact pressure and penetration results.  Further documentation can
#  found in moose/modules/contact/doc/sliding_block/
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
  [./horizontal_movement]
    type = ParsedFunction
    value = -0.04*sin(4*t)+0.02
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./constitutive]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 15
  num_steps = 1000
  nl_rel_tol = 1e-6
  dtmin = 0.01
  l_tol = 1e-6

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  file_base = frictionless_kinematic_out
  interval = 10
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+6
    formulation = kinematic
    normal_smoothing_distance = 0.1
    system = DiracKernel
  [../]
[]

modules/porous_flow/examples/tidal/barometric_fully_confined.i

# A fully-confined aquifer is fully saturated with water
# Barometric loading is applied to the aquifer.
# Because the aquifer is assumed to be sandwiched between
# impermeable aquitards, the barometric pressure is not felt
# directly by the porepressure.  Instead, the porepressure changes
# only because the barometric loading applies a total stress to
# the top surface of the aquifer.
#
# To replicate standard poroelasticity exactly:
# (1) the PorousFlowBasicTHM Action is used;
# (2) multiply_by_density = false;
# (3) PorousFlowConstantBiotModulus is used
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = 0
  xmax = 1
  ymin = 0
  ymax = 1
  zmin = 0
  zmax = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  PorousFlowDictator = dictator
  block = 0
  biot_coefficient = 0.6
  multiply_by_density = false
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./porepressure]
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    value = 0.0
    boundary = 'left right'
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    value = 0.0
    boundary = 'bottom top'
  [../]
  [./fix_z_bottom]
    type = DirichletBC
    variable = disp_z
    value = 0.0
    boundary = back
  [../]
  [./barometric_loading]
    type = FunctionNeumannBC
    variable = disp_z
    function = -1000.0 # atmospheric pressure increase of 1kPa
    boundary = front
  [../]
[]

[Modules]
  [./FluidProperties]
    [./the_simple_fluid]
      type = SimpleFluidProperties
      bulk_modulus = 2E9
    [../]
  [../]
[]

[PorousFlowBasicTHM]
  coupling_type = HydroMechanical
  displacements = 'disp_x disp_y disp_z'
  porepressure = porepressure
  gravity = '0 0 0'
  fp = the_simple_fluid
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 10.0E9 # drained bulk modulus
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./porosity]
    type = PorousFlowPorosityConst # only the initial value of this is ever used
    porosity = 0.1
  [../]
  [./biot_modulus]
    type = PorousFlowConstantBiotModulus
    solid_bulk_compliance = 1E-10
    fluid_bulk_modulus = 2E9
  [../]
  [./permeability]
    type = PorousFlowPermeabilityConst
    permeability = '1E-12 0 0   0 1E-12 0   0 0 1E-12'
  [../]
[]

[Postprocessors]
  [./pp]
    type = PointValue
    point = '0.5 0.5 0.5'
    variable = porepressure
  [../]
[]


[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  dt = 1
  end_time = 1
[]

[Outputs]
  console = true
  csv = true
[]

modules/tensor_mechanics/test/tests/jacobian/cto27.i

# CappedDruckerPrager and CappedWeakPlane, both with all parameters softening/hardening.
# With large tolerance in ComputeMultipleInelasticStress so that only 1 iteration is performed

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]


[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 2
    internal_limit = 100
  [../]
  [./cs]
    type = TensorMechanicsHardeningCubic
    value_0 = 5
    value_residual = 3
    internal_limit = 100
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningCubic
    value_0 = 10
    value_residual = 1
    internal_limit = 100
  [../]
  [./phi]
    type = TensorMechanicsHardeningCubic
    value_0 = 0.8
    value_residual = 0.4
    internal_limit = 50
  [../]
  [./psi]
    type = TensorMechanicsHardeningCubic
    value_0 = 0.4
    value_residual = 0
    internal_limit = 10
  [../]
  [./dp]
    type = TensorMechanicsPlasticDruckerPragerHyperbolic
    mc_cohesion = mc_coh
    mc_friction_angle = phi
    mc_dilation_angle = psi
    yield_function_tolerance = 1E-11     # irrelevant here
    internal_constraint_tolerance = 1E-9 # irrelevant here
  [../]
  [./wp_ts]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 100
    rate = 1
  [../]
  [./wp_cs]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0
    internal_0 = -2
    internal_limit = 0
  [../]
  [./wp_coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 2
    rate = 1
  [../]
  [./wp_tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 0.5
    rate = 2
  [../]
  [./wp_tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.05
    rate = 3
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    lambda = 0.1
    shear_modulus = 1.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '6 5 4  5 7 2  4 2 2'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'dp wp'
    relative_tolerance = 1E4
    absolute_tolerance = 2
    tangent_operator = nonlinear
  [../]
  [./dp]
    type = CappedDruckerPragerStressUpdate
    base_name = cdp
    DP_model = dp
    tensile_strength = ts
    compressive_strength = cs
    yield_function_tol = 1E-11
    tip_smoother = 1
    smoothing_tol = 1
  [../]
  [./wp]
    type = CappedWeakPlaneStressUpdate
    base_name = cwp
    cohesion = wp_coh
    tan_friction_angle = wp_tanphi
    tan_dilation_angle = wp_tanpsi
    tensile_strength = wp_ts
    compressive_strength = wp_cs
    tip_smoother = 0
    smoothing_tol = 1
    yield_function_tol = 1E-11
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/ad_elastic/incremental_small_elastic-noad.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 3
  ny = 3
  nz = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_x]
    scaling = 1e-10
  [../]
  [./disp_y]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_x]
    type = StressDivergenceTensors
    component = 0
    variable = disp_x
  [../]
  [./stress_y]
    type = StressDivergenceTensors
    component = 1
    variable = disp_y
  [../]
  [./stress_z]
    type = StressDivergenceTensors
    component = 2
    variable = disp_z
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = incremental_small_elastic_out
[]

modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/glued_penalty.i

[Mesh]
  file = blocks_2d_nogap.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    #Initial gap is 0.01
    value = -0.01
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  [../]
  [./right]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.01
  end_time = 0.10
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-8
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    system = Constraint
    master = 2
    slave = 3
    model = glued
    formulation = penalty
    penalty = 1e+7
  [../]
[]

modules/tensor_mechanics/test/tests/combined_creep_plasticity/combined_stress_prescribed.i

#
# 1x1x1 unit cube with time-varying pressure on top face
#
# The problem is a one-dimensional creep analysis.  The top face has a
#    pressure load that is a function of time.  The creep strain can be
#    calculated analytically.  There is no practical active linear
#    isotropic plasticity because the yield stress for the plasticity
#    model is set to 1e30 MPa, which will not be reached in this
#    regression test.
#
# The analytic solution to this problem is:
#
#    d ec
#    ---- = a*S^b  with S = c*t^d
#     dt
#
#    d ec = a*c^b*t^(b*d) dt
#
#         a*c^b
#    ec = ----- t^(b*d+1)
#         b*d+1
#
#    where S  = stress
#          ec = creep strain
#          t  = time
#          a  = constant
#          b  = constant
#          c  = constant
#          d  = constant
#
# With a = 3e-24,
#      b = 4,
#      c = 1,
#      d = 1/2, and
#      t = 32400
#   we have
#
#   S = t^(1/2) = 180
#
#   ec = 1e-24*t^3 = 3.4012224e-11
#
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy creep_strain_yy'
  [../]
[]

[Functions]
  [./pressure]
    type = ParsedFunction
    value = 'sqrt(t)'
  [../]

  [./dts]
    type = PiecewiseLinear
    y = '1e-2 1e-1 1e0 1e1 1e2'
    x = '0    7e-1 7e0 7e1 1e2'
  [../]
[]

[BCs]
  [./top_pressure]
    type = Pressure
    variable = disp_y
    component = 1
    boundary = top
    function = pressure
  [../]
  [./u_bottom_fix]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.8e7
    poissons_ratio = 0.3
  [../]
  [./creep_plas]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'creep plas'
    tangent_operator = elastic
  [../]
  [./creep]
    type = PowerLawCreepStressUpdate
    coefficient = 3.0e-24
    n_exponent = 4
    m_exponent = 0
    activation_energy = 0
  [../]
  [./plas]
    type = IsotropicPlasticityStressUpdate
    hardening_constant = 1
    yield_stress = 1e30
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = ' lu       superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-7
  l_tol = 1e-6
  start_time = 0.0
  end_time = 32400
  dt = 1e-2
  [./TimeStepper]
    type = FunctionDT
    function = dts
  [../]
[]

[Postprocessors]
  [./timestep]
    type = TimestepSize
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/jacobian/tensile_update2.i

# Tensile, update version, with strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Return to the stress_I = stress_II ~1 edge

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2 0 0  0 0 0  0 0 2.01'
    eigenstrain_name = ini_stress
  [../]
  [./tensile]
    type = TensileStressUpdate
    tensile_strength = ts
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = tensile
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/ad_simple_linear/linear-hand-coded.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1.0e10
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05

  #Preconditioned JFNK (default)
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = "linear-out"
[]

modules/peridynamics/test/tests/generalized_plane_strain/generalized_plane_strain_OSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  scalar_out_of_plane_strain = scalar_strain_zz
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]

  [./stress_zz]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/Peridynamics/Mechanics]
  [./Master]
    [./all]
      formulation = ORDINARY_STATE
    [../]
  [../]
  [./GeneralizedPlaneStrain]
    [./all]
      formulation = ORDINARY_STATE
      out_of_plane_stress_variable = stress_zz
    [../]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]

  [./stress_zz]
    type = NodalRankTwoPD
    variable = stress_zz

    poissons_ratio = 0.3
    youngs_modulus = 1e6
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5

    rank_two_tensor = stress
    output_type = component
    index_i = 2
    index_j = 2
  [../]
[]

[Postprocessors]
  [./react_z]
    type = NodalVariableIntegralPD
    variable = stress_zz
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    boundary = 1000
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 1000
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]

  [./force_density]
    type = ComputeSmallStrainVariableHorizonMaterialOSPD
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
  file_base = generalized_plane_strain_OSPD
[]

modules/tensor_mechanics/test/tests/2D_geometries/3D-RZ_finiteStrain_test.i

# Considers the mechanics solution for a thick spherical shell that is uniformly
# pressurized on the inner and outer surfaces, using 3D geometry.
#
# From Roark (Formulas for Stress and Strain, McGraw-Hill, 1975), the radially-dependent
# circumferential stress in a uniformly pressurized thick spherical shell is given by:
#
# S(r) = [ Pi[ri^3(2r^3+ro^3)] - Po[ro^3(2r^3+ri^3)] ] / [2r^3(ro^3-ri^3)]
#
#   where:
#          Pi = inner pressure
#          Po = outer pressure
#          ri = inner radius
#          ro = outer radius
#
# The tests assume an inner and outer radii of 5 and 10, with internal and external
# pressures of 100000 and 200000 at t = 1.0, respectively. The resulting compressive
# tangential stress is largest at the inner wall and, from the above equation, has a
# value of -271429.
#
# RESULTS are below. Since stresses are average element values, values for the
# edge element and one-element-in are used to extrapolate the stress to the
# inner surface. The vesrion of the tests that are checked use the coarsest meshes.
#
#  Mesh    Radial elem   S(edge elem)  S(one elem in)  S(extrap to surf)
# 1D-SPH
# 2D-RZ        12 (x10)    -265004      -254665        -270174
#  3D          12 (6x6)    -261880      -252811        -266415
#
# 1D-SPH
# 2D-RZ        48 (x10)    -269853      -266710        -271425
#  3D          48 (10x10)  -268522      -265653        -269957
#
# The numerical solution converges to the analytical solution as the mesh is
# refined.

[Mesh]
  file = 3D_mesh.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    block = 1
  [../]
[]

[AuxVariables]
  [./stress_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_theta]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_theta
    execute_on = timestep_end
  [../]
  [./strain_theta]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 2
    index_j = 2
    variable = strain_theta
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
    block = 1
  [../]

  [./elastic_strain]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
[]

[BCs]
# pin particle along symmetry planes
  [./no_disp_x]
    type = DirichletBC
    variable = disp_x
    boundary = xzero
    value = 0.0
  [../]

  [./no_disp_y]
    type = DirichletBC
    variable = disp_y
    boundary = yzero
    value = 0.0
  [../]

  [./no_disp_z]
    type = DirichletBC
    variable = disp_z
    boundary = zzero
    value = 0.0
  [../]

# exterior and internal pressures
  [./exterior_pressure_x]
    type = Pressure
    variable = disp_x
    boundary = outer
    component = 0
    function = '200000*t'
  [../]

 [./exterior_pressure_y]
    type = Pressure
    variable = disp_y
    boundary = outer
    component = 1
    function = '200000*t'
  [../]

[./exterior_pressure_z]
    type = Pressure
    variable = disp_z
    boundary = outer
    component = 2
    function = '200000*t'
  [../]

  [./interior_pressure_x]
    type = Pressure
    variable = disp_x
    boundary = inner
    component = 0
    function = '100000*t'
  [../]

  [./interior_pressure_y]
    type = Pressure
    variable = disp_y
    boundary = inner
    component = 1
    function = '100000*t'
  [../]

[./interior_pressure_z]
    type = Pressure
    variable = disp_z
    boundary = inner
    component = 2
    function = '100000*t'
  [../]

[]

[Debug]
    show_var_residual_norms = true
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50

  start_time = 0.0
  end_time = 0.2
  dt = 0.1

[]

[Postprocessors]
  [./strainTheta]
    type = ElementAverageValue
    variable = strain_theta
  [../]
  [./stressTheta]
    type = ElementAverageValue
    variable = stress_theta
  [../]
  [./stressTheta_pt]
    type = PointValue
    point = '5.0 0.0 0.0'
    #bottom inside edge for comparison to theory; use csv = true
    variable = stress_theta
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_1/ring1_template1.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring1_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-9
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x7 disp_y7 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/porous_flow/test/tests/thm_rehbinder/free_outer.i

[Mesh]
  [annular]
    type = AnnularMeshGenerator
    nr = 40
    nt = 16
    rmin = 0.1
    rmax = 1
    dmin = 0.0
    dmax = 90
    growth_r = 1.1
  []
  [./make3D]
    input = annular
    type = MeshExtruderGenerator
    bottom_sideset = bottom
    top_sideset = top
    extrusion_vector = '0 0 1'
    num_layers = 1
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  PorousFlowDictator = dictator
  biot_coefficient = 1.0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./porepressure]
  [../]
  [./temperature]
  [../]
[]

[BCs]
  # sideset 1 = outer
  # sideset 2 = cavity
  # sideset 3 = ymin
  # sideset 4 = xmin
  [./plane_strain]
    type = DirichletBC
    variable = disp_z
    value = 0
    boundary = 'top bottom'
  [../]
  [./ymin]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = dmin
  [../]
  [./xmin]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = dmax
  [../]

  [./cavity_temperature]
    type = DirichletBC
    variable = temperature
    value = 1000
    boundary = rmin
  [../]
  [./cavity_porepressure]
    type = DirichletBC
    variable = porepressure
    value = 1E6
    boundary = rmin
  [../]
  [./cavity_zero_effective_stress_x]
    type = Pressure
    component = 0
    variable = disp_x
    function = 1E6
    boundary = rmin
    use_displaced_mesh = false
  [../]
  [./cavity_zero_effective_stress_y]
    type = Pressure
    component = 1
    variable = disp_y
    function = 1E6
    boundary = rmin
    use_displaced_mesh = false
  [../]

  [./outer_temperature]
    type = DirichletBC
    variable = temperature
    value = 0
    boundary = rmax
  [../]
  [./outer_pressure]
    type = DirichletBC
    variable = porepressure
    value = 0
    boundary = rmax
  [../]
[]

[AuxVariables]
  [./stress_rr]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./stress_pp]
    family = MONOMIAL
    order = CONSTANT
  [../]
[]

[AuxKernels]
  [./stress_rr]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = stress_rr
    scalar_type = RadialStress
    point1 = '0 0 0'
    point2 = '0 0 1'
  [../]
  [./stress_pp]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = stress_pp
    scalar_type = HoopStress
    point1 = '0 0 0'
    point2 = '0 0 1'
  [../]
[]

[Modules]
  [./FluidProperties]
    [./the_simple_fluid]
      type = SimpleFluidProperties
      thermal_expansion = 0.0
      bulk_modulus = 1E12
      viscosity = 1.0E-3
      density0 = 1000.0
      cv = 1000.0
      cp = 1000.0
      porepressure_coefficient = 0.0
    [../]
  [../]
[]

[PorousFlowBasicTHM]
  coupling_type = ThermoHydroMechanical
  multiply_by_density = false
  add_stress_aux = true
  porepressure = porepressure
  temperature = temperature
  thermal_eigenstrain_name = thermal_contribution
  gravity = '0 0 0'
  fp = the_simple_fluid
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1E10
    poissons_ratio = 0.2
  [../]
  [./strain]
    type = ComputeSmallStrain
    eigenstrain_names = thermal_contribution
  [../]
  [./thermal_contribution]
    type = ComputeThermalExpansionEigenstrain
    temperature = temperature
    thermal_expansion_coeff = 1E-6
    eigenstrain_name = thermal_contribution
    stress_free_temperature = 0.0
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./porosity]
    type = PorousFlowPorosityConst # only the initial value of this is ever used
    porosity = 0.1
  [../]
  [./biot_modulus]
    type = PorousFlowConstantBiotModulus
    solid_bulk_compliance = 1E-10
    fluid_bulk_modulus = 1E12
  [../]
  [./permeability]
    type = PorousFlowPermeabilityConst
    permeability = '1E-12 0 0   0 1E-12 0   0 0 1E-12'
  [../]
  [./thermal_expansion]
    type = PorousFlowConstantThermalExpansionCoefficient
    fluid_coefficient = 1E-6
    drained_coefficient = 1E-6
  [../]
  [./thermal_conductivity]
    type = PorousFlowThermalConductivityIdeal
    dry_thermal_conductivity = '1E6 0 0  0 1E6 0  0 0 1E6'
  [../]
[]

[VectorPostprocessors]
  [./P]
    type = LineValueSampler
    start_point = '0.1 0 0'
    end_point = '1.0 0 0'
    num_points = 10
    sort_by = x
    variable = porepressure
  [../]
  [./T]
    type = LineValueSampler
    start_point = '0.1 0 0'
    end_point = '1.0 0 0'
    num_points = 10
    sort_by = x
    variable = temperature
  [../]
  [./U]
    type = LineValueSampler
    start_point = '0.1 0 0'
    end_point = '1.0 0 0'
    num_points = 10
    sort_by = x
    variable = disp_x
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -sub_pc_type -snes_rtol'
    petsc_options_value = 'gmres      asm      lu           1E-8'
  [../]
[]

[Executioner]
  type = Steady
  solve_type = Newton
[]

[Outputs]
  file_base = free_outer
  execute_on = timestep_end
  csv = true
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking_multiple_softening.i

# Test of cracking with direction-specific release models in 3
# directions. Block is first pulled in one direction, and then
# held while it is sequentially pulled in the other two
# directions. Poisson's ratio is zero so that the cracking in one
# direction doesn't affect the others.

# Softening in the three directions should follow the laws for the
# prescribed models in the three directions, which are power law (x),
# exponential (y), and abrupt (z).

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./displx]
    type = PiecewiseLinear
    x = '0 1 2 3'
    y = '0 1 1 1'
  [../]
  [./disply]
    type = PiecewiseLinear
    x = '0 1 2 3'
    y = '0 0 1 1'
  [../]
  [./displz]
    type = PiecewiseLinear
    x = '0 1 2 3'
    y = '0 0 0 1'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[BCs]
  [./pullx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = right
    function = displx
  [../]
  [./pully]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = disply
  [../]
  [./pullz]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = displz
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.8e7
    poissons_ratio = 0
  [../]
  [./elastic_stress]
    type = ComputeSmearedCrackingStress
    cracking_stress = 1.68e6
    softening_models = 'power_law_softening exponential_softening abrupt_softening'
    prescribed_crack_directions = 'x y z'
  [../]
  [./power_law_softening]
    type = PowerLawSoftening
    stiffness_reduction = 0.3333
  [../]
  [./exponential_softening]
    type = ExponentialSoftening
  [../]
  [./abrupt_softening]
    type = AbruptSoftening
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -sub_pc_type'
  petsc_options_value = '101                asm      lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  l_tol = 1e-5
  start_time = 0.0
  end_time = 3.0
  dt = 0.01
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/capped_mohr_coulomb/small_deform25.i

# Mohr-Coulomb only
# apply equal stretches in x, y and z directions, to observe return to the MC tip
# Because of smoothing, the expected result is around
# Smax = Smid = Smin = 12.9
# The result is not exact because the smoothing is assymetrical.
# This test also employs a very small dilation angle, which makes return
# to the tip quite numerically difficult, so max_NR_iterations has been increased to 100

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z'
  [../]
[]

[AuxVariables]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 6
    property = plastic_yield_function
    variable = yield_fcn
  [../]
  [./iter_auxk]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./intnl_auxk]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 0
    variable = intnl
  [../]
[]

[Postprocessors]
  [./s_max]
    type = PointValue
    point = '0 0 0'
    variable = max_principal_stress
  [../]
  [./s_mid]
    type = PointValue
    point = '0 0 0'
    variable = mid_principal_stress
  [../]
  [./s_min]
    type = PointValue
    point = '0 0 0'
    variable = min_principal_stress
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
  [./intnl]
    type = PointValue
    point = '0 0 0'
    variable = intnl
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 1E-4
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1E7
    poissons_ratio = 0.3
  [../]
  [./mc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = ts
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    smoothing_tol = 5
    yield_function_tol = 1.0E-9
    max_NR_iterations = 100
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    perform_finite_strain_rotations = false
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform25
  csv = true
[]

modules/xfem/test/tests/solid_mechanics_basic/test_crack_counter.i

# This test is used to verify that the pure test object (TestCrackCounter)
# is correctly using the API for extracting the crack_tip_origin_direction_map
# from XFEM.  The map contains information of the location of all the crack tips
# computed by XFEM.  The TestCrackCounter postprocessor simply returns the
# number of elements in the map which corresponds to the number of cracks.
#
# In this test case 4 prescribed cracks are applied.  Therefore, the
# TestCrackCounter postprocessor returns a value of 4.

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 11
  ny = 11
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '1.0  0.5  0.7  0.5'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
  [./line_seg_cut_uo2]
    type = LineSegmentCutUserObject
    cut_data = '0.0  0.5  0.3  0.5'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
  [./line_seg_cut_uo3]
    type = LineSegmentCutUserObject
    cut_data = '0.5  0.0  0.5  0.3'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
  [./line_seg_cut_uo4]
    type = LineSegmentCutUserObject
    cut_data = '0.5  1.0  0.5  0.7'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    planar_formulation = plane_strain
    add_variables = true
  [../]
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x='0  50   100'
    y='0  0.02 0.1'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./topx]
    type = DirichletBC
    boundary = top
    variable = disp_x
    value = 0.0
  [../]
  [./topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = pull
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
    block = 0
  [../]

  [./_elastic_strain]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Postprocessors]
  [./number_of_cracks]
    type = TestCrackCounter
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-9

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
  num_steps = 5000

  max_xfem_update = 1
[]

[Outputs]
  csv = true
[]

modules/tensor_mechanics/test/tests/thermal_expansion_function/small_const.i

# This tests the thermal expansion coefficient function using both
# options to specify that function: mean and instantaneous.  There
# two blocks, each containing a single element, and these use the
# two variants of the function.

# In this test, the instantaneous CTE function has a constant value,
# while the mean CTE function is an analytic function designed to
# give the same response.  If \bar{alpha}(T) is the mean CTE function,
# and \alpha(T) is the instantaneous CTE function,

# \bar{\alpha}(T) = 1/(T-Tref) \intA^{T}_{Tsf} \alpha(T) dT

# where Tref is the reference temperature used to define the mean CTE
# function, and Tsf is the stress-free temperature.

# This version of the test uses small deformation theory.  The results
# from the two models are identical.

[Mesh]
  file = 'blocks.e'
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    block = '1 2'
    function = temp_func
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeLinearElasticStress
  [../]
  [./thermal_expansion_strain1]
    type = ComputeMeanThermalExpansionFunctionEigenstrain
    block = 1
    thermal_expansion_function = cte_func_mean
    thermal_expansion_function_reference_temperature = 0.5
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
  [./thermal_expansion_strain2]
    type = ComputeInstantaneousThermalExpansionFunctionEigenstrain
    block = 2
    thermal_expansion_function = cte_func_inst
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_func_mean]
    type = ParsedFunction
    vars = 'tsf tref scale' #stress free temp, reference temp, scale factor
    vals = '0.0 0.5  1e-4'
    value = 'scale * (t - tsf) / (t - tref)'
  [../]
  [./cte_func_inst]
    type = PiecewiseLinear
    xy_data = '0 1.0
               2 1.0'
    scale_factor = 1e-4
  [../]

  [./temp_func]
    type = PiecewiseLinear
    xy_data = '0 1
               1 2'
  [../]
[]

[Postprocessors]
  [./disp_1]
    type = NodalMaxValue
    variable = disp_x
    boundary = 101
  [../]

  [./disp_2]
    type = NodalMaxValue
    variable = disp_x
    boundary = 102
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  l_max_its = 100
  l_tol = 1e-4
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/check_error/contact_displacements.i

[Mesh]
  file = cube.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[BCs]
  [./2_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./2_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./2_z]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]
[]

[Contact]
  [./fred]
    master = 1
    slave = 2
    displacements = 'disp_x disp_y disp_z'
    system = Constraint
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeSmallStrain
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[]

[Outputs]
  file_base = out
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_elastic/rz_small_elastic.i

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 3
  ny = 3
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = ADStressDivergenceRZTensors
    component = 0
    variable = disp_r
  [../]
  [./stress_z]
    type = ADStressDivergenceRZTensors
    component = 1
    variable = disp_z
  [../]
[]

[BCs]
  [./bottom]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0
  [../]
  [./axial]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeAxisymmetricRZSmallStrain
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_thermal_expansion_function/instantaneous.i

# This test checks the thermal expansion calculated via a instantaneous thermal expansion coefficient.
# The coefficient is selected so as to result in a 1e-4 strain in the x-axis, and to cross over
# from positive to negative strain.

[Mesh]
  [./gen]
    type = GeneratedMeshGenerator
    dim = 3
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
    use_automatic_differentiation = true
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    function = '1 + t'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ADComputeInstantaneousThermalExpansionFunctionEigenstrain
    thermal_expansion_function = 4e-4
    stress_free_temperature = 1.5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Postprocessors]
  [./disp_x_max]
    type = SideAverageValue
    variable = disp_x
    boundary = right
  [../]
  [./temp_avg]
    type = ElementAverageValue
    variable = temp
  [../]
[]

[Executioner]
  type = Transient

  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking_deprecated.i

#
# Simple pull test for cracking.
# The stress increases for two steps and then drops to zero.

[Mesh]
  file = cracking_test.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./displ]
    type = PiecewiseLinear
    x = '0 1 2 3  4'
    y = '0 1 0 -1 0'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[BCs]
  [./pull]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = displ
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = 3
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.8e7
    poissons_ratio = 0
  [../]
  [./elastic_stress]
    type = ComputeSmearedCrackingStress
    cracking_stress = 1.68e6
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -sub_pc_type'
  petsc_options_value = '101                asm      lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  l_tol = 1e-5
  start_time = 0.0
  end_time = 0.1
  dt = 0.025
[]

[Outputs]
  exodus = true
  file_base = cracking_out
[]

modules/combined/test/tests/combined_plasticity_temperature/plasticity_temperature_dep_yield.i

#
# This is a test of the piece-wise linear strain hardening model using the
# small strain formulation.  This test exercises the temperature-dependent
# yield stress.
#
# Test procedure:
# 1. The element is pulled to and then beyond the yield stress for a given
# temperature.
# 2. The displacement is then constant while the temperature increases and
# the yield stress decreases.  This results in a lower stress with more
# plastic strain.
# 3. The temperature decreases beyond its original value giving a higher
# yield stress.  The displacement increases, causing increases stress to
# the new yield stress.
# 4. The temperature and yield stress are constant with increasing
# displacement giving a constant stress and more plastic strain.
#
# Plotting total_strain_yy on the x axis and stress_yy on the y axis shows
# the stress history in a clear way.
#
#  s |
#  t |            *****
#  r |           *
#  e |   *****  *
#  s |  *    * *
#  s | *     *
#    |*
#    +------------------
#           total strain
#

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy plastic_strain_xx plastic_strain_yy plastic_strain_zz'
  [../]
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1     2    4    5    6'
    y = '0 0.025 0.05 0.05 0.06 0.085'
  [../]
  [./yield]
    type = PiecewiseLinear
    x = '400 500 600'
    y = '6e3 5e3 4e3'
  [../]
  [./temp]
    type = PiecewiseLinear
    x = '0   1   2   3   4'
    y = '500 500 500 600 400'
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = top_pull
  [../]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp]
    type = FunctionDirichletBC
    variable = temp
    function = temp
    boundary = left
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 2.0e5
    poissons_ratio = 0.3
  [../]
  [./creep_plas]
    type = ComputeMultipleInelasticStress
    tangent_operator = elastic
    block = 0
    inelastic_models = 'plasticity'
    max_iterations = 50
    absolute_tolerance = 1e-05
  [../]
  [./plasticity]
    type = IsotropicPlasticityStressUpdate
    block = 0
    hardening_constant = 0
    yield_stress_function = yield
    temperature = temp
  [../]
  [./heat_conduction]
    type = HeatConductionMaterial
    block = 0
    specific_heat = 1
    thermal_conductivity = 1
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  end_time = 6
  dt = 0.1
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/single_pnt_2d/single_point_2d.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = single_point_2d.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./appl_disp]
    type = PiecewiseLinear
    x = '0 0.001  0.101'
    y = '0 0.0   -0.10'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./incslip_x]
    type = PenetrationAux
    variable = inc_slip_x
    quantity = incremental_slip_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./incslip_y]
    type = PenetrationAux
    variable = inc_slip_y
    quantity = incremental_slip_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./botx]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./boty]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./topx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = appl_disp
  [../]
  [./topy]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = -0.002001
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e9
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputePlaneFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputePlaneFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./disp_x]
    type = NodalVariableValue
    nodeid = 5
    variable = disp_x
  [../]
  [./disp_y]
    type = NodalVariableValue
    nodeid = 5
    variable = disp_y
  [../]
  [./inc_slip_x]
    type = NodalVariableValue
    nodeid = 5
    variable = inc_slip_x
  [../]
  [./inc_slip_y]
    type = NodalVariableValue
    nodeid = 5
    variable = inc_slip_y
  [../]
  [./accum_slip_x]
    type = NodalVariableValue
    nodeid = 5
    variable = accum_slip_x
  [../]
  [./accum_slip_y]
    type = NodalVariableValue
    nodeid = 5
    variable = accum_slip_y
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package -mat_superlu_dist_iterrefine'
  petsc_options_value = 'lu    superlu_dist 1'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 200
  dt = 0.001
  end_time = 0.001
  num_steps = 10000
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-8
  dtmin = 0.001
  l_tol = 1e-3
[]

[Outputs]
  file_base = single_point_2d_out_glued_kin
  exodus = true
  print_linear_residuals = true
  perf_graph = true
  csv = true
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    master = 2
    slave = 3
    model = glued
    system = constraint
    formulation = kinematic
    penalty = 1e12
    normalize_penalty = true
    tangential_tolerance = 1e-3
  [../]
[]

modules/tensor_mechanics/test/tests/tensile/small_deform9_update_version.i

# A single unit element is stretched in a complicated way
# that the trial stress is
#
#      1.16226      -0.0116587       0.0587872
#     -0.0116587         1.12695       0.0779428
#      0.0587872       0.0779428        0.710169
#
# This has eigenvalues
# la = {0.68849, 1.14101, 1.16987}
# and eigenvectors
#
# {-0.125484, -0.176871, 0.976202}
# {-0.0343704, -0.982614, -0.182451}
# {0.9915, -0.0564471, 0.117223}
#
# The tensile strength is 0.5 and Young=1 and Poisson=0.25.
# Using smoothing_tol=0.01, the return-map algorithm should
# return to, approximately, stress_I=stress_II=0.5.  This
# is a reduction of 0.65, so stress_III is approximately
# 0.68849 - 0.25 * 0.65 * 2 = 0.36.  The stress_I reduction of
# 0.67 gives an internal parameter of
# 0.67 / (E(1-v)/(1+v)/(1-2v)) = 0.558
# The final stress is
#
# {0.498, -0.003, 0.017},
# {-0.003, 0.495, 0.024},
# {0.017, 0.024,  0.367}

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    strain = finite
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz'
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '3*x+2*y+z'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '3*x-4*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = 'x-2*z'
  [../]
[]

[AuxVariables]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./f0_auxk]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1_auxk]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2_auxk]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./intnl_auxk]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 0
    variable = intnl
  [../]
[]

[Postprocessors]
  [./s_I]
    type = PointValue
    point = '0 0 0'
    variable = max_principal_stress
  [../]
  [./s_II]
    type = PointValue
    point = '0 0 0'
    variable = mid_principal_stress
  [../]
  [./s_III]
    type = PointValue
    point = '0 0 0'
    variable = min_principal_stress
  [../]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
  [./intnl]
    type = PointValue
    point = '0 0 0'
    variable = intnl
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 0.5
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.25
  [../]
  [./tensile]
    type = TensileStressUpdate
    tensile_strength = ts
    smoothing_tol = 0.001
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = tensile
    perform_finite_strain_rotations = false
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform9_update_version
  exodus = false
  [./csv]
    type = CSV
  [../]
[]

modules/combined/test/tests/solid_mechanics/LinearStrainHardening/LinearStrainHardeningRestart1.i

#

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = LinearStrainHardening_test.e
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]


[AuxVariables]

  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_mag]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]


[Functions]
  [./top_pull]
    type = ParsedFunction
    value = t/5.0
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]


[AuxKernels]

  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]

  [./plastic_strain_xx]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]

  [./plastic_strain_yy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]

  [./plastic_strain_zz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]

  [./plastic_strain_mag]
    type = MaterialRealAux
    property = effective_plastic_strain
    variable = plastic_strain_mag
  [../]

 []


[BCs]

  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = top_pull
  [../]

  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]

  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]

  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]

[]


[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'isoplas'
    block = '1'
  [../]
  [./isoplas]
    type = IsotropicPlasticityStressUpdate
    yield_stress = 2.4e2
    hardening_constant = 1206
    relative_tolerance = 1e-25
    absolute_tolerance = 1e-5
  [../]
[]



[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'


  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'


  line_search = 'none'


  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9
  start_time = 0.0
  end_time = 0.0105
  num_steps = 4
  dt = 1.5e-3
[]



[Outputs]
  exodus = true
  csv = true
  [./out]
    type = Checkpoint
    num_files = 1
  [../]
[]

modules/xfem/test/tests/crack_tip_enrichment/penny_crack_3d.i

[XFEM]
  qrule = volfrac
  output_cut_plane = true
  use_crack_tip_enrichment = true
  crack_front_definition = crack_front
  enrichment_displacements = 'enrich1_x enrich2_x enrich3_x enrich4_x enrich1_y enrich2_y enrich3_y enrich4_y enrich1_z enrich2_z enrich3_z enrich4_z'
  displacements = 'disp_x disp_y disp_z'
  cut_off_boundary = all
  cut_off_radius = 0.3
[]

[UserObjects]
  [./circle_cut_uo]
    type = CircleCutUserObject
    cut_data = '0 0 0
                0.5 0 0
                0 0.5 0'
  [../]
  [./crack_front]
    type = CrackFrontDefinition
    crack_direction_method = CurvedCrackFront
    crack_front_points = '0.500000000000000                   0                   0
                          0.000000000000000   0.500000000000000                   0
                         -0.500000000000000   0.000000000000000                   0
                         -0.000000000000000  -0.500000000000000                   0'
  [../]
[]

[Mesh]
  [gen]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 9
    ny = 9
    nz = 3
    xmin = -1.0
    xmax = 1.0
    ymin = -1.0
    ymax = 1.0
    zmin = -0.75
    zmax = 0.75
    elem_type = HEX8
  []
  [./all_node]
    type = BoundingBoxNodeSetGenerator
    input = gen
    new_boundary = 'all'
    top_right = '1 1 1'
    bottom_left = '-1 -1 -1'
  [../]
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
  type = RankTwoAux
  rank_two_tensor = stress
  variable = stress_xx
  index_i = 0
  index_j = 0
  execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = false
    volumetric_locking_correction = false
  [../]
[]

[BCs]
  [./top_z]
    type = Pressure
    variable = disp_z
    boundary = front
    component = 2
    factor = -1
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = back
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = back
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    boundary = back
    variable = disp_z
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeCrackTipEnrichmentSmallStrain
    displacements = 'disp_x disp_y disp_z'
    crack_front_definition = crack_front
    enrichment_displacements = 'enrich1_x enrich2_x enrich3_x enrich4_x enrich1_y enrich2_y enrich3_y enrich4_y enrich1_z enrich2_z enrich3_z enrich4_z'
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  [./Quadrature]
    type = GAUSS
    order = SECOND
  [../]

  # controls for linear iterations
  l_max_its = 10
  l_tol = 1e-2

  # controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-12

  # time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_1/cyl1_mu_0_2_pen.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl1_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = cyl1_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = cyl1_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x7 disp_y7 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    tangential_tolerance = 1e-3
    friction_coefficient = 0.2
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/thermal_coupling_rz.i

# Thermal eigenstrain coupling
[Mesh]
  type = GeneratedMesh
  dim = 2
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Variables]
  [./disp_r]
  [../]
  [./disp_z]
  [../]
  [./temperature]
  [../]
[]

[Kernels]
  [./cx_elastic]
    type = StressDivergenceRZTensors
    variable = disp_r
    temperature = temperature
    thermal_eigenstrain_name = thermal_contribution
    use_displaced_mesh = false
    component = 0
  [../]
  [./cz_elastic]
    type = StressDivergenceRZTensors
    variable = disp_z
    temperature = temperature
    thermal_eigenstrain_name = thermal_contribution
    use_displaced_mesh = false
    component = 1
  [../]
  [./temperature]
    type = Diffusion
    variable = temperature
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 10.0
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeAxisymmetricRZSmallStrain
    eigenstrain_names = thermal_contribution
  [../]
  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    temperature = temperature
    thermal_expansion_coeff = 1.0E2
    eigenstrain_name = thermal_contribution
    stress_free_temperature = 0.0
  [../]
  [./admissible]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  solve_type = NEWTON
  end_time = 1
  dt = 1
  type = Transient
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update6.i

# MC update version, with only Tensile with tensile strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.
# Returns to the plane of tensile yield

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0.5
    internal_limit = 2E-2
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-1 0.1 0.2  0.1 15 -0.3  0.2 -0.3 0'
    eigenstrain_name = ini_stress
  [../]
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update2.i

# MC update version, with only Tensile with tensile strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Return to the stress_I = stress_II ~1 edge

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2 0 0  0 0 0  0 0 2.01'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/j_integral_vtest/j_int_surfbreak_ellip_crack_sym_mm_cm.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = ellip_crack_4sym_norad_mm.e
  partitioner = centroid
  centroid_partitioner_direction = z
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./resid_z]
  [../]
[]

[Functions]
  [./rampConstantUp]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 0.1'
    scale_factor = -689.5 #MPa
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 1001
  crack_direction_method = CrackMouth
  crack_mouth_boundary = 11
  crack_end_direction_method = CrackDirectionVector
  crack_direction_vector_end_1 = '0.0 1.0 0.0'
  crack_direction_vector_end_2 = '1.0 0.0 0.0'
  radius_inner = '12.5 25.0 37.5'
  radius_outer = '25.0 37.5 50.0'
  intersecting_boundary = '1 2'
  symmetry_plane = 2
  position_type = angle
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 12
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 5
      function = rampConstantUp
    [../]
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 206800
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]

   type = Transient
  # Two sets of linesearch options are for petsc 3.1 and 3.3 respectively
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'
#  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 20
   nl_abs_tol = 1e-5
   nl_rel_tol = 1e-11
   l_tol = 1e-2

   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1
[]

[Postprocessors]
  [./_dt]
    type = TimestepSize
  [../]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./lin_its]
    type = NumLinearIterations
  [../]
  [./react_z]
    type = NodalSum
    variable = resid_z
    boundary = 5
  [../]
[]


[Outputs]
  execute_on = 'timestep_end'
  file_base = j_int_surfbreak_ellip_crack_sym_mm_cm_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/ad_isotropic_elasticity_tensor/lambda_shear_modulus_test.i

[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./stress_11]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    use_automatic_differentiation = true
  [../]
[]

[AuxKernels]
  [./stress_11]
    type = RankTwoAux
    variable = stress_11
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
  [../]
[]

[BCs]
  [./bottom]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./left]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./back]
    type = ADDirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./top]
    type = ADDirichletBC
    variable = disp_y
    boundary = top
    value = 0.001
  [../]
[]

[Materials]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 113636
    shear_modulus = 454545
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady
  l_max_its = 20
  nl_max_its = 10
  solve_type = NEWTON
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update16.i

# MC update version, with only Compressive with compressive strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.
# Returns to the plane of compressive yield

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0.5
    internal_limit = 2E-2
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '1 -0.1 -0.2  -0.1 -15 0.3  -0.2 0.3 0'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/xfem/test/tests/pressure_bc/inclined_edge_2d_pressure.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = False
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 9
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '0.0 0.33 0.5 0.67'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    generate_output = 'stress_xx stress_yy'
  [../]
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0 1.0 2.0'
    y = '0 500 1000'
  [../]
[]

[BCs]
  [./bottom_y]
    type = DirichletBC
    boundary = 0
    variable = disp_y
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    boundary = 2
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = 0
    variable = disp_x
    value = 0.0
  [../]
[]

[DiracKernels]
  [./pressure_x]
    type = XFEMPressure
    variable = disp_x
    component = 0
    function = pressure
  [../]

  [./pressure_y]
    type = XFEMPressure
    variable = disp_y
    component = 1
    function = pressure
  [../]
[]


[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-12

# time control
  start_time = 0.0
  dt = 1
  end_time = 2
[]

[Outputs]
  file_base = inclined_edge_2d_pressure_out
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/2D_different_planes/planestrain_yz.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = square_yz_plane.e
[]

[Variables]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
  [./disp_x]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./plane_strain]
    block = 1
    strain = SMALL
    out_of_plane_direction = x
    planar_formulation = PLANE_STRAIN
    eigenstrain_names = 'eigenstrain'
    generate_output = 'stress_xx stress_yz stress_yy stress_zz strain_xx strain_yz strain_yy strain_zz'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-y)*t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 4
    variable = disp_y
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 4
    variable = disp_z
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_stress]
    type = ComputeLinearElasticStress
    block = 1
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
[]

[Postprocessors]
  [./react_x]
    type = MaterialTensorIntegral
    use_displaced_mesh = false
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-10

# controls for nonlinear iterations
  nl_max_its = 10
  nl_rel_tol = 1e-12

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  file_base = planestrain_yz_small_out
  exodus = true
[]

modules/combined/test/tests/ad_power_law_creep/power_law_creep.i

# 1x1x1 unit cube with uniform pressure on top face

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[Variables]
  [./temp]
    initial_condition = 1000.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy creep_strain_xx creep_strain_yy creep_strain_zz elastic_strain_yy'
    use_automatic_differentiation = true
  [../]
[]

[Kernels]
  [./heat]
    type = ADHeatConduction
    variable = temp
  [../]
  [./heat_ie]
    type = ADHeatConductionTimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./u_top_pull]
    type = ADPressure
    variable = disp_y
    component = 1
    boundary = top
    constant = -10.0e6
  [../]
  [./u_bottom_fix]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = ADDirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp_fix]
    type = DirichletBC
    variable = temp
    boundary = 'bottom top'
    value = 1000.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e11
    poissons_ratio = 0.3
  [../]
  [./radial_return_stress]
    type = ADComputeMultipleInelasticStress
    inelastic_models = 'power_law_creep'
  [../]
  [./power_law_creep]
    type = ADPowerLawCreepStressUpdate
    coefficient = 1.0e-15
    n_exponent = 4
    activation_energy = 3.0e5
    temperature = temp
  [../]

  [./thermal]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 100.
  [../]
  [./density]
    type = ADDensity
    density = 1.0
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 20
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-6
  l_tol = 1e-5
  start_time = 0.0
  end_time = 1.0
  num_steps = 10
  dt = 0.1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_elastic/incremental_small_elastic.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 3
  ny = 3
  nz = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_x]
    scaling = 1e-10
  [../]
  [./disp_y]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_x]
    type = ADStressDivergenceTensors
    component = 0
    variable = disp_x
  [../]
  [./stress_y]
    type = ADStressDivergenceTensors
    component = 1
    variable = disp_y
  [../]
  [./stress_z]
    type = ADStressDivergenceTensors
    component = 2
    variable = disp_z
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeIncrementalSmallStrain
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/multiple_two_parameter_plasticity/dp_and_wp.i

# Use ComputeMultipleInelasticStress with two inelastic models: CappedDruckerPrager and CappedWeakPlane.
# The relative_tolerance and absolute_tolerance parameters are set small so that many
# Picard iterations need to be performed.
#
# The CappedDruckerPrager has tensile strength 3E2 and large cohesion,
# and the return-map sets stress = trial_stress - diag(d, d, d), for
# some d to be determined
# The CappedWeakPlane has tensile strength zero and large cohesion,
# and the return-map sets stress = diag(t - v*w/(1-v), t - v*w/(1-v), t - w)
# where t is trial stress, v is Poisson's ratio, and w is to be determined
#
# d and w are determined by demanding that the final stress shouldn't depend
# on the order of return-mapping (DP first then WP, or WP first then DP).
#
# Let the initial_stress = diag(I, I, I).
# The returned stress is diag(I - d - v*w/(1-v), I - d - v*w/(1-v), I - d - w).  This
# must obey Tr(stress) <= dp_tensile_strength, and I-d-w <= wp_tensile_strength.
#
# For I = 1E3, and v = 0.2, the solution is d = 800 and w = 200, with
# stress = diag(150, 150, 0)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    eigenstrain_names = ini_stress
    generate_output = 'stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz'
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = 0
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = 0
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = 0
  [../]
[]

[AuxVariables]
  [./yield_fcn_dp]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn_wp]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_dp_auxk]
    type = MaterialStdVectorAux
    index = 1    # this is the tensile yield function - it should be zero
    property = cdp_plastic_yield_function
    variable = yield_fcn_dp
  [../]
  [./yield_fcn_wp_auxk]
    type = MaterialStdVectorAux
    index = 1    # this is the tensile yield function - it should be zero
    property = cwp_plastic_yield_function
    variable = yield_fcn_wp
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f_dp]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn_dp
  [../]
  [./f_wp]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn_wp
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 300
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 20
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 0
  [../]
  [./dp]
    type = TensorMechanicsPlasticDruckerPrager
    mc_cohesion = mc_coh
    mc_friction_angle = mc_phi
    mc_dilation_angle = mc_psi
    internal_constraint_tolerance = 1 # irrelevant here
    yield_function_tolerance = 1      # irrelevant here
  [../]
  [./wp_coh]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
  [./wp_tanphi]
    type = TensorMechanicsHardeningConstant
    value = 0.5
  [../]
  [./wp_tanpsi]
    type = TensorMechanicsHardeningConstant
    value = 0.1111077
  [../]
  [./wp_t_strength]
    type = TensorMechanicsHardeningConstant
    value = 0
  [../]
  [./wp_c_strength]
    type = TensorMechanicsHardeningConstant
    value = 1E4
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.2
    youngs_modulus = 1E7
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '1E3 0 0  0 1E3 0  0 0 1E3'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    relative_tolerance = 1E-8
    inelastic_models = 'cdp cwp'
    perform_finite_strain_rotations = false
  [../]
  [./cdp]
    type = CappedDruckerPragerStressUpdate
    base_name = cdp
    DP_model = dp
    tensile_strength = ts
    compressive_strength = cs
    yield_function_tol = 1E-5
    tip_smoother = 1E3
    smoothing_tol = 1E3
  [../]
  [./cwp]
    type = CappedWeakPlaneStressUpdate
    base_name = cwp
    cohesion = wp_coh
    tan_friction_angle = wp_tanphi
    tan_dilation_angle = wp_tanpsi
    tensile_strength = wp_t_strength
    compressive_strength = wp_c_strength
    tip_smoother = 1E3
    smoothing_tol = 1E3
    yield_function_tol = 1E-5
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = dp_and_wp
  csv = true
[]

modules/combined/test/tests/ad_cavity_pressure/negative_volume.i

#
# Cavity Pressure Test
#
# This test is designed to compute a negative number of moles
# to trigger an error check in the CavityPressureUserObject.
# The negative number of moles is achieved by supplying an
# open volume to the InternalVolume postprocessor, which
# calculates a negative volume.

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 1
  ny = 2
[]

[Functions]
  [./temperature]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 2'
    scale_factor = 100
  [../]
[]

[Variables]
  [./temperature]
    initial_condition = 100
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    strain = FINITE
    add_variables = true
    use_automatic_differentiation = true
  [../]
[]

[Kernels]
  [./heat]
    type = Diffusion
    variable = temperature
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./no_x]
    type = ADDirichletBC
    variable = disp_r
    boundary = left
    value = 0.0
  [../]
  [./no_y]
    type = ADDirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]
  [./temperatureInterior]
    type = ADFunctionDirichletBC
    boundary = 2
    function = temperature
    variable = temperature
  [../]
  [./CavityPressure]
    [./pressure]
      boundary = 'top bottom right'
      initial_pressure = 10e5
      R = 8.3143
      output_initial_moles = initial_moles
      temperature = aveTempInterior
      volume = internalVolume
      startup_time = 0.5
      output = ppress
      use_automatic_differentiation = true
    [../]
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress1]
    type = ADComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'NEWTON'

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_abs_tol = 1e-10
  l_max_its = 20
  dt = 0.5
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 'top bottom right'
    execute_on = 'initial linear'
  [../]
  [./aveTempInterior]
    type = AxisymmetricCenterlineAverageValue
    boundary = left
    variable = temperature
    execute_on = 'initial linear'
  [../]
[]

[Outputs]
  exodus = false
[]

modules/tensor_mechanics/test/tests/stickyBC/except1.i

# Exception testing of StickyBC.  Here min_value > max_value
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
  [../]
[]

[BCs]
  [./obstruction]
    type = StickyBC
    variable = disp_y
    boundary = bottom
    min_value = 1
    max_value = -1
  [../]
[]

[Materials]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1.0
    poissons_ratio = 0.2
  [../]
[]

[Executioner]
  type = Transient
[]

modules/tensor_mechanics/test/tests/ad_simple_linear/linear-ad-reverse-dependency.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./stress_x]
    type = ADStressDivergenceTensors
    component = 0
    variable = disp_x
  [../]
  [./stress_y]
    type = ADStressDivergenceTensors
    component = 1
    variable = disp_y
  [../]
  [./stress_z]
    type = ADStressDivergenceTensors
    component = 2
    variable = disp_z
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
[]

[Materials]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
  [./strain]
    type = ADComputeSmallStrain
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = "linear-out"
[]

modules/tensor_mechanics/test/tests/domain_integral_thermal/interaction_integral_2d.i

#This problem from [Wilson 1979] tests the thermal strain term in the
#interaction integral
#
#theta_e = 10 degrees C; a = 252; E = 207000; nu = 0.3; alpha = 1.35e-5
#
#With uniform_refine = 3, KI converges to
#KI = 5.602461e+02 (interaction integral)
#KI = 5.655005e+02 (J-integral)
#
#Both are in good agreement with [Shih 1986]:
#average_value = 0.4857 = KI / (sigma_theta * sqrt(pi * a))
#sigma_theta = E * alpha * theta_e / (1 - nu)
# = 207000 * 1.35e-5 * 10 / (1 - 0.3) = 39.9214
#KI = average_value * sigma_theta * sqrt(pi * a) = 5.656e+02
#
#References:
#W.K. Wilson, I.-W. Yu, Int J Fract 15 (1979) 377-387
#C.F. Shih, B. Moran, T. Nakamura, Int J Fract 30 (1986) 79-102

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = False
[]

[Mesh]
  file = crack2d.e
  displacements = 'disp_x disp_y'
#  uniform_refine = 3
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = 10.0*(2*x/504)
  [../]
[]

[DomainIntegral]
  integrals = 'JIntegral InteractionIntegralKI'
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  radius_inner = '60.0 80.0 100.0 120.0'
  radius_outer = '80.0 100.0 120.0 140.0'
  convert_J_to_K = true
  symmetry_plane = 1
  incremental = true

  # interaction integral parameters
  disp_x = disp_x
  disp_y = disp_y
  block = 1
  youngs_modulus = 207000
  poissons_ratio = 0.3
  temperature = temp
  eigenstrain_names = thermal_expansion
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
    eigenstrain_names = thermal_expansion
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    block = 1
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 400
    value = 0.0
  [../]
  [./no_x1]
    type = DirichletBC
    variable = disp_x
    boundary = 900
    value = 0.0
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 0.0
    thermal_expansion_coeff = 1.35e-5
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]
[]


[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart -sub_ksp_type -sub_pc_type -pc_asm_overlap'
  petsc_options_value = 'asm         31   preonly   lu      1'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 40

   nl_rel_step_tol= 1e-10
   nl_rel_tol = 1e-10


   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1

[]

[Outputs]
  file_base = interaction_integral_2d_out
  exodus = true
  csv = true
[]

[Preconditioning]
  active = 'smp'
  [./smp]
    type = SMP
    pc_side = left
    ksp_norm = preconditioned
    full = true
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_1/brick1_mu_0_2_pen.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick1_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
  [./tang_force_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_x
  [../]
  [./disp_x13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_x
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_y
  [../]
  [./disp_y13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_y
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  file_base = brick1_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = brick1_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x5 disp_x8 disp_x13 disp_x16 disp_y5 disp_y8 disp_y13 disp_y16 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+9
  [../]
[]

modules/peridynamics/test/tests/jacobian_check/2D_mechanics_BPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = BOND
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.33
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialBPD
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1
[]

modules/combined/test/tests/contact_verification/hertz_cyl/half_symm_q8/hertz_cyl_half_1deg_template3.i

[GlobalParams]
  order = SECOND
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_half_1deg.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 11.'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 1. 11.'
    y = '0. 0.0 0.0014'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./disp_x639]
    type = NodalVariableValue
    nodeid = 638
    variable = disp_x
  [../]
  [./disp_y639]
    type = NodalVariableValue
    nodeid = 638
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disp_ramp_vert
  [../]
  [./top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = disp_ramp_horz
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
  [./stuff5_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '5'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff5_strain]
    type = ComputeFiniteStrain
    block = '5'
  [../]
  [./stuff5_stress]
    type = ComputeFiniteStrainElasticStress
    block = '5'
  [../]
  [./stuff6_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '6'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff6_strain]
    type = ComputeFiniteStrain
    block = '6'
  [../]
  [./stuff6_stress]
    type = ComputeFiniteStrainElasticStress
    block = '6'
  [../]
  [./stuff7_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '7'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff7_strain]
    type = ComputeFiniteStrain
    block = '7'
  [../]
  [./stuff7_stress]
    type = ComputeFiniteStrainElasticStress
    block = '7'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 200

  start_time = 0.0
  end_time = 2.0
  l_tol = 5e-4
  dt = 0.1
  dtmin = 0.1
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./chkfile2]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x639 disp_y639 top_react_x top_react_y'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    master = 2
    slave = 3
    model = coulomb
    friction_coefficient = 0.0
    system = constraint
    formulation = penalty
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

[Dampers]
  [./contact_slip]
    type = ContactSlipDamper
    master = '2'
    slave = '3'
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/single_pnt_2d/single_point_2d_contact_line_search.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = single_point_2d.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./appl_disp]
    type = PiecewiseLinear
    x = '0 0.001  0.101'
    y = '0 0.0   -0.10'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./incslip_x]
    type = PenetrationAux
    variable = inc_slip_x
    quantity = incremental_slip_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./incslip_y]
    type = PenetrationAux
    variable = inc_slip_y
    quantity = incremental_slip_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./botx]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./boty]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./topx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = appl_disp
  [../]
  [./topy]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = -0.002001
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e9
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputePlaneFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputePlaneFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Postprocessors]
  [./disp_x]
    type = NodalVariableValue
    nodeid = 5
    variable = disp_x
  [../]
  [./disp_y]
    type = NodalVariableValue
    nodeid = 5
    variable = disp_y
  [../]
  [./inc_slip_x]
    type = NodalVariableValue
    nodeid = 5
    variable = inc_slip_x
  [../]
  [./inc_slip_y]
    type = NodalVariableValue
    nodeid = 5
    variable = inc_slip_y
  [../]
  [./accum_slip_x]
    type = NodalVariableValue
    nodeid = 5
    variable = accum_slip_x
  [../]
  [./accum_slip_y]
    type = NodalVariableValue
    nodeid = 5
    variable = accum_slip_y
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package -mat_superlu_dist_iterrefine'
  petsc_options_value = 'lu    superlu_dist 1'

  line_search = 'contact'
  contact_line_search_allowed_lambda_cuts = 0
  contact_line_search_ltol = 0.5

  l_max_its = 15
  nl_max_its = 10
  dt = 0.001
  end_time = 0.002
  num_steps = 10000
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-8
  dtmin = 0.001
  l_tol = 1e-3
[]

[Outputs]
  exodus = true
  print_linear_residuals = true
  perf_graph = true
  csv = true
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    master = 2
    slave = 3
    model = frictionless
    system = constraint
    formulation = kinematic
    penalty = 1e12
    normalize_penalty = true
    tangential_tolerance = 1e-3
  [../]
[]

modules/combined/test/tests/thermo_mech/thermo_mech.i

#Run with 4 procs
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  temperature = temp
  volumetric_locking_correction = true
[]

[Mesh]
  file = cube.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]

  [./temp]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]

  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./bottom_temp]
    type = DirichletBC
    variable = temp
    boundary = 1
    value = 10.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1.0
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeSmallStrain
    eigenstrain_names = eigenstrain
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 0.0
    thermal_expansion_coeff = 1e-5
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]

  [./heat]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]

  [./density]
    type = Density
    density = 1.0
    disp_x = disp_x
    disp_y = disp_y
    disp_z = disp_z
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-14
  l_tol = 1e-3

  l_max_its = 100

  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/jacobian/phe01.i

# Capped weak-plane plasticity, Kernel = PlasticHeatEnergy
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./silly_phe]
    type = PlasticHeatEnergy
    coeff = 0.5
    variable = disp_x
  [../]
  [./dummy_disp_y]
    type = TimeDerivative
    variable = disp_y
  [../]
  [./dummy_disp_z]
    type = TimeDerivative
    variable = disp_z
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 2
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 0.5
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.05
    rate = 3
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 100
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0
    internal_0 = -2
    internal_limit = 0
  [../]
[]

[Materials]
  [./phe]
    type = ComputePlasticHeatEnergy
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 0  0 0 1  0 1 -1.5'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 0
    smoothing_tol = 1
    yield_function_tol = 1E-10
    perfect_guess = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/thermal_strain/thermal_strain.i

# Patch Test

# This test is designed to compute displacements from a thermal strain.

# The cube is displaced by 1e-6 units in x, 2e-6 in y, and 3e-6 in z.
#  The faces are sheared as well (1e-6, 2e-6, and 3e-6 for xy, yz, and
#  zx).  This gives a uniform strain/stress state for all six unique
#  tensor components.

# The temperature moves 100 degrees, and the coefficient of thermal
#  expansion is 1e-6.  Therefore, the strain (and the displacement
#  since this is a unit cube) is 1e-4.
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = thermal_strain_test.e
[]

[Functions]
  [./tempFunc]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '117.56 217.56'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]

  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules/TensorMechanics/Master]
  use_displaced_mesh = true
  add_variables = true
  strain = SMALL
  incremental = true
  generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'

  [./block1]
    eigenstrain_names = eigenstrain1
    block = 1
  [../]
  [./block2]
    eigenstrain_names = eigenstrain2
    block = 2
  [../]
  [./block3]
    eigenstrain_names = eigenstrain3
    block = 3
  [../]
  [./block4]
    eigenstrain_names = eigenstrain4
    block = 4
  [../]
  [./block5]
    eigenstrain_names = eigenstrain5
    block = 5
  [../]
  [./block6]
    eigenstrain_names = eigenstrain6
    block = 6
  [../]
  [./block7]
    eigenstrain_names = eigenstrain7
    block = 7
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 10
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 9
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 14
    value = 0
  [../]

  [./temp]
    type = FunctionDirichletBC
    variable = temp
    boundary = '10 12'
    function = tempFunc
  [../]
[]

[Materials]
  [./elasticity_tensor1]
    type = ComputeIsotropicElasticityTensor
    block = 1
    bulk_modulus = 0.333333333333e6
    poissons_ratio = 0.0
  [../]
  [./thermal_strain1]
    type = ComputeThermalExpansionEigenstrain
    block = 1
    temperature = temp
    stress_free_temperature = 117.56
    thermal_expansion_coeff = 1e-6
    eigenstrain_name = eigenstrain1
  [../]
  [./stress1]
    type = ComputeStrainIncrementBasedStress
    block = 1
  [../]

  [./elasticity_tensor2]
    type = ComputeIsotropicElasticityTensor
    block = 2
    bulk_modulus = 0.333333333333e6
    lambda = 0.0
  [../]
  [./thermal_strain2]
    type = ComputeThermalExpansionEigenstrain
    block = 2
    temperature = temp
    stress_free_temperature = 117.56
    thermal_expansion_coeff = 1e-6
    eigenstrain_name = eigenstrain2
  [../]
  [./stress2]
    type = ComputeStrainIncrementBasedStress
    block = 2
  [../]

  [./elasticity_tensor3]
    type = ComputeIsotropicElasticityTensor
    block = 3
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]
  [./thermal_strain3]
    type = ComputeThermalExpansionEigenstrain
    block = 3
    temperature = temp
    stress_free_temperature = 117.56
    thermal_expansion_coeff = 1e-6
    eigenstrain_name = eigenstrain3
  [../]
  [./stress3]
    type = ComputeStrainIncrementBasedStress
    block = 3
  [../]

  [./elasticity_tensor4]
    type = ComputeIsotropicElasticityTensor
    block = 4
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]
  [./thermal_strain4]
    type = ComputeThermalExpansionEigenstrain
    block = 4
    temperature = temp
    stress_free_temperature = 117.56
    thermal_expansion_coeff = 1e-6
    eigenstrain_name = eigenstrain4
  [../]
  [./stress4]
    type = ComputeStrainIncrementBasedStress
    block = 4
  [../]

  [./elasticity_tensor5]
    type = ComputeIsotropicElasticityTensor
    block = 5
    youngs_modulus = 1e6
    lambda = 0.0
  [../]
  [./thermal_strain5]
    type = ComputeThermalExpansionEigenstrain
    block = 5
    temperature = temp
    stress_free_temperature = 117.56
    thermal_expansion_coeff = 1e-6
    eigenstrain_name = eigenstrain5
  [../]
  [./stress5]
    type = ComputeStrainIncrementBasedStress
    block = 5
  [../]

  [./elasticity_tensor6]
    type = ComputeIsotropicElasticityTensor
    block = 6
    youngs_modulus = 1e6
    shear_modulus = 5e5
  [../]
  [./thermal_strain6]
    type = ComputeThermalExpansionEigenstrain
    block = 6
    temperature = temp
    stress_free_temperature = 117.56
    thermal_expansion_coeff = 1e-6
    eigenstrain_name = eigenstrain6
  [../]
  [./stress6]
    type = ComputeStrainIncrementBasedStress
    block = 6
  [../]

  [./elasticity_tensor7]
    type = ComputeIsotropicElasticityTensor
    block = 7
    shear_modulus = 5e5
    poissons_ratio = 0.0
  [../]
  [./thermal_strain7]
    type = ComputeThermalExpansionEigenstrain
    block = 7
    temperature = temp
    stress_free_temperature = 117.56
    thermal_expansion_coeff = 1e-6
    eigenstrain_name = eigenstrain7
  [../]
  [./stress7]
    type = ComputeStrainIncrementBasedStress
    block = 7
  [../]

  [./heat]
    type = HeatConductionMaterial
    block = '1 2 3 4 5 6 7'
    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]

  [./density]
    type = Density
    block = '1 2 3 4 5 6 7'
    density = 1.0
    disp_x = disp_x
    disp_y = disp_y
    disp_z = disp_z
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10

  l_max_its = 20

  start_time = 0.0
  dt = 0.5
  num_steps = 2
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_isotropic_elasticity_tensor/youngs_modulus_poissons_ratio_test.i

[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_11]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    use_automatic_differentiation = true
  [../]
[]

[AuxKernels]
  [./stress_11]
    type = RankTwoAux
    variable = stress_11
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
  [../]
[]

[BCs]
  [./bottom]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./left]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./back]
    type = ADDirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./top]
    type = ADDirichletBC
    variable = disp_y
    boundary = top
    value = 0.001
  [../]
[]

[Materials]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.1
    youngs_modulus = 1e6
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady
  l_max_its = 20
  nl_max_its = 10
  solve_type = NEWTON
[]

[Outputs]
  exodus = true
[]

modules/porous_flow/test/tests/heterogeneous_materials/vol_expansion_poroperm.i

# Apply an increasing porepressure, with zero mechanical forces,
# and observe the corresponding volumetric expansion and porosity increase.
# Check that permeability is calculated correctly from porosity.
#
# P = t
# With the Biot coefficient being 1, the effective stresses should be
# stress_xx = stress_yy = stress_zz = t
# With bulk modulus = 1 then should have
# vol_strain = strain_xx + strain_yy + strain_zz = t.
#
# With the biot coefficient being 1, the porosity (phi) # at time t is:
# phi = 1 - (1 - phi0) / exp(vol_strain)
# where phi0 is the porosity at t = 0 and P = 0.
#
# The permeability (k) is
# k = k_anisotropic * f * d^2 * phi^n / (1-phi)^m

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = 0
  xmax = 1
  ymin = 0
  ymax = 1
  zmin = 0
  zmax = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  block = 0
  PorousFlowDictator = dictator
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./p]
  [../]
[]

[BCs]
  [./p]
    type = FunctionDirichletBC
    boundary = 'bottom top'
    variable = p
    function = t
  [../]
  [./xmin]
    type = DirichletBC
    boundary = left
    variable = disp_x
    value = 0
  [../]
  [./ymin]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0
  [../]
  [./zmin]
    type = DirichletBC
    boundary = back
    variable = disp_z
    value = 0
  [../]
[]

[Kernels]
  [./p_does_not_really_diffuse]
    type = Diffusion
    variable = p
  [../]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./poro_x]
    type = PorousFlowEffectiveStressCoupling
    biot_coefficient = 1
    variable = disp_x
    component = 0
  [../]
  [./poro_y]
    type = PorousFlowEffectiveStressCoupling
    biot_coefficient = 1
    variable = disp_y
    component = 1
  [../]
  [./poro_z]
    type = PorousFlowEffectiveStressCoupling
    biot_coefficient = 1
    variable = disp_z
    component = 2
  [../]
[]

[AuxVariables]
  [./poro0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./poro]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./perm_x]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./perm_y]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./perm_z]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[ICs]
  [./poro0]
    type = RandomIC
    seed = 0
    variable = poro0
    max = 0.15
    min = 0.05
  [../]
[]

[AuxKernels]
  [./poromat]
    type = PorousFlowPropertyAux
    property = porosity
    variable = poro
  [../]
  [./perm_x]
    type = PorousFlowPropertyAux
    property = permeability
    variable = perm_x
    row = 0
    column = 0
  [../]
  [./perm_y]
    type = PorousFlowPropertyAux
    property = permeability
    variable = perm_y
    row = 1
    column = 1
  [../]
  [./perm_z]
    type = PorousFlowPropertyAux
    property = permeability
    variable = perm_z
    row = 2
    column = 2
  [../]
[]

[UserObjects]
  [./dictator]
    type = PorousFlowDictator
    porous_flow_vars = 'p'
    number_fluid_phases = 1
    number_fluid_components = 1
  [../]
  [./pc]
    type = PorousFlowCapillaryPressureVG
    m = 0.5
    alpha = 1
  [../]
[]

[Materials]
  [./temperature]
    type = PorousFlowTemperature
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 1
    shear_modulus = 1
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./vol_strain]
    type = PorousFlowVolumetricStrain
  [../]
  [./ppss]
    type = PorousFlow1PhaseP
    porepressure = p
    capillary_pressure = pc
  [../]
  [./p_eff]
    type = PorousFlowEffectiveFluidPressure
  [../]
  [./porosity]
    type = PorousFlowPorosity
    fluid = true
    mechanical = true
    porosity_zero = poro0
    solid_bulk = 1
    biot_coefficient = 1
  [../]
  [./permeability]
    type = PorousFlowPermeabilityKozenyCarman
    k_anisotropy = '1 0 0  0 2 0  0 0 0.1'
    poroperm_function = kozeny_carman_fd2
    f = 0.1
    d = 5
    m = 2
    n = 7
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -ksp_atol -ksp_rtol'
    petsc_options_value = 'gmres bjacobi 1E-10 1E-10 10 1E-15 1E-10'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  start_time = 0
  dt = 0.1
  end_time = 1
[]

[Outputs]
  exodus = true
  execute_on = 'timestep_end'
[]

modules/tensor_mechanics/test/tests/action/two_block_base_name.i

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  []
  [block1]
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 0 0'
    top_right = '0.5 1 0'
    input = generated_mesh
  []
  [block2]
    type = SubdomainBoundingBoxGenerator
    block_id = 2
    bottom_left = '0.5 0 0'
    top_right = '1 1 0'
    input = block1
  []
[]
[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Modules/TensorMechanics/Master]
  # parameters that apply to all subblocks are specified at this level. They
  # can be overwritten in the subblocks.
  add_variables = true
  strain = FINITE
  generate_output = 'stress_xx'
  # base_name can be specified inside or outside a block
  base_name = 'block1'

  [./block1]
    # the `block` parameter is only valid insde a subblock.
    block = 1
  [../]
  [./block2]
    block = 2
    # the `additional_generate_output` parameter is also only valid inside a
    # subblock. Values specified here are appended to the `generate_output`
    # parameter values.
    additional_generate_output = 'strain_yy'
    base_name = 'block2'
  [../]
[]

[AuxVariables]
  [./stress_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_theta]
    type = RankTwoAux
    block = 1
    rank_two_tensor = block1_stress
    index_i = 2
    index_j = 2
    variable = stress_theta
    execute_on = timestep_end
  [../]
  [./strain_theta]
    type = RankTwoAux
    block = 2
    rank_two_tensor = block2_total_strain
    index_i = 2
    index_j = 2
    variable = strain_theta
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor_1]
    type = ComputeIsotropicElasticityTensor
    block = 1
    base_name = block1
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./elasticity_tensor_2]
    type = ComputeIsotropicElasticityTensor
    block = 2
    base_name = block2
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./_elastic_stress1]
    type = ComputeFiniteStrainElasticStress
    block = 1
    base_name = block1
  [../]
  [./_elastic_stress2]
    type = ComputeFiniteStrainElasticStress
    block = 2
    base_name = block2
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    boundary = 'left'
    variable = disp_x
    value = 0.0
  [../]
  [./top]
    type = DirichletBC
    boundary = 'top'
    variable = disp_y
    value = 0.0
  [../]
  [./right]
    type = DirichletBC
    boundary = 'right'
    variable = disp_x
    value = 0.01
  [../]
  [./bottom]
    type = DirichletBC
    boundary = 'bottom'
    variable = disp_y
    value = 0.01
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Executioner]
  type = Steady

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_2/cyl2_template1.i

#
# This input file is a template for both the frictionless and glued test
# variations for the current problem geometry. In order to create an input
# file to run outside the runtest framework, look at the tests file and add the
# appropriate input file lines from the cli_args line.
#

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl2_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 1000
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_y5 disp_x9 disp_y9 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/ad_plastic/power_law_creep.i

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 2
  second_order = true
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[AuxVariables]
  [./hydrostatic_stress]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./hydrostatic_stress]
    type = RankTwoScalarAux
    variable = hydrostatic_stress
    rank_two_tensor = stress
    scalar_type = Hydrostatic
  [../]
[]

[Variables]
  [./disp_x]
    order = SECOND
    scaling = 1e-10
  [../]
  [./disp_y]
    order = SECOND
    scaling = 1e-10
  [../]
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x = '0 10'
    y = '0 1e-3'
  [../]
[]

[Kernels]
  [./stress_x]
    type = ADStressDivergenceTensors
    component = 0
    variable = disp_x
  [../]
  [./stress_y]
    type = ADStressDivergenceTensors
    component = 1
    variable = disp_y
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ADComputeIncrementalSmallStrain
  [../]
  [./elastic_strain]
    type = ADComputeMultipleInelasticStress
  [../]

  [./creep_ten]
    type = ADPowerLawCreepStressUpdate
    coefficient = 10e-24
    n_exponent = 4
    activation_energy = 0
    base_name = creep_ten
  [../]
  [./creep_ten2]
    type = ADPowerLawCreepStressUpdate
    coefficient = 10e-24
    n_exponent = 4
    activation_energy = 0
    base_name = creep_ten2
  [../]
  [./creep_one]
    type = ADPowerLawCreepStressUpdate
    coefficient = 1e-24
    n_exponent = 4
    activation_energy = 0
    base_name = creep_one
  [../]
  [./creep_nine]
    type = ADPowerLawCreepStressUpdate
    coefficient = 9e-24
    n_exponent = 4
    activation_energy = 0
    base_name = creep_nine
  [../]
  [./creep_zero]
    type = ADPowerLawCreepStressUpdate
    coefficient = 0e-24
    n_exponent = 4
    activation_energy = 0
    base_name = creep_zero
  [../]
[]

[BCs]
  [./no_disp_x]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]

  [./no_disp_y]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./pull_disp_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = top
    function = pull
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  line_search = 'none'
  nl_rel_tol = 1e-5

  num_steps = 5
  dt = 1e-1
[]

[Postprocessors]
  [./max_disp_x]
    type = ElementExtremeValue
    variable = disp_x
  [../]
  [./max_disp_y]
    type = ElementExtremeValue
    variable = disp_y
  [../]
  [./max_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
  [../]
  [./dt]
    type = TimestepSize
  [../]
  [./num_lin]
    type = NumLinearIterations
    outputs = console
  [../]
  [./num_nonlin]
    type = NumNonlinearIterations
    outputs = console
  [../]
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/power_law_creep/power_law_creep.i

# 1x1x1 unit cube with uniform pressure on top face

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
    initial_condition = 1000.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy creep_strain_xx creep_strain_yy creep_strain_zz elastic_strain_yy'
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1'
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
  [./heat_ie]
    type = HeatConductionTimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./u_top_pull]
    type = Pressure
    variable = disp_y
    component = 1
    boundary = top
    factor = -10.0e6
    function = top_pull
  [../]
  [./u_bottom_fix]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp_fix]
    type = DirichletBC
    variable = temp
    boundary = 'bottom top'
    value = 1000.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e11
    poissons_ratio = 0.3
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'power_law_creep'
    tangent_operator = elastic
  [../]
  [./power_law_creep]
    type = PowerLawCreepStressUpdate
    coefficient = 1.0e-15
    n_exponent = 4
    activation_energy = 3.0e5
    temperature = temp
  [../]

  [./thermal]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 100.
  [../]
  [./density]
    type = Density
    density = 1.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 20
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-6
  l_tol = 1e-5
  start_time = 0.0
  end_time = 1.0
  num_steps = 10
  dt = 0.1
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_3/cyl3_template1.i

#
# This input file is a template for both the frictionless and glued test
# variations for the current problem geometry. In order to create an input
# file to run outside the runtest framework, look at the tests file and add the
# appropriate input file lines from the cli_args line.
#

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl3_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 1000
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x11 disp_y11 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/2D_different_planes/planestrain_jacobian_testing_xy.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = square_xy_plane.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./plane_strain]
    block = 1
    strain = SMALL
    out_of_plane_direction = z
    planar_formulation = PLANE_STRAIN
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.0
    youngs_modulus = 1
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  petsc_options_iname = '-ksp_type -pc_type -snes_type'
  petsc_options_value = 'bcgs bjacobi test'

  end_time = 1.0
[]

modules/tensor_mechanics/test/tests/dynamics/prescribed_displacement/3D_QStatic_1_Ramped_Displacement.i

# One 3D element under ramped displacement loading.
#
# loading:
# time : 0.0 0.1  0.2  0.3
# disp : 0.0 0.0 -0.01 -0.01

# This displacement loading is applied using the PresetDisplacement boundary condition.

# Here, the given displacement time history is converted to an acceleration
# time history using Backward Euler time differentiation. Then, the resulting
# acceleration is integrated using Newmark time integration to obtain a
# displacement time history which is then applied to the boundary.

# This is done because if the displacement is applied using Dirichlet BC, the
# resulting acceleration is very noisy.

# Boundaries:
# x = 0 left
# x = 1 right
# y = 0 bottom
# y = 1 top
# z = 0 back
# z = 1 front

# Result: The displacement at the top node in the z direction should match
# the prescribed displacement. Also, the z acceleration should
# be two triangular pulses, one peaking at 0.1 and another peaking at
# 0.2.


[Mesh]
  type = GeneratedMesh
  dim = 3 # Dimension of the mesh
  nx = 1 # Number of elements in the x direction
  ny = 1 # Number of elements in the y direction
  nz = 1 # Number of elements in the z direction
  xmin = 0.0
  xmax = 1
  ymin = 0.0
  ymax = 1
  zmin = 0.0
  zmax = 1
  allow_renumbering = false # So NodalVariableValue can index by id
[]

[Variables] # variables that are solved
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables] # variables that are calculated for output
  [./accel_x]
  [../]
  [./vel_x]
  [../]
  [./accel_y]
  [../]
  [./vel_y]
  [../]
  [./accel_z]
  [../]
  [./vel_z]
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./DynamicTensorMechanics] # zeta*K*vel + K * disp
    displacements = 'disp_x disp_y disp_z'
    zeta = 0.000025
  [../]
  [./inertia_x] # M*accel + eta*M*vel
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25 # Newmark time integration
    gamma = 0.5 # Newmark time integration
    eta = 19.63
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    eta = 19.63
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    beta = 0.25
    gamma = 0.5
    eta = 19.63
  [../]
[]

[AuxKernels]
  [./accel_x] # Calculates and stores acceleration at the end of time step
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_x] # Calculates and stores velocity at the end of the time step
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_z]
    type = NewmarkAccelAux
    variable = accel_z
    displacement = disp_z
    velocity = vel_z
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_z]
    type = NewmarkVelAux
    variable = vel_z
    acceleration = accel_z
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Functions]
  [./displacement_front]
    type = PiecewiseLinear
    data_file = 'displacement.csv'
    format = columns
  [../]
[]

[BCs]
  [./Preset_displacement]
    type = PresetDisplacement
    variable = disp_z
    function = displacement_front
    boundary = front
    beta = 0.25
    velocity = vel_z
    acceleration = accel_z
  [../]
  [./anchor_x]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./anchor_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./anchor_z]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    youngs_modulus = 325e6 #Pa
    poissons_ratio = 0.3
    type = ComputeIsotropicElasticityTensor
    block = 0
  [../]
  [./strain]
    #Computes the strain, assuming small strains
    type = ComputeSmallStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    #Computes the stress, using linear elasticity
    type = ComputeLinearElasticStress
    block = 0
  [../]
  [./density]
    type = GenericConstantMaterial
    block = 0
    prop_names = density
    prop_values = 2000 #kg/m3
  [../]
[]

[Executioner]
  type = Transient
  start_time = 0
  end_time = 3.0
  l_tol = 1e-6
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-6
  dt = 0.1
  timestep_tolerance = 1e-6
[]

[Postprocessors] # These quantites are printed to a csv file at every time step
  [./_dt]
    type = TimestepSize
  [../]
  [./accel_6x]
    type = NodalVariableValue
    nodeid = 6
    variable = accel_x
  [../]
  [./accel_6y]
    type = NodalVariableValue
    nodeid = 6
    variable = accel_y
  [../]
  [./accel_6z]
    type = NodalVariableValue
    nodeid = 6
    variable = accel_z
  [../]
  [./vel_6x]
    type = NodalVariableValue
    nodeid = 6
    variable = vel_x
  [../]
  [./vel_6y]
    type = NodalVariableValue
    nodeid = 6
    variable = vel_y
  [../]
  [./vel_6z]
    type = NodalVariableValue
    nodeid = 6
    variable = vel_z
  [../]
  [./disp_6x]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_6y]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./disp_6z]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_z
  [../]
[]

[Outputs]
  exodus = true
  csv = true
  perf_graph = true
[]

modules/combined/test/tests/evolving_mass_density/uniform_expand_compress_test_tensors.i

#  Element mass tests

#  This series of tests is designed to compute the mass of elements based on
#  an evolving mass density calculation.  The tests consist of expansion and compression
#  of the elastic patch test model along each axis, uniform expansion and compression,
#  and shear in each direction.  The expansion and compression tests change the volume of
#  the elements.  The corresponding change in density should compensate for this so the
#  mass remains constant.  The shear tests should not result in a volume change, and this
#  is checked too.  The mass calculation is done with the post processor called Mass.

#  The tests/file names are as follows:

#  Expansion and compression along a single axis
#  expand_compress_x_test_out.e
#  expand_compress_y_test_out.e
#  expand_compress_z_test_out.e

#  Volumetric expansion and compression
#  uniform_expand_compress_test.i

#  Zero volume change shear along each axis
#  shear_x_test_out.e
#  shear_y_test_out.e
#  shear_z_test_out.e

#  The resulting mass calculation for these tests should always be = 1.

# This test is a duplicate of the uniform_expand_compress_test.i test for solid mechanics, and the
#   output of this tensor mechanics test is compared to the original
#   solid mechanics output.  The duplication is necessary to test the
#   migrated tensor mechanics version while maintaining tests for solid mechanics.

[Mesh]
  file = elastic_patch.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./rampConstant2]
    type = PiecewiseLinear
    x = '0.00 1.00  2.0   3.00'
    y = '0.00 0.25  0.0  -0.25'
    scale_factor = 1
  [../]
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./9_y]
    type = DirichletBC
    variable = disp_y
    boundary = 9
    value = 0
  [../]
  [./10_y]
    type = DirichletBC
    variable = disp_x
    boundary = 10
    value = 0
  [../]
  [./14_y]
    type = DirichletBC
    variable = disp_z
    boundary = 14
    value = 0
  [../]

  [./top]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = 11
    function = rampConstant2
  [../]
  [./front]
    type = FunctionDirichletBC
    variable = disp_z
    preset = false
    boundary = 13
    function = rampConstant2
  [../]
  [./side]
    type = FunctionDirichletBC
    variable = disp_x
    preset = false
    boundary = 12
    function = rampConstant2
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2 3 4 5 6 7'
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]

  [./small_strain]
    type = ComputeSmallStrain
    block = ' 1 2 3 4 5 6 7'
  [../]

  [./elastic_stress]
    type = ComputeLinearElasticStress
    block = '1 2 3 4 5 6 7'
  [../]
[]

[Executioner]

  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10
  l_max_its = 20
  start_time = 0.0
  dt = 1.0
  num_steps = 3
  end_time =3.0
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
    file_base = uniform_expand_compress_test_out
  [../]
[]

[Postprocessors]
  [./Mass]
    type = Mass
    variable = disp_x
    execute_on = 'initial timestep_end'
  [../]
[]

modules/combined/test/tests/mortar_tm/2drz/frictionless_second/finite.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'finite'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
  [../]
  [./plank]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/xfem/test/tests/mechanical_constraint/glued_penalty.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[XFEM]
  geometric_cut_userobjects = 'line_seg_cut_uo'
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 11
  ny = 11
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '1.0  0.5  0.0  0.5'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    planar_formulation = plane_strain
    add_variables = true
  [../]
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x='0  50   100'
    y='0  0.02 0.1'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./topx]
    type = DirichletBC
    boundary = top
    variable = disp_x
    value = 0.0
  [../]
  [./topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = pull
  [../]
[]

[Constraints]
  [./disp_x]
    type = XFEMSingleVariableConstraint
    variable = disp_x
    use_penalty = true
    alpha = 1.0e8
    use_displaced_mesh = true
    geometric_cut_userobject = 'line_seg_cut_uo'
  [../]
  [./disp_y]
    type = XFEMSingleVariableConstraint
    variable = disp_y
    use_penalty = true
    alpha = 1.0e8
    use_displaced_mesh = true
    geometric_cut_userobject = 'line_seg_cut_uo'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
    block = 0
  [../]

  [./_elastic_strain]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-9

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 2.0
  num_steps = 5000

  max_xfem_update = 1
[]

[Outputs]
  exodus = true
  execute_on = timestep_end
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/test_jacobian/jacobian_test_RZ.i

# This test is designed to test the jacobian for a single
# element with/without  volumetric locking correction.

# Result: The hand coded jacobian matches well with the finite
# difference jacobian with an error norm in the order of 1e-15
# for total and incremental small strain and with an error norm
# in the order of 1e-8 for finite strain.


[Problem]
  coord_type = RZ
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 1
  ny = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = left
    value = 1.0
  [../]

  [./right]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = right
    value = 0.0
  [../]

[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
    block = 0
  [../]
  [./stress]
    block = 0
  [../]
[]

[Preconditioning]
  active = 'smp'
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient #Transient

  solve_type = NEWTON
  petsc_options = '-snes_check_jacobian -snes_check_jacobian_view'

  l_max_its = 1
  nl_abs_tol = 1e-4
  nl_rel_tol = 1e-6
  l_tol = 1e-6
  start_time = 0.0
  num_steps = 1
  dt = 0.005
  dtmin = 0.005
  end_time = 0.005
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_elastic/rz_finite_elastic-noad.i

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 3
  ny = 3
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = StressDivergenceRZTensors
    component = 0
    variable = disp_r
    use_displaced_mesh = true
  [../]
  [./stress_z]
    type = StressDivergenceRZTensors
    component = 1
    variable = disp_z
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./bottom]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0
  [../]
  [./axial]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
  [./strain]
    type = ComputeAxisymmetricRZFiniteStrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = rz_finite_elastic_out
[]

modules/tensor_mechanics/test/tests/thermal_expansion_function/finite_linear.i

# This tests the thermal expansion coefficient function using both
# options to specify that function: mean and instantaneous.  There
# two blocks, each containing a single element, and these use the
# two variants of the function.

# In this test, the instantaneous CTE function is a linear function
# while the mean CTE function is an analytic function designed to
# give the same response.  If \bar{alpha}(T) is the mean CTE function,
# and \alpha(T) is the instantaneous CTE function,

# \bar{\alpha}(T) = 1/(T-Tref) \intA^{T}_{Tsf} \alpha(T) dT

# where Tref is the reference temperature used to define the mean CTE
# function, and Tsf is the stress-free temperature.

# This version of the test uses finite deformation theory.
# The two models produce very similar results.  There are slight
# differences due to the large deformation treatment.

[Mesh]
  file = 'blocks.e'
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    block = '1 2'
    function = temp_func
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain1]
    type = ComputeMeanThermalExpansionFunctionEigenstrain
    block = 1
    thermal_expansion_function = cte_func_mean
    thermal_expansion_function_reference_temperature = 0.5
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
  [./thermal_expansion_strain2]
    type = ComputeInstantaneousThermalExpansionFunctionEigenstrain
    block = 2
    thermal_expansion_function = cte_func_inst
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_func_mean]
    type = ParsedFunction
    vars = 'tsf tref scale' #stress free temp, reference temp, scale factor
    vals = '0.0 0.5  1e-4'
    value = 'scale * (0.5 * t^2 - 0.5 * tsf^2) / (t - tref)'
  [../]
  [./cte_func_inst]
    type = PiecewiseLinear
    xy_data = '0 0.0
               2 2.0'
    scale_factor = 1e-4
  [../]

  [./temp_func]
    type = PiecewiseLinear
    xy_data = '0 1
               1 2'
  [../]
[]

[Postprocessors]
  [./disp_1]
    type = NodalMaxValue
    variable = disp_x
    boundary = 101
  [../]

  [./disp_2]
    type = NodalMaxValue
    variable = disp_x
    boundary = 102
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  l_max_its = 100
  l_tol = 1e-4
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/sliding_block/in_and_out/dirac/frictional_02_penalty.i

#  This is a benchmark test that checks Dirac based frictional
#  contact using the penalty method.  In this test a sinusoidal
#  displacement is applied in the horizontal direction to simulate
#  a small block come in and out of contact as it slides down a larger block.
#
#  The sinusoid is of the form 0.4sin(4t)+0.2 and a friction coefficient
#  of 0.2 is used.  The gold file is run on one processor and the benchmark
#  case is run on a minimum of 4 processors to ensure no parallel variability
#  in the contact pressure and penetration results.  Further documentation can
#  found in moose/modules/contact/doc/sliding_block/
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
  [./horizontal_movement]
    type = ParsedFunction
    value = -0.04*sin(4*t)+0.02
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./constitutive]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 15
  num_steps = 1000
  nl_rel_tol = 1e-6
  dtmin = 0.01
  l_tol = 1e-6

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  file_base = frictional_02_penalty_out
  interval = 10
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = coulomb
    penalty = 1e+7
    formulation = penalty
    friction_coefficient = 0.2
    normal_smoothing_distance = 0.1
    system = DiracKernel
  [../]
[]

modules/combined/test/tests/power_law_hardening/PowerLawHardening.i

# This is a test of the isotropic power law hardening constitutive model.
# In this problem, a single Hex 8 element is fixed at the bottom and pulled at the top
# at a constant rate of 0.1.
# Before yield, stress = strain (=0.1*t) as youngs modulus is 1.0.
# The yield stress for this problem is 0.25 ( as strength coefficient is 0.5 and strain rate exponent is 0.5).
# Therefore, the material should start yielding at t = 2.5 seconds and then follow stress = K *pow(strain,n) or
# stress ~ 0.5*pow(0.1*t,0.5).
#
# This tensor mechanics version of the power law hardening plasticity model matches
# the solid mechanics version for this toy problem under exodiff limits

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[AuxVariables]
  [./total_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./top_pull]
    type = ParsedFunction
    value = t*(0.1)
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = SMALL
    incremental = true
    generate_output = 'stress_yy'
  []
[]

[AuxKernels]
  [./total_strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = total_strain_yy
    index_i = 1
    index_j = 1
  [../]
 []

[BCs]
  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = top_pull
  [../]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1.0
    poissons_ratio = 0.3
  [../]
  [./power_law_hardening]
    type = IsotropicPowerLawHardeningStressUpdate
    strength_coefficient = 0.5 #K
    strain_hardening_exponent = 0.5 #n
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'power_law_hardening'
    tangent_operator = elastic
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-ksp_snes_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  end_time = 5.0
  dt = 0.25
[]

[Postprocessors]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./strain_yy]
    type = ElementAverageValue
    variable = total_strain_yy
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/combined/test/tests/solid_mechanics/spherical_shell/1D-SPH_test.i

# Considers the mechanics solution for a thick spherical shell that is uniformly
# pressurized on the inner and outer surfaces. Three versions of the test are
# provided, assuming 1D spherical geometry (1D-SPH), 2D axisymmetic geometry
# (2D-RZ), and 3D geometry (3D). The tests demonstrate that all three geometric
# approaches produce the same correct solution.
#
# From Roark (Formulas for Stress and Strain, McGraw-Hill, 1975), the radially-dependent
# circumferential stress in a uniformly pressurized thick spherical shell is given by:
#
# S(r) = [ Pi[ri^3(2r^3+ro^3)] - Po[ro^3(2r^3+ri^3)] ] / [2r^3(ro^3-ri^3)]
#
#   where:
#          Pi = inner pressure
#          Po = outer pressure
#          ri = inner radius
#          ro = outer radius
#
# The tests assume an inner and outer radii of 5 and 10, with internal and external
# pressures of 100000 and 200000, respectively. The resulting compressive tangential
# stress is largest at the inner wall and, from the above equation, has a value
# of -271429.
#
# RESULTS are below. Since stresses are average element values, values for the
# edge element and one-element-in are used to extrapolate the stress to the
# inner surface. The vesrion of the tests that are checked use the coarsest meshes.
#
#  Mesh    Radial elem   S(edge elem)  S(one elem in)  S(extrap to surf)
# 1D-SPH       12          -264842      -254419        -270053
# 2D-RZ        12          -265007      -254668        -270177
#  3D          12 (4x4)    -258922      -251099        -262834
#  3D          12 (6x6)    -262194      -252969        -266807
#
# 1D-SPH       48          -269679      -266390        -271323
# 2D-RZ        48          -269723      -266470        -271350
#  3D          48          -268617      -265717        -270067
#
# 1D-SPH      100          -270580      -268932        -271404
# 2D-RZ       100          -270587      -268946        -271408
#
# The numerical solution converges to the analytical solution as the mesh is
# refined.

