TriPinHexAssemblyGenerator Class Reference

This TriPinHexAssemblyGenerator object is a base class to be inherited for polygon mesh generators. More...

#include <TriPinHexAssemblyGenerator.h>

Inheritance diagram for TriPinHexAssemblyGenerator:

Public Types
enum	PolygonSizeStyle { PolygonSizeStyle::apothem, PolygonSizeStyle::radius }
	An enum class for style of input polygon size. More...
enum	MESH_TYPE { CORNER_MESH = 1, BOUNDARY_MESH = 2, INNER_MESH = 3 }
enum	RETURN_TYPE { ANGLE_DEGREE = 1, ANGLE_TANGENT = 2 }
enum	INTRISIC_SUBDOMAIN_ID : subdomain_id_type { PERIPHERAL_ID_SHIFT = 1000, TRANSITION_LAYER_DEFAULT = 10000 }
enum	INTRINSIC_SIDESET_ID : boundary_id_type {   OUTER_SIDESET_ID = 10000, OUTER_SIDESET_ID_ALT = 15000, SLICE_BEGIN = 30000, SLICE_END = 31000,   SLICE_ALT = 30500 }
enum	INTRINSIC_NUM_SIDES { HEXAGON_NUM_SIDES = 6, SQUARE_NUM_SIDES = 4 }
enum	TRI_ELEM_TYPE { TRI_ELEM_TYPE::TRI3, TRI_ELEM_TYPE::TRI6, TRI_ELEM_TYPE::TRI7 }
enum	QUAD_ELEM_TYPE { QUAD_ELEM_TYPE::QUAD4, QUAD_ELEM_TYPE::QUAD8, QUAD_ELEM_TYPE::QUAD9 }
typedef DataFileName	DataFileParameterType

Public Member Functions
	TriPinHexAssemblyGenerator (const InputParameters &parameters)
std::unique_ptr< MeshBase >	generate () override
std::unique_ptr< MeshBase >	generateInternal ()
const std::set< MeshGeneratorName > &	getRequestedMeshGenerators () const
const std::set< MeshGeneratorName > &	getRequestedMeshGeneratorsForSub () const
void	addParentMeshGenerator (const MeshGenerator &mg, const AddParentChildKey)
void	addChildMeshGenerator (const MeshGenerator &mg, const AddParentChildKey)
const std::set< const MeshGenerator *, Comparator > &	getParentMeshGenerators () const
const std::set< const MeshGenerator *, Comparator > &	getChildMeshGenerators () const
const std::set< const MeshGenerator *, Comparator > &	getSubMeshGenerators () const
bool	isParentMeshGenerator (const MeshGeneratorName &name, const bool direct=true) const
bool	isChildMeshGenerator (const MeshGeneratorName &name, const bool direct=true) const
bool	isNullMeshName (const MeshGeneratorName &name) const
bool	hasSaveMesh () const
bool	hasOutput () const
const std::string &	getSavedMeshName () const
bool	hasGenerateData () const
bool	isDataOnly () const
virtual bool	enabled () const
std::shared_ptr< MooseObject >	getSharedPtr ()
std::shared_ptr< const MooseObject >	getSharedPtr () const
MooseApp &	getMooseApp () const
const std::string &	type () const
virtual const std::string &	name () const
std::string	typeAndName () const
std::string	errorPrefix (const std::string &error_type) const
void	callMooseError (std::string msg, const bool with_prefix) const
MooseObjectParameterName	uniqueParameterName (const std::string &parameter_name) const
const InputParameters &	parameters () const
MooseObjectName	uniqueName () const
const T &	getParam (const std::string &name) const
std::vector< std::pair< T1, T2 > >	getParam (const std::string &param1, const std::string &param2) const
const T *	queryParam (const std::string &name) const
const T &	getRenamedParam (const std::string &old_name, const std::string &new_name) const
T	getCheckedPointerParam (const std::string &name, const std::string &error_string="") const
bool	isParamValid (const std::string &name) const
bool	isParamSetByUser (const std::string &nm) const
void	paramError (const std::string &param, Args... args) const
void	paramWarning (const std::string &param, Args... args) const
void	paramInfo (const std::string &param, Args... args) const
void	connectControllableParams (const std::string &parameter, const std::string &object_type, const std::string &object_name, const std::string &object_parameter) const
void	mooseError (Args &&... args) const
void	mooseErrorNonPrefixed (Args &&... args) const
void	mooseDocumentedError (const std::string &repo_name, const unsigned int issue_num, Args &&... args) const
void	mooseWarning (Args &&... args) const
void	mooseWarningNonPrefixed (Args &&... args) const
void	mooseDeprecated (Args &&... args) const
void	mooseInfo (Args &&... args) const
std::string	getDataFileName (const std::string &param) const
std::string	getDataFileNameByName (const std::string &relative_path) const
std::string	getDataFilePath (const std::string &relative_path) const
const Parallel::Communicator &	comm () const
processor_id_type	n_processors () const
processor_id_type	processor_id () const

Static Public Member Functions
static InputParameters	validParams ()
static bool	hasGenerateData (const InputParameters &params)
static void	setHasGenerateData (InputParameters &params)

Public Attributes
const ConsoleStream	_console

Static Public Attributes
static const std::string	data_only_param
static constexpr auto	SYSTEM
static constexpr auto	NAME

Protected Types
enum	AssmOrient { AssmOrient::pin_up, AssmOrient::pin_down }
	Assembly orientation option. More...

Protected Member Functions
std::unique_ptr< ReplicatedMesh >	buildSinglePinSection (const Real side_length, const Real ring_offset, const std::vector< Real > ring_radii, const std::vector< unsigned int > ring_intervals, const bool has_rings, const bool preserve_volumes, const unsigned int num_sectors_per_side, const unsigned int background_intervals, const std::vector< subdomain_id_type > block_ids_new, dof_id_type &node_id_background_meta)
	Generates a single-pin diamond section mesh, which is one-third of the triple-pin hexagonal assembly mesh. More...
std::unique_ptr< ReplicatedMesh >	buildSimpleSlice (std::vector< Real > ring_radii, const std::vector< unsigned int > ring_layers, const std::vector< Real > ring_radial_biases, const multiBdryLayerParams &ring_inner_boundary_layer_params, const multiBdryLayerParams &ring_outer_boundary_layer_params, std::vector< Real > ducts_center_dist, const std::vector< unsigned int > ducts_layers, const std::vector< Real > duct_radial_biases, const multiBdryLayerParams &duct_inner_boundary_layer_params, const multiBdryLayerParams &duct_outer_boundary_layer_params, const Real pitch, const unsigned int num_sectors_per_side, const unsigned int background_intervals, const Real background_radial_bias, const singleBdryLayerParams &background_inner_boundary_layer_params, const singleBdryLayerParams &background_outer_boundary_layer_params, dof_id_type &node_id_background_meta, const unsigned int side_number, const unsigned int side_index, const std::vector< Real > azimuthal_tangent=std::vector< Real >(), const subdomain_id_type block_id_shift=0, const bool quad_center_elements=false, const Real center_quad_factor=0.0, const bool create_inward_interface_boundaries=false, const bool create_outward_interface_boundaries=true, const boundary_id_type boundary_id_shift=0, const bool generate_side_specific_boundaries=true, const TRI_ELEM_TYPE tri_elem_type=TRI_ELEM_TYPE::TRI3, const QUAD_ELEM_TYPE quad_elem_type=QUAD_ELEM_TYPE::QUAD4)
	Creates a mesh of a slice that corresponds to a single side of the polygon to be generated. More...
std::unique_ptr< ReplicatedMesh >	buildGeneralSlice (std::vector< Real > ring_radii, const std::vector< unsigned int > ring_layers, const std::vector< Real > ring_radial_biases, const multiBdryLayerParams &ring_inner_boundary_layer_params, const multiBdryLayerParams &ring_outer_boundary_layer_params, std::vector< Real > ducts_center_dist, const std::vector< unsigned int > ducts_layers, const std::vector< Real > duct_radial_biases, const multiBdryLayerParams &duct_inner_boundary_layer_params, const multiBdryLayerParams &duct_outer_boundary_layer_params, const Real primary_side_length, const Real secondary_side_length, const unsigned int num_sectors_per_side, const unsigned int background_intervals, const Real background_radial_bias, const singleBdryLayerParams &background_inner_boundary_layer_params, const singleBdryLayerParams &background_outer_boundary_layer_params, dof_id_type &node_id_background_meta, const Real azimuthal_angle, const std::vector< Real > azimuthal_tangent, const unsigned int side_index, const bool quad_center_elements, const Real center_quad_factor, const Real rotation_angle, const bool generate_side_specific_boundaries=true)
	Creates a mesh of a general polygon slice with a triangular shape and circular regions on one of its vertex. More...
std::unique_ptr< ReplicatedMesh >	buildSlice (std::vector< Real > ring_radii, const std::vector< unsigned int > ring_layers, const std::vector< Real > ring_radial_biases, const multiBdryLayerParams &ring_inner_boundary_layer_params, const multiBdryLayerParams &ring_outer_boundary_layer_params, std::vector< Real > ducts_center_dist, const std::vector< unsigned int > ducts_layers, const std::vector< Real > duct_radial_biases, const multiBdryLayerParams &duct_inner_boundary_layer_params, const multiBdryLayerParams &duct_outer_boundary_layer_params, const Real pitch, const unsigned int num_sectors_per_side, const unsigned int background_intervals, const Real background_radial_bias, const singleBdryLayerParams &background_inner_boundary_layer_params, const singleBdryLayerParams &background_outer_boundary_layer_params, dof_id_type &node_id_background_meta, const Real virtual_side_number, const unsigned int side_index, const std::vector< Real > azimuthal_tangent=std::vector< Real >(), const subdomain_id_type block_id_shift=0, const bool quad_center_elements=false, const Real center_quad_factor=0.0, const bool create_inward_interface_boundaries=false, const bool create_outward_interface_boundaries=true, const boundary_id_type boundary_id_shift=0, const Real pitch_scale_factor=1.0, const bool generate_side_specific_boundaries=true, const TRI_ELEM_TYPE tri_elem_type=TRI_ELEM_TYPE::TRI3, const QUAD_ELEM_TYPE quad_elem_type=QUAD_ELEM_TYPE::QUAD4)
	Generates a mesh of a polygon slice, which is the foundation of both buildGeneralSlice and buildSimpleSlice. More...
void	centerNodes (ReplicatedMesh &mesh, const Real virtual_side_number, const unsigned int div_num, const Real ring_radii_0, std::vector< std::vector< Node *>> &nodes) const
	Creates nodes of the very central mesh layer of the polygon for quad central elements. More...
void	ringNodes (ReplicatedMesh &mesh, const std::vector< Real > ring_radii, const std::vector< unsigned int > ring_layers, const std::vector< std::vector< Real >> biased_terms, const unsigned int num_sectors_per_side, const Real corner_p[2][2], const Real corner_to_corner, const std::vector< Real > azimuthal_tangent=std::vector< Real >()) const
	Creates nodes for the ring-geometry region of a single slice. More...
void	backgroundNodes (ReplicatedMesh &mesh, const unsigned int num_sectors_per_side, const unsigned int background_intervals, const std::vector< Real > biased_terms, const Real background_corner_distance, const Real background_corner_radial_interval_length, const Real corner_p[2][2], const Real corner_to_corner, const Real background_in, const std::vector< Real > azimuthal_tangent=std::vector< Real >()) const
	Creates nodes for the ring-to-polygon transition region (i.e., background) of a single slice. More...
void	ductNodes (ReplicatedMesh &mesh, std::vector< Real > *const ducts_center_dist, const std::vector< unsigned int > ducts_layers, const std::vector< std::vector< Real >> biased_terms, const unsigned int num_sectors_per_side, const Real corner_p[2][2], const Real corner_to_corner, const std::vector< Real > azimuthal_tangent=std::vector< Real >()) const
	Creates nodes for the duct-geometry region of a single slice. More...
void	cenQuadElemDef (ReplicatedMesh &mesh, const unsigned int div_num, const subdomain_id_type block_id_shift, const bool create_outward_interface_boundaries, const boundary_id_type boundary_id_shift, std::vector< std::vector< Node *>> &nodes, const bool assign_external_boundary=false, const unsigned int side_index=0, const bool generate_side_specific_boundaries=true, const QUAD_ELEM_TYPE quad_elem_type=QUAD_ELEM_TYPE::QUAD4) const
	Defines quad elements in the very central region of the polygon. More...
void	cenTriElemDef (ReplicatedMesh &mesh, const unsigned int num_sectors_per_side, const std::vector< Real > azimuthal_tangent=std::vector< Real >(), const subdomain_id_type block_id_shift=0, const bool create_outward_interface_boundaries=true, const boundary_id_type boundary_id_shift=0, const bool assign_external_boundary=false, const unsigned int side_index=0, const bool generate_side_specific_boundaries=true, const TRI_ELEM_TYPE tri_elem_type=TRI_ELEM_TYPE::TRI3) const
	Defines triangular elements in the very central region of the polygon. More...
void	quadElemDef (ReplicatedMesh &mesh, const unsigned int num_sectors_per_side, const std::vector< unsigned int > subdomain_rings, const unsigned int side_index, const std::vector< Real > azimuthal_tangent=std::vector< Real >(), const subdomain_id_type block_id_shift=0, const dof_id_type nodeid_shift=0, const bool create_inward_interface_boundaries=false, const bool create_outward_interface_boundaries=true, const boundary_id_type boundary_id_shift=0, const bool generate_side_specific_boundaries=true, const QUAD_ELEM_TYPE quad_elem_type=QUAD_ELEM_TYPE::QUAD4) const
	Defines general quad elements for the polygon. More...
std::unique_ptr< ReplicatedMesh >	buildSimplePeripheral (const unsigned int num_sectors_per_side, const unsigned int peripheral_invervals, const std::vector< std::pair< Real, Real >> &position_inner, const std::vector< std::pair< Real, Real >> &d_position_outer, const subdomain_id_type id_shift, const QUAD_ELEM_TYPE quad_elem_type, const bool create_inward_interface_boundaries=false, const bool create_outward_interface_boundaries=true)
	Creates peripheral area mesh for the patterned hexagon mesh. More...
void	adjustPeripheralQuadraticElements (MeshBase &out_mesh, const QUAD_ELEM_TYPE boundary_quad_elem_type) const
	Adjusts the mid-edge node locations in boundary regions when using quadratic elements with uniform boundary node spacing enabled. More...
std::pair< Real, Real >	pointInterpolate (const Real pi_1_x, const Real pi_1_y, const Real po_1_x, const Real po_1_y, const Real pi_2_x, const Real pi_2_y, const Real po_2_x, const Real po_2_y, const unsigned int i, const unsigned int j, const unsigned int num_sectors_per_side, const unsigned int peripheral_intervals) const
	Calculates the point coordinates of within a parallelogram region using linear interpolation. More...
void	nodeCoordRotate (Real &x, Real &y, const Real theta) const
	Calculates x and y coordinates after rotating by theta angle. More...
void	cutOffPolyDeform (MeshBase &mesh, const Real orientation, const Real y_max_0, const Real y_max_n, const Real y_min, const unsigned int mesh_type, const Real unit_angle=60.0, const Real tols=1E-5) const
	Deforms peripheral region when the external side of a polygon assembly of stitched meshes cuts off the stitched meshes. More...
std::pair< Real, Real >	fourPointIntercept (const std::pair< Real, Real > &p1, const std::pair< Real, Real > &p2, const std::pair< Real, Real > &p3, const std::pair< Real, Real > &p4) const
	Finds the center of a quadrilateral based on four vertices. More...
std::vector< Real >	azimuthalAnglesCollector (ReplicatedMesh &mesh, std::vector< Point > &boundary_points, const Real lower_azi=-30.0, const Real upper_azi=30.0, const unsigned int return_type=ANGLE_TANGENT, const unsigned int num_sides=6, const boundary_id_type bid=OUTER_SIDESET_ID, const bool calculate_origin=true, const Real input_origin_x=0.0, const Real input_origin_y=0.0, const Real tol=1.0E-10) const
	Collects sorted azimuthal angles of the external boundary. More...
std::vector< Real >	azimuthalAnglesCollector (ReplicatedMesh &mesh, const Real lower_azi=-30.0, const Real upper_azi=30.0, const unsigned int return_type=ANGLE_TANGENT, const unsigned int num_sides=6, const boundary_id_type bid=OUTER_SIDESET_ID, const bool calculate_origin=true, const Real input_origin_x=0.0, const Real input_origin_y=0.0, const Real tol=1.0E-10) const
	Collects sorted azimuthal angles of the external boundary. More...
std::vector< std::vector< Real > >	biasTermsCalculator (const std::vector< Real > radial_biases, const std::vector< unsigned int > intervals, const multiBdryLayerParams inner_boundary_layer_params, const multiBdryLayerParams outer_boundary_layer_params) const
	Creates bias terms for multiple blocks. More...
std::vector< Real >	biasTermsCalculator (const Real radial_bias, const unsigned int intervals, const singleBdryLayerParams inner_boundary_layer_params={0.0, 0.0, 0, 1.0}, const singleBdryLayerParams outer_boundary_layer_params={0.0, 0.0, 0, 1.0}) const
	Creates bias terms for a single block. More...
void	setSectorExtraIDs (MeshBase &mesh, const std::string id_name, const unsigned int num_sides, const std::vector< unsigned int > num_sectors_per_side)
	assign sector extra ids to polygon mesh More...
void	setRingExtraIDs (MeshBase &mesh, const std::string id_name, const unsigned int num_sides, const std::vector< unsigned int > num_sectors_per_side, const std::vector< unsigned int > ring_intervals, const bool ring_wise_id, const bool quad_center_elements)
	assign ring extra ids to polygon mesh More...
void	reassignBoundaryIDs (MeshBase &mesh, const boundary_id_type id_shift, const std::set< boundary_id_type > &boundary_ids, const bool reverse=false)
	reassign interface boundary IDs on the input mesh by applying the boundary ID shift More...
std::set< boundary_id_type >	getInterfaceBoundaryIDs (const std::vector< std::vector< unsigned int >> &pattern, const std::vector< std::vector< boundary_id_type >> &interface_boundary_id_shift_pattern, const std::set< boundary_id_type > &boundary_ids, const std::vector< std::set< boundary_id_type >> &input_interface_boundary_ids, const bool use_interface_boundary_id_shift, const bool create_interface_boundary_id, const unsigned int num_extra_layers) const
	returns a list of interface boundary IDs on the mesh generated by this mesh generator More...
multiBdryLayerParams	modifiedMultiBdryLayerParamsCreator (const multiBdryLayerParams &original_multi_bdry_layer_params, const unsigned int order) const
	Modifies the input multi boundary layer parameters for node generation, especially for the quadratic elements. More...
singleBdryLayerParams	modifiedSingleBdryLayerParamsCreator (const singleBdryLayerParams &original_single_bdry_layer_params, const unsigned int order) const
	Modifies the input single boundary layer parameters for node generation, especially for the quadratic elements. More...
std::string	pitchMetaDataErrorGenerator (const std::vector< MeshGeneratorName > &input_names, const std::vector< Real > &metadata_vals, const std::string &metadata_name) const
	Generate a string that contains the detailed metadata information for inconsistent input mesh metadata error messages. More...
virtual void	generateData ()
T &	copyMeshProperty (const std::string &target_data_name, const std::string &source_data_name, const std::string &source_mesh)
T &	copyMeshProperty (const std::string &source_data_name, const std::string &source_mesh)
std::unique_ptr< MeshBase > &	getMesh (const std::string &param_name, const bool allow_invalid=false)
std::vector< std::unique_ptr< MeshBase > *>	getMeshes (const std::string &param_name)
std::unique_ptr< MeshBase > &	getMeshByName (const MeshGeneratorName &mesh_generator_name)
std::vector< std::unique_ptr< MeshBase > *>	getMeshesByName (const std::vector< MeshGeneratorName > &mesh_generator_names)
void	declareMeshForSub (const std::string &param_name)
void	declareMeshesForSub (const std::string &param_name)
void	declareMeshForSubByName (const MeshGeneratorName &mesh_generator_name)
void	declareMeshesForSubByName (const std::vector< MeshGeneratorName > &mesh_generator_names)
std::unique_ptr< MeshBase >	buildMeshBaseObject (unsigned int dim=libMesh::invalid_uint)
std::unique_ptr< ReplicatedMesh >	buildReplicatedMesh (unsigned int dim=libMesh::invalid_uint)
std::unique_ptr< DistributedMesh >	buildDistributedMesh (unsigned int dim=libMesh::invalid_uint)
void	addMeshSubgenerator (const std::string &type, const std::string &name, Ts... extra_input_parameters)
void	addMeshSubgenerator (const std::string &type, const std::string &name, InputParameters params)
void	declareNullMeshName (const MeshGeneratorName &name)
const T &	getMeshProperty (const std::string &data_name, const std::string &prefix)
const T &	getMeshProperty (const std::string &data_name)
bool	hasMeshProperty (const std::string &data_name, const std::string &prefix) const
bool	hasMeshProperty (const std::string &data_name, const std::string &prefix) const
bool	hasMeshProperty (const std::string &data_name) const
bool	hasMeshProperty (const std::string &data_name) const
std::string	meshPropertyName (const std::string &data_name) const
T &	declareMeshProperty (const std::string &data_name, Args &&... args)
T &	declareMeshProperty (const std::string &data_name, const T &data_value)
T &	declareMeshProperty (const std::string &data_name, Args &&... args)
T &	declareMeshProperty (const std::string &data_name, const T &data_value)
T &	setMeshProperty (const std::string &data_name, Args &&... args)
T &	setMeshProperty (const std::string &data_name, const T &data_value)
T &	setMeshProperty (const std::string &data_name, Args &&... args)
T &	setMeshProperty (const std::string &data_name, const T &data_value)

