#include <FEProblemSolve.h>

Inheritance diagram for FEProblemSolve:

Public Types
using	DataFileParameterType = DataFileName
	The parameter type this interface expects for a data file name. More...

Public Member Functions
	FEProblemSolve (Executioner &ex)

virtual bool	solve () override
	Picard solve the FEProblem. More...

virtual void	setInnerSolve (SolveObject &) override
	Set the inner solve object wrapped by this object. More...

unsigned int	numGridSteps () const
	Return the number of grid sequencing steps. More...

const std::vector< SolverSystem * > &	systemsToSolve () const
	Returns a reference to the vector of solver systems that this object is supposed to solve. More...

virtual void	initialSetup ()
	Method that should be executed once, before any solve calls. More...

virtual bool	enabled () const
	Return the enabled status of the object. More...

std::shared_ptr< MooseObject >	getSharedPtr ()
	Get another shared pointer to this object that has the same ownership group. More...

std::shared_ptr< const MooseObject >	getSharedPtr () const

MooseApp &	getMooseApp () const
	Get the MooseApp this class is associated with. More...

const std::string &	type () const
	Get the type of this class. More...

virtual const std::string &	name () const
	Get the name of the class. More...

std::string	typeAndName () const
	Get the class's combined type and name; useful in error handling. More...

std::string	errorPrefix (const std::string &error_type) const

void	callMooseError (std::string msg, const bool with_prefix) const
	Calls moose error with the message `msg`. More...

MooseObjectParameterName	uniqueParameterName (const std::string &parameter_name) const
	The unique parameter name of a valid parameter of this object for accessing parameter controls. More...

const InputParameters &	parameters () const
	Get the parameters of the object. More...

MooseObjectName	uniqueName () const
	The unique name for accessing input parameters of this object in the InputParameterWarehouse. More...

template<typename T >
const T &	getParam (const std::string &name) const
	Retrieve a parameter for the object. More...

template<typename T1 , typename T2 >
std::vector< std::pair< T1, T2 > >	getParam (const std::string &param1, const std::string &param2) const
	Retrieve two parameters and provide pair of parameters for the object. More...

template<typename T >
const T *	queryParam (const std::string &name) const
	Query a parameter for the object. More...

template<typename T >
const T &	getRenamedParam (const std::string &old_name, const std::string &new_name) const
	Retrieve a renamed parameter for the object. More...

template<typename T >
T	getCheckedPointerParam (const std::string &name, const std::string &error_string="") const
	Verifies that the requested parameter exists and is not NULL and returns it to the caller. More...

bool	isParamValid (const std::string &name) const
	Test if the supplied parameter is valid. More...

bool	isParamSetByUser (const std::string &nm) const
	Test if the supplied parameter is set by a user, as opposed to not set or set to default. More...

template<typename... Args>
void	paramError (const std::string &param, Args... args) const
	Emits an error prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message. More...

template<typename... Args>
void	paramWarning (const std::string &param, Args... args) const
	Emits a warning prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message. More...

template<typename... Args>
void	paramInfo (const std::string &param, Args... args) const
	Emits an informational message prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message. More...

void	connectControllableParams (const std::string &parameter, const std::string &object_type, const std::string &object_name, const std::string &object_parameter) const
	Connect controllable parameter of this action with the controllable parameters of the objects added by this action. More...

template<typename... Args>
void	mooseError (Args &&... args) const
	Emits an error prefixed with object name and type. More...

template<typename... Args>
void	mooseErrorNonPrefixed (Args &&... args) const
	Emits an error without the prefixing included in mooseError(). More...

template<typename... Args>
void	mooseDocumentedError (const std::string &repo_name, const unsigned int issue_num, Args &&... args) const
	Emits a documented error with object name and type. More...

template<typename... Args>
void	mooseWarning (Args &&... args) const
	Emits a warning prefixed with object name and type. More...

template<typename... Args>
void	mooseWarningNonPrefixed (Args &&... args) const
	Emits a warning without the prefixing included in mooseWarning(). More...

template<typename... Args>
void	mooseDeprecated (Args &&... args) const

template<typename... Args>
void	mooseInfo (Args &&... args) const

const Parallel::Communicator &	comm () const

processor_id_type	n_processors () const

processor_id_type	processor_id () const

std::string	getDataFileName (const std::string &param) const
	Deprecated method. More...

std::string	getDataFileNameByName (const std::string &relative_path) const
	Deprecated method. More...

std::string	getDataFilePath (const std::string &relative_path) const
	Returns the path of a data file for a given relative file path. More...

PerfGraph &	perfGraph ()
	Get the PerfGraph. More...

bool	isDefaultPostprocessorValue (const std::string &param_name, const unsigned int index=0) const
	Determine whether or not the Postprocessor is a default value. More...

bool	hasPostprocessor (const std::string &param_name, const unsigned int index=0) const
	Determine if the Postprocessor data exists. More...

bool	hasPostprocessorByName (const PostprocessorName &name) const
	Determine if the Postprocessor data exists. More...

std::size_t	coupledPostprocessors (const std::string &param_name) const
	Returns number of Postprocessors coupled under parameter name. More...

const PostprocessorName &	getPostprocessorName (const std::string &param_name, const unsigned int index=0) const
	Get the name of a postprocessor. More...


const PostprocessorValue &	getPostprocessorValue (const std::string &param_name, const unsigned int index=0) const
	doco-normal-methods-begin Retrieve the value of a Postprocessor or one of it's old or older values More...

const PostprocessorValue &	getPostprocessorValueOld (const std::string &param_name, const unsigned int index=0) const

const PostprocessorValue &	getPostprocessorValueOlder (const std::string &param_name, const unsigned int index=0) const


virtual const PostprocessorValue &	getPostprocessorValueByName (const PostprocessorName &name) const
	Retrieve the value of the Postprocessor. More...

const PostprocessorValue &	getPostprocessorValueOldByName (const PostprocessorName &name) const

const PostprocessorValue &	getPostprocessorValueOlderByName (const PostprocessorName &name) const

Static Public Member Functions
static InputParameters	feProblemDefaultConvergenceParams ()

static InputParameters	validParams ()

static const std::set< std::string > &	mooseLineSearches ()

Public Attributes
const ConsoleStream	_console
	An instance of helper class to write streams to the Console objects. More...

Protected Member Functions
template<typename T >
T	getParamFromNonlinearSystemVectorParam (const std::string &param_name, unsigned int index) const
	Helper routine to get the nonlinear system parameter at the right index. More...

PerfID	registerTimedSection (const std::string &section_name, const unsigned int level) const
	Call to register a named section for timing. More...

PerfID	registerTimedSection (const std::string &section_name, const unsigned int level, const std::string &live_message, const bool print_dots=true) const
	Call to register a named section for timing. More...

std::string	timedSectionName (const std::string &section_name) const

virtual void	addPostprocessorDependencyHelper (const PostprocessorName &) const
	Helper for deriving classes to override to add dependencies when a Postprocessor is requested. More...

Protected Attributes
const unsigned int	_num_grid_steps
	The number of steps to perform in a grid sequencing algorithm. More...

const bool	_using_multi_sys_fp_iterations
	Whether we are using fixed point iterations for multi-system. More...

Convergence *	_multi_sys_fp_convergence
	Convergence object to assess the convergence of the multi-system fixed point iteration. More...

std::vector< SolverSystem * >	_systems
	Vector of pointers to the systems. More...

unsigned int	_num_nl_systems
	Number of nonlinear systems. More...

Executioner &	_executioner
	Executioner used to construct this. More...

FEProblemBase &	_problem
	Reference to FEProblem. More...

DisplacedProblem *	_displaced_problem
	Displaced problem. More...

MooseMesh &	_mesh
	Mesh. More...

MooseMesh *	_displaced_mesh
	Displaced mesh. More...

SystemBase &	_solver_sys
	Reference to a system for creating vectors as needed for the solve, etc. More...

AuxiliarySystem &	_aux
	Reference to auxiliary system for faster access. More...

SolveObject *	_inner_solve
	SolveObject wrapped by this solve object. More...

const bool &	_enabled
	Reference to the "enable" InputParameters, used by Controls for toggling on/off MooseObjects. More...

MooseApp &	_app
	The MOOSE application this is associated with. More...

const std::string	_type
	The type of this class. More...

const std::string	_name
	The name of this class. More...

const InputParameters &	_pars
	Parameters of this object, references the InputParameters stored in the InputParametersWarehouse. More...

Factory &	_factory
	The Factory associated with the MooseApp. More...

ActionFactory &	_action_factory
	Builds Actions. More...

const Parallel::Communicator &	_communicator

MooseApp &	_pg_moose_app
	The MooseApp that owns the PerfGraph. More...

const std::string	_prefix
	A prefix to use for all sections. More...

Static Protected Attributes
static std::set< std::string > const	_moose_line_searches = {"contact", "project"}
	Moose provided line searches. More...

Detailed Description

Definition at line 16 of file FEProblemSolve.h.

Member Typedef Documentation

◆ DataFileParameterType

using DataFileInterface::DataFileParameterType = DataFileName

inherited

The parameter type this interface expects for a data file name.

Definition at line 27 of file DataFileInterface.h.

Constructor & Destructor Documentation

◆ FEProblemSolve()

FEProblemSolve::FEProblemSolve ( Executioner & ex )

Definition at line 221 of file FEProblemSolve.C.