[GlobalParams]
  displacements = 'disp_x'
[]

[Mesh]
  file = 1D-SPH_mesh.e
  construct_side_list_from_node_list = true
[]

[Problem]
  coord_type = RSPHERICAL
[]


[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    additional_generate_output = 'stress_zz'
  []
[]

[BCs]
  [./exterior_pressure_x]
    type = Pressure
    variable = disp_x
    boundary = outer
    component = 0
    factor = 200000
  [../]

  [./interior_pressure_x]
    type = Pressure
    variable = disp_x
    boundary = inner
    component = 0
    factor = 100000
  [../]
[]

[Materials]
  [./fuel_disp]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./fuel_disp_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
[]

[Debug]
    show_var_residual_norms = true
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50

   start_time = 0.0
   end_time = 1
   num_steps = 1000

  dtmax = 5e6
  dtmin = 1
  [./TimeStepper]
    type = IterationAdaptiveDT
    dt = 1
    optimal_iterations = 6
    iteration_window = 0
    linear_iteration_ratio = 100
  [../]

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

#  [./Quadrature]
#    order = THIRD
#  [../]
[]

[Postprocessors]
  [./dt]
    type = TimestepSize
  [../]
[]

[Outputs]
  exodus = true
  csv = false
[]

modules/combined/test/tests/contact_verification/hertz_cyl/quart_symm_q4/hertz_cyl_qsym_1deg_template1.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_qsym_1deg_q4.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_zero]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 0.0 0.0'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 4
    paired_boundary = 3
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./disp_x281]
    type = NodalVariableValue
    nodeid = 280
    variable = disp_x
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 3'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2 3'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = disp_ramp_vert
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-6
  nl_rel_tol = 1e-5
  l_max_its = 50
  nl_max_its = 100

  start_time = 0.0
  dt = 0.1
  dtmin = 0.1
  num_steps = 10
  end_time = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '4'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x281 top_react_x top_react_y x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    master = 3
    slave = 4
    system = constraint
    model = glued
    formulation = kinematic
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/ad_linear_elasticity/applied_strain.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 2
  xmax = 2
  ymax = 2
[]

[Modules/TensorMechanics/Master/All]
  strain = SMALL
  eigenstrain_names = eigenstrain
  add_variables = true
  generate_output = 'strain_xx strain_yy strain_xy'
  use_automatic_differentiation = true
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
  [./eigenstrain]
    type = ADComputeEigenstrain
    eigen_base = '0.1 0.05 0 0 0 0.01'
    prefactor = -1
    eigenstrain_name = eigenstrain
  [../]
[]

[BCs]
  [./bottom_y]
    type = ADDirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./left_x]
    type = ADDirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
[]

[Executioner]
  type = Steady
  solve_type = 'NEWTON'
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/solid_mechanics/Rayleigh_damping/Newmark_time_integration/Rayleigh_Newmark.i

# Test for rayleigh damping implemented using Newmark time integration

# The test is for an 1-D bar element of unit length fixed on one end
# with a ramped pressure boundary condition applied to the other end.
# zeta and eta correspond to the stiffness and mass proportional
# rayleigh damping beta and gamma are Newmark time integration
# parameters The equation of motion in terms of matrices is:
#
# M*accel + eta*M*vel + zeta*K*vel + K*disp = P*Area
#
# Here M is the mass matrix, K is the stiffness matrix, P is the applied pressure
#
# This equation is equivalent to:
#
# density*accel + eta*density*vel + zeta*d/dt(Div stress) + Div stress = P
#
# The first two terms on the left are evaluated using the Inertial
# force kernel The next two terms on the left involving zeta ise
# evaluated using the StressDivergence Kernel The residual due to
# Pressure is evaluated using Pressure boundary condition
#
# The system will come to steady state slowly after the pressure
# becomes constant.
[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
  order = FIRST
  family = LAGRANGE
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = 0.0
  xmax = 0.1
  ymin = 0.0
  ymax = 1.0
  zmin = 0.0
  zmax = 0.1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./vel_x]
  [../]
  [./accel_x]
  [../]
  [./vel_y]
  [../]
  [./accel_y]
  [../]
  [./vel_z]
  [../]
  [./accel_z]
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

[]

[Kernels]
  [./DynamicTensorMechanics]
    use_displaced_mesh = true
    zeta = 0.1
  [../]
  [./inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    eta=0.1
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    eta=0.1
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    beta = 0.25
    gamma = 0.5
    eta = 0.1
  [../]

[]

[AuxKernels]
  [./accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_z]
    type = NewmarkAccelAux
    variable = accel_z
    displacement = disp_z
    velocity = vel_z
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_z]
    type = NewmarkVelAux
    variable = vel_z
    acceleration = accel_z
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./stress_yy]
     type = RankTwoAux
     variable = stress_yy
     rank_two_tensor = stress
     index_i = 1
     index_j = 1
  [../]
  [./strain_yy]
     type = RankTwoAux
     variable = strain_yy
     rank_two_tensor = total_strain
     index_i = 1
     index_j = 1
  [../]

[]


[BCs]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value=0.0
  [../]
  [./top_x]
   type = DirichletBC
    variable = disp_x
    boundary = top
    value=0.0
  [../]
  [./top_z]
    type = DirichletBC
    variable = disp_z
    boundary = top
    value=0.0
  [../]
  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = bottom
    value=0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value=0.0
  [../]
  [./Pressure]
    [./Side1]
    boundary = bottom
    function = pressure
    factor = 1
    [../]
  [../]
[]

[Materials]
  [./elastic]
    type = ComputeIsotropicElasticityTensor
    block = '0'
    youngs_modulus = 210e+09
    poissons_ratio = 0
  [../]
  [./elastic_strain]
    type= ComputeFiniteStrain
    block = '0'
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
    block = '0'
  [../]
  [./density]
    type = GenericConstantMaterial
    block = 0
    prop_names = 'density'
    prop_values = '7750'
  [../]
[]


[Executioner]

  type = Transient
  start_time = 0
  end_time = 2
  dtmax = 0.1
  dtmin = 0.1
  [./TimeStepper]
    type = ConstantDT
    dt = 0.1
  [../]

[]


[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0.0 0.1 0.2 1.0 2.0 5.0'
    y = '0.0 0.1 0.2 1.0 1.0 1.0'
    scale_factor = 1e9
  [../]
  [./vel_ic]
    type = PiecewiseLinear
    x = '0.0 0.5 1.0'
    y = '0.1 0.1 0.1'
    scale_factor = 1
  [../]
[]

[Postprocessors]
   [./_dt]
     type = TimestepSize
   [../]
   [./disp]
     type = NodalMaxValue
     variable = disp_y
     boundary = bottom
   [../]
   [./vel]
     type = NodalMaxValue
     variable = vel_y
     boundary = bottom
   [../]
   [./accel]
     type = NodalMaxValue
     variable = accel_y
     boundary = bottom
   [../]
   [./stress_yy]
      type = ElementAverageValue
      variable = stress_yy
   [../]
   [./strain_yy]
      type = ElementAverageValue
      variable = strain_yy
   [../]

[]

[Outputs]
  exodus = true
[]

modules/porous_flow/test/tests/jacobian/mass01_fully_saturated.i

# FullySaturatedMassTimeDerivative
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[GlobalParams]
  PorousFlowDictator = dictator
  displacements = 'disp_x disp_y disp_z'
[]

[Modules]
  [./FluidProperties]
    [./the_simple_fluid]
      type = SimpleFluidProperties
      thermal_expansion = 0.5
      bulk_modulus = 1.5
      density0 = 1.0
    [../]
  [../]
[]

[Variables]
  [./pp]
  [../]
  [./T]
  [../]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[ICs]
  [./disp_x]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_x
  [../]
  [./disp_y]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_y
  [../]
  [./disp_z]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_z
  [../]
  [./pp]
    type = RandomIC
    variable = pp
    min = 0
    max = 1
  [../]
  [./T]
    type = RandomIC
    variable = T
    min = 0
    max = 1
  [../]
[]

[BCs]
  # necessary otherwise volumetric strain rate will be zero
  [./disp_x]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = 'left right'
  [../]
  [./disp_y]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = 'left right'
  [../]
  [./disp_z]
    type = DirichletBC
    variable = disp_z
    value = 0
    boundary = 'left right'
  [../]
[]

[Kernels]
  [./mass0]
    type = PorousFlowFullySaturatedMassTimeDerivative
    variable = pp
    coupling_type = ThermoHydroMechanical
    biot_coefficient = 0.9
  [../]
  [./dummyT]
    type = TimeDerivative
    variable = T
  [../]
  [./grad_stress_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
  [../]
  [./grad_stress_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
  [../]
  [./grad_stress_z]
    type = StressDivergenceTensors
    variable = disp_z
    component = 2
  [../]
[]

[UserObjects]
  [./dictator]
    type = PorousFlowDictator
    porous_flow_vars = 'pp disp_x disp_y disp_z T'
    number_fluid_phases = 1
    number_fluid_components = 1
  [../]
  [./simple1]
    type = TensorMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1E20
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 2.0
    shear_modulus = 3.0
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./vol_strain]
    type = PorousFlowVolumetricStrain
  [../]
  [./temperature]
    type = PorousFlowTemperature
    temperature = T
  [../]
  [./ppss]
    type = PorousFlow1PhaseFullySaturated
    porepressure = pp
  [../]
  [./massfrac]
    type = PorousFlowMassFraction
  [../]
  [./simple_fluid]
    type = PorousFlowSingleComponentFluid
    fp = the_simple_fluid
    phase = 0
  [../]
  [./porosity]
    type = PorousFlowPorosityConst  # only the initial vaue of this is ever used
    porosity = 0.1
  [../]
  [./biot_modulus]
    type = PorousFlowConstantBiotModulus
    biot_coefficient = 0.9
    fluid_bulk_modulus = 1.5
    solid_bulk_compliance = 0.5
  [../]
  [./thermal_expansion]
    type = PorousFlowConstantThermalExpansionCoefficient
    biot_coefficient = 0.9
    fluid_coefficient = 0.5
    drained_coefficient = 0.4
  [../]
[]

[Preconditioning]
  [./check]
    type = SMP
    full = true
    #petsc_options = '-snes_test_display'
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  dt = 1
  end_time = 2
[]

[Outputs]
  exodus = false
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update23.i

# MC update version, with only MohrCoulomb, cohesion=40, friction angle = 35deg, psi = 5deg, smoothing_tol = 0.5
# Tensile strength = 1MPa
# Lame lambda = 1E3.  Lame mu = 1.3E3

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 4E1
  [../]
  [./phi]
    type = TensorMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./psi]
    type = TensorMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 0.5
    shear_modulus = 1.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '10 12 -14  12 5 20  -14 20 8'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = phi
    dilation_angle = psi
    smoothing_tol = 0.5
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/peridynamics/test/tests/failure_tests/2D_stretch_failure_BPD.i


[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3
  cracks_start = '0.25 0.5 0'
  cracks_end = '0.75 0.5 0'

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 8
    ny = 8
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./damage]
  [../]
  [./intact_bonds_num]
  [../]
  [./critical_stretch]
    family = MONOMIAL
    order = CONSTANT
  [../]
[]

[AuxKernels]
  [./bond_status]
    type = StretchBasedFailureCriterionPD
    critical_variable = critical_stretch
    variable = bond_status
  [../]
[]

[UserObjects]
  [./damage]
    type = NodalDamageIndexPD
    variable = damage
  [../]
  [./intact_bonds]
    type = NodalNumIntactBondsPD
    variable = intact_bonds_num
  [../]
[]

[ICs]
  [./critical_stretch]
    type = ConstantIC
    variable = critical_stretch
    value = 0.001
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1002
    value = 0.0
  [../]
  [./bottom_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1000
    function = '-0.001*t'
  [../]

  [./rbm_x]
    type = RBMPresetOldValuePD
    variable = disp_x
    boundary = 999
  [../]
  [./rbm_y]
    type = RBMPresetOldValuePD
    variable = disp_y
    boundary = 999
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = BOND
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.33
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialBPD
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none
  start_time = 0
  dt = 0.5
  end_time = 1
[]

[Outputs]
  file_base = 2D_stretch_failure_BPD
  exodus = true
[]

modules/xfem/test/tests/corner_nodes_cut/corner_edge_cut.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[UserObjects]
  [./line_seg_cut_uo1]
    type = LineSegmentCutUserObject
    cut_data = '-0.0 0.5 0.5 0.5'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
  [./line_seg_cut_uo2]
    type = LineSegmentCutUserObject
    cut_data = '0.5 0.5 1.0 0.7'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 10
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
  [../]
[]

[BCs]
  [./top_x]
    type = DirichletBC
    boundary = 2
    variable = disp_x
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    boundary = 2
    variable = disp_y
    value = 0.1
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 0
    variable = disp_y
    value = -0.1
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = 0
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-16
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/porous_flow/test/tests/jacobian/phe01.i

# Capped weak-plane plasticity, Kernel = PorousFlowPlasticHeatEnergy
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  PorousFlowDictator = dictator
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./temperature]
  [../]
[]

[ICs]
  [./disp_x]
    type = RandomIC
    variable = disp_x
    min = -0.1
    max = 0.1
  [../]
  [./disp_y]
    type = RandomIC
    variable = disp_y
    min = -0.1
    max = 0.1
  [../]
  [./disp_z]
    type = RandomIC
    variable = disp_z
    min = -0.1
    max = 0.1
  [../]
  [./temp]
    type = RandomIC
    variable = temperature
    min = 0.1
    max = 0.2
  [../]
[]

[Kernels]
  [./phe]
    type = PorousFlowPlasticHeatEnergy
    variable = temperature
  [../]
  [./dummy_disp_x]
    type = PorousFlowPlasticHeatEnergy
    coeff = -1.3
    variable = disp_x
  [../]
  [./dummy_disp_y]
    type = PorousFlowPlasticHeatEnergy
    coeff = 1.1
    variable = disp_y
  [../]
  [./dummy_disp_z]
    type = PorousFlowPlasticHeatEnergy
    coeff = 0.2
    variable = disp_z
  [../]
[]

[UserObjects]
  [./dictator]
    type = PorousFlowDictator
    porous_flow_vars = 'temperature disp_x disp_y disp_z'
    number_fluid_phases = 0
    number_fluid_components = 0
  [../]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 2
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 0.5
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.05
    rate = 3
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 100
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0
    internal_0 = -2
    internal_limit = 0
  [../]
[]

[Materials]
  [./temp]
    type = PorousFlowTemperature
    temperature = temperature
  [../]
  [./porosity]
    type = PorousFlowPorosity
    thermal = true
    mechanical = true
    porosity_zero = 0.3
    thermal_expansion_coeff = 1.3
  [../]
  [./volstrain]
    type = PorousFlowVolumetricStrain
  [../]
  [./phe]
    type = ComputePlasticHeatEnergy
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 0  0 0 1  0 1 -1.5'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 0
    smoothing_tol = 1
    yield_function_tol = 1E-10
    perfect_guess = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/fdp_geometric_coupling/fdp_geometric_coupling.i

[Mesh]
  file = twoBlocksContactDiceSlave2OffsetGap.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./temp]
    initial_condition = 100.0
  [../]
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0 1 2'
    y = '0 1 1'
    scale_factor = 10.0
  [../]

  [./tempFunc]
    type = PiecewiseLinear
    x = '0. 3.'
    y = '100.0 440.0'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block1]
    block = 1
    volumetric_locking_correction = true
    incremental = true
    strain = FINITE
    eigenstrain_names = 'thermal_expansion1'
    decomposition_method = EigenSolution
  [../]
  [./block2]
    block = 2
    volumetric_locking_correction = true
    incremental = true
    strain = FINITE
    eigenstrain_names = 'thermal_expansion2'
    decomposition_method = EigenSolution
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./left_right_x]
    type = DirichletBC
    variable = disp_x
    boundary = '1 4'
    value = 0.0
  [../]

  [./left_right_y]
    type = DirichletBC
    variable = disp_y
    boundary = '1 4'
    value = 0.0
  [../]

  [./left_right_z]
    type = DirichletBC
    variable = disp_z
    boundary = '1 4'
    value = 0.0
  [../]

  [./temp]
    type = FunctionDirichletBC
    variable = temp
    boundary = '2 3'
    function = tempFunc
  [../]
[]

[Contact]
  [./dummy_name]
    master = 2
    slave = 3
    penalty = 1e8
    system = Constraint
  [../]
[]

[Materials]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]

  [./stress1]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]

  [./thermal_expansion1]
    type = ComputeThermalExpansionEigenstrain
    block = 1
    thermal_expansion_coeff = 1e-4
    stress_free_temperature = 100.0
    temperature = temp
    eigenstrain_name = thermal_expansion1
  [../]

  [./thermal_expansion2]
    type = ComputeThermalExpansionEigenstrain
    block = 2
    thermal_expansion_coeff = 1e-5
    stress_free_temperature = 100.0
    temperature = temp
    eigenstrain_name = thermal_expansion2
  [../]

  [./heat]
    type = HeatConductionMaterial
    block = '1 2'
    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]

  [./density]
    type = Density
    block = '1 2'
    density = 1.0
    disp_x = disp_x
    disp_y = disp_y
    disp_z = disp_z
  [../]
[]

[Preconditioning]
  [./FDP]
    type = FDP
    full = true
    implicit_geometric_coupling = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -mat_fd_coloring_err -mat_fd_type'
  petsc_options_value = 'lu       1e-8                 ds'

  nl_rel_tol = 1e-10

  l_max_its = 5
  nl_max_its = 3
  dt = 5.0e-1
  num_steps = 2
[]

[Outputs]
  file_base = fdp_geometric_coupling_out
  exodus = true
[]

modules/combined/test/tests/contact/8ElemTensionRelease.i

[Mesh]
  file = 8ElemTensionRelease.e
  partitioner = centroid
  centroid_partitioner_direction = x
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Functions]
  [./up]
    type = PiecewiseLinear
    x = '0 1      2 3'
    y = '0 0.0001 0 -.0001'
  [../]
[]

[AuxVariables]
  [./status]
  [../]
  [./pid]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  []
[]

[Contact]
  [./dummy_name]
    master = 2
    slave = 3
    penalty = 1e6
    model = frictionless
    tangential_tolerance = 0.01
    system = Constraint
  [../]
[]

[AuxKernels]
  [./pid]
    type = ProcessorIDAux
    variable = pid
    execute_on = 'initial timestep_end'
  [../]
  [./status]
    type = PenetrationAux
    quantity = mechanical_status
    variable = status
    boundary = 3
    paired_boundary = 2
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./lateral]
    type = DirichletBC
    variable = disp_x
    boundary = '1 4'
    value = 0
  [../]

  [./bottom_up]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = up
  [../]

  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre    boomeramg      101'

  line_search = 'none'
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-9
  l_tol = 1e-4

  l_max_its = 100
  nl_max_its = 10
  dt = 0.1
  num_steps = 30

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_simple_linear/linear-mixed.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./stress_x]
    type = StressDivergenceTensors
    component = 0
    variable = disp_x
  [../]
  [./stress_y]
    type = StressDivergenceTensors
    component = 1
    variable = disp_y
  [../]
  [./stress_z]
    type = StressDivergenceTensors
    component = 2
    variable = disp_z
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.1
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeSmallStrain
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = "linear-out"
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update11.i

# MC update version, with only Compressive with compressive strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Return to the stress_min = 1 plane

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2 0 0  0 0 0  0 0 -2'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/jacobian/tensile_update4.i

# Tensile, update version, with strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2 -1 0.5  1 1.9 0  0.5 0 3'
    eigenstrain_name = ini_stress
  [../]
  [./tensile]
    type = TensileStressUpdate
    tensile_strength = ts
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = tensile
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/sliding_block/in_and_out/constraint/frictional_04_penalty.i

#  This is a benchmark test that checks constraint based frictional
#  contact using the penalty method.  In this test a sinusoidal
#  displacement is applied in the horizontal direction to simulate
#  a small block come in and out of contact as it slides down a larger block.
#
#  The sinusoid is of the form 0.4sin(4t)+0.2 and a friction coefficient
#  of 0.4 is used.  The gold file is run on one processor and the benchmark
#  case is run on a minimum of 4 processors to ensure no parallel variability
#  in the contact pressure and penetration results.  Further documentation can
#  found in moose/modules/contact/doc/sliding_block/
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
  [./horizontal_movement]
    type = ParsedFunction
    value = -0.04*sin(4*t)+0.02
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./left_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -sub_pc_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm     lu    20    101'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 15
  num_steps = 1000
  l_tol = 1e-3
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-6
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  # csv = true
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = coulomb
    penalty = 1e+7
    friction_coefficient = 0.4
    formulation = penalty
    system = constraint
    normal_smoothing_distance = 0.1
  [../]
[]

modules/tensor_mechanics/test/tests/radial_disp_aux/cylinder_3d_cartesian.i

# The purpose of this set of tests is to check the values computed
# by the RadialDisplacementAux AuxKernel. They should match the
# radial component of the displacment for a cylindrical or spherical
# model.
# This particular model is of a cylinder subjected to uniform thermal
# expansion represented using a 3D Cartesian model.

[Mesh]
  type = FileMesh
  file = cylinder_sector_3d.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  order = SECOND
  family = LAGRANGE
[]

[AuxVariables]
  [./temp]
  [../]
  [./rad_disp]
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t+300.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    eigenstrain_names = eigenstrain
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
    use_displaced_mesh = false
  [../]
  [./raddispaux]
    type = RadialDisplacementCylinderAux
    variable = rad_disp
    origin = '0 0 0'
    axis_vector = '0 0 1'
  [../]
[]

[BCs]
  [./x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./z]
    type = DirichletBC
    variable = disp_z
    boundary = '3 4'
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 300
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '51'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10

  start_time = 0.0
  end_time = 1
  dt = 1
  dtmin = 1
[]

[Outputs]
 csv = true
 exodus = true
[]

#[Postprocessors]
#  [./strain_xx]
#    type = SideAverageValue
#    variable =
#    block = 0
#  [../]
#[]

modules/xfem/test/tests/solid_mechanics_basic/crack_propagation_2d.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
  use_crack_growth_increment = true
  crack_growth_increment = 0.2
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 11
  ny = 11
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '1.0  0.5  0.7  0.5'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
  [./xfem_marker_uo]
    type = XFEMRankTwoTensorMarkerUserObject
    execute_on = timestep_end
    tensor = stress
    scalar_type = MaxPrincipal
    threshold = 5e+1
    average = true
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    planar_formulation = plane_strain
    add_variables = true
  [../]
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x='0  50   100'
    y='0  0.02 0.1'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./topx]
    type = DirichletBC
    boundary = top
    variable = disp_x
    value = 0.0
  [../]
  [./topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = pull
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
    block = 0
  [../]

  [./_elastic_strain]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-9

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 2.0
  num_steps = 5000

  max_xfem_update = 1
[]

[Outputs]
  file_base = crack_propagation_2d_out
  exodus = true
  execute_on = timestep_end
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/capped_weak_plane/pull_push.i

# A column of elements has its bottom pulled down, and then pushed up again.
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 2
  xmin = -10
  xmax = 10
  ymin = -10
  ymax = 10
  zmin = -100
  zmax = 0
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./no_x2]
    type = DirichletBC
    variable = disp_x
    boundary = right
    value = 0.0
  [../]
  [./no_x1]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./no_y1]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./no_y2]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.0
  [../]

  [./topz]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0
  [../]
  [./bottomz]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = back
    function = 'if(t>1,-2.0+t,-t)'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strainp_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strainp_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strainp_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strainp_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strainp_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strainp_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./straint_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./straint_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./straint_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./straint_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./straint_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./straint_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f_shear]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f_tensile]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f_compressive]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl_shear]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl_tensile]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./ls]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./strainp_xx]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = strainp_xx
    index_i = 0
    index_j = 0
  [../]
  [./strainp_xy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = strainp_xy
    index_i = 0
    index_j = 1
  [../]
  [./strainp_xz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = strainp_xz
    index_i = 0
    index_j = 2
  [../]
  [./strainp_yy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = strainp_yy
    index_i = 1
    index_j = 1
  [../]
  [./strainp_yz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = strainp_yz
    index_i = 1
    index_j = 2
  [../]
  [./strainp_zz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = strainp_zz
    index_i = 2
    index_j = 2
  [../]
  [./straint_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = straint_xx
    index_i = 0
    index_j = 0
  [../]
  [./straint_xy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = straint_xy
    index_i = 0
    index_j = 1
  [../]
  [./straint_xz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = straint_xz
    index_i = 0
    index_j = 2
  [../]
  [./straint_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = straint_yy
    index_i = 1
    index_j = 1
  [../]
  [./straint_yz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = straint_yz
    index_i = 1
    index_j = 2
  [../]
  [./straint_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = straint_zz
    index_i = 2
    index_j = 2
  [../]
  [./f_shear]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f_shear
  [../]
  [./f_tensile]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f_tensile
  [../]
  [./f_compressive]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f_compressive
  [../]
  [./intnl_shear]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 0
    variable = intnl_shear
  [../]
  [./intnl_tensile]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 1
    variable = intnl_tensile
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./ls]
    type = MaterialRealAux
    property = plastic_linesearch_needed
    variable = ls
  [../]
[]

[UserObjects]
  [./coh_irrelevant]
    type = TensorMechanicsHardeningCubic
    value_0 = 2E6
    value_residual = 1E6
    internal_limit = 0.01
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningCubic
    value_0 = 0.5
    value_residual = 0.2
    internal_limit = 0.01
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningConstant
    value = 0.166666666667
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningConstant
    value = 2E6
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningCubic
    value_0 = 1E8
    value_residual = 0.0
    internal_limit = 0.01
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 6.4e9
    shear_modulus = 6.4e9 # young 16MPa, Poisson 0.25
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = stress
    tangent_operator = nonlinear
    perform_finite_strain_rotations = false
  [../]
  [./stress]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh_irrelevant
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 10
    tip_smoother = 0
    smoothing_tol = 0
    yield_function_tol = 1E-2
    perfect_guess = false
    min_step_size = 1
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options = '-snes_converged_reason -snes_linesearch_monitor'
    petsc_options_iname = '-pc_type -pc_asm_overlap -sub_pc_type -ksp_type -ksp_gmres_restart'
    petsc_options_value = ' asm      2              lu            gmres     200'
  [../]
[]

[Executioner]
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason'
  line_search = bt
  nl_abs_tol = 1E1
  nl_rel_tol = 1e-5
  l_tol = 1E-10

  l_max_its = 100
  nl_max_its = 100

  end_time = 3.0
  dt = 0.1
  type = Transient
[]

[Outputs]
  file_base = pull_push
  exodus = true
  csv = true
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_2/ring2_template1.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring2_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_y5 disp_x9 disp_y9 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/combined/test/tests/solid_mechanics/Wave_1_D/HHT_time_integration/wave_bc_1d.i

# Wave propogation in 1-D using HHT time integration
#
# The test is for an 1-D bar element of length 4m  fixed on one end
# with a sinusoidal pulse dirichlet boundary condition applied to the other end.
# alpha, beta and gamma are Newmark  time integration parameters
# The equation of motion in terms of matrices is:
#
# M*accel + K*((1+alpha)*disp-alpha*disp_old) = 0
#
# Here M is the mass matrix, K is the stiffness matrix
#
# The displacement at the second, third and fourth node at t = 0.1 are
# -8.097405701570538350e-02, 2.113131879547342634e-02 and -5.182787688751439893e-03, respectively.

[GlobalParams]
  volumetric_locking_correction = false
  order = FIRST
  family = LAGRANGE
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 4
  nz = 1
  xmin = 0.0
  xmax = 0.1
  ymin = 0.0
  ymax = 4.0
  zmin = 0.0
  zmax = 0.1
  displacements = 'disp_x disp_y disp_z'
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./vel_x]
  [../]
  [./accel_x]
  [../]
  [./vel_y]
  [../]
  [./accel_y]
  [../]
  [./vel_z]
  [../]
  [./accel_z]
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

[]


[Kernels]
  [./DynamicTensorMechanics]
    alpha = -0.3
    use_displaced_mesh = false
    displacements = 'disp_x disp_y disp_z'
  []
 [./inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    use_displaced_mesh = false
    beta = 0.3025
    gamma = 0.6
    alpha = -0.3
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    use_displaced_mesh = false
    beta = 0.3025
    gamma = 0.6
    alpha = -0.3
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    use_displaced_mesh = false
    beta = 0.3025
    gamma = 0.6
    alpha = -0.3
  [../]

[]

[AuxKernels]
  [./accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.6
    execute_on = timestep_end
  [../]
  [./accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.6
    execute_on = timestep_end
  [../]
  [./accel_z]
    type = NewmarkAccelAux
    variable = accel_z
    displacement = disp_z
    velocity = vel_z
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./vel_z]
    type = NewmarkVelAux
    variable = vel_z
    acceleration = accel_z
    gamma = 0.6
    execute_on = timestep_end
  [../]

[]


[BCs]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value=0.0
  [../]
  [./top_x]
   type = DirichletBC
    variable = disp_x
    boundary = top
    value=0.0
  [../]
  [./top_z]
    type = DirichletBC
    variable = disp_z
    boundary = top
    value=0.0
  [../]
  [./right_x]
   type = DirichletBC
    variable = disp_x
    boundary = right
    value=0.0
  [../]
  [./right_z]
    type = DirichletBC
    variable = disp_z
    boundary = right
    value=0.0
  [../]
  [./left_x]
   type = DirichletBC
    variable = disp_x
    boundary = left
    value=0.0
  [../]
  [./left_z]
    type = DirichletBC
    variable = disp_z
    boundary = left
    value=0.0
  [../]
  [./front_x]
   type = DirichletBC
    variable = disp_x
    boundary = front
    value=0.0
  [../]
  [./front_z]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value=0.0
  [../]
  [./back_x]
   type = DirichletBC
    variable = disp_x
    boundary = back
    value=0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value=0.0
  [../]
    [./bottom_x]
      type = DirichletBC
      variable = disp_x
      boundary = bottom
      value=0.0
    [../]
    [./bottom_z]
      type = DirichletBC
      variable = disp_z
      boundary = bottom
      value=0.0
    [../]
    [./bottom_y]
      type = FunctionDirichletBC
      variable = disp_y
      boundary = bottom
      function = displacement_bc
    [../]
[]


[Materials]
  [./constant]
    type = ComputeIsotropicElasticityTensor
    block = '0'
    youngs_modulus = 1.0
    poissons_ratio = 0.0
  [../]
  [./constant_strain]
    type= ComputeFiniteStrain
    block = '0'
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./constant_stress]
    type = ComputeFiniteStrainElasticStress
    block = '0'
  [../]
  [./density]
    type = GenericConstantMaterial
    block = '0'
    prop_names = 'density'
    prop_values = '1'
  [../]
[]

[Executioner]

  type = Transient
  start_time = 0
  end_time = 6.0
  dtmax = 0.1
  dtmin = 0.1
  l_tol = 1e-8
  nl_rel_tol = 1e-8
  [./TimeStepper]
    type = ConstantDT
    dt = 0.1
  [../]

[]


[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0.0 0.1 0.2 1.0 2.0 5.0'
    y = '0.0 0.001 1 0.001 0.0 0.0'
    scale_factor = 7750
  [../]
  [./displacement_ic]
    type = PiecewiseLinear
    axis = y
    x = '0.0 0.3 0.4 0.5 0.6 0.7 1.0'
    y = '0.0 0.0 0.0001 1.0 0.0001 0.0 0.0'
    scale_factor = 0.1
  [../]
  [./displacement_bc]
    type = PiecewiseLinear
    data_file = 'sine_wave.csv'
    format = columns
  [../]

[]

[Postprocessors]
   [./_dt]
     type = TimestepSize
   [../]
    [./disp_1]
       type = NodalVariableValue
       nodeid = 1
       variable = disp_y
     [../]
    [./disp_2]
       type = NodalVariableValue
       nodeid = 3
       variable = disp_y
     [../]
    [./disp_3]
       type = NodalVariableValue
       nodeid = 10
       variable = disp_y
     [../]
    [./disp_4]
       type = NodalVariableValue
       nodeid = 14
       variable = disp_y
     [../]
[]

[Outputs]
  exodus = true
  csv = true
  perf_graph = true
[]

modules/tensor_mechanics/test/tests/eigenstrain/reducedOrderRZLinearConstant.i

#
# This test checks whether the ComputeReducedOrderEigenstrain is functioning properly.
#
# If instead of 'fred', 'thermal_eigenstrain' is given to
# eigenstrain_names in the Modules/TensorMechanics/Master/all block, the output will be
# identical since the thermal strain is constant in the elements.
#

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 1
  xmax = 3
  xmin = 1
  ymax = 1
  ymin = 0
[]

[Functions]
  [./tempBC]
    type = ParsedFunction
    value = '700+2*t*t'
  [../]
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
    initial_condition = 700
  [../]
[]

[AuxVariables]
  [./hydro_constant]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./hydro_first]
    order = FIRST
    family = MONOMIAL
  [../]
  [./hydro_second]
    order = SECOND
    family = MONOMIAL
  [../]
  [./sxx_constant]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./sxx_first]
    order = FIRST
    family = MONOMIAL
  [../]
  [./sxx_second]
    order = SECOND
    family = MONOMIAL
  [../]
  [./szz_constant]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./szz_first]
    order = FIRST
    family = MONOMIAL
  [../]
  [./szz_second]
    order = SECOND
    family = MONOMIAL
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        add_variables = true
        strain = SMALL
        incremental = true
        temperature = temp
        eigenstrain_names = 'fred' #'thermal_eigenstrain'
      [../]
    [../]
  [../]
[]

[Kernels]
  [./heat]
    type = Diffusion
    variable = temp
  [../]
[]

[AuxKernels]
  [./hydro_constant_aux]
    type = RankTwoScalarAux
    variable = hydro_constant
    rank_two_tensor = stress
    scalar_type = Hydrostatic
  [../]
  [./hydro_first_aux]
    type = RankTwoScalarAux
    variable = hydro_first
    rank_two_tensor = stress
    scalar_type = Hydrostatic
  [../]
  [./hydro_second_aux]
    type = RankTwoScalarAux
    variable = hydro_second
    rank_two_tensor = stress
    scalar_type = Hydrostatic
  [../]
  [./sxx_constant_aux]
    type = RankTwoAux
    variable = sxx_constant
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  [../]
  [./sxx_first_aux]
    type = RankTwoAux
    variable = sxx_first
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  [../]
  [./sxx_second_aux]
    type = RankTwoAux
    variable = sxx_second
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  [../]
  [./szz_constant_aux]
    type = RankTwoAux
    variable = szz_constant
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
  [./szz_first_aux]
    type = RankTwoAux
    variable = szz_first
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
  [./szz_second_aux]
    type = RankTwoAux
    variable = szz_second
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom top'
    value = 0.0
  [../]

  [./temp_right]
    type = FunctionDirichletBC
    variable = temp
    boundary = right
    function = tempBC
  [../]
  [./temp_left]
    type = FunctionDirichletBC
    variable = temp
    boundary = left
    function = tempBC
  [../]
[]


[Materials]
  [./fuel_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0
  [../]
  [./fuel_thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-6
    temperature = temp
    stress_free_temperature = 700.0
    eigenstrain_name = 'thermal_eigenstrain'
  [../]
  [./reduced_order_eigenstrain]
    type = ComputeReducedOrderEigenstrain
    input_eigenstrain_names = 'thermal_eigenstrain'
    eigenstrain_name = 'fred'
  [../]
[]


[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew '
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type'
  petsc_options_value = '70 hypre boomeramg'

  dt = 1
  num_steps = 10
  nl_rel_tol = 1e-8
[]

[Postprocessors]
  [./_dt]
    type = TimestepSize
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_simple_linear/linear-ad.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_x]
    scaling = 1e-10
  [../]
  [./disp_y]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_x]
    type = ADStressDivergenceTensors
    component = 0
    variable = disp_x
  [../]
  [./stress_y]
    type = ADStressDivergenceTensors
    component = 1
    variable = disp_y
  [../]
  [./stress_z]
    type = ADStressDivergenceTensors
    component = 2
    variable = disp_z
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeSmallStrain
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = "linear-out"
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_3/ring3_mu_0_2_pen.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring3_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-9
  l_max_its = 100
  nl_max_its = 1000
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = ring3_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = ring3_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x11 disp_y11 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    tangential_tolerance = 1e-3
    friction_coefficient = 0.2
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/volumetric_eigenstrain/volumetric_eigenstrain.i

# This tests the ability of the ComputeVolumetricEigenstrain material
# to compute an eigenstrain tensor that results in a solution that exactly
# recovers the specified volumetric expansion.
# This model applies volumetric strain that ramps from 0 to 2 to a unit cube
# and computes the final volume, which should be exactly 3.  Note that the default
# TaylorExpansion option for decomposition_method gives a small (~4%) error
# with this very large incremental strain, but decomposition_method=EigenSolution
# gives the exact solution.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./volumetric_strain]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./master]
    use_displaced_mesh = true
    strain = FINITE
    eigenstrain_names = eigenstrain
    decomposition_method = EigenSolution #Necessary for exact solution
  [../]
[]

[AuxKernels]
  [./volumetric_strain]
    type = RankTwoScalarAux
    scalar_type = VolumetricStrain
    rank_two_tensor = total_strain
    variable = volumetric_strain
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./finite_strain_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./volumetric_eigenstrain]
    type = ComputeVolumetricEigenstrain
    volumetric_materials = volumetric_change
    eigenstrain_name = eigenstrain
    args = ''
  [../]
  [./volumetric_change]
    type = GenericFunctionMaterial
    prop_names = volumetric_change
    prop_values = t
  [../]
[]

[Postprocessors]
  [./vol]
    type = VolumePostprocessor
    use_displaced_mesh = true
    execute_on = 'initial timestep_end'
  [../]
  [./volumetric_strain]
    type = ElementalVariableValue
    variable = volumetric_strain
    elementid = 0
  [../]
  [./disp_right]
    type = NodalMaxValue
    variable = disp_x
    boundary = right
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  l_max_its = 100
  l_tol = 1e-4
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 2.0
  dt = 1.0
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/mortar_tm/2d/ad_frictionless_fir/finite_rr.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'finite_rr'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
    extra_vector_tags = 'ref'
    use_automatic_differentiation = true
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = ADFunctionDirichletBC
    variable = disp_x
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
  nl_abs_tol = 1e-7
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/combined/test/tests/mortar_tm/2d/ad_frictionless_fir/small.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'small'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
    use_automatic_differentiation = true
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = ADFunctionDirichletBC
    variable = disp_x
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
    block = 'plank block'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/combined/test/tests/sliding_block/sliding/dirac/frictionless_kinematic.i

#  This is a benchmark test that checks Dirac based frictionless
#  contact using the kinematic method.  In this test a constant
#  displacement is applied in the horizontal direction to simulate
#  a small block come sliding down a larger block.
#
#  The gold file is run on one processor
#  and the benchmark case is run on a minimum of 4 processors to ensure no
#  parallel variability in the contact pressure and penetration results.
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./stiffStuff]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]  # Materials

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter -ksp_gmres_restart'
  petsc_options_value = 'hypre    boomeramg  4    101'

  line_search = 'none'

  nl_abs_tol = 1e-7
  l_max_its = 200
  nl_max_its = 1000
  dt = 0.05
  end_time = 10
  num_steps = 1000
  nl_rel_tol = 1e-6
  dtmin = 0.01
  l_tol = 1e-6

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+6
    formulation = kinematic
    normal_smoothing_distance = 0.1
    system = DiracKernel
  [../]
[]

modules/tensor_mechanics/test/tests/thermal_expansion/constant_expansion_stress_free_temp.i

# This test involves only thermal expansion strains on a 2x2x2 cube of approximate
# steel material; however, in this case the stress free temperature of the material
# has been set to 200K so that there is an initial delta temperature of 100K.

# An initial temperature of 300K is given for the material,
# and an auxkernel is used to calculate the temperature in the entire cube to
# raise the temperature each time step.  The final temperature is 675K
# The thermal strain increment should therefore be
#     (675K - 300K) * 1.3e-5 1/K + 100K * 1.3e-5 1/K = 6.175e-3 m/m.

# This test uses a start up step to identify problems in the calculation of
# eigenstrains with a stress free temperature that is different from the initial
# value of the temperature in the problem

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
    initial_condition = 300.0
  [../]
  [./eigenstrain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./eigenstrain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./eigenstrain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./total_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./total_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./total_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t*(5000.0)+300.0
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        strain = SMALL
        incremental = true
        add_variables = true
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
  [../]
  [./eigenstrain_yy]
    type = RankTwoAux
    rank_two_tensor = eigenstrain
    variable = eigenstrain_yy
    index_i = 1
    index_j = 1
    execute_on = 'initial timestep_end'
  [../]
  [./eigenstrain_xx]
    type = RankTwoAux
    rank_two_tensor = eigenstrain
    variable = eigenstrain_xx
    index_i = 0
    index_j = 0
    execute_on = 'initial timestep_end'
  [../]
  [./eigenstrain_zz]
    type = RankTwoAux
    rank_two_tensor = eigenstrain
    variable = eigenstrain_zz
    index_i = 2
    index_j = 2
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = total_strain_yy
    index_i = 1
    index_j = 1
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = total_strain_xx
    index_i = 0
    index_j = 0
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = total_strain_zz
    index_i = 2
    index_j = 2
    execute_on = 'initial timestep_end'
  [../]
[]

[BCs]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 200
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = -0.0125
  n_startup_steps = 1
  end_time = 0.075
  dt = 0.0125
  dtmin = 0.0001
[]

[Outputs]
  exodus = true
[]

[Postprocessors]
  [./eigenstrain_xx]
    type = ElementAverageValue
    variable = eigenstrain_xx
    execute_on = 'initial timestep_end'
  [../]
  [./eigenstrain_yy]
    type = ElementAverageValue
    variable = eigenstrain_yy
    execute_on = 'initial timestep_end'
  [../]
  [./eigenstrain_zz]
    type = ElementAverageValue
    variable = eigenstrain_zz
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_xx]
    type = ElementAverageValue
    variable = total_strain_xx
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_yy]
    type = ElementAverageValue
    variable = total_strain_yy
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_zz]
    type = ElementAverageValue
    variable = total_strain_zz
    execute_on = 'initial timestep_end'
  [../]
  [./temperature]
    type = AverageNodalVariableValue
    variable = temp
    execute_on = 'initial timestep_end'
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/cwp04.i

# Capped weak-plane plasticity
# checking jacobian for tensile failure, with some shear
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 2
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 0.5
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.05
    rate = 1
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 1
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningConstant
    value = 100
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 0  0 0 1  0 1 2'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 1
    smoothing_tol = 2
    yield_function_tol = 1E-10
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    #petsc_options = '-snes_test_display'
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymm_gps_finite.i

# this test checks the asixymmetric 1D generalized plane strain formulation using finite strains

[GlobalParams]
  displacements = disp_x
  scalar_out_of_plane_strain = scalar_strain_yy
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = line.e
[]

[Variables]
  [./disp_x]
  [../]
  [./scalar_strain_yy]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./temp]
    initial_condition = 580.0
  [../]
[]

[Functions]
  [./temp]
    type = PiecewiseLinear
    x = '0   1   2'
    y = '580 580 680'
  [../]
  [./disp_x]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 2e-3'
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./GeneralizedPlaneStrain]
      [./gps]
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_zz
    index_i = 2
    index_j = 2
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./temp]
    type = FunctionAux
    variable = temp
    function = temp
    execute_on = 'timestep_begin'
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    boundary = 1
    value = 0
    variable = disp_x
  [../]
  [./disp_x]
    type = FunctionDirichletBC
    boundary = 2
    function = disp_x
    variable = disp_x
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 3600
    poissons_ratio = 0.2
  [../]

  [./strain]
    type = ComputeAxisymmetric1DFiniteStrain
    eigenstrain_names = eigenstrain
    scalar_out_of_plane_strain = scalar_strain_yy
  [../]

  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-6
    temperature = temp
    stress_free_temperature = 580
    eigenstrain_name = eigenstrain
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  line_search = 'none'

  l_max_its = 50
  l_tol = 1e-6
  nl_max_its = 15
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-10
  start_time = 0
  end_time = 2
  num_steps = 2
[]

[Outputs]
  exodus = true
  console = true
[]

modules/tensor_mechanics/test/tests/interaction_integral/interaction_integral_3d_points.i

#This tests the Interaction-Integral evaluation capability.
#This is a 3d extrusion of a 2d plane strain model with 2 elements
#through the thickness, and calculates the Interaction-Integrals using options
#to treat it as 3d.

[GlobalParams]
  order = FIRST
#  order = SECOND
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack3d.e
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = 'InteractionIntegralKI InteractionIntegralKII InteractionIntegralKIII'
  crack_front_points = '0 -10 .5
                        0 -10 0
                        0 -10 -.5'
  closed_loop = false # if user provides 'crack_front_points' instead of 'boundary', 'closed_loop' should be set by user!
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  radius_inner = '4.0 5.5'
  radius_outer = '5.5 7.0'
  block = 1
  youngs_modulus = 207000
  poissons_ratio = 0.3
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 500
    value = 0.0
  [../]
  [./no_z2]
    type = DirichletBC
    variable = disp_z
    boundary = 510
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-7
  l_tol = 1e-3

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = interaction_integral_3d_points_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymm_plane_strain_small.i

#
# This test checks elastic stress calculations with mechanical and thermal
# strain using small strain formulation. Young's modulus is 3600, and Poisson's ratio is 0.2.
# The axisymmetric, plane strain 1D mesh is pulled with 1e-6 strain.  Thus,
# the strain is [1e-6, 0, 1e-6] (xx, yy, zz).  This gives stress of
# [5e-3, 2e-3, 5e-3].  After a temperature increase of 100 with alpha of
# 1e-8, the stress becomes [-1e-3, -4e-3, -1e-3].
#

[GlobalParams]
  displacements = disp_x
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = line.e
[]

[Variables]
  [./disp_x]
  [../]
[]

[AuxVariables]
  [./temp]
    initial_condition = 580.0
  [../]
[]

[Functions]
  [./temp]
    type = PiecewiseLinear
    x = '0   1   2'
    y = '580 580 680'
  [../]
  [./disp_x]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 2e-6'
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./ps]
        planar_formulation = PLANE_STRAIN
        strain = SMALL
        generate_output = 'strain_xx strain_zz stress_xx stress_yy stress_zz'
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    function = temp
    execute_on = 'timestep_begin'
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    boundary = 1
    value = 0
    variable = disp_x
  [../]
  [./disp_x]
    type = FunctionDirichletBC
    boundary = 2
    function = disp_x
    variable = disp_x
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 3600
    poissons_ratio = 0.2
  [../]

  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-8
    temperature = temp
    stress_free_temperature = 580
    eigenstrain_name = eigenstrain
  [../]

  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  line_search = 'none'

  l_max_its = 50
  l_tol = 1e-6
  nl_max_its = 15
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-10
  start_time = 0
  end_time = 2
  num_steps = 2
[]

[Outputs]
  exodus = true
  console = true
[]

modules/tensor_mechanics/test/tests/generalized_plane_strain/generalized_plane_strain_scalar_vector.i

[Mesh]
  file = 2squares.e
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./scalar_strain_zz1]
    order = FIRST
    family = SCALAR
  [../]
  [./scalar_strain_zz2]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./aux_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Postprocessors]
  [./react_z1]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    block = 1
  [../]
  [./react_z2]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    block = 2
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./GeneralizedPlaneStrain]
      [./gps1]
        use_displaced_mesh = true
        displacements = 'disp_x disp_y'
        scalar_out_of_plane_strain = scalar_strain_zz1
        block = '1'
      [../]
      [./gps2]
        use_displaced_mesh = true
        displacements = 'disp_x disp_y'
        scalar_out_of_plane_strain = scalar_strain_zz2
        block = '2'
      [../]
    [../]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = false
    displacements = 'disp_x disp_y'
    temperature = temp
    save_in = 'saved_x saved_y'
    block = '1 2'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]

  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_xy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xy
    index_i = 0
    index_j = 1
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./aux_strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = aux_strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottom1x]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottom1y]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
  [./bottom2x]
    type = DirichletBC
    boundary = 2
    variable = disp_x
    value = 0.0
  [../]
  [./bottom2y]
    type = DirichletBC
    boundary = 2
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
    block = '1 2'
  [../]
  [./strain1]
    type = ComputePlaneSmallStrain
    displacements = 'disp_x disp_y'
    subblock_index_provider = test_subblock_index_provider
    scalar_out_of_plane_strain = 'scalar_strain_zz1 scalar_strain_zz2'
    block = '1 2'
    eigenstrain_names = eigenstrain
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    block = '1 2'
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
    block = '1 2'
  [../]
[]

[UserObjects]
  [./test_subblock_index_provider]
    type = TestSubblockIndexProvider
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-10

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
  num_steps = 5000
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/interaction_integral/interaction_integral_3d_rot.i

#This tests the Interaction-Integral evaluation capability.
#This is a 3d extrusion of a 2d plane strain model with 2 elements
#through the thickness, and calculates the Interaction-Integrals using options
#to treat it as 3d.

[GlobalParams]
  order = FIRST
#  order = SECOND
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack3d_rot.e
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = 'InteractionIntegralKI InteractionIntegralKII InteractionIntegralKIII'
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '0 0 -1'
  radius_inner = '4.0 5.5'
  radius_outer = '5.5 7.0'
  block = 1
  youngs_modulus = 207000
  poissons_ratio = 0.3
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_x
    boundary = 500
    value = 0.0
  [../]
  [./no_z2]
    type = DirichletBC
    variable = disp_x
    boundary = 510
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_z
    boundary = 700
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'


  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = interaction_integral_3d_rot_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/material_limit_time_step/damage/elements_changed_timestep_limit.i

# This is a basic test of the system for continuum damage mechanics
# materials. It uses ScalarMaterialDamage for the damage model,
# which simply gets its damage index from another material. In this
# case, we prescribe the evolution of the damage index using a
# function. A single element has a fixed prescribed displacement
# on one side that puts the element in tension, and then the
# damage index evolves from 0 to 1 over time, and this verifies
# that the stress correspondingly drops to 0.

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 10
  ny = 1
  nz = 1
  elem_type = HEX8
[]

[AuxVariables]
  [damage_index]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Modules/TensorMechanics/Master]
  [all]
    strain = SMALL
    incremental = true
    add_variables = true
    generate_output = 'stress_xx strain_xx'
  []
[]

[AuxKernels]
  [damage_index]
    type = MaterialRealAux
    variable = damage_index
    property = damage_index_prop
    execute_on = timestep_end
  []
[]

[BCs]
  [symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  []
  [symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  []
  [symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  []
  [axial_load]
    type = DirichletBC
    variable = disp_x
    boundary = right
    value = 0.01
  []
[]

[Functions]
  [damage_evolution]
    type = ParsedFunction
    value = 'min(1.0, max(0.0, t - x * 3.0))'
  []
[]

[Materials]
  [damage_index]
    type = GenericFunctionMaterial
    prop_names = damage_index_prop
    prop_values = damage_evolution
  []
  [damage]
    type = ScalarMaterialDamage
    damage_index = damage_index_prop
    use_old_damage = true
    maximum_damage_increment = 0.5
  []
  [stress]
    type = ComputeDamageStress
    damage_model = damage
  []
  [elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.2
    youngs_modulus = 10e9
  []
[]

[Postprocessors]
  [stress_xx]
    type = ElementAverageValue
    variable = stress_xx
  []
  [strain_xx]
    type = ElementAverageValue
    variable = strain_xx
  []
  [damage_index]
    type = ElementAverageValue
    variable = damage_index
  []
  [time_step_limit]
    type = MaterialTimeStepPostprocessor
    use_material_timestep_limit = false
    elements_changed_property = damage_index_prop
    elements_changed = 4
  []
[]

[Executioner]
  type = Transient

  l_max_its  = 50
  l_tol      = 1e-8
  nl_max_its = 20
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-6

  dtmin = 0.001
  end_time = 4.0
  [TimeStepper]
    type = IterationAdaptiveDT
    dt = 0.2
    growth_factor = 2.0
    cutback_factor = 0.5
    timestep_limiting_postprocessor = time_step_limit
  []
[]

[Outputs]
  exodus = true
  csv=true
[]

modules/tensor_mechanics/test/tests/jacobian/cwp01.i

# Capped weak-plane plasticity
# checking jacobian for a fully-elastic situation
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[ICs]
  [./disp_x]
    type = RandomIC
    variable = disp_x
    min = -0.1
    max = 0.1
  [../]
  [./disp_y]
    type = RandomIC
    variable = disp_y
    min = -0.1
    max = 0.1
  [../]
  [./disp_z]
    type = RandomIC
    variable = disp_z
    min = -0.1
    max = 0.1
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 2
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 0.5
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.05
    rate = 1
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 0
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningConstant
    value = 100
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '1 2 3  2 -4 -5  3 -5 2'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 1
    smoothing_tol = 2
    yield_function_tol = 1E-10
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking_exponential.i

#
# Test to exercise the exponential stress release
#
# Stress vs. strain should show a linear relationship until cracking,
#   an exponential stress release, a linear relationship back to zero
#   strain, a linear relationship with the original stiffness in
#   compression and then back to zero strain, a linear relationship
#   back to the exponential curve, and finally further exponential
#   stress release.
#

[Mesh]
  file = cracking_test.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./displx]
    type = PiecewiseLinear
    x = '0 1       2  3      4 5       6'
    y = '0 0.00175 0 -0.0001 0 0.00175 0.0035'
  [../]
  [./disply]
    type = PiecewiseLinear
    x = '0 5 6'
    y = '0 0 .00175'
  [../]
  [./displz]
    type = PiecewiseLinear
    x = '0 2 3'
    y = '0 0 .0035'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[BCs]
  [./pullx]
    type = FunctionDirichletBC
    #type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = displx
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = '11 12'
    value = 0.0
  [../]

  [./move_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = '15 16'
    function = disply
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = '3'
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 186.5e9
    poissons_ratio = .316
  [../]
  [./elastic_stress]
    type = ComputeSmearedCrackingStress
    cracking_stress = 119.3e6
    softening_models = exponential_softening
  [../]
  [./exponential_softening]
    type = ExponentialSoftening
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type'
  petsc_options_value = '101                lu'

  line_search = 'none'
  l_max_its = 100
  l_tol = 1e-6

  nl_max_its = 10
  nl_rel_tol = 1e-12
  nl_abs_tol = 1.e-4

  start_time = 0.0
  dt = 0.02
  dtmin = 0.02
  num_steps = 300
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_viscoplasticity_stress_update/lps_single.i

# This test provides an example of an individual LPS viscoplasticity model

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 1
  ny = 1
  xmax = 0.002
  ymax = 0.002
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  add_variables = true
  generate_output = 'strain_xx strain_yy strain_xy hydrostatic_stress vonmises_stress'
  use_automatic_differentiation = true
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x = '0 0.1'
    y = '0 1e-5'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ADComputeMultiplePorousInelasticStress
    inelastic_models = lps
    initial_porosity = 0.1
    outputs = all
  [../]

  [./lps]
    type = ADViscoplasticityStressUpdate
    coefficient = 'coef'
    power = 3
    outputs = all
    relative_tolerance = 1e-11
  [../]
  [./coef]
    type = ParsedMaterial
    f_name = coef
    # Example of creep power law
    function = '1e-18 * exp(-4e4 / 1.987 / 1200)'
  [../]
[]

[BCs]
  [./no_disp_x]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./no_disp_y]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./pull_disp_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = top
    function = pull
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  dt = 0.01
  end_time = 0.12
[]

[Postprocessors]
  [./disp_x]
    type = SideAverageValue
    variable = disp_x
    boundary = right
  [../]
  [./disp_y]
    type = SideAverageValue
    variable = disp_y
    boundary = top
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
  [../]
  [./dt]
    type = TimestepSize
  [../]
  [./num_lin]
    type = NumLinearIterations
    outputs = console
  [../]
  [./num_nonlin]
    type = NumNonlinearIterations
    outputs = console
  [../]
  [./eff_creep_strain]
    type = ElementAverageValue
    variable = effective_viscoplasticity
  [../]
  [./porosity]
    type = ElementAverageValue
    variable = porosity
  [../]
[]

[Outputs]
  csv = true
[]

modules/tensor_mechanics/test/tests/jacobian/thermal_coupling.i

# Thermal eigenstrain coupling
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./temperature]
  [../]
[]

[Kernels]
  [./cx_elastic]
    type = StressDivergenceTensors
    variable = disp_x
    temperature = temperature
    thermal_eigenstrain_name = thermal_contribution
    component = 0
  [../]
  [./cy_elastic]
    type = StressDivergenceTensors
    variable = disp_y
    temperature = temperature
    thermal_eigenstrain_name = thermal_contribution
    component = 1
  [../]
  [./cz_elastic]
    type = StressDivergenceTensors
    variable = disp_z
    temperature = temperature
    thermal_eigenstrain_name = thermal_contribution
    component = 2
  [../]
  [./temperature]
    type = Diffusion
    variable = temperature
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 10.0
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeSmallStrain
    eigenstrain_names = thermal_contribution
  [../]
  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    temperature = temperature
    thermal_expansion_coeff = 1.0E2
    eigenstrain_name = thermal_contribution
    stress_free_temperature = 0.0
  [../]
  [./admissible]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  solve_type = NEWTON
  end_time = 1
  dt = 1
  type = Transient
[]

modules/xfem/test/tests/corner_nodes_cut/notch.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '-0.26 0.0 0.0 0.1'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
[]

[Mesh]
  file = notch.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
  [../]
[]

[BCs]
  [./top_x]
    type = DirichletBC
    boundary = 102
    variable = disp_x
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    boundary = 102
    variable = disp_y
    value = 0.1
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 101
    variable = disp_y
    value = -0.1
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = 101
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-9

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/combined/test/tests/exception/ad.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_update_strategy = iteration
  [./gen]
    type = FileMeshGenerator
    file = mesh.e
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./temp]
    initial_condition = 501
  [../]
[]

[AuxVariables]
  [./density_aux]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master]
  [./finite]
    strain = FINITE
    use_automatic_differentiation = true
  [../]
[]

[Kernels]
  [./gravity]
    type = ADGravity
    variable = disp_y
    value = -9.81
  [../]
  [./heat]
    type = ADMatDiffusion
    variable = temp
    diffusivity = 1
  [../]
  [./heat_ie]
    type = ADTimeDerivative
    variable = temp
  [../]
[]

[AuxKernels]
  [./conductance]
    type = MaterialRealAux
    property = density
    variable = density_aux
    boundary = inner_surface
  [../]
[]

[ThermalContact]
  [./thermal_contact]
    type = GapHeatTransfer
    variable = temp
    master = outer_interior
    slave = inner_surface
    quadrature = true
  [../]
[]

[BCs]
  [./no_x]
    type = ADDirichletBC
    variable = disp_x
    boundary = 'centerline'
    value = 0.0
  [../]
  [./no_y]
    type = ADDirichletBC
    variable = disp_y
    boundary = 'centerline outer_exterior'
    value = 0.0
  [../]
  [./temp]
    type = FunctionDirichletBC
    boundary = outer_exterior
    variable = temp
    function = '500 + t'
  [../]
[]

[Materials]
  [./density]
    type = GenericConstantMaterial
    prop_names = 'density'
    prop_values = '1'
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e11
    poissons_ratio = 0.3
  [../]

  [./inner_elastic_stress]
    type = ADComputeMultipleInelasticStress
    inelastic_models = 'inner_creep'
    block = inner
    outputs = all
  [../]

  [./inner_creep]
    type = ADPowerLawCreepExceptionTest
    coefficient = 10e-22
    n_exponent = 2
    activation_energy = 0
    block = inner
  [../]

  [./outer_stressstress]
    type = ADComputeFiniteStrainElasticStress
    block = outer
  [../]
[]

[Executioner]
  type = Transient
  petsc_options = ' -snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'
  line_search = none

  nl_abs_tol = 1e-7
  l_max_its = 20

  num_steps = 1
  dt = 1
  dtmin = .1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/capped_drucker_prager/small_deform2_lode_zero.i

# apply repeated stretches in x, y and z directions, so that mean_stress = 0
# This maps out the yield surface in the octahedral plane for zero mean stress

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz'
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '-1.5E-6*x+2E-6*x*sin(t)'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2E-6*y*sin(2*t)'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '-2E-6*z*(sin(t)+sin(2*t))'
  [../]
[]

[AuxVariables]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1000
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1000
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 20
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 0
  [../]
  [./dp]
    type = TensorMechanicsPlasticDruckerPrager
    mc_cohesion = mc_coh
    mc_friction_angle = mc_phi
    mc_dilation_angle = mc_psi
    mc_interpolation_scheme = lode_zero
    internal_constraint_tolerance = 1 # irrelevant here
    yield_function_tolerance = 1      # irrelevant here
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    lambda = 0.0
    shear_modulus = 1.0e7
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = cdp
    perform_finite_strain_rotations = false
  [../]
  [./cdp]
    type = CappedDruckerPragerStressUpdate
    DP_model = dp
    tensile_strength = ts
    compressive_strength = cs
    yield_function_tol = 1E-8
    tip_smoother = 4
    smoothing_tol = 1E-5
  [../]
[]


[Executioner]
  end_time = 100
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform2_lode_zero
  exodus = false
  [./csv]
    type = CSV
  [../]
[]

modules/tensor_mechanics/test/tests/capped_mohr_coulomb/small_deform19.i

# Using CappedMohrCoulomb with compressive failure only
# A single unit element is stretched in a complicated way
# that the trial stress is
#
#  -1.2 -2.0 -0.8
#  -2.0  4.4   0
#  -0.8   0   2.8
#
# This has eigenvalues
# la = {-1.963, 2.89478, 5.06822}
# and eigenvectors
# {0.94197, 0.296077, 0.158214}
# {-0.116245, -0.154456, 0.981137},
# {-0.314929, 0.942593, 0.111075},
#
# The compressive strength is 0.5 and Young=1 and Poisson=0.25.
# The return-map algorithm should return to stress_min = -0.5
# This is an increment of 1.463, so stress_mid and stress_max
# should both increase by 1.463 v/(1-v) = 0.488, giving
# stress_mid = 3.382
# stress_max = 5.556
#
# E_22 = E(1-v)/(1+v)/(1-2v)=1.2 and E_02 = E_22 v/(1-v)
# gamma_shear = ((smax-smin)^trial - (smax-smin)) / (E_22 - E_02)
# = ((2v-1)/(1-v)) * (smin^trial - smin) / (E_22(1 - 2v)/(1-v))
# = -(smin^trial - smin) / E_22
# Using psi = 30deg, sin(psi) = 1/2
# the shear correction to the tensile internal parameter is
# gamma_shear (E_22 + E_20) sin(psi) = gamma_shear E_22 sin(psi) / (1 - v)
# = -(smin^trial - smin) / (1 - v) / 2
# Then the tensile internal parameter is
# (1 - v) * (reduction_of_(max+min)_principal - gamma_shear * E_22 / (1-v) / 2) / E_22
# = -1.829
#
# The final stress is
#
# {0.15, -1.7, -0.65},
# {-1.7, 4.97, 0.046},
# {-0.65, 0.046, 3.3}

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz'
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '-(3*x+2*y+z)'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '-(3*x-4*y)'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '-(x-2*z)'
  [../]
[]

[AuxVariables]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./f0_auxk]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1_auxk]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2_auxk]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./intnl_auxk]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 1
    variable = intnl
  [../]
[]

[Postprocessors]
  [./s_I]
    type = PointValue
    point = '0 0 0'
    variable = max_principal_stress
  [../]
  [./s_II]
    type = PointValue
    point = '0 0 0'
    variable = mid_principal_stress
  [../]
  [./s_III]
    type = PointValue
    point = '0 0 0'
    variable = min_principal_stress
  [../]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
  [./intnl]
    type = PointValue
    point = '0 0 0'
    variable = intnl
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 0.5
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.25
  [../]
  [./tensile]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.001
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = tensile
    perform_finite_strain_rotations = false
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform19
  csv = true
[]

modules/combined/test/tests/ad_power_law_creep/power_law_creep_simple.i

# 1x1x1 unit cube with uniform pressure on top face

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[AuxVariables]
  [./temp]
    initial_condition = 1000.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy creep_strain_xx creep_strain_yy creep_strain_zz elastic_strain_yy'
    use_automatic_differentiation = true
  [../]
[]
[BCs]
  [./u_top_fix]
    type = ADDirichletBC
    variable = disp_y
    boundary = top
    value = 1e-5
  [../]
  [./u_bottom_fix]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = ADDirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e11
    poissons_ratio = 0.3
  [../]
  [./radial_return_stress]
    type = ADComputeMultipleInelasticStress
    inelastic_models = 'power_law_creep'
  [../]
  [./power_law_creep]
    type = ADPowerLawCreepStressUpdate
    coefficient = 1.0e-15
    n_exponent = 4
    activation_energy = 3.0e5
    temperature = temp
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  num_steps = 10
  dt = 0.1
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/solid_mechanics/LinearStrainHardening/LinearStrainHardening_test.i

#

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = LinearStrainHardening_test.e
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]


[AuxVariables]

  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_mag]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]


[Functions]
  [./top_pull]
    type = ParsedFunction
    value = t/5.0
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]


[AuxKernels]

  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]

  [./plastic_strain_xx]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]

  [./plastic_strain_yy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]

  [./plastic_strain_zz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]

  [./plastic_strain_mag]
    type = MaterialRealAux
    property = effective_plastic_strain
    variable = plastic_strain_mag
  [../]

 []


[BCs]

  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = top_pull
  [../]

  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]

  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]

  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]

[]


[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'isoplas'
    block = '1'
  [../]
  [./isoplas]
    type = IsotropicPlasticityStressUpdate
    yield_stress = 2.4e2
    hardening_constant = 1206
    relative_tolerance = 1e-25
    absolute_tolerance = 1e-05
  [../]
[]


[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'


  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'


  line_search = 'none'


  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9
  start_time = 0.0
  end_time = 0.0105
#  num_steps = 100
  dt = 1.5e-3
[]



[Outputs]
  file_base = LinearStrainHardeningRestart2_out
  exodus = true
[]

modules/combined/test/tests/reference_residual/reference_residual.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 4
  ny = 4
  nz = 4
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]

  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./saved_t]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    volumetric_locking_correction = true
    incremental = true
    save_in = 'saved_x saved_y saved_z'
    eigenstrain_names = thermal_expansion
    strain = FINITE
    decomposition_method = EigenSolution
    extra_vector_tags = 'ref'
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
    save_in = saved_t
    extra_vector_tags = 'ref'
  [../]
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x = '0 1 2'
    y = '0 1 1'
    scale_factor = 0.1
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = bottom
    value = 0.0
  [../]

  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]

  [./top_x]
    type = DirichletBC
    variable = disp_x
    boundary = top
    value = 0.0
  [../]

  [./top_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = pull
  [../]

  [./top_z]
    type = DirichletBC
    variable = disp_z
    boundary = top
    value = 0.0
  [../]

  [./bottom_temp]
    type = DirichletBC
    variable = temp
    boundary = bottom
    value = 10.0
  [../]

  [./top_temp]
    type = DirichletBC
    variable = temp
    boundary = top
    value = 20.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 1.0
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]

  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    block = 0
    eigenstrain_name = thermal_expansion
    temperature = temp
    thermal_expansion_coeff = 1e-5
    stress_free_temperature = 0.0
  [../]

  [./heat1]
    type = HeatConductionMaterial
    block = 0
    specific_heat = 1.0
    thermal_conductivity = 1e-3 #Tuned to give temperature reference resid close to that of solidmech
  [../]

  [./density]
    type = Density
    block = 0
    density = 1.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-10

  l_tol = 1e-3
  l_max_its = 100

  dt = 1.0
  end_time = 2.0
[]

[Postprocessors]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./ref_resid_z]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_z
  [../]
  [./ref_resid_t]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_t
  [../]
  [./nonlinear_its]
    type = NumNonlinearIterations
  []
[]

[Outputs]
  exodus = true
[]

modules/combined/examples/xfem/xfem_thermomechanics_stress_growth.i

# This is a demonstration of a simple thermomechanics simulation using
# XFEM in which a single crack propagates based on a principal stress
# criterion.
#
# The top and bottom of the plate are fixed in the y direction, and the
# top of the plate is cooled down over time. The thermal contraction
# causes tensile stresses, which lead to crack propagation. The crack
# propagates in a curved path because of the changinging nature of
# the thermal gradient as a result of the crack. There is no heat
# conduction across the crack as soon as it forms.

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 11
  ny = 11
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[Variables]
  # Solve for the temperature and the displacements
  # Displacements are not specified because the TensorMechanics/Master Action sets them up
  [./temp]
    initial_condition = 300
  [../]
[]

[XFEM]
  geometric_cut_userobjects = 'line_seg_cut_uo'
  qrule = volfrac
  output_cut_plane = true
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '1.0  0.5  0.8  0.5'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
  [./xfem_marker_uo]
    type = XFEMRankTwoTensorMarkerUserObject
    execute_on = timestep_end
    tensor = stress
    scalar_type = MaxPrincipal
    threshold = 5e+1
    average = true
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    planar_formulation = plane_strain
    add_variables = true
    eigenstrain_names = eigenstrain
  [../]
[]

[Kernels]
  [./htcond]
    type = HeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./topx]
    type = DirichletBC
    boundary = top
    variable = disp_x
    value = 0.0
  [../]
  [./topy]
    type = DirichletBC
    boundary = top
    variable = disp_y
    value = 0.0
  [../]
  [./topt]
    type = FunctionDirichletBC
    boundary = top
    variable = temp
    function = 273-t*27.3
  [../]
  [./bott]
    type = FunctionDirichletBC
    boundary = bottom
    variable = temp
    function = 273
#    value = 273.0
  [../]
[]

[Materials]
  [./thcond]
    type = GenericConstantMaterial
    prop_names = 'thermal_conductivity'
    prop_values = '5e-6'
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./_elastic_strain]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./thermal_strain]
    type= ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 10e-6
    temperature = temp
    stress_free_temperature = 273
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-9

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 10.0

  max_xfem_update = 5
[]

[Outputs]
  exodus = true
  execute_on = timestep_end
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/combined/test/tests/mortar_tm/2d/frictionless_second/finite_rr.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'finite_rr'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
    extra_vector_tags = 'ref'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    preset = false
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
  nl_abs_tol = 1e-7
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking_xyz.i

#

[Mesh]
  file = cracking_test.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./displx]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.00175'
  [../]
  [./velocity_y]
    type = ParsedFunction
    value = 'if(t < 2, 0.00175, 0)'
  [../]
  [./velocity_z]
    type = ParsedFunction
    value = 0.00175
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./move_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = displx
  [../]

  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./move_y]
    type = PresetVelocity
    variable = disp_y
    boundary = 5
    function = velocity_y
#    time_periods = 'p2 p3'
  [../]

  [./fix_z]
    type = DirichletBC
    variable = disp_z
    boundary = 3
    value = 0.0
  [../]
  [./move_z]
    type = PresetVelocity
    variable = disp_z
    boundary = 6
    function = velocity_z
#    time_periods = 'p3'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 186.5e9
    poissons_ratio = .316
  [../]
  [./elastic_stress]
    type = ComputeSmearedCrackingStress
    cracking_stress = 119.3e6
    softening_models = exponential_softening
  [../]
  [./exponential_softening]
    type = ExponentialSoftening
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type'
  petsc_options_value = '101                lu'


  line_search = 'none'


  l_max_its = 100
  l_tol = 1e-5

  nl_max_its = 100
  nl_abs_tol = 1e-4
  #nl_rel_tol = 1e-4
  nl_rel_tol = 1e-6

  start_time = 0.0
  end_time = 3.0
  dt = 0.01
[]

[Controls]
  [./p1]
    type = TimePeriod
    start_time = 0.0
    end_time = 1.0
    disable_objects = 'BCs/move_y BCs/move_z'
    reverse_on_false = false
    execute_on = 'initial timestep_begin'
  [../]

  [./p2]
    type = TimePeriod
    start_time = 1.0
    end_time = 2.0
    disable_objects = 'BCs/move_z'
    enable_objects = 'BCs/move_y'
    reverse_on_false = false
    execute_on = 'initial timestep_begin'
  [../]

  [./p3]
    type = TimePeriod
    start_time = 2.0
    end_time = 3.0
    enable_objects = 'BCs/move_y BCs/move_z'
    reverse_on_false = false
    execute_on = 'initial timestep_begin'
    set_sync_times = true
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/elastic_thermal_patch/elastic_thermal_patch_rz.i

#
# This problem is modified from the Abaqus verification manual:
#   "1.5.4 Patch test for axisymmetric elements"
# The original stress solution is given as:
#   xx = yy = zz = 2000
#   xy = 400
#
# Here, E=1e6 and nu=0.25.
# However, with a +100 degree change in temperature and a coefficient
#   of thermal expansion of 1e-6, the solution becomes:
#   xx = yy = zz = 1800
#   xy = 400
#   since
#   E*(1-nu)/(1+nu)/(1-2*nu)*(1+2*nu/(1-nu))*(1e-3-1e-4) = 1800
#
# Also,
#
#   dSrr   dSrz   Srr-Stt
#   ---- + ---- + ------- + br = 0
#    dr     dz       r
#
# and
#
#   dSrz   Srz   dSzz
#   ---- + --- + ---- + bz = 0
#    dr     r     dz
#
# where
#   Srr = stress in rr
#   Szz = stress in zz
#   Stt = stress in theta-theta
#   Srz = stress in rz
#   br  = body force in r direction
#   bz  = body force in z direction
#
[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
  volumetric_locking_correction = true
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = elastic_thermal_patch_rz_test.e
[]

[Functions]
  [./ur]
    type = ParsedFunction
    value = '1e-3*x'
  [../]
  [./uz]
    type = ParsedFunction
    value = '1e-3*(x+y)'
  [../]
  [./body]
    type = ParsedFunction
    value = '-400/x'
  [../]
  [./temp]
    type = ParsedFunction
    value = '117.56+100*t'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules/TensorMechanics/Master/All]
  add_variables = true
  strain = SMALL
  incremental = true
  eigenstrain_names = eigenstrain
  generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
[]

[Kernels]
  [./body]
    type = BodyForce
    variable = disp_y
    value = 1
    function = body
  [../]

  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 10
    function = ur
  [../]
  [./uz]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 10
    function = uz
  [../]

  [./temp]
    type = FunctionDirichletBC
    variable = temp
    boundary = 10
    function = temp
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 400000.0
    poissons_ratio = 0.25
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-6
    stress_free_temperature = 117.56
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]

  [./heat]
    type = HeatConductionMaterial
    specific_heat = 0.116
    thermal_conductivity = 4.85e-4
  [../]

  [./density]
    type = Density
    density = 0.283
    disp_r = disp_x
    disp_z = disp_y
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-11
  nl_rel_tol = 1e-12

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 1
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/interaction_integral/interaction_integral_2d.i

#This tests the Interaction Integral evaluation capability.
#This is a 2d nonlinear plane strain model

[GlobalParams]
  order = FIRST
#  order = SECOND
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack2d.e
  displacements = 'disp_x disp_y'
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = 'InteractionIntegralKI InteractionIntegralKII InteractionIntegralKIII'
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  radius_inner = '4.0 4.5 5.0 5.5 6.0'
  radius_outer = '4.5 5.0 5.5 6.0 6.5'
  block = 1
  youngs_modulus = 207000
  poissons_ratio = 0.3
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]


[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = interaction_integral_2d_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/inclined_bc/inclined_bc_3d.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 2
    ny = 4
    nz = 2
    xmin = 0.0
    xmax = 1.0
    ymin = 0.0
    ymax = 2.0
    zmin = 0.0
    zmax = 1.0
    elem_type = HEX8
  []
  [rotate]
    type = TransformGenerator
    transform = ROTATE
    vector_value = '0 -20 -60'
    input = generated_mesh
  []
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  add_variables = true
[]

[BCs]
  [./Pressure]
    [./top]
      boundary = top
      function = '-1000*t'
    [../]
  [../]
  [./InclinedNoDisplacementBC]
    [./right]
      boundary = right
      penalty = 1.0e8
      displacements = 'disp_x disp_y disp_z'
    [../]
    [./bottom]
      boundary = bottom
      penalty = 1.0e8
      displacements = 'disp_x disp_y disp_z'
    [../]
    [./back]
      boundary = back
      penalty = 1.0e8
      displacements = 'disp_x disp_y disp_z'
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  # controls for linear iterations
  l_max_its = 10
  l_tol = 1e-4

  # controls for nonlinear iterations
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-12

  # time control
  start_time = 0.0
  dt = 1
  end_time = 5
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/critical_time_step/crit_time_solid_variable.i

[GlobalParams]
  displacements = 'disp_x'
[]

[Mesh]
  type = GeneratedMesh
  dim = 1
  nx = 50

  xmin = 0
  xmax = 5
[]

[Variables]
  [./disp_x]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./2_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
[]

[Functions]
  [./prefac]
    type = ParsedFunction
    value = '1+2*x'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.1
    youngs_modulus = 1e6
    elasticity_tensor_prefactor = prefac
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./density]
    type = GenericConstantMaterial
    prop_names = 'density'
    prop_values = '8050.0'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-4

  l_max_its = 3

  start_time = 0.0
  dt = 0.1
  num_steps = 1
  end_time = 1.0
[]

[Postprocessors]
  [./time_step]
    type = CriticalTimeStep
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/porous_flow/test/tests/thm_rehbinder/fixed_outer.i

[Mesh]
  [annular]
    type = AnnularMeshGenerator
    nr = 40
    nt = 16
    rmin = 0.1
    rmax = 1
    dmin = 0.0
    dmax = 90
    growth_r = 1.1
  []
  [./make3D]
    input = annular
    type = MeshExtruderGenerator
    bottom_sideset = bottom
    top_sideset = top
    extrusion_vector = '0 0 1'
    num_layers = 1
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  PorousFlowDictator = dictator
  biot_coefficient = 1.0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./porepressure]
  [../]
  [./temperature]
  [../]
[]

[BCs]
  [./plane_strain]
    type = DirichletBC
    variable = disp_z
    value = 0
    boundary = 'top bottom'
  [../]
  [./ymin]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = dmin
  [../]
  [./xmin]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = dmax
  [../]

  [./cavity_temperature]
    type = DirichletBC
    variable = temperature
    value = 1000
    boundary = rmin
  [../]
  [./cavity_porepressure]
    type = DirichletBC
    variable = porepressure
    value = 1E6
    boundary = rmin
  [../]
  [./cavity_zero_effective_stress_x]
    type = Pressure
    component = 0
    variable = disp_x
    function = 1E6
    boundary = rmin
    use_displaced_mesh = false
  [../]
  [./cavity_zero_effective_stress_y]
    type = Pressure
    component = 1
    variable = disp_y
    function = 1E6
    boundary = rmin
    use_displaced_mesh = false
  [../]

  [./outer_temperature]
    type = DirichletBC
    variable = temperature
    value = 0
    boundary = rmax
  [../]
  [./outer_pressure]
    type = DirichletBC
    variable = porepressure
    value = 0
    boundary = rmax
  [../]
  [./fixed_outer_x]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = rmax
  [../]
  [./fixed_outer_y]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = rmax
  [../]
[]

[AuxVariables]
  [./stress_rr]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./stress_pp]
    family = MONOMIAL
    order = CONSTANT
  [../]
[]

[AuxKernels]
  [./stress_rr]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = stress_rr
    scalar_type = RadialStress
    point1 = '0 0 0'
    point2 = '0 0 1'
  [../]
  [./stress_pp]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = stress_pp
    scalar_type = HoopStress
    point1 = '0 0 0'
    point2 = '0 0 1'
  [../]
[]

[Modules]
  [./FluidProperties]
    [./the_simple_fluid]
      type = SimpleFluidProperties
      thermal_expansion = 0.0
      bulk_modulus = 1E12
      viscosity = 1.0E-3
      density0 = 1000.0
      cv = 1000.0
      cp = 1000.0
      porepressure_coefficient = 0.0
    [../]
  [../]
[]

[PorousFlowBasicTHM]
  coupling_type = ThermoHydroMechanical
  multiply_by_density = false
  add_stress_aux = true
  porepressure = porepressure
  temperature = temperature
  thermal_eigenstrain_name = thermal_contribution
  gravity = '0 0 0'
  fp = the_simple_fluid
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1E10
    poissons_ratio = 0.2
  [../]
  [./strain]
    type = ComputeSmallStrain
    eigenstrain_names = thermal_contribution
  [../]
  [./thermal_contribution]
    type = ComputeThermalExpansionEigenstrain
    temperature = temperature
    thermal_expansion_coeff = 1E-6
    eigenstrain_name = thermal_contribution
    stress_free_temperature = 0.0
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./porosity]
    type = PorousFlowPorosityConst # only the initial value of this is ever used
    porosity = 0.1
  [../]
  [./biot_modulus]
    type = PorousFlowConstantBiotModulus
    solid_bulk_compliance = 1E-10
    fluid_bulk_modulus = 1E12
  [../]
  [./permeability]
    type = PorousFlowPermeabilityConst
    permeability = '1E-12 0 0   0 1E-12 0   0 0 1E-12'
  [../]
  [./thermal_expansion]
    type = PorousFlowConstantThermalExpansionCoefficient
    fluid_coefficient = 1E-6
    drained_coefficient = 1E-6
  [../]
  [./thermal_conductivity]
    type = PorousFlowThermalConductivityIdeal
    dry_thermal_conductivity = '1E6 0 0  0 1E6 0  0 0 1E6'
  [../]
[]

[VectorPostprocessors]
  [./P]
    type = LineValueSampler
    start_point = '0.1 0 0'
    end_point = '1.0 0 0'
    num_points = 10
    sort_by = x
    variable = porepressure
  [../]
  [./T]
    type = LineValueSampler
    start_point = '0.1 0 0'
    end_point = '1.0 0 0'
    num_points = 10
    sort_by = x
    variable = temperature
  [../]
  [./U]
    type = LineValueSampler
    start_point = '0.1 0 0'
    end_point = '1.0 0 0'
    num_points = 10
    sort_by = x
    variable = disp_x
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -sub_pc_type -snes_rtol'
    petsc_options_value = 'gmres      asm      lu           1E-8'
  [../]
[]

[Executioner]
  type = Steady
  solve_type = Newton
[]

[Outputs]
  file_base = fixed_outer
  execute_on = timestep_end
  csv = true
[]

modules/combined/test/tests/reference_residual/reference_residual_perfgraph.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 4
  ny = 4
  nz = 4
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]

  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./saved_t]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    volumetric_locking_correction = true
    incremental = true
    save_in = 'saved_x saved_y saved_z'
    eigenstrain_names = thermal_expansion
    strain = FINITE
    decomposition_method = EigenSolution
    extra_vector_tags = 'ref'
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
    save_in = saved_t
    extra_vector_tags = 'ref'
  [../]
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x = '0 1 2'
    y = '0 1 1'
    scale_factor = 0.1
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = bottom
    value = 0.0
  [../]

  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]

  [./top_x]
    type = DirichletBC
    variable = disp_x
    boundary = top
    value = 0.0
  [../]

  [./top_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = pull
  [../]

  [./top_z]
    type = DirichletBC
    variable = disp_z
    boundary = top
    value = 0.0
  [../]

  [./bottom_temp]
    type = DirichletBC
    variable = temp
    boundary = bottom
    value = 10.0
  [../]

  [./top_temp]
    type = DirichletBC
    variable = temp
    boundary = top
    value = 20.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 1.0
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]

  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    block = 0
    eigenstrain_name = thermal_expansion
    temperature = temp
    thermal_expansion_coeff = 1e-5
    stress_free_temperature = 0.0
  [../]

  [./heat1]
    type = HeatConductionMaterial
    block = 0
    specific_heat = 1.0
    thermal_conductivity = 1e-3 #Tuned to give temperature reference resid close to that of solidmech
  [../]

  [./density]
    type = Density
    block = 0
    density = 1.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-10
  l_tol = 1e-3
  l_max_its = 100
  dt = 1.0
  end_time = 2.0
[]

[Postprocessors]
  [./res_calls]
    type = PerfGraphData
    section_name = "ReferenceResidualProblem::computeResidualInternal"
    data_type = calls
  [../]
  [./elapsed]
    type = PerfGraphData
    section_name = "Root"
    data_type = total
  [../]
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/mortar_tm/2drz/ad_frictionless_second/finite.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'finite'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    use_automatic_differentiation = true
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
  [../]
  [./plank]
    use_automatic_differentiation = true
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ADComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/ad_simple_linear/linear-mixed-reverse.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./stress_x]
    type = StressDivergenceTensors
    component = 0
    variable = disp_x
  [../]
  [./stress_y]
    type = StressDivergenceTensors
    component = 1
    variable = disp_y
  [../]
  [./stress_z]
    type = StressDivergenceTensors
    component = 2
    variable = disp_z
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeSmallStrain
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = "linear-out"
[]

modules/combined/test/tests/elastic_patch/elastic_patch_rz_nonlinear.i

#
# This problem is taken from the Abaqus verification manual:
#   "1.5.4 Patch test for axisymmetric elements"
# The stress solution is given as:
#   xx = yy = zz = 19900
#   xy = 0
#
# If strain = log(1+1e-2) = 0.00995033...
# then
# stress = E/(1+PR)/(1-2*PR)*(1-PR +PR +PR)*strain = 19900.6617
# with E = 1e6 and PR = 0.25.
#
# The code computes stress = 19900.6617 when
# increment_calculation = eigen.  There is a small error when the
# rashidapprox option is used.
#
# Since the strain is 1e-3 in all three directions, the new density should be
#   new_density = original_density * V_0 / V
#   new_density = 0.283 / (1 + 9.95e-3 + 9.95e-3 + 9,95e-3) = 0.2747973
#
# The code computes a new density of .2746770


[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = elastic_patch_rz.e
[]

[Variables]
  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  decomposition_method = EigenSolution
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
[]

[Kernels]
  [./heat]
    type = TimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    preset = false
    boundary = 10
    function = '1e-2*x'
  [../]
  [./uz]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = 10
    function = '1e-2*y'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./density]
    type = Density
    density = 0.283
    outputs = all
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/glued_penalty_dirac.i

# This is a dirac (contact formulation) version of glued_penalty.i
[Mesh]
  file = blocks_2d_nogap.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    #Initial gap is 0.01
    value = -0.01
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  [../]
  [./right]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.01
  end_time = 0.10
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-8
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    master = 2
    slave = 3
    model = glued
    formulation = penalty
    penalty = 1e+7
    system = diracKernel
  [../]
[]

modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymmetric_gps_incremental.i

#
# This test checks the generalized plane strain using incremental small strain formulation.
# The model consists of two sets of line elements. One undergoes a temperature rise of 100 with
# the other seeing a temperature rise of 300.  Young's modulus is 3600, and
# Poisson's ratio is 0.2.  The thermal expansion coefficient is 1e-8.  All
# nodes are constrained against movement.
#
# For plane strain case, i.e., without constraining the strain_yy to be uniform,
# the stress solution would be [-6e-3, -6e-3, -6e-3] and [-18e-3, -18e-3, -18e-3] (xx, yy, zz).
# The generalized plane strain kernels work to balance the force in y direction.
#
# With out of plane strain of 3e-6, the stress solution becomes
# [-3e-3, 6e-3, -3e-3] and [-15e-3, -6e-3, -15e-3] (xx, yy, zz).  This gives
# a domain integral of out-of-plane stress to be zero.
#

[GlobalParams]
  displacements = disp_x
  scalar_out_of_plane_strain = scalar_strain_yy
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = lines.e
[]

[Variables]
  [./disp_x]
  [../]
  [./temp]
    initial_condition = 580.0
  [../]
  [./scalar_strain_yy]
    order = FIRST
    family = SCALAR
  [../]
[]

[Functions]
  [./temp100]
    type = PiecewiseLinear
    x = '0   1'
    y = '580 680'
  [../]
  [./temp300]
    type = PiecewiseLinear
    x = '0   1'
    y = '580 880'
  [../]
[]

[Kernels]
  [./heat]
    type = Diffusion
    variable = temp
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./gps]
        planar_formulation = GENERALIZED_PLANE_STRAIN
        scalar_out_of_plane_strain = scalar_strain_yy
        strain = SMALL
        incremental = true
        generate_output = 'strain_xx strain_yy strain_zz stress_xx stress_yy stress_zz'
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    boundary = 1000
    value = 0
    variable = disp_x
  [../]
  [./temp100]
    type = FunctionDirichletBC
    variable = temp
    function = temp100
    boundary = 2
  [../]
  [./temp300]
    type = FunctionDirichletBC
    variable = temp
    function = temp300
    boundary = 3
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 3600
    poissons_ratio = 0.2
  [../]

  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-8
    temperature = temp
    stress_free_temperature = 580
    eigenstrain_name = eigenstrain
  [../]

  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  line_search = 'none'

  l_max_its = 50
  l_tol = 1e-6
  nl_max_its = 15
  nl_abs_tol = 1e-10
  start_time = 0
  end_time = 1
  num_steps = 1
[]

[Outputs]
  exodus = true
  console = true
[]

modules/peridynamics/test/tests/jacobian_check/generalized_planestrain_OSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  scalar_out_of_plane_strain = scalar_strain_zz
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/Peridynamics/Mechanics]
  [./Master]
    [./all]
      formulation = ORDINARY_STATE
    [../]
  [../]
  [./GeneralizedPlaneStrain]
    [./all]
      formulation = ORDINARY_STATE
      out_of_plane_stress_variable = stress_zz
    [../]
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = NodalRankTwoPD
    variable = stress_zz

    poissons_ratio = 0.3
    youngs_modulus = 1e6

    rank_two_tensor = stress
    output_type = component
    index_i = 2
    index_j = 2
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialOSPD
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1
[]

modules/combined/test/tests/elastic_patch/elastic_patch_plane_strain.i

#
# This problem is taken from the Abaqus verification manual:
#   "1.5.1 Membrane patch test"
# The stress solution is given as:
#   xx = yy = 1600
#   zz = 800
#   xy = 400
#   yz = zx = 0
#
# Since the strain is 1e-3 in both directions, the new density should be
#   new_density = original_density * V_0 / V
#   new_density = 0.283 / (1 + 1e-3 + 1e-3) = 0.282435

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
[]

[Mesh]
  file = elastic_patch_rz.e
[]

[Variables]
  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = SMALL
  incremental = true
  planar_formulation = PLANE_STRAIN
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
[]

[Kernels]
  [./heat]
    type = TimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 10
    function = '1e-3*(x+0.5*y)'
  [../]
  [./uz]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 10
    function = '1e-3*(y+0.5*x)'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]

  [./density]
    type = Density
    density = 0.283
    outputs = all
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/plane_4/plane4_template1.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane4_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-7
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x9 disp_y9 disp_x16 disp_y16 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_4/cyl4_mu_0_2_pen.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl4_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 1000
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = cyl4_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = cyl4_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x9 disp_y9 disp_x16 disp_y16 stress_yy stress_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update4.i

# MC update version, with only Tensile with tensile strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2 -1 0.5  1 1.9 0  0.5 0 3'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/exception/nonad.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_update_strategy = iteration
  [./gen]
    type = FileMeshGenerator
    file = mesh.e
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./temp]
    initial_condition = 501
  [../]
[]

[AuxVariables]
  [./density_aux]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master]
  [./finite]
    strain = FINITE
  [../]
[]

[Kernels]
  [./gravity]
    type = Gravity
    variable = disp_y
    value = -9.81
  [../]
  [./heat]
    type = MatDiffusion
    variable = temp
    diffusivity = 1
  [../]
  [./heat_ie]
    type = TimeDerivative
    variable = temp
  [../]
[]

[AuxKernels]
  [./conductance]
    type = MaterialRealAux
    property = density
    variable = density_aux
    boundary = inner_surface
  [../]
[]

[ThermalContact]
  [./thermal_contact]
    type = GapHeatTransfer
    variable = temp
    master = outer_interior
    slave = inner_surface
    quadrature = true
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'centerline'
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'centerline outer_exterior'
    value = 0.0
  [../]
  [./temp]
    type = FunctionDirichletBC
    boundary = outer_exterior
    variable = temp
    function = '500 + t'
  [../]
[]

[Materials]
  [./density]
    type = GenericConstantMaterial
    prop_names = 'density'
    prop_values = '1'
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e11
    poissons_ratio = 0.3
  [../]

  [./inner_elastic_stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'inner_creep'
    block = inner
    outputs = all
  [../]

  [./inner_creep]
    type = PowerLawCreepExceptionTest
    coefficient = 10e-22
    n_exponent = 2
    activation_energy = 0
    block = inner
  [../]

  [./outer_stressstress]
    type = ComputeFiniteStrainElasticStress
    block = outer
  [../]
[]

[Executioner]
  type = Transient
  petsc_options = ' -snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'
  line_search = none

  nl_abs_tol = 1e-7
  l_max_its = 20

  num_steps = 1
  dt = 1
  dtmin = .1
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_1/cyl1_template1.i

#
# This input file is a template for both the frictionless and glued test
# variations for the current problem geometry. In order to create an input
# file to run outside the runtest framework, look at the tests file and add the
# appropriate input file lines from the cli_args line.
#

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl1_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 1000
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x7 disp_y7 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/cwp09.i

# Capped weak-plane plasticity
# checking jacobian for tensile failure with hardening
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 100
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 1.0
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.1
    rate = 1
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 2
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningConstant
    value = 100
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 2  0 0 -1  2 -1 1.5'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 0
    smoothing_tol = 2
    yield_function_tol = 1E-10
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/mortar_tm/2d/frictionless_second/finite_noaction.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'finite_noaction'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]

  [./slave]
    input = block_sidesets
    type = LowerDBlockFromSidesetGenerator
    sidesets = 'block_left'
    new_block_id = '30'
    new_block_name = 'frictionless_slave_subdomain'
  [../]
  [./master]
    input = slave
    type = LowerDBlockFromSidesetGenerator
    sidesets = 'plank_right'
    new_block_id = '20'
    new_block_name = 'frictionless_master_subdomain'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./frictionless_normal_lm]
    order = ${order}
    block = 'frictionless_slave_subdomain'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
  [../]
[]

[Constraints]
  [./lm]
    type = NormalNodalLMMechanicalContact
    slave = block_left
    master = plank_right
    variable = frictionless_normal_lm
    master_variable = disp_x
    disp_y = disp_y
    ncp_function_type = min
    use_displaced_mesh = true
  [../]
  [./normal_x]
    type = NormalMortarMechanicalContact
    master_boundary = plank_right
    slave_boundary = block_left
    master_subdomain = frictionless_master_subdomain
    slave_subdomain = frictionless_slave_subdomain
    variable = frictionless_normal_lm
    slave_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
  [../]
  [./normal_y]
    type = NormalMortarMechanicalContact
    master_boundary = plank_right
    slave_boundary = block_left
    master_subdomain = frictionless_master_subdomain
    slave_subdomain = frictionless_slave_subdomain
    variable = frictionless_normal_lm
    slave_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    preset = false
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/combined/test/tests/elastic_patch/ad_elastic_patch_plane_strain.i

#
# This problem is taken from the Abaqus verification manual:
#   "1.5.1 Membrane patch test"
# The stress solution is given as:
#   xx = yy = 1600
#   zz = 800
#   xy = 400
#   yz = zx = 0
#
# Since the strain is 1e-3 in both directions, the new density should be
#   new_density = original_density * V_0 / V
#   new_density = 0.283 / (1 + 1e-3 + 1e-3) = 0.282435

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
[]

[Mesh]
  file = elastic_patch_rz.e
[]

[Variables]
  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = SMALL
  incremental = true
  planar_formulation = PLANE_STRAIN
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
[]

[Kernels]
  [./heat]
    type = TimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 10
    function = '1e-3*(x+0.5*y)'
  [../]
  [./uz]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 10
    function = '1e-3*(y+0.5*x)'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]
[]

[Materials]
  [./density]
    type = ADDensity
    density = 0.283
    outputs = all
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/strain_energy_density/incr_model_elas_plas.i

# Single element test to check the strain energy density calculation

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 1
  ny = 1
  xmin = 0
  xmax = 1
  ymin = 0
  ymax = 2
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstantUp]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -100
  [../]
  [./ramp_disp_y]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 6.8e-6 1.36e-5'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = SMALL
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress elastic_strain_xx elastic_strain_yy elastic_strain_zz plastic_strain_xx plastic_strain_yy plastic_strain_zz strain_xx strain_yy strain_zz'
    planar_formulation = PLANE_STRAIN
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = 'left'
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = 'bottom'
    value = 0.0
  [../]
  [./top_disp]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = 'top'
    function = ramp_disp_y
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 30e+6
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'isoplas'
  [../]
  [./isoplas]
    type = IsotropicPlasticityStressUpdate
    yield_stress = 1e2
    hardening_constant = 0.0
  [../]
  [./strain_energy_density]
    type = StrainEnergyDensity
    incremental = true
  [../]
[]

[Executioner]
   type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 20
   nl_abs_tol = 3e-7
   nl_rel_tol = 1e-12
   l_tol = 1e-2

   start_time = 0.0
   dt = 1

   end_time = 2
   num_steps = 2
[]

[Postprocessors]
  [./epxx]
    type = ElementalVariableValue
    variable = elastic_strain_xx
    elementid = 0
  [../]
  [./epyy]
    type = ElementalVariableValue
    variable = elastic_strain_yy
    elementid = 0
  [../]
  [./epzz]
    type = ElementalVariableValue
    variable = elastic_strain_zz
    elementid = 0
  [../]
  [./eplxx]
    type = ElementalVariableValue
    variable = plastic_strain_xx
    elementid = 0
  [../]
  [./eplyy]
    type = ElementalVariableValue
    variable = plastic_strain_yy
    elementid = 0
  [../]
  [./eplzz]
    type = ElementalVariableValue
    variable = plastic_strain_zz
    elementid = 0
  [../]
  [./etxx]
    type = ElementalVariableValue
    variable = strain_xx
    elementid = 0
  [../]
  [./etyy]
    type = ElementalVariableValue
    variable = strain_yy
    elementid = 0
  [../]
  [./etzz]
    type = ElementalVariableValue
    variable = strain_zz
    elementid = 0
  [../]
  [./sigxx]
    type = ElementAverageValue
    variable = stress_xx
  [../]
  [./sigyy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigzz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./SED]
    type = ElementAverageValue
    variable = SED
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/normalized_penalty/normalized_penalty_Q8.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = normalized_penalty_Q8.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Functions]
  [./left_x]
    type = PiecewiseLinear
    x = '0 1 2'
    y = '0 0.02 0'
  [../]
[]
[AuxVariables]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx'
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  []
[]

[Contact]
  [./m3_s2]
    master = 3
    slave = 2
    penalty = 1e10
    normalize_penalty = true
    formulation = penalty
    tangential_tolerance = 1e-3
    system = Constraint
  [../]
[]

[BCs]
  [./left_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 1
    function = left_x
  [../]

  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2 3 4'
    value = 0.0
  [../]

  [./right]
    type = DirichletBC
    variable = disp_x
    boundary = '3 4'
    value = 0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2 3 4 1000'
    youngs_modulus = 3e8
    poissons_ratio = 0.0
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2 3 4 1000'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'lu       101'

  line_search = 'none'

  nl_rel_tol = 1e-12
  nl_abs_tol = 5e-8

  l_max_its = 100
  nl_max_its = 10
  dt = 0.5
  num_steps = 4
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_elastic/rz_incremental_small_elastic.i

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 3
  ny = 3
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = ADStressDivergenceRZTensors
    component = 0
    variable = disp_r
  [../]
  [./stress_z]
    type = ADStressDivergenceRZTensors
    component = 1
    variable = disp_z
  [../]
[]

[BCs]
  [./bottom]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0
  [../]
  [./axial]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeAxisymmetricRZIncrementalStrain
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/recompute_radial_return/isotropic_plasticity_incremental_strain.i

# This simulation uses the piece-wise linear strain hardening model
# with the incremental small strain formulation; incremental small strain
# is required to produce the strain_increment for the DiscreteRadialReturnStressIncrement
# class, which handles the calculation of the stress increment to return
# to the yield surface in a J2 (isotropic) plasticity problem.
#
#  This test assumes a Poissons ratio of zero and applies a displacement loading
# condition on the top in the y direction while fixing the displacement in the x
# and z directions; thus, only the normal stress and the normal strains in the
# y direction are compared in this problem.
#
# A similar problem was run in Abaqus on a similar 1 element mesh and was used
# to verify the SolidMechanics solution; this TensorMechanics code matches the
# SolidMechanics solution.
#
# Mechanical strain is the sum of the elastic and plastic strains but is different
# from total strain in cases with eigen strains, e.g. thermal strain.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./top_pull]
    type = ParsedFunction
    value = t*(0.01)
  [../]
  [./hf]
    type = PiecewiseLinear
    x = '0  0.00004 0.0001  0.1'
    y = '50   54    56       60'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    incremental = true
    add_variables = true
    generate_output = 'stress_yy plastic_strain_xx plastic_strain_yy plastic_strain_zz'
  [../]
[]

[BCs]
  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = top_pull
  [../]

  [./x_sides]
    type = DirichletBC
    variable = disp_x
    boundary = 'left right'
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./z_sides]
    type = DirichletBC
    variable = disp_z
    boundary = 'back front'
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.5e5
    poissons_ratio = 0.0
  [../]
  [./isotropic_plasticity]
    type = IsotropicPlasticityStressUpdate
    yield_stress = 25.
    hardening_constant = 1000.0
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    tangent_operator = elastic
    inelastic_models = 'isotropic_plasticity'
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 20
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-12
  l_tol = 1e-9

  start_time = 0.0
  end_time = 0.01875
  dt = 0.00125
  dtmin = 0.0001
[]

[Outputs]
  exodus = true
  print_linear_residuals = true
  perf_graph = true
[]

modules/combined/test/tests/sliding_block/sliding/dirac/frictional_02_penalty.i

#  This is a benchmark test that checks Dirac based frictional
#  contact using the penalty method.  In this test a constant
#  displacement is applied in the horizontal direction to simulate
#  a small block come sliding down a larger block.
#
#  A friction coefficient of 0.2 is used.  The gold file is run on one processor
#  and the benchmark case is run on a minimum of 4 processors to ensure no
#  parallel variability in the contact pressure and penetration results.
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./stiffStuff]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]  # Materials

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  # petsc_options_iname = '-pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter -ksp_gmres_restart'
  # petsc_options_value = 'hypre    boomeramg  4    101'

  nl_abs_tol = 1e-7
  l_max_its = 200
  nl_max_its = 1000
  dt = 0.05
  end_time = 10
  num_steps = 1000
  nl_rel_tol = 1e-6
  dtmin = 0.01
  l_tol = 1e-6

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = coulomb
    penalty = 1e+7
    formulation = penalty
    friction_coefficient = 0.2
    normal_smoothing_distance = 0.1
    system = DiracKernel
  [../]
[]

modules/combined/test/tests/solid_mechanics/pressure/pressure_rspherical.i

#
# Prescribed pressure of 1e4 leads to xx, yy, and zz stress of 1e4.
#

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x'
[]

[Problem]
  coord_type = RSPHERICAL
[]

[Mesh]#Comment
  file = pressure_rspherical.e
  construct_side_list_from_node_list = true
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 1e4
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = SMALL
    additional_generate_output = 'stress_xx stress_yy stress_zz'
  []
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = '1'
    value = 0.0
  [../]
  [./Pressure]
    [./Pressure1]
      boundary = 2
      function = pressure
    [../]
  [../]
[]

[Materials]
  [./constant]
    type = ComputeIsotropicElasticityTensor
    block = '1 2 3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./constant_stress]
    type = ComputeLinearElasticStress
    block = '1 2 3'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  nl_abs_tol = 1e-10
  l_max_its = 20
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_3d.i

#This tests the J-Integral evaluation capability.
#This is a 3d extrusion of a 2d plane strain model with 2 elements
#through the thickness, and calculates the J-Integrals using options
#to treat it as 3d.
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack3d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  radius_inner = '4.0 5.5'
  radius_outer = '5.5 7.0'
  output_variable = 'disp_x'
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 500
    value = 0.0
  [../]
  [./no_z2]
    type = DirichletBC
    variable = disp_z
    boundary = 510
    value = 0.0
  [../]

  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]

  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]

[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]


[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Postprocessors]
  [./disp_x_centercrack]
    type = CrackFrontData
    crack_front_definition = crackFrontDefinition
    variable = disp_x
    crack_front_point_index = 1
  [../]
[]

[Outputs]
  file_base = j_integral_3d_out
  exodus = true
  csv = true
[]

modules/combined/test/tests/sliding_block/in_and_out/dirac/frictionless_penalty.i

#  This is a benchmark test that checks Dirac based frictionless
#  contact using the penalty method.  In this test a sinusoidal
#  displacement is applied in the horizontal direction to simulate
#  a small block come in and out of contact as it slides down a larger block.
#
#  The sinusoid is of the form 0.4sin(4t)+0.2. The gold file is run
#  on one processor and the benchmark
#  case is run on a minimum of 4 processors to ensure no parallel variability
#  in the contact pressure and penetration results.  Further documentation can
#  found in moose/modules/contact/doc/sliding_block/
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
  [./horizontal_movement]
    type = ParsedFunction
    value = -0.04*sin(4*t)+0.02
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./constitutive]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 15
  num_steps = 1000
  nl_rel_tol = 1e-6
  dtmin = 0.01
  l_tol = 1e-6

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  file_base = frictionless_penalty_out
  interval = 10
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+7
    formulation = penalty
    normal_smoothing_distance = 0.1
    system = DiracKernel
  [../]
[]

modules/combined/test/tests/mortar_tm/2drz/frictionless_first/finite_rr.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'finite_rr'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
    extra_vector_tags = 'ref'
  [../]
  [./plank]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
    extra_vector_tags = 'ref'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
  nl_abs_tol = 1e-12
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/volumetric_locking_verification/42_node.i

# Test for volumetric locking correction

# 2D cook's membrane problem with a trapezoid
# that is fixed at one end and is sheared at
# other end. Poisson's ratio is 0.4999.