Static Protected Member Functions
static void	addRingAndSectorIDParams (InputParameters &params)
	Add InputParameters which are used by ring and sector IDs. More...
static std::string	meshPropertyName (const std::string &data_name, const std::string &prefix)

Protected Attributes
const std::vector< std::vector< Real > >	_ring_radii
	Radii of concentric circles in the three diamond sections. More...
const std::vector< bool >	_has_rings
	Whether the generated mesh contains ring regions. More...
const std::vector< std::vector< unsigned int > >	_ring_intervals
	Numbers of radial layers in each ring region in the three diamond sections. More...
const std::vector< std::vector< subdomain_id_type > >	_ring_block_ids
	Block ids of the ring regions in the three diamond sections. More...
const std::vector< std::vector< SubdomainName > >	_ring_block_names
	Block names of the ring regions in the three diamond sections. More...
const PolygonSizeStyle	_hexagon_size_style
	Type of hexagon_size parameter. More...
const Real	_side_length
	Length of the side of the hexagon. More...
const Real	_ring_offset
	Offset distance of the circle centers from the center of each diamond section. More...
const bool	_preserve_volumes
	Whether the radii need to be corrected for polygonization during meshing. More...
enum TriPinHexAssemblyGenerator::AssmOrient	_assembly_orientation
const unsigned int	_num_sectors_per_side
	Mesh sector number of each polygon side. More...
const unsigned int	_background_intervals
	Numbers of radial intervals of the background regions. More...
const std::vector< subdomain_id_type >	_background_block_ids
	Block ids of the background region. More...
const std::vector< SubdomainName >	_background_block_names
	Block names of the background region. More...
const boundary_id_type	_external_boundary_id
	Boundary ID of mesh's external boundary. More...
const std::string	_external_boundary_name
	Boundary name of mesh's external boundary. More...
const std::string	_pin_id_name
	Name of extra integer ID to be assigned to each of the three pin domains. More...
const std::vector< dof_id_type >	_pin_id_values
	Values of extra integer ID to be assigned to each of the three pin domains. More...
dof_id_type &	_node_id_background_meta
	MeshMetaData: maximum node id of the background region. More...
MooseMesh *const	_mesh
const bool &	_enabled
MooseApp &	_app
const std::string	_type
const std::string	_name
const InputParameters &	_pars
Factory &	_factory
ActionFactory &	_action_factory
const Parallel::Communicator &	_communicator

Private Member Functions
template<typename T >
std::vector< std::vector< T > >	getRingParamValues (const std::string &param_name) const
	Helper for getting a parameter that describes rings. More...

Detailed Description

This TriPinHexAssemblyGenerator object is a base class to be inherited for polygon mesh generators.

Definition at line 18 of file TriPinHexAssemblyGenerator.h.

Member Enumeration Documentation

AssmOrient

enum TriPinHexAssemblyGenerator::AssmOrient

strongprotected

Assembly orientation option.

Enumerator
pin_up
pin_down

Definition at line 47 of file TriPinHexAssemblyGenerator.h.

{ pin_up, pin_down } _assembly_orientation;

INTRINSIC_NUM_SIDES

enum PolygonMeshGeneratorBase::INTRINSIC_NUM_SIDES

inherited

Enumerator
HEXAGON_NUM_SIDES
SQUARE_NUM_SIDES

Definition at line 75 of file PolygonMeshGeneratorBase.h.

  {
    HEXAGON_NUM_SIDES = 6,
    SQUARE_NUM_SIDES = 4
  };

INTRINSIC_SIDESET_ID

enum PolygonMeshGeneratorBase::INTRINSIC_SIDESET_ID : boundary_id_type

inherited

Enumerator
OUTER_SIDESET_ID
OUTER_SIDESET_ID_ALT
SLICE_BEGIN
SLICE_END
SLICE_ALT

Definition at line 66 of file PolygonMeshGeneratorBase.h.

                            : boundary_id_type
  {
    OUTER_SIDESET_ID = 10000,
    OUTER_SIDESET_ID_ALT = 15000,
    SLICE_BEGIN = 30000,
    SLICE_END = 31000,
    SLICE_ALT = 30500
  };

INTRISIC_SUBDOMAIN_ID

enum PolygonMeshGeneratorBase::INTRISIC_SUBDOMAIN_ID : subdomain_id_type

inherited

Enumerator
PERIPHERAL_ID_SHIFT
TRANSITION_LAYER_DEFAULT

Definition at line 60 of file PolygonMeshGeneratorBase.h.

                             : subdomain_id_type
  {
    PERIPHERAL_ID_SHIFT = 1000,
    TRANSITION_LAYER_DEFAULT = 10000
  };

MESH_TYPE

enum PolygonMeshGeneratorBase::MESH_TYPE

inherited

Enumerator
CORNER_MESH
BOUNDARY_MESH
INNER_MESH

Definition at line 47 of file PolygonMeshGeneratorBase.h.

  {
    CORNER_MESH = 1,
    BOUNDARY_MESH = 2,
    INNER_MESH = 3
  };

PolygonSizeStyle

enum PolygonMeshGeneratorBase::PolygonSizeStyle

stronginherited

An enum class for style of input polygon size.

Enumerator
apothem
radius

Definition at line 41 of file PolygonMeshGeneratorBase.h.

  {
    apothem,
    radius
  };

QUAD_ELEM_TYPE

enum PolygonMeshGeneratorBase::QUAD_ELEM_TYPE

stronginherited

Enumerator
QUAD4
QUAD8
QUAD9

Definition at line 88 of file PolygonMeshGeneratorBase.h.

  {
    QUAD4,
    QUAD8,
    QUAD9
  };

RETURN_TYPE

enum PolygonMeshGeneratorBase::RETURN_TYPE

inherited

Enumerator
ANGLE_DEGREE
ANGLE_TANGENT

Definition at line 54 of file PolygonMeshGeneratorBase.h.

  {
    ANGLE_DEGREE = 1,
    ANGLE_TANGENT = 2
  };

TRI_ELEM_TYPE

enum PolygonMeshGeneratorBase::TRI_ELEM_TYPE

stronginherited

Enumerator
TRI3
TRI6
TRI7

Definition at line 81 of file PolygonMeshGeneratorBase.h.

  {
    TRI3,
    TRI6,
    TRI7
  };

Constructor & Destructor Documentation

TriPinHexAssemblyGenerator()

TriPinHexAssemblyGenerator::TriPinHexAssemblyGenerator

(

const InputParameters &

parameters

)

Definition at line 82 of file TriPinHexAssemblyGenerator.C.

  : PolygonMeshGeneratorBase(parameters),
    _ring_radii(getRingParamValues<Real>("ring_radii")),
    _has_rings({!_ring_radii[0].empty(), !_ring_radii[1].empty(), !_ring_radii[2].empty()}),
    _ring_intervals(getRingParamValues<unsigned int>("ring_intervals")),
    _ring_block_ids(getRingParamValues<subdomain_id_type>("ring_block_ids")),
    _ring_block_names(
        isParamValid("ring_block_names")
            ? (getParam<std::vector<std::vector<SubdomainName>>>("ring_block_names").size() == 1
                   ? std::vector<std::vector<SubdomainName>>(
                         3,
                         getParam<std::vector<std::vector<SubdomainName>>>("ring_block_names")
                             .front())
                   : getParam<std::vector<std::vector<SubdomainName>>>("ring_block_names"))
            : std::vector<std::vector<SubdomainName>>(3, std::vector<SubdomainName>())),
    _hexagon_size_style(
        getParam<MooseEnum>("hexagon_size_style").template getEnum<PolygonSizeStyle>()),
    _side_length(_hexagon_size_style == PolygonSizeStyle::radius
                     ? getParam<Real>("hexagon_size")
                     : (getParam<Real>("hexagon_size") / cos(M_PI / 6.0))),
    _ring_offset(getParam<Real>("ring_offset")),
    _preserve_volumes(getParam<bool>("preserve_volumes")),
    _assembly_orientation(
        getParam<MooseEnum>("assembly_orientation").template getEnum<AssmOrient>()),
    _num_sectors_per_side(getParam<unsigned int>("num_sectors_per_side")),
    _background_intervals(getParam<unsigned int>("background_intervals")),
    _background_block_ids(isParamValid("background_block_ids")
                              ? getParam<std::vector<subdomain_id_type>>("background_block_ids")
                              : std::vector<subdomain_id_type>()),
    _background_block_names(isParamValid("background_block_names")
                                ? getParam<std::vector<SubdomainName>>("background_block_names")
                                : std::vector<SubdomainName>()),
    _external_boundary_id(isParamValid("external_boundary_id")
                              ? getParam<boundary_id_type>("external_boundary_id")
                              : 0),
    _external_boundary_name(isParamValid("external_boundary_name")
                                ? getParam<std::string>("external_boundary_name")
                                : std::string()),
    _pin_id_name(isParamValid("pin_id_name") ? getParam<std::string>("pin_id_name")
                                             : std::string()),
    _pin_id_values(isParamValid("pin_id_values")
                       ? getParam<std::vector<dof_id_type>>("pin_id_values")
                       : std::vector<dof_id_type>()),
    _node_id_background_meta(declareMeshProperty<dof_id_type>("node_id_background_meta", 0))
{
  declareMeshProperty<Real>("pitch_meta", _side_length * std::sqrt(3.0));
  declareMeshProperty<Real>("pattern_pitch_meta", _side_length * std::sqrt(3.0));
  declareMeshProperty<bool>("is_control_drum_meta", false);
  declareMeshProperty<unsigned int>("background_intervals_meta", _background_intervals);
  declareMeshProperty<Real>("max_radius_meta", 0.0);
  declareMeshProperty<std::vector<unsigned int>>("num_sectors_per_side_meta",
                                                 {_num_sectors_per_side,
                                                  _num_sectors_per_side,
                                                  _num_sectors_per_side,
                                                  _num_sectors_per_side,
                                                  _num_sectors_per_side,
                                                  _num_sectors_per_side});

  /* Parameter checks */
  for (unsigned int i = 0; i < 3; i++)
    if (_ring_intervals[i].size() != _ring_radii[i].size())
      paramError("ring_intervals", "The parameter must be consistent with ring_radii.");
  for (unsigned int i = 0; i < 3; i++)
  {
    if (!_has_rings[i] && !_ring_block_ids[i].empty())
      paramError("ring_block_ids", "The parameter must be consistent with ring_radii if provided.");
    else if (!_ring_block_ids[i].empty() &&
             _ring_block_ids[i].size() != (_ring_radii[i].size() + (_ring_intervals[i][0] > 1)))
      paramError("ring_block_ids", "The parameter must be consistent with ring_radii if provided.");
    if (!_has_rings[i] && !_ring_block_names[i].empty())
      paramError("ring_block_names",
                 "The parameter must be consistent with ring_radii if provided.");
    else if (!_ring_block_names[i].empty() &&
             _ring_block_names[i].size() != (_ring_radii[i].size() + (_ring_intervals[i][0] > 1)))
      paramError("ring_block_names",
                 "The parameter must be consistent with ring_radii if provided.");
  }
  if (!_background_block_ids.empty())
  {
    if (_has_rings[0] && _has_rings[1] && _has_rings[2] && _background_block_ids.size() != 1)
      paramError("background_block_ids",
                 "If provided, the size of this parameter must be one if all sections have rings.");
    else if (!_has_rings[0] && !_has_rings[1] && !_has_rings[2] && _background_intervals == 1 &&
             _background_block_ids.size() != 1)
      paramError("background_block_ids",
                 "If provided, the size of this parameter must be one if no sections have rings "
                 "and background_intervals is one.");
    else if ((!_has_rings[0] || !_has_rings[1] || !_has_rings[2]) &&
             _background_block_ids.size() != 2)
      paramError(
          "background_block_ids",
          "If provided, the size of this parameter must be two if ring-free section exists.");
  }
  if (!_background_block_names.empty())
  {
    if (_has_rings[0] && _has_rings[1] && _has_rings[2] && _background_block_names.size() != 1)
      paramError("background_block_names",
                 "If provided, the size of this parameter must be one if all sections have rings.");
    else if (!_has_rings[0] && !_has_rings[1] && !_has_rings[2] && _background_intervals == 1 &&
             _background_block_names.size() != 1)
      paramError("background_block_names",
                 "If provided, the size of this parameter must be one if no sections have rings "
                 "and background_intervals is one.");
    else if ((!_has_rings[0] || !_has_rings[1] || !_has_rings[2]) &&
             _background_block_names.size() != 2)
      paramError(
          "background_block_names",
          "If provided, the size of this parameter must be two if ring-free section exists.");
  }
  if (_pin_id_name.empty())
  {
    if (!_pin_id_values.empty())
      paramError("pin_id_values",
                 "This parameter cannot be used when pin_id_name is not provided.");
  }
  else if (_pin_id_values.size() != 3)
    paramError(
        "pin_id_values",
        "If pin_id_name is provided, this parameter must be provided with a length of three.");

  // Just perform a simple and straightforward check for `ring_offset` here.
  // A more comprehensive check for both `ring_offset` and `ring_radii` is done later.
  if (std::abs(_ring_offset) >= _side_length / 2.0)
    paramError(
        "ring_offset",
        "This parameter cannot translate the ring center out of the hexagon assembly region.");
}

Member Function Documentation

addRingAndSectorIDParams()

void PolygonMeshGeneratorBase::addRingAndSectorIDParams ( InputParameters &  params )

staticprotectedinherited

Add InputParameters which are used by ring and sector IDs.

Parameters

params

InputParameters to be modified with the added params

Definition at line 1598 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonConcentricCircleMeshGeneratorBase::validParams(), and validParams().