   : MultiSystemSolveObject(ex),
     _num_grid_steps(cast_int<unsigned int>(getParam<unsigned int>("num_grids") - 1)),
     _using_multi_sys_fp_iterations(getParam<bool>("multi_system_fixed_point")),
     _multi_sys_fp_convergence(nullptr) // has not been created yet
 {
   if (_moose_line_searches.find(getParam<MooseEnum>("line_search").operator std::string()) !=
       _moose_line_searches.end())
     _problem.addLineSearch(_pars);
 
   auto set_solver_params = [this, &ex](const SolverSystem & sys)
   {
     const auto prefix = sys.prefix();
     Moose::PetscSupport::storePetscOptions(_problem, prefix, ex);
     Moose::PetscSupport::setConvergedReasonFlags(_problem, prefix);
 
     // Set solver parameter prefix and system number
     auto & solver_params = _problem.solverParams(sys.number());
     solver_params._prefix = prefix;
     solver_params._solver_sys_num = sys.number();
   };
 
   // Extract and store PETSc related settings on FEProblemBase
   for (const auto * const sys : _systems)
     set_solver_params(*sys);
 
   // Set linear solve parameters in the equation system
   // Nonlinear solve parameters are added in the DefaultNonlinearConvergence
   EquationSystems & es = _problem.es();
   es.parameters.set<Real>("linear solver tolerance") = getParam<Real>("l_tol");
   es.parameters.set<Real>("linear solver absolute tolerance") = getParam<Real>("l_abs_tol");
   es.parameters.set<unsigned int>("linear solver maximum iterations") =
       getParam<unsigned int>("l_max_its");
   es.parameters.set<bool>("reuse preconditioner") = getParam<bool>("reuse_preconditioner");
   es.parameters.set<unsigned int>("reuse preconditioner maximum linear iterations") =
       getParam<unsigned int>("reuse_preconditioner_max_linear_its");
 
   // Transfer to the Problem misc nonlinear solve optimization parameters
   _problem.setSNESMFReuseBase(getParam<bool>("snesmf_reuse_base"),
                               _pars.isParamSetByUser("snesmf_reuse_base"));
   _problem.skipExceptionCheck(getParam<bool>("skip_exception_check"));
 
   if (isParamValid("nonlinear_convergence"))
   {
     if (_problem.onlyAllowDefaultNonlinearConvergence())
       mooseError("The selected problem does not allow 'nonlinear_convergence' to be set.");
     _problem.setNonlinearConvergenceNames(
         getParam<std::vector<ConvergenceName>>("nonlinear_convergence"));
   }
   else
     _problem.setNeedToAddDefaultNonlinearConvergence();
   if (isParamValid("linear_convergence"))
   {
     if (_problem.numLinearSystems() == 0)
       paramError(
           "linear_convergence",
           "Setting 'linear_convergence' is currently only possible for solving linear systems");
     _problem.setLinearConvergenceNames(
         getParam<std::vector<ConvergenceName>>("linear_convergence"));
   }
 
   // Check whether the user has explicitly requested automatic scaling and is using a solve type
   // without a matrix. If so, then we warn them
   if ((_pars.isParamSetByUser("automatic_scaling") && getParam<bool>("automatic_scaling")) &&
       std::all_of(_systems.begin(),
                   _systems.end(),
                   [this](const auto & solver_sys)
                   { return _problem.solverParams(solver_sys->number())._type == Moose::ST_JFNK; }))
   {
     paramWarning("automatic_scaling",
                  "Automatic scaling isn't implemented for the case where you do not have a "
                  "preconditioning matrix. No scaling will be applied");
     _problem.automaticScaling(false);
   }
   else
     // Check to see whether automatic_scaling has been specified anywhere, including at the
     // application level. No matter what: if we don't have a matrix, we don't do scaling
     _problem.automaticScaling(
         isParamValid("automatic_scaling")
             ? getParam<bool>("automatic_scaling")
             : (getMooseApp().defaultAutomaticScaling() &&
                std::any_of(_systems.begin(),
                            _systems.end(),
                            [this](const auto & solver_sys) {
                              return _problem.solverParams(solver_sys->number())._type !=
                                     Moose::ST_JFNK;
                            })));
 
   if (!_using_multi_sys_fp_iterations && isParamValid("multi_system_fixed_point_convergence"))
     paramError("multi_system_fixed_point_convergence",
                "Cannot set a convergence object for multi-system fixed point iterations if "
                "'multi_system_fixed_point' is set to false");
   if (_using_multi_sys_fp_iterations && !isParamValid("multi_system_fixed_point_convergence"))
     paramError("multi_system_fixed_point_convergence",
                "Must set a convergence object for multi-system fixed point iterations if using "
                "multi-system fixed point iterations");
 
   // Set the same parameters to every nonlinear system by default
   int i_nl_sys = -1;
   for (const auto i_sys : index_range(_systems))
   {
     auto nl_ptr = dynamic_cast<NonlinearSystemBase *>(_systems[i_sys]);
     // Linear systems have very different parameters at the moment
     if (!nl_ptr)
       continue;
     auto & nl = *nl_ptr;
     i_nl_sys++;
 
     nl.setPreSMOResidual(getParam<bool>("use_pre_SMO_residual"));
 
     const auto & all_splittings = getParam<std::vector<std::vector<std::string>>>("splitting");
     if (all_splittings.size())
       nl.setDecomposition(
           getParamFromNonlinearSystemVectorParam<std::vector<std::string>>("splitting", i_nl_sys));
     else
       nl.setDecomposition({});
 
     const auto res_and_jac =
         getParamFromNonlinearSystemVectorParam<bool>("residual_and_jacobian_together", i_nl_sys);
     if (res_and_jac)
       nl.residualAndJacobianTogether();
 
     // Automatic scaling parameters
     nl.computeScalingOnce(
         getParamFromNonlinearSystemVectorParam<bool>("compute_scaling_once", i_nl_sys));
     nl.autoScalingParam(
         getParamFromNonlinearSystemVectorParam<Real>("resid_vs_jac_scaling_param", i_nl_sys));
     nl.offDiagonalsInAutoScaling(
         getParamFromNonlinearSystemVectorParam<bool>("off_diagonals_in_auto_scaling", i_nl_sys));
     if (isParamValid("scaling_group_variables"))
       nl.scalingGroupVariables(
           getParamFromNonlinearSystemVectorParam<std::vector<std::vector<std::string>>>(
               "scaling_group_variables", i_nl_sys));
     if (isParamValid("ignore_variables_for_autoscaling"))
     {
       // Before setting ignore_variables_for_autoscaling, check that they are not present in
       // scaling_group_variables
       if (isParamValid("scaling_group_variables"))
       {
         const auto & ignore_variables_for_autoscaling =
             getParamFromNonlinearSystemVectorParam<std::vector<std::string>>(
                 "ignore_variables_for_autoscaling", i_nl_sys);
         const auto & scaling_group_variables =
             getParamFromNonlinearSystemVectorParam<std::vector<std::vector<std::string>>>(
                 "scaling_group_variables", i_nl_sys);
         for (const auto & group : scaling_group_variables)
           for (const auto & var_name : group)
             if (std::find(ignore_variables_for_autoscaling.begin(),
                           ignore_variables_for_autoscaling.end(),
                           var_name) != ignore_variables_for_autoscaling.end())
               paramError("ignore_variables_for_autoscaling",
                          "Variables cannot be in a scaling grouping and also be ignored");
       }
       nl.ignoreVariablesForAutoscaling(
           getParamFromNonlinearSystemVectorParam<std::vector<std::string>>(
               "ignore_variables_for_autoscaling", i_nl_sys));
     }
   }
 
   // Multi-grid options
   _problem.numGridSteps(_num_grid_steps);
 }

Member Function Documentation

◆ addPostprocessorDependencyHelper()

virtual void PostprocessorInterface::addPostprocessorDependencyHelper ( const PostprocessorName & ) const

inlineprotectedvirtualinherited

Helper for deriving classes to override to add dependencies when a Postprocessor is requested.

Reimplemented in AuxKernelTempl< ComputeValueType >, AuxKernelTempl< RT >, AuxKernelTempl< RealVectorValue >, AuxKernelTempl< Real >, UserObject, and InitialConditionBase.

Definition at line 141 of file PostprocessorInterface.h.

Referenced by PostprocessorInterface::getPostprocessorValueByNameInternal().

141 {}

◆ callMooseError()

void MooseBase::callMooseError	(	std::string	msg,
		const bool	with_prefix
	)		const

inherited

Calls moose error with the message msg.

Will prefix the message with the subapp name if one exists.

If with_prefix, then add the prefix from errorPrefix() to the error.

Definition at line 33 of file MooseBase.C.

Referenced by InputParameters::callMooseErrorHelper(), MooseBaseErrorInterface::mooseDocumentedError(), MooseBaseErrorInterface::mooseError(), MooseBaseErrorInterface::mooseErrorNonPrefixed(), and MooseBaseParameterInterface::paramError().

 {
   _app.getOutputWarehouse().mooseConsole();
   const std::string prefix = _app.isUltimateMaster() ? "" : _app.name();
   if (with_prefix)
     msg = errorPrefix("error") + msg;
   moose::internal::mooseErrorRaw(msg, prefix);
 }

◆ connectControllableParams()

void MooseBaseParameterInterface::connectControllableParams	(	const std::string &	parameter,
		const std::string &	object_type,
		const std::string &	object_name,
		const std::string &	object_parameter
	)		const

inherited

Connect controllable parameter of this action with the controllable parameters of the objects added by this action.

Parameters

parameter	Name of the controllable parameter of this action
object_type	Type of the object added by this action.
object_name	Name of the object added by this action.
object_parameter	Name of the parameter of the object.

Definition at line 33 of file MooseBaseParameterInterface.C.

 {
   MooseObjectParameterName primary_name(uniqueName(), parameter);
   const auto base_type = _factory.getValidParams(object_type).get<std::string>("_moose_base");
   MooseObjectParameterName secondary_name(base_type, object_name, object_parameter);
   _moose_base.getMooseApp().getInputParameterWarehouse().addControllableParameterConnection(
       primary_name, secondary_name);
 
   const auto & tags = _pars.get<std::vector<std::string>>("control_tags");
   for (const auto & tag : tags)
   {
     if (!tag.empty())
     {
       // Only adds the parameter with the different control tags if the derived class
       // properly registers the parameter to its own syntax
       MooseObjectParameterName tagged_name(tag, _moose_base.name(), parameter);
       _moose_base.getMooseApp().getInputParameterWarehouse().addControllableParameterConnection(
           tagged_name, secondary_name, /*error_on_empty=*/false);
     }
   }
 }

◆ coupledPostprocessors()

std::size_t PostprocessorInterface::coupledPostprocessors ( const std::string & param_name ) const

inherited

Returns number of Postprocessors coupled under parameter name.

Parameters

param_name The name of the Postprocessor parameter

Returns: Number of coupled post-processors, 1 if it's a single

Definition at line 129 of file PostprocessorInterface.C.

Referenced by FunctionValuePostprocessor::FunctionValuePostprocessor().

 {
   checkParam(param_name);
 
   if (_ppi_params.isType<PostprocessorName>(param_name))
     return 1;
   return _ppi_params.get<std::vector<PostprocessorName>>(param_name).size();
 }

◆ enabled()

virtual bool MooseObject::enabled ( ) const

inlinevirtualinherited

Return the enabled status of the object.

Reimplemented in EigenKernel.

Definition at line 40 of file MooseObject.h.

Referenced by EigenKernel::enabled().

40 { return _enabled; }

MooseObject::_enabled

const bool & _enabled

Reference to the "enable" InputParameters, used by Controls for toggling on/off MooseObjects.

Definition: MooseObject.h:51

◆ errorPrefix()

std::string MooseBase::errorPrefix ( const std::string & error_type ) const

inherited

Returns: A prefix to be used in errors that contains the input file location associated with this object (if any) and the name and type of the object.

Definition at line 43 of file MooseBase.C.

Referenced by MooseBase::callMooseError(), MooseBaseErrorInterface::mooseDeprecated(), MooseBaseErrorInterface::mooseInfo(), MooseBaseErrorInterface::mooseWarning(), and MooseBaseParameterInterface::paramErrorMsg().