# Using Quad4 elements and no volumetric locking,
# vertical displacement at top right corner is 3.78
# due to locking.

# Using Quad4 elements with volumetric locking, vertical
# dispalcement at top right corner is 7.78.

# Results match with Nakshatrala et al., Comp. Mech., 41, 2008.

# Check volumetric locking correction documentation for
# more details about this problem.

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = 42_node_side.e
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        add_variables = true
        strain = SMALL
        incremental = true
      [../]
    [../]
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
[]

[NodalKernels]
  [./y_force]
    type = ConstantRate
    variable = disp_y
    boundary = 2
    rate = 2.38095238095
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 250.0
    poissons_ratio = 0.4999
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]


[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  num_steps = 1
[]


[Postprocessors]
  [./a_disp_y]
    type = PointValue
    variable = disp_y
    point = '48.0 60.0 0.0'
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/scalar_material_damage/scalar_material_damage.i

# This is a basic test of the system for continuum damage mechanics
# materials. It uses ScalarMaterialDamage for the damage model,
# which simply gets its damage index from another material. In this
# case, we prescribe the evolution of the damage index using a
# function. A single element has a fixed prescribed displacement
# on one side that puts the element in tension, and then the
# damage index evolves from 0 to 1 over time, and this verifies
# that the stress correspondingly drops to 0.

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  elem_type = HEX8
[]

[AuxVariables]
  [damage_index]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Modules/TensorMechanics/Master]
  [all]
    strain = SMALL
    incremental = true
    add_variables = true
    generate_output = 'stress_xx strain_xx'
  []
[]

[AuxKernels]
  [damage_index]
    type = MaterialRealAux
    variable = damage_index
    property = damage_index_prop
    execute_on = timestep_end
  []
[]

[BCs]
  [symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  []
  [symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  []
  [symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  []
  [axial_load]
    type = DirichletBC
    variable = disp_x
    boundary = right
    value = 0.01
  []
[]

[Functions]
  [damage_evolution]
    type = PiecewiseLinear
    xy_data = '0.0   0.0
               0.1   0.0
               2.1   2.0'
  []
[]

[Materials]
  [damage_index]
    type = GenericFunctionMaterial
    prop_names = damage_index_prop
    prop_values = damage_evolution
  []
  [damage]
    type = ScalarMaterialDamage
    damage_index = damage_index_prop
  []
  [stress]
    type = ComputeDamageStress
    damage_model = damage
  []
  [elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.2
    youngs_modulus = 10e9
  []
[]

[Postprocessors]
  [stress_xx]
    type = ElementAverageValue
    variable = stress_xx
  []
  [strain_xx]
    type = ElementAverageValue
    variable = strain_xx
  []
  [damage_index]
    type = ElementAverageValue
    variable = damage_index
  []
[]

[Executioner]
  type = Transient

  l_max_its  = 50
  l_tol      = 1e-8
  nl_max_its = 20
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-8

  dt = 0.1
  dtmin = 0.1
  end_time = 1.1
[]

[Outputs]
  csv=true
[]

modules/tensor_mechanics/test/tests/rom_stress_update/2drz.i

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 2
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./temperature]
    initial_condition = 900.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    use_automatic_differentiation = true
  [../]
[]

[BCs]
  [./symmy]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./pressure_x]
    type = ADPressure
    variable = disp_x
    component = 0
    boundary = right
    constant = 3.1675e5
  [../]
  [./pressure_y]
    type = ADPressure
    variable = disp_y
    component = 1
    boundary = top
    constant = 6.336e5
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 3.30e11
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ADComputeMultipleInelasticStress
    inelastic_models = rom_stress_prediction
  [../]
  [./rom_stress_prediction]
    type = SS316HLAROMANCEStressUpdateTest
    temperature = temperature
    initial_mobile_dislocation_density = 6.0e12
    initial_immobile_dislocation_density = 4.4e11
    outputs = all
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'NEWTON'

  nl_abs_tol = 1e-12
  automatic_scaling = true
  compute_scaling_once = false

  num_steps = 5
[]

[Postprocessors]
  [./effective_strain_avg]
    type = ElementAverageValue
    variable = effective_creep_strain
  [../]
  [./temperature]
    type = ElementAverageValue
    variable = temperature
  [../]
  [./mobile_dislocations]
    type = ElementAverageValue
    variable = mobile_dislocations
  [../]
  [./immobile_disloactions]
    type = ElementAverageValue
    variable = immobile_dislocations
  [../]
[]

[Outputs]
  csv = true
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update18.i

# MC update version, with only Compressive with compressive strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0
    internal_limit = 2E-3
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-2 1 -0.5  -1 -1.9 0  -0.5 0 -3'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/porous_flow/examples/tutorial/04.i

# Darcy flow with heat advection and conduction, and elasticity
[Mesh]
  [annular]
    type = AnnularMeshGenerator
    nr = 10
    rmin = 1.0
    rmax = 10
    growth_r = 1.4
    nt = 4
    dmin = 0
    dmax = 90
  []
  [./make3D]
    type = MeshExtruderGenerator
    extrusion_vector = '0 0 12'
    num_layers = 3
    bottom_sideset = 'bottom'
    top_sideset = 'top'
    input = annular
  [../]
  [./shift_down]
    type = TransformGenerator
    transform = TRANSLATE
    vector_value = '0 0 -6'
    input = make3D
  [../]
  [./aquifer]
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 0 -2'
    top_right = '10 10 2'
    input = shift_down
  [../]
  [./injection_area]
    type = ParsedGenerateSideset
    combinatorial_geometry = 'x*x+y*y<1.01'
    included_subdomain_ids = 1
    new_sideset_name = 'injection_area'
    input = 'aquifer'
  [../]
  [./rename]
    type = RenameBlockGenerator
    old_block_id = '0 1'
    new_block_name = 'caps aquifer'
    input = 'injection_area'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  PorousFlowDictator = dictator
  biot_coefficient = 1.0
[]

[Variables]
  [./porepressure]
  [../]
  [./temperature]
    initial_condition = 293
    scaling = 1E-8
  [../]
  [./disp_x]
    scaling = 1E-10
  [../]
  [./disp_y]
    scaling = 1E-10
  [../]
  [./disp_z]
    scaling = 1E-10
  [../]
[]

[PorousFlowBasicTHM]
  porepressure = porepressure
  temperature = temperature
  coupling_type = ThermoHydroMechanical
  gravity = '0 0 0'
  fp = the_simple_fluid
  thermal_eigenstrain_name = thermal_contribution
  use_displaced_mesh = false
[]

[BCs]
  [./constant_injection_porepressure]
    type = DirichletBC
    variable = porepressure
    value = 1E6
    boundary = injection_area
  [../]
  [./constant_injection_temperature]
    type = DirichletBC
    variable = temperature
    value = 313
    boundary = injection_area
  [../]

  [./roller_tmax]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = dmax
  [../]
  [./roller_tmin]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = dmin
  [../]
  [./roller_top_bottom]
    type = DirichletBC
    variable = disp_z
    value = 0
    boundary = 'top bottom'
  [../]
  [./cavity_pressure_x]
    type = Pressure
    boundary = injection_area
    variable = disp_x
    component = 0
    factor = 1E6
    use_displaced_mesh = false
  [../]
  [./cavity_pressure_y]
    type = Pressure
    boundary = injection_area
    variable = disp_y
    component = 1
    factor = 1E6
    use_displaced_mesh = false
  [../]
[]

[AuxVariables]
  [./stress_rr]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./stress_pp]
    family = MONOMIAL
    order = CONSTANT
  [../]
[]

[AuxKernels]
  [./stress_rr]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = stress_rr
    scalar_type = RadialStress
    point1 = '0 0 0'
    point2 = '0 0 1'
  [../]
  [./stress_pp]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = stress_pp
    scalar_type = HoopStress
    point1 = '0 0 0'
    point2 = '0 0 1'
  [../]
[]

[Modules]
  [./FluidProperties]
    [./the_simple_fluid]
      type = SimpleFluidProperties
      bulk_modulus = 2E9
      viscosity = 1.0E-3
      density0 = 1000.0
      thermal_expansion = 0.0002
      cp = 4194
      cv = 4186
      porepressure_coefficient = 0
    [../]
  [../]
[]

[Materials]
  [./porosity]
    type = PorousFlowPorosity
    porosity_zero = 0.1
  [../]
  [./biot_modulus]
    type = PorousFlowConstantBiotModulus
    solid_bulk_compliance = 2E-7
    fluid_bulk_modulus = 1E7
  [../]
  [./permeability_aquifer]
    type = PorousFlowPermeabilityConst
    block = aquifer
    permeability = '1E-14 0 0   0 1E-14 0   0 0 1E-14'
  [../]
  [./permeability_caps]
    type = PorousFlowPermeabilityConst
    block = caps
    permeability = '1E-15 0 0   0 1E-15 0   0 0 1E-16'
  [../]

  [./thermal_expansion]
    type = PorousFlowConstantThermalExpansionCoefficient
    drained_coefficient = 0.003
    fluid_coefficient = 0.0002
  [../]
  [./rock_internal_energy]
    type = PorousFlowMatrixInternalEnergy
    density = 2500.0
    specific_heat_capacity = 1200.0
  [../]
  [./thermal_conductivity]
    type = PorousFlowThermalConductivityIdeal
    dry_thermal_conductivity = '10 0 0  0 10 0  0 0 10'
    block = 'caps aquifer'
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 5E9
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeSmallStrain
    eigenstrain_names = thermal_contribution
  [../]
  [./thermal_contribution]
    type = ComputeThermalExpansionEigenstrain
    temperature = temperature
    thermal_expansion_coeff = 0.001 # this is the linear thermal expansion coefficient
    eigenstrain_name = thermal_contribution
    stress_free_temperature = 293
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  active = basic
  [./basic]
    type = SMP
    full = true
    petsc_options = '-ksp_diagonal_scale -ksp_diagonal_scale_fix'
    petsc_options_iname = '-pc_type -sub_pc_type -sub_pc_factor_shift_type -pc_asm_overlap'
    petsc_options_value = ' asm      lu           NONZERO                   2'
  [../]
  [./preferred_but_might_not_be_installed]
    type = SMP
    full = true
    petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
    petsc_options_value = ' lu       mumps'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  end_time = 1E6
  dt = 1E5
  nl_abs_tol = 1E-15
  nl_rel_tol = 1E-14
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_viscoplasticity_stress_update/lps_single_split.i

# This test provides an example of combining two LPS viscoplasticity model.
# The answer should be close, but not exactly the same, as lps_single.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 1
  ny = 1
  xmax = 0.002
  ymax = 0.002
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  add_variables = true
  generate_output = 'strain_xx strain_yy strain_xy hydrostatic_stress vonmises_stress'
  use_automatic_differentiation = true
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x = '0 0.1'
    y = '0 1e-5'
  [../]
  [./tot_effective_viscoplasticity]
    type = ParsedFunction
    vals = 'lps_1_eff_creep_strain lps_2_eff_creep_strain'
    vars = 'lps_1_eff_creep_strain lps_2_eff_creep_strain'
    value = 'lps_1_eff_creep_strain+lps_2_eff_creep_strain'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ADComputeMultiplePorousInelasticStress
    inelastic_models = 'one two'
    initial_porosity = 0.1
    outputs = all
  [../]

  [./one]
    type = ADViscoplasticityStressUpdate
    coefficient = 'coef'
    power = 3
    base_name = 'lps_first'
    outputs = all
    relative_tolerance = 1e-11
  [../]
  [./two]
    type = ADViscoplasticityStressUpdate
    coefficient = 'coef'
    power = 3
    base_name = 'lps_second'
    outputs = all
    relative_tolerance = 1e-11
  [../]
  [./coef]
    type = ParsedMaterial
    f_name = coef
    # Example of creep power law
    function = '0.5e-18 * exp(-4e4 / 1.987 / 1200)'
  [../]
[]

[BCs]
  [./no_disp_x]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./no_disp_y]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./pull_disp_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = top
    function = pull
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  dt = 0.01
  end_time = 0.12
[]

[Postprocessors]
  [./disp_x]
    type = SideAverageValue
    variable = disp_x
    boundary = right
  [../]
  [./disp_y]
    type = SideAverageValue
    variable = disp_y
    boundary = top
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
  [../]
  [./dt]
    type = TimestepSize
  [../]
  [./num_lin]
    type = NumLinearIterations
    outputs = console
  [../]
  [./num_nonlin]
    type = NumNonlinearIterations
    outputs = console
  [../]
  [./lps_1_eff_creep_strain]
    type = ElementAverageValue
    variable = lps_first_effective_viscoplasticity
    outputs = none
  [../]
  [./lps_2_eff_creep_strain]
    type = ElementAverageValue
    variable = lps_second_effective_viscoplasticity
    outputs = none
  [../]
  [./eff_creep_strain_tot]
    type = FunctionValuePostprocessor
    function = tot_effective_viscoplasticity
  [../]
  [./porosity]
    type = ElementAverageValue
    variable = porosity
  [../]
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/adaptive_timestepping/adapt_tstep_function_force_step.i

# This is a test designed to evaluate the cabability of the
# IterationAdaptiveDT TimeStepper to adjust time step size according to
# a function.  For example, if the power input function for a BISON
# simulation rapidly increases or decreases, the IterationAdaptiveDT
# TimeStepper should take time steps small enough to capture the
# oscillation.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  block = 1
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = 1hex8_10mm_cube.e
[]

[Functions]
  [./Fiss_Function]
    type = PiecewiseLinear
    data_file = blip.csv
    format = columns
  [../]
[]

[Variables]
  [./disp_x]
  [../]

  [./disp_y]
  [../]

  [./disp_z]
  [../]

  [./temp]
    initial_condition = 300.0
  [../]
[]


[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    eigenstrain_names = thermal_expansion
    add_variables  = true
    generate_output = 'vonmises_stress'
  [../]
[]


[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]

  [./heat_ie]
    type = HeatConductionTimeDerivative
    variable = temp
  [../]

  [./heat_source]
     type = HeatSource
     variable = temp
     value = 1.0
     function = Fiss_Function
  [../]
[]

[BCs]
 [./bottom_temp]
   type = DirichletBC
   variable = temp
   boundary = 1
   value = 300
 [../]
 [./top_bottom_disp_x]
   type = DirichletBC
   variable = disp_x
   boundary = '1'
   value = 0
 [../]
 [./top_bottom_disp_y]
   type = DirichletBC
   variable = disp_y
   boundary = '1'
   value = 0
 [../]
 [./top_bottom_disp_z]
   type = DirichletBC
   variable = disp_z
   boundary = '1'
   value = 0
 [../]
[]

[Materials]
 [./thermal]
    type = HeatConductionMaterial
    temp = temp
    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 300e6
    poissons_ratio = .3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 5e-6
    stress_free_temperature = 300.0
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]

  [./density]
    type = Density
    density = 10963.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  verbose = true
  nl_abs_tol = 1e-10
  start_time = 0.0
  num_steps = 50000

  end_time = 5.1e3
  [./TimeStepper]
    type = IterationAdaptiveDT
    timestep_limiting_function = Fiss_Function
    max_function_change = 3e20
    force_step_every_function_point = true
    dt = 1e2
  [../]
[]

[Postprocessors]
  [./Temperature_of_Block]
    type = ElementAverageValue
    variable = temp
    execute_on = 'initial timestep_end'
  [../]

  [./vonMises]
    type = ElementAverageValue
    variable = vonmises_stress
    execute_on = 'initial timestep_end'
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 10
  [../]
[]

modules/tensor_mechanics/test/tests/ad_action/two_block.i

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  []
  [block1]
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 0 0'
    top_right = '0.5 1 0'
    input = generated_mesh
  []
  [block2]
    type = SubdomainBoundingBoxGenerator
    block_id = 2
    bottom_left = '0.5 0 0'
    top_right = '1 1 0'
    input = block1
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Modules/TensorMechanics/Master]
  [./block1]
    strain = FINITE
    add_variables = true
    #block = 1
    use_automatic_differentiation = true
  [../]
  [./block2]
    strain = SMALL
    add_variables = true
    block = 2
    use_automatic_differentiation = true
  [../]
[]

[AuxVariables]
  [./stress_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_theta]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_theta
    execute_on = timestep_end
  [../]
  [./strain_theta]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 2
    index_j = 2
    variable = strain_theta
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./_elastic_stress1]
    type = ADComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./_elastic_stress2]
    type = ADComputeLinearElasticStress
    block = 2
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    boundary = 'left'
    variable = disp_x
    value = 0.0
  [../]
  [./top]
    type = DirichletBC
    boundary = 'top'
    variable = disp_y
    value = 0.0
  [../]
  [./right]
    type = DirichletBC
    boundary = 'right'
    variable = disp_x
    value = 0.01
  [../]
  [./bottom]
    type = DirichletBC
    boundary = 'bottom'
    variable = disp_y
    value = 0.01
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Preconditioning]
  [./full]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50
[]

[Outputs]
  exodus = true
[]

modules/xfem/test/tests/second_order_elements/square_branch_quad9_2d.i

[GlobalParams]
  order = SECOND
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 10
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD9
[]

[UserObjects]
  [./line_seg_cut_set_uo]
    type = LineSegmentCutSetUserObject
    cut_data = '-1.0000e-10   6.6340e-01   6.6340e-01  -1.0000e-10  0.0  1.0
                 3.3120e-01   3.3200e-01   1.0001e+00   3.3200e-01  1.0  2.0'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
  [../]
[]

[Functions]
  [./right_disp_x]
    type = PiecewiseLinear
    x = '0  1.0    2.0   3.0'
    y = '0  0.005  0.01  0.01'
  [../]
  [./top_disp_y]
    type = PiecewiseLinear
    x = '0  1.0    2.0   3.0'
    y = '0  0.005  0.01  0.01'
  [../]
[]

[BCs]
  [./right_x]
    type = FunctionDirichletBC
    boundary = 1
    variable = disp_x
    function = right_disp_x
  [../]
  [./top_y]
    type = FunctionDirichletBC
    boundary = 2
    variable = disp_y
    function = top_disp_y
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 0
    variable = disp_y
    value = 0.0
  [../]
  [./left_x]
    type = DirichletBC
    boundary = 3
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-16
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 2.2
  num_steps = 5000
[]

[Outputs]
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/peridynamics/test/tests/generalized_plane_strain/generalized_plane_strain_NOSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  scalar_out_of_plane_strain = scalar_strain_zz
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/Peridynamics/Mechanics]
  [./Master]
    [./all]
      formulation = NONORDINARY_STATE
    [../]
  [../]
  [./GeneralizedPlaneStrain]
    [./all]
      formulation = NONORDINARY_STATE
    [../]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    boundary = 1000
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 1000
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./strain]
    type = ComputePlaneSmallStrainNOSPD
    eigenstrain_names = thermal
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = thermal
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 1.0

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

[Outputs]
  exodus = true
  file_base = generalized_plane_strain_NOSPD
[]

modules/tensor_mechanics/test/tests/ad_thermal_expansion_function/small_const.i

# This tests the thermal expansion coefficient function using both
# options to specify that function: mean and instantaneous.  There
# two blocks, each containing a single element, and these use the
# two variants of the function.

# In this test, the instantaneous CTE function has a constant value,
# while the mean CTE function is an analytic function designed to
# give the same response.  If \bar{alpha}(T) is the mean CTE function,
# and \alpha(T) is the instantaneous CTE function,

# \bar{\alpha}(T) = 1/(T-Tref) \intA^{T}_{Tsf} \alpha(T) dT

# where Tref is the reference temperature used to define the mean CTE
# function, and Tsf is the stress-free temperature.

# This version of the test uses small deformation theory.  The results
# from the two models are identical.

[Mesh]
  file = 'blocks.e'
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
    use_automatic_differentiation = true
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    block = '1 2'
    function = temp_func
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ADComputeLinearElasticStress
  [../]
  [./thermal_expansion_strain1]
    type = ADComputeMeanThermalExpansionFunctionEigenstrain
    block = 1
    thermal_expansion_function = cte_func_mean
    thermal_expansion_function_reference_temperature = 0.5
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
  [./thermal_expansion_strain2]
    type = ADComputeInstantaneousThermalExpansionFunctionEigenstrain
    block = 2
    thermal_expansion_function = cte_func_inst
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_func_mean]
    type = ParsedFunction
    vars = 'tsf tref scale' #stress free temp, reference temp, scale factor
    vals = '0.0 0.5  1e-4'
    value = 'scale * (t - tsf) / (t - tref)'
  [../]
  [./cte_func_inst]
    type = PiecewiseLinear
    xy_data = '0 1.0
               2 1.0'
    scale_factor = 1e-4
  [../]

  [./temp_func]
    type = PiecewiseLinear
    xy_data = '0 1
               1 2'
  [../]
[]

[Postprocessors]
  [./disp_1]
    type = NodalMaxValue
    variable = disp_x
    boundary = 101
  [../]

  [./disp_2]
    type = NodalMaxValue
    variable = disp_x
    boundary = 102
  [../]
[]

[Executioner]
  type = Transient

  solve_type = NEWTON
  l_max_its = 100
  l_tol = 1e-4
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/mortar_tm/2drz/ad_frictionless_first/small.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'small'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./corner]
    type = ExtraNodesetGenerator
    input = block_rename
    coord = '0 -10.0'
    new_boundary = point
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = corner
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    use_automatic_differentiation = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
  [../]
  [./plank]
    use_automatic_differentiation = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ADComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/jacobian/cto28.i

#Cosserat capped weak plane and capped drucker prager
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./cx_elastic]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
  [../]
  [./cy_elastic]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
  [../]
  [./cz_elastic]
    type = StressDivergenceTensors
    variable = disp_z
    component = 2
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./phi]
    type = TensorMechanicsHardeningConstant
    value = 0.8
  [../]
  [./psi]
    type = TensorMechanicsHardeningConstant
    value = 0.4
  [../]
  [./dp]
    type = TensorMechanicsPlasticDruckerPragerHyperbolic
    mc_cohesion = mc_coh
    mc_friction_angle = phi
    mc_dilation_angle = psi
    yield_function_tolerance = 1E-11     # irrelevant here
    internal_constraint_tolerance = 1E-9 # irrelevant here
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 10.0
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '10 0 0  0 10 0  0 0 10'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'dp'
    relative_tolerance = 2.0
    absolute_tolerance = 1E6
    max_iterations = 1
  [../]
  [./dp]
    type = CappedDruckerPragerStressUpdate
    base_name = dp
    DP_model = dp
    tensile_strength = ts
    compressive_strength = cs
    yield_function_tol = 1E-11
    tip_smoother = 1
    smoothing_tol = 1
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  solve_type = 'NEWTON'
  end_time = 1
  dt = 1
  type = Transient
[]

modules/tensor_mechanics/test/tests/interaction_integral/interaction_integral_3d_as_2d.i

#This tests the Interaction-Integral evaluation capability.
#This is a 3d extrusion of a 2d plane strain model with one element
#through the thickness, and calculates the Interaction-Integrals using options
#to treat it as 2d.

[GlobalParams]
  order = FIRST
#  order = SECOND
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack_3d_as_2d.e
  displacements = 'disp_x disp_y disp_z'
  partitioner = centroid
  centroid_partitioner_direction = z
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = 'InteractionIntegralKI InteractionIntegralKII InteractionIntegralKIII'
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  radius_inner = '4.0 4.5 5.0 5.5 6.0'
  radius_outer = '4.5 5.0 5.5 6.0 6.5'
  block = 1
  youngs_modulus = 207000
  poissons_ratio = 0.3
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 500
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]


[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = interaction_integral_3d_as_2d_out
  exodus = true
  csv = true
[]

modules/combined/test/tests/mortar_tm/2d/ad_frictionless_fir/finite.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'finite'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
    use_automatic_differentiation = true
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = ADFunctionDirichletBC
    variable = disp_x
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/2D_geometries/2D-RZ_centerline_VLC.i

# Simple test to check for use of AxisymmetricCenterlineAverageValue with
# volumetric_locking_correction activated in a tensor mechanics simulation

[Mesh]
  type = GeneratedMesh
  dim = 2
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
  volumetric_locking_correction = true
[]

[Problem]
  coord_type = RZ
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
  [../]
[]

[AuxVariables]
  [./temperature]
    initial_condition = 298.0
  [../]
[]

[BCs]
  [./symmetry_x]
    type = DirichletBC
    variable = disp_r
    value = 0
    boundary = left
  [../]
  [./roller_z]
    type = DirichletBC
    variable = disp_z
    value = 0
    boundary = bottom
  [../]
  [./top_load]
    type = FunctionDirichletBC
    variable = disp_z
    function = -0.01*t
    boundary = top
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.3
  [../]
  [./_elastic_strain]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  line_search = 'none'

  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-6
  l_max_its = 50

  start_time = 0.0
  end_time = 0.3
  dt = 0.1
[]

[Postprocessors]
  [./center_temperature]
    type = AxisymmetricCenterlineAverageValue
    variable = temperature
    boundary = left
  [../]
[]

[Outputs]
  csv = true
  perf_graph = true
[]

modules/tensor_mechanics/test/tests/ad_thermal_expansion_function/small_linear.i

# This tests the thermal expansion coefficient function using both
# options to specify that function: mean and instantaneous.  There
# two blocks, each containing a single element, and these use the
# two variants of the function.

# In this test, the instantaneous CTE function is a linear function
# while the mean CTE function is an analytic function designed to
# give the same response.  If \bar{alpha}(T) is the mean CTE function,
# and \alpha(T) is the instantaneous CTE function,

# \bar{\alpha}(T) = 1/(T-Tref) \intA^{T}_{Tsf} \alpha(T) dT

# where Tref is the reference temperature used to define the mean CTE
# function, and Tsf is the stress-free temperature.

# This version of the test uses small deformation theory.  The results
# from the two models are identical.

[Mesh]
  file = 'blocks.e'
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
    use_automatic_differentiation = true
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    block = '1 2'
    function = temp_func
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ADComputeLinearElasticStress
  [../]
  [./thermal_expansion_strain1]
    type = ADComputeMeanThermalExpansionFunctionEigenstrain
    block = 1
    thermal_expansion_function = cte_func_mean
    thermal_expansion_function_reference_temperature = 0.5
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
  [./thermal_expansion_strain2]
    type = ADComputeInstantaneousThermalExpansionFunctionEigenstrain
    block = 2
    thermal_expansion_function = cte_func_inst
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_func_mean]
    type = ParsedFunction
    vars = 'tsf tref scale' #stress free temp, reference temp, scale factor
    vals = '0.0 0.5  1e-4'
    value = 'scale * (0.5 * t^2 - 0.5 * tsf^2) / (t - tref)'
  [../]
  [./cte_func_inst]
    type = PiecewiseLinear
    xy_data = '0 0.0
               2 2.0'
    scale_factor = 1e-4
  [../]

  [./temp_func]
    type = PiecewiseLinear
    xy_data = '0 1
               1 2'
  [../]
[]

[Postprocessors]
  [./disp_1]
    type = NodalMaxValue
    variable = disp_x
    boundary = 101
  [../]

  [./disp_2]
    type = NodalMaxValue
    variable = disp_x
    boundary = 102
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  l_max_its = 100
  l_tol = 1e-4
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/peridynamics/test/tests/auxkernels/planestrain_thermomechanics_ranktwotensor_OSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp

  poissons_ratio = 0.3
  youngs_modulus = 1e6
  thermal_expansion_coeff = 0.0002
  stress_free_temperature = 0.0
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 8
    ny = 8
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]

  [./tstrain_xx]
    order = FIRST
    family = LAGRANGE
  [../]
  [./tstrain_yy]
    order = FIRST
    family = LAGRANGE
  [../]
  [./tstrain_zz]
    order = FIRST
    family = LAGRANGE
  [../]
  [./tstrain_xy]
    order = FIRST
    family = LAGRANGE
  [../]

  [./mstrain_xx]
    order = FIRST
    family = LAGRANGE
  [../]
  [./mstrain_yy]
    order = FIRST
    family = LAGRANGE
  [../]
  [./mstrain_zz]
    order = FIRST
    family = LAGRANGE
  [../]
  [./mstrain_xy]
    order = FIRST
    family = LAGRANGE
  [../]


  [./stress_xx]
    order = FIRST
    family = LAGRANGE
  [../]
  [./stress_yy]
    order = FIRST
    family = LAGRANGE
  [../]
  [./stress_zz]
    order = FIRST
    family = LAGRANGE
  [../]
  [./stress_xy]
    order = FIRST
    family = LAGRANGE
  [../]

  [./von_mises]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = ORDINARY_STATE
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]

  [./tstrain_xx]
    type = NodalRankTwoPD
    variable = tstrain_xx
    rank_two_tensor = total_strain
    output_type = component
    index_i = 0
    index_j = 0
  [../]
  [./tstrain_yy]
    type = NodalRankTwoPD
    variable = tstrain_yy
    rank_two_tensor = total_strain
    output_type = component
    index_i = 1
    index_j = 1
  [../]
  [./tstrain_zz]
    type = NodalRankTwoPD
    variable = tstrain_zz
    rank_two_tensor = total_strain
    output_type = component
    index_i = 2
    index_j = 2
  [../]
  [./tstrain_xy]
    type = NodalRankTwoPD
    variable = tstrain_xy
    rank_two_tensor = total_strain
    output_type = component
    index_i = 0
    index_j = 1
  [../]

  [./mstrain_xx]
    type = NodalRankTwoPD
    variable = mstrain_xx
    rank_two_tensor = mechanical_strain
    output_type = component
    index_i = 0
    index_j = 0
  [../]
  [./mstrain_yy]
    type = NodalRankTwoPD
    variable = mstrain_yy
    rank_two_tensor = mechanical_strain
    output_type = component
    index_i = 1
    index_j = 1
  [../]
  [./mstrain_zz]
    type = NodalRankTwoPD
    variable = mstrain_zz
    rank_two_tensor = mechanical_strain
    output_type = component
    index_i = 2
    index_j = 2
  [../]
  [./mstrain_xy]
    type = NodalRankTwoPD
    variable = mstrain_xy
    rank_two_tensor = mechanical_strain
    output_type = component
    index_i = 0
    index_j = 1
  [../]

  [./stress_xx]
    type = NodalRankTwoPD
    variable = stress_xx
    rank_two_tensor = stress
    output_type = component
    index_i = 0
    index_j = 0
  [../]
  [./stress_yy]
    type = NodalRankTwoPD
    variable = stress_yy
    rank_two_tensor = stress
    output_type = component
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = NodalRankTwoPD
    variable = stress_zz
    rank_two_tensor = stress
    output_type = component
    index_i = 2
    index_j = 2
  [../]
  [./stress_xy]
    type = NodalRankTwoPD
    variable = stress_xy
    rank_two_tensor = stress
    output_type = component
    index_i = 0
    index_j = 1
  [../]

  [./vonmises]
    type = NodalRankTwoPD
    variable = von_mises
    rank_two_tensor = stress
    output_type = scalar
    scalar_type = VonMisesStress
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = 'x*x+y*y'
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    boundary = 1003
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 1000
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialOSPD
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  start_time = 0.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
  file_base = planestrain_thermomechanics_ranktwotensor_OSPD
[]

tutorials/darcy_thermo_mech/step11_action/problems/step11.i

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  ny = 200
  nx = 10
  ymax = 0.304 # Length of test chamber
  xmax = 0.0257 # Test chamber radius
[]

[Variables]
  [pressure]
  []
  [temperature]
    initial_condition = 300 # Start at room temperature
  []
[]

[DarcyThermoMech]
[]

[Modules/TensorMechanics/Master]
  [all]
    # This block adds all of the proper Kernels, strain calculators, and Variables
    # for TensorMechanics in the correct coordinate system (autodetected)
    add_variables = true
    strain = FINITE
    eigenstrain_names = eigenstrain
    use_automatic_differentiation = true
    generate_output = 'vonmises_stress elastic_strain_xx elastic_strain_yy strain_xx strain_yy'
  []
[]

[BCs]
  [inlet]
    type = DirichletBC
    variable = pressure
    boundary = bottom
    value = 4000 # (Pa) From Figure 2 from paper.  First data point for 1mm spheres.
  []
  [outlet]
    type = DirichletBC
    variable = pressure
    boundary = top
    value = 0 # (Pa) Gives the correct pressure drop from Figure 2 for 1mm spheres
  []
  [inlet_temperature]
    type = FunctionDirichletBC
    variable = temperature
    boundary = bottom
    function = 'if(t<0,350+50*t,350)'
  []
  [outlet_temperature]
    type = HeatConductionOutflow
    variable = temperature
    boundary = top
  []
  [hold_inlet]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0
  []
  [hold_center]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  []
  [hold_outside]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0
  []
[]

[Materials]
  viscosity_file = data/water_viscosity.csv
  density_file = data/water_density.csv
  thermal_conductivity_file = data/water_thermal_conductivity.csv
  specific_heat_file = data/water_specific_heat.csv
  thermal_expansion_file = data/water_thermal_expansion.csv

  [column]
    type = PackedColumn
    block = 0
    temperature = temperature
    radius = 1.15
    fluid_viscosity_file = ${viscosity_file}
    fluid_density_file = ${density_file}
    fluid_thermal_conductivity_file = ${thermal_conductivity_file}
    fluid_specific_heat_file = ${specific_heat_file}
    fluid_thermal_expansion_file = ${thermal_expansion_file}
  []

  [elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 200e9 # (Pa) from wikipedia
    poissons_ratio = .3 # from wikipedia

  []
  [elastic_stress]
    type = ADComputeFiniteStrainElasticStress
  []
  [thermal_strain]
    type = ADComputeThermalExpansionEigenstrain
    stress_free_temperature = 300
    eigenstrain_name = eigenstrain
    temperature = temperature
    thermal_expansion_coeff = 1e-5
  []
[]

[Postprocessors]
  [average_temperature]
    type = ElementAverageValue
    variable = temperature
  []
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Executioner]
  type = Transient
  start_time = -1
  end_time = 200
  steady_state_tolerance = 1e-7
  steady_state_detection = true
  dt = 0.25
  solve_type = PJFNK
  automatic_scaling = true
  compute_scaling_once = false
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre boomeramg 500'
  line_search = none
  [TimeStepper]
    type = FunctionDT
    function = 'if(t<0,0.1,0.25)'
  []
[]

[Outputs]
  [out]
    type = Exodus
    elemental_as_nodal = true
  []
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_3/ring3_template2.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring3_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'
#  petsc_options = '-mat_superlu_dist_iterrefine -mat_superlu_dist_replacetinypivot'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-9
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x11 disp_y11 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/combined/test/tests/internal_volume/rz_cone.i

#
# Internal Volume Test
#
# This test is designed to compute the internal volume of a cone.
#
# The mesh is composed of one block (1).  The height is 3/pi, and the radius
#   is 1.  Thus, the volume is 1/3*pi*r^2*h = 1.
#

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = meshes/rz_cone.e
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 1e4
  [../]
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    volumetric_locking_correction = true
    incremental = true
    strain = FINITE
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./Pressure]
    [./fred]
      boundary = 1
      function = pressure
      disp_x = disp_x
      disp_y = disp_y
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  nl_abs_tol = 1e-9

  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 1
    execute_on = 'initial timestep_end'
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/adaptive_timestepping/adapt_tstep_function_change.i

# This is a test designed to evaluate the cabability of the
# IterationAdaptiveDT TimeStepper to adjust time step size according to
# a function.  For example, if the power input function for a BISON
# simulation rapidly increases or decreases, the IterationAdaptiveDT
# TimeStepper should take time steps small enough to capture the
# oscillation.

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  order = FIRST
  family = LAGRANGE
  block = 1
[]

[Mesh]
  file = 1hex8_10mm_cube.e
[]

[Functions]
  [./Fiss_Function]
    type = PiecewiseLinear
    x = '0 1e6  2e6  2.001e6 2.002e6'
    y = '0 3e8  3e8  12e8    0'
  [../]
[]

[Variables]
  [./disp_x]
  [../]

  [./disp_y]
  [../]

  [./disp_z]
  [../]

  [./temp]
    initial_condition = 300.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    volumetric_locking_correction = true
    incremental = true
    eigenstrain_names = thermal_expansion
    decomposition_method = EigenSolution
    add_variables  = true
    generate_output = 'vonmises_stress'
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]

  [./heat_ie]
    type = HeatConductionTimeDerivative
    variable = temp
  [../]

  [./heat_source]
     type = HeatSource
     variable = temp
     value = 1.0
     function = Fiss_Function
  [../]
[]

[BCs]
  [./bottom_temp]
    type = DirichletBC
    variable = temp
    boundary = 1
    value = 300
  [../]
  [./top_bottom_disp_x]
    type = DirichletBC
    variable = disp_x
    boundary = '1'
    value = 0
  [../]
  [./top_bottom_disp_y]
    type = DirichletBC
    variable = disp_y
    boundary = '1'
    value = 0
  [../]
  [./top_bottom_disp_z]
    type = DirichletBC
    variable = disp_z
    boundary = '1'
    value = 0
  [../]
[]

[Materials]
 [./thermal]
    type = HeatConductionMaterial
    temp = temp
    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 300e6
    poissons_ratio = .3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 5e-6
    stress_free_temperature = 300.0
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]

  [./density]
    type = Density
    density = 10963.0
    disp_x = disp_x
    disp_y = disp_y
    disp_z = disp_z
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  verbose = true
  nl_abs_tol = 1e-10
  start_time = 0.0
  num_steps = 50000
  end_time = 2.002e6
  [./TimeStepper]
    type = IterationAdaptiveDT
    timestep_limiting_function = Fiss_Function
    max_function_change = 3e7
    dt = 1e6
  [../]
[]

[Postprocessors]
  [./Temperature_of_Block]
    type = ElementAverageValue
    variable = temp
    execute_on = 'initial timestep_end'
  [../]

  [./vonMises]
    type = ElementAverageValue
    variable = vonmises_stress
    execute_on = 'initial timestep_end'
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 10
  [../]
[]

modules/combined/test/tests/frictional_contact/single_point_2d/single_point_2d_tp.i

[Mesh]
  file = single_point_2d.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./horizontal_movement]
    type = ParsedFunction
    value = t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    save_in = 'saved_x saved_y'
    diag_save_in = 'diag_saved_x diag_saved_y'
  [../]
[]

[AuxKernels]
  [./incslip_x]
    type = PenetrationAux
    variable = inc_slip_x
    quantity = incremental_slip_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./incslip_y]
    type = PenetrationAux
    variable = inc_slip_y
    quantity = incremental_slip_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./botx]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./boty]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./botx2]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./boty2]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./topx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./topy]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = -0.005
  [../]
[]

[Materials]
  [./bottom]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1.0e9
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
  [./top]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu    superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 200
  dt = 0.001
  end_time = 0.01
  num_steps = 1000
  nl_rel_tol = 1e-08
  nl_abs_tol = 1e-08
  dtmin = 0.001
  l_tol = 1e-3
[]

[Outputs]
  exodus = true
  print_linear_residuals = true
  perf_graph = true
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    master = 2
    slave = 3
    model = coulomb
    system = constraint
    friction_coefficient = '0.25'
    formulation = tangential_penalty
    penalty = 1e10
  [../]
[]

[Dampers]
  [./contact_slip]
    type = ContactSlipDamper
    master = '2'
    slave = '3'
  [../]
[]

modules/peridynamics/test/tests/jacobian_check/2D_mechanics_FNOSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
    stabilization = FORCE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeForceStabilizedSmallStrainNOSPD
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

modules/tensor_mechanics/test/tests/ad_viscoplasticity_stress_update/exact.i

# This test provides comparison to calculated values from Leblond:1994kl

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  pore_shape_model = spherical
[]

[Mesh]
  [./msh]
    type = CartesianMeshGenerator
    dim = 3
    dx = 0.01
    dy = 0.01
    dz = 0.01
    iz = 1
    ix = 1
    iy = 1
  [../]
  [./extra_nodeset]
    type = ExtraNodesetGenerator
    input = msh
    new_boundary = 'origin'
    coord = '0 0 0'
  []
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  add_variables = true
  generate_output = 'strain_xx strain_yy strain_xy hydrostatic_stress vonmises_stress'
  use_automatic_differentiation = true
[]

[Functions]
  [./Q_gtn]
    type = ParsedFunction
    vars = 'avg_vonmises gtn_gauge_stress'
    vals = 'avg_vonmises gtn_gauge_stress'
    value = 'avg_vonmises/gtn_gauge_stress'
  [../]
  [./M_gtn]
    type = ParsedFunction
    vars = 'avg_hydro gtn_gauge_stress'
    vals = 'avg_hydro gtn_gauge_stress'
    value = 'abs(avg_hydro) / gtn_gauge_stress'
  [../]
  [./Q_ten]
    type = ParsedFunction
    vars = 'avg_vonmises ten_gauge_stress'
    vals = 'avg_vonmises ten_gauge_stress'
    value = 'avg_vonmises/ten_gauge_stress'
  [../]
  [./M_ten]
    type = ParsedFunction
    vars = 'avg_hydro ten_gauge_stress'
    vals = 'avg_hydro ten_gauge_stress'
    value = 'abs(avg_hydro) / ten_gauge_stress'
  [../]
  [./Q_five]
    type = ParsedFunction
    vars = 'avg_vonmises five_gauge_stress'
    vals = 'avg_vonmises five_gauge_stress'
    value = 'avg_vonmises/five_gauge_stress'
  [../]
  [./M_five]
    type = ParsedFunction
    vars = 'avg_hydro five_gauge_stress'
    vals = 'avg_hydro five_gauge_stress'
    value = 'abs(avg_hydro) / five_gauge_stress'
  [../]
  [./Q_three]
    type = ParsedFunction
    vars = 'avg_vonmises three_gauge_stress'
    vals = 'avg_vonmises three_gauge_stress'
    value = 'avg_vonmises / three_gauge_stress'
  [../]
  [./M_three]
    type = ParsedFunction
    vars = 'avg_hydro three_gauge_stress'
    vals = 'avg_hydro three_gauge_stress'
    value = 'abs(avg_hydro) / three_gauge_stress'
  [../]
  [./Q_two]
    type = ParsedFunction
    vars = 'avg_vonmises two_gauge_stress'
    vals = 'avg_vonmises two_gauge_stress'
    value = 'avg_vonmises/two_gauge_stress'
  [../]
  [./M_two]
    type = ParsedFunction
    vars = 'avg_hydro two_gauge_stress'
    vals = 'avg_hydro two_gauge_stress'
    value = 'abs(avg_hydro) / two_gauge_stress'
  [../]
  [./Q_onepointfive]
    type = ParsedFunction
    vars = 'avg_vonmises onepointfive_gauge_stress'
    vals = 'avg_vonmises onepointfive_gauge_stress'
    value = 'avg_vonmises / onepointfive_gauge_stress'
  [../]
  [./M_onepointfive]
    type = ParsedFunction
    vars = 'avg_hydro onepointfive_gauge_stress'
    vals = 'avg_hydro onepointfive_gauge_stress'
    value = 'abs(avg_hydro) / onepointfive_gauge_stress'
  [../]
  [./Q_one]
    type = ParsedFunction
    vars = 'avg_vonmises one_gauge_stress'
    vals = 'avg_vonmises one_gauge_stress'
    value = 'avg_vonmises / one_gauge_stress'
  [../]
  [./M_one]
    type = ParsedFunction
    vars = 'avg_hydro one_gauge_stress'
    vals = 'avg_hydro one_gauge_stress'
    value = 'abs(avg_hydro) / one_gauge_stress'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ADComputeMultiplePorousInelasticStress
    inelastic_models = 'gtn lps_ten lps_five lps_three lps_two lps_onepointfive lps_one'
    initial_porosity = 1e-3
    outputs = all
    extra_stress_names = extra_stress
  [../]

  [./gtn]
    type = ADViscoplasticityStressUpdate
    coefficient = 0
    power = 1 # arbitrary
    viscoplasticity_model = GTN
    base_name = gtn
    outputs = all
    relative_tolerance = 1e-30
  [../]
  [./lps_ten]
    type = ADViscoplasticityStressUpdate
    coefficient = 0
    power = 10
    base_name = ten
    outputs = all
    relative_tolerance = 1e-30
  [../]
  [./lps_five]
    type = ADViscoplasticityStressUpdate
    coefficient = 0
    power = 5
    base_name = five
    outputs = all
    relative_tolerance = 1e-30
  [../]
  [./lps_three]
    type = ADViscoplasticityStressUpdate
    coefficient = 0
    power = 3
    base_name = three
    outputs = all
    relative_tolerance = 1e-30
  [../]
  [./lps_two]
    type = ADViscoplasticityStressUpdate
    coefficient = 0
    power = 2
    base_name = two
    outputs = all
    relative_tolerance = 1e-30
  [../]
  [./lps_onepointfive]
    type = ADViscoplasticityStressUpdate
    coefficient = 0
    power = 1.5
    base_name = onepointfive
    outputs = all
    relative_tolerance = 1e-30
  [../]
  [./lps_one]
    type = ADViscoplasticityStressUpdate
    coefficient = 0
    power = 1
    base_name = one
    outputs = all
    relative_tolerance = 1e-30
  [../]

  [./const_stress]
    type = ComputeExtraStressConstant
    extra_stress_tensor = '1 1 1 1 1 1 1 1 1'
    outputs = all
  [../]
[]

[BCs]
  [./no_disp_x]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./no_disp_y]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./no_disp_z]
    type = ADDirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./Pressure]
    [./bcs]
      boundary = 'top right front'
      function = '10^(t/4.5)'
      use_automatic_differentiation = true
    [../]
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  num_steps = 10
  nl_abs_tol = 1e-8
[]

[Postprocessors]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
  [../]
  [./gtn_gauge_stress]
    type = ElementAverageValue
    variable = gtn_gauge_stress
    outputs = none
  [../]
  [./0Q_gtn]
    type = FunctionValuePostprocessor
    function = Q_gtn
  [../]
  [./0M_gtn]
    type = FunctionValuePostprocessor
    function = M_gtn
  [../]
  [./ten_gauge_stress]
    type = ElementAverageValue
    variable = ten_gauge_stress
    outputs = none
  [../]
  [./1Q_ten]
    type = FunctionValuePostprocessor
    function = Q_ten
  [../]
  [./1M_ten]
    type = FunctionValuePostprocessor
    function = M_ten
  [../]
  [./five_gauge_stress]
    type = ElementAverageValue
    variable = five_gauge_stress
    outputs = none
  [../]
  [./2Q_five]
    type = FunctionValuePostprocessor
    function = Q_five
  [../]
  [./2M_five]
    type = FunctionValuePostprocessor
    function = M_five
  [../]
  [./three_gauge_stress]
    type = ElementAverageValue
    variable = three_gauge_stress
    outputs = none
  [../]
  [./3Q_three]
    type = FunctionValuePostprocessor
    function = Q_three
  [../]
  [./3M_three]
    type = FunctionValuePostprocessor
    function = M_three
  [../]
  [./two_gauge_stress]
    type = ElementAverageValue
    variable = two_gauge_stress
    outputs = none
  [../]
  [./4Q_two]
    type = FunctionValuePostprocessor
    function = Q_two
  [../]
  [./4M_two]
    type = FunctionValuePostprocessor
    function = M_two
  [../]
  [./onepointfive_gauge_stress]
    type = ElementAverageValue
    variable = onepointfive_gauge_stress
    outputs = none
  [../]
  [./5Q_onepointfive]
    type = FunctionValuePostprocessor
    function = Q_onepointfive
  [../]
  [./5M_onepointfive]
    type = FunctionValuePostprocessor
    function = M_onepointfive
  [../]
  [./one_gauge_stress]
    type = ElementAverageValue
    variable = one_gauge_stress
    outputs = none
  [../]
  [./6Q_one]
    type = FunctionValuePostprocessor
    function = Q_one
  [../]
  [./6M_one]
    type = FunctionValuePostprocessor
    function = M_one
  [../]
[]

[Outputs]
  csv = true
  file_base = exact_spherical_out
[]

modules/tensor_mechanics/test/tests/ad_elastic/rspherical_incremental_small_elastic-noad.i

[Mesh]
  type = GeneratedMesh
  dim = 1
  nx = 5
[]

[Problem]
  coord_type = RSPHERICAL
[]

[GlobalParams]
  displacements = 'disp_r'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = StressDivergenceRSphericalTensors
    component = 0
    variable = disp_r
  [../]
[]

[BCs]
  [./center]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
  [./strain]
    type = ComputeRSphericalIncrementalStrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
  nl_max_its = 200
[]

[Outputs]
  exodus = true
  file_base = rspherical_incremental_small_elastic_out
[]

modules/tensor_mechanics/test/tests/initial_stress/except02.i

# Exception test: the incorrect number of initial stress AuxVariables are supplied

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 10
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -10
  zmax = 0
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '1 2 3 4 5 6 7 8 9'
    initial_stress_aux = '1 2 3'
    eigenstrain_name = ini_stress
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]


[Executioner]
  num_steps = 1
  solve_type = NEWTON
  type = Transient
[]

modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/frictionless_penalty.i

[Mesh]
  file = blocks_2d.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    #Initial gap is 0.01
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  [../]
  [./right]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.01
  end_time = 0.10
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-8
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    system = Constraint
    master = 2
    slave = 3
    model = frictionless
    formulation = penalty
    penalty = 1e+7
  [../]
[]

modules/combined/test/tests/mortar_tm/2drz/ad_frictionless_first/finite.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'finite'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    use_automatic_differentiation = true
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
  [../]
  [./plank]
    use_automatic_differentiation = true
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ADComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/jacobian/cwp10.i

# Capped weak-plane plasticity
# checking jacobian for shear failure with hardening
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 2
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 0.5
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.05
    rate = 3
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 100
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningConstant
    value = 100
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 2  0 0 -1  2 -1 0.1'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 0
    smoothing_tol = 2
    yield_function_tol = 1E-10
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/2D_geometries/finite_planestrain.i

# This test uses the strain calculator ComputePlaneFiniteStrain,
# which is generated through the use of the TensorMechanics MasterAction.

[Mesh]
  type = GeneratedMesh
  nx = 2
  ny = 2
  dim = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    planar_formulation = PLANE_STRAIN
    add_variables = true
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy strain_zz'
  [../]
[]

[Functions]
  [./pull]
    type = ParsedFunction
    value ='0.005 * t'
  [../]
[]

[BCs]
  [./leftx]
    type = DirichletBC
    boundary = left
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./pull]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = pull
  [../]
[]

[Materials]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  l_max_its = 100
  l_tol = 1e-10
  nl_max_its = 10
  nl_rel_tol = 1e-12

  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking_power.i

#
# Simple test of power law softening law for smeared cracking.
# Upon reaching the failure stress in the x direction, the
# softening model abruptly reduces the stress to a fraction
# of its original value, and re-loading occurs at a reduced
# stiffness. This is repeated multiple times.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./displ]
    type = PiecewiseLinear
    x = '0 1 2 3  4'
    y = '0 1 0 -1 0'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[BCs]
  [./pull]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = right
    function = displ
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.8e7
    poissons_ratio = 0
  [../]
  [./elastic_stress]
    type = ComputeSmearedCrackingStress
    cracking_stress = 1.68e6
    softening_models = power_law_softening
  [../]
  [./power_law_softening]
    type = PowerLawSoftening
    stiffness_reduction = 0.3333
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -sub_pc_type'
  petsc_options_value = '101                asm      lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  l_tol = 1e-5
  start_time = 0.0
  end_time = 1.0
  dt = 0.01
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/cavity_pressure/rz.i

#
# Cavity Pressure Test
#
# This test is designed to compute an internal pressure based on
#   p = n * R * T / V
# where
#   p is the pressure
#   n is the amount of material in the volume (moles)
#   R is the universal gas constant
#   T is the temperature
#   V is the volume
#
# The mesh is composed of one block (2) with an interior cavity of volume 8.
#   Block 1 sits in the cavity and has a volume of 1.  Thus, the total
#   initial volume is 7.
# The test adjusts T in the following way:
#   T => T0 + beta * t
# with
#   beta = T0
#   T0 = 240.54443866068704
#   V0 = 7
#   n0 = f(p0)
#   p0 = 100
#   R = 8.314472 J * K^(-1) * mol^(-1)
#
# So, n0 = p0 * V0 / R / T0 = 100 * 7 / 8.314472 / 240.544439
#        = 0.35
#
# At t = 1, p = 200.

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Mesh]
  file = rz.e
[]

[Functions]
  [./temperature]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 2'
    scale_factor = 240.54443866068704
  [../]
[]

[Variables]
  [./disp_r]
  [../]
  [./disp_z]
  [../]
  [./temp]
    initial_condition = 240.54443866068704
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
  [./heat]
    type = Diffusion
    variable = temp
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_r
    boundary = '1 2'
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_z
    boundary = '1 2'
    value = 0.0
  [../]
  [./temperatureInterior]
    type = FunctionDirichletBC
    boundary = 2
    function = temperature
    variable = temp
  [../]
  [./CavityPressure]
    [./1]
      boundary = 2
      initial_pressure = 100
      R = 8.314472
      temperature = aveTempInterior
      volume = internalVolume
      startup_time = 0.5
      output = ppress
    [../]
  [../]
[]

[Materials]
  [./elastic_tensor1]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
    block = 1
  [../]
  [./strain1]
    type = ComputeAxisymmetricRZFiniteStrain
    block = 1
  [../]
  [./stress1]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./elastic_tensor2]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
    block = 2
  [../]
  [./strain2]
    type = ComputeAxisymmetricRZFiniteStrain
    block = 2
  [../]
  [./stress2]
    type = ComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_abs_tol = 1e-10

  l_max_its = 20

  dt = 0.5
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 2
    execute_on = 'initial linear'
  [../]
  [./aveTempInterior]
    type = SideAverageValue
    boundary = 2
    variable = temp
    execute_on = 'initial linear'
  [../]
[]

[Outputs]
  exodus = true
  [./checkpoint]
    type = Checkpoint
    num_files = 1
  [../]
[]

modules/tensor_mechanics/test/tests/thermal_expansion_function/dilatation.i

# This test checks the thermal expansion calculated via an dilatation function.
# The coefficient is selected so as to result in a 1e-4 strain in the x-axis, and to cross over
# from positive to negative strain.

[Mesh]
  [./gen]
    type = GeneratedMeshGenerator
    dim = 3
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    function = '1 + t'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeDilatationThermalExpansionFunctionEigenstrain
    dilatation_function = cte_dilatation
    stress_free_temperature = 1.5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_dilatation]
    type = PiecewiseLinear
    x = '1 2'
    y = '-1e-4 1e-4'
  [../]
[]

[Postprocessors]
  [./disp_x_max]
    type = SideAverageValue
    variable = disp_x
    boundary = right
  [../]
  [./temp_avg]
    type = ElementAverageValue
    variable = temp
  [../]
[]

[Executioner]
  type = Transient

  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/tensor_mechanics/test/tests/test_jacobian/jacobian_test_3D.i

# This test is designed to test the jacobian for a single
# element with/without volumetric locking correction.

# The mesh contains one element whose y displacement is zero at
# the bottom surface (y=0) and -1.0 at the top surface (y=1).

# Result: The hand coded jacobian matches well with the finite
# difference jacobian with an error norm in the order of 1e-15
# for total and incremental small strain cases and with an error
# norm in the order of 1e-8 for finite strain cases.


[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
  [../]
[]

[BCs]
  [./y_force]
    type = NeumannBC
    variable = disp_y
    boundary = top
    value = -1.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
    block = 0
  [../]
  [./stress]
    block = 0
  [../]
[]

[Preconditioning]
  active = 'smp'
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient #Transient

  solve_type = NEWTON
  petsc_options = '-snes_check_jacobian -snes_check_jacobian_view'

  l_max_its = 100
  nl_abs_tol = 1e-4
  start_time = 0.0
  num_steps = 1
  dt = 0.005
  dtmin = 0.005
  end_time = 0.005
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/tutorials/basics/part_1.1.i

#Tensor Mechanics tutorial: the basics
#Step 1, part 1
#2D simulation of uniaxial tension with linear elasticity

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = necking_quad4.e
[]

[Modules/TensorMechanics/Master]
  [./block1]
    strain = SMALL #Small linearized strain, automatically set to XY coordinates
    add_variables = true #Add the variables from the displacement string in GlobalParams
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.05
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady

  solve_type = 'NEWTON'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -sub_pc_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm lu 1 101'
[]

[Outputs]
  exodus = true
  perf_graph = true
[]

modules/tensor_mechanics/test/tests/recompute_radial_return/isotropic_plasticity_finite_strain.i

# This simulation uses the piece-wise linear strain hardening model
# with the incremental small strain formulation; incremental small strain
# is required to produce the strain_increment for the DiscreteRadialReturnStressIncrement
# class, which handles the calculation of the stress increment to return
# to the yield surface in a J2 (isotropic) plasticity problem.
#
#  This test assumes a Poissons ratio of 0.3 and applies a displacement loading
# condition on the top in the y direction.
#
# An identical problem was run in Abaqus on a similar 1 element mesh and was used
# to verify the SolidMechanics solution; this TensorMechanics code matches the
# SolidMechanics solution.
#
# Mechanical strain is the sum of the elastic and plastic strains but is different
# from total strain in cases with eigen strains, e.g. thermal strain.

[Mesh]
  file = 1x1x1cube.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./top_pull]
    type = ParsedFunction
    value = t*(0.0625)
  [../]
  [./hf]
    type = PiecewiseLinear
    x = '0  0.001 0.003 0.023'
    y = '50 52    54    56'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_yy plastic_strain_xx plastic_strain_yy plastic_strain_zz'
  [../]
[]

[BCs]
  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = top_pull
  [../]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]
  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./isotropic_plasticity]
    type = IsotropicPlasticityStressUpdate
    yield_stress = 50.0
    hardening_function = hf
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    tangent_operator = elastic
    inelastic_models = 'isotropic_plasticity'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  end_time = 0.075
  dt = 0.00125
  dtmin = 0.0001
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/combined/test/tests/simple_contact/simple_contact_rz_test.i

#
# The analytic solution is:
#   disp_x = -7e-5 * x
#   disp_y =  6e-5 * y
#   stress_xx = stress_zz = -100
#   stress_yy = stress_xy = 0
#
# Note: Run merged_rz.i to generate a solution to compare to that doesn't use contact.

[Mesh]
  file = contact_rz.e
  # PETSc < 3.5.0 requires the iteration patch_update_strategy to
  # avoid PenetrationLocator warnings, which are currently treated as
  # errors by the TestHarness.
  patch_update_strategy = 'iteration'
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 1'
    scale_factor = 100
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    strain = FINITE
    generate_output = 'stress_xx stress_xy stress_zx stress_yy stress_zz stress_yz'
  [../]
[]

[Contact]
  [./dummy_name]
    master = 3
    slave = 2
    penalty = 1e5
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 10
    value = 0.0
  [../]

  [./Pressure]
    [./right_pressure]
      boundary = 4
      function = pressure
    [../]
  [../]
[]

[Materials]
  [./stiffStuff]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type '
  petsc_options_value = 'lu       '

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-9

  l_max_its = 20
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/combined/test/tests/sliding_block/in_and_out/constraint/frictionless_penalty.i

#  This is a benchmark test that checks constraint based frictionless
#  contact using the penalty method.  In this test a sinusoidal
#  displacement is applied in the horizontal direction to simulate
#  a small block come in and out of contact as it slides down a larger block.
#
#  The sinusoid is of the form 0.4sin(4t)+0.2. The gold file is run
#  on one processor and the benchmark
#  case is run on a minimum of 4 processors to ensure no parallel variability
#  in the contact pressure and penetration results.  Further documentation can
#  found in moose/modules/contact/doc/sliding_block/
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
  [./horizontal_movement]
    type = ParsedFunction
    value = -0.04*sin(4*t)+0.02
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Preconditioning]
  [./smp]
     type = SMP
     full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 15
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-6
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+7
    formulation = penalty
    system = constraint
    normal_smoothing_distance = 0.1
  [../]
[]

modules/combined/test/tests/elastic_thermal_patch/elastic_thermal_patch_rz_smp.i

#
# This problem is modified from the Abaqus verification manual:
#   "1.5.4 Patch test for axisymmetric elements"
# The original stress solution is given as:
#   xx = yy = zz = 2000
#   xy = 400
#
# Here, E=1e6 and nu=0.25.
# However, with a +100 degree change in temperature and a coefficient
#   of thermal expansion of 1e-6, the solution becomes:
#   xx = yy = zz = 1800
#   xy = 400
#   since
#   E*(1-nu)/(1+nu)/(1-2*nu)*(1+2*nu/(1-nu))*(1e-3-1e-4) = 1800
#
# Also,
#
#   dSrr   dSrz   Srr-Stt
#   ---- + ---- + ------- + br = 0
#    dr     dz       r
#
# and
#
#   dSrz   Srz   dSzz
#   ---- + --- + ---- + bz = 0
#    dr     r     dz
#
# where
#   Srr = stress in rr
#   Szz = stress in zz
#   Stt = stress in theta-theta
#   Srz = stress in rz
#   br  = body force in r direction
#   bz  = body force in z direction
#
# This test is meant to exercise the Jacobian.  To that end, the body
# force has been turned off.  This makes the results differ slightly
# from the original values, but requires a correct Jacobian for minimal
# iterations.  Iteration plotting is turned on to ensure that the
# number of iterations needed does not increase.

[GlobalParams]
  temperature = temp
  volumetric_locking_correction = true
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = elastic_thermal_patch_rz_test.e
[]

[Functions]
  [./ur]
    type = ParsedFunction
    value = '1e-3*x'
  [../]
  [./uz]
    type = ParsedFunction
    value = '1e-3*(x+y)'
  [../]
  [./body]
    type = ParsedFunction
    value = '-400/x'
  [../]
  [./temp]
    type = ParsedFunction
    value = '117.56+100*t'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules]
    [TensorMechanics]
        [Master]
            displacements = 'disp_x disp_y'
            [All]
                displacements = 'disp_x disp_y'
                add_variables = true
                strain = SMALL
                incremental = true
                eigenstrain_names = eigenstrain
                generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
            [../]
        [../]
    [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 10
    function = ur
  [../]
  [./uz]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 10
    function = uz
  [../]

  [./temp]
    type = FunctionDirichletBC
    variable = temp
    boundary = 10
    function = temp
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 666666.6666666667
    poissons_ratio = 0.25
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-6
    stress_free_temperature = 117.56
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]

  [./heat]
    type = HeatConductionMaterial
    specific_heat = 0.116
    thermal_conductivity = 4.85e-4
  [../]

  [./density]
    type = Density
    block = 1
    density = 0.283
    disp_r = disp_x
    disp_z = disp_y
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-11
  nl_rel_tol = 1e-12

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 1
  end_time = 1.0
[]

[Outputs]
  file_base = elastic_thermal_patch_rz_smp_out
  [./exodus]
    type = Exodus
    execute_on = 'initial timestep_end nonlinear'
    nonlinear_residual_dt_divisor = 100
  [../]
[]

modules/tensor_mechanics/test/tests/initial_stress/gravity_with_aux.i

# Apply an initial stress, using AuxVariables, that should be
# exactly that caused by gravity, and then
# do a transient step to check that nothing
# happens

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 10
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -10
  zmax = 0
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./weight]
    type = BodyForce
    variable = disp_z
    value = -0.5 # this is density*gravity
  [../]
[]


[BCs]
  # back = zmin
  # front = zmax
  # bottom = ymin
  # top = ymax
  # left = xmin
  # right = xmax
  [./x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left right'
    value = 0
  [../]
  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom top'
    value = 0
  [../]
  [./z]
    type = DirichletBC
    variable = disp_z
    boundary = 'back'
    value = 0
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./aux_equals_1]
    initial_condition = 1
  [../]
  [./aux_equals_2]
    initial_condition = 2
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
[]


[Functions]
  [./half_weight]
    type = ParsedFunction
    value = '0.25*z' # half of the initial stress that should result from the weight force
  [../]
  [./kxx]
    type = ParsedFunction
    value = '0.4*z' # some arbitrary xx and yy stress that should not affect the result
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeSmallStrain
    eigenstrain_names = ini_stress
  [../]
  [./strain_from_initial_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = 'kxx 0 0  0 kxx 0  0 0 half_weight'
    initial_stress_aux = 'aux_equals_1 aux_equals_1 aux_equals_1  aux_equals_1 aux_equals_1 aux_equals_1  aux_equals_1 aux_equals_1 aux_equals_2'
    eigenstrain_name = ini_stress
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]


[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]


[Executioner]
  end_time = 1.0
  dt = 1.0
  solve_type = NEWTON
  type = Transient

  nl_abs_tol = 1E-8
  nl_rel_tol = 1E-12
  l_tol = 1E-3
  l_max_its = 200
  nl_max_its = 400

  petsc_options_iname = '-pc_type -pc_asm_overlap -sub_pc_type -ksp_type -ksp_gmres_restart'
  petsc_options_value = ' asm      2              lu            gmres     200'
[]



[Outputs]
  file_base = gravity_with_aux
  exodus = true
[]

modules/peridynamics/test/tests/plane_stress/weak_planestress_NOSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  out_of_plane_strain = strain_zz
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 8
    ny = 8
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./strain_zz]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1003
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1001
    value = 0.001
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
  [../]
[]

[Kernels]
  [./strain_zz]
    type = WeakPlaneStressNOSPD
    variable = strain_zz
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e8
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputePlaneSmallStrainNOSPD
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none

  nl_rel_tol = 1e-12

  start_time = 0
  end_time = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

[Outputs]
  file_base = weak_planestress_NOSPD
  exodus = true
[]

modules/peridynamics/test/tests/generalized_plane_strain/out_of_plane_pressure_OSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  scalar_out_of_plane_strain = scalar_strain_zz
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules]
  [./Peridynamics/Mechanics]
    [./Master]
      [./all]
        formulation = ORDINARY_STATE
      [../]
    [../]
    [./GeneralizedPlaneStrain]
      [./all]
        formulation = ORDINARY_STATE
        out_of_plane_stress_variable = stress_zz
        out_of_plane_pressure = pressure_function
        factor = 1e5
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = NodalRankTwoPD
    variable = stress_zz
    poissons_ratio = 0.3
    youngs_modulus = 1e6
    rank_two_tensor = stress
    output_type = component
    index_i = 2
    index_j = 2
  [../]
[]

[Postprocessors]
  [./react_z]
    type = NodalVariableIntegralPD
    variable = stress_zz
  [../]
[]

[Functions]
  [./pressure_function]
    type = PiecewiseLinear
    x = '0  1'
    y = '0  1'
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    boundary = 1003
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 1000
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialOSPD
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  start_time = 0.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
  file_base = out_of_plane_pressure_OSPD
[]

modules/tensor_mechanics/test/tests/inclined_bc/inclined_bc_2d.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 8
    xmin = 0.0
    xmax = 1.0
    ymin = 0.0
    ymax = 2.0
    elem_type = QUAD4
  []
  [rotate]
    type = TransformGenerator
    transform = ROTATE
    vector_value = '0 0 -60'
    input = generated_mesh
  []
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  add_variables = true
[]

[BCs]
  [./Pressure]
    [./top]
      boundary = top
      function = '-1000*t'
    [../]
  [../]
  [./InclinedNoDisplacementBC]
    [./right]
      boundary = right
      penalty = 1.0e8
      displacements = 'disp_x disp_y'
    [../]
    [./bottom]
      boundary = bottom
      penalty = 1.0e8
      displacements = 'disp_x disp_y'
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  # controls for linear iterations
  l_max_its = 10
  l_tol = 1e-4

  # controls for nonlinear iterations
  nl_max_its = 100
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8

  # time control
  start_time = 0.0
  dt = 1
  end_time = 5
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Outputs]
  exodus = true
[]

modules/peridynamics/test/tests/jacobian_check/2D_thermomechanics_smallstrain_NOSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./temp]
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
    eigenstrain_names = thermal
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConductionBPD
    variable = temp
  [../]
[]

[Materials]
  [./linelast]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputePlaneSmallStrainNOSPD
    eigenstrain_names = thermal
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-5
    stress_free_temperature = 0.5
    eigenstrain_name = thermal
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]

  [./thermal]
    type = ThermalConstantHorizonMaterialBPD
    thermal_conductivity = 1.0
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/tensile_update1.i

# Tensile, update version, with strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Return to the stress_I = 1 plane

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2 0 0  0 0 0  0 0 -2'
    eigenstrain_name = ini_stress
  [../]
  [./tensile]
    type = TensileStressUpdate
    tensile_strength = ts
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = tensile
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/critical_time_step/crit_time_solid_uniform.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 10
  ny = 10
  nz = 15

  xmin = 0
  xmax = 2

  ymin = 0
  ymax = 2

  zmin = 0
  zmax = 1
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./2_x]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]
  [./2_y]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]
  [./2_z]
    type = DirichletBC
    variable = disp_z
    boundary = 3
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.1
    youngs_modulus = 1e6
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./density]
    type = GenericConstantMaterial
    prop_names = 'density'
    prop_values = '8050.0'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-4

  l_max_its = 3

  start_time = 0.0
  dt = 0.1
  num_steps = 1
  end_time = 1.0
[]

[Postprocessors]
  [./time_step]
    type = CriticalTimeStep
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/incremental_slip/incremental_slip.i


[Mesh]
  file = incremental_slip.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
  [../]
[]

[Functions]
  [./slave_x]
    type = PiecewiseLinear
    x = '0 1 2   3 4 5  6    7 8   9'
    y = '0 0 0.5 0 0 0 -0.25 0 0.5 0'
  [../]
  [./slave_y]
    type = PiecewiseLinear
    x = '0  1     9'
    y = '0 -0.15 -0.15'
  [../]
  [./slave_z]
    type = PiecewiseLinear
    x = '0 1  2   3 4 5 6    7  8   9'
    y = '0 0 -0.5 0 0 0 0.25 0 -0.5 0'
  [../]

  [./master_x]
    type = PiecewiseLinear
    x = '0 1  2 3 4   5 6    7 8   9'
    y = '0 0  0 0 0.5 0 0.25 0 0.5 0'
  [../]
  [./master_y]
    type = PiecewiseLinear
    x = '0 9'
    y = '0 0'
  [../]
  [./master_z]
    type = PiecewiseLinear
    x = '0 1  2 3 4   5  6    7  8   9'
    y = '0 0  0 0 0.5 0 -0.25 0 -0.5 0'
  [../]
[]

[AuxVariables]
  [./inc_slip_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./inc_slip_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./inc_slip_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxKernels]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    quantity = incremental_slip_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    quantity = incremental_slip_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_z]
    type = PenetrationAux
    variable = inc_slip_z
    quantity = incremental_slip_z
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Contact]
  [./dummy_name]
    master = 2
    slave = 3
    penalty = 1e7
    system = Constraint
  [../]
[]

[BCs]
  [./slave_x]
    type = FunctionDirichletBC
    variable = disp_x
    preset = false
    boundary = 4
    function = slave_x
  [../]
  [./slave_y]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = 4
    function = slave_y
  [../]
  [./slave_z]
    type = FunctionDirichletBC
    variable = disp_z
    preset = false
    boundary = 4
    function = slave_z
  [../]

  [./master_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '1 2'
    function = master_x
  [../]
  [./master_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = '1 2'
    function = master_y
  [../]
  [./master_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = '1 2'
    function = master_z
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor_1]
    type = ComputeIsotropicElasticityTensor
    block = 1
    youngs_modulus = 1.0e6
    poissons_ratio = 0.0
  [../]
  [./stress_1]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]

  [./elasticity_tensor_2]
    type = ComputeIsotropicElasticityTensor
    block = 2
    youngs_modulus = 1.0e6
    poissons_ratio = 0.0
  [../]
  [./stress_2]
    type = ComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu            superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-8
  l_max_its = 100
  nl_max_its = 10
  dt = 1.0
  num_steps = 9
[] # Executioner

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_2d_points.i

#This tests the J-Integral evaluation capability.
#This is a 2d plane strain model
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack2d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  crack_front_points = '0 -10 0'
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  radius_inner = '4.0 4.5 5.0 5.5 6.0'
  radius_outer = '4.5 5.0 5.5 6.0 6.5'
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]

  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]

  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = j_integral_2d_points_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/ad_thermal_expansion_function/finite_linear.i

# This tests the thermal expansion coefficient function using both
# options to specify that function: mean and instantaneous.  There
# two blocks, each containing a single element, and these use the
# two variants of the function.

# In this test, the instantaneous CTE function is a linear function
# while the mean CTE function is an analytic function designed to
# give the same response.  If \bar{alpha}(T) is the mean CTE function,
# and \alpha(T) is the instantaneous CTE function,

# \bar{\alpha}(T) = 1/(T-Tref) \intA^{T}_{Tsf} \alpha(T) dT

# where Tref is the reference temperature used to define the mean CTE
# function, and Tsf is the stress-free temperature.

# This version of the test uses finite deformation theory.
# The two models produce very similar results.  There are slight
# differences due to the large deformation treatment.

[Mesh]
  file = 'blocks.e'
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
    use_automatic_differentiation = true
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    block = '1 2'
    function = temp_func
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ADComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain1]
    type = ADComputeMeanThermalExpansionFunctionEigenstrain
    block = 1
    thermal_expansion_function = cte_func_mean
    thermal_expansion_function_reference_temperature = 0.5
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
  [./thermal_expansion_strain2]
    type = ADComputeInstantaneousThermalExpansionFunctionEigenstrain
    block = 2
    thermal_expansion_function = cte_func_inst
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_func_mean]
    type = ParsedFunction
    vars = 'tsf tref scale' #stress free temp, reference temp, scale factor
    vals = '0.0 0.5  1e-4'
    value = 'scale * (0.5 * t^2 - 0.5 * tsf^2) / (t - tref)'
  [../]
  [./cte_func_inst]
    type = PiecewiseLinear
    xy_data = '0 0.0
               2 2.0'
    scale_factor = 1e-4
  [../]

  [./temp_func]
    type = PiecewiseLinear
    xy_data = '0 1
               1 2'
  [../]
[]

[Postprocessors]
  [./disp_1]
    type = NodalMaxValue
    variable = disp_x
    boundary = 101
  [../]

  [./disp_2]
    type = NodalMaxValue
    variable = disp_x
    boundary = 102
  [../]
[]

[Executioner]
  type = Transient

  solve_type = NEWTON
  l_max_its = 100
  l_tol = 1e-4
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_4/ring4_template1.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring4_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-9
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x9 disp_y9 disp_x16 disp_y16 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update15.i

# MC update version, with only Compressive with compressive strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.
# Returns to close to the tip of the yield function.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0.5
    internal_limit = 2E-2
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-15 -1 -0.2  -1 -10 0.3  0.3 -0.2 -8'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymmetric_gps_small.i

#
# This test checks the generalized plane strain using small strain formulation.
# The model consists of two sets of line elements. One undergoes a temperature rise of 100 with
# the other seeing a temperature rise of 300.  Young's modulus is 3600, and
# Poisson's ratio is 0.2.  The thermal expansion coefficient is 1e-8.  All
# nodes are constrained against movement.
#
# For plane strain case, i.e., without constraining the strain_yy to be uniform,
# the stress solution would be [-6e-3, -6e-3, -6e-3] and [-18e-3, -18e-3, -18e-3] (xx, yy, zz).
# The generalized plane strain kernels work to balance the force in y direction.
#
# With out of plane strain of 3e-6, the stress solution becomes
# [-3e-3, 6e-3, -3e-3] and [-15e-3, -6e-3, -15e-3] (xx, yy, zz).  This gives
# a domain integral of out-of-plane stress to be zero.
#

[GlobalParams]
  displacements = disp_x
  scalar_out_of_plane_strain = scalar_strain_yy
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = lines.e
[]

[Variables]
  [./disp_x]
  [../]
  [./temp]
    initial_condition = 580.0
  [../]
  [./scalar_strain_yy]
    order = FIRST
    family = SCALAR
  [../]
[]

[Functions]
  [./temp100]
    type = PiecewiseLinear
    x = '0   1'
    y = '580 680'
  [../]
  [./temp300]
    type = PiecewiseLinear
    x = '0   1'
    y = '580 880'
  [../]
[]

[Kernels]
  [./heat]
    type = Diffusion
    variable = temp
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./gps]
        planar_formulation = GENERALIZED_PLANE_STRAIN
        scalar_out_of_plane_strain = scalar_strain_yy
        strain = SMALL
        generate_output = 'strain_xx strain_yy strain_zz stress_xx stress_yy stress_zz'
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    boundary = 1000
    value = 0
    variable = disp_x
  [../]
  [./temp100]
    type = FunctionDirichletBC
    variable = temp
    function = temp100
    boundary = 2
  [../]
  [./temp300]
    type = FunctionDirichletBC
    variable = temp
    function = temp300
    boundary = 3
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 3600
    poissons_ratio = 0.2
  [../]

  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-8
    temperature = temp
    stress_free_temperature = 580
    eigenstrain_name = eigenstrain
  [../]

  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  line_search = 'none'

  l_max_its = 50
  l_tol = 1e-08
  nl_max_its = 15
  nl_abs_tol = 1e-10
  start_time = 0
  end_time = 1
  num_steps = 1
[]

[Outputs]
  exodus = true
  console = true
[]

modules/combined/test/tests/contact_verification/hertz_cyl/half_symm_q4/hertz_cyl_half_1deg_template1.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_half_1deg.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. 0.0 0.0014'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./disp_x226]
    type = NodalVariableValue
    nodeid = 225
    variable = disp_x
  [../]
  [./disp_y226]
    type = NodalVariableValue
    nodeid = 225
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disp_ramp_vert
  [../]
  [./top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = disp_ramp_horz
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
  [./stuff5_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '5'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff5_strain]
    type = ComputeFiniteStrain
    block = '5'
  [../]
  [./stuff5_stress]
    type = ComputeFiniteStrainElasticStress
    block = '5'
  [../]
  [./stuff6_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '6'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff6_strain]
    type = ComputeFiniteStrain
    block = '6'
  [../]
  [./stuff6_stress]
    type = ComputeFiniteStrainElasticStress
    block = '6'
  [../]
  [./stuff7_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '7'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff7_strain]
    type = ComputeFiniteStrain
    block = '7'
  [../]
  [./stuff7_stress]
    type = ComputeFiniteStrainElasticStress
    block = '7'
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-6
  nl_rel_tol = 1e-5
  l_max_its = 100
  nl_max_its = 200

  start_time = 0.0
  end_time = 3.5
  l_tol = 1e-3
  dt = 0.1
  dtmin = 0.1
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./chkfile2]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x226 disp_y226 top_react_x top_react_y'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    master = 2
    slave = 3
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+10
    system = Constraint
  [../]
[]

modules/xfem/test/tests/crack_tip_enrichment/edge_crack_2d.i

[XFEM]
  qrule = volfrac
  output_cut_plane = true
  use_crack_tip_enrichment = true
  crack_front_definition = crack_tip
  enrichment_displacements = 'enrich1_x enrich2_x enrich3_x enrich4_x enrich1_y enrich2_y enrich3_y enrich4_y'
  displacements = 'disp_x disp_y'
  cut_off_boundary = all
  cut_off_radius = 0.2
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '0.0 1.0 0.5 1.0'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
  [./crack_tip]
    type = CrackFrontDefinition
    crack_direction_method = CrackDirectionVector
    crack_front_points = '0.5 1.0 0'
    crack_direction_vector = '1 0 0'
    2d = true
    axis_2d = 2
  [../]
[]

[Mesh]
  [gen]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 5
    ny = 9
    xmin = 0.0
    xmax = 1.0
    ymin = 0.0
    ymax = 2.0
    elem_type = QUAD4
  []
  [./all_node]
    type = BoundingBoxNodeSetGenerator
    new_boundary = 'all'
    top_right = '1 2 0'
    bottom_left = '0 0 0'
    input = gen
  [../]
  [./right_bottom_node]
    type = ExtraNodesetGenerator
    new_boundary = 'right_bottom_node'
    coord = '1.0 0.0'
    input = all_node
  [../]
  [./right_top_node]
    type = ExtraNodesetGenerator
    new_boundary = 'right_top_node'
    coord = '1.0 2.0'
    input = right_bottom_node
  [../]
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
 [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = vonmisesStress
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./top_y]
    type = Pressure
    variable = disp_y
    boundary = top
    component = 1
    factor = -1
  [../]
  [./bottom_y]
    type = Pressure
    variable = disp_y
    boundary = bottom
    component = 1
    factor = -1
  [../]
  [./fix_y]
    type = DirichletBC
    boundary = right_bottom_node
    variable = disp_y
    value = 0.0
  [../]
  [./fix_x]
    type = DirichletBC
    boundary = right_bottom_node
    variable = disp_x
    value =  0.0
  [../]
  [./fix_x2]
    type = DirichletBC
    boundary = right_top_node
    variable = disp_x
    value =  0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeCrackTipEnrichmentSmallStrain
    displacements = 'disp_x disp_y'
    crack_front_definition = crack_tip
    enrichment_displacements = 'enrich1_x enrich2_x enrich3_x enrich4_x enrich1_y enrich2_y enrich3_y enrich4_y'
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  # Since we do not sub-triangularize the tip element,
  # we need to use higher order quadrature rule to improve
  # integration accuracy.
  # Here second = SECOND is for regression test only.
  # However, order = SIXTH is recommended.
  [./Quadrature]
    type = GAUSS
    order = SECOND
  [../]

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

  # controls for linear iterations
  l_max_its = 10
  l_tol = 1e-4

  # controls for nonlinear iterations
  nl_max_its = 100
  nl_rel_tol = 1e-12 #11
  nl_abs_tol = 1e-12 #12

  # time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
  dtmin = 1.0
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]


[Outputs]
  file_base = edge_crack_2d_out
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/porous_flow/examples/tutorial/11_2D.i

# Two-phase borehole injection problem in RZ coordinates
[Mesh]
  [gen]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 10
    xmin = 1.0
    xmax = 10
    bias_x = 1.4
    ny = 3
    ymin = -6
    ymax = 6
  []
  [./aquifer]
    input = gen
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 -2 0'
    top_right = '10 2 0'
  [../]
  [./injection_area]
    type = ParsedGenerateSideset
    combinatorial_geometry = 'x<1.0001'
    included_subdomain_ids = 1
    new_sideset_name = 'injection_area'
    input = 'aquifer'
  [../]
  [./rename]
    type = RenameBlockGenerator
    old_block_id = '0 1'
    new_block_name = 'caps aquifer'
    input = 'injection_area'
  [../]
[]

[Problem]
  coord_type = RZ
[]

[UserObjects]
  [./dictator]
    type = PorousFlowDictator
    porous_flow_vars = 'pwater pgas T disp_r'
    number_fluid_phases = 2
    number_fluid_components = 2
  [../]
  [./pc]
    type = PorousFlowCapillaryPressureVG
    alpha = 1E-6
    m = 0.6
  [../]
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
  gravity = '0 0 0'
  biot_coefficient = 1.0
  PorousFlowDictator = dictator
[]

[Variables]
  [./pwater]
    initial_condition = 20E6
  [../]
  [./pgas]
    initial_condition = 20.1E6
  [../]
  [./T]
    initial_condition = 330
    scaling = 1E-5
  [../]
  [./disp_r]
    scaling = 1E-5
  [../]
[]

[Kernels]
  [./mass_water_dot]
    type = PorousFlowMassTimeDerivative
    fluid_component = 0
    use_displaced_mesh = false
    variable = pwater
  [../]
  [./flux_water]
    type = PorousFlowAdvectiveFlux
    fluid_component = 0
    use_displaced_mesh = false
    variable = pwater
  [../]
  [./vol_strain_rate_water]
    type = PorousFlowMassVolumetricExpansion
    fluid_component = 0
    use_displaced_mesh = false
    variable = pwater
  [../]
  [./mass_co2_dot]
    type = PorousFlowMassTimeDerivative
    fluid_component = 1
    use_displaced_mesh = false
    variable = pgas
  [../]
  [./flux_co2]
    type = PorousFlowAdvectiveFlux
    fluid_component = 1
    use_displaced_mesh = false
    variable = pgas
  [../]
  [./vol_strain_rate_co2]
    type = PorousFlowMassVolumetricExpansion
    fluid_component = 1
    use_displaced_mesh = false
    variable = pgas
  [../]
  [./energy_dot]
    type = PorousFlowEnergyTimeDerivative
    use_displaced_mesh = false
    variable = T
  [../]
  [./advection]
    type = PorousFlowHeatAdvection
    use_displaced_mesh = false
    variable = T
  [../]
  [./conduction]
    type = PorousFlowHeatConduction
    use_displaced_mesh = false
    variable = T
  [../]
  [./vol_strain_rate_heat]
    type = PorousFlowHeatVolumetricExpansion
    use_displaced_mesh = false
    variable = T
  [../]
  [./grad_stress_r]
    type = StressDivergenceRZTensors
    temperature = T
    variable = disp_r
    thermal_eigenstrain_name = thermal_contribution
    use_displaced_mesh = false
    component = 0
  [../]
  [./poro_r]
    type = PorousFlowEffectiveStressCoupling
    variable = disp_r
    use_displaced_mesh = false
    component = 0
  [../]
[]

[AuxVariables]
  [./disp_z]
  [../]
  [./effective_fluid_pressure]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./mass_frac_phase0_species0]
    initial_condition = 1 # all water in phase=0
  [../]
  [./mass_frac_phase1_species0]
    initial_condition = 0 # no water in phase=1
  [../]
  [./sgas]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./swater]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./stress_rr]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./stress_tt]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./stress_zz]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./porosity]
    family = MONOMIAL
    order = CONSTANT
  [../]
[]

[AuxKernels]
  [./effective_fluid_pressure]
    type = ParsedAux
    args = 'pwater pgas swater sgas'
    function = 'pwater * swater + pgas * sgas'
    variable = effective_fluid_pressure
  [../]
  [./swater]
    type = PorousFlowPropertyAux
    variable = swater
    property = saturation
    phase = 0
    execute_on = timestep_end
  [../]
  [./sgas]
    type = PorousFlowPropertyAux
    variable = sgas
    property = saturation
    phase = 1
    execute_on = timestep_end
  [../]
  [./stress_rr_aux]
    type = RankTwoAux
    variable = stress_rr
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  [../]
  [./stress_tt]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_tt
    index_i = 2
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 1
    index_j = 1
  [../]
  [./porosity]
    type = PorousFlowPropertyAux
    variable = porosity
    property = porosity
    execute_on = timestep_end
  [../]
[]


[BCs]
  [./pinned_top_bottom_r]
    type = DirichletBC
    variable = disp_r
    value = 0
    boundary = 'top bottom'
  [../]
  [./cavity_pressure_r]
    type = Pressure
    boundary = injection_area
    variable = disp_r
    component = 0
    postprocessor = constrained_effective_fluid_pressure_at_wellbore
    use_displaced_mesh = false
  [../]

  [./cold_co2]
    type = DirichletBC
    boundary = injection_area
    variable = T
    value = 290  # injection temperature
    use_displaced_mesh = false
  [../]
  [./constant_co2_injection]
    type = PorousFlowSink
    boundary = injection_area
    variable = pgas
    fluid_phase = 1
    flux_function = -1E-4
    use_displaced_mesh = false
  [../]

  [./outer_water_removal]
    type = PorousFlowPiecewiseLinearSink
    boundary = right
    variable = pwater
    fluid_phase = 0
    pt_vals = '0 1E9'
    multipliers = '0 1E8'
    PT_shift = 20E6
    use_mobility = true
    use_relperm = true
    use_displaced_mesh = false
  [../]
  [./outer_co2_removal]
    type = PorousFlowPiecewiseLinearSink
    boundary = right
    variable = pgas
    fluid_phase = 1
    pt_vals = '0 1E9'
    multipliers = '0 1E8'
    PT_shift = 20.1E6
    use_mobility = true
    use_relperm = true
    use_displaced_mesh = false
  [../]
[]

[Modules]
  [./FluidProperties]
    [./true_water]
      type = Water97FluidProperties
    [../]
    [./tabulated_water]
      type = TabulatedFluidProperties
      fp = true_water
      temperature_min = 275
      pressure_max = 1E8
      fluid_property_file = water97_tabulated_11.csv
    [../]
    [./true_co2]
      type = CO2FluidProperties
    [../]
    [./tabulated_co2]
      type = TabulatedFluidProperties
      fp = true_co2
      temperature_min = 275
      pressure_max = 1E8
      fluid_property_file = co2_tabulated_11.csv
    [../]
  [../]
[]

[Materials]
  [./temperature]
    type = PorousFlowTemperature
    temperature = T
  [../]
  [./saturation_calculator]
    type = PorousFlow2PhasePP
    phase0_porepressure = pwater
    phase1_porepressure = pgas
    capillary_pressure = pc
  [../]
  [./massfrac]
    type = PorousFlowMassFraction
    mass_fraction_vars = 'mass_frac_phase0_species0 mass_frac_phase1_species0'
  [../]
  [./water]
    type = PorousFlowSingleComponentFluid
    fp = tabulated_water
    phase = 0
  [../]
  [./co2]
    type = PorousFlowSingleComponentFluid
    fp = tabulated_co2
    phase = 1
  [../]
  [./relperm_water]
    type = PorousFlowRelativePermeabilityCorey
    n = 4
    s_res = 0.1
    sum_s_res = 0.2
    phase = 0
  [../]
  [./relperm_co2]
    type = PorousFlowRelativePermeabilityBC
    nw_phase = true
    lambda = 2
    s_res = 0.1
    sum_s_res = 0.2
    phase = 1
  [../]
  [./porosity]
    type = PorousFlowPorosity
    fluid = true
    mechanical = true
    thermal = true
    porosity_zero = 0.1
    reference_temperature = 330
    reference_porepressure = 20E6
    thermal_expansion_coeff = 15E-6 # volumetric
    solid_bulk = 8E9 # unimportant since biot = 1
  [../]
  [./permeability_aquifer]
    type = PorousFlowPermeabilityKozenyCarman
    block = aquifer
    poroperm_function = kozeny_carman_phi0
    phi0 = 0.1
    n = 2
    m = 2
    k0 = 1E-12
  [../]
  [./permeability_caps]
    type = PorousFlowPermeabilityKozenyCarman
    block = caps
    poroperm_function = kozeny_carman_phi0
    phi0 = 0.1
    n = 2
    m = 2
    k0 = 1E-15
    k_anisotropy = '1 0 0  0 1 0  0 0 0.1'
  [../]
  [./rock_thermal_conductivity]
    type = PorousFlowThermalConductivityIdeal
    dry_thermal_conductivity = '2 0 0  0 2 0  0 0 2'
  [../]
  [./rock_internal_energy]
    type = PorousFlowMatrixInternalEnergy
    specific_heat_capacity = 1100
    density = 2300
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 5E9
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeAxisymmetricRZSmallStrain
    eigenstrain_names = 'thermal_contribution initial_stress'
  [../]
  [./thermal_contribution]
    type = ComputeThermalExpansionEigenstrain
    temperature = T
    thermal_expansion_coeff = 5E-6 # this is the linear thermal expansion coefficient
    eigenstrain_name = thermal_contribution
    stress_free_temperature = 330
  [../]
  [./initial_strain]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '20E6 0 0  0 20E6 0  0 0 20E6'
    eigenstrain_name = initial_stress
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]

  [./effective_fluid_pressure]
    type = PorousFlowEffectiveFluidPressure
  [../]
  [./volumetric_strain]
    type = PorousFlowVolumetricStrain
  [../]
[]

[Postprocessors]
  [./effective_fluid_pressure_at_wellbore]
    type = PointValue
    variable = effective_fluid_pressure
    point = '1 0 0'
    execute_on = timestep_begin
    use_displaced_mesh = false
  [../]
  [./constrained_effective_fluid_pressure_at_wellbore]
    type = FunctionValuePostprocessor
    function = constrain_effective_fluid_pressure
    execute_on = timestep_begin
  [../]
[]

[Functions]
  [./constrain_effective_fluid_pressure]
    type = ParsedFunction
    vars = effective_fluid_pressure_at_wellbore
    vals = effective_fluid_pressure_at_wellbore
    value = 'max(effective_fluid_pressure_at_wellbore, 20E6)'
  [../]
[]

[Preconditioning]
  active = basic
  [./basic]
    type = SMP
    full = true
    petsc_options = '-ksp_diagonal_scale -ksp_diagonal_scale_fix'
    petsc_options_iname = '-pc_type -sub_pc_type -sub_pc_factor_shift_type -pc_asm_overlap'
    petsc_options_value = ' asm      lu           NONZERO                   2'
  [../]
  [./preferred_but_might_not_be_installed]
    type = SMP
    full = true
    petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
    petsc_options_value = ' lu       mumps'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  end_time = 1E3
  [./TimeStepper]
    type = IterationAdaptiveDT
    dt = 1E3
    growth_factor = 1.2
    optimal_iterations = 10
  [../]
  nl_abs_tol = 1E-7
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/ad_cavity_pressure/rz.i

#
# Cavity Pressure Test
#
# This test is designed to compute an internal pressure based on
#   p = n * R * T / V
# where
#   p is the pressure
#   n is the amount of material in the volume (moles)
#   R is the universal gas constant
#   T is the temperature
#   V is the volume
#
# The mesh is composed of one block (2) with an interior cavity of volume 8.
#   Block 1 sits in the cavity and has a volume of 1.  Thus, the total
#   initial volume is 7.
# The test adjusts T in the following way:
#   T => T0 + beta * t
# with
#   beta = T0
#   T0 = 240.54443866068704
#   V0 = 7
#   n0 = f(p0)
#   p0 = 100
#   R = 8.314472 J * K^(-1) * mol^(-1)
#
# So, n0 = p0 * V0 / R / T0 = 100 * 7 / 8.314472 / 240.544439
#        = 0.35
#
# At t = 1, p = 200.