{
  params.addParam<std::string>("sector_id_name",
                               "Name of integer (reporting) ID for sector regions to use the "
                               "reporting ID for azimuthal sector regions of ring geometry block.");
  params.addParam<std::string>("ring_id_name",
                               "Name of integer (reporting) ID for ring regions to use the "
                               "reporting ID for annular regions of ring geometry block.");
  MooseEnum ring_id_option("block_wise ring_wise", "block_wise");
  params.addParam<MooseEnum>(
      "ring_id_assign_type", ring_id_option, "Type of ring ID assignment: block_wise or ring_wise");
  params.addParamNamesToGroup("sector_id_name ring_id_name ring_id_assign_type", "Ring/Sector IDs");
}

adjustPeripheralQuadraticElements()

void PolygonMeshGeneratorBase::adjustPeripheralQuadraticElements ( MeshBase &  out_mesh, const QUAD_ELEM_TYPE  boundary_quad_elem_type  ) const

protectedinherited

Adjusts the mid-edge node locations in boundary regions when using quadratic elements with uniform boundary node spacing enabled.

Parameters

out_mesh	mesh to be adjusted.
boundary_quad_elem_type	boundary quad element type.

Definition at line 1253 of file PolygonMeshGeneratorBase.C.

Referenced by PatternedHexMeshGenerator::generate(), and PatternedCartesianMeshGenerator::generate().

{
  const auto side_list = out_mesh.get_boundary_info().build_side_list();

  // select out elements on outer boundary
  // std::set used to filter duplicate elem_ids
  std::set<dof_id_type> elem_set;
  for (auto side_item : side_list)
  {
    boundary_id_type boundary_id = std::get<2>(side_item);
    dof_id_type elem_id = std::get<0>(side_item);

    if (boundary_id == OUTER_SIDESET_ID)
      elem_set.insert(elem_id);
  }

  // adjust nodes for outer boundary elements
  for (const auto elem_id : elem_set)
  {
    Elem * elem = out_mesh.elem_ptr(elem_id);

    // adjust right side mid-edge node
    Point pt_5 = (elem->point(1) + elem->point(2)) / 2.0;
    out_mesh.add_point(pt_5, elem->node_ptr(5)->id());

    // adjust left side mid-edge node
    Point pt_7 = (elem->point(0) + elem->point(3)) / 2.0;
    out_mesh.add_point(pt_7, elem->node_ptr(7)->id());

    // adjust central node when using QUAD9
    if (boundary_quad_elem_type == QUAD_ELEM_TYPE::QUAD9)
    {
      Point pt_8 = elem->true_centroid();
      out_mesh.add_point(pt_8, elem->node_ptr(8)->id());
    }
  }
}

azimuthalAnglesCollector() [1/2]

std::vector<Real> PolygonMeshGeneratorBase::azimuthalAnglesCollector ( ReplicatedMesh &  mesh, std::vector< Point > &  boundary_points, const Real  lower_azi = -30.0, const Real  upper_azi = 30.0, const unsigned int  return_type = ANGLE_TANGENT, const unsigned int  num_sides = 6, const boundary_id_type  bid = OUTER_SIDESET_ID, const bool  calculate_origin = true, const Real  input_origin_x = 0.0, const Real  input_origin_y = 0.0, const Real  tol = 1.0E-10  ) const

protectedinherited

Collects sorted azimuthal angles of the external boundary.

Parameters

mesh	input mesh whose boundary node azimuthal angles need to be collected
boundary_points	reference vector to contain the Points corresponding to the collected azimuthal angles
lower_azi	lower boundary of the azimuthal angles to be collected
upper_azi	upper boundary of the azimuthal angles to be collected
return_type	whether angle values or tangent values are returned
num_sides	number of sides of the input mesh (only used if return type is ANGLE_TANGENT)
bid	id of the boundary of which the nodes' azimuthal angles are collected
calculate_origin	whether the mesh origin is calculated based on the centroid position
input_origin_x	precalculated mesh origin coordinate x
input_origin_y	precalculated mesh origin coordinate y
tol	tolerance that the minimum azimuthal angle is

Returns

the list of azimuthal angles of all the nodes on the external grain boundary within the given range

Referenced by AzimuthalBlockSplitGenerator::generate(), PolygonConcentricCircleMeshGeneratorBase::generate(), and PatternedPolygonPeripheralModifierBase::generate().

azimuthalAnglesCollector() [2/2]

std::vector<Real> PolygonMeshGeneratorBase::azimuthalAnglesCollector ( ReplicatedMesh &  mesh, const Real  lower_azi = -30.0, const Real  upper_azi = 30.0, const unsigned int  return_type = ANGLE_TANGENT, const unsigned int  num_sides = 6, const boundary_id_type  bid = OUTER_SIDESET_ID, const bool  calculate_origin = true, const Real  input_origin_x = 0.0, const Real  input_origin_y = 0.0, const Real  tol = 1.0E-10  ) const

protectedinherited

Collects sorted azimuthal angles of the external boundary.

Parameters

mesh	input mesh whose boundary node azimuthal angles need to be collected
lower_azi	lower boundary of the azimuthal angles to be collected
upper_azi	upper boundary of the azimuthal angles to be collected
return_type	whether angle values or tangent values are returned
num_sides	number of sides of the input mesh (only used if return type is ANGLE_TANGENT)
bid	id of the boundary of which the nodes' azimuthal angles are collected
calculate_origin	whether the mesh origin is calculated based on the centroid position
input_origin_x	precalculated mesh origin coordinate x
input_origin_y	precalculated mesh origin coordinate y
tol	tolerence that the minimum azimuthal angle is

Returns

the list of azimuthal angles of all the nodes on the external grain boundary within the given range

backgroundNodes()

void PolygonMeshGeneratorBase::backgroundNodes ( ReplicatedMesh &  mesh, const unsigned int  num_sectors_per_side, const unsigned int  background_intervals, const std::vector< Real >  biased_terms, const Real  background_corner_distance, const Real  background_corner_radial_interval_length, const Real  corner_p[2][2], const Real  corner_to_corner, const Real  background_in, const std::vector< Real >  azimuthal_tangent = std::vector<Real>()  ) const

protectedinherited

Creates nodes for the ring-to-polygon transition region (i.e., background) of a single slice.

Parameters

mesh	input mesh to add the nodes onto
num_sectors_per_side	number of azimuthal intervals
background_intervals	number of radial intervals of the background region
biased_terms	normalized spacing values used for radial meshing biasing in background region
background_corner_distance	center to duct (innermost duct) corner distance
background_corner_radial_interval_length	radial interval distance
corner_p[2][2]	array contains the coordinates of the corner positions
corner_to_corner	diameter of the circumscribed circle of the polygon
background_in	radius of the inner boundary of the background region
azimuthal_tangent	vector of tangent values of the azimuthal angles as reference for adaptive boundary matching

Returns

a mesh with background region nodes created

Definition at line 720 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildSlice().

{
  unsigned int angle_number =
      azimuthal_tangent.size() == 0 ? num_sectors_per_side : (azimuthal_tangent.size() - 1);
  for (unsigned int k = 0; k < (background_intervals); k++)
  {
    const Real background_corner_p_x =
        background_corner_distance / (0.5 * corner_to_corner) * corner_p[0][0] *
        (background_in +
         biased_terms[k] * background_intervals * background_corner_radial_interval_length) /
        background_corner_distance;
    const Real background_corner_p_y =
        background_corner_distance / (0.5 * corner_to_corner) * corner_p[0][1] *
        (background_in +
         biased_terms[k] * background_intervals * background_corner_radial_interval_length) /
        background_corner_distance;

    // background_corner_p(s) are the points in the background region, on the bins towards the six
    // corners, at different intervals
    mesh.add_point(Point(background_corner_p_x, background_corner_p_y, 0.0));

    for (unsigned int j = 1; j <= angle_number; j++)
    {
      const Real cell_boundary_p_x =
          background_corner_distance / (0.5 * corner_to_corner) *
          (corner_p[0][0] + (corner_p[1][0] - corner_p[0][0]) *
                                (azimuthal_tangent.size() == 0 ? ((Real)j / (Real)angle_number)
                                                               : (azimuthal_tangent[j] / 2.0)));
      const Real cell_boundary_p_y =
          background_corner_distance / (0.5 * corner_to_corner) *
          (corner_p[0][1] + (corner_p[1][1] - corner_p[0][1]) *
                                (azimuthal_tangent.size() == 0 ? ((Real)j / (Real)angle_number)
                                                               : (azimuthal_tangent[j] / 2.0)));
      // cell_boundary_p(s) are the points on the cell's six boundaries (flat sides) at different
      // azimuthal angles
      const Real pin_boundary_p_x =
          cell_boundary_p_x * background_in /
          std::sqrt(Utility::pow<2>(cell_boundary_p_x) + Utility::pow<2>(cell_boundary_p_y));
      const Real pin_boundary_p_y =
          cell_boundary_p_y * background_in /
          std::sqrt(Utility::pow<2>(cell_boundary_p_x) + Utility::pow<2>(cell_boundary_p_y));
      // pin_boundary_p(s) are the points on pin boundary (outside ring) at different azimuthal
      // angles
      const Real background_radial_interval =
          std::sqrt(Utility::pow<2>(cell_boundary_p_x - pin_boundary_p_x) +
                    Utility::pow<2>(cell_boundary_p_y - pin_boundary_p_y)) /
          background_intervals;
      const Real background_azimuthal_p_x =
          cell_boundary_p_x *
          (background_in + biased_terms[k] * background_intervals * background_radial_interval) /
          std::sqrt(Utility::pow<2>(cell_boundary_p_x) + Utility::pow<2>(cell_boundary_p_y));
      const Real background_azimuthal_p_y =
          cell_boundary_p_y *
          (background_in + biased_terms[k] * background_intervals * background_radial_interval) /
          std::sqrt(Utility::pow<2>(cell_boundary_p_x) + Utility::pow<2>(cell_boundary_p_y));
      // background_azimuthal_p are the points on the bins towards different azimuthal angles, at
      // different intervals; excluding the ones produced by background_corner_p
      mesh.add_point(Point(background_azimuthal_p_x, background_azimuthal_p_y, 0.0));
    }
  }
}

biasTermsCalculator() [1/2]

std::vector< std::vector< Real > > PolygonMeshGeneratorBase::biasTermsCalculator ( const std::vector< Real >  radial_biases, const std::vector< unsigned int >  intervals, const multiBdryLayerParams  inner_boundary_layer_params, const multiBdryLayerParams  outer_boundary_layer_params  ) const

protectedinherited

Creates bias terms for multiple blocks.

Parameters

radial_biases	bias growth factors of the elements within the main regions of the blocks
intervals	radial interval numbers of the main regions of the blocks
inner_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the inner boundary layers
outer_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the outer boundary layers

Returns

bias list of terms describing the cumulative radial fractions of the nodes within multiple blocks

Definition at line 1523 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildSlice(), and PeripheralRingMeshGenerator::generate().

{
  std::vector<std::vector<Real>> bias_terms_vec;
  for (unsigned int i = 0; i < radial_biases.size(); i++)
    bias_terms_vec.push_back(biasTermsCalculator(radial_biases[i],
                                                 intervals[i],
                                                 {0.0,
                                                  inner_boundary_layer_params.fractions[i],
                                                  inner_boundary_layer_params.intervals[i],
                                                  inner_boundary_layer_params.biases[i]},
                                                 {0.0,
                                                  outer_boundary_layer_params.fractions[i],
                                                  outer_boundary_layer_params.intervals[i],
                                                  outer_boundary_layer_params.biases[i]}));
  return bias_terms_vec;
}

biasTermsCalculator() [2/2]

std::vector< Real > PolygonMeshGeneratorBase::biasTermsCalculator ( const Real  radial_bias, const unsigned int  intervals, const singleBdryLayerParams  inner_boundary_layer_params = {0.0, 0.0, 0, 1.0}, const singleBdryLayerParams  outer_boundary_layer_params = {0.0, 0.0, 0, 1.0}  ) const

protectedinherited

Creates bias terms for a single block.

Parameters

radial_bias	bias growth factor of the elements within the main region of the block
intervals	radial interval number of the main region of the block
inner_boundary_layer_params	width, radial fraction, radial sector, and growth factor of the inner boundary layer
outer_boundary_layer_params	width, radial fraction, radial sector, and growth factor of the outer boundary layer

Returns

bias terms describing the cumulative radial fractions of the nodes within a single block

Definition at line 1545 of file PolygonMeshGeneratorBase.C.

{
  // To get biased indices:
  // If no bias is involved, namely bias factor = 1.0, the increment in indices is uniform.
  // Thus, (i + 1) is used to get such linearly increasing indices.
  // If a non-trivial bias factor q is used, the increment in the indices is geometric
  // progression. So, if first (i = 0) increment is 1.0, second (i = 1) is q, third (i = 2) is
  // q^2,..., last or n_interval'th is q^(n_interval - 1). Then, the summation of the first (i +
  // 1) increments over the summation of all n_interval increments is the (i + 1)th index The
  // summation of the first (i + 1) increments is (1.0 - q^(i + 1)) / (1 - q); The summation of
  // all n_interval increments is (1.0 - q^n_interval) / (1 - q); Thus, the index is (1.0 - q^(i +
  // 1)) / (1.0 - q^n_interval)
  // This approach is used by inner boundary layer, main region, outer boundary layer separately.

  std::vector<Real> biased_terms;
  for (unsigned int i = 0; i < inner_boundary_layer_params.intervals; i++)
    biased_terms.push_back(
        MooseUtils::absoluteFuzzyEqual(inner_boundary_layer_params.bias, 1.0)
            ? ((Real)(i + 1) * inner_boundary_layer_params.fraction /
               (Real)inner_boundary_layer_params.intervals)
            : ((1.0 - std::pow(inner_boundary_layer_params.bias, (Real)(i + 1))) /
               (1.0 - std::pow(inner_boundary_layer_params.bias,
                               (Real)(inner_boundary_layer_params.intervals))) *
               inner_boundary_layer_params.fraction));
  for (unsigned int i = 0; i < intervals; i++)
    biased_terms.push_back(inner_boundary_layer_params.fraction +
                           (MooseUtils::absoluteFuzzyEqual(radial_bias, 1.0)
                                ? ((Real)(i + 1) *
                                   (1.0 - inner_boundary_layer_params.fraction -
                                    outer_boundary_layer_params.fraction) /
                                   (Real)intervals)
                                : ((1.0 - std::pow(radial_bias, (Real)(i + 1))) /
                                   (1.0 - std::pow(radial_bias, (Real)(intervals))) *
                                   (1.0 - inner_boundary_layer_params.fraction -
                                    outer_boundary_layer_params.fraction))));
  for (unsigned int i = 0; i < outer_boundary_layer_params.intervals; i++)
    biased_terms.push_back(
        1.0 - outer_boundary_layer_params.fraction +
        (MooseUtils::absoluteFuzzyEqual(outer_boundary_layer_params.bias, 1.0)
             ? ((Real)(i + 1) * outer_boundary_layer_params.fraction /
                (Real)outer_boundary_layer_params.intervals)
             : ((1.0 - std::pow(outer_boundary_layer_params.bias, (Real)(i + 1))) /
                (1.0 - std::pow(outer_boundary_layer_params.bias,
                                (Real)(outer_boundary_layer_params.intervals))) *
                outer_boundary_layer_params.fraction)));
  return biased_terms;
}

buildGeneralSlice()

std::unique_ptr< ReplicatedMesh > PolygonMeshGeneratorBase::buildGeneralSlice ( std::vector< Real >  ring_radii, const std::vector< unsigned int >  ring_layers, const std::vector< Real >  ring_radial_biases, const multiBdryLayerParams &  ring_inner_boundary_layer_params, const multiBdryLayerParams &  ring_outer_boundary_layer_params, std::vector< Real >  ducts_center_dist, const std::vector< unsigned int >  ducts_layers, const std::vector< Real >  duct_radial_biases, const multiBdryLayerParams &  duct_inner_boundary_layer_params, const multiBdryLayerParams &  duct_outer_boundary_layer_params, const Real  primary_side_length, const Real  secondary_side_length, const unsigned int  num_sectors_per_side, const unsigned int  background_intervals, const Real  background_radial_bias, const singleBdryLayerParams &  background_inner_boundary_layer_params, const singleBdryLayerParams &  background_outer_boundary_layer_params, dof_id_type &  node_id_background_meta, const Real  azimuthal_angle, const std::vector< Real >  azimuthal_tangent, const unsigned int  side_index, const bool  quad_center_elements, const Real  center_quad_factor, const Real  rotation_angle, const bool  generate_side_specific_boundaries = true  )

protectedinherited

Creates a mesh of a general polygon slice with a triangular shape and circular regions on one of its vertex.

Parameters

ring_radii	radii of the ring regions
ring_layers	numbers of radial intervals of the ring regions
ring_radial_biases	values used for radial meshing biasing in ring regions
ring_inner_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the inner boundary layer of the ring regions
ring_outer_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the outer boundary layer of the ring regions
ducts_center_dist	distance parameters of the duct regions
ducts_layers	numbers of radial intervals of the duct regions
duct_radial_biases	values used for radial meshing biasing in duct regions
duct_inner_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the inner boundary layer of the duct regions
duct_outer_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the outer boundary layer of the duct regions
primary_side_length	length of the first side (i.e., the side that is parallel to y-axis when rotation_angle is zero) that involves the ring center vertex
secondary_side_length	length of the second side (obtained by clockwise rotating the fist side by azimuthal_angle) that involves the ring center vertex
num_sectors_per_side	number of azimuthal intervals
background_intervals	number of radial intervals of the background region
background_radial_bias	value used for radial meshing biasing in background region
background_inner_boundary_layer_params	width, radial sectors, and growth factor of the inner boundary layer of the background region
background_outer_boundary_layer_params	width, radial sectors, and growth factor of the outer boundary layer of the background region
node_id_background_meta	pointer to the first node's id of the background region
azimuthal_angle	the angle defined by the primary and secondary sides
azimuthal_tangent	vector of tangent values of the azimuthal angles as reference for adaptive boundary matching
side_index	index of the polygon side
quad_center_elements	whether the central region contains quad elements or not
center_quad_factor	A fractional radius factor used to determine the radial positions of transition nodes in the center region meshed by quad elements (default is 1.0 - 1.0/div_num)
rotation_angle	azimuthal angle of the primary side
generate_side_specific_boundaries	whether the side-specific external boundaries are generated or not

Returns

a mesh of a general slice

Definition at line 42 of file PolygonMeshGeneratorBase.C.