 {
   std::stringstream oss;
   if (const auto node = _params.getHitNode())
     if (!node->isRoot())
       oss << node->fileLocation() << ":\n";
   oss << "The following " << error_type << " occurred in the ";
   if (const auto base_ptr = _params.getBase())
     oss << *base_ptr;
   else
     oss << "object";
   oss << " '" << name() << "' of type " << type() << ".\n\n";
   return oss.str();
 }

◆ feProblemDefaultConvergenceParams()

InputParameters FEProblemSolve::feProblemDefaultConvergenceParams ( )

static

Definition at line 27 of file FEProblemSolve.C.

Referenced by AddDefaultConvergenceAction::checkUnusedNonlinearConvergenceParameters(), validParams(), and DefaultNonlinearConvergence::validParams().

 {
   InputParameters params = emptyInputParameters();
 
   params.addParam<unsigned int>("nl_max_its", 50, "Max Nonlinear Iterations");
   params.addParam<unsigned int>("nl_forced_its", 0, "The Number of Forced Nonlinear Iterations");
   params.addParam<unsigned int>("nl_max_funcs", 10000, "Max Nonlinear solver function evaluations");
   params.addParam<Real>("nl_abs_tol", 1.0e-50, "Nonlinear Absolute Tolerance");
   params.addParam<Real>("nl_rel_tol", 1.0e-8, "Nonlinear Relative Tolerance");
   params.addParam<Real>(
       "nl_div_tol",
       1.0e10,
       "Nonlinear Relative Divergence Tolerance. A negative value disables this check.");
   params.addParam<Real>(
       "nl_abs_div_tol",
       1.0e50,
       "Nonlinear Absolute Divergence Tolerance. A negative value disables this check.");
   params.addParam<Real>("nl_abs_step_tol", 0., "Nonlinear Absolute step Tolerance");
   params.addParam<Real>("nl_rel_step_tol", 0., "Nonlinear Relative step Tolerance");
   params.addParam<unsigned int>("n_max_nonlinear_pingpong",
                                 100,
                                 "The maximum number of times the nonlinear residual can ping pong "
                                 "before requesting halting the current evaluation and requesting "
                                 "timestep cut for transient simulations");
 
   params.addParamNamesToGroup(
       "nl_max_its nl_forced_its nl_max_funcs nl_abs_tol nl_rel_tol "
       "nl_rel_step_tol nl_abs_step_tol nl_div_tol nl_abs_div_tol n_max_nonlinear_pingpong",
       "Nonlinear Solver");
 
   return params;
 }

◆ getCheckedPointerParam()

template<typename T >

T MooseBaseParameterInterface::getCheckedPointerParam	(	const std::string &	name,
		const std::string &	error_string = `""`
	)		const

inherited

Verifies that the requested parameter exists and is not NULL and returns it to the caller.

The template parameter must be a pointer or an error will be thrown.

Definition at line 286 of file MooseBaseParameterInterface.h.

 {
   return parameters().getCheckedPointerParam<T>(name, error_string);
 }

◆ getDataFileName()

std::string DataFileInterface::getDataFileName ( const std::string & param ) const

inherited

Deprecated method.

The data file paths are now automatically set within the InputParameters object, so using getParam<DataFileName>("param_name") is now sufficient.

Definition at line 21 of file DataFileInterface.C.

 {
   _parent.mooseDeprecated("getDataFileName() is deprecated. The file path is now directly set "
                           "within the InputParameters.\nUse getParam<DataFileName>(\"",
                           param,
                           "\") instead.");
   return _parent.getParam<DataFileName>(param);
 }

◆ getDataFileNameByName()

std::string DataFileInterface::getDataFileNameByName ( const std::string & relative_path ) const

inherited

Deprecated method.

Use getDataFilePath() instead.

Definition at line 31 of file DataFileInterface.C.

 {
   _parent.mooseDeprecated("getDataFileNameByName() is deprecated. Use getDataFilePath(\"",
                           relative_path,
                           "\") instead.");
   return getDataFilePath(relative_path);
 }

◆ getDataFilePath()

std::string DataFileInterface::getDataFilePath ( const std::string & relative_path ) const

inherited

Returns the path of a data file for a given relative file path.

This can be used for hardcoded datafile names and will search the same locations as getDataFileName

Definition at line 40 of file DataFileInterface.C.

Referenced by DataFileInterface::getDataFileNameByName().

 {
   // This should only ever be used with relative paths. There is no point to
   // use this search path with an absolute path.
   if (std::filesystem::path(relative_path).is_absolute())
     _parent.mooseWarning("While using getDataFilePath(\"",
                          relative_path,
                          "\"): This API should not be used for absolute paths.");
 
   // Throw on error so that if getPath() fails, we can throw an error
   // with the context of _parent.mooseError()
   const auto throw_on_error_before = Moose::_throw_on_error;
   Moose::_throw_on_error = true;
   std::optional<std::string> error;
 
   // This will search the data paths for this relative path
   Moose::DataFileUtils::Path found_path;
   try
   {
     found_path = Moose::DataFileUtils::getPath(relative_path);
   }
   catch (std::exception & e)
   {
     error = e.what();
   }
 
   Moose::_throw_on_error = throw_on_error_before;
   if (error)
     _parent.mooseError(*error);
 
   mooseAssert(found_path.context == Moose::DataFileUtils::Context::DATA,
               "Should only ever obtain data");
   mooseAssert(found_path.data_name, "Should be set");
 
   const std::string msg =
       "Using data file '" + found_path.path + "' from " + *found_path.data_name + " data";
   _parent.mooseInfo(msg);
 
   return found_path.path;
 }

◆ getMooseApp()

MooseApp& MooseBase::getMooseApp ( ) const

inlineinherited

Get the MooseApp this class is associated with.

Definition at line 45 of file MooseBase.h.

Referenced by ChainControlSetupAction::act(), AddDefaultConvergenceAction::addDefaultMultiAppFixedPointConvergence(), AddDefaultConvergenceAction::addDefaultNonlinearConvergence(), FEProblemBase::advanceState(), ParsedChainControl::buildFunction(), ReporterTransferInterface::checkHasReporterValue(), AddDefaultConvergenceAction::checkUnusedMultiAppFixedPointConvergenceParameters(), AddDefaultConvergenceAction::checkUnusedNonlinearConvergenceParameters(), Coupleable::checkWritableVar(), ComponentPhysicsInterface::ComponentPhysicsInterface(), MooseBaseParameterInterface::connectControllableParams(), Coupleable::Coupleable(), MortarData::createMortarInterface(), EigenProblem::doFreeNonlinearPowerIterations(), Terminator::execute(), FEProblemSolve(), SolutionInvalidInterface::flagInvalidSolutionInternal(), ChainControl::getChainControlDataSystem(), DefaultConvergenceBase::getSharedExecutionerParam(), ChainControlDataPostprocessor::initialSetup(), MaterialPropertyInterface::MaterialPropertyInterface(), MooseVariableDataFV< OutputType >::MooseVariableDataFV(), ProgressOutput::output(), PetscOutputInterface::petscLinearOutput(), PetscOutputInterface::petscNonlinearOutput(), PetscOutputInterface::PetscOutputInterface(), PostprocessorInterface::postprocessorsAdded(), MultiApp::preTransfer(), Reporter::Reporter(), ReporterInterface::reportersAdded(), and VectorPostprocessorInterface::vectorPostprocessorsAdded().

45 { return _app; }

MooseBase::_app

MooseApp & _app

The MOOSE application this is associated with.

Definition: MooseBase.h:84

◆ getParam() [1/2]

template<typename T >

const T & MooseBaseParameterInterface::getParam ( const std::string & name ) const

inherited

Retrieve a parameter for the object.

Parameters

name	The name of the parameter

Returns: The value of the parameter

Definition at line 215 of file MooseBaseParameterInterface.h.

 {
   return InputParameters::getParamHelper(name, _pars, static_cast<T *>(0), &_moose_base);
 }

◆ getParam() [2/2]

template<typename T1 , typename T2 >

std::vector< std::pair< T1, T2 > > MooseBaseParameterInterface::getParam	(	const std::string &	param1,
		const std::string &	param2
	)		const

inherited

Retrieve two parameters and provide pair of parameters for the object.

Parameters

param1	The name of first parameter
param2	The name of second parameter

Returns: Vector of pairs of first and second parameters

Definition at line 279 of file MooseBaseParameterInterface.h.

 {
   return _pars.get<T1, T2>(param1, param2);
 }

◆ getParamFromNonlinearSystemVectorParam()

template<typename T >

T FEProblemSolve::getParamFromNonlinearSystemVectorParam	(	const std::string &	param_name,
		unsigned int	index
	)		const

protected

Helper routine to get the nonlinear system parameter at the right index.

If a single value is passed for the parameter, then that value is used

Template Parameters

T	the parameter is of type std::vector<T>

Parameters

param_name	name of the parameter
index	index of the nonlinear system

Returns: parameter for that nonlinear system

Definition at line 386 of file FEProblemSolve.C.

Referenced by FEProblemSolve().

 {
   const auto & param_vec = getParam<std::vector<T>>(param_name);
   if (index > _num_nl_systems)
     paramError(param_name,
                "Vector parameter is requested at index (" + std::to_string(index) +
                    ") which is larger than number of nonlinear systems (" +
                    std::to_string(_num_nl_systems) + ").");
   if (param_vec.size() == 0)
     paramError(
         param_name,
         "This parameter was passed to a routine which cannot handle empty vector parameters");
   if (param_vec.size() != 1 && param_vec.size() != _num_nl_systems)
     paramError(param_name,
                "Vector parameter size (" + std::to_string(param_vec.size()) +
                    ") is different than the number of nonlinear systems (" +
                    std::to_string(_num_nl_systems) + ").");
 
   // User passed only one parameter, assume it applies to all nonlinear systems
   if (param_vec.size() == 1)
     return param_vec[0];
   else
     return param_vec[index];
 }

◆ getPostprocessorName()

const PostprocessorName & PostprocessorInterface::getPostprocessorName	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

Get the name of a postprocessor.

This can only be used if the postprocessor parameter does not have a default value set (see isDefaultPostprocessorValue()), in which case the "name" is actually the default value.

Parameters

param_name	The name of the Postprocessor parameter
index	The index of the Postprocessor

Returns: The name of the given Postprocessor

Definition at line 185 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel().