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Mesh]
  file = rz.e
[]

[Functions]
  [./temperature]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 2'
    scale_factor = 240.54443866068704
  [../]
[]

[Variables]
  [./disp_r]
  [../]
  [./disp_z]
  [../]
  [./temp]
    initial_condition = 240.54443866068704
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    use_automatic_differentiation = true
  [../]
  [./heat]
    type = ADDiffusion
    variable = temp
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_r
    boundary = '1 2'
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_z
    boundary = '1 2'
    value = 0.0
  [../]
  [./temperatureInterior]
    type = ADFunctionDirichletBC
    preset = false
    boundary = 2
    function = temperature
    variable = temp
  [../]
  [./CavityPressure]
    [./1]
      boundary = 2
      initial_pressure = 100
      R = 8.314472
      temperature = aveTempInterior
      volume = internalVolume
      startup_time = 0.5
      output = ppress
      use_automatic_differentiation = true
    [../]
  [../]
[]

[Materials]
  [./elastic_tensor1]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
    block = 1
  [../]
  [./strain1]
    type = ADComputeAxisymmetricRZFiniteStrain
    block = 1
  [../]
  [./stress1]
    type = ADComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./elastic_tensor2]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
    block = 2
  [../]
  [./strain2]
    type = ADComputeAxisymmetricRZFiniteStrain
    block = 2
  [../]
  [./stress2]
    type = ADComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'NEWTON'

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_abs_tol = 1e-10

  l_max_its = 20

  dt = 0.5
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 2
    execute_on = 'initial linear'
  [../]
  [./aveTempInterior]
    type = SideAverageValue
    boundary = 2
    variable = temp
    execute_on = 'initial linear'
  [../]
[]

[Outputs]
  exodus = true
  [./checkpoint]
    type = Checkpoint
    num_files = 1
  [../]
[]

modules/peridynamics/test/tests/generalized_plane_strain/planestrain_prescribed_OSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  scalar_out_of_plane_strain = scalar_strain_zz
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]

  [./strain_zz]
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = ORDINARY_STATE
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]

  [./strain_zz]
    type = NodalRankTwoPD
    variable = strain_zz
    rank_two_tensor = total_strain
    output_type = component
    index_i = 2
    index_j = 2
  [../]
[]

[AuxScalarKernels]
  [./scalar_strain_zz]
    type = FunctionScalarAux
    variable = scalar_strain_zz
    function = scalar_strain_zz_func
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1 - x) * t'
  [../]
  [./scalar_strain_zz_func]
    type = PiecewiseLinear
    xy_data = '0 0
               1 7.901e-5
               2 1.103021e-2'
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    boundary = 1000
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 1000
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialOSPD
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  start_time = 0.0
  end_time = 2.0
[]

[Outputs]
  exodus = true
  file_base = planestrain_prescribed_OSPD
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking.i

#
# Simple pull test for cracking.
# The stress increases for two steps and then drops to zero.

[Mesh]
  file = cracking_test.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./displ]
    type = PiecewiseLinear
    x = '0 1 2 3  4'
    y = '0 1 0 -1 0'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[BCs]
  [./pull]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = displ
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = 3
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.8e7
    poissons_ratio = 0
  [../]
  [./elastic_stress]
    type = ComputeSmearedCrackingStress
    cracking_stress = 1.68e6
    softening_models = abrupt_softening
  [../]
  [./abrupt_softening]
    type = AbruptSoftening
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -sub_pc_type'
  petsc_options_value = '101                asm      lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  l_tol = 1e-5
  start_time = 0.0
  end_time = 0.1
  dt = 0.025
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/generalized_plane_strain_tm_contact/generalized_plane_strain_tm_contact.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  scalar_out_of_plane_strain = scalar_strain_zz
  temperature = temp
[]

[Mesh]
  file = 2squares.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./temp]
  [../]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./GeneralizedPlaneStrain]
      [./gps]
        use_displaced_mesh = true
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]

  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_xy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xy
    index_i = 0
    index_j = 1
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Functions]
  [./tempramp]
    type = ParsedFunction
    value = 't'
  [../]
[]

[BCs]
  [./x]
    type = DirichletBC
    boundary = '4 6'
    variable = disp_x
    value = 0.0
  [../]
  [./y]
    type = DirichletBC
    boundary = '4 6'
    variable = disp_y
    value = 0.0
  [../]
  [./t]
    type = DirichletBC
    boundary = '4'
    variable = temp
    value = 0.0
  [../]
  [./tramp]
    type = FunctionDirichletBC
    variable = temp
    boundary = '6'
    function = tempramp
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    off_diag_row =    'disp_x disp_y'
    off_diag_column = 'disp_y disp_x'
  [../]
[]

[Contact]
  [./mech]
    master = 8
    slave = 2
    penalty = 1e+10
    normalize_penalty = true
    system = Constraint
    tangential_tolerance = .1
    normal_smoothing_distance = .1
    model = frictionless
    formulation = kinematic
  [../]
[]

[ThermalContact]
  [./thermal]
    type = GapHeatTransfer
    master = 8
    slave = 2
    variable = temp
    tangential_tolerance = .1
    normal_smoothing_distance = .1
    gap_conductivity = 0.01
    min_gap = 0.001
    quadrature = true
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
    block = '1 2'
  [../]
  [./strain]
    type = ComputePlaneSmallStrain
    eigenstrain_names = eigenstrain
    block = '1 2'
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.0
    eigenstrain_name = eigenstrain
    block = '1 2'
  [../]
  [./stress]
    type = ComputeLinearElasticStress
    block = '1 2'
  [../]

  [./heatcond]
    type = HeatConductionMaterial
    thermal_conductivity = 3.0
    specific_heat = 300.0
    block = '1 2'
  [../]

  [./density]
    type = GenericConstantMaterial
    prop_names = 'density'
    prop_values = '1'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  petsc_options_iname = '-pc_type -ps_sub_type -pc_factor_mat_solver_package'
  petsc_options_value = 'asm      lu           superlu_dist'

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-4

# controls for nonlinear iterations
  nl_max_its = 20
  nl_rel_tol = 1e-9
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 0.2
  dtmin = 0.2
  end_time = 2.0
[]

[Outputs]
  exodus = true
[]

modules/porous_flow/examples/tidal/atm_tides.i

# A 10m x 10m "column" of height 100m is subjected to cyclic pressure at its top
# Assumptions:
# the boundaries are impermeable, except the top boundary
# only vertical displacement is allowed
# the atmospheric pressure sets the total stress at the top of the model
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 10
  xmin = 0
  xmax = 10
  ymin = 0
  ymax = 10
  zmin = -100
  zmax = 0
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  PorousFlowDictator = dictator
  block = 0
  biot_coefficient = 0.6
  multiply_by_density = false
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./porepressure]
    scaling = 1E11
  [../]
[]

[ICs]
  [./porepressure]
    type = FunctionIC
    variable = porepressure
    function = '-10000*z'  # approximately correct
  [../]
[]

[Functions]
  [./ini_stress_zz]
    type = ParsedFunction
    value = '(25000 - 0.6*10000)*z' # remember this is effective stress
  [../]
  [./cyclic_porepressure]
    type = ParsedFunction
    value = 'if(t>0,5000 * sin(2 * pi * t / 3600.0 / 24.0),0)'
  [../]
  [./neg_cyclic_porepressure]
    type = ParsedFunction
    value = '-if(t>0,5000 * sin(2 * pi * t / 3600.0 / 24.0),0)'
  [../]
[]

[BCs]
  # zmin is called 'back'
  # zmax is called 'front'
  # ymin is called 'bottom'
  # ymax is called 'top'
  # xmin is called 'left'
  # xmax is called 'right'
  [./no_x_disp]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = 'bottom top' # because of 1-element meshing, this fixes u_x=0 everywhere
  [../]
  [./no_y_disp]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = 'bottom top' # because of 1-element meshing, this fixes u_y=0 everywhere
  [../]
  [./no_z_disp_at_bottom]
    type = DirichletBC
    variable = disp_z
    value = 0
    boundary = back
  [../]
  [./pp]
    type = FunctionDirichletBC
    variable = porepressure
    function = cyclic_porepressure
    boundary = front
  [../]
  [./total_stress_at_top]
    type = FunctionNeumannBC
    variable = disp_z
    function = neg_cyclic_porepressure
    boundary = front
  [../]
[]

[Modules]
  [./FluidProperties]
    [./the_simple_fluid]
      type = SimpleFluidProperties
      thermal_expansion = 0.0
      bulk_modulus = 2E9
      viscosity = 1E-3
      density0 = 1000.0
    [../]
  [../]
[]

[PorousFlowBasicTHM]
  coupling_type = HydroMechanical
  displacements = 'disp_x disp_y disp_z'
  porepressure = porepressure
  gravity = '0 0 -10'
  fp = the_simple_fluid
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 10.0E9 # drained bulk modulus
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeSmallStrain
    eigenstrain_names = ini_stress
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 0  0 0 0  0 0 ini_stress_zz'
    eigenstrain_name = ini_stress
  [../]
  [./porosity]
    type = PorousFlowPorosityConst # only the initial value of this is ever used
    porosity = 0.1
  [../]
  [./biot_modulus]
    type = PorousFlowConstantBiotModulus
    solid_bulk_compliance = 1E-10
    fluid_bulk_modulus = 2E9
  [../]
  [./permeability]
    type = PorousFlowPermeabilityConst
    permeability = '1E-12 0 0   0 1E-12 0   0 0 1E-14'
  [../]
  [./density]
    type = GenericConstantMaterial
    prop_names = density
    prop_values = 2500.0
  [../]
[]

[Postprocessors]
  [./p0]
    type = PointValue
    outputs = csv
    point = '0 0 0'
    variable = porepressure
  [../]
  [./uz0]
    type = PointValue
    outputs = csv
    point = '0 0 0'
    variable = disp_z
  [../]
  [./p100]
    type = PointValue
    outputs = csv
    point = '0 0 -100'
    variable = porepressure
  [../]
[]


[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  start_time = -3600 # so postprocessors get recorded correctly at t=0
  dt = 3600
  end_time = 360000
  nl_abs_tol = 5E-7
  nl_rel_tol = 1E-10
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/frictional_contact/single_point_2d/single_point_2d_predictor.i

[Mesh]
  file = single_point_2d.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[AuxVariables]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./horizontal_movement]
    type = ParsedFunction
    value = t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    save_in = 'saved_x saved_y'
    diag_save_in = 'diag_saved_x diag_saved_y'
  [../]
[]

[AuxKernels]
  [./incslip_x]
    type = PenetrationAux
    variable = inc_slip_x
    quantity = incremental_slip_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./incslip_y]
    type = PenetrationAux
    variable = inc_slip_y
    quantity = incremental_slip_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./botx]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./boty]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./botx2]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./boty2]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./topx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./topy]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = -0.005
  [../]
[]

[Materials]
  [./bottom]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1.0e9
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
  [./top]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu    superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 200
  dt = 0.001
  end_time = 0.01
  num_steps = 1000
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  dtmin = 0.001
  l_tol = 1e-3

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  exodus = true
  print_linear_residuals = true
  perf_graph = true
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    master = 2
    slave = 3
    model = coulomb
    system = constraint
    friction_coefficient = '0.25'
  [../]
[]

[Dampers]
  [./contact_slip]
    type = ContactSlipDamper
    master = '2'
    slave = '3'
  [../]
[]

modules/tensor_mechanics/examples/hyper_elastic_test.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 5
  ny = 5
  nz = 5
  use_displaced_mesh = false
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Functions]
  [./top_displacement]
    type = ParsedFunction
    value = t
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    variable = 'disp_x'
    boundary = bottom
    value = 0
  [../]
  [./bottom_y]
    type = DirichletBC
    variable = 'disp_y'
    boundary = bottom
    value = 0
  [../]
  [./bottom_z]
    type = DirichletBC
    variable = 'disp_z'
    boundary = bottom
    value = 0
  [../]

  [./top_x]
    type = DirichletBC
    variable = 'disp_x'
    boundary = top
    value = 0
  [../]
  [./top_y]
    type = FunctionDirichletBC
    variable = 'disp_y'
    boundary = top
    function = top_displacement
  [../]
  [./top_z]
    type = DirichletBC
    variable = 'disp_z'
    boundary = top
    value = 0
  [../]
[]

[Kernels]
  [./x]
    type = ADStressDivergenceTensors
    variable = disp_x
    component = 0
  [../]
  [./y]
    type = ADStressDivergenceTensors
    variable = disp_y
    component = 1
  [../]
  [./z]
    type = ADStressDivergenceTensors
    variable = disp_z
    component = 2
  [../]
[]

[Materials]
  [./rubber_elasticity]
    type = ComputeIsotropicElasticityTensor
    # lambda = 1.2e7
    # shear_modulus = 1.2e7
    youngs_modulus = 1
    poissons_ratio = 0.45 # the closer this gets to 0.5 the worse the problem becomes
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeGreenLagrangeStrain
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  dt = 0.05
  dtmin = 0.05
  nl_abs_tol = 1e-10
  num_steps = 500
[]

[Outputs]
  execute_on = 'INITIAL TIMESTEP_END'
  exodus = true
  print_linear_residuals = false
[]

modules/peridynamics/test/tests/auxkernels/planestrain_thermomechanics_stretch_NOSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 8
    ny = 8
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]

  [./total_stretch]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mechanical_stretch]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
    eigenstrain_names = thermal_strain
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]

  [./total_stretch]
    type = MaterialRealAux
    variable = total_stretch
    property = total_stretch
  [../]
  [./mechanical_stretch]
    type = MaterialRealAux
    variable = mechanical_stretch
    property = mechanical_stretch
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = 'x*x+y*y'
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    boundary = 1003
    preset = false
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 1000
    preset = false
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./strain]
    type = ComputePlaneSmallStrainNOSPD
    eigenstrain_names = thermal_strain
    plane_strain = true
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 0.0002
    stress_free_temperature = 0.0
    eigenstrain_name = thermal_strain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  l_tol = 1e-8
  nl_rel_tol = 1e-10

  start_time = 0.0
  end_time = 1.0

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

[Outputs]
  exodus = true
  file_base = planestrain_thermomechanics_stretch_NOSPD
[]

tutorials/darcy_thermo_mech/step10_multiapps/problems/step10.i

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 100
  ymax = 0.304 # Length of test chamber
  xmax = 0.0257 # Test chamber radius
[]

[Variables]
  [pressure]
  []
  [temperature]
    initial_condition = 300 # Start at room temperature
  []
[]

[AuxVariables]
  [k_eff]
    initial_condition = 15.0 # water at 20C
  []
  [velocity]
    order = CONSTANT
    family = MONOMIAL_VEC
  []
[]

[Modules/TensorMechanics/Master]
  [all]
    # This block adds all of the proper Kernels, strain calculators, and Variables
    # for TensorMechanics in the correct coordinate system (autodetected)
    add_variables = true
    strain = FINITE
    eigenstrain_names = eigenstrain
    use_automatic_differentiation = true
    generate_output = 'vonmises_stress elastic_strain_xx elastic_strain_yy strain_xx strain_yy'
  []
[]

[Kernels]
  [darcy_pressure]
    type = DarcyPressure
    variable = pressure
  []
  [heat_conduction]
    type = ADHeatConduction
    variable = temperature
  []
  [heat_conduction_time_derivative]
    type = ADHeatConductionTimeDerivative
    variable = temperature
  []
  [heat_convection]
    type = DarcyAdvection
    variable = temperature
    pressure = pressure
  []
[]

[AuxKernels]
  [velocity]
    type = DarcyVelocity
    variable = velocity
    execute_on = timestep_end
    pressure = pressure
  []
[]

[BCs]
  [inlet]
    type = DirichletBC
    variable = pressure
    boundary = bottom
    value = 4000 # (Pa) From Figure 2 from paper.  First data point for 1mm spheres.
  []
  [outlet]
    type = DirichletBC
    variable = pressure
    boundary = top
    value = 0 # (Pa) Gives the correct pressure drop from Figure 2 for 1mm spheres
  []
  [inlet_temperature]
    type = FunctionDirichletBC
    variable = temperature
    boundary = bottom
    function = 'if(t<0,350+50*t,350)'
  []
  [outlet_temperature]
    type = HeatConductionOutflow
    variable = temperature
    boundary = top
  []
  [hold_inlet]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0
  []
  [hold_center]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  []
  [hold_outside]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0
  []
[]

[Materials]
  viscosity_file = data/water_viscosity.csv
  density_file = data/water_density.csv
  specific_heat_file = data/water_specific_heat.csv
  thermal_expansion_file = data/water_thermal_expansion.csv
  [column]
    type = PackedColumn
    temperature = temperature
    radius = 1
    thermal_conductivity = k_eff # Use the AuxVariable instead of calculating
    fluid_viscosity_file = ${viscosity_file}
    fluid_density_file = ${density_file}
    fluid_specific_heat_file = ${specific_heat_file}
    fluid_thermal_expansion_file = ${thermal_expansion_file}
  []

  [elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 200e9 # (Pa) from wikipedia
    poissons_ratio = .3 # from wikipedia
  []
  [elastic_stress]
    type = ADComputeFiniteStrainElasticStress
  []
  [thermal_strain]
    type = ADComputeThermalExpansionEigenstrain
    stress_free_temperature = 300
    thermal_expansion_coeff = 1e-6
    eigenstrain_name = eigenstrain
    temperature = temperature
  []
[]

[Postprocessors]
  [average_temperature]
    type = ElementAverageValue
    variable = temperature
  []
[]

[Executioner]
  type = Transient
  start_time = -1
  end_time = 200
  steady_state_tolerance = 1e-7
  steady_state_detection = true
  dt = 0.25
  solve_type = PJFNK
  automatic_scaling = true
  compute_scaling_once = false
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre boomeramg 500'
  line_search = none
  [TimeStepper]
    type = FunctionDT
    function = 'if(t<0,0.1,0.25)'
  []
[]


[MultiApps]
  [micro]
    type = TransientMultiApp
    app_type = DarcyThermoMechApp
    positions = '0.01285 0.0    0
                 0.01285 0.0608 0
                 0.01285 0.1216 0
                 0.01285 0.1824 0
                 0.01285 0.2432 0
                 0.01285 0.304  0'
    input_files = step10_micro.i
    execute_on = 'timestep_end'
  []
[]

[Transfers]
  [keff_from_sub]
    type = MultiAppPostprocessorInterpolationTransfer
    direction = from_multiapp
    multi_app = micro
    variable = k_eff
    power = 1
    postprocessor = k_eff
    execute_on = 'timestep_end'
  []
  [temperature_to_sub]
    type = MultiAppVariableValueSamplePostprocessorTransfer
    direction = to_multiapp
    multi_app = micro
    source_variable = temperature
    postprocessor = temperature_in
    execute_on = 'timestep_end'
  []
[]

[Controls]
  [multiapp]
    type = TimePeriod
    disable_objects = 'MultiApps::micro Transfers::keff_from_sub Transfers::temperature_to_sub'
    start_time = '0'
    execute_on = 'initial'
  []
[]

[Outputs]
  [out]
    type = Exodus
    elemental_as_nodal = true
  []
[]

modules/tensor_mechanics/test/tests/jacobian/tensile_update3.i

# Tensile, update version, with strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Return to the stress_I = stress_II = stress_III ~1 tip

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2 0 0  0 1.9 0  0 0 2.1'
    eigenstrain_name = ini_stress
  [../]
  [./tensile]
    type = TensileStressUpdate
    tensile_strength = ts
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = tensile
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/solid_mechanics/LinearStrainHardening/lsh_pressure.i

#
# This test exercises the linear strain hardening material.  The mesh is
# taken from the patch test (7 elements, 1 on the interior).  There are
# symmetry bcs on three faces with a pressure load on another face.
#
# Young's modulus    = 2.4e5
# Yield stress       = 2.4e2
# Hardening constant = 1600
#
# The pressure reaches 2.4e2 at time 1 and 2.6e2 at time 2.  Thus, at
# time 1, the stress is at the yield stress.  2.4e2/2.4e5=0.001 (the
# strain at time 1).  The increase in stress from time 1 to time 2 is
# 20.  20/1600=0.0125 (the plastic strain).  The elastic strain at
# time 2 is 260/2.4e5=0.00108333.  The total strain at time 2 is
# 0.01358333.
#

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = lsh_pressure.e
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]


[AuxVariables]

  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_mag]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]


[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0  1      2'
    y = '0 -2.4e2 -2.6e2'
  [../]

  [./dts]
    type = PiecewiseLinear
    x = '0    0.8 1   1.8'
    y = '0.8  0.2 0.8 0.2'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]

  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]

  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]

  [./plastic_strain_xx]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]

  [./plastic_strain_yy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]

  [./plastic_strain_zz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_zz
    index_i = 2
    index_j = 2
  [../]

  [./plastic_strain_mag]
    type = MaterialRealAux
    property = effective_plastic_strain
    variable = plastic_strain_mag
  [../]

 []


[BCs]

  [./Pressure]
    [./internal_pressure]
      boundary = 11
      function = top_pull
      disp_x = disp_x
      disp_y = disp_y
      disp_z = disp_z
    [../]
  [../]

  [./x]
    type = DirichletBC
    variable = disp_x
    boundary = 10
    value = 0.0
  [../]

  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = 9
    value = 0.0
  [../]

  [./z]
    type = DirichletBC
    variable = disp_z
    boundary = 14
    value = 0.0
  [../]

[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2 3 4 5 6 7'
    youngs_modulus = 2.4e5
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = '1 2 3 4 5 6 7'
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'isoplas'
    block = '1 2 3 4 5 6 7'
  [../]
  [./isoplas]
    type = IsotropicPlasticityStressUpdate
    yield_stress = 2.4e2
    hardening_constant = 1600
    relative_tolerance = 1e-20
    absolute_tolerance = 1e-09
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'


  line_search = 'none'


  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-6


  start_time = 0.0
  end_time = 2
  dt = 1.5e-3

  [./TimeStepper]
    type = FunctionDT
    function = dts
  [../]
[]



[Outputs]
  exodus = true
[]

modules/combined/test/tests/solid_mechanics/Time_integration/HHT_time_integration/HHT_test.i

# Test for  HHT time integration

# The test is for an 1-D bar element of unit length fixed on one end
# with a ramped pressure boundary condition applied to the other end.
# alpha, beta and gamma are HHT time integration parameters The
# equation of motion in terms of matrices is:
#
# M*accel + alpha*(K*disp - K*disp_old) + K*disp = P(t+alpha dt)*Area
#
# Here M is the mass matrix, K is the stiffness matrix, P is the applied pressure
#
# This equation is equivalent to:
#
# density*accel + alpha*(Div stress - Div stress_old) +Div Stress= P(t+alpha dt)
#
# The first term on the left is evaluated using the Inertial force
# kernel The next two terms on the left involving alpha is evaluated
# using the StressDivergence Kernel The residual due to Pressure is
# evaluated using Pressure boundary condition
#
# The system will come to steady state slowly after the pressure
# becomes constant.  Alpha equal to zero will result in Newmark
# integration.
[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
  order = FIRST
  family = LAGRANGE
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = 0.0
  xmax = 0.1
  ymin = 0.0
  ymax = 1.0
  zmin = 0.0
  zmax = 0.1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./vel_x]
  [../]
  [./accel_x]
  [../]
  [./vel_y]
  [../]
  [./accel_y]
  [../]
  [./vel_z]
  [../]
  [./accel_z]
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

[]

[Kernels]
  [./DynamicTensorMechanics]
   use_displaced_mesh = true
   alpha = 0.11
  [../]
  [./inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    beta = 0.25
    gamma = 0.5
  [../]

[]

[AuxKernels]
  [./accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_z]
    type = NewmarkAccelAux
    variable = accel_z
    displacement = disp_z
    velocity = vel_z
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_z]
    type = NewmarkVelAux
    variable = vel_z
    acceleration = accel_z
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./stress_yy]
     type = RankTwoAux
     rank_two_tensor = stress
     variable = stress_yy
     index_i = 1
     index_j = 1
  [../]
  [./strain_yy]
     type = RankTwoAux
     rank_two_tensor = total_strain
     variable = strain_yy
     index_i = 1
     index_j = 1
  [../]

[]


[BCs]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value=0.0
  [../]
  [./top_x]
   type = DirichletBC
    variable = disp_x
    boundary = top
    value=0.0
  [../]
  [./top_z]
    type = DirichletBC
    variable = disp_z
    boundary = top
    value=0.0
  [../]
  [./right_x]
   type = DirichletBC
    variable = disp_x
    boundary = right
    value=0.0
  [../]
  [./right_z]
    type = DirichletBC
    variable = disp_z
    boundary = right
    value=0.0
  [../]
  [./left_x]
   type = DirichletBC
    variable = disp_x
    boundary = left
    value=0.0
  [../]
  [./left_z]
    type = DirichletBC
    variable = disp_z
    boundary = left
    value=0.0
  [../]
  [./front_x]
   type = DirichletBC
    variable = disp_x
    boundary = front
    value=0.0
  [../]
  [./front_z]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value=0.0
  [../]
  [./back_x]
    type = DirichletBC
    variable = disp_x
    boundary = back
    value=0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value=0.0
  [../]
  [./bottom_x]
   type = DirichletBC
    variable = disp_x
    boundary = bottom
    value=0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value=0.0
  [../]
  [./Pressure]
    [./Side1]
    boundary = bottom
    function = pressure
    factor = 1
    alpha = 0.11
    [../]
  [../]
[]

[Materials]
  [./elastic]
    type = ComputeIsotropicElasticityTensor
    block = '0'
    youngs_modulus = 210e+09
    poissons_ratio = 0
  [../]
  [./elastic_strain]
    type= ComputeFiniteStrain
    block = '0'
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
    block = '0'
  [../]
  [./density]
    type = GenericConstantMaterial
    block = 0
    prop_names = 'density'
    prop_values = '7750'
  [../]
[]

[Executioner]

  type = Transient
  start_time = 0
  end_time = 2
  dtmax = 0.1
  dtmin = 0.1
  [./TimeStepper]
    type = ConstantDT
    dt = 0.1
  [../]

[]


[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0.0 0.1 0.2 1.0 2.0 5.0'
    y = '0.0 0.1 0.2 1.0 1.0 1.0'
    scale_factor = 1e9
  [../]
  [./vel_ic]
    type = PiecewiseLinear
    x = '0.0 0.5 1.0'
    y = '0.1 0.1 0.1'
    scale_factor = 1
  [../]
[]

[Postprocessors]
   [./_dt]
     type = TimestepSize
   [../]
   [./disp]
     type = NodalMaxValue
     variable = disp_y
     boundary = bottom
   [../]
   [./vel]
     type = NodalMaxValue
     variable = vel_y
     boundary = bottom
   [../]
   [./accel]
     type = NodalMaxValue
     variable = accel_y
     boundary = bottom
   [../]
   [./stress_yy]
      type = ElementAverageValue
      variable = stress_yy
   [../]
   [./strain_yy]
      type = ElementAverageValue
      variable = strain_yy
   [../]

[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/radial_disp_aux/sphere_1d_spherical.i

# The purpose of this set of tests is to check the values computed
# by the RadialDisplacementAux AuxKernel. They should match the
# radial component of the displacment for a cylindrical or spherical
# model.
# This particular model is of a sphere subjected to uniform thermal
# expansion represented using a 1D spherical model.

[Mesh]
  type = GeneratedMesh
  dim = 1
  elem_type = EDGE3
  nx = 4
  xmin = 0.0
  xmax = 1.0
[]

[GlobalParams]
  displacements = 'disp_x'
[]

[Problem]
  coord_type = RSPHERICAL
[]

[AuxVariables]
  [./temp]
  [../]
  [./rad_disp]
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t+300.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    eigenstrain_names = eigenstrain
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
    use_displaced_mesh = false
  [../]
  [./raddispaux]
    type = RadialDisplacementSphereAux
    variable = rad_disp
  [../]
[]

[BCs]
  [./x]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 300
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '51'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-11
  nl_abs_tol = 1e-10

  start_time = 0.0
  end_time = 1
  dt = 1
  dtmin = 1
[]

[Outputs]
  csv = true
  exodus = true
[]

modules/xfem/test/tests/init_solution_propagation/init_solution_propagation.i

# The purpose of this test is to verify that the procedures for initializing
# the solution on nodes/elements affected by XFEM works correctly in both
# serial and parallel.

# The crack cuts near to domain boundaries in parallel, and the displacement
# solution will be wrong in parallel if this is not done correctly.  This
# test also has multiple aux variables of various types that are only computed
# on initialization, and which will be wrong if the XFEM initializtion
# is not done correctly.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[XFEM]
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 7
  ny = 7
  xmin = 0.0
  xmax = 25.0
  ymin = -12.5
  ymax = 12.5
  elem_type = QUAD4
[]

[UserObjects]
  [./line_seg_cut_set_uo]
    type = LineSegmentCutSetUserObject
    cut_data ='0.0000e+000  0.0000e+000  5.5000e+000  0.0000e+000  0.0   0.0
               5.5000e+000  0.0000e+000  2.5500e+001  0.0000e+000  0.05  1.05'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./const_monomial]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./first_monomial]
    order = FIRST
    family = MONOMIAL
  [../]
  [./first_linear]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    planar_formulation = PLANE_STRAIN
  [../]
[]

[AuxKernels]
  [./const_monomial]
    type = FunctionAux
    function = 'dummy'
    variable = const_monomial
    execute_on = 'initial'
  [../]
  [./first_monomial]
    type = FunctionAux
    function = 'dummy'
    variable = first_monomial
    execute_on = 'initial'
  [../]
  [./first_linear]
    type = FunctionAux
    function = 'dummy'
    variable = first_linear
    execute_on = 'initial'
  [../]
[]

[Functions]
  [./dummy]
    type = ParsedFunction
    value = 'x*x+y*y'
  [../]
  [./disp_top_y]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.1'
  [../]
[]

[BCs]
  [./top_y]
    type = FunctionDirichletBC
    boundary = 2
    variable = disp_y
    function = disp_top_y
  [../]

  [./bottom_y]
    type = DirichletBC
    boundary = 0
    variable = disp_y
    value = 0.0
  [../]

  [./right_x]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  petsc_options = '-snes_ksp_ew'

  l_max_its = 100
  nl_max_its = 25
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-8

  start_time = 0.0
  dt = 0.1
  end_time = 1.0
  max_xfem_update = 1
[]


[Outputs]
  exodus = true
  csv = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/glued_kinematic_dirac.i

# This is a dirac (contact formulation) version of glued_kinematic.i
[Mesh]
  file = blocks_2d_nogap.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    #Initial gap is 0.01
    value = -0.01
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  [../]
  [./right]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.01
  end_time = 0.10
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-8
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    master = 2
    slave = 3
    model = glued
    penalty = 1e+6
    system = diracKernel
  [../]
[]

modules/xfem/test/tests/solid_mechanics_basic/edge_crack_3d.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 5
  ny = 5
  nz = 2
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  zmin = 0.0
  zmax = 0.2
  elem_type = HEX8
[]

[UserObjects]
  [./square_cut_uo]
    type = RectangleCutUserObject
    cut_data = ' -0.001 0.5 -0.001
                  0.401 0.5 -0.001
                  0.401 0.5  0.201
                 -0.001 0.5  0.201'
  [../]
[]

[AuxVariables]
  [./SED]
   order = CONSTANT
    family = MONOMIAL
  [../]
[]

[DomainIntegral]
  integrals = 'Jintegral InteractionIntegralKI'
  crack_front_points = '0.4 0.5 0.0
                        0.4 0.5 0.1
                        0.4 0.5 0.2'
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  radius_inner = '0.2'
  radius_outer = '0.4'
  poissons_ratio = 0.3
  youngs_modulus = 207000
  block = 0
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
    block = 0
  [../]
[]

[Functions]
  [./top_trac_y]
    type = ConstantFunction
    value = 10
  [../]
[]


[BCs]
  [./top_y]
    type = FunctionNeumannBC
    boundary = top
    variable = disp_y
    function = top_trac_y
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    boundary = bottom
    variable = disp_z
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
    block = 0
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  file_base = edge_crack_3d_out
  execute_on = 'timestep_end'
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/tensile_update8.i

# Tensile, update version, with strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0
    internal_limit = 1E-3
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2 -1 0.5  1 1.9 0  0.5 0 3'
    eigenstrain_name = ini_stress
  [../]
  [./tensile]
    type = TensileStressUpdate
    tensile_strength = ts
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = tensile
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update3.i

# MC update version, with only Tensile with tensile strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Return to the stress_I = stress_II = stress_III ~1 tip

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2 0 0  0 1.9 0  0 0 2.1'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/peridynamics/test/tests/jacobian_check/2D_thermomechanics_OSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./temp]
    initial_condition = 0.5
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = ORDINARY_STATE
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConductionBPD
    variable = temp
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.0
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialOSPD
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
  [../]

  [./thermal]
    type = ThermalConstantHorizonMaterialBPD
    thermal_conductivity = 1.0
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1
[]

modules/xfem/test/tests/bimaterials/glued_bimaterials_2d.i

# This test is for two layer materials with different youngs modulus
# The global stress is determined by switching the stress based on level set values
# The material interface is marked by a level set function
# The two layer materials are glued together

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[UserObjects]
  [./level_set_cut_uo]
    type = LevelSetCutUserObject
    level_set_var = ls
  [../]
[]

[Mesh]
  displacements = 'disp_x disp_y'
  [gen]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 5
    ny = 5
    xmin = 0.0
    xmax = 5.
    ymin = 0.0
    ymax = 5.
    elem_type = QUAD4
  []
  [./left_bottom]
    type = ExtraNodesetGenerator
    new_boundary = 'left_bottom'
    coord = '0.0 0.0'
    input = gen
  [../]
  [./left_top]
    type = ExtraNodesetGenerator
    new_boundary = 'left_top'
    coord = '0.0 5.'
    input = left_bottom
  [../]
[]

[AuxVariables]
  [./ls]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxKernels]
  [./ls_function]
    type = FunctionAux
    variable = ls
    function = ls_func
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Functions]
  [./ls_func]
    type = ParsedFunction
    value = 'y-2.5'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./a_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./a_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./a_strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./b_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./b_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./b_strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  [../]
  [./a_strain_xx]
    type = RankTwoAux
    rank_two_tensor = A_total_strain
    index_i = 0
    index_j = 0
    variable = a_strain_xx
  [../]
  [./a_strain_yy]
    type = RankTwoAux
    rank_two_tensor = A_total_strain
    index_i = 1
    index_j = 1
    variable = a_strain_yy
  [../]
  [./a_strain_xy]
    type = RankTwoAux
    rank_two_tensor = A_total_strain
    index_i = 0
    index_j = 1
    variable = a_strain_xy
  [../]
  [./b_strain_xx]
    type = RankTwoAux
    rank_two_tensor = B_total_strain
    index_i = 0
    index_j = 0
    variable = b_strain_xx
  [../]
  [./b_strain_yy]
    type = RankTwoAux
    rank_two_tensor = B_total_strain
    index_i = 1
    index_j = 1
    variable = b_strain_yy
  [../]
  [./b_strain_xy]
    type = RankTwoAux
    rank_two_tensor = B_total_strain
    index_i = 0
    index_j = 1
    variable = b_strain_xy
  [../]
[]

[Constraints]
  [./dispx_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_x
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  [../]
  [./dispy_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_y
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./topx]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_x
    function = 0.03*t
  [../]
  [./topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = '0.03*t'
  [../]
[]

[Materials]
  [./elasticity_tensor_A]
    type = ComputeIsotropicElasticityTensor
    base_name = A
    youngs_modulus = 1e9
    poissons_ratio = 0.3
  [../]
  [./strain_A]
    type = ComputeSmallStrain
    base_name = A
  [../]
  [./stress_A]
    type = ComputeLinearElasticStress
    base_name = A
  [../]
  [./elasticity_tensor_B]
    type = ComputeIsotropicElasticityTensor
    base_name = B
    youngs_modulus = 1e5
    poissons_ratio = 0.3
  [../]
  [./strain_B]
    type = ComputeSmallStrain
    base_name = B
  [../]
  [./stress_B]
    type = ComputeLinearElasticStress
    base_name = B
  [../]
  [./combined_stress]
    type = LevelSetBiMaterialRankTwo
    levelset_positive_base = 'A'
    levelset_negative_base = 'B'
    level_set_var = ls
    prop_name = stress
  [../]
  [./combined_dstressdstrain]
    type = LevelSetBiMaterialRankFour
    levelset_positive_base = 'A'
    levelset_negative_base = 'B'
    level_set_var = ls
    prop_name = Jacobian_mult
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'bt'

# controls for linear iterations
  l_max_its = 20
  l_tol = 1e-3

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-7

# time control
  start_time = 0.0
  dt = 0.1
  num_steps = 2

  max_xfem_update = 1
[]

[Outputs]
  exodus = true
  execute_on = timestep_end
  csv = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/plane_stress/weak_plane_stress_finite.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  temperature = temp
  out_of_plane_strain = strain_zz
[]

[Mesh]
  file = square.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./strain_zz]
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
  [./nl_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
  [./min_strain_zz]
    type = NodalExtremeValue
    variable = strain_zz
    value_type = min
  [../]
  [./max_strain_zz]
    type = NodalExtremeValue
    variable = strain_zz
    value_type = max
  [../]
[]

[Modules/TensorMechanics/Master]
  [plane_stress]
    planar_formulation = WEAK_PLANE_STRESS
    strain = FINITE
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy'
    eigenstrain_names = eigenstrain
  []
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = nl_strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x='0     1   100'
    y='0  0.00  0.00'
  [../]
  [./tempfunc]
    type = ParsedFunction
    value = '(1 - x) * t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-06

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/sliding_block/in_and_out/constraint/frictionless_penalty_contact_line_search.i

#  This is a benchmark test that checks constraint based frictionless
#  contact using the penalty method.  In this test a sinusoidal
#  displacement is applied in the horizontal direction to simulate
#  a small block come in and out of contact as it slides down a larger block.
#
#  The sinusoid is of the form 0.4sin(4t)+0.2. The gold file is run
#  on one processor and the benchmark
#  case is run on a minimum of 4 processors to ensure no parallel variability
#  in the contact pressure and penetration results.  Further documentation can
#  found in moose/modules/contact/doc/sliding_block/
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
  [./horizontal_movement]
    type = ParsedFunction
    value = -0.04*sin(4*t)+0.02
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
  [./tot_nonlin_it]
    type = CumulativeValuePostprocessor
    postprocessor = nonlinear_its
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Preconditioning]
  [./smp]
     type = SMP
     full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-ksp_monitor_true_residual'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'contact'
  contact_line_search_ltol = .5
  contact_line_search_allowed_lambda_cuts = 0

  l_max_its = 100
  nl_max_its = 20
  dt = 0.1
  end_time = 3
  # num_steps = 30
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-6
  dtmin = 0.01
[]

[Outputs]
  perf_graph = true
  print_linear_residuals = false
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+7
    formulation = penalty
    system = constraint
    normal_smoothing_distance = 0.1
  [../]
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking_rz_exponential.i

#
# Test to exercise the exponential stress release
#
# Stress vs. strain should show a linear relationship until cracking,
#   an exponential stress release, a linear relationship back to zero
#   strain, a linear relationship with the original stiffness in
#   compression and then back to zero strain, a linear relationship
#   back to the exponential curve, and finally further exponential
#   stress release.

[Mesh]
  file = cracking_rz_test.e
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Functions]
  [./disply]
    type = PiecewiseLinear
    x = '0 1       2  3      4 5       6'
    y = '0 0.00175 0 -0.0001 0 0.00175 0.0035'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[BCs]
  [./pully]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disply
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]

  [./sides]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 186.5e9
    poissons_ratio = 0.316
  [../]
  [./elastic_stress]
    type = ComputeSmearedCrackingStress
    cracking_stress = 119.3e6
    softening_models = exponential_softening
  [../]
  [./exponential_softening]
    type = ExponentialSoftening
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-ksp_gmres_restart -pc_type'
  petsc_options_value = '101                lu'

  line_search = 'none'
  l_max_its = 100
  l_tol = 1e-5

  nl_max_its = 10
  nl_rel_tol = 1e-8

  nl_abs_tol = 1e-4

  start_time = 0.0
  end_time = 6.0
  dt = 0.005
  dtmin = 0.005
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/notched_plastic_block/cmc_planar.i

# Uses an unsmoothed version of capped-Mohr-Coulomb (via ComputeMultiPlasticityStress with TensorMechanicsPlasticTensileMulti and TensorMechanicsPlasticMohrCoulombMulti) to simulate the following problem.
# A cubical block is notched around its equator.
# All of its outer surfaces have roller BCs, but the notched region is free to move as needed
# The block is initialised with a high hydrostatic tensile stress
# Without the notch, the BCs do not allow contraction of the block, and this stress configuration is admissible
# With the notch, however, the interior parts of the block are free to move in order to relieve stress, and this causes plastic failure
# The top surface is then pulled upwards (the bottom is fixed because of the roller BCs)
# This causes more failure
[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 9
    ny = 9
    nz = 9
    xmin = 0
    xmax = 0.1
    ymin = 0
    ymax = 0.1
    zmin = 0
    zmax = 0.1
  []
  [block_to_remove_xmin]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 -0.01 0.045'
    top_right = '0.01 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = generated_mesh
  []
  [block_to_remove_xmax]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '0.09 -0.01 0.045'
    top_right = '0.11 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_xmin
  []
  [block_to_remove_ymin]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 -0.01 0.045'
    top_right = '0.11 0.01 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_xmax
  []
  [block_to_remove_ymax]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 0.09 0.045'
    top_right = '0.11 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_ymin
  []
  [remove_block]
    type = BlockDeletionGenerator
    block_id = 1
    input = block_to_remove_ymax
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress stress_zz'
    eigenstrain_names = ini_stress
  [../]
[]

[Postprocessors]
  [./uz]
    type = PointValue
    point = '0 0 0.1'
    use_displaced_mesh = false
    variable = disp_z
  [../]
  [./s_zz]
    type = ElementAverageValue
    use_displaced_mesh = false
    variable = stress_zz
  [../]
  [./num_res]
    type = NumResidualEvaluations
  [../]
  [./nr_its]
    type = ElementAverageValue
    variable = num_iters
  [../]
  [./max_nr_its]
    type = ElementExtremeValue
    variable = num_iters
  [../]
  [./runtime]
    type = PerfGraphData
    data_type = TOTAL
    section_name = 'Root'
  [../]
[]

[BCs]
  # back=zmin, front=zmax, bottom=ymin, top=ymax, left=xmin, right=xmax
  [./xmin_xzero]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./xmax_xzero]
    type = DirichletBC
    variable = disp_x
    boundary = right
    value = 0.0
  [../]
  [./ymin_yzero]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./ymax_yzero]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.0
  [../]
  [./zmin_zzero]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = '0'
  [../]
  [./zmax_disp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = '1E-6*max(t,0)'
  [../]
[]

[AuxVariables]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_strain]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./num_iters]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./plastic_strain_aux]
    type = MaterialRankTwoTensorAux
    i = 2
    j = 2
    property = plastic_strain
    variable = plastic_strain
  [../]
  [./num_iters_auxk] # cannot use plastic_NR_iterations directly as this is zero, since no NR iterations are actually used, since we use a custom algorithm to do the return
    type = ParsedAux
    args = plastic_strain
    function = 'if(plastic_strain>0,1,0)'
    variable = num_iters
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 3E6
  [../]
  [./tensile]
    type = TensorMechanicsPlasticTensileMulti
    tensile_strength = ts
    yield_function_tolerance = 1
    internal_constraint_tolerance = 1.0E-6
    #shift = 1
    use_custom_returnMap = false
    use_custom_cto = false
  [../]

  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 5E6
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 10
    convert_to_radians = true
  [../]
  [./mc]
    type = TensorMechanicsPlasticMohrCoulombMulti
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    yield_function_tolerance = 1E-5
    internal_constraint_tolerance = 1E-11
    use_custom_returnMap = false
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 16E9
    poissons_ratio = 0.25
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    ep_plastic_tolerance = 1E-6
    plastic_models = 'tensile mc'
    max_NR_iterations = 50
    specialIC = rock
    deactivation_scheme = safe_to_dumb
    debug_fspb = crash
  [../]
  [./strain_from_initial_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2.5E6 0 0  0 2.5E6 0  0 0 2.5E6'
    eigenstrain_name = ini_stress
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  start_time = -1
  end_time = 10
  dt = 1
  solve_type = NEWTON
  type = Transient

  l_tol = 1E-2
  nl_abs_tol = 1E-5
  nl_rel_tol = 1E-7
  l_max_its = 200
  nl_max_its = 400

  petsc_options_iname = '-pc_type -pc_asm_overlap -sub_pc_type -ksp_type -ksp_gmres_restart'
  petsc_options_value = ' asm      2              lu            gmres     200'
[]


[Outputs]
  file_base = cmc_planar
  perf_graph = true
  exodus = false
  csv = true
[]

modules/tensor_mechanics/test/tests/notched_plastic_block/cmc_smooth.i

# Uses a multi-smoothed version of capped-Mohr-Coulomb (via CappedMohrCoulombStressUpdate and ComputeMultipleInelasticStress) to simulate the following problem.
# A cubical block is notched around its equator.
# All of its outer surfaces have roller BCs, but the notched region is free to move as needed
# The block is initialised with a high hydrostatic tensile stress
# Without the notch, the BCs do not allow contraction of the block, and this stress configuration is admissible
# With the notch, however, the interior parts of the block are free to move in order to relieve stress, and this causes plastic failure
# The top surface is then pulled upwards (the bottom is fixed because of the roller BCs)
# This causes more failure
[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 9
    ny = 9
    nz = 9
    xmin = 0
    xmax = 0.1
    ymin = 0
    ymax = 0.1
    zmin = 0
    zmax = 0.1
  []
  [block_to_remove_xmin]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 -0.01 0.045'
    top_right = '0.01 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = generated_mesh
  []
  [block_to_remove_xmax]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '0.09 -0.01 0.045'
    top_right = '0.11 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_xmin
  []
  [block_to_remove_ymin]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 -0.01 0.045'
    top_right = '0.11 0.01 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_xmax
  []
  [block_to_remove_ymax]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 0.09 0.045'
    top_right = '0.11 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_ymin
  []
  [remove_block]
    type = BlockDeletionGenerator
    block_id = 1
    input = block_to_remove_ymax
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress stress_zz'
    eigenstrain_names = ini_stress
  [../]
[]

[Postprocessors]
  [./uz]
    type = PointValue
    point = '0 0 0.1'
    use_displaced_mesh = false
    variable = disp_z
  [../]
  [./s_zz]
    type = ElementAverageValue
    use_displaced_mesh = false
    variable = stress_zz
  [../]
  [./num_res]
    type = NumResidualEvaluations
  [../]
  [./nr_its] # num_iters is the average number of NR iterations encountered per element in this timestep
    type = ElementAverageValue
    variable = num_iters
  [../]
  [./max_nr_its] # max_num_iters is the maximum number of NR iterations encountered in the element during the whole simulation
    type = ElementExtremeValue
    variable = max_num_iters
  [../]
  [./runtime]
    type = PerfGraphData
    data_type = TOTAL
    section_name = 'Root'
  [../]
[]

[BCs]
  # back=zmin, front=zmax, bottom=ymin, top=ymax, left=xmin, right=xmax
  [./xmin_xzero]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./xmax_xzero]
    type = DirichletBC
    variable = disp_x
    boundary = right
    value = 0.0
  [../]
  [./ymin_yzero]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./ymax_yzero]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.0
  [../]
  [./zmin_zzero]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = '0'
  [../]
  [./zmax_disp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = '1E-6*max(t,0)'
  [../]
[]

[AuxVariables]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./num_iters]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./max_num_iters]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./num_iters_auxk]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = num_iters
  [../]
  [./max_num_iters_auxk]
    type = MaterialRealAux
    property = max_plastic_NR_iterations
    variable = max_num_iters
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 3E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E16
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 5E6
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 10
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 16E9
    poissons_ratio = 0.25
  [../]
  [./mc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    smoothing_tol = 0.2E6
    yield_function_tol = 1E-5
    perfect_guess = false # this is so we can observe some Newton-Raphson iterations, for comparison with other models, and it is not optimal in any real-life simulations
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    perform_finite_strain_rotations = false
  [../]
  [./strain_from_initial_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2.5E6 0 0  0 2.5E6 0  0 0 2.5E6'
    eigenstrain_name = ini_stress
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  start_time = -1
  end_time = 10
  dt = 1
  solve_type = NEWTON
  type = Transient

  l_tol = 1E-2
  nl_abs_tol = 1E-5
  nl_rel_tol = 1E-7
  l_max_its = 200
  nl_max_its = 400

  petsc_options_iname = '-pc_type -pc_asm_overlap -sub_pc_type -ksp_type -ksp_gmres_restart'
  petsc_options_value = ' asm      2              lu            gmres     200'
[]


[Outputs]
  file_base = cmc_smooth
  perf_graph = true
  exodus = false
  csv = true
[]

modules/combined/test/tests/simple_contact/simple_contact_rz_dirac_test.i

#
# The analytic solution is:
#   disp_x = -7e-5 * x
#   disp_y =  6e-5 * y
#   stress_xx = stress_zz = -100
#   stress_yy = stress_xy = 0
#
# Note: Run merged_rz.i to generate a solution to compare to that doesn't use contact.

[Mesh]
  file = contact_rz.e
  # PETSc < 3.5.0 requires the iteration patch_update_strategy to
  # avoid PenetrationLocator warnings, which are currently treated as
  # errors by the TestHarness.
  patch_update_strategy = 'iteration'
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 1'
    scale_factor = 100
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    strain = FINITE
    generate_output = 'stress_xx stress_xy stress_zx stress_yy stress_zz stress_yz'
  [../]
[]

[Contact]
  [./dummy_name]
    master = 3
    slave = 2
    penalty = 1e5
    system = DiracKernel
  [../]
[]


[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 10
    value = 0.0
  [../]

  [./Pressure]
    [./right_pressure]
      boundary = 4
      function = pressure
      disp_x = disp_x
      disp_y = disp_y
    [../]
  [../]
[]

[Materials]
  [./stiffStuff]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type '
  petsc_options_value = 'lu       '

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-9

  l_max_its = 20
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/combined/test/tests/solid_mechanics/pressure/pressure_test.i

#
# Pressure Test
#
# This test is designed to compute pressure loads on three faces of a unit cube.
#
# The mesh is composed of one block with a single element.  Symmetry bcs are
#   applied to the faces opposite the pressures.  Poisson's ratio is zero,
#   which makes it trivial to check displacements.
#

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
  disp_z = disp_z
[../]

[Mesh]#Comment
  file = pressure_test.e
[] # Mesh

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 1.0
  [../]
  [./zeroRamp]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 0. 1.'
    scale_factor = 2.0
  [../]
  [./rampUnramp]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 0.'
    scale_factor = 10.0
  [../]
[] # Functions

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = SMALL
  []
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 5
    value = 0.0
  [../]

  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]

  [./Pressure]
    [./Side1]
      boundary = 1
      function = rampConstant
    [../]
    [./Side2]
      boundary = 2
      function = zeroRamp
    [../]
    [./Side3]
      boundary = 3
      function = rampUnramp
    [../]
  [../]
[] # BCs

[Materials]
  [./constant]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.0
  [../]
  [./constant_stress]
    type = ComputeLinearElasticStress
    block = '1'
  [../]
[]


[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'


  nl_abs_tol = 1e-10
  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[] # Executioner

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[] # Outputs

modules/tensor_mechanics/test/tests/2D_different_planes/gps_xy.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
 file = square_xy_plane.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./generalized_plane_strain]
    block = 1
    strain = SMALL
    scalar_out_of_plane_strain = scalar_strain_zz
    out_of_plane_direction = z
    planar_formulation = GENERALIZED_PLANE_STRAIN
    eigenstrain_names = 'eigenstrain'
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy strain_zz'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 3
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 3
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_stress]
    type = ComputeLinearElasticStress
    block = 1
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    use_displaced_mesh = false
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-10

# controls for nonlinear iterations
  nl_max_its = 10
  nl_rel_tol = 1e-12

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  file_base = gps_xy_small_out
  [./exodus]
    type = Exodus
  [../]
[]

modules/tensor_mechanics/test/tests/torque_reaction/torque_reaction_3D_tm.i

# Scalar torque reaction

# This test computes the sum of the torques acting on a single element cube mesh.
# Equal displacements in the x and the z are applied along the cube top to
# create a shear force along the (1, 0, 1) direction.  The rotation origin is
# set to the middle of the bottom face of the cube (0.5, 0, 0.5), and the axis of
# rotation direction vector  used to compute the torque reaction is set to (-1, 0, 1).
# Torque is calculated for the four nodes on the top of the cube. The projection
# of the node coordinates is zero for nodes 3 and 6, +1 for node 7, and -1 for
# node 2 from the selection of the direction vector and the rotation axis origin.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[GlobalParams]
  volumetric_locking_correction=true
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    save_in = 'saved_x saved_y saved_z'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end     # for efficiency, only compute at the end of a timestep
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = bottom
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]
  [./top_shear_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = top
    function = '0.01*t'
  [../]
  [./top_shear_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = top
    function = '0.01*t'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./small_strain]
    type = ComputeFiniteStrain
    block = 0
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 30
  nl_max_its = 20
  nl_abs_tol = 1e-14
  nl_rel_tol = 1e-12
  l_tol = 1e-8

  start_time = 0.0
  dt = 0.5

  end_time = 1
  num_steps = 2
[]

[Postprocessors]
  [./_dt]
    type = TimestepSize
  [../]
  [./torque]
    type = TorqueReaction
    boundary = top
    reaction_force_variables = 'saved_x saved_y saved_z'
    axis_origin = '0.5 0. 0.5'
    direction_vector = '-1. 0. 1.'
  [../]
[]

[Outputs]
  file_base = torque_reaction_3D_tm_out
  exodus = true
[]

modules/peridynamics/test/tests/simple_tests/2D_finite_strain_NOSPD.i


[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 8
    ny = 8
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1003
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 1001
    function = '0.01*t'
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
    strain = FINITE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e8
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeFiniteStrainNOSPD
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none
  start_time = 0
  end_time = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

[Outputs]
  file_base = 2D_finite_strain_NOSPD
  exodus = true
[]

modules/combined/test/tests/internal_volume/rspherical.i

#
# Internal Volume Test
#
# This test is designed to compute the internal volume of a space considering
#   an embedded volume inside.
#
# The mesh is composed of two blocks with an interior cavity of volume 3.
#   The volume of each of the blocks is also 3.  The volume of the entire sphere
#   is 9.
#
[GlobalParams]
  displacements = 'disp_x'
[]

[Problem]
  coord_type = RSPHERICAL
[]

[Mesh]
  file = meshes/rspherical.e
  construct_side_list_from_node_list = true
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 1e4
  [../]
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    incremental = true
    strain = FINITE
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2 3 4'
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 3'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK

  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 10
    component = 0
    execute_on = 'initial timestep_end'
  [../]
  [./intVol1]
    type = InternalVolume
    boundary = 2
    component = 0
    execute_on = 'initial timestep_end'
  [../]
  [./intVol1Again]
    type = InternalVolume
    boundary = 9
    component = 0
    execute_on = 'initial timestep_end'
  [../]
  [./intVol2]
    type = InternalVolume
    boundary = 11
    component = 0
    execute_on = 'initial timestep_end'
  [../]
  [./intVolTotal]
    type = InternalVolume
    boundary = 4
    component = 0
    execute_on = 'initial timestep_end'
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_1/ring1_mu_0_2_pen.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring1_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-9
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = ring1_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = ring1_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x7 disp_y7 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    tangential_tolerance = 1e-3
    friction_coefficient = 0.2
    penalty = 1e+9
  [../]
[]

modules/combined/test/tests/thermo_mech/ad-thermo_mech.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  temperature = temp
  volumetric_locking_correction = true
[]

[Mesh]
  file = cube.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]

  [./temp]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_automatic_differentiation = true
  [../]

  [./heat]
    type = ADHeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./bottom_temp]
    type = DirichletBC
    variable = temp
    preset = false
    boundary = 1
    value = 10.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1.0
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ADComputeSmallStrain
    eigenstrain_names = eigenstrain
  [../]
  [./thermal_strain]
    type = ADComputeThermalExpansionEigenstrain
    stress_free_temperature = 0.0
    thermal_expansion_coeff = 1e-5
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]

  [./heat]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]

  [./density]
    type = ADDensity
    density = 1.0
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-14
  l_tol = 1e-3

  l_max_its = 100

  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/action/two_block_new.i

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  []
  [block1]
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 0 0'
    top_right = '0.5 1 0'
    input = generated_mesh
  []
  [block2]
    type = SubdomainBoundingBoxGenerator
    block_id = 2
    bottom_left = '0.5 0 0'
    top_right = '1 1 0'
    input = block1
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Modules/TensorMechanics/Master]
  # parameters that apply to all subblocks are specified at this level. They
  # can be overwritten in the subblocks.
  add_variables = true
  strain = FINITE
  generate_output = 'stress_xx'

  [./block1]
    # the `block` parameter is only valid insde a subblock.
    block = 1
  [../]
  [./block2]
    block = 2
    # the `additional_generate_output` parameter is also only valid inside a
    # subblock. Values specified here are appended to the `generate_output`
    # parameter values.
    additional_generate_output = 'strain_yy'
  [../]
[]

[AuxVariables]
  [./stress_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_theta]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_theta
    execute_on = timestep_end
  [../]
  [./strain_theta]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 2
    index_j = 2
    variable = strain_theta
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./_elastic_stress1]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./_elastic_stress2]
    type = ComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    boundary = 'left'
    variable = disp_x
    value = 0.0
  [../]
  [./top]
    type = DirichletBC
    boundary = 'top'
    variable = disp_y
    value = 0.0
  [../]
  [./right]
    type = DirichletBC
    boundary = 'right'
    variable = disp_x
    value = 0.01
  [../]
  [./bottom]
    type = DirichletBC
    boundary = 'bottom'
    variable = disp_y
    value = 0.01
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Executioner]
  type = Steady

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/recompute_radial_return/uniaxial_viscoplasticity_incrementalstrain.i

# This is a test of the HyperbolicViscoplasticityStressUpdate model
# using the small strain formulation. The material is a visco-plastic material
# i.e. a time-dependent linear strain hardening plasticity model.
# A similar problem was run in Abaqus with exactly the same result, although the element
# used in the Abaqus simulation was a CAX4 element.  Neverthless, due to the boundary conditions
# and load, the MOOSE and Abaqus result are the same.

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = 1x1x1cube.e
[]

[Functions]
  [./top_pull]
    type = ParsedFunction
    value = t/100
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    incremental = true
    add_variables = true
    generate_output = 'stress_yy plastic_strain_xx plastic_strain_yy plastic_strain_zz'
  [../]
[]

[BCs]
  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = top_pull
  [../]

  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]

  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]

  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1000.0
    poissons_ratio = 0.3
  [../]
  [./viscoplasticity]
    type = HyperbolicViscoplasticityStressUpdate
    yield_stress = 10.0
    hardening_constant = 100.0
    c_alpha = 0.2418e-6
    c_beta = 0.1135
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'viscoplasticity'
    tangent_operator = elastic
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  line_search = none


  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  num_steps = 30

  dt = 1.0
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/xfem/test/tests/second_order_elements/square_branch_quad8_2d.i

[GlobalParams]
  order = SECOND
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 10
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD8
[]

[UserObjects]
  [./line_seg_cut_set_uo]
    type = LineSegmentCutSetUserObject
    cut_data = '-1.0000e-10   6.6340e-01   6.6340e-01  -1.0000e-10  0.0  1.0
                 3.3120e-01   3.3200e-01   1.0001e+00   3.3200e-01  1.0  2.0'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    planar_formulation = PLANE_STRAIN
  [../]
[]

[Functions]
  [./right_disp_x]
    type = PiecewiseLinear
    x = '0  1.0    2.0   3.0'
    y = '0  0.005  0.01  0.01'
  [../]
  [./top_disp_y]
    type = PiecewiseLinear
    x = '0  1.0    2.0   3.0'
    y = '0  0.005  0.01  0.01'
  [../]
[]

[BCs]
  [./right_x]
    type = FunctionDirichletBC
    boundary = 1
    variable = disp_x
    function = right_disp_x
  [../]
  [./top_y]
    type = FunctionDirichletBC
    boundary = 2
    variable = disp_y
    function = top_disp_y
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 0
    variable = disp_y
    value = 0.0
  [../]
  [./left_x]
    type = DirichletBC
    boundary = 3
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-16
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 2.2
  num_steps = 5000
[]

[Outputs]
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/thermal_expansion/ad_constant_expansion_stress_free_temp.i

# This test involves only thermal expansion strains on a 2x2x2 cube of approximate
# steel material; however, in this case the stress free temperature of the material
# has been set to 200K so that there is an initial delta temperature of 100K.

# An initial temperature of 300K is given for the material,
# and an auxkernel is used to calculate the temperature in the entire cube to
# raise the temperature each time step.  The final temperature is 675K
# The thermal strain increment should therefore be
#     (675K - 300K) * 1.3e-5 1/K + 100K * 1.3e-5 1/K = 6.175e-3 m/m.

# This test uses a start up step to identify problems in the calculation of
# eigenstrains with a stress free temperature that is different from the initial
# value of the temperature in the problem

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./temp]
    initial_condition = 300.0
  [../]
[]

[AuxVariables]
  [./eigenstrain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./eigenstrain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./eigenstrain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./total_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./total_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./total_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t*(5000.0)+300.0
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        strain = SMALL
        incremental = true
        add_variables = true
        eigenstrain_names = eigenstrain
        use_automatic_differentiation = true
      [../]
    [../]
  [../]
[]

[Kernels]
  [./temp]
    type = Diffusion
    variable = temp
  [../]
[]

[AuxKernels]
  [./eigenstrain_yy]
    type = RankTwoAux
    rank_two_tensor = eigenstrain
    variable = eigenstrain_yy
    index_i = 1
    index_j = 1
    execute_on = 'initial timestep_end'
  [../]
  [./eigenstrain_xx]
    type = RankTwoAux
    rank_two_tensor = eigenstrain
    variable = eigenstrain_xx
    index_i = 0
    index_j = 0
    execute_on = 'initial timestep_end'
  [../]
  [./eigenstrain_zz]
    type = RankTwoAux
    rank_two_tensor = eigenstrain
    variable = eigenstrain_zz
    index_i = 2
    index_j = 2
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = total_strain_yy
    index_i = 1
    index_j = 1
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = total_strain_xx
    index_i = 0
    index_j = 0
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = total_strain_zz
    index_i = 2
    index_j = 2
    execute_on = 'initial timestep_end'
  [../]
[]

[BCs]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp]
    type = FunctionDirichletBC
    variable = temp
    function = temperature_load
    boundary = 'left right'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ADComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ADComputeThermalExpansionEigenstrain
    stress_free_temperature = 200
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = -0.0125
  n_startup_steps = 1
  end_time = 0.075
  dt = 0.0125
  dtmin = 0.0001
[]

[Outputs]
  exodus = true
[]

[Postprocessors]
  [./eigenstrain_xx]
    type = ElementAverageValue
    variable = eigenstrain_xx
    execute_on = 'initial timestep_end'
  [../]
  [./eigenstrain_yy]
    type = ElementAverageValue
    variable = eigenstrain_yy
    execute_on = 'initial timestep_end'
  [../]
  [./eigenstrain_zz]
    type = ElementAverageValue
    variable = eigenstrain_zz
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_xx]
    type = ElementAverageValue
    variable = total_strain_xx
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_yy]
    type = ElementAverageValue
    variable = total_strain_yy
    execute_on = 'initial timestep_end'
  [../]
  [./total_strain_zz]
    type = ElementAverageValue
    variable = total_strain_zz
    execute_on = 'initial timestep_end'
  [../]
  [./temperature]
    type = AverageNodalVariableValue
    variable = temp
    execute_on = 'initial timestep_end'
  [../]
[]

modules/porous_flow/test/tests/dirackernels/injection_with_plasticity.i

# Example: Injection into a uniform aquifer 10 x 10 x 5 km
# Drucker-Prager deformation
# Darcy flow
gravity = -9.81
solid_density = 2350
fluid_density = 1000
porosity0 = 0.1
[Mesh]
  type = GeneratedMesh
  dim = 3
  xmin = 0
  xmax = 1e4
  ymin = 0
  ymax = 1e4
  zmax = 0
  zmin = -5e3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  PorousFlowDictator = dictator
  gravity = '0 0 ${gravity}'
  displacements = 'disp_x disp_y disp_z'
  strain_at_nearest_qp = true
[]

[Modules]
  [./FluidProperties]
    [./simple_fluid]
      type = SimpleFluidProperties
      thermal_expansion = 0 # Not doing a thermal simulation
      bulk_modulus = 2E9
      density0 = ${fluid_density}
      viscosity = 5E-4
    [../]
  [../]
[]

[PorousFlowFullySaturated]
  coupling_type = HydroMechanical
  porepressure = pp
  dictator_name = dictator
  fp = simple_fluid
  add_darcy_aux = false
  add_stress_aux = false
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./pp]
    scaling = 1E6
    [./InitialCondition]
      type = FunctionIC
      function = ini_pp
    [../]
  [../]
[]

[Functions]
  [./ini_stress]
    type = ParsedFunction
    value = '-${gravity} * z * (${solid_density} - ${fluid_density}) * (1.0 - ${porosity0})'  # initial effective stress that should result from weight force
  [../]

  [./ini_pp]
    type = ParsedFunction
    value = '${gravity} * z * ${fluid_density} + 1E5'
  [../]
[]

[BCs]
  [./p_top]
    type = FunctionDirichletBC
    variable = pp
    boundary = front
    function = ini_pp
  [../]

  [./x_roller]
    type = DirichletBC
    variable = disp_x
    boundary = 'left right'
    value = 0
  [../]
  [./y_roller]
    type = DirichletBC
    variable = disp_y
    boundary = 'top bottom'
    value = 0
  [../]
  [./z_confined]
    type = DirichletBC
    variable = disp_z
    boundary = 'back front'
    value = 0
  [../]
[]

[UserObjects]
  [./pls_total_outflow_mass]
    type = PorousFlowSumQuantity
  [../]

  # Cohesion
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 6.0E6
  [../]

  # Friction angle
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 35.0
    convert_to_radians = true
  [../]

  # Dilation angle
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 2
    convert_to_radians = true
  [../]

  # Drucker-Prager objects
  [./dp]
    type = TensorMechanicsPlasticDruckerPragerHyperbolic
    mc_cohesion = mc_coh
    mc_friction_angle = mc_phi
    mc_dilation_angle = mc_psi
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-6
  [../]

  # Tensile strength
  [./tens]
    type = TensorMechanicsHardeningConstant
    value = 3.0E6
  [../]

  # Compressive strength (cap on yield envelope)
  [./compr_all]
    type = TensorMechanicsHardeningConstant
    value = 1E10
  [../]
[]

[Materials]
  [./strain]
    type = ComputeIncrementalSmallStrain
    eigenstrain_names = eigenstrain_all
  [../]

  [./eigenstrain_all]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = 'ini_stress 0 0  0 ini_stress 0  0 0 ini_stress'
    eigenstrain_name = eigenstrain_all
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 3.3333E9
    shear_modulus = 2.5E9
  [../]

  [./dp_mat]
    type = CappedDruckerPragerStressUpdate
    DP_model = dp
    tensile_strength = tens
    compressive_strength = compr_all
    smoothing_tol = 1E5
    yield_function_tol = 1E-3
    tip_smoother = 0
  [../]

  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = dp_mat
  [../]

  # Permeability
  [./permeability]
    type = PorousFlowPermeabilityConst
    permeability = '1E-13 0 0  0 1E-13 0  0 0 1E-13'
  [../]

  # Porosity
  [./porosity]
    type = PorousFlowPorosity
    porosity_zero = ${porosity0}
    biot_coefficient = 1.0
    solid_bulk = 1.0 # Required but irrelevant when biot_coefficient is unity
    mechanical = true
    fluid = true
  [../]

  # Density of saturated rock
  [./density]
    type = PorousFlowTotalGravitationalDensityFullySaturatedFromPorosity
    rho_s = ${solid_density}
  [../]
[]

[DiracKernels]
  [./pls]
    type = PorousFlowPolyLineSink
    variable = pp
    SumQuantityUO = pls_total_outflow_mass
    point_file = two_nodes.bh
    function_of = pressure
    fluid_phase = 0
    p_or_t_vals = '0 1E7'
    fluxes = '-1.59 -1.59'
  [../]
[]

[Preconditioning]
  [./usual]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  solve_type = Newton
  type = Transient
  dt = 1E6
  end_time = 1E6
  nl_rel_tol = 1E-7
[]

[Outputs]
  exodus = true
[]

modules/porous_flow/examples/tutorial/11.i

# Two-phase borehole injection problem
[Mesh]
  [annular]
    type = AnnularMeshGenerator
    nr = 10
    rmin = 1.0
    rmax = 10
    growth_r = 1.4
    nt = 4
    dmin = 0
    dmax = 90
  []
  [./make3D]
    input = annular
    type = MeshExtruderGenerator
    extrusion_vector = '0 0 12'
    num_layers = 3
    bottom_sideset = 'bottom'
    top_sideset = 'top'
  [../]
  [./shift_down]
    type = TransformGenerator
    transform = TRANSLATE
    vector_value = '0 0 -6'
    input = make3D
  [../]
  [./aquifer]
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 0 -2'
    top_right = '10 10 2'
    input = shift_down
  [../]
  [./injection_area]
    type = ParsedGenerateSideset
    combinatorial_geometry = 'x*x+y*y<1.01'
    included_subdomain_ids = 1
    new_sideset_name = 'injection_area'
    input = 'aquifer'
  [../]
  [./rename]
    type = RenameBlockGenerator
    old_block_id = '0 1'
    new_block_name = 'caps aquifer'
    input = 'injection_area'
  [../]
[]

[UserObjects]
  [./dictator]
    type = PorousFlowDictator
    porous_flow_vars = 'pwater pgas T disp_x disp_y'
    number_fluid_phases = 2
    number_fluid_components = 2
  [../]
  [./pc]
    type = PorousFlowCapillaryPressureVG
    alpha = 1E-6
    m = 0.6
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  gravity = '0 0 0'
  biot_coefficient = 1.0
  PorousFlowDictator = dictator
[]

[Variables]
  [./pwater]
    initial_condition = 20E6
  [../]
  [./pgas]
    initial_condition = 20.1E6
  [../]
  [./T]
    initial_condition = 330
    scaling = 1E-5
  [../]
  [./disp_x]
    scaling = 1E-5
  [../]
  [./disp_y]
    scaling = 1E-5
  [../]
[]

[Kernels]
  [./mass_water_dot]
    type = PorousFlowMassTimeDerivative
    fluid_component = 0
    use_displaced_mesh = false
    variable = pwater
  [../]
  [./flux_water]
    type = PorousFlowAdvectiveFlux
    fluid_component = 0
    use_displaced_mesh = false
    variable = pwater
  [../]
  [./vol_strain_rate_water]
    type = PorousFlowMassVolumetricExpansion
    fluid_component = 0
    use_displaced_mesh = false
    variable = pwater
  [../]
  [./mass_co2_dot]
    type = PorousFlowMassTimeDerivative
    fluid_component = 1
    use_displaced_mesh = false
    variable = pgas
  [../]
  [./flux_co2]
    type = PorousFlowAdvectiveFlux
    fluid_component = 1
    use_displaced_mesh = false
    variable = pgas
  [../]
  [./vol_strain_rate_co2]
    type = PorousFlowMassVolumetricExpansion
    fluid_component = 1
    use_displaced_mesh = false
    variable = pgas
  [../]
  [./energy_dot]
    type = PorousFlowEnergyTimeDerivative
    use_displaced_mesh = false
    variable = T
  [../]
  [./advection]
    type = PorousFlowHeatAdvection
    use_displaced_mesh = false
    variable = T
  [../]
  [./conduction]
    type = PorousFlowHeatConduction
    use_displaced_mesh = false
    variable = T
  [../]
  [./vol_strain_rate_heat]
    type = PorousFlowHeatVolumetricExpansion
    use_displaced_mesh = false
    variable = T
  [../]
  [./grad_stress_x]
    type = StressDivergenceTensors
    temperature = T
    variable = disp_x
    thermal_eigenstrain_name = thermal_contribution
    use_displaced_mesh = false
    component = 0
  [../]
  [./poro_x]
    type = PorousFlowEffectiveStressCoupling
    variable = disp_x
    use_displaced_mesh = false
    component = 0
  [../]
  [./grad_stress_y]
    type = StressDivergenceTensors
    temperature = T
    variable = disp_y
    thermal_eigenstrain_name = thermal_contribution
    use_displaced_mesh = false
    component = 1
  [../]
  [./poro_y]
    type = PorousFlowEffectiveStressCoupling
    variable = disp_y
    use_displaced_mesh = false
    component = 1
  [../]
[]

[AuxVariables]
  [./disp_z]
  [../]
  [./effective_fluid_pressure]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./mass_frac_phase0_species0]
    initial_condition = 1 # all water in phase=0
  [../]
  [./mass_frac_phase1_species0]
    initial_condition = 0 # no water in phase=1
  [../]
  [./sgas]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./swater]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./stress_rr]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./stress_tt]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./stress_zz]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./porosity]
    family = MONOMIAL
    order = CONSTANT
  [../]
[]

[AuxKernels]
  [./effective_fluid_pressure]
    type = ParsedAux
    args = 'pwater pgas swater sgas'
    function = 'pwater * swater + pgas * sgas'
    variable = effective_fluid_pressure
  [../]
  [./swater]
    type = PorousFlowPropertyAux
    variable = swater
    property = saturation
    phase = 0
    execute_on = timestep_end
  [../]
  [./sgas]
    type = PorousFlowPropertyAux
    variable = sgas
    property = saturation
    phase = 1
    execute_on = timestep_end
  [../]
  [./stress_rr]
    type = RankTwoScalarAux
    variable = stress_rr
    rank_two_tensor = stress
    scalar_type = RadialStress
    point1 = '0 0 0'
    point2 = '0 0 1'
    execute_on = timestep_end
  [../]
  [./stress_tt]
    type = RankTwoScalarAux
    variable = stress_tt
    rank_two_tensor = stress
    scalar_type = HoopStress
    point1 = '0 0 0'
    point2 = '0 0 1'
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./porosity]
    type = PorousFlowPropertyAux
    variable = porosity
    property = porosity
    execute_on = timestep_end
  [../]
[]


[BCs]
  [./roller_tmax]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = dmax
  [../]
  [./roller_tmin]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = dmin
  [../]
  [./pinned_top_bottom_x]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = 'top bottom'
  [../]
  [./pinned_top_bottom_y]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = 'top bottom'
  [../]
  [./cavity_pressure_x]
    type = Pressure
    boundary = injection_area
    variable = disp_x
    component = 0
    postprocessor = constrained_effective_fluid_pressure_at_wellbore
    use_displaced_mesh = false
  [../]
  [./cavity_pressure_y]
    type = Pressure
    boundary = injection_area
    variable = disp_y
    component = 1
    postprocessor = constrained_effective_fluid_pressure_at_wellbore
    use_displaced_mesh = false
  [../]

  [./cold_co2]
    type = DirichletBC
    boundary = injection_area
    variable = T
    value = 290  # injection temperature
    use_displaced_mesh = false
  [../]
  [./constant_co2_injection]
    type = PorousFlowSink
    boundary = injection_area
    variable = pgas
    fluid_phase = 1
    flux_function = -1E-4
    use_displaced_mesh = false
  [../]

  [./outer_water_removal]
    type = PorousFlowPiecewiseLinearSink
    boundary = rmax
    variable = pwater
    fluid_phase = 0
    pt_vals = '0 1E9'
    multipliers = '0 1E8'
    PT_shift = 20E6
    use_mobility = true
    use_relperm = true
    use_displaced_mesh = false
  [../]
  [./outer_co2_removal]
    type = PorousFlowPiecewiseLinearSink
    boundary = rmax
    variable = pgas
    fluid_phase = 1
    pt_vals = '0 1E9'
    multipliers = '0 1E8'
    PT_shift = 20.1E6
    use_mobility = true
    use_relperm = true
    use_displaced_mesh = false
  [../]
[]

[Modules]
  [./FluidProperties]
    [./true_water]
      type = Water97FluidProperties
    [../]
    [./tabulated_water]
      type = TabulatedFluidProperties
      fp = true_water
      temperature_min = 275
      pressure_max = 1E8
      interpolated_properties = 'density viscosity enthalpy internal_energy'
      fluid_property_file = water97_tabulated_11.csv
    [../]
    [./true_co2]
      type = CO2FluidProperties
    [../]
    [./tabulated_co2]
      type = TabulatedFluidProperties
      fp = true_co2
      temperature_min = 275
      pressure_max = 1E8
      interpolated_properties = 'density viscosity enthalpy internal_energy'
      fluid_property_file = co2_tabulated_11.csv
    [../]
  [../]
[]

[Materials]
  [./temperature]
    type = PorousFlowTemperature
    temperature = T
  [../]
  [./saturation_calculator]
    type = PorousFlow2PhasePP
    phase0_porepressure = pwater
    phase1_porepressure = pgas
    capillary_pressure = pc
  [../]
  [./massfrac]
    type = PorousFlowMassFraction
    mass_fraction_vars = 'mass_frac_phase0_species0 mass_frac_phase1_species0'
  [../]
  [./water]
    type = PorousFlowSingleComponentFluid
    fp = tabulated_water
    phase = 0
  [../]
  [./co2]
    type = PorousFlowSingleComponentFluid
    fp = tabulated_co2
    phase = 1
  [../]
  [./relperm_water]
    type = PorousFlowRelativePermeabilityCorey
    n = 4
    s_res = 0.1
    sum_s_res = 0.2
    phase = 0
  [../]
  [./relperm_co2]
    type = PorousFlowRelativePermeabilityBC
    nw_phase = true
    lambda = 2
    s_res = 0.1
    sum_s_res = 0.2
    phase = 1
  [../]
  [./porosity]
    type = PorousFlowPorosity
    fluid = true
    mechanical = true
    thermal = true
    porosity_zero = 0.1
    reference_temperature = 330
    reference_porepressure = 20E6
    thermal_expansion_coeff = 15E-6 # volumetric
    solid_bulk = 8E9 # unimportant since biot = 1
  [../]
  [./permeability_aquifer]
    type = PorousFlowPermeabilityKozenyCarman
    block = aquifer
    poroperm_function = kozeny_carman_phi0
    phi0 = 0.1
    n = 2
    m = 2
    k0 = 1E-12
  [../]
  [./permeability_caps]
    type = PorousFlowPermeabilityKozenyCarman
    block = caps
    poroperm_function = kozeny_carman_phi0
    phi0 = 0.1
    n = 2
    m = 2
    k0 = 1E-15
    k_anisotropy = '1 0 0  0 1 0  0 0 0.1'
  [../]
  [./rock_thermal_conductivity]
    type = PorousFlowThermalConductivityIdeal
    dry_thermal_conductivity = '2 0 0  0 2 0  0 0 2'
  [../]
  [./rock_internal_energy]
    type = PorousFlowMatrixInternalEnergy
    specific_heat_capacity = 1100
    density = 2300
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 5E9
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeSmallStrain
    eigenstrain_names = 'thermal_contribution initial_stress'
  [../]
  [./thermal_contribution]
    type = ComputeThermalExpansionEigenstrain
    temperature = T
    thermal_expansion_coeff = 5E-6 # this is the linear thermal expansion coefficient
    eigenstrain_name = thermal_contribution
    stress_free_temperature = 330
  [../]
  [./initial_strain]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '20E6 0 0  0 20E6 0  0 0 20E6'
    eigenstrain_name = initial_stress
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]

  [./effective_fluid_pressure]
    type = PorousFlowEffectiveFluidPressure
  [../]
  [./volumetric_strain]
    type = PorousFlowVolumetricStrain
  [../]
[]

[Postprocessors]
  [./effective_fluid_pressure_at_wellbore]
    type = PointValue
    variable = effective_fluid_pressure
    point = '1 0 0'
    execute_on = timestep_begin
    use_displaced_mesh = false
  [../]
  [./constrained_effective_fluid_pressure_at_wellbore]
    type = FunctionValuePostprocessor
    function = constrain_effective_fluid_pressure
    execute_on = timestep_begin
  [../]
[]

[Functions]
  [./constrain_effective_fluid_pressure]
    type = ParsedFunction
    vars = effective_fluid_pressure_at_wellbore
    vals = effective_fluid_pressure_at_wellbore
    value = 'max(effective_fluid_pressure_at_wellbore, 20E6)'
  [../]
[]

[Preconditioning]
  active = basic
  [./basic]
    type = SMP
    full = true
    petsc_options = '-ksp_diagonal_scale -ksp_diagonal_scale_fix'
    petsc_options_iname = '-pc_type -sub_pc_type -sub_pc_factor_shift_type -pc_asm_overlap'
    petsc_options_value = ' asm      lu           NONZERO                   2'
  [../]
  [./preferred_but_might_not_be_installed]
    type = SMP
    full = true
    petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
    petsc_options_value = ' lu       mumps'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  end_time = 1E3
  [./TimeStepper]
    type = IterationAdaptiveDT
    dt = 1E3
    growth_factor = 1.2
    optimal_iterations = 10
  [../]
  nl_abs_tol = 1E-7
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/mortar_tm/2d/frictionless_first/finite_noaction.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'finite_noaction'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]

  [./slave]
    input = block_sidesets
    type = LowerDBlockFromSidesetGenerator
    sidesets = 'block_left'
    new_block_id = '30'
    new_block_name = 'frictionless_slave_subdomain'
  [../]
  [./master]
    input = slave
    type = LowerDBlockFromSidesetGenerator
    sidesets = 'plank_right'
    new_block_id = '20'
    new_block_name = 'frictionless_master_subdomain'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./frictionless_normal_lm]
    order = ${order}
    block = 'frictionless_slave_subdomain'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
  [../]
[]

[Constraints]
  [./lm]
    type = NormalNodalLMMechanicalContact
    slave = block_left
    master = plank_right
    variable = frictionless_normal_lm
    master_variable = disp_x
    disp_y = disp_y
    ncp_function_type = min
    use_displaced_mesh = true
  [../]
  [./normal_x]
    type = NormalMortarMechanicalContact
    master_boundary = plank_right
    slave_boundary = block_left
    master_subdomain = frictionless_master_subdomain
    slave_subdomain = frictionless_slave_subdomain
    variable = frictionless_normal_lm
    slave_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
  [../]
  [./normal_y]
    type = NormalMortarMechanicalContact
    master_boundary = plank_right
    slave_boundary = block_left
    master_subdomain = frictionless_master_subdomain
    slave_subdomain = frictionless_slave_subdomain
    variable = frictionless_normal_lm
    slave_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/test_jacobian/jacobian_test_planestrain.i

# This test is designed to test the jacobian for a single
# element with/without volumetric locking correction.

# The mesh contains one element whose y displacement is zero at
# the bottom surface (y=0) and -1.0 at the top surface (y=1).

# Result: The hand coded jacobian matches well with the finite
# difference jacobian with an error norm in the order of 1e-15
# for total and incremental small strain formulations and with
# an error in the order of 1e-8 for finite strain formulations.