Referenced by buildSinglePinSection().

{
  const Real virtual_pitch = 2.0 * primary_side_length * cos(azimuthal_angle / 360.0 * M_PI);
  const Real virtual_side_number = 360.0 / azimuthal_angle;
  const Real pitch_scale_factor = secondary_side_length / primary_side_length;

  auto mesh = buildSlice(ring_radii,
                         ring_layers,
                         ring_radial_biases,
                         ring_inner_boundary_layer_params,
                         ring_outer_boundary_layer_params,
                         ducts_center_dist,
                         ducts_layers,
                         duct_radial_biases,
                         duct_inner_boundary_layer_params,
                         duct_outer_boundary_layer_params,
                         virtual_pitch,
                         num_sectors_per_side,
                         background_intervals,
                         background_radial_bias,
                         background_inner_boundary_layer_params,
                         background_outer_boundary_layer_params,
                         node_id_background_meta,
                         virtual_side_number,
                         side_index,
                         azimuthal_tangent,
                         0,
                         quad_center_elements,
                         center_quad_factor,
                         false,
                         true,
                         0,
                         pitch_scale_factor,
                         generate_side_specific_boundaries);
  MeshTools::Modification::rotate(*mesh, rotation_angle, 0, 0);
  return mesh;
}

buildSimplePeripheral()

std::unique_ptr< ReplicatedMesh > PolygonMeshGeneratorBase::buildSimplePeripheral ( const unsigned int  num_sectors_per_side, const unsigned int  peripheral_invervals, const std::vector< std::pair< Real, Real >> &  position_inner, const std::vector< std::pair< Real, Real >> &  d_position_outer, const subdomain_id_type  id_shift, const QUAD_ELEM_TYPE  quad_elem_type, const bool  create_inward_interface_boundaries = false, const bool  create_outward_interface_boundaries = true  )

protectedinherited

Creates peripheral area mesh for the patterned hexagon mesh.

Note that the function create the peripheral area for each side of the unit hexagon mesh before stitching. An edge unit hexagon has two sides that need peripheral areas, whereas a corner unit hexagon has three such sides. The positions of the inner and outer boundary nodes are pre-calculated as positions_inner and d_positions_outer; This function performs interpolation to generate the mesh grid.

Parameters

mesh	input mesh to create the peripheral area mesh onto
num_sectors_per_side	number of azimuthal intervals
peripheral_invervals	number of radial intervals of the peripheral region
position_inner	key positions of the inner side of the peripheral region
d_position_outer	key inremental positions of the outer side of the peripheral region
id_shift	shift of subdomain id of the peripheral region
create_inward_interface_boundaries	whether inward interface boundary sidesets are created
create_outward_interface_boundaries	whether outward interface boundary sidesets are created
quad_elem_type	type of quad element to be created

Returns

a mesh with the peripheral region added to a hexagon input mesh

Definition at line 1153 of file PolygonMeshGeneratorBase.C.

Referenced by PatternedHexMeshGenerator::addPeripheralMesh(), and PatternedCartesianMeshGenerator::addPeripheralMesh().

{
  auto mesh = buildReplicatedMesh(2);
  std::pair<Real, Real> positions_p;

  // generate node positions
  for (unsigned int i = 0; i <= peripheral_invervals; i++)
  {
    for (unsigned int j = 0; j <= num_sectors_per_side / 2; j++)
    {
      positions_p = pointInterpolate(positions_inner[0].first,
                                     positions_inner[0].second,
                                     d_positions_outer[0].first,
                                     d_positions_outer[0].second,
                                     positions_inner[1].first,
                                     positions_inner[1].second,
                                     d_positions_outer[1].first,
                                     d_positions_outer[1].second,
                                     i,
                                     j,
                                     num_sectors_per_side,
                                     peripheral_invervals);
      mesh->add_point(Point(positions_p.first, positions_p.second, 0.0));
    }
    for (unsigned int j = 1; j <= num_sectors_per_side / 2; j++)
    {
      positions_p = pointInterpolate(positions_inner[1].first,
                                     positions_inner[1].second,
                                     d_positions_outer[1].first,
                                     d_positions_outer[1].second,
                                     positions_inner[2].first,
                                     positions_inner[2].second,
                                     d_positions_outer[2].first,
                                     d_positions_outer[2].second,
                                     i,
                                     j,
                                     num_sectors_per_side,
                                     peripheral_invervals);
      mesh->add_point(Point(positions_p.first, positions_p.second, 0.0));
    }
  }

  // element definition
  BoundaryInfo & boundary_info = mesh->get_boundary_info();

  for (unsigned int i = 0; i < peripheral_invervals; i++)
  {
    for (unsigned int j = 0; j < num_sectors_per_side; j++)
    {
      std::unique_ptr<Elem> new_elem;

      new_elem = std::make_unique<Quad4>();
      new_elem->set_node(0, mesh->node_ptr(j + (num_sectors_per_side + 1) * (i)));
      new_elem->set_node(1, mesh->node_ptr(j + 1 + (num_sectors_per_side + 1) * (i)));
      new_elem->set_node(2, mesh->node_ptr(j + 1 + (num_sectors_per_side + 1) * (i + 1)));
      new_elem->set_node(3, mesh->node_ptr(j + (num_sectors_per_side + 1) * (i + 1)));

      Elem * elem = mesh->add_elem(std::move(new_elem));

      // add subdoamin and boundary IDs
      elem->subdomain_id() = PERIPHERAL_ID_SHIFT + id_shift;
      if (i == 0)
      {
        boundary_info.add_side(elem, 0, OUTER_SIDESET_ID);
        if (create_inward_interface_boundaries)
          boundary_info.add_side(elem, 0, SLICE_ALT + id_shift * 2);
      }
      if (i == peripheral_invervals - 1)
      {
        boundary_info.add_side(elem, 2, OUTER_SIDESET_ID);
        if (create_outward_interface_boundaries)
          boundary_info.add_side(elem, 2, SLICE_ALT + id_shift * 2 + 1);
      }
      if (j == 0)
        boundary_info.add_side(elem, 3, OUTER_SIDESET_ID);
      if (j == num_sectors_per_side - 1)
        boundary_info.add_side(elem, 1, OUTER_SIDESET_ID);
    }
  }

  // convert element to second order if needed
  if (quad_elem_type != QUAD_ELEM_TYPE::QUAD4)
  {
    // full_ordered 2nd order element --> QUAD9, otherwise QUAD8
    const bool full_ordered = (quad_elem_type == QUAD_ELEM_TYPE::QUAD9);
    mesh->all_second_order(full_ordered);
  }

  return mesh;
}

buildSimpleSlice()

std::unique_ptr< ReplicatedMesh > PolygonMeshGeneratorBase::buildSimpleSlice ( std::vector< Real >  ring_radii, const std::vector< unsigned int >  ring_layers, const std::vector< Real >  ring_radial_biases, const multiBdryLayerParams &  ring_inner_boundary_layer_params, const multiBdryLayerParams &  ring_outer_boundary_layer_params, std::vector< Real >  ducts_center_dist, const std::vector< unsigned int >  ducts_layers, const std::vector< Real >  duct_radial_biases, const multiBdryLayerParams &  duct_inner_boundary_layer_params, const multiBdryLayerParams &  duct_outer_boundary_layer_params, const Real  pitch, const unsigned int  num_sectors_per_side, const unsigned int  background_intervals, const Real  background_radial_bias, const singleBdryLayerParams &  background_inner_boundary_layer_params, const singleBdryLayerParams &  background_outer_boundary_layer_params, dof_id_type &  node_id_background_meta, const unsigned int  side_number, const unsigned int  side_index, const std::vector< Real >  azimuthal_tangent = std::vector<Real>(), const subdomain_id_type  block_id_shift = 0, const bool  quad_center_elements = false, const Real  center_quad_factor = 0.0, const bool  create_inward_interface_boundaries = false, const bool  create_outward_interface_boundaries = true, const boundary_id_type  boundary_id_shift = 0, const bool  generate_side_specific_boundaries = true, const TRI_ELEM_TYPE  tri_elem_type = TRI_ELEM_TYPE::TRI3, const QUAD_ELEM_TYPE  quad_elem_type = QUAD_ELEM_TYPE::QUAD4  )

protectedinherited

Creates a mesh of a slice that corresponds to a single side of the polygon to be generated.

Parameters

ring_radii	radii of the ring regions
ring_layers	numbers of radial intervals of the ring regions
ring_radial_biases	values used for radial meshing biasing in ring regions
ring_inner_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the inner boundary layer of the ring regions
ring_outer_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the outer boundary layer of the ring regions
ducts_center_dist	distance parameters of the duct regions
ducts_layers	numbers of radial intervals of the duct regions
duct_radial_biases	values used for radial meshing biasing in duct regions
duct_inner_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the inner boundary layer of the duct regions
duct_outer_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the outer boundary layer of the duct regions
pitch	twice the distance from the ring center vertex to the side defined by the other vertices
num_sectors_per_side	number of azimuthal intervals
background_intervals	number of radial intervals of the background region
background_radial_bias	value used for radial meshing biasing in background region
background_inner_boundary_layer_params	width, radial sectors, and growth factor of the inner boundary layer of the background region
background_outer_boundary_layer_params	width, radial sectors, and growth factor of the outer boundary layer of the background region
node_id_background_meta	pointer to the first node's id of the background region
side_number	number of sides of the polygon
side_index	index of the polygon side
azimuthal_tangent	vector of tangent values of the azimuthal angles as reference for adaptive boundary matching
block_id_shift	shift of the subdomain ids generated by this function
quad_center_elements	whether the central region contrains quad elements or not
center_quad_factor	A fractional radius factor used to determine the radial positions of transition nodes in the center region meshed by quad elements (default is 1.0 - 1.0/div_num)
create_inward_interface_boundaries	whether inward interface boundary sidesets are created
create_outward_interface_boundaries	whether outward interface boundary sidesets are created
boundary_id_shift	shift of the interface boundary ids
generate_side_specific_boundaries	whether the side-specific external boundaries are generated or not
tri_elem_type	type of the triangular elements to be generated
quad_elem_type	type of the quadrilateral elements to be generated

Returns

a mesh of a polygon slice

Definition at line 106 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonConcentricCircleMeshGeneratorBase::generate().

{
  return buildSlice(ring_radii,
                    ring_layers,
                    ring_radial_biases,
                    ring_inner_boundary_layer_params,
                    ring_outer_boundary_layer_params,
                    ducts_center_dist,
                    ducts_layers,
                    duct_radial_biases,
                    duct_inner_boundary_layer_params,
                    duct_outer_boundary_layer_params,
                    pitch,
                    num_sectors_per_side,
                    background_intervals,
                    background_radial_bias,
                    background_inner_boundary_layer_params,
                    background_outer_boundary_layer_params,
                    node_id_background_meta,
                    side_number,
                    side_index,
                    azimuthal_tangent,
                    block_id_shift,
                    quad_center_elements,
                    center_quad_factor,
                    create_inward_interface_boundaries,
                    create_outward_interface_boundaries,
                    boundary_id_shift,
                    1.0,
                    generate_side_specific_boundaries,
                    tri_elem_type,
                    quad_elem_type);
}

buildSinglePinSection()

std::unique_ptr< ReplicatedMesh > TriPinHexAssemblyGenerator::buildSinglePinSection ( const Real  side_length, const Real  ring_offset, const std::vector< Real >  ring_radii, const std::vector< unsigned int >  ring_intervals, const bool  has_rings, const bool  preserve_volumes, const unsigned int  num_sectors_per_side, const unsigned int  background_intervals, const std::vector< subdomain_id_type >  block_ids_new, dof_id_type &  node_id_background_meta  )

protected

Generates a single-pin diamond section mesh, which is one-third of the triple-pin hexagonal assembly mesh.

Parameters

side_length	side length of the hexagon assembly to be generated.
ring_offset	offset of the center of the ring region from the center of the diamond
ring_radii	radii of major concentric circles in the diamond section
ring_intervals	number of radial mesh intervals of the major concentric circles
has_rings	whether the section contains any ring regions
preserve_volumes	whether the radii of the rings are modified to preserve volumes
num_sectors_per_side	number of azimuthal sectors per side
background_intervals	number of radial meshing intervals in background region (area outside the rings)
block_ids_new	customized block ids for the regions
node_id_background_meta	reference to the first node's id of the background region

Returns

a mesh of a single-pin diamond section mesh

Definition at line 327 of file TriPinHexAssemblyGenerator.C.

Referenced by generate().

{
  // Each SinglePinSection, which has a diamond shape, is composed of four general slices.
  // Considering symmetry, two unique general slices (0 and 1) need to be generated.
  // For each slice, the center of the pin is one of its vertices; primary and secondary sides are
  // the two sides that contain the pin center.
  const Real secondary_side_length_0(side_length / 2.0 - ring_offset);
  const Real secondary_side_length_1(
      std::sqrt(side_length * side_length / 4.0 * 3.0 + ring_offset * ring_offset));
  const Real primary_side_length_0(
      std::sqrt(side_length * side_length / 4.0 * 3.0 + ring_offset * ring_offset));
  const Real primary_side_length_1(side_length / 2.0 + ring_offset);
  // Azimuthal angle is the included angle defined by the primary and secondary sides
  const Real azimuthal_angle_0(
      acos((secondary_side_length_0 * secondary_side_length_0 +
            primary_side_length_0 * primary_side_length_0 - side_length * side_length) /
           2.0 / primary_side_length_0 / secondary_side_length_0) /
      M_PI * 180.0);
  const Real azimuthal_angle_1(
      acos((secondary_side_length_1 * secondary_side_length_1 +
            primary_side_length_1 * primary_side_length_1 - side_length * side_length) /
           2.0 / primary_side_length_1 / secondary_side_length_1) /
      M_PI * 180.0);
  // The primary side is parallel to y-axis by default (i.e., rotation_angle is zero). So the
  // general slices need to be rotated before stitching,
  const Real rotation_angle_0(azimuthal_angle_0 - 90.0);
  const Real rotation_angle_1(azimuthal_angle_0 + azimuthal_angle_1 - 90.0);
  // Alpha angle is the other included angle of the slice defined by the primary side and the third
  // side.
  const Real alpha_angle_0(
      acos((primary_side_length_0 * primary_side_length_0 + side_length * side_length -
            secondary_side_length_0 * secondary_side_length_0) /
           2.0 / primary_side_length_0 / side_length) /
      M_PI * 180.0);
  const Real alpha_angle_1(
      acos((primary_side_length_1 * primary_side_length_1 + side_length * side_length -
            secondary_side_length_1 * secondary_side_length_1) /
           2.0 / primary_side_length_1 / side_length) /
      M_PI * 180.0);

  // azimuthal_list is a list of azimuthal intervals of the mesh to support radius correction to
  // ensure preserved volume.
  std::vector<Real> azimuthal_list;
  for (unsigned int i = 0; i < num_sectors_per_side; i++)
  {
    azimuthal_list.push_back(
        atan((Real)i * side_length / num_sectors_per_side * sin(alpha_angle_0 / 180.0 * M_PI) /
             (primary_side_length_0 -
              (Real)i * side_length / num_sectors_per_side * cos(alpha_angle_0 / 180.0 * M_PI))) /
        M_PI * 180.0);
  }
  for (unsigned int i = 0; i < num_sectors_per_side; i++)
  {
    azimuthal_list.push_back(
        azimuthal_angle_0 +
        atan((Real)i * side_length / num_sectors_per_side * sin(alpha_angle_1 / 180.0 * M_PI) /
             (primary_side_length_1 -
              (Real)i * side_length / num_sectors_per_side * cos(alpha_angle_1 / 180.0 * M_PI))) /
            M_PI * 180.0);
  }
  for (unsigned int i = 0; i < num_sectors_per_side * 2; i++)
  {
    azimuthal_list.push_back(azimuthal_list[i] + 180.0);
  }

  std::vector<Real> ring_radii_corr;
  if (has_rings)
  {
    if (preserve_volumes)
    {
      const Real corr_factor = PolygonalMeshGenerationUtils::radiusCorrectionFactor(azimuthal_list);
      for (unsigned int i = 0; i < ring_radii.size(); i++)
        ring_radii_corr.push_back(ring_radii[i] * corr_factor);
    }
    else
      ring_radii_corr = ring_radii;
    if (ring_radii_corr.back() > (side_length / 2.0 - std::abs(ring_offset)) * std::sqrt(3.0) / 2.0)
      paramError("ring_radii",
                 "The radii of the rings cannot exceed the boundary of the diamond section.");
  }