 {
   return getPostprocessorNameInternal(param_name, index, /* allow_default_value = */ false);
 }

◆ getPostprocessorValue()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValue	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

doco-normal-methods-begin Retrieve the value of a Postprocessor or one of it's old or older values

Parameters

param_name	The name of the Postprocessor parameter (see below)
index	The index of the Postprocessor

Returns: A reference to the desired value

The name required by this method is the name that is hard-coded into your source code. For example, if you have a Kernel that requires a Postprocessor you may have an input file with "pp = my_pp", this function requires the "pp" name as input (see .../moose_test/functions/PostprocessorFunction.C)

see getPostprocessorValueByName getPostprocessorValueOldByName getPostprocessorValueOlderByName

Definition at line 36 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel(), FunctionValuePostprocessor::FunctionValuePostprocessor(), LinearCombinationPostprocessor::LinearCombinationPostprocessor(), and ParsedPostprocessor::ParsedPostprocessor().

 {
   return getPostprocessorValueInternal(param_name, index, /* t_index = */ 0);
 }

◆ getPostprocessorValueByName()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValueByName ( const PostprocessorName & name ) const

virtualinherited

Retrieve the value of the Postprocessor.

Parameters

name	Postprocessor name (see below)

Returns: A reference to the desired value

The name required by this method is the name defined in the input file. For example, if you have a Kernel that requires a Postprocessor you may have an input file with "pp = my_pp", this method requires the "my_pp" name as input (see .../moose_test/functions/PostprocessorFunction.C)

see getPostprocessorValue getPostprocessorValueOld getPostprocessorValueOlder

Definition at line 57 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel(), PIDTransientControl::execute(), IterationAdaptiveDT::IterationAdaptiveDT(), LibtorchNeuralNetControl::LibtorchNeuralNetControl(), ParsedODEKernel::ParsedODEKernel(), SecantSolve::savePostprocessorValues(), SteffensenSolve::savePostprocessorValues(), PicardSolve::savePostprocessorValues(), WebServerControl::startServer(), Terminator::Terminator(), SecantSolve::transformPostprocessors(), SteffensenSolve::transformPostprocessors(), PicardSolve::transformPostprocessors(), and VectorOfPostprocessors::VectorOfPostprocessors().

 {
   return getPostprocessorValueByNameInternal(name, /* t_index = */ 0);
 }

◆ getPostprocessorValueOld()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOld	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

Definition at line 43 of file PostprocessorInterface.C.

 {
   return getPostprocessorValueInternal(param_name, index, /* t_index = */ 1);
 }

◆ getPostprocessorValueOldByName()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOldByName ( const PostprocessorName & name ) const

inherited

Definition at line 63 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel().

 {
   return getPostprocessorValueByNameInternal(name, /* t_index = */ 1);
 }

◆ getPostprocessorValueOlder()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOlder	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

Definition at line 50 of file PostprocessorInterface.C.

 {
   return getPostprocessorValueInternal(param_name, index, /* t_index = */ 2);
 }

◆ getPostprocessorValueOlderByName()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOlderByName ( const PostprocessorName & name ) const

inherited

Definition at line 69 of file PostprocessorInterface.C.

 {
   return getPostprocessorValueByNameInternal(name, /* t_index = */ 2);
 }

◆ getRenamedParam()

template<typename T >

const T & MooseBaseParameterInterface::getRenamedParam	(	const std::string &	old_name,
		const std::string &	new_name
	)		const

inherited

Retrieve a renamed parameter for the object.

This helper makes sure we check both names before erroring, and that only one parameter is passed to avoid silent errors

Parameters

old_name	the old name for the parameter
new_name	the new name for the parameter

Definition at line 229 of file MooseBaseParameterInterface.h.

 {
   // this enables having a default on the new parameter but bypassing it with the old one
   // Most important: accept new parameter
   if (isParamSetByUser(new_name) && !isParamValid(old_name))
     return InputParameters::getParamHelper(new_name, _pars, static_cast<T *>(0), &_moose_base);
   // Second most: accept old parameter
   else if (isParamValid(old_name) && !isParamSetByUser(new_name))
     return InputParameters::getParamHelper(old_name, _pars, static_cast<T *>(0), &_moose_base);
   // Third most: accept default for new parameter
   else if (isParamValid(new_name) && !isParamValid(old_name))
     return InputParameters::getParamHelper(new_name, _pars, static_cast<T *>(0), &_moose_base);
   // Refuse: no default, no value passed
   else if (!isParamValid(old_name) && !isParamValid(new_name))
     mooseError(_pars.blockFullpath() + ": parameter '" + new_name +
                "' is being retrieved without being set.\n"
                "Did you misspell it?");
   // Refuse: both old and new parameters set by user
   else
     mooseError(_pars.blockFullpath() + ": parameter '" + new_name +
                "' may not be provided alongside former parameter '" + old_name + "'");
 }

◆ getSharedPtr() [1/2]

std::shared_ptr< MooseObject > MooseObject::getSharedPtr ( )

inherited

Get another shared pointer to this object that has the same ownership group.

Wrapper around shared_from_this().

Definition at line 68 of file MooseObject.C.

Referenced by MFEMProblem::addBoundaryCondition(), MFEMProblem::addKernel(), and MFEMProblem::addMFEMSolver().

 {
   try
   {
     return shared_from_this();
   }
   catch (std::bad_weak_ptr &)
   {
     mooseError(not_shared_error);
   }
 }

◆ getSharedPtr() [2/2]

std::shared_ptr< const MooseObject > MooseObject::getSharedPtr ( ) const

inherited

Definition at line 81 of file MooseObject.C.

 {
   try
   {
     return shared_from_this();
   }
   catch (std::bad_weak_ptr &)
   {
     mooseError(not_shared_error);
   }
 }

◆ hasPostprocessor()

bool PostprocessorInterface::hasPostprocessor	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

Determine if the Postprocessor data exists.

Parameters

param_name	The name of the Postprocessor parameter
index	The index of the Postprocessor

Returns: True if the Postprocessor exists

See also: hasPostprocessorByName getPostprocessorValue

Definition at line 107 of file PostprocessorInterface.C.

 {
   if (!postprocessorsAdded())
     _ppi_moose_object.mooseError(
         "Cannot call hasPostprocessor() until all Postprocessors have been constructed.");
 
   return hasPostprocessorByName(getPostprocessorNameInternal(param_name, index));
 }

◆ hasPostprocessorByName()

bool PostprocessorInterface::hasPostprocessorByName ( const PostprocessorName & name ) const

inherited

Determine if the Postprocessor data exists.

Parameters

name	The name of the Postprocessor

Returns: True if the Postprocessor exists

See also: hasPostprocessor getPostprocessorValueByName

Definition at line 118 of file PostprocessorInterface.C.

Referenced by PostprocessorInterface::getPostprocessorValueByNameInternal(), PostprocessorInterface::getPostprocessorValueInternal(), PostprocessorInterface::hasPostprocessor(), AdvancedOutput::initShowHideLists(), TableOutput::outputReporters(), Exodus::outputReporters(), and WebServerControl::startServer().

 {
   if (!postprocessorsAdded())
     _ppi_moose_object.mooseError(
         "Cannot call hasPostprocessorByName() until all Postprocessors have been constructed.");
 
   return _ppi_feproblem.getReporterData().hasReporterValue<PostprocessorValue>(
       PostprocessorReporterName(name));
 }

◆ initialSetup()

virtual void SolveObject::initialSetup ( )

inlinevirtualinherited

Method that should be executed once, before any solve calls.

Reimplemented in SteffensenSolve.

Definition at line 32 of file SolveObject.h.

Referenced by SteffensenSolve::initialSetup().

32 {};

◆ isDefaultPostprocessorValue()

bool PostprocessorInterface::isDefaultPostprocessorValue	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

Determine whether or not the Postprocessor is a default value.

A default value is when the value is either the value set by addParam, or is a user-set value in input instead of a name to a postprocessor.

Parameters

param_name	The name of the Postprocessor parameter
index	The index of the postprocessor

Returns: True if the Postprocessor is a default value, false if the Postprocessor is the name of a Postprocessor

Definition at line 75 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel().

 {
   return isDefaultPostprocessorValueByName(getPostprocessorNameInternal(param_name, index));
 }

◆ isParamSetByUser()

bool MooseBaseParameterInterface::isParamSetByUser ( const std::string & nm ) const

inlineinherited

Test if the supplied parameter is set by a user, as opposed to not set or set to default.

Parameters

nm	The name of the parameter to test

Definition at line 128 of file MooseBaseParameterInterface.h.

Referenced by SetupDebugAction::act(), ADConservativeAdvectionBC::ADConservativeAdvectionBC(), DiffusionCG::addFEBCs(), DiffusionPhysicsBase::addInitialConditions(), MFEMMesh::buildMesh(), LibtorchNeuralNetControl::conditionalParameterError(), DiffusionPhysicsBase::DiffusionPhysicsBase(), ElementSubdomainModifierBase::ElementSubdomainModifierBase(), MooseBaseParameterInterface::getRenamedParam(), DefaultConvergenceBase::getSharedExecutionerParam(), AddVariableAction::init(), PhysicsBase::initializePhysics(), ElementSubdomainModifierBase::initialSetup(), MatrixSymmetryCheck::MatrixSymmetryCheck(), MeshDiagnosticsGenerator::MeshDiagnosticsGenerator(), MultiAppGeneralFieldTransfer::MultiAppGeneralFieldTransfer(), SolutionInvalidityOutput::output(), Output::Output(), MultiAppGeneralFieldTransfer::outputValueConflicts(), PetscExternalPartitioner::partition(), PiecewiseTabularBase::PiecewiseTabularBase(), MooseMesh::prepare(), SolutionUserObjectBase::readXda(), PhysicsBase::reportPotentiallyMissedParameters(), MFEMSolverBase::setPreconditioner(), SideSetsFromBoundingBoxGenerator::SideSetsFromBoundingBoxGenerator(), TimedSubdomainModifier::TimedSubdomainModifier(), and XYDelaunayGenerator::XYDelaunayGenerator().

128 { return _pars.isParamSetByUser(nm); }

InputParameters::isParamSetByUser

bool isParamSetByUser(const std::string &name) const

Method returns true if the parameter was set by the user.

Definition: InputParameters.C:1178

MooseBaseParameterInterface::_pars

const InputParameters & _pars

Parameters of this object, references the InputParameters stored in the InputParametersWarehouse.

Definition: MooseBaseParameterInterface.h:173

◆ isParamValid()

bool MooseBaseParameterInterface::isParamValid ( const std::string & name ) const

inlineinherited

Test if the supplied parameter is valid.

Parameters

name	The name of the parameter to test

Definition at line 122 of file MooseBaseParameterInterface.h.

122 { return _pars.isParamValid(name); }

MooseBaseParameterInterface::_pars

const InputParameters & _pars

Parameters of this object, references the InputParameters stored in the InputParametersWarehouse.

Definition: MooseBaseParameterInterface.h:173

InputParameters::isParamValid

bool isParamValid(const std::string &name) const

This method returns parameters that have been initialized in one fashion or another, i.e.