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 1
  ny = 1
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]

  [./y_force]
    type = NeumannBC
    variable = disp_y
    boundary = top
    value = -1.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
    block = 0
  [../]
  [./strain]
    block = 0
  [../]
  [./stress]
    block = 0
  [../]
[]

[Preconditioning]
  active = 'smp'
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient #Transient

  solve_type = NEWTON
  petsc_options = '-snes_check_jacobian -snes_check_jacobian_view'

  l_max_its = 100
  nl_abs_tol = 1e-4
  start_time = 0.0
  num_steps = 1
  dt = 0.005
  dtmin = 0.005
  end_time = 0.005
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/jacobian/cto25.i

# CappedDruckerPrager

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]


[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./phi]
    type = TensorMechanicsHardeningConstant
    value = 0.8
  [../]
  [./psi]
    type = TensorMechanicsHardeningConstant
    value = 0.4
  [../]
  [./dp]
    type = TensorMechanicsPlasticDruckerPragerHyperbolic
    mc_cohesion = mc_coh
    mc_friction_angle = phi
    mc_dilation_angle = psi
    yield_function_tolerance = 1E-11     # irrelevant here
    internal_constraint_tolerance = 1E-9 # irrelevant here
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    lambda = 0.0
    shear_modulus = 1.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '6 5 4  5 7 2  4 2 2'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = dp
  [../]
  [./dp]
    type = CappedDruckerPragerStressUpdate
    DP_model = dp
    tensile_strength = ts
    compressive_strength = cs
    yield_function_tol = 1E-11
    tip_smoother = 1
    smoothing_tol = 1
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/elastic_patch/elastic_patch_rz.i

#
# This problem is taken from the Abaqus verification manual:
#   "1.5.4 Patch test for axisymmetric elements"
# The stress solution is given as:
#   xx = yy = zz = 2000
#   xy = 400
#
# Since the strain is 1e-3 in all three directions, the new density should be
#   new_density = original_density * V_0 / V
#   new_density = 0.283 / (1 + 1e-3 + 1e-3 + 1e-3) = 0.282153

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = elastic_patch_rz.e
[]

[Variables]
  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = SMALL
  incremental = true
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
[]

[Kernels]
  [./body]
    type = BodyForce
    variable = disp_y
    value = 1
    function = '-400/x'
  [../]

  [./heat]
    type = TimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 10
    function = '1e-3*x'
  [../]
  [./uz]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 10
    function = '1e-3*(x+y)'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]

  [./density]
    type = Density
    density = 0.283
    outputs = all
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  end_time = 1.0
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymm_gps_small.i

# this test checks the asixymmetric 1D generalized plane strain formulation using incremental small strains

[GlobalParams]
  displacements = disp_x
  scalar_out_of_plane_strain = scalar_strain_yy
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = line.e
[]

[Variables]
  [./disp_x]
  [../]
  [./scalar_strain_yy]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./temp]
    initial_condition = 580.0
  [../]
[]

[Functions]
  [./temp]
    type = PiecewiseLinear
    x = '0   1   2'
    y = '580 580 680'
  [../]
  [./disp_x]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 2e-6'
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./GeneralizedPlaneStrain]
      [./gps]
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_zz
    index_i = 2
    index_j = 2
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./temp]
    type = FunctionAux
    variable = temp
    function = temp
    execute_on = 'timestep_begin'
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    boundary = 1
    value = 0
    variable = disp_x
  [../]
  [./disp_x]
    type = FunctionDirichletBC
    boundary = 2
    function = disp_x
    variable = disp_x
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 3600
    poissons_ratio = 0.2
  [../]

  [./strain]
    type = ComputeAxisymmetric1DSmallStrain
    eigenstrain_names = eigenstrain
    scalar_out_of_plane_strain = scalar_strain_yy
  [../]

  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-8
    temperature = temp
    stress_free_temperature = 580
    eigenstrain_name = eigenstrain
  [../]

  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  line_search = 'none'

  l_max_its = 50
  l_tol = 1e-6
  nl_max_its = 15
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-10
  start_time = 0
  end_time = 2
  num_steps = 2
[]

[Outputs]
  exodus = true
  console = true
[]

modules/combined/test/tests/contact/4ElemTensionRelease_mechanical_constraint.i

# This is a mechanical constraint (contact formulation) version of 4ElemTensionRelease.i
[Mesh]
  file = 4ElemTensionRelease.e
[]

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Functions]
  [./up]
    type = PiecewiseLinear
    x = '0 1      2 3'
    y = '0 0.0001 0 -.0001'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = SMALL
    generate_output = 'stress_yy'
  []
[]

[Contact]
  [./dummy_name]
    master = 2
    slave = 3
    penalty = 1e6
    model = frictionless
    tangential_tolerance = 0.01
    system = constraint
  [../]
[]

[BCs]
  [./lateral]
    type = DirichletBC
    variable = disp_x
    boundary = '1 4'
    value = 0
  [../]

  [./bottom_up]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = up
  [../]

  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff1_stress]
    type = ComputeLinearElasticStress
    block = '1 2'
  [../]

[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre    boomeramg      101'

  line_search = 'none'
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-10
  l_tol = 1e-4

  l_max_its = 100
  nl_max_its = 10
  dt = 0.2
  dtmin = 0.2
  end_time = 3

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/gravity/gravity_hex20.i

# Gravity Test
#
# This test is designed to exercise the gravity body force kernel.
#
# The mesh for this problem is a rectangular bar 10 units by 1 unit
#   by 1 unit.
#
# The boundary conditions for this problem are as follows.  The
#   displacement is zero on each of side that faces a negative
#   coordinate direction.  The acceleration of gravity is 20.
#
# The material has a Young's modulus of 1e6 and a density of 2.
#
# The analytic solution for the displacement along the bar is:
#
# u(x) = -b*x^2/(2*E)+b*L*x/E
#
# The displacement at x=L is b*L^2/(2*E) = 2*20*10*10/(2*1e6) = 0.002.
#
# The analytic solution for the stress along the bar assuming linear
#   elasticity is:
#
# S(x) = b*(L-x)
#
# The stress at x=0 is b*L = 2*20*10 = 400.
#
# Note:  The simulation does not measure stress at x=0.  The stress
#   is reported at element centers.  The element closest to x=0 sits
#   at x = 1/4 and has a stress of 390.  This matches the linear
#   stress distribution that is expected.  The same situation applies
#   at x = L where the stress is zero analytically.  The nearest
#   element is at x=9.75 where the stress is 10.
#
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  order = SECOND
  family = LAGRANGE
[]

[Mesh]
  file = gravity_hex20_test.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  add_variables = true
  generate_output = 'stress_xx'
[]

[Kernels]
  [./gravity]
    type = Gravity
    variable = disp_x
    value = 20
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 5
    value = 0.0
  [../]
[]

[Materials]
  [./elasticty_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    bulk_modulus = 0.333333333333333e6
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./density]
    type = Density
    density = 2
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  start_time = 0.0
  end_time = 1.0

  [./Quadrature]
    order = THIRD
  [../]
[]

[Outputs]
  file_base = gravity_hex20_out
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_1/cyl1_template2.i

#
# This input file is a template for both the frictionless and glued test
# variations for the current problem geometry. In order to create an input
# file to run outside the runtest framework, look at the tests file and add the
# appropriate input file lines from the cli_args line.
#

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl1_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 1000
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x7 disp_y7 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/plane_1/plane1_template2.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane1_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  maximum_lagrangian_update_iterations = 200
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-9
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x7 disp_y7 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/tensor_mechanics/test/tests/ad_isotropic_elasticity_tensor/bulk_modulus_shear_modulus_test.i

[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./stress_11]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    use_automatic_differentiation = true
  [../]
[]

[AuxKernels]
  [./stress_11]
    type = RankTwoAux
    variable = stress_11
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
  [../]
[]

[BCs]
  [./bottom]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./left]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./back]
    type = ADDirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./top]
    type = ADDirichletBC
    variable = disp_y
    boundary = top
    value = 0.001
  [../]
[]

[Materials]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 416666
    shear_modulus = 454545
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady
  l_max_its = 20
  nl_max_its = 10
  solve_type = NEWTON
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/generalized_plane_strain/generalized_plane_strain_small.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = square.e
[]

[Variables]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy strain_zz'
    planar_formulation = GENERALIZED_PLANE_STRAIN
    eigenstrain_names = eigenstrain
    scalar_out_of_plane_strain = scalar_strain_zz
    temperature = temp
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-4

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-5

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
  num_steps = 5000
[]

[Outputs]
  exodus = true
[]

modules/peridynamics/test/tests/jacobian_check/2D_mechanics_OSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = ORDINARY_STATE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.0
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialOSPD
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1
[]

modules/tensor_mechanics/test/tests/check_error/pressure_component.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = cube.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./2_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./2_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./2_z]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]

  [./fred]
    type = Pressure
    boundary = 4
    component = 123456789
    variable = disp_x
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 1e6
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[]

[Outputs]
  file_base = out
  exodus = true
[]

modules/tensor_mechanics/test/tests/isotropic_elasticity_tensor/youngs_modulus_poissons_ratio_test.i

[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_11]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
  [../]
[]

[AuxKernels]
  [./stress_11]
    type = RankTwoAux
    variable = stress_11
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
  [../]
[]

[BCs]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.001
  [../]
[]

[Materials]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.1
    youngs_modulus = 1e6
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady
  l_max_its = 20
  nl_max_its = 10
  solve_type = NEWTON
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/mortar_tm/2drz/frictionless_first/small.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'small'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./corner]
    type = ExtraNodesetGenerator
    input = block_rename
    coord = '0 -10.0'
    new_boundary = point
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = corner
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
  [../]
  [./plank]
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeLinearElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/2D_different_planes/gps_xz.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = square_xz_plane.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_z]
  [../]
  [./scalar_strain_yy]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./generalized_plane_strain]
    block = 1
    strain = SMALL
    scalar_out_of_plane_strain = scalar_strain_yy
    out_of_plane_direction = y
    planar_formulation = GENERALIZED_PLANE_STRAIN
    eigenstrain_names = 'eigenstrain'
    generate_output = 'stress_xx stress_xz stress_yy stress_zz strain_xx strain_xz strain_yy strain_zz'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 3
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 3
    variable = disp_z
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_stress]
    type = ComputeLinearElasticStress
    block = 1
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
[]

[Postprocessors]
  [./react_y]
    type = MaterialTensorIntegral
    use_displaced_mesh = false
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-10

# controls for nonlinear iterations
  nl_max_its = 10
  nl_rel_tol = 1e-12

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  file_base = gps_xz_small_out
  exodus = true
[]

modules/combined/test/tests/internal_volume/rz.i

#
# Internal Volume Test
#
# This test is designed to compute the internal volume of a space considering
#   an embedded volume inside.
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total volume
#   is 7.
#
[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = meshes/rz.e
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 1e4
  [../]
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    volumetric_locking_correction = true
    incremental = true
    strain = FINITE
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  [../]

  [./Pressure]
    [./fred]
      boundary = 3
      function = pressure
      disp_x = disp_x
      disp_y = disp_y
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK

  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 2
    execute_on = 'initial timestep_end'
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/contact_verification/patch_tests/automatic_patch_update/sliding_update.i

[Mesh]
  file = sliding_update.e
  displacements = 'disp_x disp_y'
  patch_size = 5
  patch_update_strategy = 'iteration'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+4
    model = frictionless
    formulation = penalty
  [../]
[]

[Executioner]
   type = Transient
   solve_type = 'PJFNK'
   start_time = 0
   end_time = 10.0
   l_tol = 1e-8
   nl_rel_tol = 1e-6
   nl_abs_tol = 1e-4
   dt = 2.0
   line_search = 'none'
   petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
   petsc_options_value = 'lu superlu_dist'
   timestep_tolerance = 1e-1
[]

[BCs]
  [./fixed_1_2x]
    type = DirichletBC
    boundary = '1'
    value = 0.0
    variable = disp_x
  [../]
  [./fixed_1_2y]
    type = DirichletBC
    boundary = '1'
    value = 0.0
    variable = disp_y
  [../]
  [./sliding_1]
    type = FunctionDirichletBC
    function = sliding_fn
    variable = disp_x
    boundary = '4'
  [../]
  [./normal_y]
    type = DirichletBC
    variable = disp_y
    boundary = '4'
    value = -0.01
  [../]
#  [./Pressure]
#    [./normal_pressure]
#      disp_x = disp_x
#      disp_y = disp_y
#      factor = 100.0
#      boundary = 4
#    [../]
#  [../]
[]

[Functions]
  [./sliding_fn]
    type = ParsedFunction
    value = 't'
  [../]
[]

[Outputs]
  exodus = true
  perf_graph = true
[]

modules/peridynamics/test/tests/jacobian_check/2D_mechanics_smallstrain_NOSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputePlaneSmallStrainNOSPD
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

modules/combined/test/tests/frictional_contact/sliding_elastic_blocks_2d/sliding_elastic_blocks_2d.i

[Mesh]
  file = sliding_elastic_blocks_2d.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    save_in = 'saved_x saved_y'
    diag_save_in = 'diag_saved_x diag_saved_y'
  [../]
[]

[AuxKernels]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    quantity = incremental_slip_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    quantity = incremental_slip_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip]
    type = PenetrationAux
    variable = accum_slip
    execute_on = timestep_end
    quantity = accumulated_slip
    boundary = 3
    paired_boundary = 2
  [../]
  [./tangential_force_x]
    type = PenetrationAux
    variable = tang_force_x
    execute_on = timestep_end
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./tangential_force_y]
    type = PenetrationAux
    variable = tang_force_y
    execute_on = timestep_end
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.005
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1.0e7
    poissons_ratio = 0.3
  [../]
  [./right]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.01
  end_time = 0.05
  num_steps = 1000
  nl_rel_tol = 1e-16
  nl_abs_tol = 1e-09
  dtmin = 0.01
  l_tol = 1e-3

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  file_base = sliding_elastic_blocks_2d_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = coulomb
    system = constraint
    friction_coefficient = '0.25'
    penalty = 1e6
  [../]
[]

[Dampers]
  [./contact_slip]
    type = ContactSlipDamper
    slave = 3
    master = 2
  [../]
[]

modules/combined/test/tests/gravity/gravity_rz.i

# Gravity Test
#
# This test is designed to exercise the gravity body force rz kernel.
#
# The mesh for this problem is a rectangle 10 units by 1 unit.
#
# The boundary conditions for this problem are as follows.  The
#   displacement is zero at the top.  The acceleration of gravity is 20.
#
# The material has a Young's modulus of 1e6 and a density of 2.
#
# The analytic solution for the displacement along the bar is:
#
# u(y) = -b*y^2/(2*E)+b*L*y/E
#
# The displacement at y=L is b*L^2/(2*E) = 2*20*10*10/(2*1e6) = 0.002.
#
# The analytic solution for the stress along the bar assuming linear
#   elasticity is:
#
# S(y) = b*(L-y)
#
# The stress at x=0 is b*L = 2*20*10 = 400.
#
# Note:  The simulation does not measure stress at y=0.  The stress
#   is reported at element centers.  The element closest to y=0 sits
#   at y = 1/4 and has a stress of 390.  This matches the linear
#   stress distribution that is expected.  The same situation applies
#   at y = L where the stress is zero analytically.  The nearest
#   element is at y=9.75 where the stress is 10.
#
[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = gravity_rz_test.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master/All]
  volumetric_locking_correction = true
  strain = FINITE
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_xy'
[]

[Kernels]
  [./gravity]
    type = Gravity
    variable = disp_y
    value = 20
  [../]
[]

[BCs]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    shear_modulus = 0.5e6
    lambda = 0.0
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./density]
    type = Density
    density = 2
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  start_time = 0.0
  end_time = 1.0
[]

[Outputs]
  file_base = gravity_rz_out
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/tensor_mechanics/test/tests/check_error/youngs_modulus.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = cube.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./2_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./2_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./2_z]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = -1e6
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[]

[Outputs]
  file_base = out
  exodus = true
[]

modules/combined/test/tests/contact/pressurePenalty_mechanical_constraint.i

# This is a mechanical constraint (contact formulation) version of pressurePenalty.i
[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = pressure.e
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = SMALL
    generate_output = 'stress_yy'
  []
[]

[Contact]
  [./m20_s10]
    master = 20
    slave = 10
    penalty = 1e8
    formulation = penalty
    tangential_tolerance = 1e-3
    system = constraint
    tension_release = -1
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]

  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./z]
    type = DirichletBC
    variable = disp_z
    boundary = 5
    value = 0.0
  [../]

  [./Pressure]
    [./press]
      boundary = 7
      factor = 1e3
    [../]
  [../]

  [./down]
    type = DirichletBC
    variable = disp_y
    boundary = 8
    value = -2e-3
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.0
  [../]
  [./stiffStuff1_stress]
    type = ComputeLinearElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'lu       101'

  line_search = 'none'

  nl_rel_tol = 1e-9
  nl_abs_tol = 1e-9

  l_max_its = 100
  nl_max_its = 10
  dt = 1.0
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_2d_mouth_dir.i

#This tests the J-Integral evaluation capability.
#This is a 2d plane strain model
#Crack direction is defined using the crack mouth coordinates.
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack2d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackMouth
  crack_mouth_boundary = 900
  2d = true
  axis_2d = 2
  radius_inner = '4.0 4.5 5.0 5.5 6.0'
  radius_outer = '4.5 5.0 5.5 6.0 6.5'
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]

  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]

  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = j_integral_2d_mouth_dir_out
  exodus = true
  csv = true
[]

modules/combined/test/tests/solid_mechanics/Wave_1_D/Newmark_time_integration/wave_bc_1d.i

# Wave propogation in 1-D using Newmark time integration
#
# The test is for an 1-D bar element of length 4m  fixed on one end
# with a sinusoidal pulse dirichlet boundary condition applied to the other end.
# beta and gamma are Newmark time integration parameters
# The equation of motion in terms of matrices is:
#
# M*accel +  K*disp = 0
#
# Here M is the mass matrix, K is the stiffness matrix
#
# This equation is equivalent to:
#
# density*accel + Div Stress= 0
#
# The first term on the left is evaluated using the Inertial force kernel
# The last term on the left is evaluated using StressDivergenceTensors
#
# The displacement at the second, third and fourth node at t = 0.1 are
# -8.021501116638234119e-02, 2.073994362053969628e-02 and  -5.045094181261772920e-03, respectively
[GlobalParams]
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 4
  nz = 1
  xmin = 0.0
  xmax = 0.1
  ymin = 0.0
  ymax = 4.0
  zmin = 0.0
  zmax = 0.1
[]

[AuxVariables]
  [./vel_x]
  [../]
  [./accel_x]
  [../]
  [./vel_y]
  [../]
  [./accel_y]
  [../]
  [./vel_z]
  [../]
  [./accel_z]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  []
[]


[Kernels]
 [./inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    use_displaced_mesh = false
    beta = 0.3025
    gamma = 0.6
    eta = 0
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    use_displaced_mesh = false
    beta = 0.3025
    gamma = 0.6
    eta = 0
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    use_displaced_mesh = false
    beta = 0.3025
    gamma = 0.6
    eta = 0
  [../]

[]

[AuxKernels]
  [./accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.6
    execute_on = timestep_end
  [../]
  [./accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.6
    execute_on = timestep_end
  [../]
  [./accel_z]
    type = NewmarkAccelAux
    variable = accel_z
    displacement = disp_z
    velocity = vel_z
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./vel_z]
    type = NewmarkVelAux
    variable = vel_z
    acceleration = accel_z
    gamma = 0.6
    execute_on = timestep_end
  [../]
[]


[BCs]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value=0.0
  [../]
  [./top_x]
   type = DirichletBC
    variable = disp_x
    boundary = top
    value=0.0
  [../]
  [./top_z]
    type = DirichletBC
    variable = disp_z
    boundary = top
    value=0.0
  [../]
  [./right_x]
   type = DirichletBC
    variable = disp_x
    boundary = right
    value=0.0
  [../]
  [./right_z]
    type = DirichletBC
    variable = disp_z
    boundary = right
    value=0.0
  [../]
  [./left_x]
   type = DirichletBC
    variable = disp_x
    boundary = left
    value=0.0
  [../]
  [./left_z]
    type = DirichletBC
    variable = disp_z
    boundary = left
    value=0.0
  [../]
  [./front_x]
   type = DirichletBC
    variable = disp_x
    boundary = front
    value=0.0
  [../]
  [./front_z]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value=0.0
  [../]
  [./back_x]
   type = DirichletBC
    variable = disp_x
    boundary = back
    value=0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value=0.0
  [../]
    [./bottom_x]
      type = DirichletBC
      variable = disp_x
      boundary = bottom
      value=0.0
    [../]
    [./bottom_z]
      type = DirichletBC
      variable = disp_z
      boundary = bottom
      value=0.0
    [../]
    [./bottom_y]
      type = FunctionDirichletBC
      variable = disp_y
      boundary = bottom
      function = displacement_bc
    [../]
[]

[Materials]
  [./constant]
    type = ComputeIsotropicElasticityTensor
    block = '0'
    youngs_modulus = 1.0
    poissons_ratio = 0.0
  [../]
  [./constant_stress]
    type = ComputeFiniteStrainElasticStress
    block = '0'
  [../]
  [./density]
    type = GenericConstantMaterial
    block = '0'
    prop_names = 'density'
    prop_values = '1'
  [../]
[]


[Executioner]

  type = Transient
  start_time = 0
  end_time = 6.0
  dtmax = 0.1
  dtmin = 0.1
  l_tol = 1e-12
  nl_rel_tol = 1e-12
  [./TimeStepper]
    type = ConstantDT
    dt = 0.1
  [../]

[]


[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0.0 0.1 0.2 1.0 2.0 5.0'
    y = '0.0 0.001 1 0.001 0.0 0.0'
    scale_factor = 7750
  [../]
  [./displacement_ic]
    type = PiecewiseLinear
    axis = y
    x = '0.0 0.3 0.4 0.5 0.6 0.7 1.0'
    y = '0.0 0.0 0.0001 1.0 0.0001 0.0 0.0'
    scale_factor = 0.1
  [../]
  [./displacement_bc]
    type = PiecewiseLinear
    data_file = 'sine_wave.csv'
    format = columns
  [../]

[]

[Postprocessors]
   [./_dt]
     type = TimestepSize
   [../]
    [./disp_1]
       type = NodalVariableValue
       nodeid = 1
       variable = disp_y
     [../]
    [./disp_2]
       type = NodalVariableValue
       nodeid = 3
       variable = disp_y
     [../]
    [./disp_3]
       type = NodalVariableValue
       nodeid = 10
       variable = disp_y
     [../]
    [./disp_4]
       type = NodalVariableValue
       nodeid = 14
       variable = disp_y
     [../]
[]

[Outputs]
  exodus = true
  print_linear_residuals = true
  perf_graph = true
[]

modules/combined/test/tests/glued_contact/glued_contact_test.i

[Mesh]
  file = glued_contact_test.e
[]

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./up]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.5001'
  [../]

  [./lateral]
    type = PiecewiseLinear
    x = '0 1 2 3'
    y = '0 0 1 0'
    scale_factor = 0.5
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[Contact]
  [./dummy_name]
    master = 2
    slave = 3
    penalty = 1e6
    model = glued
    formulation = kinematic
    system = Constraint
  [../]
[]

[BCs]
  [./bottom_lateral]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 1
    function = lateral
  [../]

  [./bottom_up]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = up
  [../]

  [./bottom_out]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff1_strain]
    type= ComputeFiniteStrain
    block = '1'
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]

  [./stiffStuff2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff2_strain]
    type= ComputeFiniteStrain
    block = '2'
  [../]
  [./stiffStuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  #petsc_options_iname = '-pc_type -pc_hypre_type -snes_type -snes_ls -snes_linesearch_type -ksp_gmres_restart'
  #petsc_options_value = 'hypre    boomeramg      ls         basic    basic                    101'
  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'ilu      101'

  line_search = 'none'

  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-8
  l_tol = 1e-4

  l_max_its = 100
  nl_max_its = 10
  dt = 0.1
  num_steps = 30

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Postprocessors]
  active = ''
  [./resid]
    type = Residual
  [../]
  [./iters]
    type = NumNonlinearIterations
  [../]
[]

[Outputs]
  file_base = out
  exodus = true
[]

modules/combined/test/tests/solid_mechanics/hoop_stress/hoop_stress.i

#
# Hoop stress
#
# This test checks that hoop stress is calculated correctly for three orientations.
# 1. A hoop centered at (20,20,20) with vector (0,0,1)
# 2. A hoop centered at (-25,20,20) with vector (0,1,0)
# 3. A hoop centered at (-20,-20,20) with vector (1,0,0)
# All three have radius = 20, t = 1.
#
# Hoop stress should be P*r/t -> 1e3*20/1 = 20e3
#
# The output hoop stress is close to this value (nonlinear geometry is on) for all
# elements.
#

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  order = FIRST
  family = LAGRANGE
[]

[Mesh]
  file = hoops.e
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 1e3
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]

  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./hoop1]
    order = CONSTANT
    family = MONOMIAL
    block = 1
  [../]
  [./hoop2]
    order = CONSTANT
    family = MONOMIAL
    block = 2
  [../]
  [./hoop3]
    order = CONSTANT
    family = MONOMIAL
    block = 3
  [../]
  [./radial1]
    order = CONSTANT
    family = MONOMIAL
    block = 1
  [../]
  [./radial2]
    order = CONSTANT
    family = MONOMIAL
    block = 2
  [../]
  [./radial3]
    order = CONSTANT
    family = MONOMIAL
    block = 3
  [../]
  [./axial1]
    order = CONSTANT
    family = MONOMIAL
    block = 1
  [../]
  [./axial2]
    order = CONSTANT
    family = MONOMIAL
    block = 2
  [../]
  [./axial3]
    order = CONSTANT
    family = MONOMIAL
    block = 3
  [../]

[] # AuxVariables

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
    execute_on = timestep_end
  [../]
  [./stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zx
    index_i = 2
    index_j = 0
    execute_on = timestep_end
  [../]
  [./hoop1]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = HoopStress
    variable = hoop1
    block = 1
    point1 = '20 20 -4'
    point2 = '20 20 47'
    execute_on = timestep_end
  [../]
  [./hoop2]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = HoopStress
    variable = hoop2
    block = 2
    point1 = '-25 12 20'
    point2 = '-25 10 20'
    execute_on = timestep_end
  [../]
  [./hoop3]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = HoopStress
    variable = hoop3
    block = 3
    point1 = '0 -20 20'
    point2 = '16 -20 20'
    execute_on = timestep_end
  [../]
  [./radial1]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = RadialStress
    variable = radial1
    block = 1
    point1 = '20 20 -4'
    point2 = '20 20 47'
    execute_on = timestep_end
  [../]
  [./radial2]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = RadialStress
    variable = radial2
    block = 2
    point1 = '-25 12 20'
    point2 = '-25 10 20'
    execute_on = timestep_end
  [../]
  [./radial3]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = RadialStress
    variable = radial3
    block = 3
    point1 = '0 -20 20'
    point2 = '16 -20 20'
    execute_on = timestep_end
  [../]
  [./axial1]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = AxialStress
    variable = axial1
    block = 1
    point1 = '20 20 -4'
    point2 = '20 20 47'
    execute_on = timestep_end
  [../]
  [./axial2]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = AxialStress
    variable = axial2
    block = 2
    point1 = '-25 12 20'
    point2 = '-25 10 20'
    execute_on = timestep_end
  [../]
  [./axial3]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = AxialStress
    variable = axial3
    block = 3
    point1 = '0 -20 20'
    point2 = '16 -20 20'
    execute_on = timestep_end
  [../]

[] # AuxKernels

[BCs]

  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = '300 11'
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = '200 12'
    value = 0
  [../]
  [./fix_z]
    type = DirichletBC
    variable = disp_z
    boundary = '100 13'
    value = 0
  [../]

  [./Pressure]
    [./internal_pressure]
      boundary = 1
      function = pressure
      disp_x = disp_x
      disp_y = disp_y
      disp_z = disp_z
    [../]
  [../]

[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.35
    block = '1 2 3'
  [../]
  [./small_strain]
    type = ComputeIncrementalSmallStrain
    block = '1 2 3'
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2 3'
  [../]
[] # Materials

[Executioner]

  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'


  petsc_options = '-snes_ksp_ew -ksp_gmres_modifiedgramschmidt'
  petsc_options_iname = '-ksp_gmres_restart -pc_type  -pc_hypre_type'
  petsc_options_value = '201                 hypre     boomeramg'


  line_search = 'none'

  l_tol = 1e-8
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-14

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 1
  end_time = 1.0
[] # Executioner

[Outputs]
  exodus = true
  file_base = hoop_stress_out
[] # Outputs

modules/combined/test/tests/contact_verification/patch_tests/plane_4/plane4_mu_0_2_pen.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane4_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-7
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = plane4_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = plane4_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x9 disp_y9 disp_x16 disp_y16 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/tutorials/basics/part_2.2.i

#Tensor Mechanics tutorial: the basics
#Step 2, part 2
#2D axisymmetric RZ simulation of uniaxial tension with finite strain elasticity

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = necking_quad4.e
  uniform_refine = 1
  second_order = true
[]

[Modules/TensorMechanics/Master]
  [./block1]
    strain = FINITE #change to use finite strain instead of small linearized strain class
    add_variables = true #detects the change of the mesh to second order and automatically sets the variables
    generate_output = 'stress_zz vonmises_stress'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]
  [./top]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = top
    function = '0.0007*t'
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  end_time = 5

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -sub_pc_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm lu 1 101'
[]

[Outputs]
  exodus = true
  perf_graph = true
[]

modules/combined/test/tests/axisymmetric_2d3d_solution_function/3dy.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  disp_x = disp_x
  disp_y = disp_y
  disp_z = disp_z
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = 3dy.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
  [./hoop_stress]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[UserObjects]
  [./soln]
    type = SolutionUserObject
    mesh = 2d_out.e
    system_variables = 'disp_x disp_y temp'
  [../]
[]

[Functions]
  [./soln_func_temp]
    type = Axisymmetric2D3DSolutionFunction
    solution = soln
    from_variables = 'temp'
  [../]
  [./soln_func_disp_x]
    type = Axisymmetric2D3DSolutionFunction
    solution = soln
    from_variables = 'disp_x disp_y'
    component = 0
  [../]
  [./soln_func_disp_y]
    type = Axisymmetric2D3DSolutionFunction
    solution = soln
    from_variables = 'disp_x disp_y'
    component = 1
  [../]
  [./soln_func_disp_z]
    type = Axisymmetric2D3DSolutionFunction
    solution = soln
    from_variables = 'disp_x disp_y'
    component = 2
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    volumetric_locking_correction = true
    add_variables  = true
    incremental = true
    strain = FINITE
    eigenstrain_names = thermal_expansion
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress'
  [../]
[]

[AuxKernels]
  [./t_soln_aux]
    type = FunctionAux
    variable = temp
    block = '1 2'
    function = soln_func_temp
  [../]
  [./hoop_stress]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = hoop_stress
    scalar_type = HoopStress
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./x_soln_bc]
    type = FunctionDirichletBC
    variable = disp_x
    preset = false
    boundary = '1 2'
    function = soln_func_disp_x
  [../]
  [./y_soln_bc]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = '1 2'
    function = soln_func_disp_y
  [../]
  [./z_soln_bc]
    type = FunctionDirichletBC
    variable = disp_z
    preset = false
    boundary = '1 2'
    function = soln_func_disp_z
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 193.05e9
    poissons_ratio = 0.3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]

  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    block = '1 2'
    thermal_expansion_coeff = 13e-6
    stress_free_temperature = 295.00
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]

  [./density]
    type = Density
    block = '1'
    density = 8000.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-ksp_snes_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = ' 201                hypre    boomeramg      4'
  line_search = 'none'
  l_max_its = 25
  nl_max_its = 20
  nl_rel_tol = 1e-10
  l_tol = 1e-2

  start_time = 0.0
  dt = 1
  end_time = 1
  dtmin = 1
[]

[Outputs]
  file_base = 3dy_out
  exodus = true
  [./console]
    type = Console
    max_rows = 25
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update14.i

# MC update version, with only Compressive with compressive strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-2 1 -0.5  -1 -1.9 0  -0.5 0 -3'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/ad_elastic/rspherical_small_elastic-noad.i

[Mesh]
  type = GeneratedMesh
  dim = 1
  nx = 5
[]

[Problem]
  coord_type = RSPHERICAL
[]

[GlobalParams]
  displacements = 'disp_r'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = StressDivergenceRSphericalTensors
    component = 0
    variable = disp_r
  [../]
[]

[BCs]
  [./center]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
  [./strain]
    type = ComputeRSphericalSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
  nl_max_its = 200
[]

[Outputs]
  exodus = true
  file_base = rspherical_small_elastic_out
[]

modules/tensor_mechanics/test/tests/check_error/poissons_ratio.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = cube.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./2_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./2_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./2_z]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.6
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[]

[Outputs]
  file_base = out
  exodus = true
[]

modules/combined/test/tests/sliding_block/in_and_out/constraint/frictional_02_penalty.i

#  This is a benchmark test that checks constraint based frictional
#  contact using the penalty method.  In this test a sinusoidal
#  displacement is applied in the horizontal direction to simulate
#  a small block come in and out of contact as it slides down a larger block.
#
#  The sinusoid is of the form 0.4sin(4t)+0.2 and a friction coefficient
#  of 0.2 is used.  The gold file is run on one processor and the benchmark
#  case is run on a minimum of 4 processors to ensure no parallel variability
#  in the contact pressure and penetration results.  Further documentation can
#  found in moose/modules/contact/doc/sliding_block/
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
  [./horizontal_movement]
    type = ParsedFunction
    value = -0.04*sin(4*t)+0.02
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./left_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -sub_pc_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm     lu    20    101'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 15
  num_steps = 1000
  l_tol = 1e-3
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-6
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = coulomb
    penalty = 1e+7
    friction_coefficient = 0.2
    formulation = penalty
    system = constraint
    normal_smoothing_distance = 0.1
  [../]
[]

modules/tensor_mechanics/test/tests/ad_elastic/rspherical_finite_elastic.i

[Mesh]
  type = GeneratedMesh
  dim = 1
  nx = 5
[]

[Problem]
  coord_type = RSPHERICAL
[]

[GlobalParams]
  displacements = 'disp_r'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = ADStressDivergenceRSphericalTensors
    component = 0
    variable = disp_r
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./center]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeRSphericalFiniteStrain
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymmetric_gps_finite.i

#
# This test checks the generalized plane strain using finite strain formulation.
# since we constrain all the nodes against movement and the applied thermal strain
# is very small, the results are the same as small and incremental small strain formulations
#

[GlobalParams]
  displacements = disp_x
  scalar_out_of_plane_strain = scalar_strain_yy
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = lines.e
[]

[Variables]
  [./disp_x]
  [../]
  [./temp]
    initial_condition = 580.0
  [../]
  [./scalar_strain_yy]
    order = FIRST
    family = SCALAR
  [../]
[]

[Functions]
  [./temp100]
    type = PiecewiseLinear
    x = '0   1'
    y = '580 680'
  [../]
  [./temp300]
    type = PiecewiseLinear
    x = '0   1'
    y = '580 880'
  [../]
[]

[Kernels]
  [./heat]
    type = Diffusion
    variable = temp
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./gps]
        planar_formulation = GENERALIZED_PLANE_STRAIN
        scalar_out_of_plane_strain = scalar_strain_yy
        strain = FINITE
        generate_output = 'strain_xx strain_yy strain_zz stress_xx stress_yy stress_zz'
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    boundary = 1000
    value = 0
    variable = disp_x
  [../]
  [./temp100]
    type = FunctionDirichletBC
    variable = temp
    function = temp100
    boundary = 2
  [../]
  [./temp300]
    type = FunctionDirichletBC
    variable = temp
    function = temp300
    boundary = 3
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 3600
    poissons_ratio = 0.2
  [../]

  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-8
    temperature = temp
    stress_free_temperature = 580
    eigenstrain_name = eigenstrain
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  line_search = 'none'

  l_max_its = 50
  l_tol = 1e-08
  nl_max_its = 15
  nl_abs_tol = 1e-10
  start_time = 0
  end_time = 1
  num_steps = 1
[]

[Outputs]
  exodus = true
  console = true
[]

modules/combined/test/tests/evolving_mass_density/expand_compress_test_tensors.i

#  Element mass tests

#  This series of tests is designed to compute the mass of elements based on
#  an evolving mass density calculation.  The tests consist of expansion and compression
#  of the elastic patch test model along each axis, uniform expansion and compression,
#  and shear in each direction.  The expansion and compression tests change the volume of
#  the elements.  The corresponding change in density should compensate for this so the
#  mass remains constant.  The shear tests should not result in a volume change, and this
#  is checked too.  The mass calculation is done with the post processor called Mass.

#  The tests/file names are as follows:

#  Expansion and compression along a single axis
#  expand_compress_x_test_out.e
#  expand_compress_y_test_out.e
#  expand_compress_z_test_out.e

#  Volumetric expansion and compression
#  uniform_expand_compress_test.i

#  Zero volume change shear along each axis
#  shear_x_test_out.e
#  shear_y_test_out.e
#  shear_z_test_out.e

#  The resulting mass calculation for these tests should always be = 1.

# This test is a duplicate of the uniform_expand_compress_test.i test for solid mechanics, and the
#   output of this tensor mechanics test is compared to the original
#   solid mechanics output.  The duplication is necessary to test the
#   migrated tensor mechanics version while maintaining tests for solid mechanics.

[Mesh]
  file = elastic_patch.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  order = FIRST
  family = LAGRANGE
[]

[Functions]
  [./rampConstant1]
    type = PiecewiseLinear
    x = '0.00 1.00  2.0   3.00'
    y = '0.00 0.25  0.0  -0.25'
    scale_factor = 1
  [../]
[] # Functions

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./bot_x]
    type = DirichletBC
    variable = disp_x
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    value = 0
  [../]
  [./bot_z]
    type = DirichletBC
    variable = disp_z
    value = 0
  [../]
  [./top]
    type = FunctionDirichletBC
    preset = false
    function = rampConstant1
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2 3 4 5 6 7'
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]

  [./small_strain]
    type = ComputeSmallStrain
    block = ' 1 2 3 4 5 6 7'
  [../]

  [./elastic_stress]
    type = ComputeLinearElasticStress
    block = '1 2 3 4 5 6 7'
  [../]
[]

[Executioner]

  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10
  l_max_its = 20
  start_time = 0.0
  dt = 1.0
  num_steps = 3
  end_time = 3.0
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

[Postprocessors]
  [./Mass]
    type = Mass
    variable = disp_x
    execute_on = 'initial timestep_end'
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_2/brick2_template2.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick2_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_x26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_x
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./disp_y26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5

[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x7 disp_y7 disp_x26 disp_y26 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+7
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/combined/test/tests/contact_verification/hertz_cyl/half_symm_q4/hertz_cyl_half_1deg_template3.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_half_1deg.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 11.'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 1. 11.'
    y = '0. 0.0 0.0014'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    extra_vector_tags = 'ref'
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./disp_x226]
    type = NodalVariableValue
    nodeid = 225
    variable = disp_x
  [../]
  [./disp_y226]
    type = NodalVariableValue
    nodeid = 225
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disp_ramp_vert
  [../]
  [./top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = disp_ramp_horz
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
  [./stuff5_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '5'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff5_strain]
    type = ComputeFiniteStrain
    block = '5'
  [../]
  [./stuff5_stress]
    type = ComputeFiniteStrainElasticStress
    block = '5'
  [../]
  [./stuff6_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '6'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff6_strain]
    type = ComputeFiniteStrain
    block = '6'
  [../]
  [./stuff6_stress]
    type = ComputeFiniteStrainElasticStress
    block = '6'
  [../]
  [./stuff7_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '7'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff7_strain]
    type = ComputeFiniteStrain
    block = '7'
  [../]
  [./stuff7_stress]
    type = ComputeFiniteStrainElasticStress
    block = '7'
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 200

  start_time = 0.0
  end_time = 2.0
  l_tol = 5e-4
  dt = 0.1
  dtmin = 0.1
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./chkfile2]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x226 disp_y226 top_react_x top_react_y'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    master = 2
    slave = 3
    disp_x = disp_x
    disp_y = disp_y
    model = coulomb
    friction_coefficient = 0.0
    system = constraint
    formulation = penalty
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

[Dampers]
  [./contact_slip]
    type = ContactSlipDamper
    master = '2'
    slave = '3'
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/cwp11.i

# Capped weak-plane plasticity
# checking jacobian for shear + tensile failure with hardening
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 2
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 0.5
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.05
    rate = 3
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 100
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0
    internal_0 = -2
    internal_limit = 0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 0  0 0 1  0 1 -1.5'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 0
    smoothing_tol = 1
    yield_function_tol = 1E-10
    perfect_guess = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/porous_flow/examples/tidal/earth_tide_fullsat.i

# A confined aquifer is fully saturated with water
# Earth tides apply strain to the aquifer and the resulting porepressure changes are recorded
#
# To replicate standard poroelasticity exactly:
# (1) the PorousFlowBasicTHM Action is used;
# (2) multiply_by_density = false;
# (3) PorousFlowConstantBiotModulus is used
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = 0
  xmax = 1
  ymin = 0
  ymax = 1
  zmin = 0
  zmax = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  PorousFlowDictator = dictator
  block = 0
  biot_coefficient = 0.6
  multiply_by_density = false
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./porepressure]
  [../]
[]

[BCs]
  [./strain_x]
    type = FunctionDirichletBC
    variable = disp_x
    function = earth_tide_x
    boundary = 'left right'
  [../]
  [./strain_y]
    type = FunctionDirichletBC
    variable = disp_y
    function = earth_tide_y
    boundary = 'bottom top'
  [../]
  [./strain_z]
    type = FunctionDirichletBC
    variable = disp_z
    function = earth_tide_z
    boundary = 'back front'
  [../]
[]

[Functions]
  [./earth_tide_x]
    type = ParsedFunction
    value = 'x*1E-8*(5*cos(t*2*pi) + 2*cos((t-0.5)*2*pi) + 1*cos((t+0.3)*0.5*pi))'
  [../]
  [./earth_tide_y]
    type = ParsedFunction
    value = 'y*1E-8*(7*cos(t*2*pi) + 4*cos((t-0.3)*2*pi) + 7*cos((t+0.6)*0.5*pi))'
  [../]
  [./earth_tide_z]
    type = ParsedFunction
    value = 'z*1E-8*(7*cos((t-0.5)*2*pi) + 4*cos((t-0.8)*2*pi) + 7*cos((t+0.1)*4*pi))'
  [../]
[]

[Modules]
  [./FluidProperties]
    [./the_simple_fluid]
      type = SimpleFluidProperties
      bulk_modulus = 2E9
    [../]
  [../]
[]

[PorousFlowBasicTHM]
  coupling_type = HydroMechanical
  displacements = 'disp_x disp_y disp_z'
  porepressure = porepressure
  gravity = '0 0 0'
  fp = the_simple_fluid
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 10.0E9 # drained bulk modulus
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./porosity]
    type = PorousFlowPorosityConst # only the initial value of this is ever used
    porosity = 0.1
  [../]
  [./biot_modulus]
    type = PorousFlowConstantBiotModulus
    solid_bulk_compliance = 1E-10
    fluid_bulk_modulus = 2E9
  [../]
  [./permeability]
    type = PorousFlowPermeabilityConst
    permeability = '1E-12 0 0   0 1E-12 0   0 0 1E-12'
  [../]
[]

[Postprocessors]
  [./pp]
    type = PointValue
    point = '0.5 0.5 0.5'
    variable = porepressure
  [../]
[]


[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  dt = 0.01
  end_time = 2
[]

[Outputs]
  console = true
  csv = true
[]

modules/tensor_mechanics/test/tests/ad_elastic/rz_finite_elastic.i

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 3
  ny = 3
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = ADStressDivergenceRZTensors
    component = 0
    variable = disp_r
    use_displaced_mesh = true
  [../]
  [./stress_z]
    type = ADStressDivergenceRZTensors
    component = 1
    variable = disp_z
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./bottom]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0
  [../]
  [./axial]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeAxisymmetricRZFiniteStrain
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/torque_reaction/torque_reaction_tm.i

# Scalar torque reaction

# This test computes the sum of the torques acting on a ten element 2D bar mesh
# and is intended to replicate the classical wrench problem from statics.
# A displacement in the y along the right face is applied to the bar end to create
# a shear force along the bar end. The rotation origin default (the global origin)
# and the axis of rotation direction vector used to compute the torque reaction
# is set to (0, 0, 1) out of the plane.
# Torque is calculated for the two nodes on the left of the bar. For the bottom
# node on the right, the torque/ moment lever is the x coordinate value, and for
# the top node on the right the torque lever is the hypotenuse of the x and y
# coordinates.  The expected sum of the torque reaction is just over 37.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 1
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = left
    value = 0.0
  [../]
  [./right_shear_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = right
    function = '0.001*t'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./small_strain]
    type = ComputeSmallStrain
    block = 0
  [../]
  [./elastic_stress]
    type = ComputeLinearElasticStress
    block = 0
  [../]
[]

[Executioner]
  type = Transient

  line_search = 'none'

  l_max_its = 30
  nl_max_its = 20
  nl_abs_tol = 1e-12
  nl_rel_tol = 1e-10
  l_tol = 1e-8

  start_time = 0.0
  dt = 0.5

  end_time = 1
  num_steps = 2
[]

[Postprocessors]
  [./_dt]
    type = TimestepSize
  [../]
  [./torque]
    type = TorqueReaction
    boundary = right
    reaction_force_variables = 'saved_x saved_y'
    direction_vector = '0. 0. 1.'
  [../]
[]

[Outputs]
  file_base = torque_reaction_tm_out
  exodus = true
[]

modules/combined/test/tests/beam_eigenstrain_transfer/subapp_err_2.i

# SubApp with 2D model to test multi app vectorpostprocessor to aux var transfer

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 5
  xmin = 0.0
  xmax = 0.5
  ymin = 0.0
  ymax = 0.150080
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./temp]
  [../]
  [./axial_strain]
    order = FIRST
    family = MONOMIAL
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t*(500.0)+300.0
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        strain = SMALL
        incremental = true
        add_variables = true
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
  [../]
  [./axial_strain]
    type = RankTwoAux
    variable = axial_strain
    rank_two_tensor = total_strain
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 298
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  l_tol = 1e-9

  start_time = 0.0
  end_time = 0.075
  dt = 0.0125
  dtmin = 0.0001
[]

[Outputs]
  csv = true
  exodus = true
[]

[VectorPostprocessors]
  [./axial_str]
    type = LineValueSampler
    start_point = '0.5 0.0 0.0'
    end_point = '0.5 0.150080 0.0'
    variable = 'axial_strain axial_strain'
    num_points = 21
    sort_by = 'y'
  [../]
[]

[Postprocessors]
  [./end_disp]
    type = PointValue
    variable = disp_y
    point = '0.5 0.150080 0.0'
  [../]
[]

modules/combined/test/tests/solid_mechanics/HHT_time_integrator/one_element_b_0_3025_g_0_6_cubic.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = one_element.e
[]

[Variables]
  [./disp_x]
  [../]

  [./disp_y]
  [../]

  [./disp_z]
  [../]

[]

[AuxVariables]
  [./vel_x]
  [../]
  [./vel_y]
  [../]
  [./vel_z]
  [../]
  [./accel_x]
  [../]
  [./accel_y]
  [../]
  [./accel_z]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  []
[]

[Kernels]
  [./inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.3025
    gamma = 0.6
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.3025
    gamma = 0.6
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    beta = 0.3025
    gamma = 0.6
  [../]
[]

[AuxKernels]
  [./accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./accel_z]
    type = NewmarkAccelAux
    variable = accel_z
    displacement = disp_z
    velocity = vel_z
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.6
    execute_on = timestep_end
  [../]
  [./vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.6
    execute_on = timestep_end
  [../]
  [./vel_z]
    type = NewmarkVelAux
    variable = vel_z
    acceleration = accel_z
    gamma = 0.6
    execute_on = timestep_end
  [../]
[]


[BCs]
  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./top_z]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]

  [./top_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]

  [./top_y]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = 2
    function = pull
  [../]

[]

[Materials]

  [./constant]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1.26e6
    poissons_ratio = .33
  [../]
  [./constant_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]

  [./density]
    type = GenericConstantMaterial
    block = 1
    prop_names = 'density'
    prop_values = '0.00023832'
  [../]

[]


[Executioner]

  type = Transient
  # PETSC options
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'
  line_search = 'none'

  start_time = 0
  end_time = 1
  dtmax = 0.1
  dtmin = 0.1

  # control for adaptive time steping
  [./TimeStepper]
    type = ConstantDT
    dt = 0.1
  [../]

[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x = '0.0 0.1      0.2     0.3    0.4        0.5      0.6   0.7      0.8    0.9    1.0'
    y = '0.0 0.000167 0.00133 0.0045 0.010667   0.020833 0.036 0.057167 0.0853 0.1215 0.16667'
    scale_factor = 1
  [../]
[]

[Postprocessors]
   [./_dt]
     type = TimestepSize
   [../]
   [./nonlinear_its]
     type = NumNonlinearIterations
   [../]

[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/plane_3/plane3_template2.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane3_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  maximum_lagrangian_update_iterations = 200
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu       superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-8
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x11 disp_y11 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_2/brick2_mu_0_2_pen.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick2_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
  [./tang_force_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_x26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_x
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./disp_y26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5

[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  file_base = brick2_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = brick2_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x7 disp_y7 disp_x26 disp_y26 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+7
  [../]
[]

modules/tensor_mechanics/test/tests/eigenstrain/reducedOrderRZLinear.i

#
# This test checks whether the ComputeReducedOrderEigenstrain is functioning properly.
#
# If instead of 'reduced_eigenstrain', 'thermal_eigenstrain' is given to
# eigenstrain_names in the Modules/TensorMechanics/Master/all block, the output will be
# quite different.
#
# Open the reducedOrderRZLinear_out_hydro_0001.csv file and plot the hydro variables as
# a function of x.  For the reduced order case, the values are smooth across each of the
# two elements with a jump upward from the left element to the right element.  However,
# when not using 'reduced_order_eigenstrain', a jump downward appears from the left
# element to the right element.
#

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 1
  xmax = 3
  xmin = 1
  ymax = 1
  ymin = 0
  #second_order = true
[]

[Functions]
  [./tempLinear]
    type = ParsedFunction
    value = '715-5*x'
  [../]
  [./tempQuadratic]
    type = ParsedFunction
    value = '2.5*x*x-15*x+722.5'
  [../]
  [./tempCubic]
    type = ParsedFunction
    value = '-1.25*x*x*x+11.25*x*x-33.75*x+733.75'
  [../]
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
    initial_condition = 700
  [../]
[]

[AuxVariables]
  [./hydro_constant]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./hydro_first]
    order = FIRST
    family = MONOMIAL
  [../]
  [./hydro_second]
    order = SECOND
    family = MONOMIAL
  [../]
  [./sxx_constant]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./sxx_first]
    order = FIRST
    family = MONOMIAL
  [../]
  [./sxx_second]
    order = SECOND
    family = MONOMIAL
  [../]
  [./szz_constant]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./szz_first]
    order = FIRST
    family = MONOMIAL
  [../]
  [./szz_second]
    order = SECOND
    family = MONOMIAL
  [../]
  [./temp2]
    order = FIRST
    family = LAGRANGE
    initial_condition = 700
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        add_variables = true
        strain = SMALL
        incremental = true
        temperature = temp2
        eigenstrain_names = 'reduced_eigenstrain' #'thermal_eigenstrain'
      [../]
    [../]
  [../]
[]

[Kernels]
  [./heat]
    type = Diffusion
    variable = temp
  [../]
[]

[AuxKernels]
  [./hydro_constant_aux]
    type = RankTwoScalarAux
    variable = hydro_constant
    rank_two_tensor = stress
    scalar_type = Hydrostatic
  [../]
  [./hydro_first_aux]
    type = RankTwoScalarAux
    variable = hydro_first
    rank_two_tensor = stress
    scalar_type = Hydrostatic
  [../]
  [./hydro_second_aux]
    type = RankTwoScalarAux
    variable = hydro_second
    rank_two_tensor = stress
    scalar_type = Hydrostatic
  [../]
  [./sxx_constant_aux]
    type = RankTwoAux
    variable = sxx_constant
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  [../]
  [./sxx_first_aux]
    type = RankTwoAux
    variable = sxx_first
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  [../]
  [./sxx_second_aux]
    type = RankTwoAux
    variable = sxx_second
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  [../]
  [./szz_constant_aux]
    type = RankTwoAux
    variable = szz_constant
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
  [./szz_first_aux]
    type = RankTwoAux
    variable = szz_first
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
  [./szz_second_aux]
    type = RankTwoAux
    variable = szz_second
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
  [./temp2]
    type = FunctionAux
    variable = temp2
    function = tempLinear
    execute_on = timestep_begin
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom top'
    value = 0.0
  [../]

  [./temp_right]
    type = DirichletBC
    variable = temp
    boundary = right
    value = 700
  [../]
  [./temp_left]
    type = DirichletBC
    variable = temp
    boundary = left
    value = 710
  [../]
[]


[Materials]
  [./fuel_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0
  [../]
  [./fuel_thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1
    temperature = temp2
    stress_free_temperature = 700.0
    eigenstrain_name = 'thermal_eigenstrain'
  [../]
  [./reduced_order_eigenstrain]
    type = ComputeReducedOrderEigenstrain
    input_eigenstrain_names = 'thermal_eigenstrain'
    eigenstrain_name = 'reduced_eigenstrain'
  [../]
[]


[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew '
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type'
  petsc_options_value = '70 hypre boomeramg'

  num_steps = 1
  nl_rel_tol = 1e-8 #1e-12
[]

[Postprocessors]
  [./_dt]
    type = TimestepSize
  [../]
[]

[VectorPostprocessors]
  [./hydro]
    type = LineValueSampler
    num_points = 100
    start_point = '1 0.07e-3 0'
    end_point = '3 0.07e-3 0'
    sort_by = x
    variable = 'hydro_constant hydro_first hydro_second temp2 disp_x disp_y'
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/capped_mohr_coulomb/small_deform22.i

# Mohr-Coulomb only
# apply stretches in x direction and smaller stretches in the y direction
# to observe return to the MC plane
# This tests uses hardening of the cohesion.  The returned configuration
# should obey
# 0 = 0.5 * (Smax - Smin) + 0.5 * (Smax + Smin) * sin(phi) - C cos(phi)
# which allows inference of C.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0.4E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.1E-6*y*t'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 6
    property = plastic_yield_function
    variable = yield_fcn
  [../]
  [./iter_auxk]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./intnl_auxk]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 0
    variable = intnl
  [../]
[]

[Postprocessors]
  [./s_max]
    type = PointValue
    point = '0 0 0'
    variable = max_principal_stress
  [../]
  [./s_mid]
    type = PointValue
    point = '0 0 0'
    variable = mid_principal_stress
  [../]
  [./s_min]
    type = PointValue
    point = '0 0 0'
    variable = min_principal_stress
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
  [./intnl]
    type = PointValue
    point = '0 0 0'
    variable = intnl
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningCubic
    value_0 = 10
    value_residual = 20
    internal_limit = 5E-6
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1E7
    poissons_ratio = 0.3
  [../]
  [./mc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = ts
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    smoothing_tol = 0
    yield_function_tol = 1.0E-9
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    perform_finite_strain_rotations = false
  [../]
[]


[Executioner]
  end_time = 10
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform_hard21
  csv = true
[]

modules/combined/test/tests/sliding_block/in_and_out/dirac/frictional_04_penalty.i

#  This is a benchmark test that checks Dirac based frictional
#  contact using the penalty method.  In this test a sinusoidal
#  displacement is applied in the horizontal direction to simulate
#  a small block come in and out of contact as it slides down a larger block.
#
#  The sinusoid is of the form 0.4sin(4t)+0.2 and a friction coefficient
#  of 0. is used.  The gold file is run on one processor and the benchmark
#  case is run on a minimum of 4 processors to ensure no parallel variability
#  in the contact pressure and penetration results.  Further documentation can
#  found in moose/modules/contact/doc/sliding_block/
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
  [./horizontal_movement]
    type = ParsedFunction
    value = -0.04*sin(4*t)+0.02
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./constitutive]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 15
  num_steps = 1000
  nl_rel_tol = 1e-6
  dtmin = 0.01
  l_tol = 1e-6

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  file_base = frictional_04_penalty_out
  interval = 10
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+7
    formulation = penalty
    friction_coefficient = 0.4
    normal_smoothing_distance = 0.1
    system = DiracKernel
  [../]
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking_rotation.i

# This test is to ensure that the smeared cracking model correctly handles finite
# rotation of cracked elements.

# This consists of a single element that is first  subjected to tensile loading
# in the y-direction via a prescribed displacement. This loading is sufficiently
# high to crack the material in that direction, but not completely unload. The
# prescribed displacement is then reversed so that the element is returned to its
# original configuration.

# In the next phase of the analysis, this element is then rotated 90 degrees by
# prescribing the displacement of the bottom of the element. The prescribed
# displacement BC used to crack the element in the first phase is deactivated.

# Once the element is fully rotated, a new BC is activated on what was originally
# the top surface (but is now the surface on the right hand side) to pull in
# the x-direction.

# If everything is working correctly, the model should re-load on the original
# crack (which should be rotated along with the elemnent) up to the peak stress
# in the first phase of the analysis, and then continue the unloading process
# as the crack strains continue to increase. Throughout this analysis, there should
# only be a single crack, as manifested in the crack_flags variables.

[Mesh]
  file = cracking_test.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[AuxVariables]
  [./crack_flags1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./crack_flags2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./crack_flags3]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./crack_flags1]
    type = MaterialRealVectorValueAux
    property = crack_flags
    variable = crack_flags1
    component = 0
  [../]
  [./crack_flags2]
    type = MaterialRealVectorValueAux
    property = crack_flags
    variable = crack_flags2
    component = 1
  [../]
  [./crack_flags3]
    type = MaterialRealVectorValueAux
    property = crack_flags
    variable = crack_flags3
    component = 2
  [../]
[]

[BCs]
  [./x_pin]
    type = DirichletBC
    variable = disp_x
    boundary = '15 16'
    value = 0.0
  [../]
  [./y_pin]
    type = DirichletBC
    variable = disp_y
    boundary = '15 16'
    value = 0.0
  [../]
  [./z_all]
    type = DirichletBC
    variable = disp_z
    boundary = '11 12 13 14 15 16 17 18'
    value = 0.0
  [../]
  [./x_lb]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '11 12'
    function = 'if(t<10,0,if(t>=100,1,1-cos((t-10)*pi/180)))'
  [../]
  [./y_lb]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = '11 12'
    function = 'if(t<10,0,if(t>=100,1,sin((t-10)*pi/180)))'
  [../]
  [./x_lt]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '13 14'
    function = '2+(t-100)*0.01'
  [../]
  [./x_rt]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '17 18'
    function = '1+(t-100)*0.01'
  [../]
  [./top_pull]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = '13 14 17 18'
    function = 'if(t<5,t*0.01,0.05-(t-5)*0.01)'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 100.e9
    poissons_ratio = 0.
  [../]
  [./cracking_stress]
    type = ComputeSmearedCrackingStress
    shear_retention_factor = 0.1
    cracking_stress = 3.e9
    softening_models = exponential_softening
  [../]
  [./exponential_softening]
    type = ExponentialSoftening
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type'
  petsc_options_value = '101                lu'
  line_search = 'none'

  l_max_its = 100
  l_tol = 1e-5

  nl_max_its = 100
  nl_abs_tol = 1e-5
  nl_rel_tol = 1e-12

  start_time = 0
  end_time = 110
  dt = 1
[]

[Controls]
  [./p1]
    type = TimePeriod
    start_time = 0.0
    end_time = 10.0
    disable_objects = 'BCs/x_lt BCs/x_rt'
    enable_objects = 'BCs/top_pull'
    reverse_on_false = false
    execute_on = 'initial timestep_begin'
  [../]
  [./p2]
    type = TimePeriod
    start_time = 10.0
    end_time = 101.0
    disable_objects = 'BCs/x_lt BCs/x_rt BCs/top_pull'
    reverse_on_false = false
    execute_on = 'initial timestep_begin'
  [../]
  [./p3]
    type = TimePeriod
    start_time = 101.0
    end_time = 110.0
    enable_objects = 'BCs/x_lt BCs/x_rt'
    disable_objects = 'BCs/top_pull'
    reverse_on_false = false
    execute_on = 'initial timestep_begin'
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_mouth_dir_end_dir_vec.i

#This tests the J-Integral evaluation capability.
#This is a 3d extrusion of a 2d plane strain model with 2 elements
#through the thickness, and calculates the J-Integrals using options
#to treat it as 3d.
#Crack direction is defined using the crack mouth coordinates.
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack3d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackMouth
  crack_mouth_boundary = 900
  crack_end_direction_method = CrackDirectionVector
  crack_direction_vector_end_1 = '1.0 0.0 0.0'
  crack_direction_vector_end_2 = '1.0 0.0 0.0'
  radius_inner = '4.0 5.5'
  radius_outer = '5.5 7.0'
  output_variable = 'disp_x'
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 500
    value = 0.0
  [../]
  [./no_z2]
    type = DirichletBC
    variable = disp_z
    boundary = 510
    value = 0.0
  [../]

  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]

  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]

[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]


[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Postprocessors]
  [./disp_x_centercrack]
    type = CrackFrontData
    crack_front_definition = crackFrontDefinition
    variable = disp_x
    crack_front_point_index = 1
  [../]
[]

[Outputs]
  file_base = j_integral_3d_mouth_dir_end_dir_vec_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/radial_disp_aux/cylinder_2d_cartesian.i

# The purpose of this set of tests is to check the values computed
# by the RadialDisplacementAux AuxKernel. They should match the
# radial component of the displacment for a cylindrical or spherical
# model.
# This particular model is of a cylinder subjected to uniform thermal
# expansion represented using a 2D Cartesian model.

[Mesh]
  type = FileMesh
  file = circle_sector_2d.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
  order = SECOND
  family = LAGRANGE
[]

[AuxVariables]
  [./temp]
  [../]
  [./rad_disp]
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t+300.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    eigenstrain_names = eigenstrain
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
    use_displaced_mesh = false
  [../]
  [./raddispaux]
    type = RadialDisplacementCylinderAux
    variable = rad_disp
    origin = '0 0 0'
  [../]
[]

[BCs]
  [./x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 300
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '51'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  start_time = 0.0
  end_time = 1
  dt = 1
  dtmin = 1
[]

[Outputs]
 csv = true
 exodus = true
[]

#[Postprocessors]
#  [./strain_xx]
#    type = SideAverageValue
#    variable =
#    block = 0
#  [../]
#[]

modules/tensor_mechanics/test/tests/stickyBC/push_down.i

# Testing StickyBC
#
# Push the top of an element downward until the bottom hits an (invisible) obstruction.
# 10 timesteps are used.  In each timestep disp_y is decreased by 0.1.  The
# StickyBC has a min_value of -0.49, so at timestep 5 this bound will be violated
# and the bottom boundary will be fixed forever after.
#
# This test also illustrates that StickyBC is only ever meant to be used in
# special situations:
# - if, after the simulation ends, the top is moved upward again, the StickyBC
#   will keep the bottom fixed.  Ie, the StickyBC is truly "sticky".
# - setting min_value = -0.5 in this test illustrates the "approximate" nature
#   of StickyBC, in that some nodes will be fixed at disp_y=-0.5, while others
#   will be fixed at disp_y=-0.6, due to the timestepping and roundoff errors
#   in MOOSE's solution.
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
  [../]
[]

[BCs]
  [./obstruction]
    type = StickyBC
    variable = disp_y
    boundary = bottom
    min_value = -0.49
  [../]
  [./top]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = -t
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./front]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0
  [../]
[]

[Materials]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1.0
    poissons_ratio = 0.2
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Linear
  dt = 0.1
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/power_law_creep/power_law_creep_restart1.i

# 1x1x1 unit cube with uniform pressure on top face

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
    initial_condition = 1000.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy creep_strain_xx creep_strain_yy creep_strain_zz elastic_strain_yy'
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1'
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
  [./heat_ie]
    type = HeatConductionTimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./u_top_pull]
    type = Pressure
    variable = disp_y
    component = 1
    boundary = top
    factor = -10.0e6
    function = top_pull
  [../]
  [./u_bottom_fix]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp_fix]
    type = DirichletBC
    variable = temp
    boundary = 'bottom top'
    value = 1000.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e11
    poissons_ratio = 0.3
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    tangent_operator = elastic
    inelastic_models = 'power_law_creep'
  [../]
  [./power_law_creep]
    type = PowerLawCreepStressUpdate
    coefficient = 1.0e-15
    n_exponent = 4
    activation_energy = 3.0e5
    temperature = temp
  [../]

  [./thermal]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 100.
  [../]
  [./density]
    type = Density
    density = 1.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 20
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-6
  l_tol = 1e-5
  start_time = 0.0
  end_time = 1.0
  num_steps = 6
  dt = 0.1
[]

[Outputs]
  exodus = true
  csv = true
  [./out]
    type = Checkpoint
    num_files = 1
  [../]
[]

modules/tensor_mechanics/test/tests/line_material_rank_two_sampler/rank_two_sampler.i

[GlobalParams]
  displacements = 'x_disp y_disp z_disp'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 3
  ny = 3
  nz = 3
  elem_type = HEX
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 1e-6
  [../]
[]

[Variables]
  [./x_disp]
    order = FIRST
    family = LAGRANGE
  [../]
  [./y_disp]
    order = FIRST
    family = LAGRANGE
  [../]
  [./z_disp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
 [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
 [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
[]

[VectorPostprocessors]
  [./stress_xx]
    type = LineMaterialRankTwoSampler
    start = '0.1667 0.4 0.45'
    end   = '0.8333 0.6 0.55'
    property = stress
    index_i = 0
    index_j = 0
    sort_by = id
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./front]
    type = FunctionDirichletBC
    variable = z_disp
    boundary = 5
    function = rampConstant
  [../]
  [./back_x]
    type = DirichletBC
    variable = x_disp
    boundary = 0
    value = 0.0
  [../]
  [./back_y]
    type = DirichletBC
    variable = y_disp
    boundary = 0
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = z_disp
    boundary = 0
    value = 0.0
  [../]
[]

[Materials]
  [./elast_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = .3
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK

  l_max_its = 100

  start_time = 0.0
  num_steps = 99999
  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  file_base = rank_two_sampler_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/stress_recovery/patch/patch.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 2
  elem_type = QUAD9
  uniform_refine = 0
[]

[Variables]
  [disp_x]
    order = SECOND
    family = LAGRANGE
  []
  [disp_y]
    order = SECOND
    family = LAGRANGE
  []
[]

[AuxVariables]
  [stress_xx]
    order = FIRST
    family = MONOMIAL
  []
  [stress_yy]
    order = FIRST
    family = MONOMIAL
  []
  [stress_xx_recovered]
    order = SECOND
    family = LAGRANGE
  []
  [stress_yy_recovered]
    order = SECOND
    family = LAGRANGE
  []
[]

[AuxKernels]
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = 'timestep_end'
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = 'timestep_end'
  []
  [stress_xx_recovered]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_recovered
    index_i = 0
    index_j = 0
    execute_on = 'timestep_end'
  []
  [stress_yy_recovered]
    type = RankTwoAux
    patch_polynomial_order = SECOND
    rank_two_tensor = stress
    variable = stress_yy_recovered
    index_i = 1
    index_j = 1
    execute_on = 'timestep_end'
  []
[]

[Kernels]
  [solid_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
  []
  [solid_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
  []
[]

[Materials]
  [strain]
    type = ComputeSmallStrain
  []
  [Cijkl]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 2.1e+5
  []
  [stress]
    type = ComputeLinearElasticStress
  []
[]

[BCs]
  [top_xdisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'top'
    function = 0
  []
  [top_ydisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'top'
    function = t
  []
  [bottom_xdisp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'bottom'
    function = 0
  []
  [bottom_ydisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'bottom'
    function = 0
  []
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
    ksp_norm = default
  []
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  petsc_options_iname = '-ksp_type -pc_type'
  petsc_options_value = 'preonly   lu'
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-8
  l_max_its = 100
  nl_max_its = 30
  dt = 0.01
  dtmin = 1e-11
  start_time = 0
  end_time = 0.05
[]

[Outputs]
  interval = 1
  exodus = true
  print_linear_residuals = false
[]

modules/tensor_mechanics/test/tests/ad_action/two_block_no_action.i

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  []
  [block1]
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 0 0'
    top_right = '0.5 1 0'
    input = generated_mesh
  []
  [block2]
    type = SubdomainBoundingBoxGenerator
    block_id = 2
    bottom_left = '0.5 0 0'
    top_right = '1 1 0'
    input = block1
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

# [Modules/TensorMechanics/Master]
#   [./block1]
#     strain = FINITE
#     add_variables = true
#     #block = 1
#     use_automatic_differentiation = true
#   [../]
#   [./block2]
#     strain = SMALL
#     add_variables = true
#     block = 2
#     use_automatic_differentiation = true
#   [../]
# []

[Kernels]
  [./disp_x]
    type = ADStressDivergenceTensors
    variable = disp_x
    component = 0
  [../]
  [./disp_y]
    type = ADStressDivergenceTensors
    variable = disp_y
    component = 1
  [../]
[]

[AuxVariables]
  [./stress_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_theta]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_theta
    execute_on = timestep_end
  [../]
  [./strain_theta]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 2
    index_j = 2
    variable = strain_theta
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./block_1]
    type = ADComputeFiniteStrain
    block = 1
  [../]
  [./block_2]
    type = ADComputeSmallStrain
    block = 2
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./_elastic_stress1]
    type = ADComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./_elastic_stress2]
    type = ADComputeLinearElasticStress
    block = 2
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    boundary = 'left'
    variable = disp_x
    value = 0.0
  [../]
  [./top]
    type = DirichletBC
    boundary = 'top'
    variable = disp_y
    value = 0.0
  [../]
  [./right]
    type = DirichletBC
    boundary = 'right'
    variable = disp_x
    value = 0.01
  [../]
  [./bottom]
    type = DirichletBC
    boundary = 'bottom'
    variable = disp_y
    value = 0.01
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Preconditioning]
  [./full]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/temperature_dependent_hardening/temp_dep_hardening.i

#
# This is a test of the piece-wise linear strain hardening model using the
# small strain formulation.  This test exercises the temperature-dependent
# hardening curve capability.
#
# Test procedure:
# 1. The element is pulled to and then beyond the yield stress for a given
# temperature.
# 2. The displacement is then constant while the temperature increases and
# the yield stress decreases.  This results in a lower stress with more
# plastic strain.
# 3. The temperature decreases beyond its original value giving a higher
# yield stress.  The displacement increases, causing increases stress to
# the new yield stress.
# 4. The temperature and yield stress are constant with increasing
# displacement giving a constant stress and more plastic strain.
#
# Plotting total_strain_yy on the x axis and stress_yy on the y axis shows
# the stress history in a clear way.
#
#  s |
#  t |            *****
#  r |           *
#  e |   *****  *
#  s |  *    * *
#  s | *     *
#    |*
#    +------------------
#           total strain
#
# The exact same problem was run in Abaqus with exactly the same result.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  # This test uses ElementalVariableValue postprocessors on specific
  # elements, so element numbering needs to stay unchanged
  allow_renumbering = false
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
    initial_condition = 500.0
  [../]
[]

[AuxKernels]
  [./temp_aux]
    type = FunctionAux
    variable = temp
    function = temp_hist
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1     2    4    5    6'
    y = '0 0.025 0.05 0.05 0.06 0.085'
  [../]
  [./hf1]
    type = PiecewiseLinear
    x = '0.0  0.01 0.02 0.03 0.1'
    y = '5000 5030 5060 5090 5300'
  [../]
  [./hf2]
    type = PiecewiseLinear
    x = '0.0  0.01 0.02 0.03 0.1'
    y = '4000 4020 4040 4060 4200'
  [../]
  [./temp_hist]
    type = PiecewiseLinear
    x = '0   1   2   3   4'
    y = '500 500 500 600 400'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    incremental = true
    add_variables = true
    generate_output = 'stress_yy strain_yy plastic_strain_xx plastic_strain_yy plastic_strain_zz'
  [../]
[]


[BCs]
  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 3
    function = top_pull
  [../]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = 0
    value = 0.0
  [../]
[]

[Postprocessors]
  [./stress_yy_el]
    type = ElementalVariableValue
    variable = stress_yy
    elementid = 0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.3
  [../]
  [./temp_dep_hardening]
    type = TemperatureDependentHardeningStressUpdate
    hardening_functions = 'hf1 hf2'
    temperatures = '300.0 800.0'
    relative_tolerance = 1e-25
    absolute_tolerance = 1e-5
    temperature = temp
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    tangent_operator = elastic
    inelastic_models = 'temp_dep_hardening'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  end_time = 6
  dt = 0.1
[]

[Outputs]
  [./out]
    type = Exodus
  [../]
[]

modules/combined/test/tests/mortar_tm/2d/frictionless_second/small.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'small'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeLinearElasticStress
    block = 'plank block'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_1/brick1_template1.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick1_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_x
  [../]
  [./disp_x13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_x
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_y
  [../]
  [./disp_y13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_y
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_x8 disp_x13 disp_x16 disp_y5 disp_y8 disp_y13 disp_y16 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/peridynamics/test/tests/auxkernels/boundary_offset_node_area_2D.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./fmg]
    type = FileMeshGenerator
    file = 2D_square.e
  [../]
  [./mgpd]
    type = MeshGeneratorPD
    input = fmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./gap_offset]
  [../]
  [./node_area]
  [../]
[]

[AuxKernels]
  [./gap_offset]
    type = BoundaryOffsetPD
    variable = gap_offset
  [../]
  [./node_area]
    type = NodalVolumePD
    variable = node_area
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./blk1]
    formulation = BOND
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./material_pd]
    type = ComputeSmallStrainVariableHorizonMaterialBPD
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1001
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1001
    value = 0
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  end_time = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/capped_drucker_prager/small_deform2_inner_edge.i

# apply repeated stretches in x, y and z directions, so that mean_stress = 0
# This maps out the yield surface in the octahedral plane for zero mean stress

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz'
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '-1.5E-6*x+2E-6*x*sin(t)'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2E-6*y*sin(2*t)'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '-2E-6*z*(sin(t)+sin(2*t))'
  [../]
[]

[AuxVariables]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1000
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1000
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 20
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 0
  [../]
  [./dp]
    type = TensorMechanicsPlasticDruckerPrager
    mc_cohesion = mc_coh
    mc_friction_angle = mc_phi
    mc_dilation_angle = mc_psi
    mc_interpolation_scheme = inner_edge
    internal_constraint_tolerance = 1 # irrelevant here
    yield_function_tolerance = 1      # irrelevant here
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    lambda = 0.0
    shear_modulus = 1.0e7
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = cdp
    perform_finite_strain_rotations = false
  [../]
  [./cdp]
    type = CappedDruckerPragerStressUpdate
    DP_model = dp
    tensile_strength = ts
    compressive_strength = cs
    yield_function_tol = 1E-8
    tip_smoother = 4
    smoothing_tol = 1E-5
  [../]
[]


[Executioner]
  end_time = 100
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform2_inner_edge
  exodus = false
  [./csv]
    type = CSV
  [../]
[]

modules/tensor_mechanics/test/tests/radial_disp_aux/sphere_2d_axisymmetric.i

# The purpose of this set of tests is to check the values computed
# by the RadialDisplacementAux AuxKernel. They should match the
# radial component of the displacment for a cylindrical or spherical
# model.
# This particular model is of a sphere subjected to uniform thermal
# expansion represented using a 2D axisymmetric model.

[Mesh]
  type = FileMesh
  file = circle_sector_2d.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
  order = SECOND
  family = LAGRANGE
[]

[Problem]
  coord_type = RZ
[]

[AuxVariables]
  [./temp]
  [../]
  [./rad_disp]
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t+300.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    eigenstrain_names = eigenstrain
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
    use_displaced_mesh = false
  [../]
  [./raddispaux]
    type = RadialDisplacementSphereAux
    variable = rad_disp
    origin = '0 0 0'
  [../]
[]

[BCs]
  [./x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 300
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '51'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  start_time = 0.0
  end_time = 1
  dt = 1
  dtmin = 1
[]

[Outputs]
 csv = true
 exodus = true
[]

#[Postprocessors]
#  [./strain_xx]
#    type = SideAverageValue
#    variable =
#    block = 0
#  [../]
#[]

modules/combined/test/tests/contact/pressurePenalty.i


[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = pressure.e
[]


[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_yy'
  []
[]

[Contact]
  [./m20_s10]
    master = 20
    slave = 10
    penalty = 1e8
    formulation = penalty
    tangential_tolerance = 1e-3
    tension_release = -1
    system = Constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]

  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./z]
    type = DirichletBC
    variable = disp_z
    boundary = 5
    value = 0.0
  [../]

  [./Pressure]
    [./press]
      boundary = 7
      factor = 1e3
    [../]
  [../]

  [./down]
    type = DirichletBC
    variable = disp_y
    boundary = 8
    value = -2e-3
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.0
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'lu       101'

  line_search = 'none'

  nl_rel_tol = 1e-9
  nl_abs_tol = 1e-9

  l_max_its = 100
  nl_max_its = 10
  dt = 1.0
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/dynamics/prescribed_displacement/3D_QStatic_1_Ramped_Displacement_with_gravity.i

# One 3D element under ramped displacement loading.
#
# loading in z direction:
# time : 0.0 0.1  0.2  0.3
# disp : 0.0 0.0 -0.01 -0.01

# Gravity is applied in y direction. To equilibrate the system
# under gravity, a static analysis is run in the first time step
# by turning off the inertial terms. (see controls block and
# DynamicTensorMechanics block).

# Result: The displacement at the top node in the z direction should match
# the prescribed displacement. Also, the z acceleration should
# be two triangular pulses, one peaking at 0.1 and another peaking at
# 0.2.

# The y displacement would be offset by the gravity displacement.
# Also the y acceleration and velocity should be zero until the loading in
# the z direction starts (i.e, until 0.1s)

# Note: The time step used in the displacement data file should match
# the simulation time step (dt and dtmin in the Executioner block).

[Mesh]
  type = GeneratedMesh
  dim = 3 # Dimension of the mesh
  nx = 1 # Number of elements in the x direction
  ny = 1 # Number of elements in the y direction
  nz = 1 # Number of elements in the z direction
  xmin = 0.0
  xmax = 1
  ymin = 0.0
  ymax = 1
  zmin = 0.0
  zmax = 1
  allow_renumbering = false # So NodalVariableValue can index by id
[]

[Variables] # variables that are solved
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables] # variables that are calculated for output
  [./accel_x]
  [../]
  [./vel_x]
  [../]
  [./accel_y]
  [../]
  [./vel_y]
  [../]
  [./accel_z]
  [../]
  [./vel_z]
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./DynamicTensorMechanics] # zeta*K*vel + K * disp
    displacements = 'disp_x disp_y disp_z'
    zeta = 0.000025
    static_initialization = true #turns off rayliegh damping for the first time step to stabilize system under gravity
  [../]
  [./inertia_x] # M*accel + eta*M*vel
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25 # Newmark time integration
    gamma = 0.5 # Newmark time integration
    eta = 19.63
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    eta = 19.63
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    beta = 0.25
    gamma = 0.5
    eta = 19.63
  [../]
  [./gravity]
    type = Gravity
    variable = disp_y
    value = -9.81
  [../]
[]

[AuxKernels]
  [./accel_x] # Calculates and stores acceleration at the end of time step
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_x] # Calculates and stores velocity at the end of the time step
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./accel_z]
    type = NewmarkAccelAux
    variable = accel_z
    displacement = disp_z
    velocity = vel_z
    beta = 0.25
    execute_on = timestep_end
  [../]
  [./vel_z]
    type = NewmarkVelAux
    variable = vel_z
    acceleration = accel_z
    gamma = 0.5
    execute_on = timestep_end
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Functions]
  [./displacement_front]
    type = PiecewiseLinear
    data_file = 'displacement.csv'
    format = columns
  [../]
[]

[BCs]
  [./prescribed_displacement]
    type = PresetDisplacement
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    beta = 0.25
    boundary = front
    function = displacement_front
  [../]
  [./anchor_x]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./anchor_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./anchor_z]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    youngs_modulus = 325e6 #Pa
    poissons_ratio = 0.3
    type = ComputeIsotropicElasticityTensor
    block = 0
  [../]
  [./strain]
    #Computes the strain, assuming small strains
    type = ComputeSmallStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    #Computes the stress, using linear elasticity
    type = ComputeLinearElasticStress
    block = 0
  [../]
  [./density]
    type = GenericConstantMaterial
    block = 0
    prop_names = density
    prop_values = 2000 #kg/m3
  [../]
[]

[Controls] # turns off inertial terms for the first time step
  [./period0]
    type = TimePeriod
    disable_objects = '*/vel_x */vel_y */vel_z */accel_x */accel_y */accel_z */inertia_x */inertia_y */inertia_z'
    start_time = 0.0
    end_time = 0.1 # dt used in the simulation
  [../]
[../]

[Executioner]
  type = Transient
  start_time = 0
  end_time = 3.0
  l_tol = 1e-6
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-6
  dt = 0.1
  timestep_tolerance = 1e-6
[]

[Postprocessors] # These quantites are printed to a csv file at every time step
  [./_dt]
    type = TimestepSize
  [../]
  [./accel_6x]
    type = NodalVariableValue
    nodeid = 6
    variable = accel_x
  [../]
  [./accel_6y]
    type = NodalVariableValue
    nodeid = 6
    variable = accel_y
  [../]
  [./accel_6z]
    type = NodalVariableValue
    nodeid = 6
    variable = accel_z
  [../]
  [./vel_6x]
    type = NodalVariableValue
    nodeid = 6
    variable = vel_x
  [../]
  [./vel_6y]
    type = NodalVariableValue
    nodeid = 6
    variable = vel_y
  [../]
  [./vel_6z]
    type = NodalVariableValue
    nodeid = 6
    variable = vel_z
  [../]
  [./disp_6x]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_6y]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./disp_6z]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_z
  [../]
[]

[Outputs]
  exodus = true
  csv = true
  perf_graph = true
[]

modules/xfem/test/tests/solid_mechanics_basic/sm/test_crack_counter.i

# This test is used to verify that the pure test object (TestCrackCounter)
# is correctly using the API for extracting the crack_tip_origin_direction_map
# from XFEM.  The map contains information of the location of all the crack tips
# computed by XFEM.  The TestCrackCounter postprocessor simply returns the
# number of elements in the map which corresponds to the number of cracks.
#
# In this test case 4 prescribed cracks are applied.  Therefore, the
# TestCrackCounter postprocessor returns a value of 4.

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 11
  ny = 11
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '1.0  0.5  0.7  0.5'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
  [./line_seg_cut_uo2]
    type = LineSegmentCutUserObject
    cut_data = '0.0  0.5  0.3  0.5'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
  [./line_seg_cut_uo3]
    type = LineSegmentCutUserObject
    cut_data = '0.5  0.0  0.5  0.3'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
  [./line_seg_cut_uo4]
    type = LineSegmentCutUserObject
    cut_data = '0.5  1.0  0.5  0.7'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    planar_formulation = plane_strain
    add_variables = true
  [../]
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x='0  50   100'
    y='0  0.02 0.1'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./topx]
    type = DirichletBC
    boundary = top
    variable = disp_x
    value = 0.0
  [../]
  [./topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = pull
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
    block = 0
  [../]

  [./_elastic_strain]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Postprocessors]
  [./number_of_cracks]
    type = TestCrackCounter
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-9

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
  num_steps = 5000

  max_xfem_update = 1
[]

[Outputs]
  csv = true
[]

modules/tensor_mechanics/test/tests/ad_2D_geometries/2D-RZ_test.i

# Considers the mechanics solution for a thick spherical shell that is uniformly
# pressurized on the inner and outer surfaces, using 2D axisymmetric geometry.
# This test uses the strain calculators ComputeAxisymmetricRZSmallStrain
# and ComputeAxisymmetricRZIncrementalStrain which are generated by the
# TensorMechanics MasterAction depending on the cli_args given in the tests file.
#
# From Roark (Formulas for Stress and Strain, McGraw-Hill, 1975), the radially-dependent
# circumferential stress in a uniformly pressurized thick spherical shell is given by:
#
# S(r) = [ Pi[ri^3(2r^3+ro^3)] - Po[ro^3(2r^3+ri^3)] ] / [2r^3(ro^3-ri^3)]
#
#   where:
#          Pi = inner pressure
#          Po = outer pressure
#          ri = inner radius
#          ro = outer radius
#
# The tests assume an inner and outer radii of 5 and 10, with internal and external
# pressures of 100000 and 200000, respectively. The resulting compressive tangential
# stress is largest at the inner wall and, from the above equation, has a value
# of -271429.

[Mesh]
  file = 2D-RZ_mesh.e
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Problem]
  coord_type = RZ
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    generate_output = 'stress_zz'
    use_automatic_differentiation = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./stress]
  [../]
[]

[BCs]
# pin particle along symmetry planes
  [./no_disp_r]
    type = DirichletBC
    variable = disp_r
    boundary = xzero
    value = 0.0
  [../]

  [./no_disp_z]
    type = DirichletBC
    variable = disp_z
    boundary = yzero
    value = 0.0
  [../]

# exterior and internal pressures
  [./exterior_pressure_r]
    type = ADPressure
    variable = disp_r
    boundary = outer
    component = 0
    constant = 200000
  [../]

 [./exterior_pressure_z]
    type = ADPressure
    variable = disp_z
    boundary = outer
    component = 1
    constant = 200000
  [../]

  [./interior_pressure_r]
    type = ADPressure
    variable = disp_r
    boundary = inner
    component = 0
    constant = 100000
  [../]

  [./interior_pressure_z]
    type = ADPressure
    variable = disp_z
    boundary = inner
    component = 1
    constant = 100000
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50

  start_time = 0.0
  end_time = 1
#  num_steps = 1000

  dtmax = 5e6
  dtmin = 1

  [./TimeStepper]
    type = IterationAdaptiveDT
    dt = 1
    optimal_iterations = 6
    iteration_window = 0
    linear_iteration_ratio = 100
  [../]

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

[]

[Postprocessors]
  [./dt]
    type = TimestepSize
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/2D_different_planes/planestrain_jacobian_testing_yz.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = square_yz_plane.e
[]

[Variables]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./disp_x]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./plane_strain]
    block = 1
    strain = SMALL
    out_of_plane_direction = x
    planar_formulation = PLANE_STRAIN
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.0
    youngs_modulus = 1
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  petsc_options_iname = '-ksp_type -pc_type -snes_type'
  petsc_options_value = 'bcgs bjacobi test'

  end_time = 1.0
[]

modules/tensor_mechanics/examples/bridge/bridge.i

#
# Bridge linear elasticity example
#
# This example models a bridge using linear elasticity.
# It can be either steel or concrete.
# Gravity is applied
# A pressure of 0.5 MPa is also applied
#

[Mesh]
  displacements = 'disp_x disp_y disp_z' #Define displacements for deformed mesh
  type = FileMesh #Read in mesh from file
  file = bridge.e

  boundary_id = '1 2 3 4 5 6' #Assign names to boundaries to make things clearer
  boundary_name = 'top left right bottom1 bottom2 bottom3'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Kernels]
  [./gravity_y]
    #Gravity is applied to bridge
    type = Gravity
    variable = disp_y
    value = -9.81
  [../]
  [./TensorMechanics]
    #Stress divergence kernels
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[AuxVariables]
  [./von_mises]
    #Dependent variable used to visualize the Von Mises stress
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./von_mises_kernel]
    #Calculates the von mises stress and assigns it to von_mises
    type = RankTwoScalarAux
    variable = von_mises
    rank_two_tensor = stress
    execute_on = timestep_end
    scalar_type = VonMisesStress
  [../]
[]

[BCs]
  [./Pressure]
    [./load]
      #Applies the pressure
      boundary = top
      factor = 5e5 # Pa
      disp_x = disp_x
      disp_y = disp_y
      disp_z = disp_z
    [../]
  [../]
  [./anchor_x]
    #Anchors the bottom and sides against deformation in the x-direction
    type = DirichletBC
    variable = disp_x
    boundary = 'left right bottom1 bottom2 bottom3'
    value = 0.0
  [../]
  [./anchor_y]
    #Anchors the bottom and sides against deformation in the y-direction
    type = DirichletBC
    variable = disp_y
    boundary = 'left right bottom1 bottom2 bottom3'
    value = 0.0
  [../]
  [./anchor_z]
    #Anchors the bottom and sides against deformation in the z-direction
    type = DirichletBC
    variable = disp_z
    boundary = 'left right bottom1 bottom2 bottom3'
    value = 0.0
  [../]
[]

[Materials]
  active = 'density_concrete stress strain elasticity_tensor_concrete'
  [./elasticity_tensor_steel]
    #Creates the elasticity tensor using steel parameters
    youngs_modulus = 210e9 #Pa
    poissons_ratio = 0.3
    type = ComputeIsotropicElasticityTensor
    block = 1
  [../]
  [./elasticity_tensor_concrete]
    #Creates the elasticity tensor using concrete parameters
    youngs_modulus = 16.5e9 #Pa
    poissons_ratio = 0.2
    type = ComputeIsotropicElasticityTensor
    block = 1
  [../]
  [./strain]
    #Computes the strain, assuming small strains
    type = ComputeSmallStrain
    block = 1
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    #Computes the stress, using linear elasticity
    type = ComputeLinearElasticStress
    block = 1
  [../]
  [./density_steel]
    #Defines the density of steel
    type = GenericConstantMaterial
    block = 1
    prop_names = density
    prop_values = 7850 # kg/m^3
  [../]
  [./density_concrete]
    #Defines the density of concrete
    type = GenericConstantMaterial
    block = 1
    prop_names = density
    prop_values = 2400 # kg/m^3
  [../]
[]

[Preconditioning]
  [./SMP]
    #Creates the entire Jacobian, for the Newton solve
    type = SMP
    full = true
  [../]
[]

[Executioner]
  #We solve a steady state problem using Newton's iteration
  type = Steady
  solve_type = NEWTON
  nl_rel_tol = 1e-9
  l_max_its = 30
  l_tol = 1e-4
  nl_max_its = 10
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre boomeramg 31'
[]

[Outputs]
  exodus = true
  perf_graph = true
[]

modules/combined/test/tests/frictional_contact/sliding_elastic_blocks_2d/sliding_elastic_blocks_2d_tp.i

[Mesh]
  file = sliding_elastic_blocks_2d.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    save_in = 'saved_x saved_y'
    diag_save_in = 'diag_saved_x diag_saved_y'
  [../]
[]


[AuxKernels]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    quantity = incremental_slip_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    quantity = incremental_slip_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip]
    type = PenetrationAux
    variable = accum_slip
    execute_on = timestep_end
    quantity = accumulated_slip
    boundary = 3
    paired_boundary = 2
  [../]
  [./tangential_force_x]
    type = PenetrationAux
    variable = tang_force_x
    execute_on = timestep_end
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./tangential_force_y]
    type = PenetrationAux
    variable = tang_force_y
    execute_on = timestep_end
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.005
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1.0e7
    poissons_ratio = 0.3
  [../]
  [./right]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.01
  end_time = 0.05
  num_steps = 1000
  nl_rel_tol = 1e-16
  nl_abs_tol = 1e-09
  dtmin = 0.01
  l_tol = 1e-3

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = coulomb
    system = constraint
    formulation = tangential_penalty
    friction_coefficient = '0.25'
    penalty = 1e6
  [../]
[]

[Dampers]
  [./contact_slip]
    type = ContactSlipDamper
    slave = 3
    master = 2
  [../]
[]

modules/tensor_mechanics/test/tests/interaction_integral_benchmark/input.i

# Uses InteractionIntegralBenchmarkBC to test the mixed-mode stress intensity
# factor capability. InteractionIntegralBenchmarkBC applies a displacement
# field for which KI = KII = KIII = 1.0. Using the option 2d = true gives a
# q field that is constant along the tangent and returns Ki = 1.0 for all i.
# To get the correct value for all nodes with 2d = false, the mesh around the
# crack tip must be refined and the q-function radii must be reduced by at
# least two orders of magnitude.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = 360degree_model.e
  displacements = 'disp_x disp_y disp_z'
[]

[Problem]
  type = FEProblem
[]

[Functions]
  [./kifunc]
    type = PiecewiseLinear
    x = '0.0 1.0 2.0'
    y = '0.0 1.0 2.0'
  [../]
[]

[DomainIntegral]
  integrals = 'JIntegral InteractionIntegralKI InteractionIntegralKII InteractionIntegralKIII'
  boundary = 1001
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  radius_inner = '0.5 1.0 1.5 2.0'
  radius_outer = '1.0 1.5 2.0 2.5'
  youngs_modulus = 30000
  poissons_ratio = 0.3
  block = 1
  2d = true
  axis_2d = 2
  equivalent_k = True
  incremental = true
[]

[AuxVariables]
  [./dq_x]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./dq_y]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./dq_z]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[BCs]
  [./all_x]
    type = InteractionIntegralBenchmarkBC
    variable = disp_x
    component = x
    boundary = 1
    KI_function = kifunc
    KII_function = 1.0
    KIII_function = 1.0
    youngs_modulus = 30000
    poissons_ratio = 0.3
    crack_front_definition = crackFrontDefinition
    crack_front_point_index = 0
  [../]
  [./all_y]
    type = InteractionIntegralBenchmarkBC
    variable = disp_y
    component = y
    boundary = 1
    KI_function = kifunc
    KII_function = 1.0
    KIII_function = 1.0
    youngs_modulus = 30000
    poissons_ratio = 0.3
    crack_front_definition = crackFrontDefinition
    crack_front_point_index = 0
  [../]
  [./all_z]
    type = InteractionIntegralBenchmarkBC
    variable = disp_z
    component = z
    boundary = 1
    KI_function = kifunc
    KII_function = 1.0
    KIII_function = 1.0
    youngs_modulus = 30000
    poissons_ratio = 0.3
    crack_front_definition = crackFrontDefinition
    crack_front_point_index = 0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 30000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-3
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 2
  num_steps = 2
[]

[Postprocessors]
  [./_dt]
    type = TimestepSize
  [../]

  [./nl_its]
    type = NumNonlinearIterations
  [../]

  [./lin_its]
    type = NumLinearIterations
  [../]

[]

[Outputs]
  execute_on = 'timestep_end'
  file_base = 360degree_model_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/ad_elastic/rz_small_elastic-noad.i

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 3
  ny = 3
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = StressDivergenceRZTensors
    component = 0
    variable = disp_r
  [../]
  [./stress_z]
    type = StressDivergenceRZTensors
    component = 1
    variable = disp_z
  [../]
[]

[BCs]
  [./bottom]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0
  [../]
  [./axial]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
  [./strain]
    type = ComputeAxisymmetricRZSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = rz_small_elastic_out
[]

modules/combined/test/tests/contact_verification/patch_tests/ring_2/ring2_template2.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = ring2_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_y5 disp_x9 disp_y9 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/tensor_mechanics/test/tests/capped_mohr_coulomb/small_deform9.i

# Using CappedMohrCoulomb with tensile failure only
# A single unit element is stretched in a complicated way
# that the trial stress is
#
#      1.16226      -0.0116587       0.0587872
#     -0.0116587         1.12695       0.0779428
#      0.0587872       0.0779428        0.710169
#
# This has eigenvalues
# la = {0.68849, 1.14101, 1.16987}
# and eigenvectors
#
# {-0.125484, -0.176871, 0.976202}
# {-0.0343704, -0.982614, -0.182451}
# {0.9915, -0.0564471, 0.117223}
#
# The tensile strength is 0.5 and Young=1 and Poisson=0.25.
# Using smoothing_tol=0.01, the return-map algorithm should
# return to, approximately, stress_I=stress_II=0.5.  This
# is a reduction of 0.66, so stress_III is approximately
# 0.68849 - v * 0.66 * 2 = 0.68849 - 0.25 * 0.66 * 2 = 0.36.
#
# E_22 = E(1-v)/(1+v)/(1-2v) = 1.2, and E_02 = E_22 v/(1-v)
# gamma_shear = ((smax-smin)^trial - (smax-smin)) / (E_22 - E_02)
# = (1-2v) * (smax^trial - smax) / (E_22(1 - 2v)/(1-v))
# = (1 - v) * (smax^trial - smax) / E_22
# Using psi = 30deg, sin(psi) = 1/2
# the shear correction to the tensile internal parameter is
# gamma_shear (E_22 + E_20) sin(psi) = gamma_shear E_22 sin(psi) / (1 - v)
# = gamma_shear E_22 / (1 - v) / 2
# Then the tensile internal parameter is
# (1 - v) * (reduction_of_(max+min)_principal - gamma_shear * E_22 / (1-v) / 2) / E_22
# = (1-v)(1+2v)(smax^trial - smax)/E_22 - gamma_shear / 2
# = 0.41 (approximately)
#
# The final stress is
#
# {0.498, -0.003, 0.017},
# {-0.003, 0.495, 0.024},
# {0.017, 0.024,  0.367}

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = finite
    incremental = true
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress stress_xx stress_xy stress_xz stress_yy stress_yz stress_zz'
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '3*x+2*y+z'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '3*x-4*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = 'x-2*z'
  [../]
[]

[AuxVariables]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./f0_auxk]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1_auxk]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2_auxk]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./intnl_auxk]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    index = 1
    variable = intnl
  [../]
[]

[Postprocessors]
  [./s_I]
    type = PointValue
    point = '0 0 0'
    variable = max_principal_stress
  [../]
  [./s_II]
    type = PointValue
    point = '0 0 0'
    variable = mid_principal_stress
  [../]
  [./s_III]
    type = PointValue
    point = '0 0 0'
    variable = min_principal_stress
  [../]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
  [./intnl]
    type = PointValue
    point = '0 0 0'
    variable = intnl
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 0.5
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.25
  [../]
  [./tensile]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.001
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = tensile
    perform_finite_strain_rotations = false
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform9
  csv = true
[]

modules/tensor_mechanics/test/tests/ad_1D_spherical/smallStrain_1DSphere.i

# This simulation models the mechanics solution for a solid sphere under
# pressure, applied on the outer surfaces, using 1D spherical symmetry
# assumpitions.  The inner center of the sphere, r = 0, is pinned to prevent
# movement of the sphere.
#
# From Bower (Applied Mechanics of Solids, 2008, available online at
# solidmechanics.org/text/Chapter4_1/Chapter4_1.htm), and applying the outer
# pressure and pinned displacement boundary conditions set in this simulation,
# the radial displacement is given by:
#
# u(r) = \frac{- P * (1 - 2 * v) * r}{E}
#
# where P is the applied pressure, v is Poisson's ration, E is Young's Modulus,
# and r is the radial position.
#
# The test assumes a radius of 4, zero displacement at r = 0mm, and an applied
# outer pressure of 1MPa.  Under these conditions in a solid sphere, the radial
# stress is constant and has a value of -1 MPa.
[Mesh]
  type = GeneratedMesh
  dim = 1
  xmin = 0
  xmax = 4
  nx = 4
[]

[GlobalParams]
  displacements = 'disp_r'
[]

[Problem]
  coord_type = RSPHERICAL
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    save_in = residual_r
    use_automatic_differentiation = true
  [../]
[]

[AuxVariables]
  [./stress_rr]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./residual_r]
  [../]
[]

[Postprocessors]
  [./stress_rr]
    type = ElementAverageValue
    variable = stress_rr
  [../]
  [./residual_r]
    type = NodalSum
    variable = residual_r
    boundary = right
  [../]
[]

[AuxKernels]
  [./stress_rr]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_rr
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./innerDisp]
    type = ADDirichletBC
    boundary = left
    variable = disp_r
    value = 0.0
  [../]
  [./outerPressure]
    type = ADPressure
    boundary = right
    variable = disp_r
    component = 0
    constant = 1
  [../]
[]

[Materials]
  [./Elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.345
    youngs_modulus = 1e4
  [../]
  [./stress]
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-8

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-5

# time control
  start_time = 0.0
  dt = 0.25
  dtmin = 0.0001
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/internal_volume/rz_displaced_quad8.i

#
# Volume Test
#
# This test is designed to compute the volume of a space when displacements
#   are imposed.
#
# The mesh is composed of one block (1) with two elements.  The mesh is
#   such that the initial volume is 1.  One element face is displaced to
#   produce a final volume of 2.
#
#     r1
#   +----+   -
#   |    |   |
#   +----+   h    V1 = pi * h * r1^2
#   |    |   |
#   +----+   -
#
#   becomes
#
#   +----+
#   |     \
#   +------+      v2 = pi * h/2 * ( r2^2 + 1/3 * ( r2^2 + r2*r1 + r1^2 ) )
#   |      |
#   +------+
#      r2
#
#   r1 = 1
#   r2 = 1.5380168369562588
#   h  = 1/pi
#
#  Note:  Because the InternalVolume PP computes cavity volumes as positive,
#         the volumes reported are negative.
#

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = meshes/rz_displaced_quad8.e
  displacements = 'disp_x disp_y'
[]

[Functions]
  [./disp_x]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 0.5380168369562588'
  [../]
  [./disp_x2]
    type = PiecewiseLinear
    scale_factor = 0.5
    x = '0. 1.'
    y = '0. 0.5380168369562588'
  [../]
[]

[Variables]
  [./disp_x]
    order = SECOND
    family = LAGRANGE
  [../]

  [./disp_y]
    order = SECOND
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    volumetric_locking_correction = false
    decomposition_method = EigenSolution
    incremental = true
    strain = FINITE
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]

  [./x]
    type = FunctionDirichletBC
    boundary = 3
    variable = disp_x
    function = disp_x
  [../]
  [./x2]
    type = FunctionDirichletBC
    boundary = 4
    variable = disp_x
    function = disp_x2
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK

  start_time = 0.0
  dt = 1.0
  end_time = 1.0

  [./Quadrature]
    order = THIRD
  [../]
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 2
    execute_on = 'initial timestep_end'
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/simplest_contact/simplest_contact_skew_test.i

[Mesh]
  file = simplest_contact_skew.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  []
[]

[AuxKernels]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 2
    paired_boundary = 3
  [../]
[]

[Constraints]
  [./contact_x]
    type = MultiDContactConstraint
    variable = disp_x
    master_variable = disp_x
    component = 0
    slave = 2
    master = 3
    penalty = 1e6
  [../]

  [./contact_y]
    type = MultiDContactConstraint
    variable = disp_y
    master_variable = disp_y
    component = 1
    slave = 2
    master = 3
    penalty = 1e6
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.0001
  [../]

  [./right_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  #petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  #petsc_options_value = 'hypre    boomeramg      101'
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre    boomeramg      101'

  line_search = 'none'

  nl_abs_tol = 1e-8

  l_max_its = 100
  nl_max_its = 10
  dt = 1.0
  num_steps = 1
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/tensor_mechanics/test/tests/ad_elastic/finite_elastic.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 3
  ny = 3
  nz = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_x]
    scaling = 1e-10
  [../]
  [./disp_y]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_x]
    type = ADStressDivergenceTensors
    component = 0
    variable = disp_x
    use_displaced_mesh = true
  [../]
  [./stress_y]
    type = ADStressDivergenceTensors
    component = 1
    variable = disp_y
    use_displaced_mesh = true
  [../]
  [./stress_z]
    type = ADStressDivergenceTensors
    component = 2
    variable = disp_z
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeFiniteStrain
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/truss/truss_hex_action.i

# This test is designed to check
# whether truss element works well with other multi-dimensional element
# e.g. the hex element in this case, by assigning different block number
# to different types of elements.
[Mesh]
  type = FileMesh
  file = truss_hex.e
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./axial_stress]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./e_over_l]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./area]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./react_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./react_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./react_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Functions]
  [./x2]
    type = PiecewiseLinear
    x = '0  1 2 3'
    y = '0 .5 1 1'
  [../]
  [./y2]
    type = PiecewiseLinear
    x = '0 1  2 3'
    y = '0 0 .5 1'
  [../]
[]

[BCs]
  [./fixx1]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./fixy1]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0
  [../]
  [./fixz1]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0
  [../]

  [./fixx2]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0
  [../]
  [./fixz2]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0
  [../]

  [./fixDummyHex_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1000
    value = 0
  [../]

  [./fixDummyHex_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1000
    value = 0
  [../]

  [./fixDummyHex_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1000
    value = 0
  [../]
[]

[DiracKernels]
  [./pull]
    type = ConstantPointSource
    value = -25
    point = '0 -2 0'
    variable = disp_y
  [../]
[]

[AuxKernels]
  [./axial_stress]
    type = MaterialRealAux
    block = '1 2'
    property = axial_stress
    variable = axial_stress
  [../]
  [./e_over_l]
    type = MaterialRealAux
    block = '1 2'
    property = e_over_l
    variable = e_over_l
  [../]
  [./area1]
    type = ConstantAux
    block = 1
    variable = area
    value = 1.0
    execute_on = 'initial timestep_begin'
  [../]
  [./area2]
    type = ConstantAux
    block = 2
    variable = area
    value = 0.25
    execute_on = 'initial timestep_begin'
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK

  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'jacobi   101'

  nl_max_its = 15
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-10

  dt = 1
  num_steps = 1
  end_time = 1
[]

[Kernels]
  [./TensorMechanics]
    block = 1000
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[Modules/TensorMechanics/LineElementMaster]
   [./block]
     truss = true
     displacements = 'disp_x disp_y disp_z'

     area = area

     block = '1 2'
     save_in = 'react_x react_y react_z'
   [../]
[]

[Materials]
   [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1000
    youngs_modulus = 1e6
    poissons_ratio = 0
  [../]
  [./strain]
    type = ComputeSmallStrain
    block = 1000
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    type = ComputeLinearElasticStress
    block = 1000
  [../]
  [./linelast]
    type = LinearElasticTruss
    block = '1 2'
    displacements = 'disp_x disp_y disp_z'
    youngs_modulus = 1e6
  [../]
[]