  // build the first slice of the polygon.
  auto mesh0 = buildGeneralSlice(
      ring_radii_corr,
      ring_intervals,
      std::vector<Real>(ring_radii_corr.size(), 1.0),
      {std::vector<Real>(ring_radii_corr.size(), 0.0),
       std::vector<Real>(ring_radii_corr.size(), 0.0),
       std::vector<unsigned int>(ring_radii_corr.size(), 0),
       std::vector<Real>(ring_radii_corr.size(), 1.0)},
      {std::vector<Real>(ring_radii_corr.size(), 0.0),
       std::vector<Real>(ring_radii_corr.size(), 0.0),
       std::vector<unsigned int>(ring_radii_corr.size(), 0),
       std::vector<Real>(ring_radii_corr.size(), 1.0)},
      std::vector<Real>(),
      std::vector<unsigned int>(),
      std::vector<Real>(),
      {std::vector<Real>(), std::vector<Real>(), std::vector<unsigned int>(), std::vector<Real>()},
      {std::vector<Real>(), std::vector<Real>(), std::vector<unsigned int>(), std::vector<Real>()},
      primary_side_length_0,
      secondary_side_length_0,
      num_sectors_per_side,
      background_intervals,
      1.0,
      {0.0, 0.0, 0, 1.0},
      {0.0, 0.0, 0, 1.0},
      node_id_background_meta,
      azimuthal_angle_0,
      std::vector<Real>(),
      /* side_index = */ 1,
      false,
      0.0,
      rotation_angle_0,
      false);

  auto mesh1 = buildGeneralSlice(
      ring_radii_corr,
      ring_intervals,
      std::vector<Real>(ring_radii_corr.size(), 1.0),
      {std::vector<Real>(ring_radii_corr.size(), 0.0),
       std::vector<Real>(ring_radii_corr.size(), 0.0),
       std::vector<unsigned int>(ring_radii_corr.size(), 0),
       std::vector<Real>(ring_radii_corr.size(), 1.0)},
      {std::vector<Real>(ring_radii_corr.size(), 0.0),
       std::vector<Real>(ring_radii_corr.size(), 0.0),
       std::vector<unsigned int>(ring_radii_corr.size(), 0),
       std::vector<Real>(ring_radii_corr.size(), 1.0)},
      std::vector<Real>(),
      std::vector<unsigned int>(),
      std::vector<Real>(),
      {std::vector<Real>(), std::vector<Real>(), std::vector<unsigned int>(), std::vector<Real>()},
      {std::vector<Real>(), std::vector<Real>(), std::vector<unsigned int>(), std::vector<Real>()},
      primary_side_length_1,
      secondary_side_length_1,
      num_sectors_per_side,
      background_intervals,
      1.0,
      {0.0, 0.0, 0, 1.0},
      {0.0, 0.0, 0, 1.0},
      node_id_background_meta,
      azimuthal_angle_1,
      std::vector<Real>(),
      /* side_index = */ 1,
      false,
      0.0,
      rotation_angle_1,
      false);

  mesh0->stitch_meshes(*mesh1,
                       SLICE_BEGIN,
                       SLICE_END,
                       TOLERANCE,
                       /*clear_stitched_boundary_ids=*/true);
  MooseMesh::changeBoundaryId(*mesh0, SLICE_BEGIN, SLICE_END, true);

  auto mesh2 = dynamic_pointer_cast<ReplicatedMesh>(mesh0->clone());
  MeshTools::Modification::rotate(*mesh2, 0, 180.0, 0);
  mesh0->stitch_meshes(*mesh2,
                       SLICE_END,
                       SLICE_END,
                       TOLERANCE,
                       /*clear_stitched_boundary_ids=*/true);
  MeshTools::Modification::translate(*mesh0, side_length / 2.0 + ring_offset, 0, 0);

  for (const auto & elem : mesh0->element_ptr_range())
    elem->subdomain_id() = block_ids_new[elem->subdomain_id() - 1];

  return mesh0;
}

buildSlice()

std::unique_ptr< ReplicatedMesh > PolygonMeshGeneratorBase::buildSlice ( std::vector< Real >  ring_radii, const std::vector< unsigned int >  ring_layers, const std::vector< Real >  ring_radial_biases, const multiBdryLayerParams &  ring_inner_boundary_layer_params, const multiBdryLayerParams &  ring_outer_boundary_layer_params, std::vector< Real >  ducts_center_dist, const std::vector< unsigned int >  ducts_layers, const std::vector< Real >  duct_radial_biases, const multiBdryLayerParams &  duct_inner_boundary_layer_params, const multiBdryLayerParams &  duct_outer_boundary_layer_params, const Real  pitch, const unsigned int  num_sectors_per_side, const unsigned int  background_intervals, const Real  background_radial_bias, const singleBdryLayerParams &  background_inner_boundary_layer_params, const singleBdryLayerParams &  background_outer_boundary_layer_params, dof_id_type &  node_id_background_meta, const Real  virtual_side_number, const unsigned int  side_index, const std::vector< Real >  azimuthal_tangent = std::vector<Real>(), const subdomain_id_type  block_id_shift = 0, const bool  quad_center_elements = false, const Real  center_quad_factor = 0.0, const bool  create_inward_interface_boundaries = false, const bool  create_outward_interface_boundaries = true, const boundary_id_type  boundary_id_shift = 0, const Real  pitch_scale_factor = 1.0, const bool  generate_side_specific_boundaries = true, const TRI_ELEM_TYPE  tri_elem_type = TRI_ELEM_TYPE::TRI3, const QUAD_ELEM_TYPE  quad_elem_type = QUAD_ELEM_TYPE::QUAD4  )

protectedinherited

Generates a mesh of a polygon slice, which is the foundation of both buildGeneralSlice and buildSimpleSlice.

Parameters

ring_radii	radii of the ring regions
ring_layers	numbers of radial intervals of the ring regions
ring_radial_biases	values used for radial meshing biasing in ring regions
ring_inner_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the inner boundary layer of the ring regions
ring_outer_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the outer boundary layer of the ring regions
ducts_center_dist	distance parameters of the duct regions
ducts_layers	numbers of radial intervals of the duct regions
duct_radial_biases	values used for radial meshing biasing in duct regions
duct_inner_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the inner boundary layer of the duct regions
duct_outer_boundary_layer_params	widths, radial fractions, radial sectors, and growth factors of the outer boundary layer of the duct regions
pitch	twice of the length of the first side times cosine of the azimuthal angle
num_sectors_per_side	number of azimuthal intervals
background_intervals	number of radial intervals of the background region
background_radial_bias	value used for radial meshing biasing in background region
background_inner_boundary_layer_params	width, radial sectors, and growth factor of the inner boundary layer of the background region
background_outer_boundary_layer_params	width, radial sectors, and growth factor of the outer boundary layer of the background region
node_id_background_meta	pointer to the first node's id of the background region
virtual_side_number	360.0 over the azimuthal angle of the slice (happens to be number of sides of the polygon if a regular polygon is to be generated)
side_index	index of the polygon side
azimuthal_tangent	vector of tangent values of the azimuthal angles as reference for adaptive boundary matching
block_id_shift	shift of the subdomain ids generated by this function
quad_center_elements	whether the central region contrains quad elements or not
center_quad_factor	A fractional radius factor used to determine the radial positions of transition nodes in the center region meshed by quad elements (default is 1.0 - 1.0/div_num)
create_inward_interface_boundaries	whether inward interface boundary sidesets are created
create_outward_interface_boundaries	whether outward interface boundary sidesets are created
boundary_id_shift	shift of the interface boundary ids
pitch_scale_factor	the ratio between the secondary side length to the primary side length.
generate_side_specific_boundaries	whether the side-specific external boundaries are generated or not
tri_elem_type	type of the triangular elements to be generated
quad_elem_type	type of the quadrilateral elements to be generated

Returns

a mesh of a slice

Definition at line 170 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildGeneralSlice(), PolygonMeshGeneratorBase::buildSimpleSlice(), and AdvancedConcentricCircleGenerator::generate().

{
  const unsigned short order = quad_elem_type == QUAD_ELEM_TYPE::QUAD4 ? 1 : 2;
  if (order != (tri_elem_type == TRI_ELEM_TYPE::TRI3 ? 1 : 2))
    mooseError("In mesh generator ",
               this->name(),
               ", an incompatible elements type combination is used when calling "
               "PolygonMeshGeneratorBase::buildSlice().");
  // In order to create quadratic elements (i.e., order = 2), we creates nodes with double mesh
  // density. Thus, the related parameters need to be modified accordingly. A prefix "mod_" is used
  // to indicate the modified parameters.

  // For ring_layers, modification is to double the number of layers for order = 2
  std::vector<unsigned int> mod_ring_layers(ring_layers);
  std::for_each(
      mod_ring_layers.begin(), mod_ring_layers.end(), [&order](unsigned int & n) { n *= order; });
  // For ring_radial_biases, modification is to take the square root of the original biases for
  // order = 2
  std::vector<Real> mod_ring_radial_biases(ring_radial_biases);
  std::for_each(mod_ring_radial_biases.begin(),
                mod_ring_radial_biases.end(),
                [&order](Real & n) { n = std::pow(n, 1.0 / order); });
  // ducts_layers is similar to ring_layers
  std::vector<unsigned int> mod_ducts_layers(ducts_layers);
  std::for_each(
      mod_ducts_layers.begin(), mod_ducts_layers.end(), [&order](unsigned int & n) { n *= order; });
  // duct_radial_biases is similar to ring_radial_biases
  std::vector<Real> mod_duct_radial_biases(duct_radial_biases);
  std::for_each(mod_duct_radial_biases.begin(),
                mod_duct_radial_biases.end(),
                [&order](Real & n) { n = std::pow(n, 1.0 / order); });
  // Azimuthal mesh density is also doubled for order = 2
  const unsigned int mod_num_sectors_per_side = num_sectors_per_side * order;
  const unsigned int mod_background_intervals = background_intervals * order;
  // background_radial_bias is similar to ring_radial_biases
  const Real mod_background_radial_bias = std::pow(background_radial_bias, 1.0 / order);
  // Perform similar modifications for boundary layer parameters
  const auto mod_ring_inner_boundary_layer_params =
      modifiedMultiBdryLayerParamsCreator(ring_inner_boundary_layer_params, order);
  const auto mod_ring_outer_boundary_layer_params =
      modifiedMultiBdryLayerParamsCreator(ring_outer_boundary_layer_params, order);
  const auto mod_duct_inner_boundary_layer_params =
      modifiedMultiBdryLayerParamsCreator(duct_inner_boundary_layer_params, order);
  const auto mod_duct_outer_boundary_layer_params =
      modifiedMultiBdryLayerParamsCreator(duct_outer_boundary_layer_params, order);

  const auto mod_background_inner_boundary_layer_params =
      modifiedSingleBdryLayerParamsCreator(background_inner_boundary_layer_params, order);
  const auto mod_background_outer_boundary_layer_params =
      modifiedSingleBdryLayerParamsCreator(background_outer_boundary_layer_params, order);

  // The distance parameters of the rings and duct need to be modified too as they may be involved
  // in the boundary layer cases.
  std::vector<Real> mod_ducts_center_dist(ducts_center_dist);
  std::vector<Real> mod_ring_radii(ring_radii);
  bool has_rings(ring_radii.size());
  bool has_ducts(ducts_center_dist.size());
  bool has_background(background_intervals);
  auto mesh = buildReplicatedMesh(2);

  // Calculate biasing terms
  // background region needs to be split into three parts
  const auto main_background_bias_terms =
      biasTermsCalculator(background_radial_bias, background_intervals);
  const auto inner_background_bias_terms =
      biasTermsCalculator(background_inner_boundary_layer_params.bias,
                          background_inner_boundary_layer_params.intervals);
  const auto outer_background_bias_terms =
      biasTermsCalculator(background_outer_boundary_layer_params.bias,
                          background_outer_boundary_layer_params.intervals);
  auto rings_bias_terms = biasTermsCalculator(ring_radial_biases,
                                              ring_layers,
                                              ring_inner_boundary_layer_params,
                                              ring_outer_boundary_layer_params);
  auto duct_bias_terms = biasTermsCalculator(duct_radial_biases,
                                             ducts_layers,
                                             duct_inner_boundary_layer_params,
                                             duct_outer_boundary_layer_params);
  // Equivalent "mod_" parts
  const auto mod_main_background_bias_terms =
      biasTermsCalculator(mod_background_radial_bias, mod_background_intervals);
  const auto mod_inner_background_bias_terms =
      biasTermsCalculator(mod_background_inner_boundary_layer_params.bias,
                          mod_background_inner_boundary_layer_params.intervals);
  const auto mod_outer_background_bias_terms =
      biasTermsCalculator(mod_background_outer_boundary_layer_params.bias,
                          mod_background_outer_boundary_layer_params.intervals);
  auto mod_rings_bias_terms = biasTermsCalculator(mod_ring_radial_biases,
                                                  mod_ring_layers,
                                                  mod_ring_inner_boundary_layer_params,
                                                  mod_ring_outer_boundary_layer_params);
  auto mod_duct_bias_terms = biasTermsCalculator(mod_duct_radial_biases,
                                                 mod_ducts_layers,
                                                 mod_duct_inner_boundary_layer_params,
                                                 mod_duct_outer_boundary_layer_params);

  std::vector<unsigned int> total_ring_layers;
  for (unsigned int i = 0; i < ring_layers.size(); i++)
    total_ring_layers.push_back(ring_layers[i] + ring_inner_boundary_layer_params.intervals[i] +
                                ring_outer_boundary_layer_params.intervals[i]);

  if (background_inner_boundary_layer_params.intervals)
  {
    total_ring_layers.push_back(background_inner_boundary_layer_params.intervals);
    rings_bias_terms.push_back(inner_background_bias_terms);
    ring_radii.push_back((ring_radii.empty() ? 0.0 : ring_radii.back()) +
                         background_inner_boundary_layer_params.width);
    has_rings = true;
  }
  std::vector<unsigned int> mod_total_ring_layers;
  for (unsigned int i = 0; i < mod_ring_layers.size(); i++)
    mod_total_ring_layers.push_back(mod_ring_layers[i] +
                                    mod_ring_inner_boundary_layer_params.intervals[i] +
                                    mod_ring_outer_boundary_layer_params.intervals[i]);

  if (mod_background_inner_boundary_layer_params.intervals)
  {
    mod_total_ring_layers.push_back(mod_background_inner_boundary_layer_params.intervals);
    mod_rings_bias_terms.push_back(mod_inner_background_bias_terms);
    mod_ring_radii.push_back((mod_ring_radii.empty() ? 0.0 : mod_ring_radii.back()) +
                             mod_background_inner_boundary_layer_params.width);
    // has_rings should be modified before in the none "mod_" part
  }

  std::vector<unsigned int> total_ducts_layers;
  if (background_outer_boundary_layer_params.intervals)
  {
    total_ducts_layers.push_back(background_outer_boundary_layer_params.intervals);
    duct_bias_terms.insert(duct_bias_terms.begin(), outer_background_bias_terms);
    ducts_center_dist.insert(ducts_center_dist.begin(),
                             (ducts_center_dist.empty()
                                  ? pitch / 2.0 / std::cos(M_PI / virtual_side_number)
                                  : ducts_center_dist.front()) -
                                 background_outer_boundary_layer_params.width);
    has_ducts = true;
  }
  for (unsigned int i = 0; i < ducts_layers.size(); i++)
    total_ducts_layers.push_back(ducts_layers[i] + duct_inner_boundary_layer_params.intervals[i] +
                                 duct_outer_boundary_layer_params.intervals[i]);

  std::vector<unsigned int> mod_total_ducts_layers;
  if (mod_background_outer_boundary_layer_params.intervals)
  {
    mod_total_ducts_layers.push_back(mod_background_outer_boundary_layer_params.intervals);
    mod_duct_bias_terms.insert(mod_duct_bias_terms.begin(), mod_outer_background_bias_terms);
    mod_ducts_center_dist.insert(mod_ducts_center_dist.begin(),
                                 (mod_ducts_center_dist.empty()
                                      ? pitch / 2.0 / std::cos(M_PI / virtual_side_number)
                                      : mod_ducts_center_dist.front()) -
                                     mod_background_outer_boundary_layer_params.width);
    // has_ducts should be modified before in the none "mod_" part
  }
  for (unsigned int i = 0; i < mod_ducts_layers.size(); i++)
    mod_total_ducts_layers.push_back(mod_ducts_layers[i] +
                                     mod_duct_inner_boundary_layer_params.intervals[i] +
                                     mod_duct_outer_boundary_layer_params.intervals[i]);

  unsigned int angle_number = azimuthal_tangent.size() == 0
                                  ? num_sectors_per_side
                                  : ((azimuthal_tangent.size() - 1) / order);
  unsigned int mod_angle_number =
      azimuthal_tangent.size() == 0 ? mod_num_sectors_per_side : (azimuthal_tangent.size() - 1);

  // Geometries
  const Real corner_to_corner =
      pitch / std::cos(M_PI / virtual_side_number); // distance of bin center to cell corner
  const Real corner_p[2][2] = {
      {0.0, 0.5 * corner_to_corner},
      {0.5 * corner_to_corner * pitch_scale_factor * std::sin(2.0 * M_PI / virtual_side_number),
       0.5 * corner_to_corner * pitch_scale_factor * std::cos(2.0 * M_PI / virtual_side_number)}};
  const unsigned int div_num = angle_number / 2 + 1;
  const unsigned int mod_div_num = mod_angle_number / 2 + 1;

  // From now on, we work on the nodes, which need the "mod_" parameters
  std::vector<std::vector<Node *>> nodes(mod_div_num, std::vector<Node *>(mod_div_num));
  if (quad_center_elements)
  {
    Real ring_radii_0;

    if (has_rings)
      ring_radii_0 = ring_radii.front() * mod_rings_bias_terms.front()[order - 1];
    else if (has_ducts)
      ring_radii_0 = mod_ducts_center_dist.front() * std::cos(M_PI / virtual_side_number) *
                     mod_main_background_bias_terms[order - 1];
    else
      ring_radii_0 = pitch / 2.0 * mod_main_background_bias_terms[order - 1];
    // If center_quad_factor is zero, default value (div_num - 1)/div_num  is used.
    // We use div_num instead of mod_div_num because we are dealing wth elements here
    // This approach ensures that the order = 2 mesh elements are consistent with the order = 1
    ring_radii_0 *=
        center_quad_factor == 0.0 ? (((Real)div_num - 1.0) / (Real)div_num) : center_quad_factor;

    centerNodes(*mesh, virtual_side_number, mod_div_num, ring_radii_0, nodes);
  }
  else // pin-cell center
    mesh->add_point(Point(0.0, 0.0, 0.0));