Definition: InputParameters.C:390

◆ mooseDeprecated()

template<typename... Args>

void MooseBaseErrorInterface::mooseDeprecated ( Args &&... args ) const

inlineinherited

Definition at line 91 of file MooseBaseErrorInterface.h.

Referenced by FEProblemBase::addAuxArrayVariable(), FEProblemBase::addAuxScalarVariable(), FEProblemBase::addAuxVariable(), FEProblemBase::advanceMultiApps(), MultiApp::appProblem(), MooseMesh::buildSideList(), ChangeOverTimestepPostprocessor::ChangeOverTimestepPostprocessor(), AddVariableAction::determineType(), EigenProblem::EigenProblem(), Eigenvalue::Eigenvalue(), MooseMesh::elem(), UserForcingFunction::f(), FaceFaceConstraint::FaceFaceConstraint(), FunctionDT::FunctionDT(), RandomICBase::generateRandom(), MooseMesh::getBoundariesToElems(), DataFileInterface::getDataFileName(), DataFileInterface::getDataFileNameByName(), Control::getExecuteOptions(), FEProblemBase::getNonlinearSystem(), FEProblemBase::getUserObjects(), FEProblemBase::hasPostprocessor(), MatDiffusionBase< Real >::MatDiffusionBase(), MultiAppNearestNodeTransfer::MultiAppNearestNodeTransfer(), MultiAppShapeEvaluationTransfer::MultiAppShapeEvaluationTransfer(), MultiAppUserObjectTransfer::MultiAppUserObjectTransfer(), NodalScalarKernel::NodalScalarKernel(), MooseMesh::node(), FixedPointSolve::numPicardIts(), RelationshipManager::operator>=(), PercentChangePostprocessor::PercentChangePostprocessor(), ReferenceResidualConvergence::ReferenceResidualConvergence(), Residual::Residual(), MooseMesh::setBoundaryToNormalMap(), Exodus::setOutputDimension(), and UserForcingFunction::UserForcingFunction().

   {
     moose::internal::mooseDeprecatedStream(
         _console, false, true, _moose_base.errorPrefix("deprecation"), std::forward<Args>(args)...);
   }

◆ mooseDocumentedError()

template<typename... Args>

void MooseBaseErrorInterface::mooseDocumentedError	(	const std::string &	repo_name,
		const unsigned int	issue_num,
		Args &&...	args
	)		const

inlineinherited

Emits a documented error with object name and type.

Documented errors are errors that have an issue associated with them.

The repository name repo_name links a named repository to a URL and should be registered at the application level with registerRepository(). See Moose.C for an example of the "moose" repository registration.

Parameters

repo_name	The repository name where the issue resides
issue_num	The number of the issue
args	The error message to be combined

Definition at line 61 of file MooseBaseErrorInterface.h.

Referenced by ArrayDGLowerDKernel::ArrayDGLowerDKernel(), ArrayHFEMDirichletBC::ArrayHFEMDirichletBC(), ArrayLowerDIntegratedBC::ArrayLowerDIntegratedBC(), DGLowerDKernel::DGLowerDKernel(), HFEMDirichletBC::HFEMDirichletBC(), and LowerDIntegratedBC::LowerDIntegratedBC().

   {
     std::ostringstream oss;
     moose::internal::mooseStreamAll(oss, std::forward<Args>(args)...);
     const auto msg = moose::internal::formatMooseDocumentedError(repo_name, issue_num, oss.str());
     _moose_base.callMooseError(msg, /* with_prefix = */ true);
   }

◆ mooseError()

template<typename... Args>

void MooseBaseErrorInterface::mooseError ( Args &&... args ) const

inlineinherited

Emits an error prefixed with object name and type.

Definition at line 29 of file MooseBaseErrorInterface.h.

   {
     std::ostringstream oss;
     moose::internal::mooseStreamAll(oss, std::forward<Args>(args)...);
     _moose_base.callMooseError(oss.str(), /* with_prefix = */ true);
   }

◆ mooseErrorNonPrefixed()

template<typename... Args>

void MooseBaseErrorInterface::mooseErrorNonPrefixed ( Args &&... args ) const

inlineinherited

Emits an error without the prefixing included in mooseError().

Definition at line 40 of file MooseBaseErrorInterface.h.

   {
     std::ostringstream oss;
     moose::internal::mooseStreamAll(oss, std::forward<Args>(args)...);
     _moose_base.callMooseError(oss.str(), /* with_prefix = */ false);
   }

◆ mooseInfo()

template<typename... Args>

void MooseBaseErrorInterface::mooseInfo ( Args &&... args ) const

inlineinherited

Definition at line 98 of file MooseBaseErrorInterface.h.

Referenced by SetupRecoverFileBaseAction::act(), AStableDirk4::AStableDirk4(), MeshDiagnosticsGenerator::checkNonConformalMeshFromAdaptivity(), MultiAppGeneralFieldNearestLocationTransfer::evaluateInterpValuesNearestNode(), PIDTransientControl::execute(), ExplicitRK2::ExplicitRK2(), ExplicitTVDRK2::ExplicitTVDRK2(), DataFileInterface::getDataFilePath(), MFEMScalarFESpace::getFECName(), MultiAppTransfer::getPointInTargetAppFrame(), ImplicitMidpoint::ImplicitMidpoint(), ParsedDownSelectionPositions::initialize(), PropertyReadFile::initialize(), MultiAppGeneralFieldTransfer::initialSetup(), InversePowerMethod::InversePowerMethod(), LStableDirk2::LStableDirk2(), LStableDirk3::LStableDirk3(), LStableDirk4::LStableDirk4(), PNGOutput::makeMeshFunc(), NonlinearEigen::NonlinearEigen(), SolutionInvalidityOutput::output(), MultiAppGeneralFieldTransfer::outputValueConflicts(), ProjectionAux::ProjectionAux(), ReferenceResidualConvergence::ReferenceResidualConvergence(), MFEMDataCollection::registerFields(), FEProblemBase::setRestartFile(), SolutionUserObjectBase::SolutionUserObjectBase(), and SymmetryTransformGenerator::SymmetryTransformGenerator().

   {
     moose::internal::mooseInfoStream(
         _console, _moose_base.errorPrefix("information"), std::forward<Args>(args)...);
   }

◆ mooseLineSearches()

const std::set< std::string > & FEProblemSolve::mooseLineSearches ( )

static

Definition at line 21 of file FEProblemSolve.C.

Referenced by validParams().

 {
   return _moose_line_searches;
 }

◆ mooseWarning()

template<typename... Args>

void MooseBaseErrorInterface::mooseWarning ( Args &&... args ) const

inlineinherited

Emits a warning prefixed with object name and type.

Definition at line 75 of file MooseBaseErrorInterface.h.

Referenced by CopyMeshPartitioner::_do_partition(), AddKernelAction::act(), MeshOnlyAction::act(), AddFunctionAction::act(), MaterialOutputAction::act(), CommonOutputAction::act(), MFEMProblem::addFunction(), MooseMesh::addPeriodicVariable(), DiracKernelBase::addPoint(), BoundaryMarker::BoundaryMarker(), DistributedRectilinearMeshGenerator::buildCube(), MultiAppVariableValueSamplePostprocessorTransfer::cacheElemToPostprocessorData(), CartesianMeshGenerator::CartesianMeshGenerator(), CheckOutputAction::checkConsoleOutput(), MultiAppTransfer::checkMultiAppExecuteOn(), MeshDiagnosticsGenerator::checkNonMatchingEdges(), ActionComponent::checkRequiredTasks(), PhysicsBase::checkRequiredTasks(), SampledOutput::cloneMesh(), MultiAppGeneralFieldTransfer::closestToPosition(), VariableValueElementSubdomainModifier::computeSubdomainID(), GapValueAux::computeValue(), MultiApp::createApp(), DebugResidualAux::DebugResidualAux(), MeshDiagnosticsGenerator::diagnosticsLog(), CylindricalGridDivision::divisionIndex(), SphericalGridDivision::divisionIndex(), CartesianGridDivision::divisionIndex(), ElementMaterialSampler::ElementMaterialSampler(), Postprocessor::evaluateDotWarning(), MeshDivisionFunctorReductionVectorPostprocessor::execute(), ElementQualityChecker::finalize(), FiniteDifferencePreconditioner::FiniteDifferencePreconditioner(), FixedPointSolve::FixedPointSolve(), SubdomainPerElementGenerator::generate(), StitchedMeshGenerator::generate(), ParsedGenerateSideset::generate(), MultiAppTransfer::getAppInfo(), FunctorBinnedValuesDivision::getBinIndex(), DataFileInterface::getDataFilePath(), PointSamplerBase::getLocalElemContainingPoint(), FEProblemBase::getMaterial(), LineValueSampler::getValue(), Terminator::handleMessage(), IndicatorMarker::IndicatorMarker(), CylindricalGridDivision::initialize(), SphericalGridDivision::initialize(), ElementGroupCentroidPositions::initialize(), CartesianGridDivision::initialize(), MultiAppGeneralFieldNearestLocationTransfer::initialSetup(), BoundsBase::initialSetup(), ReferenceResidualConvergence::initialSetup(), MultiAppGeneralFieldTransfer::initialSetup(), FEProblemBase::initialSetup(), AdvancedOutput::initPostprocessorOrVectorPostprocessorLists(), MaterialBase::initStatefulProperties(), LeastSquaresFit::LeastSquaresFit(), IterationAdaptiveDT::limitDTToPostprocessorValue(), FEProblemBase::mesh(), MultiAppGeneralFieldTransfer::MultiAppGeneralFieldTransfer(), NewmarkBeta::NewmarkBeta(), NodalPatchRecovery::NodalPatchRecovery(), NonlocalIntegratedBC::NonlocalIntegratedBC(), NonlocalKernel::NonlocalKernel(), Output::Output(), MultiAppGeneralFieldTransfer::outputValueConflicts(), PiecewiseConstantFromCSV::PiecewiseConstantFromCSV(), Executioner::problem(), PropertyReadFile::readData(), TestSourceStepper::rejectStep(), PhysicsBase::reportPotentiallyMissedParameters(), MaterialBase::resetQpProperties(), SecondTimeDerivativeAux::SecondTimeDerivativeAux(), MooseMesh::setCoordSystem(), SidesetAroundSubdomainUpdater::SidesetAroundSubdomainUpdater(), FEProblemBase::sizeZeroes(), TransientMultiApp::solveStep(), Tecplot::Tecplot(), TimeDerivativeAux::TimeDerivativeAux(), Checkpoint::updateCheckpointFiles(), SampledOutput::updateSample(), PiecewiseConstantFromCSV::value(), and VariableCondensationPreconditioner::VariableCondensationPreconditioner().