[Outputs]
  file_base = 'truss_hex_out'
  exodus = true
[]

modules/xfem/test/tests/moving_interface/moving_bimaterial.i

# This test is for two layer materials with different youngs modulus
# The global stress is determined by switching the stress based on level set values
# The material interface is marked by a level set function
# The two layer materials are glued together

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[UserObjects]
  [./level_set_cut_uo]
    type = LevelSetCutUserObject
    level_set_var = ls
    heal_always = true
  [../]
[]

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 5
    ny = 5
    xmin = 0.0
    xmax = 5.
    ymin = 0.0
    ymax = 5.
    elem_type = QUAD4
  []
  [./left_bottom]
    type = ExtraNodesetGenerator
    new_boundary = 'left_bottom'
    coord = '0.0 0.0'
    input = generated_mesh
  [../]
  [./left_top]
    type = ExtraNodesetGenerator
    new_boundary = 'left_top'
    coord = '0.0 5.'
    input = left_bottom
  [../]
[]

[AuxVariables]
  [./ls]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxKernels]
  [./ls_function]
    type = FunctionAux
    variable = ls
    function = ls_func
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Functions]
  [./ls_func]
    type = ParsedFunction
    value = 'y-2.5 + t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./a_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./a_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./a_strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./b_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./b_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./b_strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  [../]
  [./a_strain_xx]
    type = RankTwoAux
    rank_two_tensor = A_total_strain
    index_i = 0
    index_j = 0
    variable = a_strain_xx
  [../]
  [./a_strain_yy]
    type = RankTwoAux
    rank_two_tensor = A_total_strain
    index_i = 1
    index_j = 1
    variable = a_strain_yy
  [../]
  [./a_strain_xy]
    type = RankTwoAux
    rank_two_tensor = A_total_strain
    index_i = 0
    index_j = 1
    variable = a_strain_xy
  [../]
  [./b_strain_xx]
    type = RankTwoAux
    rank_two_tensor = B_total_strain
    index_i = 0
    index_j = 0
    variable = b_strain_xx
  [../]
  [./b_strain_yy]
    type = RankTwoAux
    rank_two_tensor = B_total_strain
    index_i = 1
    index_j = 1
    variable = b_strain_yy
  [../]
  [./b_strain_xy]
    type = RankTwoAux
    rank_two_tensor = B_total_strain
    index_i = 0
    index_j = 1
    variable = b_strain_xy
  [../]
[]

[Constraints]
  [./dispx_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_x
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  [../]
  [./dispy_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_y
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./topx]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_x
    function = 0.03*t
  [../]
  [./topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = '0.03*t'
  [../]
[]

[Materials]
  [./elasticity_tensor_A]
    type = ComputeIsotropicElasticityTensor
    base_name = A
    youngs_modulus = 1e9
    poissons_ratio = 0.3
  [../]
  [./strain_A]
    type = ComputeSmallStrain
    base_name = A
  [../]
  [./stress_A]
    type = ComputeLinearElasticStress
    base_name = A
  [../]
  [./elasticity_tensor_B]
    type = ComputeIsotropicElasticityTensor
    base_name = B
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  [../]
  [./strain_B]
    type = ComputeSmallStrain
    base_name = B
  [../]
  [./stress_B]
    type = ComputeLinearElasticStress
    base_name = B
  [../]
  [./combined_stress]
    type = LevelSetBiMaterialRankTwo
    levelset_positive_base = 'A'
    levelset_negative_base = 'B'
    level_set_var = ls
    prop_name = stress
  [../]
  [./combined_dstressdstrain]
    type = LevelSetBiMaterialRankFour
    levelset_positive_base = 'A'
    levelset_negative_base = 'B'
    level_set_var = ls
    prop_name = Jacobian_mult
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'bt'

# controls for linear iterations
  l_max_its = 20
  l_tol = 1e-3

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-12

# time control
  start_time = 0.0
  dt = 0.1
  num_steps = 2

  max_xfem_update = 1
[]

[Outputs]
  exodus = true
  execute_on = timestep_end
  csv = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/peridynamics/test/tests/auxkernels/boundary_offset_node_volume_3D.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./fmg]
    type = FileMeshGenerator
    file = 3D_cube.e
  [../]
  [./mgpd]
    type = MeshGeneratorPD
    input = fmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./gap_offset]
  [../]
  [./node_volume]
  [../]
[]

[AuxKernels]
  [./gap_offset]
    type = BoundaryOffsetPD
    variable = gap_offset
  [../]
  [./node_volume]
    type = NodalVolumePD
    variable = node_volume
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./blk1]
    formulation = BOND
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./material_pd]
    type = ComputeSmallStrainVariableHorizonMaterialBPD
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1001
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1001
    value = 0
  [../]
  [./fix_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1001
    value = 0
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  end_time = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_2d_topo_q_func.i

#This tests the J-Integral evaluation capability.
#This is a 2d plane strain model
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack2d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  q_function_type = Topology
  ring_first = 1
  ring_last = 4
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]

  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]

  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = j_integral_2d_topo_q_func_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/t_stress/t_stress_crack_infinite_plate_2d.i

# T-stress test for a through crack in a wide ("infinite") plate.
# For a finer mesh this problem converges to the solution T = -sigma.
# Ref: T.L. Anderson, Fracture Mechanics: Fundamentals and Applications

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack_infinite_plate.e
  displacements = 'disp_x disp_y'
  partitioner = centroid
  centroid_partitioner_direction = z
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstantUp]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -100
  [../]
[]

[DomainIntegral]
  integrals = 'JIntegral InteractionIntegralKI InteractionIntegralT'
  boundary = 1001
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  radius_inner = '0.06 0.08 0.10'
  radius_outer = '0.08 0.10 0.12'
  block = 1
  youngs_modulus = 30e+6
  poissons_ratio = 0.3
  2d = true
  axis_2d = 2
  symmetry_plane = 1
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 300
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./Pressure]
    [./top]
      boundary = 200
      function = rampConstantUp
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 30e+6
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
   type = Transient

#  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 20
   nl_abs_tol = 3e-7
   nl_rel_tol = 1e-12
   l_tol = 1e-2

   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1
[]

[Outputs]
  file_base = t_stress_crack_infinite_plate_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/jacobian/tensile_update6.i

# Tensile, update version, with strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.
# Returns to the plane of tensile yield

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0.5
    internal_limit = 2E-2
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 0.5E3
    shear_modulus = 1.0E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-1 0.1 0.2  0.1 15 -0.3  0.2 -0.3 0'
    eigenstrain_name = ini_stress
  [../]
  [./tensile]
    type = TensileStressUpdate
    tensile_strength = ts
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = tensile
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/rom_stress_update/verification.i

[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temperature]
  [../]
[]

[AuxKernels]
  [./temp_aux]
    type = FunctionAux
    variable = temperature
    function = temp_fcn
    execute_on = 'initial timestep_begin'
  [../]
[]

[Functions]
  [./rhom_fcn]
    type = PiecewiseConstant
    data_file = ss316_verification_data.csv
    x_index_in_file = 0
    y_index_in_file = 1
    format = columns
    xy_in_file_only = false
    direction = right
  [../]
  [./rhoi_fcn]
    type = PiecewiseConstant
    data_file = ss316_verification_data.csv
    x_index_in_file = 0
    y_index_in_file = 2
    format = columns
    xy_in_file_only = false
    direction = right
  [../]
  [./vmJ2_fcn]
    type = PiecewiseConstant
    data_file = ss316_verification_data.csv
    x_index_in_file = 0
    y_index_in_file = 3
    format = columns
    xy_in_file_only = false
    direction = right
  [../]
  [./evm_fcn]
    type = PiecewiseConstant
    data_file = ss316_verification_data.csv
    x_index_in_file = 0
    y_index_in_file = 4
    format = columns
    xy_in_file_only = false
    direction = right
  [../]
  [./temp_fcn]
    type = PiecewiseConstant
    data_file = ss316_verification_data.csv
    x_index_in_file = 0
    y_index_in_file = 5
    format = columns
    xy_in_file_only = false
    direction = right
  [../]

  [./rhom_soln_fcn]
    type = PiecewiseConstant
    data_file = ss316_verification_data.csv
    x_index_in_file = 0
    y_index_in_file = 7
    format = columns
    xy_in_file_only = false
    direction = right
  [../]
  [./rhoi_soln_fcn]
    type = PiecewiseConstant
    data_file = ss316_verification_data.csv
    x_index_in_file = 0
    y_index_in_file = 8
    format = columns
    xy_in_file_only = false
    direction = right
  [../]
  [./creep_rate_soln_fcn]
    type = PiecewiseConstant
    data_file = ss316_verification_data.csv
    x_index_in_file = 0
    y_index_in_file = 10
    format = columns
    xy_in_file_only = false
    direction = right
  [../]

  [./rhom_diff_fcn]
    type = ParsedFunction
    vars = 'rhom_soln rhom'
    vals = 'rhom_soln rhom'
    value = 'abs(rhom_soln - rhom) / rhom_soln'
  [../]
  [./rhoi_diff_fcn]
    type = ParsedFunction
    vars = 'rhoi_soln rhoi'
    vals = 'rhoi_soln rhoi'
    value = 'abs(rhoi_soln - rhoi) / rhoi_soln'
  [../]
  [./creep_rate_diff_fcn]
    type = ParsedFunction
    vars = 'creep_rate_soln creep_rate'
    vals = 'creep_rate_soln creep_rate'
    value = 'abs(creep_rate_soln - creep_rate) / creep_rate_soln'
  [../]
[]


[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'vonmises_stress'
    use_automatic_differentiation = true
  [../]
[]

[BCs]
  [./symmx]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmy]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmz]
    type = ADDirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./pressure_x]
    type = ADPressure
    variable = disp_x
    component = 0
    boundary = right
    function = vmJ2_fcn
    constant = 0.5e6
  [../]
  [./pressure_y]
    type = ADPressure
    variable = disp_y
    component = 1
    boundary = top
    function = vmJ2_fcn
    constant = -0.5e6
  [../]
  [./pressure_z]
    type = ADPressure
    variable = disp_z
    component = 2
    boundary = front
    function = vmJ2_fcn
    constant = -0.5e6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e11
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ADComputeMultipleInelasticStress
    inelastic_models = rom_stress_prediction
  [../]
  [./rom_stress_prediction]
    type = SS316HLAROMANCEStressUpdateTest
    temperature = temperature
    effective_inelastic_strain_name = effective_creep_strain
    internal_solve_full_iteration_history = true
    apply_strain = false
    outputs = all
    immobile_dislocation_density_forcing_function = rhoi_fcn
    mobile_dislocation_density_forcing_function = rhom_fcn
    old_creep_strain_forcing_function = evm_fcn
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'NEWTON'

  petsc_options = '-snes_ksp_ew -snes_converged_reason -ksp_converged_reason'# -ksp_error_if_not_converged -snes_error_if_not_converged'
  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'
  line_search = 'none'
  automatic_scaling = true
  compute_scaling_once = false

  nl_abs_tol = 1e-10

  dt = 1e-3
  end_time = 1e-2
[]

[Postprocessors]
  [./effective_strain_avg]
    type = ElementAverageValue
    variable = effective_creep_strain
    outputs = console
  [../]
  [./temperature]
    type = ElementAverageValue
    variable = temperature
    outputs = console
  [../]
  [./rhom]
    type = ElementAverageValue
    variable = mobile_dislocations
  [../]
  [./rhoi]
    type = ElementAverageValue
    variable = immobile_dislocations
  [../]
  [./vonmises_stress]
    type = ElementAverageValue
    variable = vonmises_stress
    outputs = console
  [../]
  [./creep_rate]
    type = ElementAverageValue
    variable = creep_rate
  [../]
  [./rhom_in]
    type = FunctionValuePostprocessor
    function = rhom_fcn
    execute_on = 'TIMESTEP_END initial'
    outputs = console
  [../]
  [./rhoi_in]
    type = FunctionValuePostprocessor
    function = rhoi_fcn
    execute_on = 'TIMESTEP_END initial'
    outputs = console
  [../]
  [./vmJ2_in]
    type = FunctionValuePostprocessor
    function = vmJ2_fcn
    execute_on = 'TIMESTEP_END initial'
    outputs = console
  [../]
  [./rhom_soln]
    type = FunctionValuePostprocessor
    function = rhom_soln_fcn
    outputs = console
  [../]
  [./rhoi_soln]
    type = FunctionValuePostprocessor
    function = rhoi_soln_fcn
    outputs = console
  [../]
  [./creep_rate_soln]
    type = FunctionValuePostprocessor
    function = creep_rate_soln_fcn
    outputs = console
  [../]

  [./rhom_diff]
    type = FunctionValuePostprocessor
    function = rhom_diff_fcn
    outputs = console
  [../]
  [./rhoi_diff]
    type = FunctionValuePostprocessor
    function = rhoi_diff_fcn
    outputs = console
  [../]
  [./creep_rate_diff]
    type = FunctionValuePostprocessor
    function = creep_rate_diff_fcn
    outputs = console
  [../]

  [./rhom_max_diff]
    type = TimeExtremeValue
    postprocessor = rhom_diff
    outputs = console
  [../]
  [./rhoi_max_diff]
    type = TimeExtremeValue
    postprocessor = rhoi_diff
    outputs = console
  [../]
  [./creep_rate_max_diff]
    type = TimeExtremeValue
    postprocessor = creep_rate_diff
    outputs = console
  [../]
[]

[Outputs]
  csv = true
  file_base = 'verification_1e-3_out'
[]

modules/tensor_mechanics/test/tests/domain_integral_thermal/j_integral_2d_mean_ctefunc.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack2d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = 10.0*(2*x/504)
  [../]
  [./cte_func_mean]
    type = ParsedFunction
    vars = 'tsf tref scale' #stress free temp, reference temp, scale factor
    vals = '0.0 0.5  1e-6'
    value = 'scale * (0.5 * t^2 - 0.5 * tsf^2) / (t - tref)'
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  radius_inner = '60.0 80.0 100.0 120.0'
  radius_outer = '80.0 100.0 120.0 140.0'
  temperature = temp
  incremental = true
  eigenstrain_names = thermal_expansion
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
    eigenstrain_names = thermal_expansion
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    block = 1
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 400
    value = 0.0
  [../]

  [./no_x1]
    type = DirichletBC
    variable = disp_x
    boundary = 900
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeMeanThermalExpansionFunctionEigenstrain
    block = 1
    thermal_expansion_function = cte_func_mean
    stress_free_temperature = 0.0
    thermal_expansion_function_reference_temperature = 0.5
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart -sub_ksp_type -sub_pc_type -pc_asm_overlap'
  petsc_options_value = 'asm         31   preonly   lu      1'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 40

  nl_rel_step_tol= 1e-10
  nl_rel_tol = 1e-10

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  csv = true
  execute_on = 'timestep_end'
[]

[Preconditioning]
  [./smp]
    type = SMP
    pc_side = left
    ksp_norm = preconditioned
    full = true
  [../]
[]

modules/tensor_mechanics/test/tests/ad_elastic/rspherical_incremental_small_elastic.i

[Mesh]
  type = GeneratedMesh
  dim = 1
  nx = 5
[]

[Problem]
  coord_type = RSPHERICAL
[]

[GlobalParams]
  displacements = 'disp_r'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = ADStressDivergenceRSphericalTensors
    component = 0
    variable = disp_r
  [../]
[]

[BCs]
  [./center]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeRSphericalIncrementalStrain
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/elastic_patch/elastic_patch_quadratic.i

# Patch Test for second order hex elements (HEX20)
#
# From Abaqus, Verification Manual, 1.5.2
#
# This test is designed to compute constant xx, yy, zz, xy, yz, and zx
#  stress on a set of irregular hexes.  The mesh is composed of one
#  block with seven elements.  The elements form a unit cube with one
#  internal element.  There is a nodeset for each exterior node.

# The cube is displaced on all exterior nodes using the functions,
#
#    ux = 1e-4 * (2x + y + z) / 2
#    uy = 1e-4 * (x + 2y + z) / 2
#    ux = 1e-4 * (x + y + 2z) / 2
#
#  giving uniform strains of
#
#    exx = eyy = ezz = 2*exy = 2*eyz = 2*exz = 1e-4
#
#
# Hooke's Law provides an analytical solution for the uniform stress state.
#  For example,
#
#    stress xx = lambda(exx + eyy + ezz) + 2 * G * exx
#    stress xy = 2 * G * exy
#
#   where:
#
#    lambda = (2 * G * nu) / (1 - 2 * nu)
#    G = 0.5 * E / (1 + nu)
#
# For the test below, E = 1e6 and nu = 0.25, giving lambda = G = 4e5
#
# Thus
#
#    stress xx = 4e5 * (3e-4) + 2 * 4e5 * 1e-4 = 200
#    stress xy = 2 * 4e5 * 1e-4 / 2 = 40
#
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]
[Mesh]
  file = elastic_patch_quadratic.e
[] # Mesh

[Functions]
  [./xDispFunc]
    type = ParsedFunction
    value = 5e-5*(2*x+y+z)
  [../]
  [./yDispFunc]
    type = ParsedFunction
    value = 5e-5*(x+2*y+z)
  [../]
  [./zDispFunc]
    type = ParsedFunction
    value = 5e-5*(x+y+2*z)
  [../]
[] # Functions

[Variables]
  [./disp_x]
    order = SECOND
    family = LAGRANGE
  [../]
  [./disp_y]
    order = SECOND
    family = LAGRANGE
  [../]
  [./disp_z]
    order = SECOND
    family = LAGRANGE
  [../]
[] # Variables

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_energy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./hydrostatic]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./firstinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./secondinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./thirdinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
[] # AuxVariables

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 2
    variable = stress_yz
  [../]
  [./stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 0
    variable = stress_zx
  [../]
  [./elastic_energy]
    type = ElasticEnergyAux
    variable = elastic_energy
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = VonMisesStress
    variable = vonmises
  [../]
  [./hydrostatic]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = Hydrostatic
    variable = hydrostatic
  [../]
  [./fi]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = FirstInvariant
    variable = firstinv
  [../]
  [./si]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = SecondInvariant
    variable = secondinv
  [../]
  [./ti]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    scalar_type = ThirdInvariant
    variable = thirdinv
  [../]
[] # AuxKernels

[BCs]
  [./all_nodes_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '1 2 3 4 6 7 8 9 10 12 15 17 18 19 20 21 23 24 25 26'
    function = xDispFunc
  [../]
  [./all_nodes_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = '1 2 3 4 6 7 8 9 10 12 15 17 18 19 20 21 23 24 25 26'
    function = yDispFunc
  [../]
  [./all_nodes_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = '1 2 3 4 6 7 8 9 10 12 15 17 18 19 20 21 23 24 25 26'
    function = zDispFunc
  [../]
[] # BCs

[Materials]
  [./elast_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[] # Materials

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-6

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 1
  end_time = 1.0
[] # Executioner

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[] # Outputs

modules/combined/test/tests/sliding_block/sliding/constraint/frictionless_aug.i

#  This is a benchmark test that checks constraint based frictionless
#  contact using the augmented lagrangian method.  In this test a constant
#  displacement is applied in the horizontal direction to simulate
#  a small block come sliding down a larger block.
#
#  The gold file is run on one processor
#  and the benchmark case is run on a minimum of 4 processors to ensure no
#  parallel variability in the contact pressure and penetration results.
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./contact_traction]
  [../]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]


[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  dt = 0.1
  end_time = 15
  num_steps = 200
  l_tol = 1e-6
  nl_rel_tol = 1e-7
  nl_abs_tol = 1e-6
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  solution_variables = 'disp_x disp_y'
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  maximum_lagrangian_update_iterations = 25
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+7
    normalize_penalty = true
    formulation = augmented_lagrange
    tangential_tolerance = 1e-3
    system = constraint
    normal_smoothing_distance = 0.1
    al_penetration_tolerance = 1e-9
  [../]
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_2d.i

#This tests the J-Integral evaluation capability.
#This is a 2d plane strain model
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack2d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  radius_inner = '4.0 4.5 5.0 5.5 6.0'
  radius_outer = '4.5 5.0 5.5 6.0 6.5'
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]

  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]

  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = j_integral_2d_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking_rz.i

#

[Mesh]
  file = cracking_rz_test.e
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Functions]
  [./displ]
    type = PiecewiseLinear
    x = '0 1 2 3  4'
    y = '0 1 0 -1 0'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[BCs]
  [./pull]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 2
    function = displ
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 4.0e7
    poissons_ratio = 0.0
  [../]
  [./elastic_stress]
    type = ComputeSmearedCrackingStress
    cracking_stress = 1.68e6
    softening_models = abrupt_softening
  [../]
  [./abrupt_softening]
    type = AbruptSoftening
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK


  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101               '


  line_search = 'none'


  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-2
  l_tol = 1e-5
  start_time = 0.0
  end_time = 0.1
  dt = 0.025
[]

[Outputs]
  exodus = true
[]

modules/xfem/test/tests/moment_fitting/solid_mechanics_moment_fitting.i

# Test for a mechanics problem which uses four points moment_fitting approach.
# See this paper (https://doi.org/10.1007/s00466-018-1544-2) for more details about moment_fitting approach.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = moment_fitting
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 10
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[UserObjects]
  [./line_seg_cut_uo0]
    type = LineSegmentCutUserObject
    cut_data = '0.0000e+00   6.3330e-01   3.9000e-01   6.3330e-01'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
  [./line_seg_cut_uo1]
    type = LineSegmentCutUserObject
    cut_data = '3.9000e-01   6.3330e-01   6.8000e-01   6.3330e-01'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
  [../]
[]

[Functions]
  [./right_trac_x]
    type = ParsedFunction
    value = '-(t*M*y)/I'
    vars = 'M E I'
    vals = '2e4 1e6 0.666666667'
  [../]
  [./bottom_disp_y]
    type = ParsedFunction
    value = '((t*M)/(2*E*I))*(1-nu*nu)*(x*x-0.25*l*l)'
    vars = 'M E I l nu'
    vals = '2e4 1e6 0.666666667 2.0 0.3'
  [../]
  [./soln_x]
    type = ParsedFunction
    value = '-(M/(E*I))*(1-nu*nu)*x*y'
    vars = 'M E I nu'
    vals = '2e4 1e6 0.666666667 0.3'
  [../]
  [./soln_y]
    type = ParsedFunction
    value = '(M/(2*E*I))*(1-nu*nu)*(x*x-0.25*l*l+(nu/(1-nu))*y*y)'
    vars = 'M E I l nu'
    vals = '2e4 1e6 0.666666667 2.0 0.3'
  [../]
[]

[BCs]
  [./right_x]
    type = FunctionNeumannBC
    boundary = 1
    variable = disp_x
    function = right_trac_x
  [../]
  [./bottom_y]
    type = FunctionDirichletBC
    boundary = 0
    variable = disp_y
    function = bottom_disp_y
  [../]
  [./left_x]
    type = DirichletBC
    boundary = 3
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

#  [./Quadrature]
#    order = FOURTH
#    type = MONOMIAL
#  [../]

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-16
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 0.5
  end_time = 1.0
  num_steps = 5000
[]

[Postprocessors]
  [./numel]
    type = NumElems
    execute_on = timestep_end
  [../]
  [./integral]
    type = ElementVectorL2Error
    var_x = disp_x
    var_y = disp_y
    function_x = soln_x
    function_y = soln_y
    execute_on = timestep_end
  [../]
[]

[Outputs]
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/generalized_plane_strain/plane_strain_prescribed.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  scalar_out_of_plane_strain = scalar_strain_zz
  block = 1
[]

[Mesh]
  file = square.e
[]

[AuxVariables]
  [./temp]
  [../]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
[]

[AuxScalarKernels]
  [./strain_zz]
    type = FunctionScalarAux
    variable = scalar_strain_zz
    function = scalar_strain_zz_func
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
  [./scalar_strain_zz_func]
    type = PiecewiseLinear
    xy_data = '0 0
               1 7.901e-5
               2 1.103021e-2'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    temperature = temp
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy strain_zz'
    planar_formulation = PLANE_STRAIN
    eigenstrain_names = eigenstrain
    save_in = 'saved_x saved_y'
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-4

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-5

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
  num_steps = 5000
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/plane_stress/weak_plane_stress_small.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  temperature = temp
  out_of_plane_strain = strain_zz
[]

[Mesh]
  file = square.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./strain_zz]
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
  [./nl_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
  [./min_strain_zz]
    type = NodalExtremeValue
    variable = strain_zz
    value_type = min
  [../]
  [./max_strain_zz]
    type = NodalExtremeValue
    variable = strain_zz
    value_type = max
  [../]
[]

[Modules/TensorMechanics/Master]
  [plane_stress]
    planar_formulation = WEAK_PLANE_STRESS
    strain = SMALL
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy'
    eigenstrain_names = eigenstrain
  []
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = nl_strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x='0     1   100'
    y='0  0.00  0.00'
  [../]
  [./tempfunc]
    type = ParsedFunction
    value = '(1 - x) * t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-06

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-12

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/j_integral_vtest/j_int_surfbreak_ellip_crack_sym_mm_cfp.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = ellip_crack_4sym_norad_mm.e
  partitioner = centroid
  centroid_partitioner_direction = z
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./resid_z]
  [../]
[]

[Functions]
  [./rampConstantUp]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 0.1'
    scale_factor = -689.5 #MPa
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  crack_direction_method = CurvedCrackFront
  crack_end_direction_method = CrackDirectionVector
  crack_direction_vector_end_1 = '0.0 1.0 0.0'
  crack_direction_vector_end_2 = '1.0 0.0 0.0'
  crack_front_points = '0             254           0
                        127.308       248.843       0
                        249.446       233.581       0
                        361.455       208.835       0
                        508.003       152.398       0
                        602.415       80.3208       0
                        635           0             0'
  radius_inner = '12.5 25.0 37.5'
  radius_outer = '25.0 37.5 50.0'
  intersecting_boundary = '1 2'
  symmetry_plane = 2
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 12
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 5
      function = rampConstantUp
    [../]
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 206800
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]

   type = Transient
  # Two sets of linesearch options are for petsc 3.1 and 3.3 respectively
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

#  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 20
   nl_abs_tol = 1e-5
   nl_rel_tol = 1e-11
   l_tol = 1e-2

   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1
[]

[Postprocessors]
  [./_dt]
    type = TimestepSize
  [../]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./lin_its]
    type = NumLinearIterations
  [../]
  [./react_z]
    type = NodalSum
    variable = resid_z
    boundary = 5
  [../]
[]

[Outputs]
  execute_on = 'timestep_end'
  file_base = j_int_surfbreak_ellip_crack_sym_mm_cfp_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/2D_geometries/2D-RZ_test.i

# Considers the mechanics solution for a thick spherical shell that is uniformly
# pressurized on the inner and outer surfaces, using 2D axisymmetric geometry.
# This test uses the strain calculators ComputeAxisymmetricRZSmallStrain
# and ComputeAxisymmetricRZIncrementalStrain which are generated by the
# TensorMechanics MasterAction depending on the cli_args given in the tests file.
#
# From Roark (Formulas for Stress and Strain, McGraw-Hill, 1975), the radially-dependent
# circumferential stress in a uniformly pressurized thick spherical shell is given by:
#
# S(r) = [ Pi[ri^3(2r^3+ro^3)] - Po[ro^3(2r^3+ri^3)] ] / [2r^3(ro^3-ri^3)]
#
#   where:
#          Pi = inner pressure
#          Po = outer pressure
#          ri = inner radius
#          ro = outer radius
#
# The tests assume an inner and outer radii of 5 and 10, with internal and external
# pressures of 100000 and 200000, respectively. The resulting compressive tangential
# stress is largest at the inner wall and, from the above equation, has a value
# of -271429.

[Mesh]
  file = 2D-RZ_mesh.e
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Problem]
  coord_type = RZ
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    generate_output = 'stress_zz'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./stress]
  [../]
[]

[BCs]
# pin particle along symmetry planes
  [./no_disp_r]
    type = DirichletBC
    variable = disp_r
    boundary = xzero
    value = 0.0
  [../]

  [./no_disp_z]
    type = DirichletBC
    variable = disp_z
    boundary = yzero
    value = 0.0
  [../]

# exterior and internal pressures
  [./exterior_pressure_r]
    type = Pressure
    variable = disp_r
    boundary = outer
    component = 0
    factor = 200000
  [../]

 [./exterior_pressure_z]
    type = Pressure
    variable = disp_z
    boundary = outer
    component = 1
    factor = 200000
  [../]

  [./interior_pressure_r]
    type = Pressure
    variable = disp_r
    boundary = inner
    component = 0
    factor = 100000
  [../]

  [./interior_pressure_z]
    type = Pressure
    variable = disp_z
    boundary = inner
    component = 1
    factor = 100000
  [../]
[]

[Debug]
    show_var_residual_norms = true
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50

  start_time = 0.0
  end_time = 1
#  num_steps = 1000

  dtmax = 5e6
  dtmin = 1

  [./TimeStepper]
    type = IterationAdaptiveDT
    dt = 1
    optimal_iterations = 6
    iteration_window = 0
    linear_iteration_ratio = 100
  [../]

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

[]

[Postprocessors]
  [./dt]
    type = TimestepSize
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_thermal_expansion_function/finite_const.i

# This tests the thermal expansion coefficient function using both
# options to specify that function: mean and instantaneous.  There
# two blocks, each containing a single element, and these use the
# two variants of the function.

# In this test, the instantaneous CTE function has a constant value,
# while the mean CTE function is an analytic function designed to
# give the same response.  If \bar{alpha}(T) is the mean CTE function,
# and \alpha(T) is the instantaneous CTE function,

# \bar{\alpha}(T) = 1/(T-Tref) \intA^{T}_{Tsf} \alpha(T) dT

# where Tref is the reference temperature used to define the mean CTE
# function, and Tsf is the stress-free temperature.

# This version of the test uses finite deformation theory.
# The two models produce very similar results.  There are slight
# differences due to the large deformation treatment.

[Mesh]
  file = 'blocks.e'
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
    use_automatic_differentiation = true
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 3
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    block = '1 2'
    function = temp_func
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ADComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain1]
    type = ADComputeMeanThermalExpansionFunctionEigenstrain
    block = 1
    thermal_expansion_function = cte_func_mean
    thermal_expansion_function_reference_temperature = 0.5
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
  [./thermal_expansion_strain2]
    type = ADComputeInstantaneousThermalExpansionFunctionEigenstrain
    block = 2
    thermal_expansion_function = cte_func_inst
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_func_mean]
    type = ParsedFunction
    vars = 'tsf tref scale' #stress free temp, reference temp, scale factor
    vals = '0.0 0.5  1e-4'
    value = 'scale * (t - tsf) / (t - tref)'
  [../]
  [./cte_func_inst]
    type = PiecewiseLinear
    xy_data = '0 1.0
               2 1.0'
    scale_factor = 1e-4
  [../]

  [./temp_func]
    type = PiecewiseLinear
    xy_data = '0 1
               1 2'
  [../]
[]

[Postprocessors]
  [./disp_1]
    type = NodalMaxValue
    variable = disp_x
    boundary = 101
  [../]

  [./disp_2]
    type = NodalMaxValue
    variable = disp_x
    boundary = 102
  [../]
[]

[Executioner]
  type = Transient

  solve_type = NEWTON
  l_max_its = 100
  l_tol = 1e-4
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

modules/tensor_mechanics/test/tests/action/no_block.i

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  []
  [block1]
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 0 0'
    top_right = '0.5 1 0'
    input = generated_mesh
  []
  [block2]
    type = SubdomainBoundingBoxGenerator
    block_id = 2
    bottom_left = '0.5 0 0'
    top_right = '1 1 0'
    input = block1
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Modules/TensorMechanics/Master]
  # parameters that apply to all subblocks are specified at this level. But
  # no subblocks are present. This should trigger a warning.
  add_variables = true
  strain = FINITE
  generate_output = 'stress_xx'
[]

[AuxVariables]
  [./stress_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_theta]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_theta
    execute_on = timestep_end
  [../]
  [./strain_theta]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 2
    index_j = 2
    variable = strain_theta
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./_elastic_stress1]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./_elastic_stress2]
    type = ComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    boundary = 'left'
    variable = disp_x
    value = 0.0
  [../]
  [./top]
    type = DirichletBC
    boundary = 'top'
    variable = disp_y
    value = 0.0
  [../]
  [./right]
    type = DirichletBC
    boundary = 'right'
    variable = disp_x
    value = 0.01
  [../]
  [./bottom]
    type = DirichletBC
    boundary = 'bottom'
    variable = disp_y
    value = 0.01
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Executioner]
  type = Steady

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/jacobian/cwp07.i

# Capped weak-plane plasticity
# checking jacobian for shear + tensile failure
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 1
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 1.0
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.1
    rate = 1
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 0
    value_residual = 0
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningConstant
    value = 100
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 1  0 0 -1  1 -1 1'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 0
    smoothing_tol = 2
    yield_function_tol = 1E-10
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/jacobian/tensile_update5.i

# Tensile, update version, with strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.
# Returns to close to the tip of the yield function.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0.5
    internal_limit = 2E-2
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '15 1 0.2  1 10 -0.3  -0.3 0.2 8'
    eigenstrain_name = ini_stress
  [../]
  [./tensile]
    type = TensileStressUpdate
    tensile_strength = ts
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = tensile
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/sliding_block/sliding/constraint/frictionless_penalty.i

#  This is a benchmark test that checks constraint based frictionless
#  contact using the penalty method.  In this test a constant
#  displacement is applied in the horizontal direction to simulate
#  a small block come sliding down a larger block.
#
#  The gold file is run on one processor
#  and the benchmark case is run on a minimum of 4 processors to ensure no
#  parallel variability in the contact pressure and penetration results.
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./left_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.1
  end_time = 15
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-6
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+7
    formulation = penalty
    system = constraint
    normal_smoothing_distance = 0.1
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/single_pnt_2d/single_point_2d_frictional.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = single_point_2d.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./appl_disp]
    type = PiecewiseLinear
    x = '0 0.001  0.101'
    y = '0 0.0   -0.10'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./incslip_x]
    type = PenetrationAux
    variable = inc_slip_x
    quantity = incremental_slip_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./incslip_y]
    type = PenetrationAux
    variable = inc_slip_y
    quantity = incremental_slip_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./botx]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./boty]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./topx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = appl_disp
  [../]
  [./topy]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = -0.002001
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e9
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputePlaneFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputePlaneFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./disp_x]
    type = NodalVariableValue
    nodeid = 5
    variable = disp_x
  [../]
  [./disp_y]
    type = NodalVariableValue
    nodeid = 5
    variable = disp_y
  [../]
  [./inc_slip_x]
    type = NodalVariableValue
    nodeid = 5
    variable = inc_slip_x
  [../]
  [./inc_slip_y]
    type = NodalVariableValue
    nodeid = 5
    variable = inc_slip_y
  [../]
  [./accum_slip_x]
    type = NodalVariableValue
    nodeid = 5
    variable = accum_slip_x
  [../]
  [./accum_slip_y]
    type = NodalVariableValue
    nodeid = 5
    variable = accum_slip_y
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu    superlu_dist'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 200
  dt = 0.001
  end_time = 0.001
  num_steps = 10000
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-8
  dtmin = 0.001
  l_tol = 1e-3
[]

[Outputs]
  file_base = single_point_2d_out_frictional_0_2_kin
  exodus = true
  print_linear_residuals = true
  perf_graph = true
  csv = true
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    master = 2
    slave = 3
    model = coulomb
    system = constraint
    formulation = kinematic
    penalty = 1e12
    normalize_penalty = true
    friction_coefficient = '0.2'
    tangential_tolerance = 1e-3
  [../]
[]

 [Dampers]
   [./contact_slip]
     type = ContactSlipDamper
     master = '2'
     slave = '3'
   [../]
 []

modules/tensor_mechanics/test/tests/plane_stress/weak_plane_stress_incremental.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  temperature = temp
  out_of_plane_strain = strain_zz
[]

[Mesh]
  file = square.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./strain_zz]
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
  [./nl_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
  [./min_strain_zz]
    type = NodalExtremeValue
    variable = strain_zz
    value_type = min
  [../]
  [./max_strain_zz]
    type = NodalExtremeValue
    variable = strain_zz
    value_type = max
  [../]
[]

[Modules/TensorMechanics/Master]
  [plane_stress]
    planar_formulation = WEAK_PLANE_STRESS
    strain = SMALL
    incremental = true
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy'
    eigenstrain_names = eigenstrain
  []
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = nl_strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x='0     1   100'
    y='0  0.00  0.00'
  [../]
  [./tempfunc]
    type = ParsedFunction
    value = '(1 - x) * t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-06

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-12

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_elastic/finite_elastic-noad.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 3
  ny = 3
  nz = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_x]
    scaling = 1e-10
  [../]
  [./disp_y]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_x]
    type = StressDivergenceTensors
    component = 0
    variable = disp_x
    use_displaced_mesh = true
  [../]
  [./stress_y]
    type = StressDivergenceTensors
    component = 1
    variable = disp_y
    use_displaced_mesh = true
  [../]
  [./stress_z]
    type = StressDivergenceTensors
    component = 2
    variable = disp_z
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
  [./strain]
    type = ComputeFiniteStrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = finite_elastic_out
[]

modules/tensor_mechanics/test/tests/finite_strain_elastic/finite_strain_stress_errorcheck.i

[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1.0e10
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

modules/tensor_mechanics/test/tests/inclined_bc/inclined_bc_action.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 2
    ny = 4
    nz = 2
    xmin = 0.0
    xmax = 1.0
    ymin = 0.0
    ymax = 2.0
    zmin = 0.0
    zmax = 1.0
    elem_type = HEX8
  []
  [rotate]
    type = TransformGenerator
    transform = ROTATE
    vector_value = '0 -20 -60'
    input = generated_mesh
  []
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  add_variables = true
[]

[BCs]
  [./Pressure]
    [./top]
      boundary = top
      function = '-1000*t'
    [../]
  [../]
  [./InclinedNoDisplacementBC]
    [./right]
      boundary = right
      penalty = 1.0e8
      displacements = 'disp_x disp_y disp_z'
    [../]
    [./bottom]
      boundary = bottom
      penalty = 1.0e8
      displacements = 'disp_x disp_y disp_z'
    [../]
    [./back]
      boundary = back
      penalty = 1.0e8
      displacements = 'disp_x disp_y disp_z'
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  # controls for linear iterations
  l_max_its = 10
  l_tol = 1e-4

  # controls for nonlinear iterations
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-12

  # time control
  start_time = 0.0
  dt = 1
  end_time = 5
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Outputs]
  file_base = 'inclined_bc_3d_out'
  exodus = true
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update8.i

# MC update version, with only Tensile with tensile strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0
    internal_limit = 2E-3
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '2 -1 0.5  1 1.9 0  0.5 0 3'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/jacobian/cwp08.i

# Capped weak-plane plasticity
# checking jacobian for shear + compression failure
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 1
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 1.0
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.1
    rate = 1
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 100
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningConstant
    value = 0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 0.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 1  0 0 -1  1 -1 0'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 0
    smoothing_tol = 2
    yield_function_tol = 1E-10
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/combined_creep_plasticity/combined_creep_plasticity_start_time.i

#
# This test is Example 2 from "A Consistent Formulation for the Integration
#   of Combined Plasticity and Creep" by P. Duxbury, et al., Int J Numerical
#   Methods in Engineering, Vol. 37, pp. 1277-1295, 1994.
#
# The problem is a one-dimensional bar which is loaded from yield to a value of twice
#   the initial yield stress and then unloaded to return to the original stress. The
#   bar must harden to the required yield stress during the load ramp, with no
#   further yielding during unloading. The initial yield stress (sigma_0) is prescribed
#   as 20 with a plastic strain hardening of 100. The mesh is a 1x1x1 cube with symmetry
#   boundary conditions on three planes to provide a uniaxial stress field.
#
#  In the PowerLawCreep model, the creep strain rate is defined by:
#
#   edot = A(sigma)**n * exp(-Q/(RT)) * t**m
#
#   The creep law specified in the paper, however, defines the creep strain rate as:
#
#   edot = Ao * mo * (sigma)**n * t**(mo-1)
#      with the creep parameters given by
#         Ao = 1e-7
#         mo = 0.5
#         n  = 5
#
#   thus, input parameters for the test were specified as:
#         A = Ao * mo = 1e-7 * 0.5 = 0.5e-7
#         m = mo-1 = -0.5
#         n = 5
#         Q = 0
#
#   The variation of load P with time is:
#       P = 20 + 20t      0 < t < 1
#       P = 40 - 40(t-1)  1 < t 1.5
#
#  The analytic solution for total strain during the loading period 0 < t < 1 is:
#
#    e_tot = (sigma_0 + 20*t)/E + 0.2*t + A * t**0.5  * sigma_0**n * [ 1 + (5/3)*t +
#               + 2*t**2 + (10/7)*t**3 + (5/9)**t**4 + (1/11)*t**5 ]
#
#    and during the unloading period 1 < t < 1.5:
#
#    e_tot = (sigma_1 - 40*(t-1))/E + 0.2 + (4672/693) * A * sigma_0**n +
#               A * sigma_0**n * [ t**0.5 * ( 32 - (80/3)*t + 16*t**2 - (40/7)*t**3
#                                  + (10/9)*t**4 - (1/11)*t**5 ) - (11531/693) ]
#
#         where sigma_1 is the stress at time t = 1.
#
#  Assuming a Young's modulus (E) of 1000 and using the parameters defined above:
#
#    e_tot(1) = 2.39734
#    e_tot(1.5) = 3.16813
#
#
#   The numerically computed solution is:
#
#    e_tot(1) = 2.39718         (~0.006% error)
#    e_tot(1.5) = 3.15555       (~0.40% error)
#
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy elastic_strain_yy creep_strain_yy plastic_strain_yy'
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '  10   11   11.5'
    y = '-20 -40   -20'
  [../]

  [./dts]
    type = PiecewiseLinear
    x = '10        10.5    11.0    11.5'
    y = '0.015  0.015  0.005  0.005'
  [../]
[]

[BCs]
  [./u_top_pull]
    type = Pressure
    variable = disp_y
    component = 1
    boundary = top
    factor = 1
    function = top_pull
  [../]
  [./u_bottom_fix]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 1e3
    poissons_ratio = 0.3
  [../]
  [./creep_plas]
    type = ComputeMultipleInelasticStress
    block = 0
    tangent_operator = elastic
    inelastic_models = 'creep plas'
    max_iterations = 50
    absolute_tolerance = 1e-05
    combined_inelastic_strain_weights = '0.0 1.0'
  [../]
  [./creep]
    type = PowerLawCreepStressUpdate
    block = 0
    coefficient = 0.5e-7
    n_exponent = 5
    m_exponent = -0.5
    activation_energy = 0
    start_time = 10
  [../]
  [./plas]
    type = IsotropicPlasticityStressUpdate
    block = 0
    hardening_constant = 100
    yield_stress = 20
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 6
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-10
  l_tol = 1e-5
  start_time = 10.0
  end_time = 11.5

  [./TimeStepper]
    type = FunctionDT
    function = dts
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/mortar_tm/2drz/ad_frictionless_second/small.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'small'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./corner]
    type = ExtraNodesetGenerator
    input = block_rename
    coord = '0 -10.0'
    new_boundary = point
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = corner
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    use_automatic_differentiation = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
  [../]
  [./plank]
    use_automatic_differentiation = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ADComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/combined/test/tests/ad_power_law_creep/power_law_creep_smallstrain.i

# 1x1x1 unit cube with uniform pressure on top face for the case of small strain.
#  This test does not have a solid mechanics analog because there is not an equvialent
#  small strain with rotations strain calculator material in solid mechanics

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
    initial_condition = 1000.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    incremental = true
    add_variables = true
    generate_output = 'stress_yy creep_strain_xx creep_strain_yy creep_strain_zz elastic_strain_yy'
    use_automatic_differentiation = true
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1'
  [../]
[]

[Kernels]
  [./heat]
    type = ADHeatConduction
    variable = temp
  [../]
  [./heat_ie]
    type = ADHeatConductionTimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./u_top_pull]
    type = ADPressure
    variable = disp_y
    component = 1
    boundary = top
    constant = -10.0e6
    function = top_pull
  [../]
  [./u_bottom_fix]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = ADDirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp_fix]
    type = DirichletBC
    variable = temp
    boundary = 'bottom top'
    value = 1000.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e11
    poissons_ratio = 0.3
  [../]
  [./radial_return_stress]
    type = ADComputeMultipleInelasticStress
    inelastic_models = 'power_law_creep'
  [../]
  [./power_law_creep]
    type = ADPowerLawCreepStressUpdate
    coefficient = 1.0e-15
    n_exponent = 4
    activation_energy = 3.0e5
    temperature = temp
  [../]

  [./thermal]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 100.
  [../]
  [./density]
    type = ADDensity
    density = 1.0
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 20
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-6
  l_tol = 1e-5
  start_time = 0.0
  end_time = 1.0
  num_steps = 10
  dt = 0.1
[]

[Outputs]
  exodus = true
[]

modules/peridynamics/test/tests/restart/2D_mesh_restartable_NOSPD_second.i


[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  restart_file_base = 2D_mesh_restartable_nospd_out_cp/LATEST
[]

[Mesh]
  file = 2D_mesh_restartable_nospd_out_cp/LATEST
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1003
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1001
    value = 0.001
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = NONORDINARY_STATE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e8
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputePlaneSmallStrainNOSPD
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady
  solve_type = PJFNK

  [./Quadrature]
    type = GAUSS_LOBATTO
    order = FIRST
  [../]
[]

[Outputs]
  file_base = 2D_mesh_restartable_NOSPD_second_out
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_3/cyl3_template2.i

#
# This input file is a template for both the frictionless and glued test
# variations for the current problem geometry. In order to create an input
# file to run outside the runtest framework, look at the tests file and add the
# appropriate input file lines from the cli_args line.
#

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl3_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu       superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 1000
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x11 disp_y11 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    tangential_tolerance = 1e-3
    penalty = 1e+11
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/tensor_mechanics/test/tests/material_limit_time_step/damage/scalar_material_damage_timestep_limit.i

# This is a basic test of the system for continuum damage mechanics
# materials. It uses ScalarMaterialDamage for the damage model,
# which simply gets its damage index from another material. In this
# case, we prescribe the evolution of the damage index using a
# function. A single element has a fixed prescribed displacement
# on one side that puts the element in tension, and then the
# damage index evolves from 0 to 1 over time, and this verifies
# that the stress correspondingly drops to 0.

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  elem_type = HEX8
[]

[AuxVariables]
  [damage_index]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Modules/TensorMechanics/Master]
  [all]
    strain = SMALL
    incremental = true
    add_variables = true
    generate_output = 'stress_xx strain_xx'
  []
[]

[AuxKernels]
  [damage_index]
    type = MaterialRealAux
    variable = damage_index
    property = damage_index_prop
    execute_on = timestep_end
  []
[]

[BCs]
  [symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  []
  [symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  []
  [symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  []
  [axial_load]
    type = DirichletBC
    variable = disp_x
    boundary = right
    value = 0.01
  []
[]

[Functions]
  [damage_evolution]
    type = PiecewiseLinear
    xy_data = '0.0   0.0
               0.1   0.0
               2.1   2.0'
  []
[]

[Materials]
  [damage_index]
    type = GenericFunctionMaterial
    prop_names = damage_index_prop
    prop_values = damage_evolution
  []
  [damage]
    type = ScalarMaterialDamage
    damage_index = damage_index_prop
  []
  [stress]
    type = ComputeDamageStress
    damage_model = damage
  []
  [elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.2
    youngs_modulus = 10e9
  []
[]

[Postprocessors]
  [stress_xx]
    type = ElementAverageValue
    variable = stress_xx
  []
  [strain_xx]
    type = ElementAverageValue
    variable = strain_xx
  []
  [damage_index]
    type = ElementAverageValue
    variable = damage_index
  []
  [time_step_limit]
    type = MaterialTimeStepPostprocessor
  []
[]

[Executioner]
  type = Transient

  l_max_its  = 50
  l_tol      = 1e-8
  nl_max_its = 20
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-8

  dt = 0.1
  dtmin = 0.001
  end_time = 1.1
  [TimeStepper]
    type = IterationAdaptiveDT
    dt = 0.1
    growth_factor = 2.0
    cutback_factor = 0.5
    timestep_limiting_postprocessor = time_step_limit
  []
[]

[Outputs]
  csv=true
[]

modules/tensor_mechanics/test/tests/material_limit_time_step/creep/nafems_test5a_lim.i

[GlobalParams]
  temperature = temp
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane1_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  group_variables = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./temp]
    initial_condition = 1500.0
  [../]
  [./creep]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./pressure]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./invariant3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./creep_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./creep_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./creep_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./creep_strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./creep_aux]
    type = MaterialRealAux
    property = effective_creep_strain
    variable = creep
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = VonMisesStress
  [../]
  [./pressure]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = pressure
    scalar_type = Hydrostatic
  [../]
  [./invariant3]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = invariant3
    scalar_type = ThirdInvariant
  [../]
  [./creep_strain_xx]
    type = RankTwoAux
    rank_two_tensor = creep_strain
    variable = creep_strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./creep_strain_yy]
    type = RankTwoAux
    rank_two_tensor = creep_strain
    variable = creep_strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./creep_strain_zz]
    type = RankTwoAux
    rank_two_tensor = creep_strain
    variable = creep_strain_zz
    index_i = 2
    index_j = 2
  [../]
  [./creep_strain_xy]
    type = RankTwoAux
    rank_two_tensor = creep_strain
    variable = creep_strain_xy
    index_i = 0
    index_j = 1
  [../]
  [./elastic_str_xx_aux]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./elastic_str_yy_aux]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./elastic_str_zz_aux]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 3
    component = 1
    factor = -100.0
  [../]
  [./side_press]
    type = Pressure
    variable = disp_x
    boundary = 4
    component = 0
    factor = -200.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    youngs_modulus = 200e3
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputePlaneFiniteStrain
    block = 1
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    block = 1
    inelastic_models = 'powerlawcrp'
  [../]
  [./powerlawcrp]
    type = PowerLawCreepStressUpdate
    block = 1
    coefficient = 3.125e-14
    n_exponent = 5.0
    m_exponent = 0.0
    activation_energy = 0.0
    max_inelastic_increment = 0.01
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = ' lu       superlu_dist'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 100
  end_time = 1000.0
  num_steps = 10000
  l_tol = 1e-3

  [./TimeStepper]
    type = IterationAdaptiveDT
    dt = 1e-6
    time_t = '1e-6  2e-6 3e-6 5e-6 9e-6 1.7e-5 3.3e-5 6.5e-5 1.29e-4 2.57e-4 5.13e-4 1.025e-3 2.049e-3 4.097e-3 8.193e-3 1.638e-2 3.276e-2 5.734e-2 0.106 0.180 0.291 0.457 0.706 1.08 1.64 2.48 3.74 5.63 8.46 12.7 19.1 28.7 43.0 64.5 108.0 194.0 366.0 710.0 1000.0'
    time_dt = '1e-6 1e-6 2e-6 4e-6 8e-6 1.6e-5 3.2e-5 6.4e-5 1.28e-4 2.56e-4 5.12e-4 1.024e-3 2.048e-3 4.096e-3 8.192e-3 1.6384e-2 2.458e-2 4.915e-2 7.40e-2 0.111 0.166 0.249 0.374 0.560 0.840 1.26 1.89 2.83 4.25 6.40 9.6 14.3 21.5 43.0 86.1 172.0 344.0 290.0 290.0'
    optimal_iterations = 30
    iteration_window = 9
    growth_factor = 2.0
    cutback_factor = 0.5
    timestep_limiting_postprocessor = matl_ts_min
  [../]
[]

[Postprocessors]
  [./matl_ts_min]
    type = MaterialTimeStepPostprocessor
  [../]
  [./sigma_xx]
    type = ElementAverageValue
    variable = stress_xx
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./vonmises]
    type = ElementAverageValue
    variable = vonmises
  [../]
  [./pressure]
    type = ElementAverageValue
    variable = pressure
  [../]
  [./invariant3]
    type = ElementAverageValue
    variable = invariant3
  [../]
  [./eps_crp_xx]
    type = ElementAverageValue
    variable = creep_strain_xx
  [../]
  [./eps_crp_yy]
    type = ElementAverageValue
    variable = creep_strain_yy
  [../]
  [./eps_crp_zz]
    type = ElementAverageValue
    variable = creep_strain_zz
  [../]
  [./eps_crp_mag]
    type = ElementAverageValue
    variable = creep
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x3]
    type = NodalVariableValue
    nodeid = 2
    variable = disp_x
  [../]
  [./disp_y3]
    type = NodalVariableValue
    nodeid = 2
    variable = disp_y
  [../]
  [./disp_y4]
    type = NodalVariableValue
    nodeid = 3
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./elas_str_xx]
    type = ElementAverageValue
    variable = elastic_strain_xx
  [../]
  [./elas_str_yy]
    type = ElementAverageValue
    variable = elastic_strain_yy
  [../]
  [./elas_str_zz]
    type = ElementAverageValue
    variable = elastic_strain_zz
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  csv = true
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 25
  [../]
[]

modules/tensor_mechanics/test/tests/combined_creep_plasticity/combined_stress_relaxation.i

#
# 1x1x1 unit cube with constant displacement on top face
#
# This problem was taken from "Finite element three-dimensional elastic-plastic
#    creep analysis" by A. Levy, Eng. Struct., 1981, Vol. 3, January, pp. 9-16.
#
# The problem is a one-dimensional creep analysis.  The top face is displaced 0.01
#    units and held there.  The stress relaxes in time according to the creep law.
#
# The analytic solution to this problem is (contrary to what is shown in the paper):
#
#                 /      (E*ef)^3      \^(1/3)
#    stress_yy = |---------------------|
#                \ 3*a*E^4*ef^3*t + 1 /
#
#    where E  = 2.0e11  (Young's modulus)
#          a  = 3e-26  (creep coefficient)
#          ef = 0.01   (displacement)
#          t  = 2160.0    (time)
#
#    such that the analytical solution is computed to be 2.9518e3 Pa
#
# Averaged over the single element block, MOOSE calculates the stress in the yy direction to be
#     to be 3.046e3 Pa, which is a 3.2% error from the analytical solution.
#

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Functions]
  [./dts]
    type = PiecewiseLinear
    y = '1e-2 1e-1 1e0 1e1 1e2'
    x = '0    7e-1 7e0 7e1 1e2'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy creep_strain_xx creep_strain_yy creep_strain_zz elastic_strain_yy'
  [../]
[]

[BCs]
  [./u_top_pull]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.01
  [../]
  [./u_bottom_fix]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.0e11
    poissons_ratio = 0.3
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    tangent_operator = elastic
    inelastic_models = 'power_law_creep'
  [../]
  [./power_law_creep]
    type = PowerLawCreepStressUpdate
    coefficient = 3.0e-26
    n_exponent = 4
    activation_energy = 0.0
    relative_tolerance = 1e-14
    absolute_tolerance = 1e-14
  [../]
[]

[Postprocessors]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-5
  nl_abs_tol = 1e-8
  l_tol = 1e-5
  start_time = 0.0
  end_time = 2160

  [./TimeStepper]
    type = FunctionDT
    function = dts
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/elastic_patch/ad_elastic_patch_rz_nonlinear.i

#
# This problem is taken from the Abaqus verification manual:
#   "1.5.4 Patch test for axisymmetric elements"
# The stress solution is given as:
#   xx = yy = zz = 19900
#   xy = 0
#
# If strain = log(1+1e-2) = 0.00995033...
# then
# stress = E/(1+PR)/(1-2*PR)*(1-PR +PR +PR)*strain = 19900.6617
# with E = 1e6 and PR = 0.25.
#
# The code computes stress = 19900.6617 when
# increment_calculation = eigen.  There is a small error when the
# rashidapprox option is used.
#
# Since the strain is 1e-3 in all three directions, the new density should be
#   new_density = original_density * V_0 / V
#   new_density = 0.283 / (1 + 9.95e-3 + 9.95e-3 + 9,95e-3) = 0.2747973
#
# The code computes a new density of .2746770


[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = elastic_patch_rz.e
[]

[Variables]
  [./temp]
    initial_condition = 117.56
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  decomposition_method = EigenSolution
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
[]

[Kernels]
  [./heat]
    type = TimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    preset = false
    boundary = 10
    function = '1e-2*x'
  [../]
  [./uz]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = 10
    function = '1e-2*y'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Materials]
  [./density]
    type = ADDensity
    density = 0.283
    outputs = all
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/inelastic_strain/creep/creep_nl1.i

#
# Test for effective strain calculation.
# Boundary conditions from NAFEMS test NL1
#
# This is not a verification test. This is the creep analog of the same test
# in the elas_plas directory. Instead of using the IsotropicPlasticity
# material model this test uses the PowerLawCreep material model.
#
[GlobalParams]
  temperature = temp
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = one_elem2.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./temp]
    initial_condition = 600.0
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./pressure]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./creep_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./creep_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./creep_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./eff_creep_strain]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    decomposition_method = EigenSolution
  [../]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
  [./heat_ie]
    type = HeatConductionTimeDerivative
    variable = temp
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = VonMisesStress
    execute_on = timestep_end
  [../]
  [./pressure]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = pressure
    scalar_type = Hydrostatic
    execute_on = timestep_end
  [../]
  [./elastic_strain_xx]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./elastic_strain_yy]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./elastic_strain_zz]
    type = RankTwoAux
    rank_two_tensor = elastic_strain
    variable = elastic_strain_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./creep_strain_xx]
    type = RankTwoAux
    rank_two_tensor = creep_strain
    variable = creep_strain_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./creep_strain_yy]
    type = RankTwoAux
    rank_two_tensor = creep_strain
    variable = creep_strain_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./creep_strain_zz]
    type = RankTwoAux
    rank_two_tensor = creep_strain
    variable = creep_strain_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./tot_strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = tot_strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./tot_strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = tot_strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./tot_strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = tot_strain_zz
    index_i = 2
    index_j = 2
  [../]
  [./eff_creep_strain]
    type = MaterialRealAux
    property = effective_creep_strain
    variable = eff_creep_strain
  [../]
[]

[Functions]
  [./appl_dispy]
    type = PiecewiseLinear
    x = '0     1.0     2.0'
    y = '0.0 0.25e-4 0.50e-4'
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 101
    value = 0.0
  [../]
  [./origin_x]
    type = DirichletBC
    variable = disp_x
    boundary = 103
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 102
    value = 0.0
  [../]
  [./origin_y]
    type = DirichletBC
    variable = disp_y
    boundary = 103
    value = 0.0
  [../]
  [./top_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = appl_dispy
  [../]
  [./temp_fix]
    type = DirichletBC
    variable = temp
    boundary = '1 2'
    value = 600.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    youngs_modulus = 250e9
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputePlaneFiniteStrain
    block = 1
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    block = 1
    inelastic_models = 'powerlawcrp'
  [../]
  [./powerlawcrp]
    type = PowerLawCreepStressUpdate
    block = 1
    coefficient = 3.125e-14
    n_exponent = 5.0
    m_exponent = 0.0
    activation_energy = 0.0
  [../]
  [./thermal]
    type = HeatConductionMaterial
    block = 1
    specific_heat = 1.0
    thermal_conductivity = 100.
  [../]
  [./density]
    type = Density
    block = 1
    density = 1.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-12
  l_tol = 1e-6
  l_max_its = 100
  nl_max_its = 20

  dt = 1.0
  start_time = 0.0
  num_steps = 100
  end_time = 2.0
[]

[Postprocessors]
  [./stress_xx]
    type = ElementAverageValue
    variable = stress_xx
  [../]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./stress_xy]
    type = ElementAverageValue
    variable = stress_xy
  [../]
  [./vonmises]
    type = ElementAverageValue
    variable = vonmises
  [../]
  [./pressure]
    type = ElementAverageValue
    variable = pressure
  [../]
  [./el_strain_xx]
    type = ElementAverageValue
    variable = elastic_strain_xx
  [../]
  [./el_strain_yy]
    type = ElementAverageValue
    variable = elastic_strain_yy
  [../]
  [./el_strain_zz]
    type = ElementAverageValue
    variable = elastic_strain_zz
  [../]
  [./crp_strain_xx]
    type = ElementAverageValue
    variable = creep_strain_xx
  [../]
  [./crp_strain_yy]
    type = ElementAverageValue
    variable = creep_strain_yy
  [../]
  [./crp_strain_zz]
    type = ElementAverageValue
    variable = creep_strain_zz
  [../]
  [./eff_creep_strain]
    type = ElementAverageValue
    variable = eff_creep_strain
  [../]
  [./tot_strain_xx]
    type = ElementAverageValue
    variable = tot_strain_xx
  [../]
  [./tot_strain_yy]
    type = ElementAverageValue
    variable = tot_strain_yy
  [../]
  [./tot_strain_zz]
    type = ElementAverageValue
    variable = tot_strain_zz
  [../]
  [./disp_x1]
    type = NodalVariableValue
    nodeid = 0
    variable = disp_x
  [../]
  [./disp_x4]
    type = NodalVariableValue
    nodeid = 3
    variable = disp_x
  [../]
  [./disp_y1]
    type = NodalVariableValue
    nodeid = 0
    variable = disp_y
  [../]
  [./disp_y4]
    type = NodalVariableValue
    nodeid = 3
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
[]

[Outputs]
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/recompute_radial_return/affine_plasticity.i

# Affine Plasticity Test for Transient Stress Eigenvalues with Stationary Eigenvectors

# This test is taken from K. Jamojjala, R. Brannon, A. Sadeghirad, J. Guilkey,
#  "Verification tests in solid mechanics," Engineering with Computers, Vol 31.,
#  p. 193-213.

# The test involves applying particular strains and expecting particular stresses.

# The material properties are:
#  Yield in shear     165 MPa
#  Shear modulus       79 GPa
#  Poisson's ratio    1/3

# The strains are:
#  Time        e11        e22        e33
#  0             0          0          0
#  1        -0.003     -0.003      0.006
#  2    -0.0103923          0  0.0103923

# The expected stresses are:
#  sigma11:
#   -474*t                             0 < t <= 0.201
#   -95.26                             0.201 < t <= 1
#   (189.4+0.1704*sqrt(a)-0.003242*a)
#   ---------------------------------  1 < t <= 2
#            1+0.00001712*a
#   -189.4                             t > 2 (paper erroneously gives a positive value)
#
#  sigma22:
#   -474*t                             0 < t <= 0.201
#   -95.26                             0.201 < t <= 1
#   -(76.87+1.443*sqrt(a)-0.001316*a)
#   ---------------------------------  1 < t <= 2 (paper gives opposite sign)
#             1+0.00001712*a
#   76.87                              t > 2
#
#  sigma33:
#   948*t                              0 < t <= 0.201
#   190.5                              0.201 < t <= 1
#   -(112.5-1.272*sqrt(a)-0.001926*a)
#   ---------------------------------  1 < t <= 2 (paper has two sign errors here)
#            1+0.00001712*a
#   112.5                              t > 2
#
#  where a = exp(12.33*t).
#
# Note: If planning to run this case with strain type ComputeFiniteStrain, the
#   displacement function must be adjusted.  Instead of
#     strain = (l - l0)/l0 = (u+l0 - l0)/l0 = u/l0
#   with l0=1.0, we would have
#     strain = log(l/l0) = log((u+l0)/l0)
#   with l0=1.0.  So, for strain = -0.003,
#     -0.003 = log((u+l0)/l0) ->
#     u = exp(-0.003)*l0 - l0 = -0.0029955044966269995.
#


[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  block = '0'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  # This test uses ElementalVariableValue postprocessors on specific
  # elements, so element numbering needs to stay unchanged
  allow_renumbering = false
[]

[Functions]
  [./disp_x]
    type = PiecewiseLinear
    x = '0.  1.     2.'
    y = '0. -0.003 -0.0103923'
  [../]
  [./disp_y]
    type = PiecewiseLinear
    x = '0.  1.    2.'
    y = '0. -0.003 0.'
  [../]
  [./disp_z]
    type = PiecewiseLinear
    x = '0. 1.    2.'
    y = '0. 0.006 0.0103923'
  [../]
  [./stress_xx]
    type = ParsedFunction
    # The paper gives 0.201 as the time at initial yield, but 0.20097635952803425 is the exact value.
    # The paper gives -95.26 MPa as the stress at yield, but -95.26279441628823 is the exact value.
    # The paper gives 12.33 as the factor in the exponential, but 12.332921390339125 is the exact value.
    # 189.409039923814000, 0.170423791206825, -0.003242011311945, 1.711645501845780E-05 - exact values
    vars = 'timeAtYield stressAtYield expFac a b c d'
    vals = '0.20097635952803425 -95.26279441628823 12.332921390339125 189.409039923814000 0.170423791206825 -0.003242011311945 1.711645501845780E-05'
    value = '1e6*
             if(t<=timeAtYield, -474*t,
             if(t<=1, stressAtYield,
             (a+b*sqrt(exp(expFac*t))+c*exp(expFac*t))/(1.0+d*exp(expFac*t))))' # tends to -a
  [../]
  [./stress_yy]
    type = ParsedFunction
    # The paper gives 0.201 as the time at initial yield, but 0.20097635952803425 is the exact value.
    # the paper gives -95.26 MPa as the stress at yield, but -95.26279441628823 is the exact value.
    # The paper gives 12.33 as the factor in the exponential, but 12.332921390339125 is the exact value.
    # -76.867432297315000, -1.442488120272900, 0.001315697947301, 1.711645501845780E-05 - exact values
    vars = 'timeAtYield stressAtYield expFac a b c d'
    vals = '0.20097635952803425 -95.26279441628823 12.332921390339125 -76.867432297315000 -1.442488120272900 0.001315697947301 1.711645501845780E-05'
    value = '1e6*
             if(t<=timeAtYield, -474*t,
             if(t<=1, stressAtYield,
             (a+b*sqrt(exp(expFac*t))+c*exp(expFac*t))/(1.0+d*exp(expFac*t))))' # tends to -a
  [../]
  [./stress_zz]
    type = ParsedFunction
    # The paper gives 0.201 as the time at initial yield, but 0.20097635952803425 is the exact value.
    # the paper gives 190.5 MPa as the stress at yield, but 190.52558883257645 is the exact value.
    # The paper gives 12.33 as the factor in the exponential, but 12.332921390339125 is the exact value.
    # -112.541607626499000, 1.272064329066080, 0.001926313364644, 1.711645501845780E-05 - exact values
    vars = 'timeAtYield stressAtYield expFac a b c d'
    vals = '0.20097635952803425 190.52558883257645 12.332921390339125 -112.541607626499000 1.272064329066080 0.001926313364644 1.711645501845780E-05'
    value = '1e6*
             if(t<=timeAtYield, 948*t,
             if(t<=1, stressAtYield,
             (a+b*sqrt(exp(expFac*t))+c*exp(expFac*t))/(1.0+d*exp(expFac*t))))' # tends to -a
  [../]
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./plastic_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]

[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = 'timestep_end'
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = 'timestep_end'
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = 'timestep_end'
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = vonmisesStress
    execute_on = 'timestep_end'
  [../]

  [./plastic_strain_xx]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_xx
    index_i = 0
    index_j = 0
    execute_on = 'timestep_end'
  [../]
  [./plastic_strain_yy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_yy
    index_i = 1
    index_j = 1
    execute_on = 'timestep_end'
  [../]
  [./plastic_strain_zz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_strain_zz
    index_i = 2
    index_j = 2
    execute_on = 'timestep_end'
  [../]
[]

[BCs]
  [./fixed_x]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./fixed_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./fixed_z]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]

  [./disp_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = right
    function = disp_x
  [../]
  [./disp_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = disp_y
  [../]
  [./disp_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = disp_z
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 210666666666.666667
    poissons_ratio = 0.3333333333333333
  [../]

  [./strain]
    type = ComputeIncrementalSmallStrain
  [../]

  [./isotropic_plasticity]
    type = IsotropicPlasticityStressUpdate
    yield_stress = 285788383.2488647 # = sqrt(3)*165e6 = sqrt(3) * yield in shear
    hardening_constant = 0.0
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    tangent_operator = elastic
    inelastic_models = 'isotropic_plasticity'
  [../]
[]

[Executioner]

  type = Transient

  solve_type = 'PJFNK'
  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  nl_abs_tol = 1e-10

  l_max_its = 20

  start_time = 0.0
  dt = 0.01 # use 0.0001 for a nearly exact match
  end_time = 2.0
[]

[Postprocessors]
  [./analytic_xx]
    type = FunctionValuePostprocessor
    function = stress_xx
  [../]
  [./analytic_yy]
    type = FunctionValuePostprocessor
    function = stress_yy
  [../]
  [./analytic_zz]
    type = FunctionValuePostprocessor
    function = stress_zz
  [../]

  [./stress_xx]
    type = ElementalVariableValue
    variable = stress_xx
    elementid = 0
  [../]
  [./stress_yy]
    type = ElementalVariableValue
    variable = stress_yy
    elementid = 0
  [../]
  [./stress_zz]
    type = ElementalVariableValue
    variable = stress_zz
    elementid = 0
  [../]

  [./stress_xx_l2_error]
    type = ElementL2Error
    variable = stress_xx
    function = stress_xx
  [../]
  [./stress_yy_l2_error]
    type = ElementL2Error
    variable = stress_yy
    function = stress_yy
  [../]
  [./stress_zz_l2_error]
    type = ElementL2Error
    variable = stress_zz
    function = stress_zz
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/2D_different_planes/planestrain_xy.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
 file = square_xy_plane.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./plane_strain]
    block = 1
    strain = SMALL
    out_of_plane_direction = z
    planar_formulation = PLANE_STRAIN
    eigenstrain_names = 'eigenstrain'
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy strain_zz'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 3
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 3
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_stress]
    type = ComputeLinearElasticStress
    block = 1
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-10

# controls for nonlinear iterations
  nl_max_its = 10
  nl_rel_tol = 1e-12

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  file_base = planestrain_xy_small_out
  [./exodus]
    type = Exodus
  [../]
[]

modules/combined/test/tests/contact/4ElemTensionRelease.i

[Mesh]
  file = 4ElemTensionRelease.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[Functions]
  [./up]
    type = PiecewiseLinear
    x = '0 1      2 3'
    y = '0 0.0001 0 -.0001'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  []
[]

[Contact]
  [./dummy_name]
    master = 2
    slave = 3
    penalty = 1e6
    model = frictionless
    tangential_tolerance = 0.01
    system = Constraint
  [../]
[]

[BCs]
  [./lateral]
    type = DirichletBC
    variable = disp_x
    boundary = '1 4'
    value = 0
  [../]

  [./bottom_up]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = up
  [../]

  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1.0e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre    boomeramg      101'

  line_search = 'none'
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  l_tol = 1e-4

  l_max_its = 100
  nl_max_its = 10
  dt = 0.2
  dtmin = 0.2
  end_time = 3

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/thermal_expansion/ad_constant_expansion_coeff.i

# This test involves only thermal expansion strains on a 2x2x2 cube of approximate
# steel material.  An initial temperature of 25 degrees C is given for the material,
# and an auxkernel is used to calculate the temperature in the entire cube to
# raise the temperature each time step.  After the first timestep,in which the
# temperature jumps, the temperature increases by 6.25C each timestep.
# The thermal strain increment should therefore be
#     6.25 C * 1.3e-5 1/C = 8.125e-5 m/m.

# This test is also designed to be used to identify problems with restart files

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./temp]
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t*(500.0)+300.0
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        strain = SMALL
        incremental = true
        add_variables = true
        eigenstrain_names = eigenstrain
        generate_output = 'strain_xx strain_yy strain_zz'
        use_automatic_differentiation = true
      [../]
    [../]
  [../]
[]

[Kernels]
  [./tempfuncaux]
    type = Diffusion
    variable = temp
  [../]
[]

[BCs]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp]
    type = FunctionDirichletBC
    variable = temp
    function = temperature_load
    boundary = 'left right'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ADComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ADComputeThermalExpansionEigenstrain
    stress_free_temperature = 298
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  end_time = 0.075
  dt = 0.0125
  dtmin = 0.0001
[]

[Outputs]
  csv = true
  exodus = true
[]

[Postprocessors]
  [./strain_xx]
    type = ElementAverageValue
    variable = strain_xx
  [../]
  [./strain_yy]
    type = ElementAverageValue
    variable = strain_yy
  [../]
  [./strain_zz]
    type = ElementAverageValue
    variable = strain_zz
  [../]
  [./temperature]
    type = AverageNodalVariableValue
    variable = temp
  [../]
[]

modules/combined/test/tests/simple_contact/merged.i

[GlobalParams]
  volumetric_locking_correction= false
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = merged.e
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[DiracKernels]
  [./master_x]
    type = ContactMaster
    variable = disp_x
    component = 0
    boundary = 3
    slave = 2
  [../]

  [./master_y]
    type = ContactMaster
    variable = disp_y
    component = 1
    boundary = 3
    slave = 2
  [../]

  [./master_z]
    type = ContactMaster
    variable = disp_z
    component = 2
    boundary = 3
    slave = 2
  [../]

  [./slave_x]
    type = SlaveConstraint
    variable = disp_x
    component = 0
    boundary = 2
    master = 3
  [../]

  [./slave_y]
    type = SlaveConstraint
    variable = disp_y
    component = 1
    boundary = 2
    master = 3
  [../]

  [./slave_z]
    type = SlaveConstraint
    variable = disp_z
    component = 2
    boundary = 2
    master = 3
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./left_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.0001
  [../]

  [./right_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]

  [./right_z]
    type = DirichletBC
    variable = disp_z
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type '
  petsc_options_value = 'lu       '

  line_search = 'none'

  nl_abs_tol = 1e-8

  l_max_its = 20
  dt = 1.0
  num_steps = 1
[]

[Outputs]
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/tensor_mechanics/test/tests/truss/truss_hex.i

# This test is designed to check
# whether truss element works well with other multi-dimensional element
# e.g. the hex element in this case, by assigning different brock number
# to different types of elements.
[Mesh]
  type = FileMesh
  file = truss_hex.e
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./axial_stress]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./e_over_l]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./area]
    order = CONSTANT
    family = MONOMIAL
#    initial_condition = 1.0
  [../]
  [./react_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./react_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./react_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Functions]
  [./x2]
    type = PiecewiseLinear
    x = '0  1 2 3'
    y = '0 .5 1 1'
  [../]
  [./y2]
    type = PiecewiseLinear
    x = '0 1  2 3'
    y = '0 0 .5 1'
  [../]
[]

[BCs]
  [./fixx1]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./fixy1]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0
  [../]
  [./fixz1]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0
  [../]

  [./fixx2]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0
  [../]
  [./fixz2]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0
  [../]

  [./fixDummyHex_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1000
    value = 0
  [../]

  [./fixDummyHex_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1000
    value = 0
  [../]

  [./fixDummyHex_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1000
    value = 0
  [../]
[]

[DiracKernels]
  [./pull]
    type = ConstantPointSource
    value = -25
    point = '0 -2 0'
    variable = disp_y
  [../]
[]

[AuxKernels]
  [./axial_stress]
    type = MaterialRealAux
    block = '1 2'
    property = axial_stress
    variable = axial_stress
  [../]
  [./e_over_l]
    type = MaterialRealAux
    block = '1 2'
    property = e_over_l
    variable = e_over_l
  [../]
  [./area1]
    type = ConstantAux
    block = 1
    variable = area
    value = 1.0
    execute_on = 'initial timestep_begin'
  [../]
  [./area2]
    type = ConstantAux
    block = 2
    variable = area
    value = 0.25
    execute_on = 'initial timestep_begin'
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK

  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'jacobi   101'

  nl_max_its = 15
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-10

  dt = 1
  num_steps = 1
  end_time = 1
[]

[Kernels]
  [./truss_x]
    type = StressDivergenceTensorsTruss
    block = '1 2'
    variable = disp_x
    displacements = 'disp_x disp_y disp_z'
    component = 0
    area = area
    save_in = react_x
  [../]
  [./truss_y]
    type = StressDivergenceTensorsTruss
    block = '1 2'
    variable = disp_y
    component = 1
    displacements = 'disp_x disp_y disp_z'
    area = area
    save_in = react_y
  [../]
  [./truss_z]
    type = StressDivergenceTensorsTruss
    block = '1 2'
    variable = disp_z
    component = 2
    displacements = 'disp_x disp_y disp_z'
    area = area
    save_in = react_z
  [../]
  [./TensorMechanics]
    block = 1000
    displacements = 'disp_x disp_y disp_z'
  [../]
#  [./hex_x]
#    type = StressDivergenceTensors
#    block = 1000
#    variable = disp_x
#    component = 0
#    displacements = 'disp_x disp_y disp_z'
#  [../]
#  [./hex_y]
#    type = StressDivergenceTensors
#    block = 1000
#    variable = disp_y
#    component = 1
#    displacements = 'disp_x disp_y disp_z'
#  [../]
#  [./hex_z]
#    type = StressDivergenceTensors
#    block = 1000
#    variable = disp_z
#    component = 2
#    displacements = 'disp_x disp_y disp_z'
#  [../]
[]

[Materials]
   [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1000
    youngs_modulus = 1e6
    poissons_ratio = 0
  [../]
  [./strain]
    type = ComputeSmallStrain
    block = 1000
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    type = ComputeLinearElasticStress
    block = 1000
  [../]
  [./linelast]
    type = LinearElasticTruss
    block = '1 2'
    displacements = 'disp_x disp_y disp_z'
    youngs_modulus = 1e6
  [../]
[]

[Outputs]
  exodus = true
[]

modules/peridynamics/test/tests/simple_tests/2D_irregularD_variableH_OSPD.i

# Test for ordinary state-based peridynamic formulation
# for irregular grid from file mesh with varying bond constants
# partial Jacobian
# Jacobian from bond-based formulation is used for preconditioning

# Square plate with Dirichlet boundary conditions applied
# at the left, top and bottom edges

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./fmg]
    type = FileMeshGenerator
    file = square.e
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = fmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1001
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1004
    value = 0.0
  [../]
  [./bottom_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1002
    function = '-0.001 * t'
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = ORDINARY_STATE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.0
  [../]

  [./force_density]
    type = ComputeSmallStrainVariableHorizonMaterialOSPD
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none
  start_time = 0
  end_time = 1
[]

[Outputs]
  file_base = 2D_irregularD_variableH_OSPD
  exodus = true
[]

modules/tensor_mechanics/test/tests/volumetric_eigenstrain/volumetric_mechanical.i

# This test ensures that the reported volumetric strain for a cube with
# mechanically imposed displacements (through Dirichlet BCs) exactly
# matches that from a version of this test that experiences the same
# defomation, but due to imposed eigenstrains.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./volumetric_strain]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./master]
    use_displaced_mesh = true
    strain = FINITE
    decomposition_method = EigenSolution #Necessary for exact solution
  [../]
[]

[AuxKernels]
  [./volumetric_strain]
    type = RankTwoScalarAux
    scalar_type = VolumetricStrain
    rank_two_tensor = total_strain
    variable = volumetric_strain
  [../]
[]

[Functions]
  [pres_disp]
    type = PiecewiseLinear
    # These values are taken from the displacements in the eigenstrain
    # version of this test. The volume of the cube (which starts out as
    # a 1x1x1 cube) is (1 + disp)^3. At time 2, this is
    # (1.44224957030741)^3, which is 3.0.
    xy_data = '0 0
               1 0.25992104989487
               2 0.44224957030741'
  []
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./right]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = right
    function = pres_disp
  [../]
  [./top]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = pres_disp
  [../]
  [./front]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = pres_disp
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./finite_strain_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./volumetric_change]
    type = GenericFunctionMaterial
    prop_names = volumetric_change
    prop_values = t
  [../]
[]

[Postprocessors]
  [./vol]
    type = VolumePostprocessor
    use_displaced_mesh = true
    execute_on = 'initial timestep_end'
  [../]
  [./volumetric_strain]
    type = ElementalVariableValue
    variable = volumetric_strain
    elementid = 0
  [../]
  [./disp_right]
    type = NodalMaxValue
    variable = disp_x
    boundary = right
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  l_max_its = 100
  l_tol = 1e-4
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-12

  start_time = 0.0
  end_time = 2.0
  dt = 1.0
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/power_law_creep/power_law_creep_restart2.i

# 1x1x1 unit cube with uniform pressure on top face

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
    initial_condition = 1000.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy creep_strain_xx creep_strain_yy creep_strain_zz elastic_strain_yy'
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1'
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
  [./heat_ie]
    type = HeatConductionTimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./u_top_pull]
    type = Pressure
    variable = disp_y
    component = 1
    boundary = top
    factor = -10.0e6
    function = top_pull
  [../]
  [./u_bottom_fix]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp_fix]
    type = DirichletBC
    variable = temp
    boundary = 'bottom top'
    value = 1000.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e11
    poissons_ratio = 0.3
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'power_law_creep'
    tangent_operator = elastic
  [../]
  [./power_law_creep]
    type = PowerLawCreepStressUpdate
    coefficient = 1.0e-15
    n_exponent = 4
    activation_energy = 3.0e5
    temperature = temp
  [../]

  [./thermal]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 100.
  [../]
  [./density]
    type = Density
    density = 1.0
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 20
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-6
  l_tol = 1e-5
  start_time = 0.6
  end_time = 1.0
  num_steps = 12
  dt = 0.1
[]

[Outputs]
  file_base = power_law_creep_out
  exodus = true
[]

[Problem]
  restart_file_base = power_law_creep_restart1_out_cp/0006
[]

modules/combined/test/tests/sliding_block/sliding/constraint/frictional_02_aug.i

#  This is a benchmark test that checks constraint based frictional
#  contact using the augmented lagrangian method.  In this test a constant
#  displacement is applied in the horizontal direction to simulate
#  a small block come sliding down a larger block.
#
#  A friction coefficient of 0.2 is used.  The gold file is run on one processor
#  and the benchmark case is run on a minimum of 4 processors to ensure no
#  parallel variability in the contact pressure and penetration results.
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = false
[]

[AuxVariables]
  [./contact_traction]
  [../]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]


[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 200
  dt = 0.1
  end_time = 15
  num_steps = 200
  l_tol = 1e-6
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  solution_variables = 'disp_x disp_y'
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  maximum_lagrangian_update_iterations = 100
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = coulomb
    penalty = 1e+7
    friction_coefficient = 0.2
    formulation = augmented_lagrange
    system = constraint
    normalize_penalty = true
    al_penetration_tolerance = 1e-6
    al_incremental_slip_tolerance = 1.0e-2
    al_frictional_force_tolerance =  1e-3
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

modules/tensor_mechanics/tutorials/basics/part_3_1.i

#Tensor Mechanics tutorial: the basics
#Step 3, part 1
#3D simulation of uniaxial tension with J2 plasticity

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  [file_mesh]
    type = FileMeshGenerator
    file = necking_quad4.e
  []
  [extrude]
    type = MeshExtruderGenerator
    extrusion_vector = '0 0 0.5'
    num_layers = 2
    bottom_sideset = 'back'
    top_sideset = 'front'
    input = file_mesh
  []
  uniform_refine = 0
  second_order = true
[]

[Modules/TensorMechanics/Master]
  [./block1]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_yy strain_yy'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeMultiPlasticityStress
    ep_plastic_tolerance = 1e-9
    plastic_models = J2
  [../]
[]

[UserObjects]
  [./hardening]
    type = TensorMechanicsHardeningCubic
    value_0 = 2.4e2
    value_residual = 3.0e2
    internal_0 = 0
    internal_limit = 0.005
  [../]
  [./J2]
    type = TensorMechanicsPlasticJ2
    yield_strength = hardening
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x #change the variable to reflect the new displacement names
    boundary = 1
    value = 0.0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z #change the variable to reflect the new displacement names
    boundary = back
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y #change the variable to reflect the new displacement names
    boundary = 3
    value = 0.0
  [../]
  [./top]
    type = FunctionDirichletBC
    variable = disp_y #change the variable to reflect the new displacement names
    boundary = 4
    function = '0.0007*t'
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.25
  end_time = 16

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -sub_pc_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm lu 1 101'
[]

[Postprocessors]
  [./ave_stress_bottom]
    type = SideAverageValue
    variable = stress_yy
    boundary = 3
  [../]
  [./ave_strain_bottom]
    type = SideAverageValue
    variable = strain_yy
    boundary = 3
  [../]
[]

[Outputs]
  exodus = true
  perf_graph = true
  csv = true
  print_linear_residuals = false
[]

modules/tensor_mechanics/test/tests/domain_integral_thermal/interaction_integral_2d_rot.i

#This problem from [Wilson 1979] tests the thermal strain term in the
#interaction integral
#
#theta_e = 10 degrees C; a = 252; E = 207000; nu = 0.3; alpha = 1.35e-5
#
#With uniform_refine = 3, KI converges to
#KI = 5.602461e+02 (interaction integral)
#KI = 5.655005e+02 (J-integral)
#
#Both are in good agreement with [Shih 1986]:
#average_value = 0.4857 = KI / (sigma_theta * sqrt(pi * a))
#sigma_theta = E * alpha * theta_e / (1 - nu)
# = 207000 * 1.35e-5 * 10 / (1 - 0.3) = 39.9214
#KI = average_value * sigma_theta * sqrt(pi * a) = 5.656e+02
#
#References:
#W.K. Wilson, I.-W. Yu, Int J Fract 15 (1979) 377-387
#C.F. Shih, B. Moran, T. Nakamura, Int J Fract 30 (1986) 79-102

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = False
[]

[Mesh]
  displacements = 'disp_x disp_y'
  [file_mesh]
    type = FileMeshGenerator
    file = crack2d.e
  []
  [rotate]
    type = TransformGenerator
    transform = ROTATE
    vector_value = '0 0 90'
    input = file_mesh
  []
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]


[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = 10.0*(2*y/504)
  [../]
[]

[DomainIntegral]
  integrals = 'JIntegral InteractionIntegralKI'
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '0 1 0'
  2d = true
  axis_2d = 2
  radius_inner = '60.0 80.0 100.0 120.0'
  radius_outer = '80.0 100.0 120.0 140.0'
  convert_J_to_K = true
  symmetry_plane = 0
  incremental = true

  # interaction integral parameters
  disp_x = disp_x
  disp_y = disp_y
  block = 1
  youngs_modulus = 207000
  poissons_ratio = 0.3
  temperature = temp
  eigenstrain_names = thermal_expansion
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
    eigenstrain_names = thermal_expansion
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    block = 1
  [../]
[]

[BCs]
  [./crack_x]
    type = DirichletBC
    variable = disp_x
    boundary = 100
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 400
    value = 0.0
  [../]
  [./no_y1]
    type = DirichletBC
    variable = disp_y
    boundary = 900
    value = 0.0
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 0.0
    thermal_expansion_coeff = 1.35e-5
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]
[]


[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart -sub_ksp_type -sub_pc_type -pc_asm_overlap'
  petsc_options_value = 'asm         31   preonly   lu      1'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 40

   nl_rel_step_tol= 1e-10
   nl_rel_tol = 1e-10


   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1

[]

[Outputs]
  file_base = interaction_integral_2d_rot_out
  exodus = true
  csv = true
[]

[Preconditioning]
  active = 'smp'
  [./smp]
    type = SMP
    pc_side = left
    ksp_norm = preconditioned
    full = true
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update34.i

# MC update version, with only MohrCoulomb, cohesion=40, friction angle = 35deg, psi = 5deg, smoothing_tol = 0.5
# Compressive strength = 1MPa
# Lame lambda = 1E3.  Lame mu = 1.3E3

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E2
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 4E1
  [../]
  [./phi]
    type = TensorMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./psi]
    type = TensorMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-100.1 -0.1 0.2  -0.1 -0.9 0  0.2 0 -1.1'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = phi
    dilation_angle = psi
    smoothing_tol = 0.5
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/frictionless_kinematic.i

[Mesh]
  file = blocks_2d.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    #Initial gap is 0.01
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  [../]
  [./right]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.01
  end_time = 0.10
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-8
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    system = Constraint
    master = 2
    slave = 3
    model = frictionless
    penalty = 1e+6
  [../]
[]

modules/combined/test/tests/sliding_block/in_and_out/constraint/frictional_lm.i

[Mesh]
  patch_size = 80
  [file]
    type = FileMeshGenerator
    file = sliding_elastic_blocks_2d.e
  []
  [slave]
    input = file
    type = LowerDBlockFromSidesetGenerator
    sidesets = '3'
    new_block_id = '30'
  []
  [master]
    input = slave
    type = LowerDBlockFromSidesetGenerator
    sidesets = '2'
    new_block_id = '20'
  []
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Variables]
  [normal_lm]
    block = '30'
  []
  [tangential_lm]
    block = '30'
    family = MONOMIAL
    order = CONSTANT
  []
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = horizontal_movement
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    block = '1 2'
  [../]
[]

[Materials]
  [./tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_ksp_ew'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 15
  dt = 0.1
  dtmin = 0.01
  l_max_its = 30
  nl_max_its = 20
  line_search = 'none'
  timestep_tolerance = 1e-6

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  sync_times = '1 2 3 4 5 6 7 8 9 10 11 12 13 14 15'
  [out]
    type = Exodus
    sync_only = true
  []
  [dof]
    execute_on = 'initial'
    type = DOFMap
  []
  [csv]
    type = CSV
    execute_on = 'nonlinear timestep_end'
  []
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
  [./horizontal_movement]
    type = ParsedFunction
    value = -0.04*sin(4*t)+0.02
  [../]
[]

[Constraints]
  [./lm]
    type = NormalNodalLMMechanicalContact
    slave = 3
    master = 2
    variable = normal_lm
    master_variable = disp_x
    disp_y = disp_y
    ncp_function_type = min
    use_displaced_mesh = true
    c = 1e6 # relative scale difference between pressure and gap
  [../]
  [normal_x]
    type = NormalMortarMechanicalContact
    master_boundary = '2'
    slave_boundary = '3'
    master_subdomain = '20'
    slave_subdomain = '30'
    variable = normal_lm
    slave_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
  []
  [normal_y]
    type = NormalMortarMechanicalContact
    master_boundary = '2'
    slave_boundary = '3'
    master_subdomain = '20'
    slave_subdomain = '30'
    variable = normal_lm
    slave_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
  []
  [tangential_lm]
    type = TangentialMortarLMMechanicalContact
    master_boundary = '2'
    slave_boundary = '3'
    master_subdomain = '20'
    slave_subdomain = '30'
    variable = tangential_lm
    slave_variable = disp_x
    slave_disp_y = disp_y
    use_displaced_mesh = true
    compute_primal_residuals = false
    contact_pressure = normal_lm
    friction_coefficient = .4
    ncp_function_type = fb
    c = 1000 # relative scale difference between pressure and velocity
  []
  [tangential_x]
    type = TangentialMortarMechanicalContact
    master_boundary = '2'
    slave_boundary = '3'
    master_subdomain = '20'
    slave_subdomain = '30'
    variable = tangential_lm
    slave_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
  []
  [tangential_y]
    type = TangentialMortarMechanicalContact
    master_boundary = '2'
    slave_boundary = '3'
    master_subdomain = '20'
    slave_subdomain = '30'
    variable = tangential_lm
    slave_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
  []
[]

[Postprocessors]
  [./num_nl]
    type = NumNonlinearIterations
  [../]
  [./cumulative]
    type = CumulativeValuePostprocessor
    postprocessor = num_nl
  [../]
  [lin]
    type = NumLinearIterations
  []
  [cum_lin]
    type = CumulativeValuePostprocessor
    postprocessor = lin
  []
  [contact]
    type = ContactDOFSetSize
    variable = normal_lm
    subdomain = '30'
    execute_on = 'nonlinear timestep_end'
  []
[]

modules/tensor_mechanics/test/tests/strain_energy_density/incr_model.i

# Single element test to check the strain energy density calculation

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 1
  ny = 1
  xmin = 0
  xmax = 1
  ymin = 0
  ymax = 2
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstantUp]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -100
  [../]
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress strain_xx strain_yy strain_zz'
    planar_formulation = PLANE_STRAIN
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0.0
  [../]
  [./Pressure]
    [./top]
      boundary = 'top'
      function = rampConstantUp
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 30e+6
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./strain_energy_density]
    type = StrainEnergyDensity
    incremental = true
  [../]
[]

[Executioner]
   type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 20
   nl_abs_tol = 3e-7
   nl_rel_tol = 1e-12
   l_tol = 1e-2

   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1
[]

[Postprocessors]
  [./epxx]
    type = ElementalVariableValue
    variable = strain_xx
    elementid = 0
  [../]
  [./epyy]
    type = ElementalVariableValue
    variable = strain_yy
    elementid = 0
  [../]
  [./epzz]
    type = ElementalVariableValue
    variable = strain_zz
    elementid = 0
  [../]
  [./sigxx]
    type = ElementAverageValue
    variable = stress_xx
  [../]
  [./sigyy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigzz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./SED]
    type = ElementAverageValue
    variable = SED
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/cavity_pressure/3d.i

#
# Cavity Pressure Test
#
# This test is designed to compute an internal pressure based on
#   p = n * R * T / V
# where
#   p is the pressure
#   n is the amount of material in the volume (moles)
#   R is the universal gas constant
#   T is the temperature
#   V is the volume
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total
#   initial volume is 7.
# The test adjusts n, T, and V in the following way:
#   n => n0 + alpha * t
#   T => T0 + beta * t
#   V => V0 + gamma * t
# with
#   alpha = n0
#   beta = T0 / 2
#   gamma = - (0.003322259...) * V0
#   T0 = 240.54443866068704
#   V0 = 7
#   n0 = f(p0)
#   p0 = 100
#   R = 8.314472 J * K^(-1) * mol^(-1)
#
# So, n0 = p0 * V0 / R / T0 = 100 * 7 / 8.314472 / 240.544439
#        = 0.35
#
# The parameters combined at t = 1 gives p = 301.
#

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = 3d.e
[]

[Functions]
  [./displ_positive]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.0029069767441859684'
  [../]
  [./displ_negative]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 -0.0029069767441859684'
  [../]
  [./temp1]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1.5'
    scale_factor = 240.54443866068704
  [../]
  [./material_input_function]
    type = PiecewiseLinear
    x = '0    1'
    y = '0 0.35'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./temp]
    initial_condition = 240.54443866068704
  [../]
  [./material_input]
  [../]
[]

[AuxVariables]
  [./pressure_residual_x]
  [../]
  [./pressure_residual_y]
  [../]
  [./pressure_residual_z]
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zx]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
  [./heat]
    type = Diffusion
    variable = temp
    use_displaced_mesh = true
  [../]
  [./material_input_dummy]
    type = Diffusion
    variable = material_input
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 2
    variable = stress_yz
  [../]
  [./stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 0
    variable = stress_zx
  [../]
[]

[BCs]
  [./no_x_exterior]
    type = DirichletBC
    variable = disp_x
    boundary = '7 8'
    value = 0.0
  [../]
  [./no_y_exterior]
    type = DirichletBC
    variable = disp_y
    boundary = '9 10'
    value = 0.0
  [../]
  [./no_z_exterior]
    type = DirichletBC
    variable = disp_z
    boundary = '11 12'
    value = 0.0
  [../]
  [./prescribed_left]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 13
    function = displ_positive
  [../]
  [./prescribed_right]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 14
    function = displ_negative
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = '15 16'
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = '17 18'
    value = 0.0
  [../]
  [./no_x_interior]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./no_y_interior]
    type = DirichletBC
    variable = disp_y
    boundary = '3 4'
    value = 0.0
  [../]
  [./no_z_interior]
    type = DirichletBC
    variable = disp_z
    boundary = '5 6'
    value = 0.0
  [../]
  [./temperatureInterior]
    type = FunctionDirichletBC
    boundary = 100
    function = temp1
    variable = temp
  [../]
  [./MaterialInput]
    type = FunctionDirichletBC
    boundary = '100 13 14 15 16'
    function = material_input_function
    variable = material_input
  [../]
  [./CavityPressure]
    [./1]
      boundary = 100
      initial_pressure = 100
      material_input = materialInput
      R = 8.314472
      temperature = aveTempInterior
      volume = internalVolume
      startup_time = 0.5
      output = ppress
      save_in = 'pressure_residual_x pressure_residual_y pressure_residual_z'
    [../]
  [../]
[]

[Materials]
  [./elast_tensor1]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e1
    poissons_ratio = 0
    block = 1
  [../]
  [./strain1]
    type = ComputeFiniteStrain
    block = 1
  [../]
  [./stress1]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./elast_tensor2]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0
    block = 2
  [../]
  [./strain2]
    type = ComputeFiniteStrain
    block = 2
  [../]
  [./stress2]
    type = ComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_rel_tol = 1e-12
  l_tol = 1e-12

  l_max_its = 20

  dt = 0.5
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 100
    execute_on = 'initial linear'
  [../]
  [./aveTempInterior]
    type = SideAverageValue
    boundary = 100
    variable = temp
    execute_on = 'initial linear'
  [../]
  [./materialInput]
    type = SideAverageValue
    boundary = '7 8 9 10 11 12'
    variable = material_input
    execute_on = linear
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/plane_4/plane4_template2.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane4_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  maximum_lagrangian_update_iterations = 200
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-7
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x9 disp_y9 disp_x16 disp_y16 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/tensor_mechanics/tutorials/basics/part_2.1.i

#Tensor Mechanics tutorial: the basics
#Step 2, part 1
#2D axisymmetric RZ simulation of uniaxial tension linear elasticity

[GlobalParams]
  displacements = 'disp_r disp_z' #change the variable names for the coordinate system
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = necking_quad4.e
  uniform_refine = 1
[]

[Modules/TensorMechanics/Master]
  [./block1]
    strain = SMALL #detects the change in coordinate system and automatically sets the correct strain class
    add_variables = true
    generate_output = 'stress_zz vonmises_stress' #use stress_zz to get stress_theta quantity
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_r #change the variable to reflect the new displacement names
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_z #change the variable to reflect the new displacement names
    boundary = bottom
    value = 0.0
  [../]
  [./top]
    type = DirichletBC
    variable = disp_z #change the variable to reflect the new displacement names
    boundary = top
    value = 0.0035
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady

  solve_type = 'NEWTON'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -sub_pc_type -pc_asm_overlap -ksp_gmres_restart'
  petsc_options_value = 'asm lu 1 101'
[]

[Outputs]
  exodus = true
  perf_graph = true
[]

modules/tensor_mechanics/test/tests/combined_creep_plasticity/combined_creep_plasticity.i

#
# This test is Example 2 from "A Consistent Formulation for the Integration
#   of Combined Plasticity and Creep" by P. Duxbury, et al., Int J Numerical
#   Methods in Engineering, Vol. 37, pp. 1277-1295, 1994.
#
# The problem is a one-dimensional bar which is loaded from yield to a value of twice
#   the initial yield stress and then unloaded to return to the original stress. The
#   bar must harden to the required yield stress during the load ramp, with no
#   further yielding during unloading. The initial yield stress (sigma_0) is prescribed
#   as 20 with a plastic strain hardening of 100. The mesh is a 1x1x1 cube with symmetry
#   boundary conditions on three planes to provide a uniaxial stress field.
#
#  In the PowerLawCreep model, the creep strain rate is defined by:
#
#   edot = A(sigma)**n * exp(-Q/(RT)) * t**m
#
#   The creep law specified in the paper, however, defines the creep strain rate as:
#
#   edot = Ao * mo * (sigma)**n * t**(mo-1)
#      with the creep parameters given by
#         Ao = 1e-7
#         mo = 0.5
#         n  = 5
#
#   thus, input parameters for the test were specified as:
#         A = Ao * mo = 1e-7 * 0.5 = 0.5e-7
#         m = mo-1 = -0.5
#         n = 5
#         Q = 0
#
#   The variation of load P with time is:
#       P = 20 + 20t      0 < t < 1
#       P = 40 - 40(t-1)  1 < t 1.5
#
#  The analytic solution for total strain during the loading period 0 < t < 1 is:
#
#    e_tot = (sigma_0 + 20*t)/E + 0.2*t + A * t**0.5  * sigma_0**n * [ 1 + (5/3)*t +
#               + 2*t**2 + (10/7)*t**3 + (5/9)**t**4 + (1/11)*t**5 ]
#
#    and during the unloading period 1 < t < 1.5:
#
#    e_tot = (sigma_1 - 40*(t-1))/E + 0.2 + (4672/693) * A * sigma_0**n +
#               A * sigma_0**n * [ t**0.5 * ( 32 - (80/3)*t + 16*t**2 - (40/7)*t**3
#                                  + (10/9)*t**4 - (1/11)*t**5 ) - (11531/693) ]
#
#         where sigma_1 is the stress at time t = 1.
#
#  Assuming a Young's modulus (E) of 1000 and using the parameters defined above:
#
#    e_tot(1) = 2.39734
#    e_tot(1.5) = 3.16813
#
#
#   The numerically computed solution is:
#
#    e_tot(1) = 2.39718         (~0.006% error)
#    e_tot(1.5) = 3.15555       (~0.40% error)
#
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy elastic_strain_yy creep_strain_yy plastic_strain_yy'
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '  0   1   1.5'
    y = '-20 -40   -20'
  [../]

  [./dts]
    type = PiecewiseLinear
    x = '0        0.5    1.0    1.5'
    y = '0.015  0.015  0.005  0.005'
  [../]
[]

[BCs]
  [./u_top_pull]
    type = Pressure
    variable = disp_y
    component = 1
    boundary = top
    factor = 1
    function = top_pull
  [../]
  [./u_bottom_fix]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 1e3
    poissons_ratio = 0.3
  [../]
  [./creep_plas]
    type = ComputeMultipleInelasticStress
    block = 0
    tangent_operator = elastic
    inelastic_models = 'creep plas'
    max_iterations = 50
    absolute_tolerance = 1e-05
    combined_inelastic_strain_weights = '0.0 1.0'
  [../]
  [./creep]
    type = PowerLawCreepStressUpdate
    block = 0
    coefficient = 0.5e-7
    n_exponent = 5
    m_exponent = -0.5
    activation_energy = 0
  [../]
  [./plas]
    type = IsotropicPlasticityStressUpdate
    block = 0
    hardening_constant = 100
    yield_stress = 20
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 6
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-10
  l_tol = 1e-5
  start_time = 0.0
  end_time = 1.5

  [./TimeStepper]
    type = FunctionDT
    function = dts
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/2D_geometries/2D-RZ_finiteStrain_test.i

# Considers the mechanics solution for a thick spherical shell that is uniformly
# pressurized on the inner and outer surfaces, using 2D axisymmetric geometry.
# This test uses the strain calculator ComputeAxisymmetricRZFiniteStrain,
# which is generated through the use of the TensorMechanics MasterAction.
#
# From Roark (Formulas for Stress and Strain, McGraw-Hill, 1975), the radially-dependent
# circumferential stress in a uniformly pressurized thick spherical shell is given by:
#
# S(r) = [ Pi[ri^3(2r^3+ro^3)] - Po[ro^3(2r^3+ri^3)] ] / [2r^3(ro^3-ri^3)]
#
#   where:
#          Pi = inner pressure
#          Po = outer pressure
#          ri = inner radius
#          ro = outer radius
#
# The tests assume an inner and outer radii of 5 and 10, with internal and external
# pressures of 100000 and 200000 at t = 1.0, respectively. The resulting compressive
# tangential stress is largest at the inner wall and, from the above equation, has a
# value of -271429.
#
# RESULTS are below. Since stresses are average element values, values for the
# edge element and one-element-in are used to extrapolate the stress to the
# inner surface. The vesrion of the tests that are checked use the coarsest meshes.
#
#  Mesh    Radial elem   S(edge elem)  S(one elem in)  S(extrap to surf)
# 1D-SPH
# 2D-RZ        12 (x10)    -265004      -254665        -270174
#  3D          12 (6x6)    -261880      -252811        -266415
#
# 1D-SPH
# 2D-RZ        48 (x10)    -269853      -266710        -271425
#  3D          48 (10x10)  -268522      -265653        -269957
#
# The numerical solution converges to the analytical solution as the mesh is
# refined.