  // create nodes for the ring regions
  if (has_rings)
    ringNodes(*mesh,
              ring_radii,
              mod_total_ring_layers,
              mod_rings_bias_terms,
              mod_num_sectors_per_side,
              corner_p,
              corner_to_corner,
              azimuthal_tangent);

  if (has_background)
  {
    // add nodes in background region; the background region is defined as the area between the
    // outermost pin (if there is a pin; if no pin, the center) and the innermost hex/duct; if
    // _has_ducts is false, the background region is the area between the pin and enclosing hexagon
    Real background_corner_radial_interval_length;
    Real background_corner_distance;
    Real background_in;
    Real background_out; // background outer frontier
    if (has_rings)
      background_in = ring_radii.back();
    else
      background_in = 0;

    if (has_ducts)
    {
      background_out = mod_ducts_center_dist.front();
      background_corner_distance =
          mod_ducts_center_dist
              .front(); // it is the center to duct (innermost duct) corner distance
    }
    else
    {
      background_out = 0.5 * corner_to_corner;
      background_corner_distance =
          0.5 * corner_to_corner; // it is the center to hex corner distance
    }

    background_corner_radial_interval_length =
        (background_out - background_in) / mod_background_intervals;

    node_id_background_meta = mesh->n_nodes();

    // create nodes for background region
    backgroundNodes(*mesh,
                    mod_num_sectors_per_side,
                    mod_background_intervals,
                    mod_main_background_bias_terms,
                    background_corner_distance,
                    background_corner_radial_interval_length,
                    corner_p,
                    corner_to_corner,
                    background_in,
                    azimuthal_tangent);
  }

  // create nodes for duct regions
  if (has_ducts)
    ductNodes(*mesh,
              &mod_ducts_center_dist,
              mod_total_ducts_layers,
              mod_duct_bias_terms,
              mod_num_sectors_per_side,
              corner_p,
              corner_to_corner,
              azimuthal_tangent);

  // See if the central region is the only part of the innermost part
  // The central region of the slice is special.
  // Unlike the outer regions, which are layered quad elements,
  // the central region is either a layer of tri elements or a specially-patterned quad elements.
  // If there is at least one `ring` defined in the slice,
  // the central region must belong to the innermost (first) ring.
  // Otherwise the central region belongs to the `background`
  // In either case, if the innermost ring or background has only one radial interval,
  // the central region is an independent ring or background
  // Otherwise, the central region and one or several quad element layers together form the
  // innermost ring or background
  bool is_central_region_independent;
  if (ring_layers.empty())
    is_central_region_independent = mod_background_inner_boundary_layer_params.intervals +
                                        mod_background_intervals +
                                        mod_background_outer_boundary_layer_params.intervals ==
                                    1;
  else
    is_central_region_independent = mod_ring_layers[0] +
                                        mod_ring_inner_boundary_layer_params.intervals[0] +
                                        mod_ring_outer_boundary_layer_params.intervals[0] ==
                                    1;

  // From now on, we work on the elements, which need the none "mod_" parameters
  // Assign elements, boundaries, and subdomains;
  // Add Tri3/Tri6/Tri7 or Quad4/Quad8/Quad9 mesh into innermost (central) region
  if (quad_center_elements)
    cenQuadElemDef(*mesh,
                   div_num,
                   block_id_shift,
                   create_outward_interface_boundaries && is_central_region_independent,
                   boundary_id_shift,
                   nodes,
                   (!has_rings) && (!has_ducts) && (background_intervals == 1),
                   // Note here, has_ring means either there are ring regions or background inner
                   // boundary layer; has_ducts means either there are duct regions or background
                   // outer boundary layer. Same in cenTriElemDef()
                   side_index,
                   generate_side_specific_boundaries,
                   quad_elem_type);
  else
    cenTriElemDef(
        *mesh,
        num_sectors_per_side,
        azimuthal_tangent,
        block_id_shift,
        create_outward_interface_boundaries && is_central_region_independent,
        boundary_id_shift,
        ((!has_rings) && (!has_ducts) && (background_intervals == 1)) ||
            ((!has_background) &&
             (std::accumulate(total_ring_layers.begin(), total_ring_layers.end(), 0) == 1)),
        // Only for ACCG, it is possible that the entire mesh is a single-layer ring.
        // cenQuadElemDef() does not need this as it does not work for ACCG.
        side_index,
        generate_side_specific_boundaries,
        tri_elem_type);

  // Add Quad4 mesh into outer circle
  // total number of mesh should be all the rings for pin regions + background regions;
  // total number of quad mesh should be total number of mesh -1 (-1 is because the inner circle for
  // tri/quad mesh has been added above)

  std::vector<unsigned int> subdomain_rings;
  if (has_rings) //  define the rings in each subdomain
  {
    subdomain_rings = total_ring_layers;
    subdomain_rings.front() -= 1; // remove the inner TRI mesh subdomain
    if (background_inner_boundary_layer_params.intervals)
    {
      subdomain_rings.back() =
          background_inner_boundary_layer_params.intervals + background_intervals +
          background_outer_boundary_layer_params.intervals; // add the background region
      if (ring_radii.size() == 1)
        subdomain_rings.back() -= 1; // remove the inner TRI mesh subdomain
    }
    else if (has_background)
      subdomain_rings.push_back(background_inner_boundary_layer_params.intervals +
                                background_intervals +
                                background_outer_boundary_layer_params.intervals);
  }
  else
  {
    subdomain_rings.push_back(
        background_inner_boundary_layer_params.intervals + background_intervals +
        background_outer_boundary_layer_params.intervals); // add the background region
    subdomain_rings[0] -= 1;                               // remove the inner TRI mesh subdomain
  }

  if (has_ducts)
    for (unsigned int i = (background_outer_boundary_layer_params.intervals > 0);
         i < total_ducts_layers.size();
         i++)
      subdomain_rings.push_back(total_ducts_layers[i]);

  quadElemDef(*mesh,
              num_sectors_per_side,
              subdomain_rings,
              side_index,
              azimuthal_tangent,
              block_id_shift,
              quad_center_elements ? (mod_div_num * mod_div_num - 1) : 0,
              create_inward_interface_boundaries,
              create_outward_interface_boundaries,
              boundary_id_shift,
              generate_side_specific_boundaries,
              quad_elem_type);
  if (tri_elem_type == TRI_ELEM_TYPE::TRI6 || quad_elem_type == QUAD_ELEM_TYPE::QUAD8)
    mesh->remove_orphaned_nodes();
  return mesh;
}

cenQuadElemDef()

void PolygonMeshGeneratorBase::cenQuadElemDef ( ReplicatedMesh &  mesh, const unsigned int  div_num, const subdomain_id_type  block_id_shift, const bool  create_outward_interface_boundaries, const boundary_id_type  boundary_id_shift, std::vector< std::vector< Node *>> &  nodes, const bool  assign_external_boundary = false, const unsigned int  side_index = 0, const bool  generate_side_specific_boundaries = true, const QUAD_ELEM_TYPE  quad_elem_type = QUAD_ELEM_TYPE::QUAD4  ) const

protectedinherited

Defines quad elements in the very central region of the polygon.

Parameters

mesh	input mesh to create the elements onto
div_num	division number of the central mesh layer
block_id_shift	shift of the subdomain ids generated by this function
create_outward_interface_boundaries	whether outward interface boundary sidesets are created
boundary_id_shift	shift of the interface boundary ids
id_array	pointer to a vector that contains the node_ids with basic geometry information
assign_external_boundary	whether the external boundary ids are assigned
side_index	index of the polygon side (only used if external boundary ids are assigned)
generate_side_specific_boundaries	whether the side-specific external boundaries are generated or not
quad_elem_type	type of the quadrilateral elements to be generated

Definition at line 853 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildSlice().

{

  BoundaryInfo & boundary_info = mesh.get_boundary_info();

  // This loop defines quad elements for the central regions except for the outermost layer
  for (unsigned int i = 0; i < div_num - 1; i++)
  {
    unsigned int id_x = 0;
    unsigned int id_y = i;
    for (unsigned int j = 0; j < 2 * i + 1; j++)
    {
      std::unique_ptr<Elem> new_elem;
      if (quad_elem_type == QUAD_ELEM_TYPE::QUAD4)
      {
        new_elem = std::make_unique<Quad4>();
        new_elem->set_node(0, nodes[id_x][id_y]);
        new_elem->set_node(3, nodes[id_x][id_y + 1]);
        new_elem->set_node(2, nodes[id_x + 1][id_y + 1]);
        new_elem->set_node(1, nodes[id_x + 1][id_y]);
        new_elem->subdomain_id() = 1 + block_id_shift;
      }
      else // QUAD8/QUAD9
      {
        new_elem = std::make_unique<Quad8>();
        if (quad_elem_type == QUAD_ELEM_TYPE::QUAD9)
        {
          new_elem = std::make_unique<Quad9>();
          new_elem->set_node(8, nodes[id_x * 2 + 1][id_y * 2 + 1]);
        }
        new_elem->set_node(0, nodes[id_x * 2][id_y * 2]);
        new_elem->set_node(3, nodes[id_x * 2][id_y * 2 + 2]);
        new_elem->set_node(2, nodes[id_x * 2 + 2][id_y * 2 + 2]);
        new_elem->set_node(1, nodes[id_x * 2 + 2][id_y * 2]);
        new_elem->set_node(4, nodes[id_x * 2 + 1][id_y * 2]);
        new_elem->set_node(5, nodes[id_x * 2 + 2][id_y * 2 + 1]);
        new_elem->set_node(6, nodes[id_x * 2 + 1][id_y * 2 + 2]);
        new_elem->set_node(7, nodes[id_x * 2][id_y * 2 + 1]);
        new_elem->subdomain_id() = 1 + block_id_shift;
      }
      Elem * elem_Quad = mesh.add_elem(std::move(new_elem));

      if (id_x == 0)
        boundary_info.add_side(elem_Quad, 3, SLICE_BEGIN);
      if (id_y == 0)
        boundary_info.add_side(elem_Quad, 0, SLICE_END);
      if (j < i)
        id_x++;
      if (j >= i)
        id_y--;
    }
  }
  // This loop defines the outermost layer quad elements of the central region
  for (unsigned int i = (div_num - 1) * (div_num - 1); i < div_num * div_num - 1; i++)
  {
    std::unique_ptr<Elem> new_elem;
    if (quad_elem_type == QUAD_ELEM_TYPE::QUAD4)
    {
      new_elem = std::make_unique<Quad4>();
      new_elem->set_node(0, mesh.node_ptr(i));
      new_elem->set_node(3, mesh.node_ptr(i + 2 * div_num - 1));
      new_elem->set_node(2, mesh.node_ptr(i + 2 * div_num));
      new_elem->set_node(1, mesh.node_ptr(i + 1));
    }
    else // QUAD8/QUAD9
    {
      new_elem = std::make_unique<Quad8>();
      if (quad_elem_type == QUAD_ELEM_TYPE::QUAD9)
      {
        new_elem = std::make_unique<Quad9>();
        new_elem->set_node(8,
                           mesh.node_ptr((div_num - 1) * (div_num - 1) * 4 +
                                         (i - (div_num - 1) * (div_num - 1)) * 2 + 1 +
                                         ((div_num - 1) * 4 + 1)));
      }
      new_elem->set_node(0,
                         mesh.node_ptr((div_num - 1) * (div_num - 1) * 4 +
                                       (i - (div_num - 1) * (div_num - 1)) * 2));
      new_elem->set_node(3,
                         mesh.node_ptr((div_num - 1) * (div_num - 1) * 4 +
                                       (i - (div_num - 1) * (div_num - 1)) * 2 +
                                       ((div_num - 1) * 4 + 1) * 2));
      new_elem->set_node(2,
                         mesh.node_ptr((div_num - 1) * (div_num - 1) * 4 +
                                       (i - (div_num - 1) * (div_num - 1)) * 2 + 2 +
                                       ((div_num - 1) * 4 + 1) * 2));
      new_elem->set_node(1,
                         mesh.node_ptr((div_num - 1) * (div_num - 1) * 4 +
                                       (i - (div_num - 1) * (div_num - 1)) * 2 + 2));
      new_elem->set_node(4,
                         mesh.node_ptr((div_num - 1) * (div_num - 1) * 4 +
                                       (i - (div_num - 1) * (div_num - 1)) * 2 + 1));
      new_elem->set_node(5,
                         mesh.node_ptr((div_num - 1) * (div_num - 1) * 4 +
                                       (i - (div_num - 1) * (div_num - 1)) * 2 + 2 +
                                       ((div_num - 1) * 4 + 1)));
      new_elem->set_node(6,
                         mesh.node_ptr((div_num - 1) * (div_num - 1) * 4 +
                                       (i - (div_num - 1) * (div_num - 1)) * 2 + 1 +
                                       ((div_num - 1) * 4 + 1) * 2));
      new_elem->set_node(7,
                         mesh.node_ptr((div_num - 1) * (div_num - 1) * 4 +
                                       (i - (div_num - 1) * (div_num - 1)) * 2 +
                                       ((div_num - 1) * 4 + 1)));
    }

    Elem * elem_Quad = mesh.add_elem(std::move(new_elem));
    elem_Quad->subdomain_id() = 1 + block_id_shift;
    if (create_outward_interface_boundaries)
      boundary_info.add_side(elem_Quad, 2, 1 + boundary_id_shift);
    if (i == (div_num - 1) * (div_num - 1))
      boundary_info.add_side(elem_Quad, 3, SLICE_BEGIN);
    if (i == div_num * div_num - 2)
      boundary_info.add_side(elem_Quad, 1, SLICE_END);
    if (assign_external_boundary)
    {
      boundary_info.add_side(elem_Quad, 2, OUTER_SIDESET_ID);
      if (generate_side_specific_boundaries)
        boundary_info.add_side(
            elem_Quad,
            2,
            (i < div_num * (div_num - 1) ? OUTER_SIDESET_ID : OUTER_SIDESET_ID_ALT) + side_index);
    }
  }
}

centerNodes()

void PolygonMeshGeneratorBase::centerNodes ( ReplicatedMesh &  mesh, const Real  virtual_side_number, const unsigned int  div_num, const Real  ring_radii_0, std::vector< std::vector< Node *>> &  nodes  ) const

protectedinherited

Creates nodes of the very central mesh layer of the polygon for quad central elements.

Parameters

mesh	input mesh to add the nodes onto
virtual_side_number	virtual number of sides of the polygon (360/slice_azimuthal)
div_num	division number of the central mesh layer
ring_radii_0	radius of the central mesh layer
nodes	pointer to the mesh's nodes
nodes	vector that contains the nodes with basic geometry information

Definition at line 577 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildSlice().

{
  const std::pair<Real, Real> p_origin = std::make_pair(0.0, 0.0);
  const std::pair<Real, Real> p_bottom =
      std::make_pair(0.0, ring_radii_0 * std::cos(M_PI / virtual_side_number));
  const std::pair<Real, Real> p_top =
      std::make_pair(p_bottom.second * std::sin(2.0 * M_PI / virtual_side_number),
                     p_bottom.second * std::cos(2.0 * M_PI / virtual_side_number));
  const std::pair<Real, Real> p_diag =
      std::make_pair(ring_radii_0 * std::sin(M_PI / virtual_side_number),
                     ring_radii_0 * std::cos(M_PI / virtual_side_number));

  // The four vertices of the central quad region are defined above.
  // The following loops transverse all the nodes within this central quad region by moving p1 thru
  // p4 and calculate the four-point intercept (pc).
  //  p_top------o-------p4--------o-----p_diag
  //    |        |        |        |        |
  //    |        |        |        |        |
  //    o--------o--------o--------o--------o
  //    |        |        |        |        |
  //    |        |        |        |        |
  //   p1--------o-------pc--------o-------p2
  //    |        |        |        |        |
  //    |        |        |        |        |
  //    o--------o--------o--------o--------o
  //    |        |        |        |        |
  //    |        |        |        |        |
  // p_origin-----o-------p3--------o----p_bottom
  //
  // The loops are designed to transverse the nodes as shown below to facilitate elements
  // and sides creation.
  //
  //   25-------24-------23-------22-------21
  //    |        |        |        |        |
  //    |        |        |        |        |
  //   16-------15-------14-------13-------20
  //    |        |        |        |        |
  //    |        |        |        |        |
  //    9--------8------- 7-------12-------19
  //    |        |        |        |        |
  //    |        |        |        |        |
  //    4--------3--------6-------11-------18
  //    |        |        |        |        |
  //    |        |        |        |        |
  //    1--------2--------5-------10-------17

  for (unsigned int i = 0; i < div_num; i++)
  {
    unsigned int id_x = 0;
    unsigned int id_y = i;
    for (unsigned int j = 0; j < 2 * i + 1; j++)
    {
      std::pair<Real, Real> p1 = std::make_pair(
          (p_origin.first * (div_num - 1 - id_x) + p_top.first * id_x) / (div_num - 1),
          (p_origin.second * (div_num - 1 - id_x) + p_top.second * id_x) / (div_num - 1));
      std::pair<Real, Real> p2 = std::make_pair(
          (p_bottom.first * (div_num - 1 - id_x) + p_diag.first * id_x) / (div_num - 1),
          (p_bottom.second * (div_num - 1 - id_x) + p_diag.second * id_x) / (div_num - 1));
      std::pair<Real, Real> p3 = std::make_pair(
          (p_origin.first * (div_num - 1 - id_y) + p_bottom.first * id_y) / (div_num - 1),
          (p_origin.second * (div_num - 1 - id_y) + p_bottom.second * id_y) / (div_num - 1));
      std::pair<Real, Real> p4 = std::make_pair(
          (p_top.first * (div_num - 1 - id_y) + p_diag.first * id_y) / (div_num - 1),
          (p_top.second * (div_num - 1 - id_y) + p_diag.second * id_y) / (div_num - 1));
      std::pair<Real, Real> pc = fourPointIntercept(p1, p2, p3, p4);
      nodes[id_x][id_y] = mesh.add_point(Point(pc.first, pc.second, 0.0));
      if (j < i)
        id_x++;
      if (j >= i)
        id_y--;
    }
  }
}

cenTriElemDef()

void PolygonMeshGeneratorBase::cenTriElemDef ( ReplicatedMesh &  mesh, const unsigned int  num_sectors_per_side, const std::vector< Real >  azimuthal_tangent = std::vector<Real>(), const subdomain_id_type  block_id_shift = 0, const bool  create_outward_interface_boundaries = true, const boundary_id_type  boundary_id_shift = 0, const bool  assign_external_boundary = false, const unsigned int  side_index = 0, const bool  generate_side_specific_boundaries = true, const TRI_ELEM_TYPE  tri_elem_type = TRI_ELEM_TYPE::TRI3  ) const

protectedinherited

Defines triangular elements in the very central region of the polygon.