   {
     moose::internal::mooseWarningStream(
         _console, _moose_base.errorPrefix("warning"), std::forward<Args>(args)...);
   }

◆ mooseWarningNonPrefixed()

template<typename... Args>

void MooseBaseErrorInterface::mooseWarningNonPrefixed ( Args &&... args ) const

inlineinherited

Emits a warning without the prefixing included in mooseWarning().

Definition at line 85 of file MooseBaseErrorInterface.h.

   {
     moose::internal::mooseWarningStream(_console, std::forward<Args>(args)...);
   }

◆ name()

virtual const std::string& MooseBase::name ( ) const

inlinevirtualinherited

Get the name of the class.

Returns: The name of the class

Reimplemented in MooseVariableBase.

Definition at line 57 of file MooseBase.h.

57 { return _name; }

MooseBase::_name

const std::string _name

The name of this class.

Definition: MooseBase.h:90

◆ numGridSteps()

unsigned int FEProblemSolve::numGridSteps ( ) const

inline

Return the number of grid sequencing steps.

Definition at line 40 of file FEProblemSolve.h.

Referenced by Eigenvalue::numGridSteps().

40 { return _num_grid_steps; }

FEProblemSolve::_num_grid_steps

const unsigned int _num_grid_steps

The number of steps to perform in a grid sequencing algorithm.

Definition: FEProblemSolve.h:62

◆ paramError()

template<typename... Args>

void MooseBaseParameterInterface::paramError	(	const std::string &	param,
		Args...	args
	)		const

inherited

Emits an error prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message.

If this object's parameters were not created directly by the Parser, then this function falls back to the normal behavior of mooseError - only printing a message using the given args.

Definition at line 255 of file MooseBaseParameterInterface.h.

 {
   Moose::show_trace = false;
   _moose_base.callMooseError(paramErrorMsg(param, std::forward<Args>(args)...),
                              /* with_prefix = */ false);
   Moose::show_trace = true;
 }

◆ parameters()

const InputParameters& MooseBaseParameterInterface::parameters ( ) const

inlineinherited

Get the parameters of the object.

Returns: The parameters of the object

Definition at line 62 of file MooseBaseParameterInterface.h.

62 { return _pars; }

MooseBaseParameterInterface::_pars

const InputParameters & _pars

Parameters of this object, references the InputParameters stored in the InputParametersWarehouse.

Definition: MooseBaseParameterInterface.h:173

◆ paramInfo()

template<typename... Args>

void MooseBaseParameterInterface::paramInfo	(	const std::string &	param,
		Args...	args
	)		const

inherited

Emits an informational message prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message.

If this object's parameters were not created directly by the Parser, then this function falls back to the normal behavior of mooseInfo - only printing a message using the given args.

Definition at line 272 of file MooseBaseParameterInterface.h.

Referenced by GridPartitioner::_do_partition(), ComboMarker::ComboMarker(), FunctorIC::FunctorIC(), and TransientMultiApp::TransientMultiApp().

 {
   mooseInfo(paramErrorMsg(param, std::forward<Args>(args)...));
 }

◆ paramWarning()

template<typename... Args>

void MooseBaseParameterInterface::paramWarning	(	const std::string &	param,
		Args...	args
	)		const

inherited

Emits a warning prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message.

If this object's parameters were not created directly by the Parser, then this function falls back to the normal behavior of mooseWarning - only printing a message using the given args.

Definition at line 265 of file MooseBaseParameterInterface.h.

Referenced by GridPartitioner::_do_partition(), EigenProblem::checkProblemIntegrity(), CombinerGenerator::copyIntoMesh(), DefaultMultiAppFixedPointConvergence::DefaultMultiAppFixedPointConvergence(), MultiAppNearestNodeTransfer::execute(), FEProblemSolve(), UniqueExtraIDMeshGenerator::generate(), PlaneIDMeshGenerator::generate(), Terminator::initialSetup(), SampledOutput::initSample(), MooseMesh::MooseMesh(), FEProblemBase::setPreserveMatrixSparsityPattern(), and Terminator::Terminator().

 {
   mooseWarning(paramErrorMsg(param, std::forward<Args>(args)...));
 }

◆ perfGraph()

PerfGraph & PerfGraphInterface::perfGraph ( )

inherited

Get the PerfGraph.

Definition at line 78 of file PerfGraphInterface.C.

Referenced by CommonOutputAction::act(), PerfGraphData::finalize(), and PerfGraphOutput::output().

 {
   return _pg_moose_app.perfGraph();
 }

◆ queryParam()

template<typename T >

const T * MooseBaseParameterInterface::queryParam ( const std::string & name ) const

inherited

Query a parameter for the object.

If the parameter is not valid, nullptr will be returned

Parameters

name	The name of the parameter

Returns: A pointer to the parameter value, if it exists

Definition at line 222 of file MooseBaseParameterInterface.h.

 {
   return isParamValid(name) ? &getParam<T>(name) : nullptr;
 }

◆ registerTimedSection() [1/2]

PerfID PerfGraphInterface::registerTimedSection	(	const std::string &	section_name,
		const unsigned int	level
	)		const

protectedinherited

Call to register a named section for timing.

Parameters

section_name	The name of the code section to be timed
level	The importance of the timer - lower is more important (0 will always come out)

Returns: The ID of the section - use when starting timing

Definition at line 53 of file PerfGraphInterface.C.

 {
   const auto timed_section_name = timedSectionName(section_name);
   if (!moose::internal::getPerfGraphRegistry().sectionExists(timed_section_name))
     return moose::internal::getPerfGraphRegistry().registerSection(timed_section_name, level);
   else
     return moose::internal::getPerfGraphRegistry().sectionID(timed_section_name);
 }

◆ registerTimedSection() [2/2]

PerfID PerfGraphInterface::registerTimedSection	(	const std::string &	section_name,
		const unsigned int	level,
		const std::string &	live_message,
		const bool	print_dots = `true`
	)		const

protectedinherited

Call to register a named section for timing.

Parameters

section_name	The name of the code section to be timed
level	The importance of the timer - lower is more important (0 will always come out)
live_message	The message to be printed to the screen during execution
print_dots	Whether or not progress dots should be printed for this section

Returns: The ID of the section - use when starting timing

Definition at line 64 of file PerfGraphInterface.C.

 {
   const auto timed_section_name = timedSectionName(section_name);
   if (!moose::internal::getPerfGraphRegistry().sectionExists(timed_section_name))
     return moose::internal::getPerfGraphRegistry().registerSection(
         timedSectionName(section_name), level, live_message, print_dots);
   else
     return moose::internal::getPerfGraphRegistry().sectionID(timed_section_name);
 }

◆ setInnerSolve()

virtual void FEProblemSolve::setInnerSolve ( SolveObject & solve )

inlineoverridevirtual

Set the inner solve object wrapped by this object.

Reimplemented from SolveObject.

Definition at line 32 of file FEProblemSolve.h.

   {
     mooseError("Cannot set inner solve for FEProblemSolve");
   }

◆ solve()

bool FEProblemSolve::solve ( )

overridevirtual

Picard solve the FEProblem.

Returns: True if solver is converged.

Implements SolveObject.

Definition at line 413 of file FEProblemSolve.C.

 {
   // This should be late enough to retrieve the convergence object.
   // TODO: Move this to a setup phase, which does not exist for SolveObjects
   if (isParamValid("multi_system_fixed_point_convergence"))
     _multi_sys_fp_convergence =
         &_problem.getConvergence(getParam<ConvergenceName>("multi_system_fixed_point_convergence"));
 
   // Outer loop for multi-grid convergence
   bool converged = false;
   unsigned int num_fp_multisys_iters = 0;
   for (MooseIndex(_num_grid_steps) grid_step = 0; grid_step <= _num_grid_steps; ++grid_step)
   {
     // Multi-system fixed point loop
     // Use a convergence object if provided, if not, use a reasonable default of every nested system
     // being converged
     num_fp_multisys_iters = 0;
     converged = false;
     while (!converged)
     {
       // Loop over each system
       for (const auto sys : _systems)
       {
         const bool is_nonlinear = (dynamic_cast<NonlinearSystemBase *>(sys) != nullptr);
 
         // Call solve on the problem for that system
         if (is_nonlinear)
           _problem.solve(sys->number());
         else
         {
           const auto linear_sys_number =
               cast_int<unsigned int>(sys->number() - _problem.numNonlinearSystems());
           _problem.solveLinearSystem(linear_sys_number, &_problem.getPetscOptions());
 
           // This is for postprocessing purposes in case none of the objects
           // request the gradients.
           // TODO: Somehow collect information if the postprocessors
           // need gradients and if nothing needs this, just skip it
           _problem.getLinearSystem(linear_sys_number).computeGradients();
         }
 
         // Check convergence
         const auto solve_name =
             _systems.size() == 1 ? " Solve" : "System " + sys->name() + ": Solve";
         if (_problem.shouldSolve())
         {
           if (_problem.converged(sys->number()))
             _console << COLOR_GREEN << solve_name << " Converged!" << COLOR_DEFAULT << std::endl;
           else
           {
             _console << COLOR_RED << solve_name << " Did NOT Converge!" << COLOR_DEFAULT
                      << std::endl;
             return false;
           }
         }
         else
           _console << COLOR_GREEN << solve_name << " Skipped!" << COLOR_DEFAULT << std::endl;
       }
 
       // Assess convergence of the multi-system fixed point iteration
       if (!_using_multi_sys_fp_iterations)
         converged = true;
       else
       {
         converged = _multi_sys_fp_convergence->checkConvergence(num_fp_multisys_iters) ==
                     Convergence::MooseConvergenceStatus::CONVERGED;
         if (_multi_sys_fp_convergence->checkConvergence(num_fp_multisys_iters) ==
             Convergence::MooseConvergenceStatus::DIVERGED)
           break;
       }
       num_fp_multisys_iters++;
     }
 
     if (grid_step != _num_grid_steps)
       _problem.uniformRefine();
   }
 
   if (_multi_sys_fp_convergence)
     return (_multi_sys_fp_convergence->checkConvergence(num_fp_multisys_iters) ==
             Convergence::MooseConvergenceStatus::CONVERGED);
   else
     return converged;
 }

◆ systemsToSolve()

const std::vector<SolverSystem *>& MultiSystemSolveObject::systemsToSolve ( ) const

inlineinherited

Returns a reference to the vector of solver systems that this object is supposed to solve.

Definition at line 30 of file MultiSystemSolveObject.h.

Referenced by Steady::checkIntegrity(), Transient::getTimeIntegrators(), and Transient::relativeSolutionDifferenceNorm().

30 { return _systems; }

MultiSystemSolveObject::_systems

std::vector< SolverSystem * > _systems

Vector of pointers to the systems.