[Mesh]
  file = 2D-RZ_mesh.e
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Problem]
  coord_type = RZ
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    block = 1
  [../]
[]

[AuxVariables]
  [./stress_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_theta]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_theta
    execute_on = timestep_end
  [../]
  [./strain_theta]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 2
    index_j = 2
    variable = strain_theta
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
    block = 1
  [../]

  [./_elastic_strain]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
[]

[BCs]
# pin particle along symmetry planes
  [./no_disp_r]
    type = DirichletBC
    variable = disp_r
    boundary = xzero
    value = 0.0
  [../]

  [./no_disp_z]
    type = DirichletBC
    variable = disp_z
    boundary = yzero
    value = 0.0
  [../]

# exterior and internal pressures
  [./exterior_pressure_r]
    type = Pressure
    variable = disp_r
    boundary = outer
    component = 0
    function = '200000*t'
  [../]

 [./exterior_pressure_z]
    type = Pressure
    variable = disp_z
    boundary = outer
    component = 1
    function = '200000*t'
  [../]

  [./interior_pressure_r]
    type = Pressure
    variable = disp_r
    boundary = inner
    component = 0
    function = '100000*t'
  [../]

  [./interior_pressure_z]
    type = Pressure
    variable = disp_z
    boundary = inner
    component = 1
    function = '100000*t'
  [../]
[]

[Debug]
    show_var_residual_norms = true
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50

  start_time = 0.0
  end_time = 0.2
  dt = 0.1
[]

[Postprocessors]
  [./strainTheta]
    type = ElementAverageValue
    variable = strain_theta
  [../]
  [./stressTheta]
    type = ElementAverageValue
    variable = stress_theta
  [../]
  [./stressTheta_pt]
    type = PointValue
    point = '5.0 0.0 0.0'
    #bottom inside edge for comparison to theory; use csv = true
    variable = stress_theta
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/examples/bridge/bridge_large_strain.i

#
# Bridge linear elasticity example
#
# This example models a bridge using linear elasticity.
# It can be either steel or concrete.
# Gravity is applied
# A pressure of 0.5 MPa is also applied
#

[Mesh]
  displacements = 'disp_x disp_y disp_z' #Define displacements for deformed mesh
  type = FileMesh #Read in mesh from file
  file = bridge.e

  boundary_id = '1 2 3 4 5 6' #Assign names to boundaries to make things clearer
  boundary_name = 'top left right bottom1 bottom2 bottom3'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Kernels]
  [./gravity_y]
    #Gravity is applied to bridge
    type = Gravity
    variable = disp_y
    value = -9.81
  [../]
  [./TensorMechanics]
    #Stress divergence kernels
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[AuxVariables]
  [./von_mises]
    #Dependent variable used to visualize the Von Mises stress
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./von_mises_kernel]
    #Calculates the von mises stress and assigns it to von_mises
    type = RankTwoScalarAux
    variable = von_mises
    rank_two_tensor = stress
    execute_on = timestep_end
    scalar_type = VonMisesStress
  [../]
[]

[BCs]
  [./Pressure]
    [./load]
      #Applies the pressure
      boundary = top
      factor = 5e5 # Pa
      disp_x = disp_x
      disp_y = disp_y
      disp_z = disp_z
    [../]
  [../]
  [./anchor_x]
    #Anchors the bottom and sides against deformation in the x-direction
    type = DirichletBC
    variable = disp_x
    boundary = 'left right bottom1 bottom2 bottom3'
    value = 0.0
  [../]
  [./anchor_y]
    #Anchors the bottom and sides against deformation in the y-direction
    type = DirichletBC
    variable = disp_y
    boundary = 'left right bottom1 bottom2 bottom3'
    value = 0.0
  [../]
  [./anchor_z]
    #Anchors the bottom and sides against deformation in the z-direction
    type = DirichletBC
    variable = disp_z
    boundary = 'left right bottom1 bottom2 bottom3'
    value = 0.0
  [../]
[]

[Materials]
  active = 'density_steel stress strain elasticity_tensor_steel'
  [./elasticity_tensor_steel]
    #Creates the elasticity tensor using steel parameters
    youngs_modulus = 210e9 #Pa
    poissons_ratio = 0.3
    type = ComputeIsotropicElasticityTensor
    block = 1
  [../]
  [./elasticity_tensor_concrete]
    #Creates the elasticity tensor using concrete parameters
    youngs_modulus = 16.5e9 #Pa
    poissons_ratio = 0.2
    type = ComputeIsotropicElasticityTensor
    block = 1
  [../]
  [./strain]
    #Computes the strain, assuming small strains
    type = ComputeFiniteStrain
    block = 1
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    #Computes the stress, using linear elasticity
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./density_steel]
    #Defines the density of steel
    type = GenericConstantMaterial
    block = 1
    prop_names = density
    prop_values = 7850 # kg/m^3
  [../]
  [./density_concrete]
    #Defines the density of concrete
    type = GenericConstantMaterial
    block = 1
    prop_names = density
    prop_values = 2400 # kg/m^3
  [../]
[]

[Preconditioning]
  [./SMP]
    #Creates the entire Jacobian, for the Newton solve
    type = SMP
    full = true
  [../]
[]

[Executioner]
  #We solve a steady state problem using Newton's iteration
  type = Transient
  solve_type = NEWTON
  nl_rel_tol = 1e-9
  l_max_its = 30
  l_tol = 1e-4
  nl_max_its = 10
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre boomeramg 31'
  dt = 0.1
  num_steps = 1
[]

[Outputs]
  exodus = true
  perf_graph = true
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update24.i

# MC update version, with only MohrCoulomb, cohesion=40, friction angle = 35deg, psi = 5deg, smoothing_tol = 0.5
# Tensile strength = 1MPa
# Lame lambda = 1E3.  Lame mu = 1.3E3

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E2
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E8
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 4E1
  [../]
  [./phi]
    type = TensorMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./psi]
    type = TensorMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '100.1 0.1 -0.2  0.1 0.9 0  -0.2 0 1.1'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = phi
    dilation_angle = psi
    smoothing_tol = 0.5
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/internal_volume/hex8.i

#
# Internal Volume Test
#
# This test is designed to compute the internal volume of a space considering
#   an embedded volume inside.
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total volume
#   is 7.
#
# The internal volume is then adjusted by a piecewise linear time varying
# function.  Thus, the total volume is 7 plus the addition at the particular
# time.
#
#  Time |  Addition  | Total volume
#   0   |    0.0     |     7.0
#   1   |    3.0     |    10.0
#   2   |    7.0     |    14.0
#   3   |   -3.0     |     4.0
#
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = meshes/hex8.e
[]

[Functions]
  [./step]
    type = PiecewiseLinear
    x = '0. 1. 2. 3.'
    y = '0. 0. 1e-2 0.'
    scale_factor = 0.5
  [../]
  [./addition]
    type = PiecewiseLinear
    x = '0. 1. 2. 3.'
    y = '0. 3. 7. -3.'
  [../]
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    volumetric_locking_correction = true
    incremental = true
    strain = FINITE
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 100
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]

  [./prescribed_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 100
    function = step
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  start_time = 0.0
  dt = 1.0
  end_time = 3.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 100
    addition = addition
    execute_on = 'initial timestep_end'
  [../]

  [./dispZ]
    type = ElementAverageValue
    block = '1 2'
    variable = disp_z
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/elastic_thermal_patch/elastic_thermal_weak_plane_stress_jacobian.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  temperature = temp
  out_of_plane_strain = strain_zz
  thermal_eigenstrain_name = thermal_eigenstrain
[]

[Mesh]
  file = square.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./strain_zz]
  [../]

  [./temp]
  [../]
[]

[Kernels]
  [./disp_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
  [../]
  [./disp_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
  [../]

  [./solid_z]
    type = WeakPlaneStress
    variable = strain_zz
  [../]

  [./heat]
    type = HeatConduction
    variable = temp
    use_displaced_mesh = false
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.0
    youngs_modulus = 1
  [../]
  [./strain]
    type = ComputePlaneSmallStrain
    eigenstrain_names = thermal_eigenstrain
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-5
    stress_free_temperature = 0
    eigenstrain_name = thermal_eigenstrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]

  [./conductivity]
    type = HeatConductionMaterial
    thermal_conductivity = 1
    use_displaced_mesh = false
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON

  petsc_options_iname = '-ksp_type -pc_type -snes_type'
  petsc_options_value = 'bcgs bjacobi test'

  end_time = 1.0
[]

modules/combined/test/tests/solid_mechanics/Wave_1_D/Rayleigh_Newmark/wave_bc_1d.i

# Wave propogation in 1-D using Newmark time integration in the
# presence of Rayleigh damping
#
# The test is for an 1-D bar element of length 4m fixed on one end
# with a sinusoidal pulse dirichlet boundary condition applied to the
# other end.  beta and gamma are Newmark time integration parameters
# eta and zeta are mass dependent and stiffness dependent Rayleigh
# damping coefficients, respectively.  The equation of motion in terms
# of matrices is:
#
# M*accel + (eta*M+zeta*K)*vel +K*disp = 0
#
# Here M is the mass matrix, K is the stiffness matrix
#
# The displacement at the second, third and fourth node at t = 0.1 are
# -7.776268399030435152e-02, 1.949967184623528985e-02 and -4.615737877580032046e-03, respectively
[GlobalParams]
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 4
  nz = 1
  xmin = 0.0
  xmax = 0.1
  ymin = 0.0
  ymax = 4.0
  zmin = 0.0
  zmax = 0.1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./vel_x]
  [../]
  [./accel_x]
  [../]
  [./vel_y]
  [../]
  [./accel_y]
  [../]
  [./vel_z]
  [../]
  [./accel_z]
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

[]

[Kernels]

  [./DynamicTensorMechanics]
    use_displaced_mesh = false
    zeta = 0.1
  [../]
 [./inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.3025
    gamma = 0.6
    eta=0.1
    use_displaced_mesh = false
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.3025
    gamma = 0.6
    eta=0.1
    use_displaced_mesh = false
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    beta = 0.3025
    gamma = 0.6
    eta = 0.1
    use_displaced_mesh = false
  [../]

[]

[AuxKernels]
  [./accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.6
    execute_on = timestep_end
  [../]
  [./accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.6
    execute_on = timestep_end
  [../]
  [./accel_z]
    type = NewmarkAccelAux
    variable = accel_z
    displacement = disp_z
    velocity = vel_z
    beta = 0.3025
    execute_on = timestep_end
  [../]
  [./vel_z]
    type = NewmarkVelAux
    variable = vel_z
    acceleration = accel_z
    gamma = 0.6
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value=0.0
  [../]
  [./top_x]
   type = DirichletBC
    variable = disp_x
    boundary = top
    value=0.0
  [../]
  [./top_z]
    type = DirichletBC
    variable = disp_z
    boundary = top
    value=0.0
  [../]
  [./right_x]
   type = DirichletBC
    variable = disp_x
    boundary = right
    value=0.0
  [../]
  [./right_z]
    type = DirichletBC
    variable = disp_z
    boundary = right
    value=0.0
  [../]
  [./left_x]
   type = DirichletBC
    variable = disp_x
    boundary = left
    value=0.0
  [../]
  [./left_z]
    type = DirichletBC
    variable = disp_z
    boundary = left
    value=0.0
  [../]
  [./front_x]
   type = DirichletBC
    variable = disp_x
    boundary = front
    value=0.0
  [../]
  [./front_z]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value=0.0
  [../]
  [./back_x]
   type = DirichletBC
    variable = disp_x
    boundary = back
    value=0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value=0.0
  [../]
    [./bottom_x]
      type = DirichletBC
      variable = disp_x
      boundary = bottom
      value=0.0
    [../]
    [./bottom_z]
      type = DirichletBC
      variable = disp_z
      boundary = bottom
      value=0.0
    [../]
    [./bottom_y]
      type = FunctionDirichletBC
      variable = disp_y
      boundary = bottom
      function = displacement_bc
    [../]
[]

[Materials]
  [./constant]
    type = ComputeIsotropicElasticityTensor
    block = '0'
    youngs_modulus = 1.0
    poissons_ratio = 0.0
  [../]

  [./constant_strain]
    type= ComputeFiniteStrain
    block = '0'
  [../]
  [./constant_stress]
    type = ComputeFiniteStrainElasticStress
    block = '0'
  [../]
  [./density]
    type = GenericConstantMaterial
    block = '0'
    prop_names = 'density'
    prop_values = '1'
  [../]
[]


[Executioner]

  type = Transient
  start_time = 0
  end_time = 6.0
  dtmax = 0.1
  dtmin = 0.1
#  l_tol = 1e-8
#  nl_rel_tol = 1e-8
  [./TimeStepper]
    type = ConstantDT
    dt = 0.1
  [../]
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0.0 0.1 0.2 1.0 2.0 5.0'
    y = '0.0 0.001 1 0.001 0.0 0.0'
    scale_factor = 7750
  [../]
  [./displacement_ic]
    type = PiecewiseLinear
    axis = y
    x = '0.0 0.3 0.4 0.5 0.6 0.7 1.0'
    y = '0.0 0.0 0.0001 1.0 0.0001 0.0 0.0'
    scale_factor = 0.1
  [../]
  [./displacement_bc]
    type = PiecewiseLinear
    data_file = 'sine_wave.csv'
    format = columns
  [../]

[]

[Postprocessors]
   [./_dt]
     type = TimestepSize
   [../]
    [./disp_1]
       type = NodalVariableValue
       nodeid = 1
       variable = disp_y
     [../]
    [./disp_2]
       type = NodalVariableValue
       nodeid = 3
       variable = disp_y
     [../]
    [./disp_3]
       type = NodalVariableValue
       nodeid = 10
       variable = disp_y
     [../]
    [./disp_4]
       type = NodalVariableValue
       nodeid = 14
       variable = disp_y
     [../]
[]

[Outputs]
  exodus = true
  print_linear_residuals = true
  perf_graph = true
[]

modules/tensor_mechanics/test/tests/jacobian/cwp03.i

# Capped weak-plane plasticity
# checking jacobian for tensile failure, with some shear
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 2
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 0.5
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.05
    rate = 1
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 1
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningConstant
    value = 100
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 -2  0 0 1  -2 1 2'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 1
    smoothing_tol = 2
    yield_function_tol = 1E-10
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    #petsc_options = '-snes_test_display'
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/porous_flow/examples/tidal/atm_tides_open_hole.i

# A 100m x 10m "slab" of height 100m is subjected to cyclic pressure at its top
# Assumptions:
# the boundaries are impermeable, except the top boundary
# only vertical displacement is allowed
# the atmospheric pressure sets the total stress at the top of the model
# at the slab left-hand side there is a borehole that taps into the base of the slab.
[Mesh]
  [./the_mesh]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 10
    ny = 1
    nz = 10
    xmin = 0
    xmax = 100
    ymin = -5
    ymax = 5
    zmin = -100
    zmax = 0
  [../]
  [./bh_back]
    type = ExtraNodesetGenerator
    coord = '0 -5 -100'
    input = the_mesh
    new_boundary = 11
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  PorousFlowDictator = dictator
  block = 0
  biot_coefficient = 0.6
  multiply_by_density = false
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./porepressure]
    scaling = 1E11
  [../]
[]

[ICs]
  [./porepressure]
    type = FunctionIC
    variable = porepressure
    function = '-10000*z'  # this is only approximately correct
  [../]
[]

[Functions]
  [./ini_stress_zz]
    type = ParsedFunction
    value = '(25000 - 0.6*10000)*z' # remember this is effective stress
  [../]
  [./cyclic_porepressure]
    type = ParsedFunction
    value = 'if(t>0,5000 * sin(2 * pi * t / 3600.0 / 24.0),0)'
  [../]
  [./cyclic_porepressure_at_depth]
    type = ParsedFunction
    value = '-10000*z + if(t>0,5000 * sin(2 * pi * t / 3600.0 / 24.0),0)'
  [../]
  [./neg_cyclic_porepressure]
    type = ParsedFunction
    value = '-if(t>0,5000 * sin(2 * pi * t / 3600.0 / 24.0),0)'
  [../]
[]

[BCs]
  # zmin is called 'back'
  # zmax is called 'front'
  # ymin is called 'bottom'
  # ymax is called 'top'
  # xmin is called 'left'
  # xmax is called 'right'
  [./no_x_disp]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = 'bottom top' # because of 1-element meshing, this fixes u_x=0 everywhere
  [../]
  [./no_y_disp]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = 'bottom top' # because of 1-element meshing, this fixes u_y=0 everywhere
  [../]
  [./no_z_disp_at_bottom]
    type = DirichletBC
    variable = disp_z
    value = 0
    boundary = back
  [../]
  [./pp]
    type = FunctionDirichletBC
    variable = porepressure
    function = cyclic_porepressure
    boundary = front
  [../]
  [./pp_downhole]
    type = FunctionDirichletBC
    variable = porepressure
    function = cyclic_porepressure_at_depth
    boundary = 11
  [../]
  [./total_stress_at_top]
    type = FunctionNeumannBC
    variable = disp_z
    function = neg_cyclic_porepressure
    boundary = front
  [../]
[]

[Modules]
  [./FluidProperties]
    [./the_simple_fluid]
      type = SimpleFluidProperties
      thermal_expansion = 0.0
      bulk_modulus = 2E9
      viscosity = 1E-3
      density0 = 1000.0
    [../]
  [../]
[]

[PorousFlowBasicTHM]
  coupling_type = HydroMechanical
  displacements = 'disp_x disp_y disp_z'
  porepressure = porepressure
  gravity = '0 0 -10'
  fp = the_simple_fluid
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 10.0E9 # drained bulk modulus
    poissons_ratio = 0.25
  [../]
  [./strain]
    type = ComputeSmallStrain
    eigenstrain_names = ini_stress
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 0  0 0 0  0 0 ini_stress_zz'
    eigenstrain_name = ini_stress
  [../]
  [./porosity]
    type = PorousFlowPorosityConst # only the initial value of this is ever used
    porosity = 0.1
  [../]
  [./biot_modulus]
    type = PorousFlowConstantBiotModulus
    solid_bulk_compliance = 1E-10
    fluid_bulk_modulus = 2E9
  [../]
  [./permeability]
    type = PorousFlowPermeabilityConst
    permeability = '1E-14 0 0   0 1E-14 0   0 0 1E-14'
  [../]
  [./density]
    type = GenericConstantMaterial
    prop_names = density
    prop_values = 2500.0
  [../]
[]

[Postprocessors]
  [./p0_0]
    type = PointValue
    outputs = csv
    point = '0 0 0'
    variable = porepressure
  [../]
  [./p100_0]
    type = PointValue
    outputs = csv
    point = '100 0 0'
    variable = porepressure
  [../]
  [./p0_100]
    type = PointValue
    outputs = csv
    point = '0 0 -100'
    variable = porepressure
  [../]
  [./p100_100]
    type = PointValue
    outputs = csv
    point = '100 0 -100'
    variable = porepressure
  [../]
  [./uz0]
    type = PointValue
    outputs = csv
    point = '0 0 0'
    variable = disp_z
  [../]
  [./uz100]
    type = PointValue
    outputs = csv
    point = '100 0 0'
    variable = disp_z
  [../]
[]


[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  start_time = -3600
  dt = 3600
  end_time = 172800
  nl_rel_tol = 1E-10
  nl_abs_tol = 1E-5
[]

[Outputs]
  print_linear_residuals = false
  csv = true
[]

modules/tensor_mechanics/test/tests/ad_2D_geometries/2D-RZ_centerline_VLC.i

# Simple test to check for use of AxisymmetricCenterlineAverageValue with
# volumetric_locking_correction activated in a tensor mechanics simulation

[Mesh]
  type = GeneratedMesh
  dim = 2
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
  volumetric_locking_correction = true
[]

[Problem]
  coord_type = RZ
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    use_automatic_differentiation = true
  [../]
[]

[AuxVariables]
  [./temperature]
    initial_condition = 298.0
  [../]
[]

[BCs]
  [./symmetry_x]
    type = ADDirichletBC
    variable = disp_r
    value = 0
    boundary = left
  [../]
  [./roller_z]
    type = ADDirichletBC
    variable = disp_z
    value = 0
    boundary = bottom
  [../]
  [./top_load]
    type = ADFunctionDirichletBC
    variable = disp_z
    function = -0.01*t
    boundary = top
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.3
  [../]
  [./_elastic_strain]
    type = ADComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  line_search = 'none'

  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-6
  l_max_its = 50

  start_time = 0.0
  end_time = 0.3
  dt = 0.1
[]

[Postprocessors]
  [./center_temperature]
    type = AxisymmetricCenterlineAverageValue
    variable = temperature
    boundary = left
  [../]
[]

[Outputs]
  csv = true
  perf_graph = true
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking_exponential_deprecated.i

#
# Test to exercise the exponential stress release
#
# Stress vs. strain should show a linear relationship until cracking,
#   an exponential stress release, a linear relationship back to zero
#   strain, a linear relationship with the original stiffness in
#   compression and then back to zero strain, a linear relationship
#   back to the exponential curve, and finally further exponential
#   stress release.
#

[Mesh]
  file = cracking_test.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./displx]
    type = PiecewiseLinear
    x = '0 1       2  3      4 5       6'
    y = '0 0.00175 0 -0.0001 0 0.00175 0.0035'
  [../]
  [./disply]
    type = PiecewiseLinear
    x = '0 5 6'
    y = '0 0 .00175'
  [../]
  [./displz]
    type = PiecewiseLinear
    x = '0 2 3'
    y = '0 0 .0035'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  [../]
[]

[BCs]
  [./pullx]
    type = FunctionDirichletBC
    #type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = displx
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]

  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = '11 12'
    value = 0.0
  [../]

  [./move_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = '15 16'
    function = disply
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = '3'
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 186.5e9
    poissons_ratio = .316
  [../]
  [./elastic_stress]
    type = ComputeSmearedCrackingStress
    cracking_stress = 119.3e6
    cracking_release = exponential
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type'
  petsc_options_value = '101                lu'

  line_search = 'none'
  l_max_its = 100
  l_tol = 1e-6

  nl_max_its = 10
  nl_rel_tol = 1e-12
  nl_abs_tol = 1.e-4

  start_time = 0.0
  dt = 0.02
  dtmin = 0.02
  num_steps = 300
[]

[Outputs]
  exodus = true
  file_base = cracking_exponential_out
[]

modules/tensor_mechanics/test/tests/generalized_plane_strain/plane_strain.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  block = 1
[]

[Mesh]
  file = square.e
[]

[AuxVariables]
  [./temp]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    temperature = temp
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy strain_zz'
    planar_formulation = PLANE_STRAIN
    eigenstrain_names = eigenstrain
    save_in = 'saved_x saved_y'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeLinearElasticStress
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 0.02
    temperature = temp
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  # controls for linear iterations
  l_max_its = 100
  l_tol = 1e-8

  # controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-12

  # time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/ad_elastic/rspherical_small_elastic.i

[Mesh]
  type = GeneratedMesh
  dim = 1
  nx = 5
[]

[Problem]
  coord_type = RSPHERICAL
[]

[GlobalParams]
  displacements = 'disp_r'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_r]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_r]
    type = ADStressDivergenceRSphericalTensors
    component = 0
    variable = disp_r
  [../]
[]

[BCs]
  [./center]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0
  [../]
  [./rdisp]
    type = DirichletBC
    variable = disp_r
    boundary = right
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
[]

[Materials]
  [./strain]
    type = ADComputeRSphericalSmallStrain
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
[]

modules/xfem/test/tests/solid_mechanics_basic/penny_crack.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  file = quarter_sym.e
[]

[UserObjects]
  [./circle_cut_uo]
    type = CircleCutUserObject
    cut_data = '-0.5 -0.5 0
                0.0 -0.5 0
                -0.5 0 0'
  [../]
[]

[AuxVariables]
  [./SED]
   order = CONSTANT
    family = MONOMIAL
  [../]
[]

[DomainIntegral]
  integrals = 'Jintegral'
  disp_x = disp_x
  disp_y = disp_y
  disp_z = disp_z
  crack_front_points = '-0.5 0.0 0.0
                        -0.25 -0.07 0
                        -0.15 -0.15 0
                        -0.07 -0.25 0
                         0 -0.5 0'
  crack_end_direction_method = CrackDirectionVector
  crack_direction_vector_end_1 = '0 1 0'
  crack_direction_vector_end_2 = '1 0 0'
  crack_direction_method = CurvedCrackFront
  intersecting_boundary = '3 4' #It would be ideal to use this, but can't use with XFEM yet
  radius_inner = '0.3'
  radius_outer = '0.6'
  poissons_ratio = 0.3
  youngs_modulus = 207000
  block = 1
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
    block = 1
  [../]
[]

[Functions]
  [./top_trac_z]
    type = ConstantFunction
    value = 10
  [../]
[]


[BCs]
  [./top_z]
    type = FunctionNeumannBC
    boundary = 2
    variable = disp_z
    function = top_trac_z
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    boundary = 1
    variable = disp_z
    value = 0.0
  [../]
  [./sym_y]
    type = DirichletBC
    boundary = 3
    variable = disp_y
    value = 0.0
  [../]
  [./sym_x]
    type = DirichletBC
    boundary = 4
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  file_base = penny_crack_out
  execute_on = timestep_end
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/notched_plastic_block/biaxial_abbo.i

# Uses an Abbo et al smoothed version of Mohr-Coulomb (via TensorMechanicsPlasticMohrCoulomb and ComputeMultiPlasticityStress) to simulate the following problem.
# A cubical block is notched around its equator.
# All of its outer surfaces have roller BCs, but the notched region is free to move as needed
# The block is initialised with a high hydrostatic tensile stress
# Without the notch, the BCs do not allow contraction of the block, and this stress configuration is admissible
# With the notch, however, the interior parts of the block are free to move in order to relieve stress, and this causes plastic failure
# The top surface is then pulled upwards (the bottom is fixed because of the roller BCs)
# This causes more failure
[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 9
    ny = 9
    nz = 9
    xmin = 0
    xmax = 0.1
    ymin = 0
    ymax = 0.1
    zmin = 0
    zmax = 0.1
  []
  [block_to_remove_xmin]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 -0.01 0.045'
    top_right = '0.01 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = generated_mesh
  []
  [block_to_remove_xmax]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '0.09 -0.01 0.045'
    top_right = '0.11 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_xmin
  []
  [block_to_remove_ymin]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 -0.01 0.045'
    top_right = '0.11 0.01 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_xmax
  []
  [block_to_remove_ymax]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 0.09 0.045'
    top_right = '0.11 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_ymin
  []
  [remove_block]
    type = BlockDeletionGenerator
    block_id = 1
    input = block_to_remove_ymax
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress stress_zz'
    eigenstrain_names = ini_stress
  [../]
[]

[Postprocessors]
  [./uz]
    type = PointValue
    point = '0 0 0.1'
    use_displaced_mesh = false
    variable = disp_z
  [../]
  [./s_zz]
    type = ElementAverageValue
    use_displaced_mesh = false
    variable = stress_zz
  [../]
  [./num_res]
    type = NumResidualEvaluations
  [../]
  [./nr_its] # num_iters is the average number of NR iterations encountered per element in this timestep
    type = ElementAverageValue
    variable = num_iters
  [../]
  [./max_nr_its] # num_iters is the average number of NR iterations encountered in the element in this timestep, so we must get max(max_nr_its) to obtain the max number of iterations
    type = ElementExtremeValue
    variable = num_iters
  [../]
  [./runtime]
    type = PerfGraphData
    data_type = TOTAL
    section_name = 'Root'
  [../]
[]

[BCs]
  # back=zmin, front=zmax, bottom=ymin, top=ymax, left=xmin, right=xmax
  [./xmin_xzero]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./xmax_xzero]
    type = DirichletBC
    variable = disp_x
    boundary = right
    value = 0.0
  [../]
  [./ymin_yzero]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./ymax_yzero]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.0
  [../]
  [./zmin_zzero]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = '0'
  [../]
  [./zmax_disp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = '1E-6*max(t,0)'
  [../]
[]

[AuxVariables]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./num_iters]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./num_iters_auxk]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = num_iters
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 5E6
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 10
    convert_to_radians = true
  [../]
  [./mc]
    type = TensorMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 0.02E6
    mc_edge_smoother = 29
    yield_function_tolerance = 1E-5
    internal_constraint_tolerance = 1E-11
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 16E9
    poissons_ratio = 0.25
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    ep_plastic_tolerance = 1E-11
    plastic_models = mc
    max_NR_iterations = 1000
    debug_fspb = crash
  [../]
  [./strain_from_initial_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '6E6 0 0  0 6E6 0  0 0 6E6'
    eigenstrain_name = ini_stress
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  start_time = -1
  end_time = 10
  dt = 1
  solve_type = NEWTON
  type = Transient

  l_tol = 1E-2
  nl_abs_tol = 1E-5
  nl_rel_tol = 1E-7
  l_max_its = 200
  nl_max_its = 400

  petsc_options_iname = '-pc_type -pc_asm_overlap -sub_pc_type -ksp_type -ksp_gmres_restart'
  petsc_options_value = ' asm      2              lu            gmres     200'
[]


[Outputs]
  file_base = biaxial_abbo
  perf_graph = true
  exodus = false
  csv = true
[]

modules/xfem/test/tests/pressure_bc/edge_2d_pressure.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = False
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 9
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '0.0 0.5 0.5 0.5'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    generate_output = 'stress_xx stress_yy'
  [../]
[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0 1.0 2.0'
    y = '0 500 1000'
  [../]
[]

[BCs]
  [./bottom_y]
    type = DirichletBC
    boundary = 0
    variable = disp_y
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    boundary = 2
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = 0
    variable = disp_x
    value = 0.0
  [../]
[]

[DiracKernels]
  [./pressure_x]
    type = XFEMPressure
    variable = disp_x
    component = 0
    function = pressure
  [../]

  [./pressure_y]
    type = XFEMPressure
    variable = disp_y
    component = 1
    function = pressure
  [../]
[]


[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-12

# time control
  start_time = 0.0
  dt = 1
  end_time = 2
[]

[Outputs]
  file_base = edge_2d_pressure_out
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/plane_stress/weak_plane_stress_finite_tension_pull.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  out_of_plane_strain = strain_zz
[]

[Problem]
  extra_tag_vectors = 'ref'
[]

[Mesh]
  [gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 1
    ny = 1
  []
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
  [strain_zz]
  []
[]

[AuxVariables]
  [react_x]
  []
[]

[Postprocessors]
  [react_x]
    type = NodalSum
    variable = 'react_x'
    boundary = 'right'
  []
  [stress_xx]
    type = ElementalVariableValue
    variable = 'stress_xx'
    elementid = 0
  []
  [strain_zz]
    type = ElementalVariableValue
    variable = 'strain_zz'
    elementid = 0
  []
[]

[Modules/TensorMechanics/Master]
  [plane_stress]
    strain = FINITE
    planar_formulation = WEAK_PLANE_STRESS
    extra_vector_tags = 'ref'
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy'
  []
[]

[AuxKernels]
  [react_x]
    type = TagVectorAux
    vector_tag = 'ref'
    v = 'disp_x'
    variable = 'react_x'
  []
[]

[BCs]
  [leftx]
    type = DirichletBC
    boundary = left
    variable = disp_x
    value = 0.0
  []
  [bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  []
  [rightx]
    type = FunctionDirichletBC
    boundary = right
    variable = disp_x
    function = 't'
  []
[]

[Materials]
  [elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
  []
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10

  # time control
  start_time = 0.0
  dt = 0.01
  dtmin = 0.01
  end_time = 0.2
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/sliding_block/sliding/dirac/frictionless_penalty.i

#  This is a benchmark test that checks Dirac based frictionless
#  contact using the penalty method.  In this test a constant
#  displacement is applied in the horizontal direction to simulate
#  a small block come sliding down a larger block.
#
#  The gold file is run on one processor
#  and the benchmark case is run on a minimum of 4 processors to ensure no
#  parallel variability in the contact pressure and penetration results.
#

[Mesh]
  file = sliding_elastic_blocks_2d.e
  patch_size = 80
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
    order = FIRST
    family = LAGRANGE
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./nonlinear_its]
    type = NumNonlinearIterations
    execute_on = timestep_end
  [../]
  [./penetration]
    type = NodalVariableValue
    variable = penetration
    nodeid = 222
  [../]
  [./contact_pressure]
    type = NodalVariableValue
    variable = contact_pressure
    nodeid = 222
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./stiffStuff]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]  # Materials


[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  l_max_its = 100
  nl_max_its = 1000
  dt = 0.05
  end_time = 10
  num_steps = 1000
  nl_rel_tol = 1e-6
  dtmin = 0.01
  l_tol = 1e-6

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  interval = 10
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 2
    model = frictionless
    penalty = 1e+7
    formulation = penalty
    normal_smoothing_distance = 0.1
    system = DiracKernel
  [../]
[]

modules/tensor_mechanics/test/tests/line_material_rank_two_sampler/rank_two_scalar_sampler.i

[GlobalParams]
  displacements = 'x_disp y_disp z_disp'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 3
  ny = 3
  nz = 3
  elem_type = HEX
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 1e-6
  [../]
[]

[Variables]
  [./x_disp]
    order = FIRST
    family = LAGRANGE
  [../]
  [./y_disp]
    order = FIRST
    family = LAGRANGE
  [../]
  [./z_disp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
 [../]
 [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
 [../]
[]

[AuxKernels]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = VonMisesStress
  [../]
[]

[VectorPostprocessors]
  [./vonmises]
    type = LineMaterialRankTwoScalarSampler
    start = '0.1667 0.4 0.45'
    end   = '0.8333 0.6 0.55'
    property = stress
    scalar_type = VonMisesStress
    sort_by = id
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./front]
    type = FunctionDirichletBC
    variable = z_disp
    boundary = 5
    function = rampConstant
  [../]
  [./back_x]
    type = DirichletBC
    variable = x_disp
    boundary = 0
    value = 0.0
  [../]
  [./back_y]
    type = DirichletBC
    variable = y_disp
    boundary = 0
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = z_disp
    boundary = 0
    value = 0.0
  [../]
[]

[Materials]
  [./elast_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = .3
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK

  l_max_its = 100

  start_time = 0.0
  num_steps = 99999
  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  file_base = rank_two_scalar_sampler_out
  exodus = true
  csv = true
[]

modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/glued_kinematic.i

[Mesh]
  file = blocks_2d_nogap.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    #Initial gap is 0.01
    value = -0.01
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  [../]
  [./right]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.01
  end_time = 0.10
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-8
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    system = Constraint
    master = 2
    slave = 3
    model = glued
    penalty = 1e+6
  [../]
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_3d_topo_q_func.i

#This tests the J-Integral evaluation capability.
#This is a 3d extrusion of a 2d plane strain model with 2 elements
#through the thickness, and calculates the J-Integrals using options
#to treat it as 3d.
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack3d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  q_function_type = Topology
  ring_first = 1
  ring_last = 3
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 500
    value = 0.0
  [../]
  [./no_z2]
    type = DirichletBC
    variable = disp_z
    boundary = 510
    value = 0.0
  [../]

  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]

  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]

[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]


[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = j_integral_3d_topo_q_func_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update17.i

# MC update version, with only Compressive with compressive strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.
# Returns to close to the edge of compressive yield

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0.5
    internal_limit = 2E-2
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '1 -0.1 -0.2  -0.1 -15 0.3  -0.2 0.3 -14'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/gravity/gravity.i

# Gravity Test
#
# This test is designed to exercise the gravity body force kernel.
#
# The mesh for this problem is a rectangular bar 10 units by 1 unit
#   by 1 unit.
#
# The boundary conditions for this problem are as follows.  The
#   displacement is zero on each of side that faces a negative
#   coordinate direction.  The acceleration of gravity is 20.
#
# The material has a Young's modulus of 1e6 and a density of 2.
#
# The analytic solution for the displacement along the bar is:
#
# u(x) = -b*x^2/(2*E)+b*L*x/E
#
# The displacement at x=L is b*L^2/(2*E) = 2*20*10*10/(2*1e6) = 0.002.
#
# The analytic solution for the stress along the bar assuming linear
#   elasticity is:
#
# S(x) = b*(L-x)
#
# The stress at x=0 is b*L = 2*20*10 = 400.
#
# Note:  The simulation does not measure stress at x=0.  The stress
#   is reported at element centers.  The element closest to x=0 sits
#   at x = 1/4 and has a stress of 390.  This matches the linear
#   stress distribution that is expected.  The same situation applies
#   at x = L where the stress is zero analytically.  The nearest
#   element is at x=9.75 where the stress is 10.
#
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = gravity_test.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Modules/TensorMechanics/Master/All]
  volumetric_locking_correction = true
  strain = FINITE
  add_variables = true
  generate_output = 'stress_xx'
[]

[Kernels]
  [./gravity]
    type = Gravity
    variable = disp_x
    value = 20
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 5
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    bulk_modulus = 0.333333333333333e6
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./density]
    type = Density
    block = 1
    density = 2
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  start_time = 0.0
  end_time = 1.0
[]

[Outputs]
  file_base = gravity_out
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/combined/test/tests/gap_heat_transfer_convex/gap_heat_transfer_convex.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  temperature = temp
[]

[Mesh]
  file = gap_heat_transfer_convex.e
[]

[Functions]
  [./disp]
    type = PiecewiseLinear
    x = '0 2.0'
    y = '0 1.0'
  [../]
  [./temp]
    type = PiecewiseLinear
    x = '0     1'
    y = '200 200'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]

  [./temp]
    initial_condition = 100
  [../]
[]

[ThermalContact]
  [./thermal_contact]
    type = GapHeatTransfer
    variable = temp
    master = 2
    slave = 3
  [../]
[]

[Modules/TensorMechanics/Master/All]
  volumetric_locking_correction = true
  strain = FINITE
  eigenstrain_names = eigenstrain
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[BCs]
  [./move_right]
    type = FunctionDirichletBC
    boundary = '3'
    variable = disp_x
    function = disp
  [../]

  [./fixed_x]
    type = DirichletBC
    boundary = '1'
    variable = disp_x
    value = 0
  [../]
  [./fixed_y]
    type = DirichletBC
    boundary = '1 2 3 4'
    variable = disp_y
    value = 0
  [../]
  [./fixed_z]
    type = DirichletBC
    boundary = '1 2 3 4'
    variable = disp_z
    value = 0
  [../]

  [./temp_bottom]
    type = FunctionDirichletBC
    boundary = 1
    variable = temp
    function = temp
  [../]
  [./temp_top]
    type = DirichletBC
    boundary = 4
    variable = temp
    value = 100
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 100
    thermal_expansion_coeff = 0
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./heat1]
    type = HeatConductionMaterial
    block = 1

    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]
  [./heat2]
    type = HeatConductionMaterial
    block = 2

    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]

  [./density]
    type = Density
    block = '1 2'
    density = 1.0
    disp_x = disp_x
    disp_y = disp_y
    disp_z = disp_z
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  start_time = 0.0
  dt = 0.1
  end_time = 2.0
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_2/brick2_aug.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick2_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  maximum_lagrangian_update_iterations = 100
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_x26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_x
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./disp_y26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5

[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x7 disp_y7 disp_x26 disp_y26 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    tangential_tolerance = 1e-3
    formulation = augmented_lagrange
    system = constraint
    normalize_penalty = true
    penalty = 1e8
    model = frictionless
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/tensor_mechanics/test/tests/ad_2D_geometries/2D-RZ_finiteStrain_test.i

# Considers the mechanics solution for a thick spherical shell that is uniformly
# pressurized on the inner and outer surfaces, using 2D axisymmetric geometry.
# This test uses the strain calculator ComputeAxisymmetricRZFiniteStrain,
# which is generated through the use of the TensorMechanics MasterAction.
#
# From Roark (Formulas for Stress and Strain, McGraw-Hill, 1975), the radially-dependent
# circumferential stress in a uniformly pressurized thick spherical shell is given by:
#
# S(r) = [ Pi[ri^3(2r^3+ro^3)] - Po[ro^3(2r^3+ri^3)] ] / [2r^3(ro^3-ri^3)]
#
#   where:
#          Pi = inner pressure
#          Po = outer pressure
#          ri = inner radius
#          ro = outer radius
#
# The tests assume an inner and outer radii of 5 and 10, with internal and external
# pressures of 100000 and 200000 at t = 1.0, respectively. The resulting compressive
# tangential stress is largest at the inner wall and, from the above equation, has a
# value of -271429.
#
# RESULTS are below. Since stresses are average element values, values for the
# edge element and one-element-in are used to extrapolate the stress to the
# inner surface. The vesrion of the tests that are checked use the coarsest meshes.
#
#  Mesh    Radial elem   S(edge elem)  S(one elem in)  S(extrap to surf)
# 1D-SPH
# 2D-RZ        12 (x10)    -265004      -254665        -270174
#  3D          12 (6x6)    -261880      -252811        -266415
#
# 1D-SPH
# 2D-RZ        48 (x10)    -269853      -266710        -271425
#  3D          48 (10x10)  -268522      -265653        -269957
#
# The numerical solution converges to the analytical solution as the mesh is
# refined.

[Mesh]
  file = 2D-RZ_mesh.e
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Problem]
  coord_type = RZ
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    block = 1
    use_automatic_differentiation = true
  [../]
[]

[AuxVariables]
  [./stress_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_theta]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_theta
    execute_on = timestep_end
  [../]
  [./strain_theta]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 2
    index_j = 2
    variable = strain_theta
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
    block = 1
  [../]

  [./_elastic_strain]
    type = ADComputeFiniteStrainElasticStress
    block = 1
  [../]
[]

[BCs]
# pin particle along symmetry planes
  [./no_disp_r]
    type = ADDirichletBC
    variable = disp_r
    boundary = xzero
    value = 0.0
  [../]

  [./no_disp_z]
    type = ADDirichletBC
    variable = disp_z
    boundary = yzero
    value = 0.0
  [../]

# exterior and internal pressures
  [./exterior_pressure_r]
    type = ADPressure
    variable = disp_r
    boundary = outer
    component = 0
    function = '200000*t'
  [../]

 [./exterior_pressure_z]
    type = ADPressure
    variable = disp_z
    boundary = outer
    component = 1
    function = '200000*t'
  [../]

  [./interior_pressure_r]
    type = ADPressure
    variable = disp_r
    boundary = inner
    component = 0
    function = '100000*t'
  [../]

  [./interior_pressure_z]
    type = ADPressure
    variable = disp_z
    boundary = inner
    component = 1
    function = '100000*t'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50

  start_time = 0.0
  end_time = 0.2
  dt = 0.1
[]

[Postprocessors]
  [./strainTheta]
    type = ElementAverageValue
    variable = strain_theta
  [../]
  [./stressTheta]
    type = ElementAverageValue
    variable = stress_theta
  [../]
  [./stressTheta_pt]
    type = PointValue
    point = '5.0 0.0 0.0'
    #bottom inside edge for comparison to theory; use csv = true
    variable = stress_theta
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/adaptive_timestepping/adapt_tstep_function_change_restart1.i

# This is a test designed to evaluate the cabability of the
# IterationAdaptiveDT TimeStepper to adjust time step size according to
# a function.  For example, if the power input function for a BISON
# simulation rapidly increases or decreases, the IterationAdaptiveDT
# TimeStepper should take time steps small enough to capture the
# oscillation.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  block = 1
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = 1hex8_10mm_cube.e
[]

[Functions]
  [./Fiss_Function]
    type = PiecewiseLinear
    x = '0 1e6  2e6  2.001e6 2.002e6'
    y = '0 3e8  3e8  12e8    0'
  [../]
[]

[Variables]
  [./disp_x]
  [../]

  [./disp_y]
  [../]

  [./disp_z]
  [../]

  [./temp]
    initial_condition = 300.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    volumetric_locking_correction = true
    eigenstrain_names = thermal_expansion
    decomposition_method = EigenSolution
    add_variables  = true
    generate_output = 'vonmises_stress'
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]

  [./heat_ie]
    type = HeatConductionTimeDerivative
    variable = temp
  [../]

  [./heat_source]
     type = HeatSource
     variable = temp
     value = 1.0
     function = Fiss_Function
  [../]
[]

[BCs]
 [./bottom_temp]
   type = DirichletBC
   variable = temp
   boundary = 1
   value = 300
 [../]
 [./top_bottom_disp_x]
   type = DirichletBC
   variable = disp_x
   boundary = '1'
   value = 0
 [../]
 [./top_bottom_disp_y]
   type = DirichletBC
   variable = disp_y
   boundary = '1'
   value = 0
 [../]
 [./top_bottom_disp_z]
   type = DirichletBC
   variable = disp_z
   boundary = '1'
   value = 0
 [../]
[]

[Materials]
 [./thermal]
    type = HeatConductionMaterial
    temp = temp
    specific_heat = 1.0
    thermal_conductivity = 1.0
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 300e6
    poissons_ratio = .3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 5e-6
    stress_free_temperature = 300.0
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]

  [./density]
    type = Density
    density = 10963.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  verbose = true
  nl_abs_tol = 1e-10
  start_time = 0.0

  num_steps = 65
  end_time = 2.002e6
  [./TimeStepper]
    type = IterationAdaptiveDT
    timestep_limiting_function = Fiss_Function
    max_function_change = 3e7
    dt = 1e6
  [../]
[]

[Postprocessors]
  [./Temperature_of_Block]
    type = ElementAverageValue
    variable = temp
    execute_on = 'initial timestep_end'
  [../]

  [./vonMises]
    type = ElementAverageValue
    variable = vonmises_stress
    execute_on = 'initial timestep_end'
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 10
  [../]
  [./checkpoint]
    type = Checkpoint
    num_files = 1
  [../]
[]

modules/tensor_mechanics/test/tests/t_stress/t_stress_ellip_crack_3d.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = ellip_crack_4sym_norad_mm.e
  displacements = 'disp_x disp_y disp_z'
  partitioner = centroid
  centroid_partitioner_direction = z
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstantUp]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -689.5 #MPa
  [../]
[]

[DomainIntegral]
  integrals = 'JIntegral InteractionIntegralKI InteractionIntegralT'
  boundary = 1001
  crack_direction_method = CurvedCrackFront
  crack_end_direction_method = CrackDirectionVector
  crack_direction_vector_end_1 = '0.0 1.0 0.0'
  crack_direction_vector_end_2 = '1.0 0.0 0.0'
  radius_inner = '12.5 25.0 37.5'
  radius_outer = '25.0 37.5 50.0'
  intersecting_boundary = '1 2'
  symmetry_plane = 2
  youngs_modulus = 206.8e+3 #MPa
  poissons_ratio = 0.3
  block = 1
  disp_x = disp_x
  disp_y = disp_y
  disp_z = disp_z
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress strain_xx strain_yy strain_zz'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 12
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 5
      function = rampConstantUp
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 206.8e+3
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
   type = Transient
  #petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 20
   nl_abs_tol = 1e-5
   nl_rel_tol = 1e-11
   l_tol = 1e-2

   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1
[]

[Outputs]
  execute_on = 'timestep_end'
  file_base = t_stress_ellip_crack_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/j_integral/j_integral_2d_small_strain.i

#This tests the J-Integral evaluation capability.
#This is a 2d plane strain model
#The analytic solution for J1 is 2.434.  This model
#converges to that solution with a refined mesh.
#Reference: National Agency for Finite Element Methods and Standards (U.K.):
#Test 1.1 from NAFEMS publication "Test Cases in Linear Elastic Fracture
#Mechanics" R0020.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack2d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  radius_inner = '4.0 4.5 5.0 5.5 6.0'
  radius_outer = '4.5 5.0 5.5 6.0 6.5'
  output_q = false
  incremental = false
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = SMALL
    add_variables = true
    incremental = false
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]

  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]

  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = j_integral_2d_small_strain_out
  exodus = true
  csv = true
[]

modules/combined/test/tests/beam_eigenstrain_transfer/subapp2_uo_transfer.i

# This test involves only thermal expansion strains on a 2x2x2 cube of approximate
# steel material.  An initial temperature of 25 degrees C is given for the material,
# and an auxkernel is used to calculate the temperature in the entire cube to
# raise the temperature each time step.  After the first timestep,in which the
# temperature jumps, the temperature increases by 6.25C each timestep.
# The thermal strain increment should therefore be
#     6.25 C * 1.3e-5 1/C = 8.125e-5 m/m.

# This test is also designed to be used to identify problems with restart files

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 5
  xmin = 0.0
  xmax = 0.5
  ymin = 0.0
  ymax = 0.150080
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./temp]
  [../]
  [./axial_strain]
    order = FIRST
    family = MONOMIAL
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t*(1000.0)+300.0
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        strain = SMALL
        incremental = true
        add_variables = true
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
  [../]
  [./axial_strain]
    type = RankTwoAux
    variable = axial_strain
    rank_two_tensor = total_strain
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 298
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  end_time = 0.075
  dt = 0.0125
  dtmin = 0.0001
[]

[Outputs]
  csv = true
  exodus = true
[]

[VectorPostprocessors]
  [./axial_str]
    type = LineValueSampler
    start_point = '0.5 0.0 0.0'
    end_point = '0.5 0.150080 0.0'
    variable = axial_strain
    num_points = 11
    sort_by = 'id'
  [../]
[]

[Postprocessors]
  [./end_disp]
    type = PointValue
    variable = disp_y
    point = '0.5 0.150080 0.0'
  [../]
[]

modules/combined/test/tests/cavity_pressure/multiple_postprocessors.i

#
# Cavity Pressure Test (Volume input as a vector of postprocessors)
#
# This test is designed to compute an internal pressure based on
#   p = n * R * T / V
# where
#   p is the pressure
#   n is the amount of material in the volume (moles)
#   R is the universal gas constant
#   T is the temperature
#   V is the volume
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total
#   initial volume is 7.
# The test adjusts n, T, and V in the following way:
#   n => n0 + alpha * t
#   T => T0 + beta * t
#   V => V0 + gamma * t
# with
#   alpha = n0
#   beta = T0 / 2
#   gamma = - (0.003322259...) * V0
#   T0 = 240.54443866068704
#   V0 = 7
#   n0 = f(p0)
#   p0 = 100
#   R = 8.314472 J * K^(-1) * mol^(-1)
#
# So, n0 = p0 * V0 / R / T0 = 100 * 7 / 8.314472 / 240.544439
#        = 0.35
#
# In this test the internal volume is calculated as the sum of two Postprocessors
# internalVolumeInterior and internalVolumeExterior.  This sum equals the value
# reported by the internalVolume postprocessor.
#
# The parameters combined at t = 1 gives p = 301.
#

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = 3d.e
[]

[Functions]
  [./displ_positive]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.0029069767441859684'
  [../]
  [./displ_negative]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 -0.0029069767441859684'
  [../]
  [./temp1]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1.5'
    scale_factor = 240.54443866068704
  [../]
  [./material_input_function]
    type = PiecewiseLinear
    x = '0    1'
    y = '0 0.35'
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./temp]
    initial_condition = 240.54443866068704
  [../]
  [./material_input]
  [../]
[]

[AuxVariables]
  [./pressure_residual_x]
  [../]
  [./pressure_residual_y]
  [../]
  [./pressure_residual_z]
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zx]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
  [./heat]
    type = Diffusion
    variable = temp
    use_displaced_mesh = true
  [../]
  [./material_input_dummy]
    type = Diffusion
    variable = material_input
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 2
    variable = stress_yz
  [../]
  [./stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 0
    variable = stress_zx
  [../]
[]

[BCs]
  [./no_x_exterior]
    type = DirichletBC
    variable = disp_x
    boundary = '7 8'
    value = 0.0
  [../]
  [./no_y_exterior]
    type = DirichletBC
    variable = disp_y
    boundary = '9 10'
    value = 0.0
  [../]
  [./no_z_exterior]
    type = DirichletBC
    variable = disp_z
    boundary = '11 12'
    value = 0.0
  [../]
  [./prescribed_left]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 13
    function = displ_positive
  [../]
  [./prescribed_right]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 14
    function = displ_negative
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = '15 16'
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = '17 18'
    value = 0.0
  [../]
  [./no_x_interior]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./no_y_interior]
    type = DirichletBC
    variable = disp_y
    boundary = '3 4'
    value = 0.0
  [../]
  [./no_z_interior]
    type = DirichletBC
    variable = disp_z
    boundary = '5 6'
    value = 0.0
  [../]
  [./temperatureInterior]
    type = FunctionDirichletBC
    boundary = 100
    function = temp1
    variable = temp
  [../]
  [./MaterialInput]
    type = FunctionDirichletBC
    boundary = '100 13 14 15 16'
    function = material_input_function
    variable = material_input
  [../]
  [./CavityPressure]
    [./1]
      boundary = 100
      initial_pressure = 100
      material_input = materialInput
      R = 8.314472
      temperature = aveTempInterior
      volume = 'internalVolumeInterior internalVolumeExterior'
      startup_time = 0.5
      output = ppress
      save_in = 'pressure_residual_x pressure_residual_y pressure_residual_z'
    [../]
  [../]
[]

[Materials]
  [./elast_tensor1]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e1
    poissons_ratio = 0
    block = 1
  [../]
  [./strain1]
    type = ComputeFiniteStrain
    block = 1
  [../]
  [./stress1]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./elast_tensor2]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0
    block = 2
  [../]
  [./strain2]
    type = ComputeFiniteStrain
    block = 2
  [../]
  [./stress2]
    type = ComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_rel_tol = 1e-12
  l_tol = 1e-12

  l_max_its = 20

  dt = 0.5
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 100
    execute_on = 'initial linear'
  [../]
  [./aveTempInterior]
    type = SideAverageValue
    boundary = 100
    variable = temp
    execute_on = 'initial linear'
  [../]
  [./internalVolumeInterior]
    type = InternalVolume
    boundary = '1 2 3 4 5 6'
    execute_on = 'initial linear'
  [../]
  [./internalVolumeExterior]
    type = InternalVolume
    boundary = '13 14 15 16 17 18'
    execute_on = 'initial linear'
  [../]
  [./materialInput]
    type = SideAverageValue
    boundary = '7 8 9 10 11 12'
    variable = material_input
    execute_on = linear
  [../]
[]

[Outputs]
  exodus = true
[]

modules/peridynamics/test/tests/simple_tests/2D_regularD_constH_BPD.i

# Test for bond-based peridynamic formulation
# for regular grid from generated mesh with const bond constants

# Square plate with Dirichlet boundary conditions applied
# at the left, top and bottom edges

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1002
    value = 0.0
  [../]
  [./bottom_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1000
    function = '-0.001*t'
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = BOND
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.33
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialBPD
  [../]
[]

[Functions]
  [./disp_x_anal]
    type = PiecewiseLinear
    axis = x
    x = '0 1'
    y = '0 -0.00033'
  [../]
  [./disp_y_anal]
    type = PiecewiseLinear
    axis = y
    x = '0 1'
    y = '-0.001 0'
  [../]
[]

[Postprocessors]
  [./anal_disp_L2]
    type = NodalFunctionsL2NormPD
    functions = 'disp_x_anal disp_y_anal'
  [../]
  [./disp_diff_L2]
    type = NodalDisplacementDifferenceL2NormPD
    analytic_functions = 'disp_x_anal disp_y_anal'
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none
  start_time = 0
  end_time = 1
[]

[Outputs]
  file_base = 2D_regularD_constH_BPD
  exodus = true
[]

modules/combined/test/tests/mechanical_contact_constraint/blocks_2d/frictionless_penalty_dirac.i

# This is a dirac (contact formulation) version of frictionless_penalty.i
[Mesh]
  file = blocks_2d.e
[]

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Functions]
  [./vertical_movement]
    type = ParsedFunction
    value = -t
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
  [../]
[]

[AuxKernels]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 3
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    #Initial gap is 0.01
    value = -0.02
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = vertical_movement
  [../]
[]

[Materials]
  [./left]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  [../]
  [./right]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 1000
  dt = 0.01
  end_time = 0.10
  num_steps = 1000
  l_tol = 1e-6
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-8
  dtmin = 0.01

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    master = 2
    slave = 3
    model = frictionless
    formulation = penalty
    penalty = 1e+7
    system = diracKernel
  [../]
[]

modules/tensor_mechanics/test/tests/thermal_expansion/constant_expansion_coeff_restart.i

# This test involves only thermal expansion strains on a 2x2x2 cube of approximate
# steel material.  An initial temperature of 25 degrees C is given for the material,
# and an auxkernel is used to calculate the temperature in the entire cube to
# raise the temperature each time step.  After the first timestep,in which the
# temperature jumps, the temperature increases by 6.25C each timestep.
# The thermal strain increment should therefore be
#     6.25 C * 1.3e-5 1/C = 8.125e-5 m/m.

# This test is also designed to be used to identify problems with restart files

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[Problem]
  restart_file_base =  constant_expansion_coeff_out_cp/LATEST
  force_restart = true
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t*(500.0)+300.0
  [../]
[]

[Modules]
    [TensorMechanics]
        [Master]
            [./all]
                strain = SMALL
                incremental = true
                add_variables = true
                eigenstrain_names = eigenstrain
                generate_output = 'strain_xx strain_yy strain_zz'
            [../]
        [../]
    [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
    use_displaced_mesh = false
  [../]
[]

[BCs]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 298
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  end_time = 0.1
  dt = 0.0125
  dtmin = 0.0001
[]

[Outputs]
  csv = true
  exodus = true
  checkpoint = true
[]

[Postprocessors]
  [./strain_xx]
    type = ElementAverageValue
    variable = strain_xx
  [../]
  [./strain_yy]
    type = ElementAverageValue
    variable = strain_yy
  [../]
  [./strain_zz]
    type = ElementAverageValue
    variable = strain_zz
  [../]
  [./temperature]
    type = AverageNodalVariableValue
    variable = temp
  [../]
[]

modules/tensor_mechanics/test/tests/domain_integral_thermal/j_integral_2d_ctefunc.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack2d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = 10.0*(2*x/504)
  [../]
  [./cte_func]
    type = PiecewiseLinear
    x = '-10 -6 -2 0 2 6 10'
    y = '1.484e-5 1.489e-5 1.494e-5 1.496e-5 1.498e-5 1.502e-5 1.505e-5'
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  radius_inner = '60.0 80.0 100.0 120.0'
  radius_outer = '80.0 100.0 120.0 140.0'
  temperature = temp
  incremental = true
  eigenstrain_names = thermal_expansion
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
    eigenstrain_names = thermal_expansion
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    block = 1
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 400
    value = 0.0
  [../]

  [./no_x1]
    type = DirichletBC
    variable = disp_x
    boundary = 900
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeInstantaneousThermalExpansionFunctionEigenstrain
    block = 1
    thermal_expansion_function = cte_func
    stress_free_temperature = 0.0
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart -sub_ksp_type -sub_pc_type -pc_asm_overlap'
  petsc_options_value = 'asm         31   preonly   lu      1'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 40

  nl_rel_step_tol= 1e-10
  nl_rel_tol = 1e-10

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  csv = true
[]

[Preconditioning]
  [./smp]
    type = SMP
    pc_side = left
    ksp_norm = preconditioned
    full = true
  [../]
[]

modules/tensor_mechanics/test/tests/generalized_plane_strain/generalized_plane_strain_increment.i

[GlobalParams]
  displacements = 'disp_x disp_y'
  scalar_out_of_plane_strain = scalar_strain_zz
  block = 1
[]

[Mesh]
  file = square.e
[]

[Variables]
  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
[]

[Postprocessors]
  [./react_z]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    incremental = true
    add_variables = true
    generate_output = 'stress_xx stress_xy stress_yy stress_zz strain_xx strain_xy strain_yy strain_zz'
    planar_formulation = GENERALIZED_PLANE_STRAIN
    eigenstrain_names = eigenstrain
    scalar_out_of_plane_strain = scalar_strain_zz
    temperature = temp
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

  # controls for linear iterations
  l_max_its = 100
  l_tol = 1e-4

  # controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-5

  # time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/mortar_tm/2drz/ad_frictionless_second/finite_rr.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'finite_rr'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    use_automatic_differentiation = true
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
    extra_vector_tags = 'ref'
  [../]
  [./plank]
    use_automatic_differentiation = true
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
    extra_vector_tags = 'ref'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ADComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
  nl_abs_tol = 1e-12
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/jacobian/cto26.i

# CappedDruckerPrager

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]


[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 2
    internal_limit = 100
  [../]
  [./cs]
    type = TensorMechanicsHardeningCubic
    value_0 = 5
    value_residual = 3
    internal_limit = 100
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningCubic
    value_0 = 10
    value_residual = 1
    internal_limit = 100
  [../]
  [./phi]
    type = TensorMechanicsHardeningCubic
    value_0 = 0.8
    value_residual = 0.4
    internal_limit = 50
  [../]
  [./psi]
    type = TensorMechanicsHardeningCubic
    value_0 = 0.4
    value_residual = 0
    internal_limit = 10
  [../]
  [./dp]
    type = TensorMechanicsPlasticDruckerPragerHyperbolic
    mc_cohesion = mc_coh
    mc_friction_angle = phi
    mc_dilation_angle = psi
    yield_function_tolerance = 1E-11     # irrelevant here
    internal_constraint_tolerance = 1E-9 # irrelevant here
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    lambda = 0.1
    shear_modulus = 1.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '6 5 4  5 7 2  4 2 2'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = dp
  [../]
  [./dp]
    type = CappedDruckerPragerStressUpdate
    DP_model = dp
    tensile_strength = ts
    compressive_strength = cs
    yield_function_tol = 1E-11
    tip_smoother = 1
    smoothing_tol = 1
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/peridynamics/test/tests/simple_tests/2D_regularD_constH_OSPD.i

# Test for ordinary state-based peridynamic formulation
# for regular grid from generated mesh with const bond constants
# partial Jacobian
# Jacobian from bond-based formulation is used for preconditioning

# Square plate with Dirichlet boundary conditions applied
# at the left, top and bottom edges

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1002
    value = 0.0
  [../]
  [./bottom_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1000
    function = '-0.001 * t'
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = ORDINARY_STATE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e5
    poissons_ratio = 0.0
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialOSPD
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none
  start_time = 0
  end_time = 1
[]

[Outputs]
  file_base = 2D_regularD_constH_OSPD
  exodus = true
[]

modules/combined/test/tests/solid_mechanics/pressure/pressure_rz_test.i

#
# Pressure Test
#
# This test is taken from the Abaqus verification manual:
#   "1.3.4 Axisymmetric solid elements"
#
# The two lower nodes are not allowed to translate in the z direction.
# Step 1:
#   Pressure of 1000 is applied on each face.
# Step 2:
#   Step 1 load plus a pressure on the vertical faces that varies from
#   0 to 1000 from top to bottom.
#
# Solution:
# Step 1:
#    Stress xx, yy, zz = -1000
#    Stress xy = 0
# Step 2:
#    Stress xx, zz = -1500
#    Stress yy = -1000
#    Stress xy = 0

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]#Comment
  file = pressure_rz_test.e
[] # Mesh

[Functions]
  [./constant]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 1e3
  [../]
  [./vary]
    type = ParsedFunction
    value = 'if(t <= 1, 1000 , 1000+1000*(1-y))'
  [../]
[] # Functions

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = SMALL
    additional_generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx'
  []
[]

[BCs]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]

  [./Pressure]
    [./Pressure1]
      boundary = '3 4'
      function = constant
    [../]
    [./Pressure2]
      boundary = '1 2'
      function = vary
    [../]
  [../]
[] # BCs

[Materials]
  [./constant]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]
  [./constant_stress]
    type = ComputeLinearElasticStress
    block = '1'
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10
  nl_rel_tol = 1e-12

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[] # Executioner

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
  [../]
[] # Outputs

modules/combined/test/tests/contact_verification/patch_tests/plane_2/plane2_mu_0_2_pen.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane2_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-7
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = plane2_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = plane2_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x5 disp_y5 disp_x9 disp_y9 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/capped_mohr_coulomb/random5.i

# Using CappedMohrCoulomb
# Plasticity models:
# Tensile strength = 1.5
# Compressive strength = 3.0
# Cohesion = 1.0
# Friction angle = dilation angle = 20deg
#
# Young = 1, Poisson = 0.3
#
# A line of elements is perturbed randomly, and return to the yield surface at each quadpoint is checked

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 100
  ny = 12
  nz = 1
  xmin = 0
  xmax = 100
  ymin = 0
  ymax = 12
  zmin = 0
  zmax = 1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[ICs]
  [./x]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_x
  [../]
  [./y]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_y
  [../]
  [./z]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_z
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./Smax]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./Smid]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./Smin]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./Smax]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = Smax
    scalar_type = MaxPrincipal
  [../]
  [./Smid]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = Smid
    scalar_type = MidPrincipal
  [../]
  [./Smin]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = Smin
    scalar_type = MinPrincipal
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1.5
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 3.0
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1.0
  [../]
  [./phi]
    type = TensorMechanicsHardeningConstant
    value = 20
    convert_to_radians = true
  [../]
  [./psi]
    type = TensorMechanicsHardeningConstant
    value = 3
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 100
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./capped_mc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = phi
    dilation_angle = psi
    smoothing_tol = 0.2
    yield_function_tol = 1.0E-12
    max_NR_iterations = 1000
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = capped_mc
    perform_finite_strain_rotations = false
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = random5
  exodus = true
[]

modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymm_plane_strain_finite.i

#
# This test checks elastic stress calculations with mechanical and thermal
# strain using finite strain formulation. Young's modulus is 3600, and Poisson's ratio is 0.2.
# The axisymmetric, plane strain 1D mesh is pulled with displacement of 2e-3.
# Thus, the strain is [log(1+1e-3)=9.995e-4, 0, log(1+1e-3)=9.995e-4] (xx, yy, zz). This gives stress of
# [4.9975, 1.999, 4.9975].  After a temperature increase of 100 with alpha of
# 1e-6, the stress becomes [4.3975, 1.399, 4.3975].
#

[GlobalParams]
  displacements = disp_x
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = line.e
[]

[Variables]
  [./disp_x]
  [../]
[]

[AuxVariables]
  [./temp]
    initial_condition = 580.0
  [../]
[]

[Functions]
  [./temp]
    type = PiecewiseLinear
    x = '0   1   2'
    y = '580 580 680'
  [../]
  [./disp_x]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 2e-3'
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./ps]
        planar_formulation = PLANE_STRAIN
        strain = FINITE
        generate_output = 'strain_xx strain_zz stress_xx stress_yy stress_zz'
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    function = temp
    execute_on = 'timestep_begin'
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    boundary = 1
    value = 0
    variable = disp_x
  [../]
  [./disp_x]
    type = FunctionDirichletBC
    boundary = 2
    function = disp_x
    variable = disp_x
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 3600
    poissons_ratio = 0.2
  [../]

  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-6
    temperature = temp
    stress_free_temperature = 580
    eigenstrain_name = eigenstrain
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  line_search = 'none'

  l_max_its = 50
  l_tol = 1e-6
  nl_max_its = 15
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-10
  start_time = 0
  end_time = 2
  num_steps = 2
[]

[Outputs]
  exodus = true
  console = true
[]

modules/combined/test/tests/normalized_penalty/normalized_penalty_kin.i

[GlobalParams]
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = normalized_penalty.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Functions]
  [./left_x]
    type = PiecewiseLinear
    x = '0 1 2'
    y = '0 0.02 0'
  [../]
[]

[AuxVariables]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx'
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  []
[]

[Contact]
  [./m3_s2]
    master = 3
    slave = 2
    penalty = 1e10
    normalize_penalty = true
    tangential_tolerance = 1e-3
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 1
    function = left_x
  [../]

  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2 3 4'
    value = 0.0
  [../]

  [./right]
    type = DirichletBC
    variable = disp_x
    boundary = '3 4'
    value = 0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2 3 4 1000'
    youngs_modulus = 3e8
    poissons_ratio = 0.0
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2 3 4 1000'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'lu       101'

  line_search = 'none'

  nl_rel_tol = 1e-12
  nl_abs_tol = 3e-8

  l_max_its = 100
  nl_max_its = 20
  dt = 0.5
  num_steps = 4
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/hertz_cyl/half_symm_q8/hertz_cyl_half_1deg_template1.i

[GlobalParams]
  order = SECOND
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_half_1deg.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. 0.0 0.0014'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./disp_x639]
    type = NodalVariableValue
    nodeid = 638
    variable = disp_x
  [../]
  [./disp_y639]
    type = NodalVariableValue
    nodeid = 638
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disp_ramp_vert
  [../]
  [./top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = disp_ramp_horz
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
  [./stuff5_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '5'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff5_strain]
    type = ComputeFiniteStrain
    block = '5'
  [../]
  [./stuff5_stress]
    type = ComputeFiniteStrainElasticStress
    block = '5'
  [../]
  [./stuff6_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '6'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff6_strain]
    type = ComputeFiniteStrain
    block = '6'
  [../]
  [./stuff6_stress]
    type = ComputeFiniteStrainElasticStress
    block = '6'
  [../]
  [./stuff7_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '7'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff7_strain]
    type = ComputeFiniteStrain
    block = '7'
  [../]
  [./stuff7_stress]
    type = ComputeFiniteStrainElasticStress
    block = '7'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-6
  nl_rel_tol = 1e-5
  l_max_its = 100
  nl_max_its = 200

  start_time = 0.0
  end_time = 3.5
  l_tol = 1e-3
  dt = 0.1
  dtmin = 0.1
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./chkfile2]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x639 disp_y639 top_react_x top_react_y'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    master = 2
    slave = 3
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+10
    system = Constraint
  [../]
[]

modules/combined/test/tests/ad_power_law_creep/power_law_creep_restart2.i

# 1x1x1 unit cube with uniform pressure on top face

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
    initial_condition = 1000.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    incremental = true
    add_variables = true
    generate_output = 'stress_yy creep_strain_xx creep_strain_yy creep_strain_zz elastic_strain_yy'
    use_automatic_differentiation = true
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1'
  [../]
[]

[Kernels]
  [./heat]
    type = ADHeatConduction
    variable = temp
  [../]
  [./heat_ie]
    type = ADHeatConductionTimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./u_top_pull]
    type = ADPressure
    variable = disp_y
    component = 1
    boundary = top
    constant = -10.0e6
    function = top_pull
  [../]
  [./u_bottom_fix]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = ADDirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp_fix]
    type = DirichletBC
    variable = temp
    boundary = 'bottom top'
    value = 1000.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e11
    poissons_ratio = 0.3
  [../]
  [./radial_return_stress]
    type = ADComputeMultipleInelasticStress
    inelastic_models = 'power_law_creep'
  [../]
  [./power_law_creep]
    type = ADPowerLawCreepStressUpdate
    coefficient = 1.0e-15
    n_exponent = 4
    activation_energy = 3.0e5
    temperature = temp
  [../]

  [./thermal]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 100.
  [../]
  [./density]
    type = ADDensity
    density = 1.0
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 20
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-6
  l_tol = 1e-5
  start_time = 0.6
  end_time = 1.0
  num_steps = 12
  dt = 0.1
[]

[Outputs]
  file_base = power_law_creep_out
  exodus = true
[]

[Problem]
  restart_file_base = power_law_creep_restart1_out_cp/0006
[]

modules/combined/test/tests/solid_mechanics/Wave_1_D/Rayleigh_HHT/wave_bc_1d.i

# Wave propogation in 1-D using HHT time integration in the presence
# of Rayleigh damping
#
# The test is for an 1-D bar element of length 4m fixed on one end
# with a sinusoidal pulse dirichlet boundary condition applied to the
# other end.  alpha, beta and gamma are HHT time integration
# parameters eta and zeta are mass dependent and stiffness dependent
# Rayleigh damping coefficients, respectively.  The equation of motion
# in terms of matrices is:
#
# M*accel + (eta*M+zeta*K)*((1+alpha)*vel-alpha*vel_old)+(1+alpha)*K*disp-alpha*K*disp_old = 0
#
# Here M is the mass matrix, K is the stiffness matrix
#
# The displacement at the first, second, third and fourth node at t = 0.1 are
# -7.787499960311491942e-02, 1.955566679096475483e-02 and -4.634888180231294501e-03, respectively.
[GlobalParams]
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 4
  nz = 1
  xmin = 0.0
  xmax = 0.1
  ymin = 0.0
  ymax = 4.0
  zmin = 0.0
  zmax = 0.1
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./vel_x]
  [../]
  [./accel_x]
  [../]
  [./vel_y]
  [../]
  [./accel_y]
  [../]
  [./vel_z]
  [../]
  [./accel_z]
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

[]

[Kernels]
  [./DynamicTensorMechanics]
    use_displaced_mesh = false
    zeta = 0.1
    alpha = -0.3
  [../]

 [./inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.422
    gamma = 0.8
    eta=0.1
    alpha = -0.3
    use_displaced_mesh = false
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.422
    gamma = 0.8
    eta=0.1
    alpha = -0.3
    use_displaced_mesh = false
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    velocity = vel_z
    acceleration = accel_z
    beta = 0.422
    gamma = 0.8
    eta = 0.1
    alpha = -0.3
    use_displaced_mesh = false
  [../]

[]

[AuxKernels]
  [./accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.422
    execute_on = timestep_end
  [../]
  [./vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.8
    execute_on = timestep_end
  [../]
  [./accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.422
    execute_on = timestep_end
  [../]
  [./vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.8
    execute_on = timestep_end
  [../]
  [./accel_z]
    type = NewmarkAccelAux
    variable = accel_z
    displacement = disp_z
    velocity = vel_z
    beta = 0.422
    execute_on = timestep_end
  [../]
  [./vel_z]
    type = NewmarkVelAux
    variable = vel_z
    acceleration = accel_z
    gamma = 0.8
    execute_on = timestep_end
  [../]

[]


[BCs]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value=0.0
  [../]
  [./top_x]
   type = DirichletBC
    variable = disp_x
    boundary = top
    value=0.0
  [../]
  [./top_z]
    type = DirichletBC
    variable = disp_z
    boundary = top
    value=0.0
  [../]
  [./right_x]
   type = DirichletBC
    variable = disp_x
    boundary = right
    value=0.0
  [../]
  [./right_z]
    type = DirichletBC
    variable = disp_z
    boundary = right
    value=0.0
  [../]
  [./left_x]
   type = DirichletBC
    variable = disp_x
    boundary = left
    value=0.0
  [../]
  [./left_z]
    type = DirichletBC
    variable = disp_z
    boundary = left
    value=0.0
  [../]
  [./front_x]
   type = DirichletBC
    variable = disp_x
    boundary = front
    value=0.0
  [../]
  [./front_z]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value=0.0
  [../]
  [./back_x]
   type = DirichletBC
    variable = disp_x
    boundary = back
    value=0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value=0.0
  [../]
    [./bottom_x]
      type = DirichletBC
      variable = disp_x
      boundary = bottom
      value=0.0
    [../]
    [./bottom_z]
      type = DirichletBC
      variable = disp_z
      boundary = bottom
      value=0.0
    [../]
    [./bottom_y]
      type = FunctionDirichletBC
      variable = disp_y
      boundary = bottom
      function = displacement_bc
    [../]
[]

[Materials]
  [./constant]
    type = ComputeIsotropicElasticityTensor
    block = '0'
    youngs_modulus = 1.0
    poissons_ratio = 0.0
  [../]

  [./constant_strain]
    type= ComputeFiniteStrain
    block = '0'
  [../]
  [./constant_stress]
    type = ComputeFiniteStrainElasticStress
    block = '0'
  [../]
  [./density]
    type = GenericConstantMaterial
    block = '0'
    prop_names = 'density'
    prop_values = '1'
  [../]
[]


[Executioner]

  type = Transient
  start_time = 0
  end_time = 6.0
  dtmax = 0.1
  dtmin = 0.1
  l_tol = 1e-8
  nl_rel_tol = 1e-8
  [./TimeStepper]
    type = ConstantDT
    dt = 0.1
  [../]

[]

[Functions]
  [./pressure]
    type = PiecewiseLinear
    x = '0.0 0.1 0.2 1.0 2.0 5.0'
    y = '0.0 0.001 1 0.001 0.0 0.0'
    scale_factor = 7750
  [../]
  [./displacement_ic]
    type = PiecewiseLinear
    axis = y
    x = '0.0 0.3 0.4 0.5 0.6 0.7 1.0'
    y = '0.0 0.0 0.0001 1.0 0.0001 0.0 0.0'
    scale_factor = 0.1
  [../]
  [./displacement_bc]
    type = PiecewiseLinear
    data_file = 'sine_wave.csv'
    format = columns
  [../]

[]

[Postprocessors]
   [./_dt]
     type = TimestepSize
   [../]
    [./disp_1]
       type = NodalVariableValue
       nodeid = 1
       variable = disp_y
     [../]
    [./disp_2]
       type = NodalVariableValue
       nodeid = 3
       variable = disp_y
     [../]
    [./disp_3]
       type = NodalVariableValue
       nodeid = 10
       variable = disp_y
     [../]
    [./disp_4]
       type = NodalVariableValue
       nodeid = 14
       variable = disp_y
     [../]
[]

[Outputs]
  exodus = true
  csv = true
  print_linear_residuals = true
  perf_graph = true
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update22.i

# MC update version, with only MohrCoulomb, cohesion=10, friction angle = 60, psi = 5, smoothing_tol = 1
# Lame lambda = 0.5.  Lame mu = 1

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./phi]
    type = TensorMechanicsHardeningConstant
    value = 60
    convert_to_radians = true
  [../]
  [./psi]
    type = TensorMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 0.5
    shear_modulus = 1.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '6 5 4  5 7 2  4 2 2'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = phi
    dilation_angle = psi
    smoothing_tol = 1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/j_integral_vtest/j_int_surfbreak_ellip_crack_sym_mm.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = ellip_crack_4sym_norad_mm.e
  partitioner = centroid
  centroid_partitioner_direction = z
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./resid_z]
  [../]
[]

[Functions]
  [./rampConstantUp]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 0.1'
    scale_factor = -689.5 #MPa
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 1001
  crack_direction_method = CurvedCrackFront
  crack_end_direction_method = CrackDirectionVector
  crack_direction_vector_end_1 = '0.0 1.0 0.0'
  crack_direction_vector_end_2 = '1.0 0.0 0.0'
  radius_inner = '12.5 25.0 37.5'
  radius_outer = '25.0 37.5 50.0'
  intersecting_boundary = '1 2'
  symmetry_plane = 2
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 12
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 5
      function = rampConstantUp
    [../]
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 206800
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]

   type = Transient
  # Two sets of linesearch options are for petsc 3.1 and 3.3 respectively
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

#  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'
  line_search = 'none'

   l_max_its = 50
   nl_max_its = 20
   nl_abs_tol = 1e-5
   nl_rel_tol = 1e-11
   l_tol = 1e-2

   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1
[]

[Postprocessors]
  [./_dt]
    type = TimestepSize
  [../]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./lin_its]
    type = NumLinearIterations
  [../]
  [./react_z]
    type = NodalSum
    variable = resid_z
    boundary = 5
  [../]
[]

[Outputs]
  execute_on = 'timestep_end'
  file_base = j_int_surfbreak_ellip_crack_sym_mm_out
  exodus = true
  csv = true
[]

modules/combined/test/tests/solid_mechanics/spherical_shell/2D-RZ_test.i

# Considers the mechanics solution for a thick spherical shell that is uniformly
# pressurized on the inner and outer surfaces. Three versions of the test are
# provided, assuming 1D spherical geometry (1D-SPH), 2D axisymmetic geometry
# (2D-RZ), and 3D geometry (3D). The tests demonstrate that all three geometric
# approaches produce the same correct solution.
#
# From Roark (Formulas for Stress and Strain, McGraw-Hill, 1975), the radially-dependent
# circumferential stress in a uniformly pressurized thick spherical shell is given by:
#
# S(r) = [ Pi[ri^3(2r^3+ro^3)] - Po[ro^3(2r^3+ri^3)] ] / [2r^3(ro^3-ri^3)]
#
#   where:
#          Pi = inner pressure
#          Po = outer pressure
#          ri = inner radius
#          ro = outer radius
#
# The tests assume an inner and outer radii of 5 and 10, with internal and external
# pressures of 100000 and 200000, respectively. The resulting compressive tangential
# stress is largest at the inner wall and, from the above equation, has a value
# of -271429.
#
# RESULTS are below. Since stresses are average element values, values for the
# edge element and one-element-in are used to extrapolate the stress to the
# inner surface. The vesrion of the tests that are checked use the coarsest meshes.
#
#  Mesh    Radial elem   S(edge elem)  S(one elem in)  S(extrap to surf)
# 1D-SPH       12          -264842      -254419        -270053
# 2D-RZ        12          -265007      -254668        -270177
#  3D          12 (4x4)    -258922      -251099        -262834
#  3D          12 (6x6)    -262194      -252969        -266807
#
# 1D-SPH       48          -269679      -266390        -271323
# 2D-RZ        48          -269723      -266470        -271350
#  3D          48          -268617      -265717        -270067
#
# 1D-SPH      100          -270580      -268932        -271404
# 2D-RZ       100          -270587      -268946        -271408
#
# The numerical solution converges to the analytical solution as the mesh is
# refined.

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = 2D-RZ_mesh.e
[]

[Problem]
  coord_type = RZ
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    additional_generate_output = 'stress_zz'
  []
[]

[BCs]
# pin particle along symmetry planes
  [./no_disp_x]
    type = DirichletBC
    variable = disp_x
    boundary = xzero
    value = 0.0
  [../]

  [./no_disp_y]
    type = DirichletBC
    variable = disp_y
    boundary = yzero
    value = 0.0
  [../]

# exterior and internal pressures
  [./exterior_pressure_x]
    type = Pressure
    variable = disp_x
    boundary = outer
    component = 0
    factor = 200000
  [../]

 [./exterior_pressure_y]
    type = Pressure
    variable = disp_y
    boundary = outer
    component = 1
    factor = 200000
  [../]

  [./interior_pressure_x]
    type = Pressure
    variable = disp_x
    boundary = inner
    component = 0
    factor = 100000
  [../]

  [./interior_pressure_y]
    type = Pressure
    variable = disp_y
    boundary = inner
    component = 1
    factor = 100000
  [../]
[]

[Materials]
  [./fuel_disp]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./fuel_disp_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
[]

[Debug]
    show_var_residual_norms = true
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50

   start_time = 0.0
   end_time = 1
   num_steps = 1000

  dtmax = 5e6
  dtmin = 1
  [./TimeStepper]
    type = IterationAdaptiveDT
    dt = 1
    optimal_iterations = 6
    iteration_window = 0
    linear_iteration_ratio = 100
  [../]

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

#  [./Quadrature]
#    order = THIRD
#  [../]
[]

[Postprocessors]
  [./dt]
    type = TimestepSize
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/radial_disp_aux/sphere_3d_cartesian.i

# The purpose of this set of tests is to check the values computed
# by the RadialDisplacementAux AuxKernel. They should match the
# radial component of the displacment for a cylindrical or spherical
# model.
# This particular model is of a sphere subjected to uniform thermal
# expansion represented using a 3D Cartesian model.