Parameters

mesh	input mesh to create the elements onto
num_sectors_per_side	number of azimuthal intervals
azimuthal_tangent	vector of tangent values of the azimuthal angles as reference for adaptive boundary matching
block_id_shift	shift of the subdomain ids generated by this function
create_outward_interface_boundaries	whether outward interface boundary sidesets are created
boundary_id_shift	shift of the interface boundary ids
assign_external_boundary	whether the external boundary ids are assigned
side_index	index of the polygon side (only used if external boundary ids are assigned)
generate_side_specific_boundaries	whether the side-specific external boundaries are generated or not
tri_elem_type	type of the triangular elements to be generated

Definition at line 989 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildSlice().

{
  const unsigned short order = tri_elem_type == TRI_ELEM_TYPE::TRI3 ? 1 : 2;
  unsigned int angle_number = azimuthal_tangent.size() == 0
                                  ? num_sectors_per_side
                                  : ((azimuthal_tangent.size() - 1) / order);

  BoundaryInfo & boundary_info = mesh.get_boundary_info();
  for (unsigned int i = 1; i <= angle_number; i++)
  {
    std::unique_ptr<Elem> new_elem;
    if (tri_elem_type == TRI_ELEM_TYPE::TRI3)
    {
      new_elem = std::make_unique<Tri3>();
      new_elem->set_node(0, mesh.node_ptr(0));
      new_elem->set_node(2, mesh.node_ptr(i));
      new_elem->set_node(1, mesh.node_ptr(i + 1));
    }
    else // TRI6/TRI7
    {
      new_elem = std::make_unique<Tri6>();
      if (tri_elem_type == TRI_ELEM_TYPE::TRI7)
      {
        new_elem = std::make_unique<Tri7>();
        new_elem->set_node(6, mesh.node_ptr(i * 2));
      }
      new_elem->set_node(0, mesh.node_ptr(0));
      new_elem->set_node(2, mesh.node_ptr(i * 2 + angle_number * order));
      new_elem->set_node(1, mesh.node_ptr((i + 1) * 2 + angle_number * order));
      new_elem->set_node(3, mesh.node_ptr(i * 2 + 1));
      new_elem->set_node(5, mesh.node_ptr(i * 2 - 1));
      new_elem->set_node(4, mesh.node_ptr(i * 2 + 1 + angle_number * order));
    }

    Elem * elem = mesh.add_elem(std::move(new_elem));
    if (create_outward_interface_boundaries)
      boundary_info.add_side(elem, 1, 1 + boundary_id_shift);
    elem->subdomain_id() = 1 + block_id_shift;
    if (i == 1)
      boundary_info.add_side(elem, 2, SLICE_BEGIN);
    if (i == angle_number)
      boundary_info.add_side(elem, 0, SLICE_END);
    if (assign_external_boundary)
    {
      boundary_info.add_side(elem, 1, OUTER_SIDESET_ID);
      if (generate_side_specific_boundaries)
        boundary_info.add_side(elem,
                               1,
                               (i <= angle_number / 2 ? OUTER_SIDESET_ID : OUTER_SIDESET_ID_ALT) +
                                   side_index);
    }
  }
}

cutOffPolyDeform()

void PolygonMeshGeneratorBase::cutOffPolyDeform ( MeshBase &  mesh, const Real  orientation, const Real  y_max_0, const Real  y_max_n, const Real  y_min, const unsigned int  mesh_type, const Real  unit_angle = 60.0, const Real  tols = 1E-5  ) const

protectedinherited

Deforms peripheral region when the external side of a polygon assembly of stitched meshes cuts off the stitched meshes.

Parameters

mesh	input mesh to be deformed
orientation	orientation angle of the input mesh (move the deformation direction to y)
y_max_0	original maximum y position
y_max_n	maximum y position after deformation
y_min	minimum y position that is affected by the deformation
mesh_type	whether the peripheral region is for a corner or a side hexagon mesh.
tols	tolerance used to determine the boundary of deformation region
unit_angle	unit angle of the geometry, which is 60.0 for hexagonal and 90.0 for square

Returns

n/a (input mesh is directly altered)

Definition at line 1329 of file PolygonMeshGeneratorBase.C.

Referenced by PatternedHexMeshGenerator::generate(), and PatternedCartesianMeshGenerator::generate().

{
  for (auto & node_ptr : as_range(mesh.nodes_begin(), mesh.nodes_end()))
  {
    // This function can definitely be optimized in future for better efficiency.
    Real & x = (*node_ptr)(0);
    Real & y = (*node_ptr)(1);
    if (mesh_type == CORNER_MESH)
    {
      nodeCoordRotate(x, y, orientation);
      if (x >= 0.0 && y > y_max_0)
        y = y - y_max_0 + y_max_n;
      else if (x >= 0.0 && y >= y_min)
        y = (y - y_min) / (y_max_0 - y_min) * (y_max_n - y_min) + y_min;
      else if (y > -x / std::tan(unit_angle / 360.0 * M_PI) + tols && y > y_max_0)
      {
        x /= y;
        y = y - y_max_0 + y_max_n;
        x *= y;
      }
      else if (y > -x / std::tan(unit_angle / 360.0 * M_PI) + tols && y >= y_min)
      {
        x /= y;
        y = (y - y_min) / (y_max_0 - y_min) * (y_max_n - y_min) + y_min;
        x *= y;
      }
      nodeCoordRotate(x, y, -orientation);

      nodeCoordRotate(x, y, orientation - unit_angle);
      if (x <= 0 && y > y_max_0)
        y = y - y_max_0 + y_max_n;
      else if (x <= 0 && y >= y_min)
        y = (y - y_min) / (y_max_0 - y_min) * (y_max_n - y_min) + y_min;
      else if (y >= x / std::tan(unit_angle / 360.0 * M_PI) - tols && y > y_max_0)
      {
        x /= y;
        y = y - y_max_0 + y_max_n;
        x *= y;
      }
      else if (y >= x / std::tan(unit_angle / 360.0 * M_PI) - tols && y >= y_min)
      {
        x /= y;
        y = (y - y_min) / (y_max_0 - y_min) * (y_max_n - y_min) + y_min;
        x *= y;
      }
      nodeCoordRotate(x, y, unit_angle - orientation);
    }
    else
    {
      nodeCoordRotate(x, y, orientation);
      if (y > y_max_0)
        y = y - y_max_0 + y_max_n;
      else if (y >= y_min)
        y = (y - y_min) / (y_max_0 - y_min) * (y_max_n - y_min) + y_min;
      nodeCoordRotate(x, y, -orientation);
    }
  }
}

ductNodes()

void PolygonMeshGeneratorBase::ductNodes ( ReplicatedMesh &  mesh, std::vector< Real > *const  ducts_center_dist, const std::vector< unsigned int >  ducts_layers, const std::vector< std::vector< Real >>  biased_terms, const unsigned int  num_sectors_per_side, const Real  corner_p[2][2], const Real  corner_to_corner, const std::vector< Real >  azimuthal_tangent = std::vector<Real>()  ) const

protectedinherited

Creates nodes for the duct-geometry region of a single slice.

Parameters

mesh	input mesh to add the nodes onto
ducts_center_dist	distance parameters of the duct regions
ducts_layers	numbers of radial intervals of the duct regions
biased_terms	normalized spacing values used for radial meshing biasing in duct region
num_sectors_per_side	number of azimuthal intervals
corner_p[2][2]	array contains the coordinates of the corner positions
corner_to_corner	diameter of the circumscribed circle of the polygon
azimuthal_tangent	vector of tangent values of the azimuthal angles as reference for adaptive boundary matching

Definition at line 792 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildSlice().

{
  unsigned int angle_number =
      azimuthal_tangent.size() == 0 ? num_sectors_per_side : (azimuthal_tangent.size() - 1);
  // Add nodes in ducts regions
  (*ducts_center_dist)
      .push_back(0.5 * corner_to_corner); // add hex boundary as the last element in this vector
  std::vector<Real> duct_radius_interval_length(ducts_layers.size());

  Real bin_radial_distance;
  for (unsigned int l = 0; l < ducts_layers.size(); l++)
  {
    duct_radius_interval_length[l] =
        ((*ducts_center_dist)[l + 1] - (*ducts_center_dist)[l]) /
        ducts_layers[l]; // the pin radius interval for each ring_radii/subdomain

    // add rings in each pin subdomain
    for (unsigned int k = 0; k < ducts_layers[l]; k++)
    {
      bin_radial_distance = ((*ducts_center_dist)[l] +
                             biased_terms[l][k] * ducts_layers[l] * duct_radius_interval_length[l]);
      const Real pin_corner_p_x = corner_p[0][0] * bin_radial_distance / (0.5 * corner_to_corner);
      const Real pin_corner_p_y = corner_p[0][1] * bin_radial_distance / (0.5 * corner_to_corner);

      // pin_corner_p(s) are the points in the pin region, on the bins towards the six corners,
      // at different intervals
      mesh.add_point(Point(pin_corner_p_x, pin_corner_p_y, 0.0));

      for (unsigned int j = 1; j <= angle_number; j++)
      {
        const Real cell_boundary_p_x =
            corner_p[0][0] + (corner_p[1][0] - corner_p[0][0]) *
                                 (azimuthal_tangent.size() == 0 ? ((Real)j / (Real)angle_number)
                                                                : (azimuthal_tangent[j] / 2.0));
        const Real cell_boundary_p_y =
            corner_p[0][1] + (corner_p[1][1] - corner_p[0][1]) *
                                 (azimuthal_tangent.size() == 0 ? ((Real)j / (Real)angle_number)
                                                                : (azimuthal_tangent[j] / 2.0));
        // cell_boundary_p(s) are the points on the cell's six boundaries (flat sides) at
        // different azimuthal angles
        const Real pin_azimuthal_p_x =
            cell_boundary_p_x * bin_radial_distance / (0.5 * corner_to_corner);
        const Real pin_azimuthal_p_y =
            cell_boundary_p_y * bin_radial_distance / (0.5 * corner_to_corner);

        // pin_azimuthal_p are the points on the bins towards different azimuthal angles, at
        // different intervals; excluding the ones produced by pin_corner_p
        mesh.add_point(Point(pin_azimuthal_p_x, pin_azimuthal_p_y, 0.0));
      }
    }
  }
}

fourPointIntercept()

std::pair< Real, Real > PolygonMeshGeneratorBase::fourPointIntercept ( const std::pair< Real, Real > &  p1, const std::pair< Real, Real > &  p2, const std::pair< Real, Real > &  p3, const std::pair< Real, Real > &  p4  ) const

protectedinherited

Finds the center of a quadrilateral based on four vertices.

Parameters

p1	vertex 1
p2	vertex 2
p3	vertex 3
p4	vertex 4

Returns

the intecept point coordinate x and y

Definition at line 1396 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::centerNodes(), and AzimuthalBlockSplitGenerator::nodeModifier().

{
  const Real x1 = p1.first;
  const Real y1 = p1.second;
  const Real x2 = p2.first;
  const Real y2 = p2.second;
  const Real x3 = p3.first;
  const Real y3 = p3.second;
  const Real x4 = p4.first;
  const Real y4 = p4.second;

  Real x = -((x1 - x2) * (y3 * x4 - x3 * y4) - (x3 - x4) * (y1 * x2 - x1 * y2)) /
           ((y1 - y2) * (x3 - x4) - (y3 - y4) * (x1 - x2));
  Real y = -((y1 - y2) * (y3 * x4 - x3 * y4) - (y3 - y4) * (y1 * x2 - x1 * y2)) /
           ((y1 - y2) * (x3 - x4) - (y3 - y4) * (x1 - x2));

  return std::make_pair(x, y);
}

generate()

std::unique_ptr< MeshBase > TriPinHexAssemblyGenerator::generate ( )

overridevirtual

Reimplemented from PolygonMeshGeneratorBase.

Definition at line 211 of file TriPinHexAssemblyGenerator.C.

{
  /* Pair specified block names and ids */
  std::set<subdomain_id_type> tmp_block_ids;
  std::set<SubdomainName> tmp_block_names;
  std::vector<std::pair<subdomain_id_type, SubdomainName>> block_info;
  for (unsigned int i = 0; i < 3; i++)
    for (unsigned int j = 0; j < _ring_block_names[i].size(); j++)
    {
      tmp_block_names.emplace(_ring_block_names[i][j]);
      tmp_block_ids.emplace(_ring_block_ids[i].empty() ? (j + 1) : _ring_block_ids[i][j]);
      if (tmp_block_names.size() != tmp_block_ids.size())
        paramError("ring_block_names",
                   "The block name assignment must be compatible with the existing block ids.");
      else
        block_info.push_back(std::make_pair(
            _ring_block_ids[i].empty() ? (j + 1) : _ring_block_ids[i][j], _ring_block_names[i][j]));
    }
  const subdomain_id_type max_ring_radii_size =
      std::max({_ring_radii[0].size(), _ring_radii[1].size(), _ring_radii[2].size()});
  for (unsigned int i = 0; i < _background_block_names.size(); i++)
  {
    tmp_block_names.emplace(_background_block_names[i]);
    tmp_block_ids.emplace(_background_block_ids.empty() ? (max_ring_radii_size + i)
                                                        : _background_block_ids[i]);
    if (tmp_block_names.size() != tmp_block_ids.size())
      paramError("background_block_names",
                 "The block name assignment must be compatible with the existing block ids.");
    else
      block_info.push_back(std::make_pair(_background_block_ids.empty() ? (max_ring_radii_size + i)
                                                                        : _background_block_ids[i],
                                          _background_block_names[i]));
  }
  std::vector<std::vector<subdomain_id_type>> block_ids_new(3, std::vector<subdomain_id_type>());
  for (unsigned int i = 0; i < 3; i++)
  {
    if (_has_rings[i])
    {
      for (unsigned int j = 0; j < (_ring_radii[i].size() + (_ring_intervals[i][0] > 1)); j++)
        block_ids_new[i].push_back(_ring_block_ids[i].empty() ? j + 1 : _ring_block_ids[i][j]);
      block_ids_new[i].push_back(_background_block_ids.empty() ? max_ring_radii_size + 1
                                                               : _background_block_ids.back());
    }
    else
    {
      block_ids_new[i].push_back(_background_block_ids.empty() ? (max_ring_radii_size + 1)
                                                               : _background_block_ids.front());
      block_ids_new[i].push_back(_background_block_ids.empty() ? (max_ring_radii_size + 2)
                                                               : _background_block_ids.back());
    }
  }
  std::vector<std::unique_ptr<ReplicatedMesh>> meshes;
  for (unsigned int i = 0; i < 3; i++)
  {
    meshes.push_back(buildSinglePinSection(_side_length,
                                           _ring_offset,
                                           _ring_radii[i],
                                           _ring_intervals[i],
                                           _has_rings[i],
                                           _preserve_volumes,
                                           _num_sectors_per_side,
                                           _background_intervals,
                                           block_ids_new[i],
                                           _node_id_background_meta));
    // add sector ids
    if (isParamValid("sector_id_name"))
      setSectorExtraIDs(*meshes[i],
                        getParam<std::string>("sector_id_name"),
                        4,
                        std::vector<unsigned int>(4, _num_sectors_per_side));
    // add ring ids
    if (isParamValid("ring_id_name") && _has_rings[i])
      setRingExtraIDs(*meshes[i],
                      getParam<std::string>("ring_id_name"),
                      4,
                      std::vector<unsigned int>(4, _num_sectors_per_side),
                      _ring_intervals[i],
                      getParam<MooseEnum>("ring_id_assign_type") == "ring_wise",
                      false);

    if (!_pin_id_name.empty())
      meshes[i]->add_elem_integer(_pin_id_name, true, _pin_id_values[i]);
    if (i > 0)
    {
      MeshTools::Modification::rotate(*meshes[i], 120.0 * (Real)i, 0, 0);
      meshes[0]->stitch_meshes(*std::move(meshes[i]),
                               OUTER_SIDESET_ID,
                               OUTER_SIDESET_ID,
                               TOLERANCE,
                               /*clear_stitched_boundary_ids=*/true);
    }
  }

  if (_assembly_orientation == AssmOrient::pin_up)
    MeshTools::Modification::rotate(*meshes[0], 90, 0, 0);
  else
    MeshTools::Modification::rotate(*meshes[0], 270, 0, 0);
  /* Add subdomain names */
  for (const auto & block_info_pair : block_info)
    meshes[0]->subdomain_name(block_info_pair.first) = block_info_pair.second;
  if (_external_boundary_id > 0)
    MooseMesh::changeBoundaryId(*meshes[0], OUTER_SIDESET_ID, _external_boundary_id, false);
  if (!_external_boundary_name.empty())
  {
    meshes[0]->get_boundary_info().sideset_name(
        _external_boundary_id > 0 ? _external_boundary_id : (boundary_id_type)OUTER_SIDESET_ID) =
        _external_boundary_name;
    meshes[0]->get_boundary_info().nodeset_name(
        _external_boundary_id > 0 ? _external_boundary_id : (boundary_id_type)OUTER_SIDESET_ID) =
        _external_boundary_name;
  }
  meshes[0]->set_isnt_prepared();
  return dynamic_pointer_cast<MeshBase>(meshes[0]);
}

getInterfaceBoundaryIDs()

std::set< boundary_id_type > PolygonMeshGeneratorBase::getInterfaceBoundaryIDs ( const std::vector< std::vector< unsigned int >> &  pattern, const std::vector< std::vector< boundary_id_type >> &  interface_boundary_id_shift_pattern, const std::set< boundary_id_type > &  boundary_ids, const std::vector< std::set< boundary_id_type >> &  input_interface_boundary_ids, const bool  use_interface_boundary_id_shift, const bool  create_interface_boundary_id, const unsigned int  num_extra_layers  ) const

protectedinherited

returns a list of interface boundary IDs on the mesh generated by this mesh generator

Parameters

pattern	pattern of cells used in this mesh generator
interface_boundary_id_shift_pattern	2D pattern of shift values applied to the boundary IDs inside each pattern cells
boundary_ids	list of boundary IDs on the mesh generated by this mesh generator
input_interface_boundary_ids	list of interface boundary IDs of the pattern cells
use_interface_boundary_id_shift	whether ID shifts are applied to interface boundary IDs of the pattern cells
create_interface_boundary_id	whether interface boundary IDs are generated by this mesh generator
num_extra_layers	number of extra layers to define background and duct regions on the patterned mesh generated by this mesh generator

Definition at line 1722 of file PolygonMeshGeneratorBase.C.