Definition: MultiSystemSolveObject.h:34

◆ timedSectionName()

std::string PerfGraphInterface::timedSectionName ( const std::string & section_name ) const

protectedinherited

Returns: The name of the timed section with the name section_name.

Optionally adds a prefix if one is defined.

Definition at line 47 of file PerfGraphInterface.C.

Referenced by PerfGraphInterface::registerTimedSection().

 {
   return _prefix.empty() ? "" : (_prefix + "::") + section_name;
 }

◆ type()

const std::string& MooseBase::type ( ) const

inlineinherited

Get the type of this class.

Returns: the name of the type of this class

Definition at line 51 of file MooseBase.h.

51 { return _type; }

MooseBase::_type

const std::string _type

The type of this class.

Definition: MooseBase.h:87

◆ typeAndName()

std::string MooseBase::typeAndName ( ) const

inherited

Get the class's combined type and name; useful in error handling.

Returns: The type and name of this class in the form '<type()> "<name()>"'.

Definition at line 27 of file MooseBase.C.

Referenced by MaterialPropertyStorage::addProperty(), MeshGeneratorSystem::dataDrivenError(), ReporterContext< std::vector< T > >::finalize(), and ReporterData::getReporterInfo().

 {
   return type() + std::string(" \"") + name() + std::string("\"");
 }

◆ uniqueName()

MooseObjectName MooseBaseParameterInterface::uniqueName ( ) const

inlineinherited

The unique name for accessing input parameters of this object in the InputParameterWarehouse.

Definition at line 67 of file MooseBaseParameterInterface.h.

Referenced by MooseBaseParameterInterface::connectControllableParams(), and Action::uniqueActionName().

   {
     return MooseObjectName(_pars.get<std::string>("_unique_name"));
   }

◆ uniqueParameterName()

MooseObjectParameterName MooseBaseParameterInterface::uniqueParameterName ( const std::string & parameter_name ) const

inlineinherited

The unique parameter name of a valid parameter of this object for accessing parameter controls.

Definition at line 52 of file MooseBaseParameterInterface.h.

   {
     return MooseObjectParameterName(
         _pars.get<std::string>("_moose_base"), _moose_base.name(), parameter_name);
   }

◆ validParams()

InputParameters FEProblemSolve::validParams ( )

static

Definition at line 61 of file FEProblemSolve.C.

Referenced by Steady::validParams(), Transient::validParams(), EigenExecutionerBase::validParams(), and Eigenvalue::validParams().

 {
   InputParameters params = MultiSystemSolveObject::validParams();
   params += FEProblemSolve::feProblemDefaultConvergenceParams();
 
   params.addParam<std::vector<std::vector<std::string>>>(
       "splitting",
       {},
       "Top-level splitting defining a hierarchical decomposition into "
       "subsystems to help the solver. Outer-vector of this vector-of-vector parameter correspond "
       "to each nonlinear system.");
 
   std::set<std::string> line_searches = mooseLineSearches();
 
   std::set<std::string> alias_line_searches = {"default", "none", "basic"};
   line_searches.insert(alias_line_searches.begin(), alias_line_searches.end());
   std::set<std::string> petsc_line_searches = Moose::PetscSupport::getPetscValidLineSearches();
   line_searches.insert(petsc_line_searches.begin(), petsc_line_searches.end());
   std::string line_search_string = Moose::stringify(line_searches, " ");
   MooseEnum line_search(line_search_string, "default");
   std::string addtl_doc_str(" (Note: none = basic)");
   params.addParam<MooseEnum>(
       "line_search", line_search, "Specifies the line search type" + addtl_doc_str);
   MooseEnum line_search_package("petsc moose", "petsc");
   params.addParam<MooseEnum>("line_search_package",
                              line_search_package,
                              "The solver package to use to conduct the line-search");
 
   params.addParam<unsigned>("contact_line_search_allowed_lambda_cuts",
                             2,
                             "The number of times lambda is allowed to be cut in half in the "
                             "contact line search. We recommend this number be roughly bounded by 0 "
                             "<= allowed_lambda_cuts <= 3");
   params.addParam<Real>("contact_line_search_ltol",
                         "The linear relative tolerance to be used while the contact state is "
                         "changing between non-linear iterations. We recommend that this tolerance "
                         "be looser than the standard linear tolerance");
 
   params += Moose::PetscSupport::getPetscValidParams();
   params.addParam<Real>("l_tol", 1.0e-5, "Linear Relative Tolerance");
   params.addParam<Real>("l_abs_tol", 1.0e-50, "Linear Absolute Tolerance");
   params.addParam<unsigned int>("l_max_its", 10000, "Max Linear Iterations");
   params.addParam<std::vector<ConvergenceName>>(
       "nonlinear_convergence",
       "Name of the Convergence object(s) to use to assess convergence of the "
       "nonlinear system(s) solve. If not provided, the default Convergence "
       "associated with the Problem will be constructed internally.");
   params.addParam<std::vector<ConvergenceName>>(
       "linear_convergence",
       "Name of the Convergence object(s) to use to assess convergence of the "
       "linear system(s) solve. If not provided, the linear solver tolerance parameters are used");
   params.addParam<bool>(
       "snesmf_reuse_base",
       true,
       "Specifies whether or not to reuse the base vector for matrix-free calculation");
   params.addParam<bool>(
       "skip_exception_check", false, "Specifies whether or not to skip exception check");
   params.addParam<bool>("compute_initial_residual_before_preset_bcs",
                         false,
                         "Use the residual norm computed *before* solution modifying objects like "
                         "preset BCs are imposed in relative convergence check.");
   params.deprecateParam(
       "compute_initial_residual_before_preset_bcs", "use_pre_SMO_residual", "12/31/2024");
   params.addParam<bool>(
       "use_pre_SMO_residual",
       false,
       "Compute the pre-SMO residual norm and use it in the relative convergence check. The "
       "pre-SMO residual is computed at the begining of the time step before solution-modifying "
       "objects are executed. Solution-modifying objects include preset BCs, constraints, "
       "predictors, etc.");
   params.addParam<bool>("automatic_scaling", "Whether to use automatic scaling for the variables.");
   params.addParam<std::vector<bool>>(
       "compute_scaling_once",
       {true},
       "Whether the scaling factors should only be computed once at the beginning of the simulation "
       "through an extra Jacobian evaluation. If this is set to false, then the scaling factors "
       "will be computed during an extra Jacobian evaluation at the beginning of every time step. "
       "Vector entries correspond to each nonlinear system.");
   params.addParam<std::vector<bool>>(
       "off_diagonals_in_auto_scaling",
       {false},
       "Whether to consider off-diagonals when determining automatic scaling factors. Vector "
       "entries correspond to each nonlinear system.");
   params.addRangeCheckedParam<std::vector<Real>>(
       "resid_vs_jac_scaling_param",
       {0},
       "0<=resid_vs_jac_scaling_param<=1",
       "A parameter that indicates the weighting of the residual vs the Jacobian in determining "
       "variable scaling parameters. A value of 1 indicates pure residual-based scaling. A value of "
       "0 indicates pure Jacobian-based scaling. Vector entries correspond to each nonlinear "
       "system.");
   params.addParam<std::vector<std::vector<std::vector<std::string>>>>(
       "scaling_group_variables",
       "Name of variables that are grouped together for determining scale factors. (Multiple "
       "groups can be provided, separated by semicolon). Vector entries correspond to each "
       "nonlinear system.");
   params.addParam<std::vector<std::vector<std::string>>>(
       "ignore_variables_for_autoscaling",
       "List of variables that do not participate in autoscaling. Vector entries correspond to each "
       "nonlinear system.");
   params.addRangeCheckedParam<unsigned int>(
       "num_grids",
       1,
       "num_grids>0",
       "The number of grids to use for a grid sequencing algorithm. This includes the final grid, "
       "so num_grids = 1 indicates just one solve in a time-step");
   params.addParam<std::vector<bool>>("residual_and_jacobian_together",
                                      {false},
                                      "Whether to compute the residual and Jacobian together. "
                                      "Vector entries correspond to each nonlinear system.");
 
   params.addParam<bool>("reuse_preconditioner",
                         false,
                         "If true reuse the previously calculated "
                         "preconditioner for the linearized "
                         "system across multiple solves "
                         "spanning nonlinear iterations and time steps. "
                         "The preconditioner resets as controlled by "
                         "reuse_preconditioner_max_linear_its");
   params.addParam<unsigned int>("reuse_preconditioner_max_linear_its",
                                 25,
                                 "Reuse the previously calculated "
                                 "preconditioner for the linear system "
                                 "until the number of linear iterations "
                                 "exceeds this number");
 
   // Multi-system fixed point
   // Defaults to false because of the difficulty of defining a good multi-system convergence
   // criterion, unless we add a default one to the simulation?
   params.addParam<bool>(
       "multi_system_fixed_point",
       false,
       "Whether to perform fixed point (Picard) iterations between the nonlinear systems.");
   params.addParam<ConvergenceName>(
       "multi_system_fixed_point_convergence",
       "Convergence object to determine the convergence of the multi-system fixed point iteration. "
       "If unspecified, defaults to checking that every system is converged (based on their own "
       "convergence criterion)");
 
   params.addParamNamesToGroup("l_tol l_abs_tol l_max_its reuse_preconditioner "
                               "reuse_preconditioner_max_linear_its",
                               "Linear Solver");
   params.addParamNamesToGroup(
       "solve_type snesmf_reuse_base use_pre_SMO_residual "
       "num_grids residual_and_jacobian_together splitting nonlinear_convergence linear_convergence",
       "Nonlinear Solver");
   params.addParamNamesToGroup(
       "automatic_scaling compute_scaling_once off_diagonals_in_auto_scaling "
       "scaling_group_variables resid_vs_jac_scaling_param ignore_variables_for_autoscaling",
       "Solver variable scaling");
   params.addParamNamesToGroup("line_search line_search_package contact_line_search_ltol "
                               "contact_line_search_allowed_lambda_cuts",
                               "Solver line search");
   params.addParamNamesToGroup("multi_system_fixed_point multi_system_fixed_point_convergence",
                               "Multiple solver system");
   params.addParamNamesToGroup("skip_exception_check", "Advanced");
 
   return params;
 }

Member Data Documentation

◆ _action_factory

ActionFactory& MooseBaseParameterInterface::_action_factory

protectedinherited

Builds Actions.

Definition at line 179 of file MooseBaseParameterInterface.h.

Referenced by AddActionComponentAction::act(), CreateMeshSetupActionsForComponents::act(), ActionComponent::checkRequiredTasks(), PhysicsBase::checkRequiredTasks(), CommonOutputAction::create(), AddVariableAction::createInitialConditionAction(), DynamicObjectRegistrationAction::DynamicObjectRegistrationAction(), CreateExecutionerAction::setupAutoPreconditioning(), and ReadExecutorParamsAction::setupAutoPreconditioning().