[Mesh]
  type = FileMesh
  file = sphere_sector_3d.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  order = SECOND
  family = LAGRANGE
[]

[AuxVariables]
  [./temp]
  [../]
  [./rad_disp]
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t+300.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    eigenstrain_names = eigenstrain
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
    use_displaced_mesh = false
  [../]
  [./raddispaux]
    type = RadialDisplacementSphereAux
    variable = rad_disp
    origin = '0 0 0'
  [../]
[]

[BCs]
  [./x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./z]
    type = DirichletBC
    variable = disp_z
    boundary = 3
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 300
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '51'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10

  start_time = 0.0
  end_time = 1
  dt = 1
  dtmin = 1
[]

[Outputs]
 csv = true
 exodus = true
[]

#[Postprocessors]
#  [./strain_xx]
#    type = SideAverageValue
#    variable =
#    block = 0
#  [../]
#[]

modules/combined/test/tests/contact_verification/patch_tests/brick_4/brick4_template1.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick4_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_x
  [../]
  [./disp_x64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_x
  [../]
  [./disp_y59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_y
  [../]
  [./disp_y64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x59 disp_y59 disp_x64 disp_y64 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymm_gps_incremental.i

# this test checks the asixymmetric 1D generalized plane strain formulation using incremental small strains

[GlobalParams]
  displacements = disp_x
  scalar_out_of_plane_strain = scalar_strain_yy
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = line.e
[]

[Variables]
  [./disp_x]
  [../]
  [./scalar_strain_yy]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./temp]
    initial_condition = 580.0
  [../]
[]

[Functions]
  [./temp]
    type = PiecewiseLinear
    x = '0   1   2'
    y = '580 580 680'
  [../]
  [./disp_x]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 2e-6'
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./GeneralizedPlaneStrain]
      [./gps]
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_zz
    index_i = 2
    index_j = 2
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./temp]
    type = FunctionAux
    variable = temp
    function = temp
    execute_on = 'timestep_begin'
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    boundary = 1
    value = 0
    variable = disp_x
  [../]
  [./disp_x]
    type = FunctionDirichletBC
    boundary = 2
    function = disp_x
    variable = disp_x
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 3600
    poissons_ratio = 0.2
  [../]

  [./strain]
    type = ComputeAxisymmetric1DIncrementalStrain
    eigenstrain_names = eigenstrain
    scalar_out_of_plane_strain = scalar_strain_yy
  [../]

  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-8
    temperature = temp
    stress_free_temperature = 580
    eigenstrain_name = eigenstrain
  [../]

  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  line_search = 'none'

  l_max_its = 50
  l_tol = 1e-6
  nl_max_its = 15
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-10
  start_time = 0
  end_time = 2
  num_steps = 2
[]

[Outputs]
  exodus = true
  console = true
[]

modules/combined/test/tests/gravity/gravity_qp_select.i

# Gravity Test
#
# This test is similar to the other gravity tests, but it also tests the
# capability in MaterialTensorAux to return the stress of a single,
# specified integration point, rather than the element average.
# To get the stress at a single integration point, set the parameter
# qp_select to the integration point number (i.e. 0-9 for a quad 8)
# in the AuxKernel
#
# The mesh for this problem is a unit square.
#
# The boundary conditions for this problem are as follows.  The
#   displacement is zero on each of side that faces a negative
#   coordinate direction.  The acceleration of gravity is 20.
#
# The material has a Young's modulus of 1e6 and a density of 2.
#
# The analytic solution for the displacement along the bar is:
#
# u(x) = -b*x^2/(2*E)+b*L*x/E
#
# The displacement at x=L is b*L^2/(2*E) = 2*20*1*1/(2*1e6) = 0.00002.
#
# The analytic solution for the stress along the bar assuming linear
#   elasticity is:
#
# S(x) = b*(L-x)
#
# The stress at x=0 is b*L = 2*20*1 = 40.
#
# Note:  The isoparametric coordinate for a quad8 (fourth order) element
# is: +/- 0.77459667 and 0.  For a 1 unit square with the edge of
# the element in the x = 0 plane, there would be an integration point
# at x_coordinate 0.5 - 0.5*0.77459667 (0.11270167), 0.5, and
# 0.50 + 0.5*0.77459667 (0.88729834).
#
# The corresponding stresses are:
#
# S(0.11270167) = 40(1-0.11270167) = 35.491933
# S(0.5) = 40(1-0.5) = 20
# S(0.88729834) = 40(1-0.88729834) = 4.5080664
#
# These stresses are a precise match to the simulation result.
#

[GlobalParams]
  displacements = 'disp_x disp_y'
  order = SECOND
  family = LAGRANGE
[]

[Mesh]
  file = gravity_2D.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx_qp_0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx_qp_1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx_qp_2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx_qp_3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx_qp_4]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx_qp_5]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx_qp_6]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx_qp_7]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xx_qp_8]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Modules/TensorMechanics/Master/All]
  strain = FINITE
  #incremental = true
  add_variables = true
  generate_output = 'stress_xx'
[]

[Kernels]
  [./gravity]
    type = Gravity
    variable = disp_x
    value = 20
  [../]
[]

[AuxKernels]
  [./stress_xx_qp_0]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_qp_0
    index_i = 0
    index_j = 0
    selected_qp = 0
  [../]
  [./stress_xx_qp_1]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_qp_1
    index_i = 0
    index_j = 0
    selected_qp = 1
  [../]
  [./stress_xx_qp_2]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_qp_2
    index_i = 0
    index_j = 0
    selected_qp = 2
  [../]
  [./stress_xx_qp_3]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_qp_3
    index_i = 0
    index_j = 0
    selected_qp = 3
  [../]
  [./stress_xx_qp_4]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_qp_4
    index_i = 0
    index_j = 0
    selected_qp = 4
  [../]
  [./stress_xx_qp_5]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_qp_5
    index_i = 0
    index_j = 0
    selected_qp = 5
  [../]
  [./stress_xx_qp_6]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_qp_6
    index_i = 0
    index_j = 0
    selected_qp = 6
  [../]
  [./stress_xx_qp_7]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_qp_7
    index_i = 0
    index_j = 0
    selected_qp = 7
  [../]
  [./stress_xx_qp_8]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx_qp_8
    index_i = 0
    index_j = 0
    selected_qp = 8
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_y
    boundary = 5
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    bulk_modulus = 0.333333333333333e6
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./density]
    type = Density
    density = 2
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  start_time = 0.0
  end_time = 1.0
[]

[Outputs]
  file_base = gravity_qp_select_out
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_2/brick2_template1.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick2_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_x26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_x
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./disp_y26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5

[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x7 disp_y7 disp_x26 disp_y26 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_3/brick3_template2.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick3_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_x
  [../]
  [./disp_x33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_x
  [../]
  [./disp_y28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_y
  [../]
  [./disp_y33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-7
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x28 disp_y28 disp_x33 disp_y33 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+7
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/porous_flow/examples/thm_example/2D.i

# Two phase, temperature-dependent, with mechanics, radial with fine mesh, constant injection of cold co2 into a overburden-reservoir-underburden containing mostly water
# species=0 is water
# species=1 is co2
# phase=0 is liquid, and since massfrac_ph0_sp0 = 1, this is all water
# phase=1 is gas, and since massfrac_ph1_sp0 = 0, this is all co2
#
# The mesh used below has very high resolution, so the simulation takes a long time to complete.
# Some suggested meshes of different resolution:
# nx=50, bias_x=1.2
# nx=100, bias_x=1.1
# nx=200, bias_x=1.05
# nx=400, bias_x=1.02
# nx=1000, bias_x=1.01
# nx=2000, bias_x=1.003
[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2000
  bias_x = 1.003
  xmin = 0.1
  xmax = 5000
  ny = 1
  ymin = 0
  ymax = 11
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
  PorousFlowDictator = dictator
  gravity = '0 0 0'
  biot_coefficient = 1.0
[]

[Variables]
  [./pwater]
    initial_condition = 18.3e6
  [../]
  [./sgas]
    initial_condition = 0.0
  [../]
  [./temp]
    initial_condition = 358
  [../]
  [./disp_r]
  [../]
[]

[AuxVariables]
  [./rate]
  [../]
  [./disp_z]
  [../]
  [./massfrac_ph0_sp0]
    initial_condition = 1 # all H20 in phase=0
  [../]
  [./massfrac_ph1_sp0]
    initial_condition = 0 # no H2O in phase=1
  [../]
  [./pgas]
    family = MONOMIAL
    order = FIRST
  [../]
  [./swater]
    family = MONOMIAL
    order = FIRST
  [../]
  [./stress_rr]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_tt]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [./mass_water_dot]
    type = PorousFlowMassTimeDerivative
    fluid_component = 0
    use_displaced_mesh = false
    variable = pwater
  [../]
  [./flux_water]
    type = PorousFlowAdvectiveFlux
    fluid_component = 0
    use_displaced_mesh = false
    variable = pwater
  [../]
  [./mass_co2_dot]
    type = PorousFlowMassTimeDerivative
    fluid_component = 1
    use_displaced_mesh = false
    variable = sgas
  [../]
  [./flux_co2]
    type = PorousFlowAdvectiveFlux
    fluid_component = 1
    use_displaced_mesh = false
    variable = sgas
  [../]
  [./energy_dot]
    type = PorousFlowEnergyTimeDerivative
    use_displaced_mesh = false
    variable = temp
  [../]
  [./advection]
    type = PorousFlowHeatAdvection
    use_displaced_mesh = false
    variable = temp
  [../]
  [./conduction]
    type = PorousFlowExponentialDecay
    use_displaced_mesh = false
    variable = temp
    reference = 358
    rate = rate
  [../]
  [./grad_stress_r]
    type = StressDivergenceRZTensors
    temperature = temp
    thermal_eigenstrain_name = thermal_contribution
    variable = disp_r
    use_displaced_mesh = false
    component = 0
  [../]
  [./poro_r]
    type = PorousFlowEffectiveStressCoupling
    variable = disp_r
    use_displaced_mesh = false
    component = 0
  [../]
[]

[AuxKernels]
  [./rate]
    type = FunctionAux
    variable = rate
    execute_on = timestep_begin
    function = decay_rate
  [../]
  [./pgas]
    type = PorousFlowPropertyAux
    property = pressure
    phase = 1
    variable = pgas
  [../]
  [./swater]
    type = PorousFlowPropertyAux
    property = saturation
    phase = 0
    variable = swater
  [../]
  [./stress_rr]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_rr
    index_i = 0
    index_j = 0
  [../]
  [./stress_tt]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_tt
    index_i = 2
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 1
    index_j = 1
  [../]
[]

[Functions]
  [./decay_rate]
# Eqn(26) of the first paper of LaForce et al.
# Ka * (rho C)_a = 10056886.914
# h = 11
    type = ParsedFunction
    value = 'sqrt(10056886.914/t)/11.0'
  [../]
[]

[UserObjects]
  [./dictator]
    type = PorousFlowDictator
    porous_flow_vars = 'temp pwater sgas disp_r'
    number_fluid_phases = 2
    number_fluid_components = 2
  [../]
  [./pc]
    type = PorousFlowCapillaryPressureConst
    pc = 0
  [../]
[]

[Modules]
  [./FluidProperties]
    [./water]
      type = SimpleFluidProperties
      bulk_modulus = 2.27e14
      density0 = 970.0
      viscosity = 0.3394e-3
      cv = 4149.0
      cp = 4149.0
      porepressure_coefficient = 0.0
      thermal_expansion = 0
    [../]
    [./co2]
      type = SimpleFluidProperties
      bulk_modulus = 2.27e14
      density0 = 516.48
      viscosity = 0.0393e-3
      cv = 2920.5
      cp = 2920.5
      porepressure_coefficient = 0.0
      thermal_expansion = 0
    [../]
  [../]
[]

[Materials]
  [./temperature]
    type = PorousFlowTemperature
    temperature = temp
  [../]
  [./ppss]
    type = PorousFlow2PhasePS
    phase0_porepressure = pwater
    phase1_saturation = sgas
    capillary_pressure = pc
  [../]
  [./massfrac]
    type = PorousFlowMassFraction
    mass_fraction_vars = 'massfrac_ph0_sp0 massfrac_ph1_sp0'
  [../]
  [./water]
    type = PorousFlowSingleComponentFluid
    fp = water
    phase = 0
  [../]
  [./gas]
    type = PorousFlowSingleComponentFluid
    fp = co2
    phase = 1
  [../]
  [./porosity_reservoir]
    type = PorousFlowPorosityConst
    porosity = 0.2
  [../]
  [./permeability_reservoir]
    type = PorousFlowPermeabilityConst
    permeability = '2e-12 0 0  0 0 0  0 0 0'
  [../]
  [./relperm_liquid]
    type = PorousFlowRelativePermeabilityCorey
    n = 4
    phase = 0
    s_res = 0.200
    sum_s_res = 0.405
  [../]
  [./relperm_gas]
    type = PorousFlowRelativePermeabilityBC
    phase = 1
    s_res = 0.205
    sum_s_res = 0.405
    nw_phase = true
    lambda = 2
  [../]
  [./thermal_conductivity_reservoir]
    type = PorousFlowThermalConductivityIdeal
    dry_thermal_conductivity = '0 0 0  0 1.320 0  0 0 0'
    wet_thermal_conductivity = '0 0 0  0 3.083 0  0 0 0'
  [../]
  [./internal_energy_reservoir]
    type = PorousFlowMatrixInternalEnergy
    specific_heat_capacity = 1100
    density = 2350.0
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    shear_modulus = 6.0E9
    poissons_ratio = 0.2
  [../]
  [./strain]
    type = ComputeAxisymmetricRZSmallStrain
    eigenstrain_names = 'thermal_contribution ini_stress'
  [../]
  [./ini_strain]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-12.8E6 0 0  0 -51.3E6 0  0 0 -12.8E6'
    eigenstrain_name = ini_stress
  [../]
  [./thermal_contribution]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    stress_free_temperature = 358
    thermal_expansion_coeff = 5E-6
    eigenstrain_name = thermal_contribution
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./eff_fluid_pressure]
    type = PorousFlowEffectiveFluidPressure
  [../]
  [./vol_strain]
    type = PorousFlowVolumetricStrain
  [../]
[]

[BCs]
  [./outer_pressure_fixed]
    type = DirichletBC
    boundary = right
    value = 18.3e6
    variable = pwater
  [../]
  [./outer_saturation_fixed]
    type = DirichletBC
    boundary = right
    value = 0.0
    variable = sgas
  [../]
  [./outer_temp_fixed]
    type = DirichletBC
    boundary = right
    value = 358
    variable = temp
  [../]
  [./fixed_outer_r]
    type = DirichletBC
    variable = disp_r
    value = 0
    boundary = right
  [../]
  [./co2_injection]
    type = PorousFlowSink
    boundary = left
    variable = sgas
    use_mobility = false
    use_relperm = false
    fluid_phase = 1
    flux_function = 'min(t/100.0,1)*(-2.294001475)' # 5.0E5 T/year = 15.855 kg/s, over area of 2Pi*0.1*11
  [../]
  [./cold_co2]
    type = DirichletBC
    boundary = left
    variable = temp
    value = 294
  [../]
  [./cavity_pressure_x]
    type = Pressure
    boundary = left
    variable = disp_r
    component = 0
    postprocessor = p_bh # note, this lags
    use_displaced_mesh = false
  [../]
[]

[Postprocessors]
  [./p_bh]
    type = PointValue
    variable = pwater
    point = '0.1 0 0'
    execute_on = timestep_begin
    use_displaced_mesh = false
  [../]
[]

[VectorPostprocessors]
  [./ptsuss]
    type = LineValueSampler
    use_displaced_mesh = false
    start_point = '0.1 0 0'
    end_point = '5000 0 0'
    sort_by = x
    num_points = 50000
    outputs = csv
    variable = 'pwater temp sgas disp_r stress_rr stress_tt'
  [../]
[]

[Preconditioning]
  active = 'mumps'
  [./smp]
    type = SMP
    full = true
    #petsc_options = '-snes_converged_reason -ksp_diagonal_scale -ksp_diagonal_scale_fix -ksp_gmres_modifiedgramschmidt -snes_linesearch_monitor'
    petsc_options_iname = '-ksp_type -pc_type -sub_pc_type -sub_pc_factor_shift_type -pc_asm_overlap -snes_atol -snes_rtol -snes_max_it'
    petsc_options_value = 'gmres      asm      lu           NONZERO                   2               1E2       1E-5        500'
  [../]
  [./mumps]
    type = SMP
    full = true
    petsc_options = '-snes_converged_reason -ksp_diagonal_scale -ksp_diagonal_scale_fix -ksp_gmres_modifiedgramschmidt -snes_linesearch_monitor'
    petsc_options_iname = '-ksp_type -pc_type -pc_factor_mat_solver_package -pc_factor_shift_type -snes_rtol -snes_atol -snes_max_it'
    petsc_options_value = 'gmres      lu       mumps                         NONZERO               1E-5       1E2       50'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1.5768e8
  #dtmax = 1e6
  [./TimeStepper]
    type = IterationAdaptiveDT
    dt = 1
    growth_factor = 1.1
  [../]
[]

[Outputs]
  print_linear_residuals = false
  sync_times = '3600 86400 2.592E6 1.5768E8'
  perf_graph = true
  exodus = true
  [./csv]
    type = CSV
    sync_only = true
  [../]
[]

modules/combined/test/tests/cavity_pressure/negative_volume.i

#
# Cavity Pressure Test
#
# This test is designed to compute a negative number of moles
# to trigger an error check in the CavityPressureUserObject.
# The negative number of moles is achieved by supplying an
# open volume to the InternalVolume postprocessor, which
# calculates a negative volume.

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 1
  ny = 2
[]

[Functions]
  [./temperature]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 2'
    scale_factor = 100
  [../]
[]

[Variables]
  [./temperature]
    initial_condition = 100
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    strain = FINITE
    add_variables = true
  [../]
[]

[Kernels]
  [./heat]
    type = Diffusion
    variable = temperature
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_r
    boundary = left
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]
  [./temperatureInterior]
    type = FunctionDirichletBC
    boundary = 2
    function = temperature
    variable = temperature
  [../]
  [./CavityPressure]
    [./pressure]
      boundary = 'top bottom right'
      initial_pressure = 10e5
      R = 8.3143
      output_initial_moles = initial_moles
      temperature = aveTempInterior
      volume = internalVolume
      startup_time = 0.5
      output = ppress
    [../]
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress1]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_abs_tol = 1e-10
  l_max_its = 20
  dt = 0.5
  end_time = 1.0
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 'top bottom right'
    execute_on = 'initial linear'
  [../]
  [./aveTempInterior]
    type = AxisymmetricCenterlineAverageValue
    boundary = left
    variable = temperature
    execute_on = 'initial linear'
  [../]
[]

[Outputs]
  exodus = false
[]

modules/tensor_mechanics/test/tests/jacobian/cto24.i

# CappedDruckerPrager

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]


[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 10
  [../]
  [./phi]
    type = TensorMechanicsHardeningConstant
    value = 0.8
  [../]
  [./psi]
    type = TensorMechanicsHardeningConstant
    value = 0.4
  [../]
  [./dp]
    type = TensorMechanicsPlasticDruckerPragerHyperbolic
    mc_cohesion = mc_coh
    mc_friction_angle = phi
    mc_dilation_angle = psi
    yield_function_tolerance = 1E-11     # irrelevant here
    internal_constraint_tolerance = 1E-9 # irrelevant here
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 0
    lambda = 0.7
    shear_modulus = 1.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '10 0 0  0 10 0  0 0 10'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = dp
  [../]
  [./dp]
    type = CappedDruckerPragerStressUpdate
    DP_model = dp
    tensile_strength = ts
    compressive_strength = cs
    yield_function_tol = 1E-11
    tip_smoother = 1
    smoothing_tol = 1
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/evolving_mass_density/rz_tensors.i

#  Constant mass in RZ using Tensor Mechanics
#
# This test forces an RZ mesh to move through a series of displacements
#   in order to test whether the mass is constant.  The density is chosen
#   such that the mass is 2.5.
# This test is a duplicate of the rz.i test for solid mechanics, and the
#   output of this tensor mechanics test is compared to the original
#   solid mechanics output.  The duplication is necessary to test the
#   migrated tensor mechanics version while maintaining tests for solid mechanics.

[Mesh]
  file = elastic_patch_rz.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Functions]
  [./x101]
    type = PiecewiseLinear
    x = '0 5 6'
    y = '0 0 0.24'
  [../]
  [./y101]
    type = PiecewiseLinear
    x = '0 6'
    y = '0 0'
  [../]
  [./x102]
    type = PiecewiseLinear
    x = '0 4 5'
    y = '0 0 0.24'
  [../]
  [./y102]
    type = PiecewiseLinear
    x = '0 1 2 3'
    y = '0 0 0.12 0'
  [../]
  [./x103]
    type = PiecewiseLinear
    x = '0 4 5'
    y = '0 0 0.24'
  [../]
  [./y103]
    type = PiecewiseLinear
    x = '0 1    3    4'
    y = '0 0.12 0.12 0'
  [../]
  [./x104]
    type = PiecewiseLinear
    x = '0 5 6'
    y = '0 0 0.24'
  [../]
  [./y104]
    type = PiecewiseLinear
    x = '0 2 3    4'
    y = '0 0 0.12 0'
  [../]
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[BCs]

  [./101x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 101
    function = x101
  [../]
  [./101y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 101
    function = y101
  [../]

  [./102x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 102
    function = x102
  [../]
  [./102y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 102
    function = y102
  [../]

  [./103x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 103
    function = x103
  [../]
  [./103y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 103
    function = y103
  [../]

  [./104x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 104
    function = x104
  [../]
  [./104y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 104
    function = y104
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = PATCH
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]

  [./small_strain_rz]
    type = ComputeAxisymmetricRZSmallStrain
    block = PATCH
  [../]

  [./elastic_stress]
    type = ComputeLinearElasticStress
    block = PATCH
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  # Two sets of linesearch options are for petsc 3.1 and 3.3 respectively
  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'lu       101'

  line_search = 'none'
  nl_abs_tol = 1e-10
  l_max_its = 20

  start_time = 0.0
  dt = 1
  num_steps = 6
  end_time = 6.0
[]

[Outputs]
  [./out]
    type = Exodus
    elemental_as_nodal = true
    file_base = rz_out
  [../]
[]

[Postprocessors]
  [./mass]
    type = Mass
    variable = disp_x
    execute_on = 'initial timestep_end'
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/cwp06.i

# Capped weak-plane plasticity
# checking jacobian for shear failure, with smoothing
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  block = 0
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./coh]
    type = TensorMechanicsHardeningExponential
    value_0 = 1
    value_residual = 1
    rate = 1
  [../]
  [./tanphi]
    type = TensorMechanicsHardeningExponential
    value_0 = 1.0
    value_residual = 1.0
    rate = 2
  [../]
  [./tanpsi]
    type = TensorMechanicsHardeningExponential
    value_0 = 0.1
    value_residual = 0.1
    rate = 1
  [../]
  [./t_strength]
    type = TensorMechanicsHardeningExponential
    value_0 = 100
    value_residual = 100
    rate = 1
  [../]
  [./c_strength]
    type = TensorMechanicsHardeningConstant
    value = 100
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0
    shear_modulus = 2.0
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '0 0 1  0 0 -1  1 -1 0'
    eigenstrain_name = ini_stress
  [../]
  [./admissible]
    type = ComputeMultipleInelasticStress
    inelastic_models = mc
    tangent_operator = nonlinear
  [../]
  [./mc]
    type = CappedWeakPlaneStressUpdate
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    tensile_strength = t_strength
    compressive_strength = c_strength
    max_NR_iterations = 20
    tip_smoother = 1
    smoothing_tol = 2
    yield_function_tol = 1E-10
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -snes_type'
    petsc_options_value = 'bcgs bjacobi 1E-15 1E-10 10000 test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/tensor_mechanics/test/tests/jacobian/mc_update13.i

# MC update version, with only Compressive with compressive strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Return to the stress_I = stress_II = stress_III ~1 tip

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./cs]
    type = TensorMechanicsHardeningConstant
    value = 1
  [../]
  [./coh]
    type = TensorMechanicsHardeningConstant
    value = 1E6
  [../]
  [./ang]
    type = TensorMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 1.0E3
    shear_modulus = 1.3E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-2 0 0  0 -1.9 0  0 0 -2.1'
    eigenstrain_name = ini_stress
  [../]
  [./cmc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = ang
    dilation_angle = ang
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = cmc
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/peridynamics/test/tests/plane_stress/conventional_planestress_OSPD.i

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 10
    ny = 10
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1003
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1003
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1001
    value = 0.001
  [../]
[]

[Modules/Peridynamics/Mechanics/Master]
  [./all]
    formulation = ORDINARY_STATE
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e8
    poissons_ratio = 0.3
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialOSPD
    plane_stress = true
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  line_search = none
  start_time = 0
  end_time = 1
  nl_rel_tol = 1e-10
[]

[Outputs]
  file_base = conventional_planestress_OSPD
  exodus = true
[]

modules/tensor_mechanics/test/tests/torque_reaction/torque_reaction_cylinder.i

# This test uses the DisplacementAboutAxis boundary condition to twist the top
# of a cylinder while the bottom face of the cylinder remains fixed.  The
# TorqueReaction postprocessor is used to calculate the applied torque acting
# on the cylinder at the top face.  This test can be extended, with a new mesh,
# to model a crack in the center of the cylinder face under type III loading.

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = cylinder.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[GlobalParams]
  volumetric_locking_correction=true
[]

[AuxVariables]
  [./stress_xx]      # stress aux variables are defined for output; this is a way to get integration point variables to the output file
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
[]

[Functions]
  [./rampConstantAngle]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = 0.1
  [../]
[]

[Kernels]
  [./TensorMechanics]
    save_in = 'saved_x saved_y saved_z'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./bottom_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]
  [./top_x]
    type = DisplacementAboutAxis
    boundary = 2
    function = rampConstantAngle
    angle_units = degrees
    axis_origin = '10. 10. 10.'
    axis_direction = '0 -1.0 1.0'
    component = 0
    variable = disp_x
  [../]
  [./top_y]
    type = DisplacementAboutAxis
    boundary = 2
    function = rampConstantAngle
    angle_units = degrees
    axis_origin = '10. 10. 10.'
    axis_direction = '0 -1.0 1.0'
    component = 1
    variable = disp_y
  [../]
  [./top_z]
    type = DisplacementAboutAxis
    boundary = 2
    function = rampConstantAngle
    angle_units = degrees
    axis_origin = '10. 10. 10.'
    axis_direction = '0 -1.0 1.0'
    component = 2
    variable = disp_z
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 1
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
[]

[Executioner]

  type = Transient
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-12
  nl_rel_tol = 1e-11
  l_tol = 1e-10

  start_time = 0.0
  dt = 0.25

  end_time = 0.5
[]

[Postprocessors]
  [./torque]
    type = TorqueReaction
    boundary = 2
    reaction_force_variables = 'saved_x saved_y saved_z'
    axis_origin = '10. 10. 10.'
    direction_vector = '0 -1.0 1.0'
  [../]
[]

[Outputs]
  file_base = torque_reaction_cylinder_out
  exodus = true
[]

modules/combined/test/tests/beam_eigenstrain_transfer/subapp_err_4.i

# SubApp with 2D model to test multi app vectorpostprocessor to aux var transfer

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 5
  xmin = 0.0
  xmax = 0.5
  ymin = 0.0
  ymax = 0.150080
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./temp]
  [../]
  [./axial_strain]
    order = FIRST
    family = MONOMIAL
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t*(500.0)+300.0
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./all]
        strain = SMALL
        incremental = true
        add_variables = true
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
  [../]
  [./axial_strain]
    type = RankTwoAux
    variable = axial_strain
    rank_two_tensor = total_strain
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 298
    thermal_expansion_coeff = 1.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8
  l_tol = 1e-9

  start_time = 0.0
  end_time = 0.075
  dt = 0.0125
  dtmin = 0.0001
[]

[Outputs]
  csv = true
  exodus = true
[]

[VectorPostprocessors]
  [./axial_str]
    type = LineValueSampler
    start_point = '0.5 0.0 0.0'
    end_point = '0.5 0.1 0.0'
    variable = axial_strain
    num_points = 21
    sort_by = 'id'
  [../]
[]

[Postprocessors]
  [./end_disp]
    type = PointValue
    variable = disp_y
    point = '0.5 0.150080 0.0'
  [../]
[]

modules/tensor_mechanics/test/tests/notched_plastic_block/biaxial_planar.i

# Uses non-smoothed Mohr-Coulomb (via ComputeMultiPlasticityStress and TensorMechanicsPlasticMohrCoulombMulti) to simulate the following problem.
# A cubical block is notched around its equator.
# All of its outer surfaces have roller BCs, but the notched region is free to move as needed
# The block is initialised with a high hydrostatic tensile stress
# Without the notch, the BCs do not allow contraction of the block, and this stress configuration is admissible
# With the notch, however, the interior parts of the block are free to move in order to relieve stress, and this causes plastic failure
# The top surface is then pulled upwards (the bottom is fixed because of the roller BCs)
# This causes more failure
[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 9
    ny = 9
    nz = 9
    xmin = 0
    xmax = 0.1
    ymin = 0
    ymax = 0.1
    zmin = 0
    zmax = 0.1
  []
  [block_to_remove_xmin]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 -0.01 0.045'
    top_right = '0.01 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = generated_mesh
  []
  [block_to_remove_xmax]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '0.09 -0.01 0.045'
    top_right = '0.11 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_xmin
  []
  [block_to_remove_ymin]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 -0.01 0.045'
    top_right = '0.11 0.01 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_xmax
  []
  [block_to_remove_ymax]
    type = SubdomainBoundingBoxGenerator
    bottom_left = '-0.01 0.09 0.045'
    top_right = '0.11 0.11 0.055'
    location = INSIDE
    block_id = 1
    input = block_to_remove_ymin
  []
  [remove_block]
    type = BlockDeletionGenerator
    block_id = 1
    input = block_to_remove_ymax
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    incremental = true
    generate_output = 'max_principal_stress mid_principal_stress min_principal_stress stress_zz'
    eigenstrain_names = ini_stress
  [../]
[]

[Postprocessors]
  [./uz]
    type = PointValue
    point = '0 0 0.1'
    use_displaced_mesh = false
    variable = disp_z
  [../]
  [./s_zz]
    type = ElementAverageValue
    use_displaced_mesh = false
    variable = stress_zz
  [../]
  [./num_res]
    type = NumResidualEvaluations
  [../]
  [./nr_its]
    type = ElementAverageValue
    variable = num_iters
  [../]
  [./max_nr_its]
    type = ElementExtremeValue
    variable = num_iters
  [../]
  [./runtime]
    type = PerfGraphData
    data_type = TOTAL
    section_name = 'Root'
  [../]
[]

[BCs]
  # back=zmin, front=zmax, bottom=ymin, top=ymax, left=xmin, right=xmax
  [./xmin_xzero]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./xmax_xzero]
    type = DirichletBC
    variable = disp_x
    boundary = right
    value = 0.0
  [../]
  [./ymin_yzero]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./ymax_yzero]
    type = DirichletBC
    variable = disp_y
    boundary = top
    value = 0.0
  [../]
  [./zmin_zzero]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = '0'
  [../]
  [./zmax_disp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = '1E-6*max(t,0)'
  [../]
[]

[AuxVariables]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_strain]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./num_iters]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./plastic_strain_aux]
    type = MaterialRankTwoTensorAux
    i = 2
    j = 2
    property = plastic_strain
    variable = plastic_strain
  [../]
  [./num_iters_auxk] # cannot use plastic_NR_iterations directly as this is zero, since no NR iterations are actually used, since we use a custom algorithm to do the return
    type = ParsedAux
    args = plastic_strain
    function = 'if(plastic_strain>0,1,0)'
    variable = num_iters
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = TensorMechanicsHardeningConstant
    value = 5E6
  [../]
  [./mc_phi]
    type = TensorMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = TensorMechanicsHardeningConstant
    value = 10
    convert_to_radians = true
  [../]
  [./mc]
    type = TensorMechanicsPlasticMohrCoulombMulti
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    yield_function_tolerance = 1E-5
    internal_constraint_tolerance = 1E-11
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 16E9
    poissons_ratio = 0.25
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    ep_plastic_tolerance = 1E-11
    plastic_models = mc
    max_NR_iterations = 1000
    debug_fspb = crash
  [../]
  [./strain_from_initial_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '6E6 0 0  0 6E6 0  0 0 6E6'
    eigenstrain_name = ini_stress
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  start_time = -1
  end_time = 10
  dt = 1
  solve_type = NEWTON
  type = Transient

  l_tol = 1E-2
  nl_abs_tol = 1E-5
  nl_rel_tol = 1E-7
  l_max_its = 200
  nl_max_its = 400

  petsc_options_iname = '-pc_type -pc_asm_overlap -sub_pc_type -ksp_type -ksp_gmres_restart'
  petsc_options_value = ' asm      2              lu            gmres     200'
[]


[Outputs]
  file_base = biaxial_planar
  perf_graph = true
  exodus = false
  csv = true
[]

modules/tensor_mechanics/test/tests/rom_stress_update/3d.i

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temperature]
    initial_condition = 900.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'vonmises_stress'
    use_automatic_differentiation = true
  [../]
[]

[BCs]
  [./symmy]
    type = ADDirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = ADDirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = ADDirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./pressure_x]
    type = ADPressure
    variable = disp_x
    component = 0
    boundary = right
    constant = 1.0e5
  [../]
  [./pressure_y]
    type = ADPressure
    variable = disp_y
    component = 1
    boundary = top
    constant = -1.0e5
  [../]
  [./pressure_z]
    type = ADPressure
    variable = disp_z
    component = 2
    boundary = front
    constant = -1.0e5
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 3.30e11
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ADComputeMultipleInelasticStress
    inelastic_models = rom_stress_prediction
  [../]
  [./rom_stress_prediction]
    type = SS316HLAROMANCEStressUpdateTest
    temperature = temperature
    initial_mobile_dislocation_density = 6.0e12
    initial_immobile_dislocation_density = 4.4e11
    outputs = all
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'NEWTON'

  nl_abs_tol = 1e-12
  automatic_scaling = true
  compute_scaling_once = false

  num_steps = 5
[]

[Postprocessors]
  [./effective_strain_avg]
    type = ElementAverageValue
    variable = effective_creep_strain
  [../]
  [./temperature]
    type = ElementAverageValue
    variable = temperature
  [../]
  [./mobile_dislocations]
    type = ElementAverageValue
    variable = mobile_dislocations
  [../]
  [./immobile_disloactions]
    type = ElementAverageValue
    variable = immobile_dislocations
  [../]
[]

[Outputs]
  csv = true
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_3/cyl3_mu_0_2_pen.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl3_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_x
  [../]
  [./disp_x11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_x
  [../]
  [./disp_y2]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_y
  [../]
  [./disp_y11]
    type = NodalVariableValue
    nodeid = 10
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = cyl3_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = cyl3_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x2 disp_y2 disp_x11 disp_y11 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    tangential_tolerance = 1e-3
    friction_coefficient = 0.2
    penalty = 1e+9
  [../]
[]

modules/porous_flow/test/tests/thm_rehbinder/fixed_outer_rz.i

# A version of fixed_outer.i that uses the RZ cylindrical coordinate system
[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 40 # this is the r direction
  ny = 1 # this is the height direction
  xmin = 0.1
  xmax = 1
  bias_x = 1.1
  ymin = 0.0
  ymax = 1.0
[]

[Problem]
  coord_type = RZ
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
  PorousFlowDictator = dictator
  biot_coefficient = 1.0
[]

[Variables]
  [./disp_r]
  [../]
  [./disp_z]
  [../]
  [./porepressure]
  [../]
  [./temperature]
  [../]
[]

[BCs]
  [./plane_strain]
    type = DirichletBC
    variable = disp_z
    value = 0
    boundary = 'top bottom'
  [../]

  [./cavity_temperature]
    type = DirichletBC
    variable = temperature
    value = 1000
    boundary = left
  [../]
  [./cavity_porepressure]
    type = DirichletBC
    variable = porepressure
    value = 1E6
    boundary = left
  [../]
  [./cavity_zero_effective_stress_x]
    type = Pressure
    component = 0
    variable = disp_r
    function = 1E6
    boundary = left
    use_displaced_mesh = false
  [../]

  [./outer_temperature]
    type = DirichletBC
    variable = temperature
    value = 0
    boundary = right
  [../]
  [./outer_pressure]
    type = DirichletBC
    variable = porepressure
    value = 0
    boundary = right
  [../]
  [./fixed_outer_disp]
    type = DirichletBC
    variable = disp_r
    value = 0
    boundary = right
  [../]
[]

[AuxVariables]
  [./stress_rr]
    family = MONOMIAL
    order = CONSTANT
  [../]
  [./stress_pp]
    family = MONOMIAL
    order = CONSTANT
  [../]
[]

[AuxKernels]
  [./stress_rr]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_rr
    index_i = 0
    index_j = 0
  [../]
  [./stress_pp] # hoop stress
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_pp
    index_i = 2
    index_j = 2
  [../]
[]

[Modules]
  [./FluidProperties]
    [./the_simple_fluid]
      type = SimpleFluidProperties
      thermal_expansion = 0.0
      bulk_modulus = 1E12
      viscosity = 1.0E-3
      density0 = 1000.0
      cv = 1000.0
      cp = 1000.0
      porepressure_coefficient = 0.0
    [../]
  [../]
[]

[PorousFlowBasicTHM]
  coupling_type = ThermoHydroMechanical
  multiply_by_density = false
  add_stress_aux = true
  porepressure = porepressure
  temperature = temperature
  thermal_eigenstrain_name = thermal_contribution
  gravity = '0 0 0'
  fp = the_simple_fluid
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1E10
    poissons_ratio = 0.2
  [../]
  [./strain]
    type = ComputeAxisymmetricRZSmallStrain
    eigenstrain_names = thermal_contribution
  [../]
  [./thermal_contribution]
    type = ComputeThermalExpansionEigenstrain
    temperature = temperature
    thermal_expansion_coeff = 1E-6
    eigenstrain_name = thermal_contribution
    stress_free_temperature = 0.0
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./porosity]
    type = PorousFlowPorosityConst # only the initial value of this is ever used
    porosity = 0.1
  [../]
  [./biot_modulus]
    type = PorousFlowConstantBiotModulus
    solid_bulk_compliance = 1E-10
    fluid_bulk_modulus = 1E12
  [../]
  [./permeability]
    type = PorousFlowPermeabilityConst
    permeability = '1E-12 0 0   0 1E-12 0   0 0 1E-12' # note this is ordered: rr, zz, angle-angle
  [../]
  [./thermal_expansion]
    type = PorousFlowConstantThermalExpansionCoefficient
    fluid_coefficient = 1E-6
    drained_coefficient = 1E-6
  [../]
  [./thermal_conductivity]
    type = PorousFlowThermalConductivityIdeal
    dry_thermal_conductivity = '1E6 0 0  0 1E6 0  0 0 1E6' # note this is ordered: rr, zz, angle-angle
  [../]
[]

[VectorPostprocessors]
  [./P]
    type = LineValueSampler
    start_point = '0.1 0 0'
    end_point = '1.0 0 0'
    num_points = 10
    sort_by = x
    variable = porepressure
  [../]
  [./T]
    type = LineValueSampler
    start_point = '0.1 0 0'
    end_point = '1.0 0 0'
    num_points = 10
    sort_by = x
    variable = temperature
  [../]
  [./U]
    type = LineValueSampler
    start_point = '0.1 0 0'
    end_point = '1.0 0 0'
    num_points = 10
    sort_by = x
    variable = disp_r
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -sub_pc_type -snes_rtol'
    petsc_options_value = 'gmres      asm      lu           1E-8'
  [../]
[]

[Executioner]
  type = Steady
  solve_type = Newton
[]

[Outputs]
  file_base = fixed_outer_rz
  execute_on = timestep_end
  csv = true
[]

modules/peridynamics/test/tests/jacobian_check/generalized_planestrain_thermomechanics_OSPD.i


# NOTE: this jacobian test for the coupled thermomechanical model must use displaced mesh, otherwise the difference for the first step is huge

[GlobalParams]
  displacements = 'disp_x disp_y'
  temperature = temp
  scalar_out_of_plane_strain = scalar_strain_zz
  full_jacobian = true
[]

[Mesh]
  type = PeridynamicsMesh
  horizon_number = 3

  [./gmg]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  [../]
  [./gpd]
    type = MeshGeneratorPD
    input = gmg
    retain_fe_mesh = false
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./temp]
    initial_condition = 0.5
  [../]

  [./scalar_strain_zz]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Modules/Peridynamics/Mechanics]
  [./Master]
    [./all]
      formulation = ORDINARY_STATE
    [../]
  [../]
  [./GeneralizedPlaneStrain]
    [./all]
      formulation = ORDINARY_STATE
      out_of_plane_stress_variable = stress_zz
    [../]
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConductionBPD
    variable = temp
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = NodalRankTwoPD
    variable = stress_zz

    poissons_ratio = 0.3
    youngs_modulus = 1e6
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5

    rank_two_tensor = stress
    output_type = component
    index_i = 2
    index_j = 2
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]

  [./force_density]
    type = ComputeSmallStrainConstantHorizonMaterialOSPD
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
  [../]
  [./thermal_mat]
    type = ThermalConstantHorizonMaterialBPD
    thermal_conductivity = 1.0
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_type'
    petsc_options_value = 'bcgs bjacobi test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  end_time = 1
  dt = 1
  num_steps = 1
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_4/cyl4_template2.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl4_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 1000
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x9 disp_y9 disp_x16 disp_y16 stress_yy stress_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

modules/combined/test/tests/normalized_penalty/normalized_penalty_kin_Q8.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = normalized_penalty_Q8.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[AuxVariables]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
[]

[Functions]
  [./left_x]
    type = PiecewiseLinear
    x = '0 1 2'
    y = '0 0.02 0'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx'
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  []
[]

[Contact]
  [./m3_s2]
    master = 3
    slave = 2
    penalty = 1e10
    normalize_penalty = true
    tangential_tolerance = 1e-3
    system = Constraint
  [../]
[]

[BCs]
  [./left_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 1
    function = left_x
  [../]

  [./y]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2 3 4'
    value = 0.0
  [../]

  [./right]
    type = DirichletBC
    variable = disp_x
    boundary = '3 4'
    value = 0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2 3 4 1000'
    youngs_modulus = 3e8
    poissons_ratio = 0.0
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2 3 4 1000'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'lu       101'

  line_search = 'none'

  nl_rel_tol = 1e-12
  nl_abs_tol = 5e-8

  l_max_its = 100
  nl_max_its = 20
  dt = 0.5
  num_steps = 4
[]

[Outputs]
  exodus = true
[]

modules/xfem/test/tests/solid_mechanics_basic/elliptical_crack.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[Mesh]
  file = quarter_sym.e
[]

[UserObjects]
  [./ellip_cut_uo]
    type = EllipseCutUserObject
    cut_data = '-0.5 -0.5 0
                -0.5 -0.1 0
                 0.1 -0.5 0'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[Functions]
  [./top_trac_z]
    type = ConstantFunction
    value = 10
  [../]
[]


[BCs]
  [./top_z]
    type = FunctionNeumannBC
    boundary = 2
    variable = disp_z
    function = top_trac_z
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_z]
    type = DirichletBC
    boundary = 1
    variable = disp_z
    value = 0.0
  [../]
  [./sym_y]
    type = DirichletBC
    boundary = 3
    variable = disp_y
    value = 0.0
  [../]
  [./sym_x]
    type = DirichletBC
    boundary = 4
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  file_base = elliptical_crack_out
  exodus = true
  execute_on = timestep_end
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/combined/test/tests/internal_volume/hex20.i

#
# Internal Volume Test
#
# This test is designed to compute the internal volume of a space considering
#   an embedded volume inside.
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total volume
#   is 7.
#
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = meshes/hex20.e
[]

[Functions]
  [./step]
    type = PiecewiseLinear
    x = '0. 1. 2. 3.'
    y = '0. 0. 1e-2 0.'
    scale_factor = 0.5
  [../]
[]

[Variables]
  [./disp_x]
    order = SECOND
    family = LAGRANGE
  [../]

  [./disp_y]
    order = SECOND
    family = LAGRANGE
  [../]

  [./disp_z]
    order = SECOND
    family = LAGRANGE
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    incremental = true
    strain = FINITE
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 100
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]

  [./prescribed_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 100
    function = step
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = PJFNK

  start_time = 0.0
  dt = 1.0
  end_time = 3.0

  [./Quadrature]
    order = THIRD
  [../]
[]

[Postprocessors]
  [./internalVolume]
    type = InternalVolume
    boundary = 100
    execute_on = 'initial timestep_end'
  [../]

  [./dispZ]
    type = ElementAverageValue
    block = '1 2'
    variable = disp_z
  [../]
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/nodal_area/nodal_area_Hex27.i

[Mesh]
  file = nodal_area_Hex27.e
[]

[GlobalParams]
  order = SECOND
  displacements = 'displ_x displ_y displ_z'
[]

[Functions]
  [./disp]
    type = PiecewiseLinear
    x = '0     1'
    y = '0  20e-6'
  [../]
[]

[Variables]
  [./displ_x]
  [../]
  [./displ_y]
  [../]
  [./displ_z]
  [../]
[]

[AuxVariables]
  [./react_x]
  [../]
  [./react_y]
  [../]
  [./react_z]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    incremental = true
    save_in = 'react_x react_y react_z'
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx'
  [../]
[]

[BCs]
  [./move_right]
    type = FunctionDirichletBC
    boundary = '1'
    variable = displ_x
    function = disp
  [../]

  [./fixed_x]
    type = DirichletBC
    boundary = '3 4'
    variable = displ_x
    value = 0
  [../]

  [./fixed_y]
    type = DirichletBC
    boundary = 10
    variable = displ_y
    value = 0
  [../]

  [./fixed_z]
    type = DirichletBC
    boundary = 11
    variable = displ_z
    value = 0
  [../]
[]

[Contact]
  [./dummy_name]
    master = 3
    slave = 2
    penalty = 1e8
    tangential_tolerance = 1e-4
    system = Constraint
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = '1 2'
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  #petsc_options_iname = '-snes_type -snes_ls -snes_linesearch_type -ksp_gmres_restart -pc_type'
  #petsc_options_value = 'ls         basic    basic                    201                lu'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6

  l_tol = 1e-4
  l_max_its = 40

  start_time = 0.0
  dt = 1.0
  end_time = 1.0
  num_steps = 100

  [./Quadrature]
    order = THIRD
  [../]
[]

[Postprocessors]
  [./react_x]
    type = NodalSum
    variable = react_x
    boundary = 1
  [../]
  [./total_area]
    type = NodalSum
    variable = nodal_area_dummy_name
    boundary = 2
  [../]
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/mortar_tm/2drz/frictionless_first/finite.i

E_block = 1e7
E_plank = 1e7
elem = QUAD4
order = FIRST
name = 'finite'

[Problem]
  coord_type = RZ
[]

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 0.6
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.61
    xmax = 1.21
    ymin = 9.2
    ymax = 10.0
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.9  9.2  0
              1.21 9.5  0
              0.9  10.0 0
              0.61 9.5  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./block]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'block'
  [../]
  [./plank]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank'
    eigenstrain_names = 'swell'
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = block_right
    value = 0
  [../]
  [./right_y]
    type = FunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
  [./swell]
    type = ComputeEigenstrain
    block = 'plank'
    eigenstrain_name = swell
    eigen_base = '1 0 0 0 0 0 0 0 0'
    prefactor = swell_mat
  [../]
  [./swell_mat]
    type = GenericFunctionMaterial
    prop_names = 'swell_mat'
    prop_values = '7e-2*(1-cos(4*t))'
    block = 'plank'
  [../]
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 10
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/stickyBC/push_up.i

# Testing StickyBC
#
# Push the bottom of an element upward until the top hits an (invisible) obstruction.
# 10 timesteps are used.  In each timestep disp_y is increased by 0.1.  The
# StickyBC has a max_value of 0.49, so at timestep 5 this bound will be violated
# and the top boundary will be fixed forever after.
#
# This test also illustrates that StickyBC is only ever meant to be used in
# special situations:
# - if, after the simulation ends, the bottom is moved downward again, the StickyBC
#   will keep the top fixed.  Ie, the StickyBC is truly "sticky".
# - setting max_value = 0.5 in this test illustrates the "approximate" nature
#   of StickyBC, in that some nodes will be fixed at disp_y=0.5, while others
#   will be fixed at disp_y=0.6, due to the timestepping and roundoff errors
#   in MOOSE's solution.
[Mesh]
  type = GeneratedMesh
  dim = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
  [../]
[]

[BCs]
  [./obstruction]
    type = StickyBC
    variable = disp_y
    boundary = top
    max_value = 0.49
  [../]
  [./bottom]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = bottom
    function = t
  [../]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./front]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0
  [../]
[]

[Materials]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1.0
    poissons_ratio = 0.2
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Linear
  dt = 0.1
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/contact_verification/patch_tests/cyl_2/cyl2_mu_0_2_pen.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = cyl2_mesh.e
[]

[Problem]
  type = FEProblem
  coord_type = RZ
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[] # AuxKernels

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeAxisymmetricRZIncrementalStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  file_base = cyl2_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = cyl2_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x5 disp_y5 disp_x9 disp_y9 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    tangential_tolerance = 1e-3
    friction_coefficient = 0.2
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/jacobian/tensile_update7.i

# Tensile, update version, with strength = 1MPa and smoothing_tol = 0.1E5
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
# Units in this file are MPa (not Pa)
#
# Start from non-diagonal stress state with softening.
# Returns to close to the edge of tensile yield

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./ts]
    type = TensorMechanicsHardeningCubic
    value_0 = 1
    value_residual = 0.5
    internal_limit = 2E-2
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    lambda = 0.5E3
    shear_modulus = 1.0E3
  [../]
  [./strain]
    type = ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-1 0.1 0.2  0.1 15 -0.3  0.2 -0.3 14'
    eigenstrain_name = ini_stress
  [../]
  [./tensile]
    type = TensileStressUpdate
    tensile_strength = ts
    smoothing_tol = 0.1
    yield_function_tol = 1.0E-12
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = tensile
    perform_finite_strain_rotations = false
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-snes_type'
    petsc_options_value = 'test'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
[]

modules/combined/test/tests/power_law_creep/power_law_creep_smallstrain.i

# 1x1x1 unit cube with uniform pressure on top face for the case of small strain.
#  This test does not have a solid mechanics analog because there is not an equvialent
#  small strain with rotations strain calculator material in solid mechanics

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
[]

[Variables]
  [./temp]
    order = FIRST
    family = LAGRANGE
    initial_condition = 1000.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    incremental = true
    add_variables = true
    generate_output = 'stress_yy creep_strain_xx creep_strain_yy creep_strain_zz elastic_strain_yy'
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1'
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
  [./heat_ie]
    type = HeatConductionTimeDerivative
    variable = temp
  [../]
[]

[BCs]
  [./u_top_pull]
    type = Pressure
    variable = disp_y
    component = 1
    boundary = top
    factor = -10.0e6
    function = top_pull
  [../]
  [./u_bottom_fix]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./u_yz_fix]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./u_xy_fix]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./temp_fix]
    type = DirichletBC
    variable = temp
    boundary = 'bottom top'
    value = 1000.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2e11
    poissons_ratio = 0.3
  [../]
  [./radial_return_stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'power_law_creep'
    tangent_operator = elastic
  [../]
  [./power_law_creep]
    type = PowerLawCreepStressUpdate
    coefficient = 1.0e-15
    n_exponent = 4
    activation_energy = 3.0e5
    temperature = temp
  [../]

  [./thermal]
    type = HeatConductionMaterial
    specific_heat = 1.0
    thermal_conductivity = 100.
  [../]
  [./density]
    type = Density
    density = 1.0
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 20
  nl_max_its = 20
  nl_rel_tol = 1e-6
  nl_abs_tol = 1e-6
  l_tol = 1e-5
  start_time = 0.0
  end_time = 1.0
  num_steps = 10
  dt = 0.1
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/2D_different_planes/gps_jacobian_testing_xz.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = square_xz_plane.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_z]
  [../]
  [./scalar_strain_yy]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./generalized_plane_strain]
    block = 1
    strain = SMALL
    scalar_out_of_plane_strain = scalar_strain_yy
    out_of_plane_direction = y
    planar_formulation = GENERALIZED_PLANE_STRAIN
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.0
    youngs_modulus = 1
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  petsc_options_iname = '-ksp_type -pc_type -snes_type'
  petsc_options_value = 'bcgs bjacobi test'

  end_time = 1.0
[]

modules/combined/examples/xfem/xfem_mechanics_prescribed_growth.i

# This is a demonstration of a simple mechanics simulation using XFEM
# to represent a single crack that is prescribed to propagate along
# a line over time.

[GlobalParams]
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 11
  ny = 11
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[XFEM]
  geometric_cut_userobjects = 'line_seg_cut_uo'
  qrule = volfrac
  output_cut_plane = true
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '1.0  0.5  0.1  0.5'
    time_start_cut = 0.0
    time_end_cut = 8.0
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    planar_formulation = plane_strain
    add_variables = true
  [../]
[]

[Functions]
  [./pull]
    type = PiecewiseLinear
    x='0  50'
    y='0  0.02'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  [../]
  [./topx]
    type = DirichletBC
    boundary = top
    variable = disp_x
    value = 0.0
  [../]
  [./topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = pull
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./_elastic_strain]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-14
  nl_abs_tol = 1e-9

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 10.0

  max_xfem_update = 5
[]

[Outputs]
  exodus = true
  execute_on = timestep_end
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/porous_flow/test/tests/actions/basicthm_thm.i

# PorousFlowBasicTHM action with coupling_type = ThermoHydroMechanicalGenerator

[Mesh]
  [gen]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 10
    ny = 3
    xmax = 10
    ymax = 3
  []
  [./aquifer]
    input = gen
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 1 0'
    top_right = '10 2 0'
  [../]
  [./injection_area]
    type = SideSetsAroundSubdomainGenerator
    block = 1
    new_boundary = 'injection_area'
    normal = '-1 0 0'
    input = 'aquifer'
  [../]
  [./outflow_area]
    type = SideSetsAroundSubdomainGenerator
    block = 1
    new_boundary = 'outflow_area'
    normal = '1 0 0'
    input = 'injection_area'
  [../]
  [./rename]
    type = RenameBlockGenerator
    old_block_id = '0 1'
    new_block_name = 'caprock aquifer'
    input = 'outflow_area'
  [../]
[]

[GlobalParams]
  PorousFlowDictator = dictator
  displacements = 'disp_x disp_y'
  biot_coefficient = 1.0
[]

[Variables]
  [./porepressure]
    initial_condition = 1e6
  [../]
  [./temperature]
    initial_condition = 293
    scaling = 1e-6
  [../]
  [./disp_x]
    scaling = 1e-6
  [../]
  [./disp_y]
    scaling = 1e-6
  [../]
[]

[PorousFlowBasicTHM]
  porepressure = porepressure
  temperature = temperature
  coupling_type = ThermoHydroMechanical
  gravity = '0 0 0'
  fp = simple_fluid
  thermal_eigenstrain_name = thermal_contribution
  use_displaced_mesh = false
  add_stress_aux = false
[]

[BCs]
  [./constant_injection_porepressure]
    type = DirichletBC
    variable = porepressure
    value = 1.5e6
    boundary = injection_area
  [../]
  [./constant_injection_temperature]
    type = DirichletBC
    variable = temperature
    value = 313
    boundary = injection_area
  [../]
  [./constant_outflow_porepressure]
    type = PorousFlowPiecewiseLinearSink
    variable = porepressure
    boundary = outflow_area
    pt_vals = '0 1e9'
    multipliers = '0 1e9'
    flux_function = 1e-6
    PT_shift = 1e6
  [../]
  [./constant_outflow_temperature]
    type = DirichletBC
    variable = temperature
    value = 293
    boundary = outflow_area
  [../]
  [./top_bottom]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = 'top bottom'
  [../]
  [./right]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = right
  [../]
[]

[Modules]
  [./FluidProperties]
    [./simple_fluid]
      type = SimpleFluidProperties
    [../]
  [../]
[]

[Materials]
  [./porosity]
    type = PorousFlowPorosity
    porosity_zero = 0.1
  [../]
  [./biot_modulus]
    type = PorousFlowConstantBiotModulus
    biot_coefficient = 0.8
    solid_bulk_compliance = 2e-7
    fluid_bulk_modulus = 1e7
  [../]
  [./permeability_aquifer]
    type = PorousFlowPermeabilityConst
    block = aquifer
    permeability = '1e-13 0 0   0 1e-13 0   0 0 1e-13'
  [../]
  [./permeability_caprock]
    type = PorousFlowPermeabilityConst
    block = caprock
    permeability = '1e-15 0 0   0 1e-15 0   0 0 1e-15'
  [../]
  [./thermal_expansion]
    type = PorousFlowConstantThermalExpansionCoefficient
    drained_coefficient = 0.003
    fluid_coefficient = 0.0002
  [../]
  [./rock_internal_energy]
    type = PorousFlowMatrixInternalEnergy
    density = 2500.0
    specific_heat_capacity = 1200.0
  [../]
  [./thermal_conductivity]
    type = PorousFlowThermalConductivityIdeal
    dry_thermal_conductivity = '10 0 0  0 10 0  0 0 10'
    block = 'caprock aquifer'
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 5e9
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeSmallStrain
    eigenstrain_names = thermal_contribution
  [../]
  [./thermal_contribution]
    type = ComputeThermalExpansionEigenstrain
    temperature = temperature
    thermal_expansion_coeff = 0.001
    eigenstrain_name = thermal_contribution
    stress_free_temperature = 293
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./basic]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  end_time = 1e4
  dt = 1e3
  nl_abs_tol = 1e-12
  nl_rel_tol = 1E-10
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/j_integral_vtest/j_int_surfbreak_ellip_crack_sym_mm_cfp_cm.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = ellip_crack_4sym_norad_mm.e
  partitioner = centroid
  centroid_partitioner_direction = z
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./resid_z]
  [../]
[]

[Functions]
  [./rampConstantUp]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 0.1'
    scale_factor = -689.5 #MPa
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  crack_direction_method = CrackMouth
  crack_mouth_boundary = 11
  crack_end_direction_method = CrackDirectionVector
  crack_direction_vector_end_1 = '0.0 1.0 0.0'
  crack_direction_vector_end_2 = '1.0 0.0 0.0'
  crack_front_points = '0             254           0
                        127.308       248.843       0
                        249.446       233.581       0
                        361.455       208.835       0
                        508.003       152.398       0
                        602.415       80.3208       0
                        635           0             0'
  radius_inner = '12.5 25.0 37.5'
  radius_outer = '25.0 37.5 50.0'
  intersecting_boundary = '1 2'
  symmetry_plane = 2
  position_type = angle
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 12
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 5
      function = rampConstantUp
    [../]
  [../]
[] # BCs

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 206800
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Executioner]

   type = Transient
  # Two sets of linesearch options are for petsc 3.1 and 3.3 respectively
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

#  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

   l_max_its = 50
   nl_max_its = 20
   nl_abs_tol = 1e-5
   nl_rel_tol = 1e-11
   l_tol = 1e-2

   start_time = 0.0
   dt = 1

   end_time = 1
   num_steps = 1
[]

[Postprocessors]
  [./_dt]
    type = TimestepSize
  [../]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./lin_its]
    type = NumLinearIterations
  [../]
  [./react_z]
    type = NodalSum
    variable = resid_z
    boundary = 5
  [../]
[]


[Outputs]
  execute_on = 'timestep_end'
  file_base = j_int_surfbreak_ellip_crack_sym_mm_cfp_cm_out
  exodus = true
  csv = true
[]

modules/tensor_mechanics/test/tests/check_error/bulk_modulus.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = cube.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[BCs]
  [./2_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./2_y]
    type = DirichletBC
    variable = disp_y
    boundary = 2
    value = 0.0
  [../]
  [./2_z]
    type = DirichletBC
    variable = disp_z
    boundary = 2
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = -1e6
    poissons_ratio = 0.0
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/reference_residual/group_variables.i

[Mesh]
  file = 2squares.e
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  group_variables = 'disp_x disp_y;
                     scalar_strain_zz1 scalar_strain_zz2'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]

  [./scalar_strain_zz1]
    order = FIRST
    family = SCALAR
  [../]
  [./scalar_strain_zz2]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./aux_strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_scalar_strain_zz1]
    order = FIRST
    family = SCALAR
  [../]
  [./saved_scalar_strain_zz2]
    order = FIRST
    family = SCALAR
  [../]
[]

[Postprocessors]
  [./react_z1]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    block = 1
  [../]
  [./react_z2]
    type = MaterialTensorIntegral
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    block = 2
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./GeneralizedPlaneStrain]
      [./gps1]
        use_displaced_mesh = true
        displacements = 'disp_x disp_y'
        scalar_out_of_plane_strain = scalar_strain_zz1
        block = '1'
      [../]
      [./gps2]
        use_displaced_mesh = true
        displacements = 'disp_x disp_y'
        scalar_out_of_plane_strain = scalar_strain_zz2
        block = '2'
      [../]
    [../]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = false
    displacements = 'disp_x disp_y'
    temperature = temp
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
    block = '1 2'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    use_displaced_mesh = false
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]

  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_xy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xy
    index_i = 0
    index_j = 1
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./aux_strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = aux_strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[AuxScalarKernels]
  [./saved_scalar_strain_zz1_ref_resid]
    type = GeneralizedPlaneStrainReferenceResidual
    variable = saved_scalar_strain_zz1
    generalized_plane_strain = gps1_GeneralizedPlaneStrainUserObject
  [../]
  [./saved_scalar_strain_zz2_ref_resid]
    type = GeneralizedPlaneStrainReferenceResidual
    variable = saved_scalar_strain_zz2
    generalized_plane_strain = gps2_GeneralizedPlaneStrainUserObject
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-x)*t'
  [../]
[]

[BCs]
  [./bottom1x]
    type = DirichletBC
    boundary = 1
    variable = disp_x
    value = 0.0
  [../]
  [./bottom1y]
    type = DirichletBC
    boundary = 1
    variable = disp_y
    value = 0.0
  [../]
  [./bottom2x]
    type = DirichletBC
    boundary = 2
    variable = disp_x
    value = 0.0
  [../]
  [./bottom2y]
    type = DirichletBC
    boundary = 2
    variable = disp_y
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e6
    block = '1 2'
  [../]
  [./strain1]
    type = ComputePlaneSmallStrain
    displacements = 'disp_x disp_y'
    scalar_out_of_plane_strain = scalar_strain_zz1
    block = 1
    eigenstrain_names = eigenstrain
  [../]
  [./strain2]
    type = ComputePlaneSmallStrain
    displacements = 'disp_x disp_y'
    scalar_out_of_plane_strain = scalar_strain_zz2
    block = 2
    eigenstrain_names = eigenstrain
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    block = '1 2'
    eigenstrain_name = eigenstrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
    block = '1 2'
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-10

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
  num_steps = 5000
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/domain_integral_thermal/j_integral_2d.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack2d.e
[]

[AuxVariables]
  [./SED]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./temp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = 10.0*(2*x/504)
  [../]
[]

[DomainIntegral]
  integrals = JIntegral
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  2d = true
  axis_2d = 2
  radius_inner = '60.0 80.0 100.0 120.0'
  radius_outer = '80.0 100.0 120.0 140.0'
  temperature = temp
  incremental = true
  eigenstrain_names = thermal_expansion
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
    planar_formulation = PLANE_STRAIN
    eigenstrain_names = thermal_expansion
  [../]
[]

[AuxKernels]
  [./SED]
    type = MaterialRealAux
    variable = SED
    property = strain_energy_density
    execute_on = timestep_end
  [../]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
    block = 1
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]

  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 400
    value = 0.0
  [../]

  [./no_x1]
    type = DirichletBC
    variable = disp_x
    boundary = 900
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 0.0
    thermal_expansion_coeff = 1.35e-5
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart -sub_ksp_type -sub_pc_type -pc_asm_overlap'
  petsc_options_value = 'asm         31   preonly   lu      1'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 40

  nl_rel_step_tol= 1e-10
  nl_rel_tol = 1e-10

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = j_integral_2d_out
  exodus = true
[]

[Preconditioning]
  [./smp]
    type = SMP
    pc_side = left
    ksp_norm = preconditioned
    full = true
  [../]
[]

modules/tensor_mechanics/test/tests/ad_linear_elasticity/extra_stresses.i

# This input file is designed to test adding extra stress to ADComputeLinearElasticStress

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 10
  xmax = 50
  ymax = 50
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Modules/TensorMechanics/Master/All]
  strain = SMALL
  add_variables = true
  generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx hydrostatic_stress vonmises_stress'
  use_automatic_differentiation = true
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0
  [../]
  [./stress]
    type = ADComputeLinearElasticStress
    extra_stress_names = 'stress_one stress_two'
  [../]
  [./stress_one]
    type = GenericConstantRankTwoTensor
    tensor_name = stress_one
    tensor_values = '0 1e3 1e3 1e3 0 1e3 1e3 1e3 0'
  [../]
  [./stress_two]
    type = GenericConstantRankTwoTensor
    tensor_name = stress_two
    tensor_values = '1e3 0 0 0 1e3 0 0 0 1e3'
  [../]
[]

[BCs]
  [./disp_x_BC]
    type = ADDirichletBC
    variable = disp_x
    boundary = 'bottom top'
    value = 0.5
  [../]
  [./disp_x_BC2]
    type = ADDirichletBC
    variable = disp_x
    boundary = 'left right'
    value = 0.01
  [../]
  [./disp_y_BC]
    type = ADDirichletBC
    variable = disp_y
    boundary = 'bottom top'
    value = 0.8
  [../]
  [./disp_y_BC2]
    type = ADDirichletBC
    variable = disp_y
    boundary = 'left right'
    value = 0.02
  [../]
[]

[Executioner]
  type = Steady
  solve_type = 'NEWTON'
[]

[Postprocessors]
  [./hydrostatic]
    type = ElementAverageValue
    variable = hydrostatic_stress
  [../]
  [./von_mises]
    type = ElementAverageValue
    variable = vonmises_stress
  [../]
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/1D_axisymmetric/axisymm_plane_strain_incremental.i

#
# This test checks elastic stress calculations with mechanical and thermal
# strain using incremental small strain formulation. Young's modulus is 3600, and Poisson's ratio is 0.2.
# The axisymmetric, plane strain 1D mesh is pulled with 1e-6 strain.  Thus,
# the strain is [1e-6, 0, 1e-6] (xx, yy, zz).  This gives stress of
# [5e-3, 2e-3, 5e-3].  After a temperature increase of 100 with alpha of
# 1e-8, the stress becomes [-1e-3, -4e-3, -1e-3].
#

[GlobalParams]
  displacements = disp_x
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = line.e
[]

[Variables]
  [./disp_x]
  [../]
[]

[AuxVariables]
  [./temp]
    initial_condition = 580.0
  [../]
[]

[Functions]
  [./temp]
    type = PiecewiseLinear
    x = '0   1   2'
    y = '580 580 680'
  [../]
  [./disp_x]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 2e-6'
  [../]
[]

[Modules]
  [./TensorMechanics]
    [./Master]
      [./ps]
        planar_formulation = PLANE_STRAIN
        strain = SMALL
        incremental = true
        generate_output = 'strain_xx strain_zz stress_xx stress_yy stress_zz'
        eigenstrain_names = eigenstrain
      [../]
    [../]
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    function = temp
    execute_on = 'timestep_begin'
  [../]
[]

[BCs]
  [./no_x]
    type = DirichletBC
    boundary = 1
    value = 0
    variable = disp_x
  [../]
  [./disp_x]
    type = FunctionDirichletBC
    boundary = 2
    function = disp_x
    variable = disp_x
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 3600
    poissons_ratio = 0.2
  [../]

  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 1e-8
    temperature = temp
    stress_free_temperature = 580
    eigenstrain_name = eigenstrain
  [../]

  [./stress]
    type = ComputeStrainIncrementBasedStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'
  line_search = 'none'

  l_max_its = 50
  l_tol = 1e-6
  nl_max_its = 15
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-10
  start_time = 0
  end_time = 2
  num_steps = 2
[]

[Outputs]
  exodus = true
  console = true
[]

modules/tensor_mechanics/test/tests/2D_different_planes/gps_yz.i

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = square_yz_plane.e
[]

[Variables]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./scalar_strain_xx]
    order = FIRST
    family = SCALAR
  [../]
[]

[AuxVariables]
  [./temp]
  [../]
  [./disp_x]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./generalized_plane_strain]
    block = 1
    strain = SMALL
    scalar_out_of_plane_strain = scalar_strain_xx
    out_of_plane_direction = x
    planar_formulation = GENERALIZED_PLANE_STRAIN
    eigenstrain_names = 'eigenstrain'
    generate_output = 'stress_xx stress_yz stress_yy stress_zz strain_xx strain_yz strain_yy strain_zz'
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = tempfunc
  [../]
[]

[Functions]
  [./tempfunc]
    type = ParsedFunction
    value = '(1-y)*t'
  [../]
[]

[BCs]
  [./bottomx]
    type = DirichletBC
    boundary = 4
    variable = disp_y
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    boundary = 4
    variable = disp_z
    value = 0.0
  [../]
[]

[Materials]
  [./elastic_stress]
    type = ComputeLinearElasticStress
    block = 1
  [../]
  [./thermal_strain]
    type = ComputeThermalExpansionEigenstrain
    temperature = temp
    thermal_expansion_coeff = 0.02
    stress_free_temperature = 0.5
    eigenstrain_name = eigenstrain
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    block = 1
    poissons_ratio = 0.3
    youngs_modulus = 1e6
  [../]
[]

[Postprocessors]
  [./react_x]
    type = MaterialTensorIntegral
    use_displaced_mesh = false
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK
  line_search = none

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-10

# controls for nonlinear iterations
  nl_max_its = 10
  nl_rel_tol = 1e-12

# time control
  start_time = 0.0
  dt = 1.0
  dtmin = 1.0
  end_time = 2.0
[]

[Outputs]
  file_base = gps_yz_small_out
  exodus = true
[]

modules/combined/test/tests/axisymmetric_2d3d_solution_function/2d.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  disp_x = disp_x
  disp_y = disp_y
  displacements = 'disp_x disp_y'
[]

[Problem]
  coord_type = RZ
[]

[Mesh]
  file = 2d.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./temp]
    initial_condition = 400
  [../]
[]

[AuxVariables]
  [./hoop_stress]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./temp_inner_func]
    type = PiecewiseLinear
    xy_data = '0 400
               1 350'
  [../]
  [./temp_outer_func]
    type = PiecewiseLinear
    xy_data = '0 400
               1 400'
  [../]
  [./press_func]
    type = PiecewiseLinear
    xy_data = '0 15
               1 15'
  [../]
[]

[Kernels]
  [./heat]
    type = HeatConduction
    variable = temp
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    volumetric_locking_correction = true
    add_variables  = true
    incremental = true
    strain = FINITE
    eigenstrain_names = thermal_expansion
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress'
  [../]
[]

[AuxKernels]
  [./hoop_stress]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = hoop_stress
    scalar_type = HoopStress
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = '1'
    value = 0.0
  [../]

  [./Pressure]
    [./internal_pressure]
      boundary = '4'
      factor = 1.e6
      function = press_func
    [../]
  [../]

  [./t_in]
    type = FunctionDirichletBC
    variable = temp
    boundary = '4'
    function = temp_inner_func
  [../]

  [./t_out]
    type = FunctionDirichletBC
    variable = temp
    boundary = '2'
    function = temp_outer_func
  [../]
[]

[Constraints]
  [./disp_y]
    type = EqualValueBoundaryConstraint
    variable = disp_y
    master = '65'
    slave = '3'
    penalty = 1e18
  [../]
[]

[Materials]
  [./thermal1]
    type = HeatConductionMaterial
    block = '1'
    thermal_conductivity = 25.0
    specific_heat = 490.0
    temp = temp
  [../]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 193.05e9
    poissons_ratio = 0.3
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

  [./thermal_expansion]
    type = ComputeThermalExpansionEigenstrain
    thermal_expansion_coeff = 13e-6
    stress_free_temperature = 295.00
    temperature = temp
    eigenstrain_name = thermal_expansion
  [../]

  [./density]
    type = Density
    block = '1'
    density = 8000.0
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-ksp_snes_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = ' 201                hypre    boomeramg      4'
  line_search = 'none'
  l_max_its = 25
  nl_max_its = 20
  nl_rel_tol = 1e-9
  l_tol = 1e-2

  start_time = 0.0
  dt = 1
  end_time = 1
  dtmin = 1
[]

[Outputs]
  file_base = 2d_out
  exodus = true
  [./console]
    type = Console
    max_rows = 25
  [../]
[]

modules/tensor_mechanics/test/tests/smeared_cracking/cracking_function.i

#
# Simple pull test for cracking. This tests the option to prescribe the
# cracking strength using an AuxVariable. In this case, an elemental
# AuxVariable is used, and a function is used to prescribe its value.
# One of the elements is weaker than the others, so the crack localizes
# in that element.
#
[Mesh]
   file = plate.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./cracking_stress_fn]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./crack_flags2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./displ]
    type = PiecewiseLinear
    x = '0 0.1 0.2 0.3 0.4'
    y = '0 0.001 0 -0.001 0'
  [../]
  [./fstress]
    type = ParsedFunction
    value = 'if(x > 0.667, 1.1e6, 1.2e6)'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    generate_output = 'stress_xx stress_yy stress_zz stress_xy stress_yz stress_zx strain_xx strain_yy strain_xy strain_yz'
  [../]
[]

[AuxKernels]
  [./cracking_stress_fn]
    type = FunctionAux
    variable = cracking_stress_fn
    function = fstress
    execute_on = initial
  [../]
  [./crack_flags2]
    type = MaterialRealVectorValueAux
    property = crack_flags
    variable = crack_flags2
   component = 2
  [../]
[]

[BCs]
  [./pull]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '3 4'
    function = displ
  [../]

  [./pin_x]
    type = DirichletBC
    variable = disp_x
    boundary =  '1 2'
    value = 0
  [../]
  [./pin_y]
    type = DirichletBC
    variable = disp_y
    boundary = '1 4'
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 200.0e7
    poissons_ratio = 0.0
  [../]
  [./elastic_stress]
    type = ComputeSmearedCrackingStress
    cracking_stress = cracking_stress_fn
    softening_models = abrupt_softening
  [../]
  [./abrupt_softening]
    type = AbruptSoftening
    residual_stress = 0.0
  [../]
[]

[Postprocessors]
  [./elem_stress_xx]
    type = ElementalVariableValue
    variable = stress_xx
    elementid = 2
  [../]
  [./elem_strain_xx]
    type = ElementalVariableValue
    variable = strain_xx
    elementid = 2
  [../]
  [./elem_crack_flags_x]
    type = ElementalVariableValue
    variable = crack_flags2
    elementid = 2
  [../]
[]

[Executioner]
  type = Transient

  solve_type = PJFNK

  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101               '

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-6
  l_tol = 1e-5
  start_time = 0.0
  end_time = 0.2
  dt = 0.0025
[]

[Outputs]
  exodus = true
  csv = true
[]

modules/combined/test/tests/glued_contact_constraint/glued_contact_constraint.i

[Mesh]
  type = FileMesh
  file = simplest_contact.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[AuxVariables]
  [./penetration]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    planar_formulation = PLANE_STRAIN
    strain = SMALL
    add_variables = true
  [../]
[]

[AuxKernels]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 2
    paired_boundary = 3
  [../]
[]

[Constraints]
  [./contact_x]
    type = GluedContactConstraint
    variable = disp_x
    master_variable = disp_x
    component = 0
    slave = 2
    master = 3
    penalty = 1e6
    nodal_area = penetration
    boundary = 2
  [../]
  [./contact_y]
    type = GluedContactConstraint
    variable = disp_y
    master_variable = disp_y
    component = 1
    slave = 2
    master = 3
    penalty = 1e6
    nodal_area = penetration
    boundary = 3
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./right_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = -0.0001
  [../]
  [./right_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient
  solve_type = PJFNK
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre    boomeramg      101'
  line_search = none
  nl_abs_tol = 1e-8
  l_max_its = 100
  nl_max_its = 10
  dt = 1.0
  num_steps = 1
[]

[Outputs]
  file_base = out
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
[]

modules/tensor_mechanics/test/tests/ad_action/two_block_new.i

[Mesh]
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 4
    ny = 4
  []
  [block1]
    type = SubdomainBoundingBoxGenerator
    block_id = 1
    bottom_left = '0 0 0'
    top_right = '0.5 1 0'
    input = generated_mesh
  []
  [block2]
    type = SubdomainBoundingBoxGenerator
    block_id = 2
    bottom_left = '0.5 0 0'
    top_right = '1 1 0'
    input = block1
  []
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Modules/TensorMechanics/Master]
  # parameters that apply to all subblocks are specified at this level. They
  # can be overwritten in the subblocks.
  add_variables = true
  strain = FINITE
  generate_output = 'stress_xx'

  [./block1]
    # the `block` parameter is only valid insde a subblock.
    block = 1
    use_automatic_differentiation = true
  [../]
  [./block2]
    block = 2
    # the `additional_generate_output` parameter is also only valid inside a
    # subblock. Values specified here are appended to the `generate_output`
    # parameter values.
    additional_generate_output = 'strain_yy'
    use_automatic_differentiation = true
  [../]
[]

[AuxVariables]
  [./stress_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_theta]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_theta]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_theta
    execute_on = timestep_end
  [../]
  [./strain_theta]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 2
    index_j = 2
    variable = strain_theta
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.345
  [../]
  [./_elastic_stress1]
    type = ADComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./_elastic_stress2]
    type = ADComputeFiniteStrainElasticStress
    block = 2
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    boundary = 'left'
    variable = disp_x
    value = 0.0
  [../]
  [./top]
    type = DirichletBC
    boundary = 'top'
    variable = disp_y
    value = 0.0
  [../]
  [./right]
    type = DirichletBC
    boundary = 'right'
    variable = disp_x
    value = 0.01
  [../]
  [./bottom]
    type = DirichletBC
    boundary = 'bottom'
    variable = disp_y
    value = 0.01
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Preconditioning]
  [./full]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Steady

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50
[]

[Outputs]
  exodus = true
[]

modules/combined/test/tests/mortar_tm/2d/ad_frictionless_sec/finite_rr.i

E_block = 1e7
E_plank = 1e7
elem = QUAD9
order = SECOND
name = 'finite_rr'

[Mesh]
  patch_size = 80
  patch_update_strategy = auto
  [./plank]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = -0.3
    xmax = 0.3
    ymin = -10
    ymax = 10
    nx = 2
    ny = 67
    elem_type = ${elem}
  [../]
  [./plank_sidesets]
    type = RenameBoundaryGenerator
    input = plank
    old_boundary_id = '0 1 2 3'
    new_boundary_name = 'plank_bottom plank_right plank_top plank_left'
  [../]
  [./plank_id]
    type = SubdomainIDGenerator
    input = plank_sidesets
    subdomain_id = 1
  [../]

  [./block]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0.31
    xmax = 0.91
    ymin = 7.7
    ymax = 8.5
    nx = 3
    ny = 4
    elem_type = ${elem}
  [../]
  [./block_id]
    type = SubdomainIDGenerator
    input = block
    subdomain_id = 2
  [../]

  [./combined]
    type = MeshCollectionGenerator
    inputs = 'plank_id block_id'
  [../]
  [./block_rename]
    type = RenameBlockGenerator
    input = combined
    old_block_id = '1 2'
    new_block_name = 'plank block'
  [../]
  [./block_sidesets]
    type = SideSetsFromPointsGenerator
    input = block_rename
    points = '0.6  7.7  0
              0.91 8.0  0
              0.6  8.5 0
              0.31 8.0  0'
    new_boundary = 'block_bottom block_right block_top block_left'
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
  [./disp_y]
    order = ${order}
    block = 'plank block'
    scaling = ${fparse 2.0 / (E_plank + E_block)}
  [../]
[]

[Modules/TensorMechanics/Master]
  [./action]
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress hydrostatic_stress strain_xx strain_yy strain_zz'
    block = 'plank block'
    extra_vector_tags = 'ref'
    use_automatic_differentiation = true
  [../]
[]

[Contact]
  [./frictionless]
    mesh = block_sidesets
    master = plank_right
    slave = block_left
    formulation = mortar
    system = constraint
  [../]
[]

[BCs]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    preset = false
    boundary = plank_left
    value = 0.0
  [../]
  [./left_y]
    type = DirichletBC
    variable = disp_y
    preset = false
    boundary = plank_bottom
    value = 0.0
  [../]
  [./right_x]
    type = ADFunctionDirichletBC
    variable = disp_x
    preset = false
    boundary = block_right
    function = '-0.04*sin(4*(t+1.5))+0.02'
  [../]
  [./right_y]
    type = ADFunctionDirichletBC
    variable = disp_y
    preset = false
    boundary = block_right
    function = '-t'
  [../]
[]

[Materials]
  [./plank]
    type = ComputeIsotropicElasticityTensor
    block = 'plank'
    poissons_ratio = 0.3
    youngs_modulus = ${E_plank}
  [../]
  [./block]
    type = ComputeIsotropicElasticityTensor
    block = 'block'
    poissons_ratio = 0.3
    youngs_modulus = ${E_block}
  [../]
  [./stress]
    type = ADComputeFiniteStrainElasticStress
    block = 'plank block'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason'
  petsc_options_iname = '-pc_type -mat_mffd_err -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       1e-5          NONZERO               1e-15'
  end_time = 13.5
  dt = 0.1
  dtmin = 0.1
  timestep_tolerance = 1e-6
  line_search = 'contact'
  nl_abs_tol = 1e-7
[]

[Postprocessors]
  [./nl_its]
    type = NumNonlinearIterations
  [../]
  [./total_nl_its]
    type = CumulativeValuePostprocessor
    postprocessor = nl_its
  [../]
  [./l_its]
    type = NumLinearIterations
  [../]
  [./total_l_its]
    type = CumulativeValuePostprocessor
    postprocessor = l_its
  [../]
  [./contact]
    type = ContactDOFSetSize
    variable = frictionless_normal_lm
    subdomain = frictionless_slave_subdomain
  [../]
  [./avg_hydro]
    type = ElementAverageValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./max_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
  [../]
  [./min_hydro]
    type = ElementExtremeValue
    variable = hydrostatic_stress
    block = 'block'
    value_type = min
  [../]
  [./avg_vonmises]
    type = ElementAverageValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./max_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
  [../]
  [./min_vonmises]
    type = ElementExtremeValue
    variable = vonmises_stress
    block = 'block'
    value_type = min
  [../]
[]

[Outputs]
  exodus = true
  file_base = ${name}
  [./comp]
    type = CSV
    show = 'contact'
  [../]
  [./out]
    type = CSV
    file_base = '${name}_out'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

modules/tensor_mechanics/test/tests/thermal_expansion/multiple_thermal_eigenstrains.i

# The primary purpose of this test is to verify that the ability to combine
# multiple eigenstrains works correctly.  It should behave identically to the
# constant_expansion_coeff.i model in this directory. Instead of applying the
# thermal expansion in one eigenstrain, it splits that into two eigenstrains
# that get added together.

# This test involves only thermal expansion strains on a 2x2x2 cube of approximate
# steel material.  An initial temperature of 25 degrees C is given for the material,
# and an auxkernel is used to calculate the temperature in the entire cube to
# raise the temperature each time step.  After the first timestep,in which the
# temperature jumps, the temperature increases by 6.25C each timestep.
# The thermal strain increment should therefore be
#     6.25 C * 1.3e-5 1/C = 8.125e-5 m/m.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 2
  ny = 2
  nz = 2
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./temp]
  [../]

  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./temperature_load]
    type = ParsedFunction
    value = t*(500.0)+300.0
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./tempfuncaux]
    type = FunctionAux
    variable = temp
    function = temperature_load
    use_displaced_mesh = false
  [../]

  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
  [./strain_zz]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_zz
    index_i = 2
    index_j = 2
  [../]
[]

[BCs]
  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 2.1e5
    poissons_ratio = 0.3
  [../]
  [./small_strain]
    type = ComputeIncrementalSmallStrain
    eigenstrain_names = 'eigenstrain1 eigenstrain2'
  [../]
  [./small_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./thermal_expansion_strain1]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 298
    thermal_expansion_coeff = 1.0e-5
    temperature = temp
    eigenstrain_name = eigenstrain1
  [../]
  [./thermal_expansion_strain2]
    type = ComputeThermalExpansionEigenstrain
    stress_free_temperature = 298
    thermal_expansion_coeff = 0.3e-5
    temperature = temp
    eigenstrain_name = eigenstrain2
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  l_max_its = 50
  nl_max_its = 50
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  end_time = 0.075
  dt = 0.0125
  dtmin = 0.0001
[]

[Outputs]
  csv = true
  exodus = true
  checkpoint = true
[]

[Postprocessors]
  [./strain_xx]
    type = ElementAverageValue
    variable = strain_xx
    block = 0
  [../]
  [./strain_yy]
    type = ElementAverageValue
    variable = strain_yy
    block = 0
  [../]
  [./strain_zz]
    type = ElementAverageValue
    variable = strain_zz
    block = 0
  [../]
  [./temperature]
    type = AverageNodalVariableValue
    variable = temp
    block = 0
  [../]
[]

modules/combined/test/tests/contact_verification/patch_tests/plane_2/plane2_template1.i

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = plane2_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./zeroslip_x]
    type = ConstantAux
    variable = inc_slip_x
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./zeroslip_y]
    type = ConstantAux
    variable = inc_slip_y
    boundary = 4
    execute_on = timestep_begin
    value = 0.0
  [../]
  [./accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  [../]
  [./accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y9]
    type = NodalVariableValue
    nodeid = 8
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeIncrementalSmallStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeIncrementalSmallStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-7
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = x
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = x
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_y5 disp_x9 disp_y9 sigma_yy sigma_zz top_react_x top_react_y x_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/porous_flow/test/tests/poro_elasticity/vol_expansion_poroperm.i

# Apply an increasing porepressure, with zero mechanical forces,
# and observe the corresponding volumetric expansion and porosity increase.
# Check that permeability is calculated correctly from porosity.
#
# P = t
# With the Biot coefficient being 1, the effective stresses should be
# stress_xx = stress_yy = stress_zz = t
# With bulk modulus = 1 then should have
# vol_strain = strain_xx + strain_yy + strain_zz = t.
#
# With the biot coefficient being 1, the porosity (phi) # at time t is:
# phi = 1 - (1 - phi0) / exp(vol_strain)
# where phi0 is the porosity at t = 0 and P = 0.
#
# The permeability (k) is
# k = k_anisotropic * f * d^2 * phi^n / (1-phi)^m

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = 0
  xmax = 1
  ymin = 0
  ymax = 1
  zmin = 0
  zmax = 1
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  block = 0
  PorousFlowDictator = dictator
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./p]
  [../]
[]

[BCs]
  [./p]
    type = FunctionDirichletBC
    boundary = 'bottom top'
    variable = p
    function = t
  [../]
  [./xmin]
    type = DirichletBC
    boundary = left
    variable = disp_x
    value = 0
  [../]
  [./ymin]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0
  [../]
  [./zmin]
    type = DirichletBC
    boundary = back
    variable = disp_z
    value = 0
  [../]
[]

[Kernels]
  [./p_does_not_really_diffuse]
    type = Diffusion
    variable = p
  [../]
  [./TensorMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./poro_x]
    type = PorousFlowEffectiveStressCoupling
    biot_coefficient = 1
    variable = disp_x
    component = 0
  [../]
  [./poro_y]
    type = PorousFlowEffectiveStressCoupling
    biot_coefficient = 1
    variable = disp_y
    component = 1
  [../]
  [./poro_z]
    type = PorousFlowEffectiveStressCoupling
    biot_coefficient = 1
    variable = disp_z
    component = 2
  [../]
[]

[AuxVariables]
  [./poro]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./perm_x]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./perm_y]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./perm_z]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./poro]
    type = PorousFlowPropertyAux
    property = porosity
    variable = poro
  [../]
  [./perm_x]
    type = PorousFlowPropertyAux
    property = permeability
    variable = perm_x
    row = 0
    column = 0
  [../]
  [./perm_y]
    type = PorousFlowPropertyAux
    property = permeability
    variable = perm_y
    row = 1
    column = 1
  [../]
  [./perm_z]
    type = PorousFlowPropertyAux
    property = permeability
    variable = perm_z
    row = 2
    column = 2
  [../]
[]

[Postprocessors]
  [./poro]
    type = PointValue
    variable = poro
    point = '0 0 0'
  [../]
  [./perm_x]
    type = PointValue
    variable = perm_x
    point = '0 0 0'
  [../]
  [./perm_y]
    type = PointValue
    variable = perm_y
    point = '0 0 0'
  [../]
  [./perm_z]
    type = PointValue
    variable = perm_z
    point = '0 0 0'
  [../]
[]

[UserObjects]
  [./dictator]
    type = PorousFlowDictator
    porous_flow_vars = 'p'
    number_fluid_phases = 1
    number_fluid_components = 1
  [../]
  [./pc]
    type = PorousFlowCapillaryPressureVG
    m = 0.5
    alpha = 1
  [../]
[]

[Materials]
  [./temperature]
    type = PorousFlowTemperature
  [../]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 1
    shear_modulus = 1
  [../]
  [./strain]
    type = ComputeSmallStrain
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./vol_strain]
    type = PorousFlowVolumetricStrain
  [../]
  [./ppss]
    type = PorousFlow1PhaseP
    porepressure = p
    capillary_pressure = pc
  [../]
  [./p_eff]
    type = PorousFlowEffectiveFluidPressure
  [../]
  [./porosity]
    type = PorousFlowPorosity
    fluid = true
    mechanical = true
    porosity_zero = 0.1
    solid_bulk = 1
    biot_coefficient = 1
  [../]
  [./permeability]
    type = PorousFlowPermeabilityKozenyCarman
    k_anisotropy = '1 0 0  0 2 0  0 0 0.1'
    poroperm_function = kozeny_carman_fd2
    f = 0.1
    d = 5
    m = 2
    n = 7
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -ksp_atol -ksp_rtol'
    petsc_options_value = 'gmres bjacobi 1E-10 1E-10 10 1E-15 1E-10'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  start_time = 0
  dt = 0.1
  end_time = 1
[]

[Outputs]
  file_base = vol_expansion_poroperm
  csv = true
  execute_on = 'timestep_end'
[]

modules/combined/test/tests/simple_contact/simple_contact_rspherical_dirac.i

#
# This is similar to the patch test for 1D spherical elements with the
#   addition of a contact interface.
#
# The 1D mesh is pinned at x=0.  The displacement at the outer node is set to
#   -3e-3*X where X is the x-coordinate of that node.  That gives a strain of
#   -3e-3 for the x, y, and z directions.
#
# Young's modulus is 1e6, and Poisson's ratio is 0.25.  This gives:
#
# Stress xx, yy, zz = E/(1+nu)/(1-2nu)*strain*((1-nu) + nu + nu) = -6000
#

[Problem]
  coord_type = RSPHERICAL
[]

[Mesh]
  file = simple_contact_rspherical.e
  construct_side_list_from_node_list = true
[]

[GlobalParams]
  displacements = 'disp_x'
[]

[Functions]
  [./ur]
    type = ParsedFunction
    value = '-3e-3*x'
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    add_variables = true
    strain = FINITE
    generate_output = 'stress_xx stress_yy stress_zz'
  [../]
[]

[BCs]
  [./ur]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '1 4'
    function = ur
  [../]
[]

[Contact]
  [./fred]
    master = 2
    slave = 3
    system = DiracKernel
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1 2 3'
    youngs_modulus = 1e6
    poissons_ratio = 0.25
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2 3'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'lu       101'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-11

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 1
  end_time = 1.0
[]

[Outputs]
  exodus = true
[]

modules/tensor_mechanics/test/tests/interaction_integral/interaction_integral_3d.i

#This tests the Interaction-Integral evaluation capability.
#This is a 3d extrusion of a 2d plane strain model with 2 elements
#through the thickness, and calculates the Interaction-Integrals using options
#to treat it as 3d.

[GlobalParams]
  order = FIRST
#  order = SECOND
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = crack3d.e
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./rampConstant]
    type = PiecewiseLinear
    x = '0. 1.'
    y = '0. 1.'
    scale_factor = -1e2
  [../]
[]

[DomainIntegral]
  integrals = 'InteractionIntegralKI InteractionIntegralKII InteractionIntegralKIII'
  boundary = 800
  crack_direction_method = CrackDirectionVector
  crack_direction_vector = '1 0 0'
  radius_inner = '4.0 5.5'
  radius_outer = '5.5 7.0'
  block = 1
  youngs_modulus = 207000
  poissons_ratio = 0.3
  output_q = false
  incremental = true
[]

[Modules/TensorMechanics/Master]
  [./master]
    strain = FINITE
    add_variables = true
    incremental = true
    generate_output = 'stress_xx stress_yy stress_zz vonmises_stress'
  [../]
[]

[BCs]
  [./crack_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = 500
    value = 0.0
  [../]
  [./no_z2]
    type = DirichletBC
    variable = disp_z
    boundary = 510
    value = 0.0
  [../]
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 700
    value = 0.0
  [../]
  [./Pressure]
    [./Side1]
      boundary = 400
      function = rampConstant
    [../]
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 207000
    poissons_ratio = 0.3
  [../]
  [./elastic_stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]


[Executioner]
  type = Transient

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 50
  nl_max_its = 20
  nl_abs_tol = 1e-5
  l_tol = 1e-2

  start_time = 0.0
  dt = 1

  end_time = 1
  num_steps = 1
[]

[Outputs]
  file_base = interaction_integral_3d_out
  exodus = true
  csv = true
[]

modules/combined/test/tests/contact_verification/patch_tests/brick_3/brick3_template1.i

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick3_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_x
  [../]
  [./disp_x33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_x
  [../]
  [./disp_y28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_y
  [../]
  [./disp_y33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    component = 1
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x28 disp_y28 disp_x33 disp_y33 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    slave = 3
    master = 4
    system = constraint
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

modules/tensor_mechanics/test/tests/2D_different_planes/planestrain_jacobian_testing_xz.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = square_xz_plane.e
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./plane_strain]
    block = 1
    strain = SMALL
    out_of_plane_direction = y
    planar_formulation = PLANE_STRAIN
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.0
    youngs_modulus = 1
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  petsc_options_iname = '-ksp_type -pc_type -snes_type'
  petsc_options_value = 'bcgs bjacobi test'

  end_time = 1.0
[]

modules/tensor_mechanics/test/tests/ad_2D_geometries/2D-RZ_finiteStrain_resid.i

# This tests the save_in_disp residual aux-variables for
# ComputeAxisymmetricRZFiniteStrain, which is generated through the use of the
# TensorMechanics MasterAction. The GeneratedMesh is 1x1, rotated via axisym to
# create a cylinder of height 1, radius 1.
#
# PostProcessor force_z plots the force on the top surface of the cylinder.
#
# Displacement of 0.1 is applied to top of cylinder while other surfaces are
# constrained. Plotting force_z vs stress_z will show a slope of 3.14159 (pi),
# consistent with formula for normal stress:
#
# Stress = force / area
#
# where area is A = pi * r^2 for a circle.

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 5
  ny = 5
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
[]

[GlobalParams]
  displacements = 'disp_r disp_z'
[]

[Problem]
  coord_type = RZ
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = FINITE
    add_variables = true
    save_in = 'force_r force_z'
    use_automatic_differentiation = true
  [../]
[]

[AuxVariables]
  [./stress_r]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_r]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_z]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_z]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./force_r]
    order = FIRST
    family = LAGRANGE
  [../]
  [./force_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxKernels]
  [./stress_r]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_r
    execute_on = timestep_end
  [../]
  [./strain_r]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 0
    index_j = 0
    variable = strain_r
    execute_on = timestep_end
  [../]
  [./stress_z]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_z
    execute_on = timestep_end
  [../]
  [./strain_z]
    type = RankTwoAux
    rank_two_tensor = total_strain
    index_i = 1
    index_j = 1
    variable = strain_z
    execute_on = timestep_end
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]

  [./_elastic_strain]
    type = ADComputeFiniteStrainElasticStress
  [../]
[]

[BCs]
  [./no_disp_r_left]
    type = ADDirichletBC
    variable = disp_r
    boundary = left
    value = 0.0
  [../]
  [./no_disp_r_right]
    type = ADDirichletBC
    variable = disp_r
    boundary = right
    value = 0.0
  [../]
  [./no_disp_z_bottom]
    type = ADDirichletBC
    variable = disp_z
    boundary = bottom
    value = 0.0
  [../]
  [./top]
    type = ADFunctionDirichletBC
    variable = disp_z
    boundary = top
    function = 't'
  [../]
[]

[Debug]
  show_var_residual_norms = true
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '  201               hypre    boomeramg      10'

  line_search = 'none'

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 5e-9
  nl_abs_tol = 1e-10
  nl_max_its = 15

  l_tol = 1e-3
  l_max_its = 50

  start_time = 0.0
  end_time = 0.1
  dt = 0.01
[]

[Postprocessors]
  [./strainR]
    type = ElementAverageValue
    variable = strain_r
  [../]
  [./stressR]
    type = ElementAverageValue
    variable = stress_r
  [../]
  [./strainZ]
    type = ElementAverageValue
    variable = strain_z
  [../]
  [./stressZ]
    type = ElementAverageValue
    variable = stress_z
  [../]
  [./force_r]
    type = NodalSum
    variable = force_r
    boundary = top
  [../]
  [./force_z]
    type = NodalSum
    variable = force_z
    boundary = top
  [../]
[]

[Outputs]
  exodus = true
  print_linear_residuals = false
  perf_graph = true
[]

modules/xfem/test/tests/corner_nodes_cut/corner_node_cut.i

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  displacements = 'disp_x disp_y'
  volumetric_locking_correction = true
[]

[XFEM]
  qrule = volfrac
  output_cut_plane = true
[]

[UserObjects]
  [./line_seg_cut_uo]
    type = LineSegmentCutUserObject
    cut_data = '0.0 0.5 0.5 0.5'
    time_start_cut = 0.0
    time_end_cut = 0.0
  [../]
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 4
  ny = 4
  xmin = 0.0
  xmax = 1.0
  ymin = 0.0
  ymax = 1.0
  elem_type = QUAD4
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
  [../]
[]

[BCs]
  [./top_x]
    type = DirichletBC
    boundary = 2
    variable = disp_x
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    boundary = 2
    variable = disp_y
    value = 0.1
  [../]
  [./bottom_y]
    type = DirichletBC
    boundary = 0
    variable = disp_y
    value = 0.0
  [../]
  [./bottom_x]
    type = DirichletBC
    boundary = 0
    variable = disp_x
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      8'

  line_search = 'none'

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]

# max_xfem_update = 1

# controls for linear iterations
  l_max_its = 100
  l_tol = 1e-2

# controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-16
  nl_abs_tol = 1e-10

# time control
  start_time = 0.0
  dt = 1.0
  end_time = 1.0
[]

[Outputs]
  exodus = true
  [./console]
    type = Console
    output_linear = true
  [../]
[]

modules/tensor_mechanics/test/tests/thermal_expansion_function/mean.i

# This test checks the thermal expansion calculated via a mean thermal expansion coefficient.
# The coefficient is selected so as to result in a 1e-4 strain in the x-axis, and to cross over
# from positive to negative strain.

[Mesh]
  [./gen]
    type = GeneratedMeshGenerator
    dim = 3
  [../]
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[AuxVariables]
  [./temp]
  [../]
[]

[Modules/TensorMechanics/Master]
  [./all]
    strain = SMALL
    add_variables = true
    eigenstrain_names = eigenstrain
    generate_output = 'strain_xx strain_yy strain_zz'
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]

  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]

  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
[]

[AuxKernels]
  [./temp]
    type = FunctionAux
    variable = temp
    function = '1 + t'
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1
    poissons_ratio = 0.3
  [../]
  [./stress]
    type = ComputeLinearElasticStress
  [../]
  [./thermal_expansion_strain]
    type = ComputeMeanThermalExpansionFunctionEigenstrain
    thermal_expansion_function = cte_func_mean
    thermal_expansion_function_reference_temperature = 1.2
    stress_free_temperature = 1.5
    temperature = temp
    eigenstrain_name = eigenstrain
  [../]
[]

[Functions]
  [./cte_func_mean]
    type = ParsedFunction
    vars = 'T T_stress_free T_ref end_strain'
    vals = '2 1.5           1.2   1e-4'
    value = 'end_strain / (T - T_stress_free - end_strain * (T_stress_free - T_ref))'
  [../]
[]

[Postprocessors]
  [./disp_x_max]
    type = SideAverageValue
    variable = disp_x
    boundary = right
  [../]
  [./temp_avg]
    type = ElementAverageValue
    variable = temp
  [../]
[]

[Executioner]
  type = Transient

  end_time = 1.0
  dt = 0.1
[]

[Outputs]
  csv = true
[]

Child Objects

modules/peridynamics/test/include/materials/ComputePlaneStressIsotropicElasticityTensor.h

modules/peridynamics/test/include/materials/ComputePlaneStressIsotropicElasticityTensor.h

// This file is part of the MOOSE framework
// https://www.mooseframework.org
//
// All rights reserved, see COPYRIGHT for full restrictions
// https://github.com/idaholab/moose/blob/master/COPYRIGHT
//
// Licensed under LGPL 2.1, please see LICENSE for details
// https://www.gnu.org/licenses/lgpl-2.1.html

#pragma once

#include "ComputeIsotropicElasticityTensor.h"

class ComputePlaneStressIsotropicElasticityTensor;

template <>
InputParameters validParams<ComputePlaneStressIsotropicElasticityTensor>();

/**
 * Material class to define elasticity tensor for conventional plane stress of isotropic material
 */
class ComputePlaneStressIsotropicElasticityTensor : public ComputeIsotropicElasticityTensor
{
public:
  ComputePlaneStressIsotropicElasticityTensor(const InputParameters & parameters);
};

References

Lawrence E Malvern. Introduction to the Mechanics of a Continuous Medium. Prentice-Hall, 1969.

William S Slaughter. The Linearized Theory of Elasticity. Springer Science & Business Media, 2012.

Description
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