◆ _app

MooseApp& MooseBase::_app

protectedinherited

The MOOSE application this is associated with.

Definition at line 84 of file MooseBase.h.

◆ _aux

AuxiliarySystem& SolveObject::_aux

protectedinherited

Reference to auxiliary system for faster access.

Definition at line 57 of file SolveObject.h.

◆ _console

const ConsoleStream ConsoleStreamInterface::_console

inherited

An instance of helper class to write streams to the Console objects.

Definition at line 31 of file ConsoleStreamInterface.h.

◆ _displaced_mesh

MooseMesh* SolveObject::_displaced_mesh

protectedinherited

Displaced mesh.

Definition at line 53 of file SolveObject.h.

◆ _displaced_problem

DisplacedProblem* SolveObject::_displaced_problem

protectedinherited

Displaced problem.

Definition at line 49 of file SolveObject.h.

◆ _enabled

const bool& MooseObject::_enabled

protectedinherited

Reference to the "enable" InputParameters, used by Controls for toggling on/off MooseObjects.

Definition at line 51 of file MooseObject.h.

Referenced by MooseObject::enabled().

◆ _executioner

Executioner& SolveObject::_executioner

protectedinherited

Executioner used to construct this.

Definition at line 45 of file SolveObject.h.

Referenced by FixedPointSolve::autoAdvance(), and FixedPointSolve::solveStep().

◆ _factory

Factory& MooseBaseParameterInterface::_factory

protectedinherited

The Factory associated with the MooseApp.

Definition at line 176 of file MooseBaseParameterInterface.h.

Referenced by ElementIDOutputAction::act(), AutoCheckpointAction::act(), CreateExecutionerAction::act(), PartitionerAction::act(), CreateProblemAction::act(), CreateProblemDefaultAction::act(), AdaptivityAction::act(), CombineComponentsMeshes::act(), SetupMeshAction::act(), SetupPredictorAction::act(), SetupTimeStepperAction::act(), ComposeTimeStepperAction::act(), SetupDebugAction::act(), SetupPreconditionerAction::act(), SetupResidualDebugAction::act(), CreateDisplacedProblemAction::act(), MaterialDerivativeTestAction::act(), SetAdaptivityOptionsAction::act(), DisplayGhostingAction::act(), AddControlAction::act(), MaterialOutputAction::act(), AddPeriodicBCAction::act(), CommonOutputAction::act(), AddNodalNormalsAction::act(), ComponentMeshTransformHelper::addMeshGenerators(), CylinderComponent::addMeshGenerators(), DiffusionPhysicsBase::addPostprocessors(), CreateDisplacedProblemAction::addProxyRelationshipManagers(), Action::addRelationshipManager(), SampledOutput::cloneMesh(), MooseBaseParameterInterface::connectControllableParams(), DynamicObjectRegistrationAction::DynamicObjectRegistrationAction(), ActionComponent::getFactory(), PhysicsBase::getFactory(), MaterialOutputAction::getParams(), and ProjectedStatefulMaterialStorageAction::processProperty().

◆ _inner_solve

SolveObject* SolveObject::_inner_solve

protectedinherited

SolveObject wrapped by this solve object.

Definition at line 59 of file SolveObject.h.

Referenced by SolveObject::setInnerSolve(), and FixedPointSolve::solveStep().

◆ _mesh

MooseMesh& SolveObject::_mesh

protectedinherited

Mesh.

Definition at line 51 of file SolveObject.h.

◆ _moose_line_searches

std::set< std::string > const FEProblemSolve::_moose_line_searches = {"contact", "project"}

staticprotected

Moose provided line searches.

Definition at line 54 of file FEProblemSolve.h.

Referenced by FEProblemSolve(), and mooseLineSearches().

◆ _multi_sys_fp_convergence

Convergence* FEProblemSolve::_multi_sys_fp_convergence

protected

Convergence object to assess the convergence of the multi-system fixed point iteration.

Definition at line 67 of file FEProblemSolve.h.

Referenced by solve().

◆ _name

const std::string MooseBase::_name

protectedinherited

The name of this class.

Definition at line 90 of file MooseBase.h.

◆ _num_grid_steps

const unsigned int FEProblemSolve::_num_grid_steps

protected

The number of steps to perform in a grid sequencing algorithm.

This is one less than the number of grids requested by the user in their input, e.g. if they requested num_grids = 1, then there won't be any steps because we only need to perform one solve per time-step. Storing this member in this way allows for easy boolean operations, e.g. if (_num_grid_steps) as opposed to if (_num_grids)

Definition at line 62 of file FEProblemSolve.h.

Referenced by FEProblemSolve(), numGridSteps(), and solve().

◆ _num_nl_systems

unsigned int MultiSystemSolveObject::_num_nl_systems

protectedinherited

Number of nonlinear systems.

Definition at line 37 of file MultiSystemSolveObject.h.

Referenced by getParamFromNonlinearSystemVectorParam(), and MultiSystemSolveObject::MultiSystemSolveObject().

◆ _pars

const InputParameters& MooseBaseParameterInterface::_pars

protectedinherited

Parameters of this object, references the InputParameters stored in the InputParametersWarehouse.

Definition at line 173 of file MooseBaseParameterInterface.h.

◆ _pg_moose_app

MooseApp& PerfGraphInterface::_pg_moose_app

protectedinherited

The MooseApp that owns the PerfGraph.

Definition at line 124 of file PerfGraphInterface.h.

Referenced by PerfGraphInterface::perfGraph().

◆ _prefix

const std::string PerfGraphInterface::_prefix

protectedinherited

A prefix to use for all sections.

Definition at line 127 of file PerfGraphInterface.h.

Referenced by PerfGraphInterface::timedSectionName().

◆ _problem

FEProblemBase& SolveObject::_problem

protectedinherited

Reference to FEProblem.

Definition at line 47 of file SolveObject.h.

Referenced by SecantSolve::allocateStorage(), SteffensenSolve::allocateStorage(), PicardSolve::allocateStorage(), FixedPointSolve::autoAdvance(), FixedPointSolve::examineFixedPointConvergence(), FEProblemSolve(), FixedPointSolve::FixedPointSolve(), SteffensenSolve::initialSetup(), MultiSystemSolveObject::MultiSystemSolveObject(), solve(), FixedPointSolve::solve(), FixedPointSolve::solveStep(), SecantSolve::transformPostprocessors(), SteffensenSolve::transformPostprocessors(), and PicardSolve::transformPostprocessors().

◆ _solver_sys

SystemBase& SolveObject::_solver_sys

protectedinherited

Reference to a system for creating vectors as needed for the solve, etc.

Definition at line 55 of file SolveObject.h.

Referenced by SecantSolve::allocateStorage(), SteffensenSolve::allocateStorage(), PicardSolve::allocateStorage(), SecantSolve::saveVariableValues(), SteffensenSolve::saveVariableValues(), PicardSolve::saveVariableValues(), SecantSolve::transformVariables(), SteffensenSolve::transformVariables(), and PicardSolve::transformVariables().

◆ _systems

std::vector<SolverSystem *> MultiSystemSolveObject::_systems

protectedinherited

Vector of pointers to the systems.

Definition at line 34 of file MultiSystemSolveObject.h.

Referenced by FEProblemSolve(), MultiSystemSolveObject::MultiSystemSolveObject(), solve(), and MultiSystemSolveObject::systemsToSolve().

◆ _type

const std::string MooseBase::_type

protectedinherited

The type of this class.

Definition at line 87 of file MooseBase.h.

Referenced by ExplicitTimeIntegrator::ExplicitTimeIntegrator(), FEProblemSolve(), FillBetweenCurvesGenerator::generate(), FillBetweenPointVectorsGenerator::generate(), FillBetweenSidesetsGenerator::generate(), ExplicitTimeIntegrator::init(), FEProblemBase::init(), MooseStaticCondensationPreconditioner::MooseStaticCondensationPreconditioner(), PhysicsBasedPreconditioner::PhysicsBasedPreconditioner(), FEProblemBase::solverTypeString(), and MooseBase::type().

◆ _using_multi_sys_fp_iterations

const bool FEProblemSolve::_using_multi_sys_fp_iterations

protected

Whether we are using fixed point iterations for multi-system.

Definition at line 65 of file FEProblemSolve.h.

Referenced by FEProblemSolve(), and solve().

The documentation for this class was generated from the following files:

include/executioners/FEProblemSolve.h
src/executioners/FEProblemSolve.C

Public Types

Public Member Functions

Static Public Member Functions

Public Attributes

Protected Member Functions

Protected Attributes

Static Protected Attributes

Detailed Description

Member Typedef Documentation

◆ DataFileParameterType

Constructor & Destructor Documentation

◆ FEProblemSolve()

Member Function Documentation

◆ addPostprocessorDependencyHelper()

◆ callMooseError()

◆ connectControllableParams()

◆ coupledPostprocessors()

◆ enabled()

◆ errorPrefix()

◆ feProblemDefaultConvergenceParams()

◆ getCheckedPointerParam()

◆ getDataFileName()

◆ getDataFileNameByName()

◆ getDataFilePath()

◆ getMooseApp()

◆ getParam() [1/2]

◆ getParam() [2/2]

◆ getParamFromNonlinearSystemVectorParam()

◆ getPostprocessorName()

◆ getPostprocessorValue()

◆ getPostprocessorValueByName()

◆ getPostprocessorValueOld()

◆ getPostprocessorValueOldByName()

◆ getPostprocessorValueOlder()

◆ getPostprocessorValueOlderByName()

◆ getRenamedParam()

◆ getSharedPtr() [1/2]

◆ getSharedPtr() [2/2]

◆ hasPostprocessor()

◆ hasPostprocessorByName()

◆ initialSetup()

◆ isDefaultPostprocessorValue()

◆ isParamSetByUser()

◆ isParamValid()

◆ mooseDeprecated()

◆ mooseDocumentedError()

◆ mooseError()

◆ mooseErrorNonPrefixed()

◆ mooseInfo()

◆ mooseLineSearches()

◆ mooseWarning()

◆ mooseWarningNonPrefixed()

◆ name()

◆ numGridSteps()

◆ paramError()

◆ parameters()

◆ paramInfo()

◆ paramWarning()

◆ perfGraph()

◆ queryParam()

◆ registerTimedSection() [1/2]

◆ registerTimedSection() [2/2]

◆ setInnerSolve()

◆ solve()

◆ systemsToSolve()

◆ timedSectionName()

◆ type()

◆ typeAndName()

◆ uniqueName()

◆ uniqueParameterName()

◆ validParams()

Member Data Documentation

◆ _action_factory

◆ _app

◆ _aux

◆ _console

◆ _displaced_mesh

◆ _displaced_problem

◆ _enabled

◆ _executioner