Referenced by PatternedHexMeshGenerator::generate(), and PatternedCartesianMeshGenerator::generate().

{
  std::set<boundary_id_type> interface_boundary_ids;
  // add existing interface boundary ids from input meshes
  if (use_interface_boundary_id_shift)
  {
    for (const auto i : make_range(pattern.size()))
      for (const auto j : make_range(pattern[i].size()))
      {
        const auto & ids = input_interface_boundary_ids[pattern[i][j]];
        for (const auto & id : ids)
        {
          const boundary_id_type new_id = id + interface_boundary_id_shift_pattern[i][j];
          auto it = boundary_ids.find(new_id);
          if (it != boundary_ids.end())
            interface_boundary_ids.insert(new_id);
        }
      }
  }
  else
  {
    for (const auto & ids : input_interface_boundary_ids)
      for (const auto & id : ids)
      {
        auto it = boundary_ids.find(id);
        if (it != boundary_ids.end())
          interface_boundary_ids.insert(id);
      }
  }
  // add unshifted interface boundary ids for the duct & background regions
  if (create_interface_boundary_id)
    for (const auto i : make_range(num_extra_layers))
    {
      boundary_id_type id = SLICE_ALT + i * 2 + 1;
      auto it = boundary_ids.find(id);
      if (it != boundary_ids.end())
        interface_boundary_ids.insert(id);
      id = SLICE_ALT + i * 2;
      it = boundary_ids.find(id);
      if (it != boundary_ids.end())
        interface_boundary_ids.insert(id);
    }
  return interface_boundary_ids;
}

getRingParamValues()

template<typename T >

std::vector< std::vector< T > > TriPinHexAssemblyGenerator::getRingParamValues ( const std::string &  param_name ) const

private

Helper for getting a parameter that describes rings.

Definition at line 105 of file TriPinHexAssemblyGenerator.h.

{
  std::vector<std::vector<T>> value = {{}, {}, {}};

  if (isParamValid(param_name))
  {
    const auto & param_value = getParam<std::vector<std::vector<T>>>(param_name);
    if (param_value.size() == 1)
      value = {param_value[0], param_value[0], param_value[0]};
    else if (param_value.size() == 3)
      value = param_value;
    else if (param_value.size() != 0) // override case where you want to unset it
      paramError(param_name, "This parameter must have a size of one or three.");
  }

  return value;
}

modifiedMultiBdryLayerParamsCreator()

PolygonMeshGeneratorBase::multiBdryLayerParams PolygonMeshGeneratorBase::modifiedMultiBdryLayerParamsCreator ( const multiBdryLayerParams &  original_multi_bdry_layer_params, const unsigned int  order  ) const

protectedinherited

Modifies the input multi boundary layer parameters for node generation, especially for the quadratic elements.

Parameters

original_multi_bdry_layer_params	original multi boundary layer parameters
order	order of the elements

Returns

modified multi boundary layer parameters

Definition at line 1775 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildSlice().

{
  multiBdryLayerParams mod_multi_bdry_layer_params(original_multi_bdry_layer_params);
  std::for_each(mod_multi_bdry_layer_params.intervals.begin(),
                mod_multi_bdry_layer_params.intervals.end(),
                [&order](unsigned int & n) { n *= order; });
  std::for_each(mod_multi_bdry_layer_params.biases.begin(),
                mod_multi_bdry_layer_params.biases.end(),
                [&order](Real & n) { n = std::pow(n, 1.0 / order); });
  return mod_multi_bdry_layer_params;
}

modifiedSingleBdryLayerParamsCreator()

PolygonMeshGeneratorBase::singleBdryLayerParams PolygonMeshGeneratorBase::modifiedSingleBdryLayerParamsCreator ( const singleBdryLayerParams &  original_single_bdry_layer_params, const unsigned int  order  ) const

protectedinherited

Modifies the input single boundary layer parameters for node generation, especially for the quadratic elements.

Parameters

original_single_bdry_layer_params	original single boundary layer parameters
order	order of the elements

Returns

modified single boundary layer parameters

Definition at line 1789 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildSlice().

{
  singleBdryLayerParams mod_single_bdry_layer_params(original_single_bdry_layer_params);
  mod_single_bdry_layer_params.intervals *= order;
  mod_single_bdry_layer_params.bias = std::pow(mod_single_bdry_layer_params.bias, 1.0 / order);
  return mod_single_bdry_layer_params;
}

nodeCoordRotate()

void PolygonMeshGeneratorBase::nodeCoordRotate ( Real &  x, Real &  y, const Real  theta  ) const

protectedinherited

Calculates x and y coordinates after rotating by theta angle.

Parameters

x	x coordinate of the node to be rotated
y	y coordinate of the node to be rotated
theta	rotation angle

Returns

n/a

Definition at line 1320 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::cutOffPolyDeform(), FlexiblePatternGenerator::FlexiblePatternGenerator(), PolygonConcentricCircleMeshGeneratorBase::generate(), PatternedHexMeshGenerator::generate(), and PatternedCartesianMeshGenerator::generate().

{
  const Real x_tmp = x;
  const Real y_tmp = y;
  x = x_tmp * std::cos(theta * M_PI / 180.0) - y_tmp * std::sin(theta * M_PI / 180.0);
  y = x_tmp * std::sin(theta * M_PI / 180.0) + y_tmp * std::cos(theta * M_PI / 180.0);
}

pitchMetaDataErrorGenerator()

std::string PolygonMeshGeneratorBase::pitchMetaDataErrorGenerator ( const std::vector< MeshGeneratorName > &  input_names, const std::vector< Real > &  metadata_vals, const std::string &  metadata_name  ) const

protectedinherited

Generate a string that contains the detailed metadata information for inconsistent input mesh metadata error messages.

Parameters

input_names	list of input mesh generator names
metadata_vals	list of input mesh metadata values
metadata_name	name of the input mesh metadata

Returns

a string that contains the detailed metadata information

Definition at line 1799 of file PolygonMeshGeneratorBase.C.

Referenced by PatternedHexMeshGenerator::generate(), and PatternedCartesianMeshGenerator::generate().

{
  FormattedTable table;
  for (unsigned int i = 0; i < input_names.size(); i++)
  {
    table.addRow(i);
    table.addData<std::string>("input name", (std::string)input_names[i]);
    table.addData<Real>(metadata_name, metadata_vals[i]);
  }
  table.outputTimeColumn(false);
  std::stringstream detailed_error;
  table.printTable(detailed_error);
  return "\n" + detailed_error.str();
}

pointInterpolate()

std::pair< Real, Real > PolygonMeshGeneratorBase::pointInterpolate ( const Real  pi_1_x, const Real  pi_1_y, const Real  po_1_x, const Real  po_1_y, const Real  pi_2_x, const Real  pi_2_y, const Real  po_2_x, const Real  po_2_y, const unsigned int  i, const unsigned int  j, const unsigned int  num_sectors_per_side, const unsigned int  peripheral_intervals  ) const

protectedinherited

Calculates the point coordinates of within a parallelogram region using linear interpolation.

Parameters

pi_1_x	x coordinate of the first inner side point (parallelogram vertex)
pi_1_y	y coordinate of the first inner side point (parallelogram vertex)
po_1_x	x coordinate of the first outer side point (parallelogram vertex)
po_1_y	y coordinate of the first outer side point (parallelogram vertex)
pi_2_x	x coordinate of the second inner side point (parallelogram vertex)
pi_2_y	y coordinate of the second inner side point (parallelogram vertex)
po_2_x	x coordinate of the second outer side point (parallelogram vertex)
po_2_y	y coordinate of the second outer side point (parallelogram vertex)
i	passed loop index 1
j	passed loop index 2
num_sectors_per_side	number of azimuthal intervals
peripheral_invervals	number of radial intervals of the peripheral region

Returns

an interpolated position within a parallelogram

Definition at line 1293 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildSimplePeripheral().

{
  auto position_px_inner =
      (pi_1_x * (num_sectors_per_side / 2.0 - j) + pi_2_x * j) / (num_sectors_per_side / 2.0);
  auto position_py_inner =
      (pi_1_y * (num_sectors_per_side / 2.0 - j) + pi_2_y * j) / (num_sectors_per_side / 2.0);
  auto position_px_outer =
      (d_po_1_x * (num_sectors_per_side / 2.0 - j) + d_po_2_x * j) / (num_sectors_per_side / 2.0);
  auto position_py_outer =
      (d_po_1_y * (num_sectors_per_side / 2.0 - j) + d_po_2_y * j) / (num_sectors_per_side / 2.0);
  auto position_px = position_px_inner + position_px_outer * i / peripheral_intervals;
  auto position_py = position_py_inner + position_py_outer * i / peripheral_intervals;
  return std::make_pair(position_px, position_py);
}

quadElemDef()

void PolygonMeshGeneratorBase::quadElemDef ( ReplicatedMesh &  mesh, const unsigned int  num_sectors_per_side, const std::vector< unsigned int >  subdomain_rings, const unsigned int  side_index, const std::vector< Real >  azimuthal_tangent = std::vector<Real>(), const subdomain_id_type  block_id_shift = 0, const dof_id_type  nodeid_shift = 0, const bool  create_inward_interface_boundaries = false, const bool  create_outward_interface_boundaries = true, const boundary_id_type  boundary_id_shift = 0, const bool  generate_side_specific_boundaries = true, const QUAD_ELEM_TYPE  quad_elem_type = QUAD_ELEM_TYPE::QUAD4  ) const

protectedinherited

Defines general quad elements for the polygon.

Parameters

mesh	input mesh to create the elements onto
num_sectors_per_side	number of azimuthal intervals
subdomain_rings	numbers of radial intervals of all involved subdomain layers
side_index	index of the polygon side
azimuthal_tangent	vector of tangent values of the azimuthal angles as reference for adaptive boundary matching
block_id_shift	shift of the subdomain ids generated by this function
nodeid_shift	shift of the node_ids of these elements
create_inward_interface_boundaries	whether inward interface boundary sidesets are created
create_outward_interface_boundaries	whether outward interface boundary sidesets are created
boundary_id_shift	shift of the interface boundary ids
generate_side_specific_boundaries	whether the side-specific external boundaries are generated or not
quad_elem_type	type of the quadrilateral elements to be generated

Definition at line 1053 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildSlice().

{
  const unsigned short order = quad_elem_type == QUAD_ELEM_TYPE::QUAD4 ? 1 : 2;
  unsigned int angle_number = azimuthal_tangent.size() == 0
                                  ? num_sectors_per_side
                                  : ((azimuthal_tangent.size() - 1) / order);

  BoundaryInfo & boundary_info = mesh.get_boundary_info();
  unsigned int j = 0;
  for (unsigned int k = 0; k < (subdomain_rings.size()); k++)
  {
    for (unsigned int m = 0; m < subdomain_rings[k]; m++)
    {
      for (unsigned int i = 1; i <= angle_number; i++)
      {
        std::unique_ptr<Elem> new_elem;
        if (quad_elem_type == QUAD_ELEM_TYPE::QUAD4)
        {
          new_elem = std::make_unique<Quad4>();
          new_elem->set_node(0, mesh.node_ptr(nodeid_shift + i + (angle_number + 1) * j));
          new_elem->set_node(1, mesh.node_ptr(nodeid_shift + i + 1 + (angle_number + 1) * j));
          new_elem->set_node(2, mesh.node_ptr(nodeid_shift + i + (angle_number + 1) * (j + 1) + 1));
          new_elem->set_node(3, mesh.node_ptr(nodeid_shift + i + (angle_number + 1) * (j + 1)));
        }
        else // QUAD8/QUAD9
        {
          new_elem = std::make_unique<Quad8>();
          if (quad_elem_type == QUAD_ELEM_TYPE::QUAD9)
          {
            new_elem = std::make_unique<Quad9>();
            new_elem->set_node(
                8, mesh.node_ptr(nodeid_shift + i * 2 + (angle_number * 2 + 1) * (j * 2 + 2)));
          }
          new_elem->set_node(
              0,
              mesh.node_ptr(nodeid_shift + (i - 1) * 2 + 1 + (angle_number * 2 + 1) * (j * 2 + 1)));
          new_elem->set_node(
              1, mesh.node_ptr(nodeid_shift + i * 2 + 1 + (angle_number * 2 + 1) * (j * 2 + 1)));
          new_elem->set_node(
              2, mesh.node_ptr(nodeid_shift + i * 2 + 1 + (angle_number * 2 + 1) * (j * 2 + 3)));
          new_elem->set_node(
              3,
              mesh.node_ptr(nodeid_shift + (i - 1) * 2 + 1 + (angle_number * 2 + 1) * (j * 2 + 3)));
          new_elem->set_node(
              4, mesh.node_ptr(nodeid_shift + i * 2 + (angle_number * 2 + 1) * (j * 2 + 1)));
          new_elem->set_node(
              5, mesh.node_ptr(nodeid_shift + i * 2 + 1 + (angle_number * 2 + 1) * (j * 2 + 2)));
          new_elem->set_node(
              6, mesh.node_ptr(nodeid_shift + i * 2 + (angle_number * 2 + 1) * (j * 2 + 3)));
          new_elem->set_node(
              7,
              mesh.node_ptr(nodeid_shift + (i - 1) * 2 + 1 + (angle_number * 2 + 1) * (j * 2 + 2)));
        }
        Elem * elem = mesh.add_elem(std::move(new_elem));
        if (i == 1)
          boundary_info.add_side(elem, 3, SLICE_BEGIN);
        if (i == angle_number)
          boundary_info.add_side(elem, 1, SLICE_END);

        if (subdomain_rings[0] == 0)
          elem->subdomain_id() = k + 1 + block_id_shift;
        else
          elem->subdomain_id() = k + 2 + block_id_shift;

        if (m == 0 && create_inward_interface_boundaries && k > 0)
          boundary_info.add_side(elem, 0, k * 2 + boundary_id_shift);
        if (m == (subdomain_rings[k] - 1))
        {
          if (k == (subdomain_rings.size() - 1))
          {
            boundary_info.add_side(elem, 2, OUTER_SIDESET_ID);
            if (generate_side_specific_boundaries)
            {
              if (i <= angle_number / 2)
                boundary_info.add_side(elem, 2, OUTER_SIDESET_ID + side_index);
              else
                boundary_info.add_side(elem, 2, OUTER_SIDESET_ID_ALT + side_index);
            }
          }
          else if (create_outward_interface_boundaries)
            boundary_info.add_side(elem, 2, k * 2 + 1 + boundary_id_shift);
        }
      }
      j++;
    }
  }
}

reassignBoundaryIDs()

void PolygonMeshGeneratorBase::reassignBoundaryIDs ( MeshBase &  mesh, const boundary_id_type  id_shift, const std::set< boundary_id_type > &  boundary_ids, const bool  reverse = false  )

protectedinherited

reassign interface boundary IDs on the input mesh by applying the boundary ID shift

Parameters

mesh	input mesh
id_shift	ID shift value to be applied
boundary_ids	list of boundary IDs to be reassigned
reverse	remove boundary ID shift

Definition at line 1703 of file PolygonMeshGeneratorBase.C.

Referenced by PatternedHexMeshGenerator::generate(), and PatternedCartesianMeshGenerator::generate().

{
  const std::set<boundary_id_type> existing_boundary_ids =
      mesh.get_boundary_info().get_boundary_ids();
  for (const auto id : boundary_ids)
  {

    const boundary_id_type old_id = (!reverse) ? id : id + id_shift;
    const boundary_id_type new_id = (!reverse) ? id + id_shift : id;
    auto it = existing_boundary_ids.find(old_id);
    if (it != existing_boundary_ids.end())
      MooseMesh::changeBoundaryId(mesh, old_id, new_id, true);
  }
}

ringNodes()

void PolygonMeshGeneratorBase::ringNodes ( ReplicatedMesh &  mesh, const std::vector< Real >  ring_radii, const std::vector< unsigned int >  ring_layers, const std::vector< std::vector< Real >>  biased_terms, const unsigned int  num_sectors_per_side, const Real  corner_p[2][2], const Real  corner_to_corner, const std::vector< Real >  azimuthal_tangent = std::vector<Real>()  ) const

protectedinherited

Creates nodes for the ring-geometry region of a single slice.

Parameters

mesh	input mesh to add the nodes onto
ring_radii	radii of the ring regions
ring_layers	numbers of radial intervals of the ring regions
biased_terms	normalized spacing values used for radial meshing biasing in ring regions
num_sectors_per_side	number of azimuthal intervals
corner_p[2][2]	array contains the coordinates of the corner positions
corner_to_corner	diameter of the circumscribed circle of the polygon
azimuthal_tangent	vector of tangent values of the azimuthal angles as reference for adaptive boundary matching

Definition at line 656 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonMeshGeneratorBase::buildSlice().

{
  const unsigned int angle_number =
      azimuthal_tangent.size() == 0 ? num_sectors_per_side : (azimuthal_tangent.size() - 1);

  // Add nodes in pins regions
  for (unsigned int l = 0; l < ring_layers.size(); l++)
  {
    // the pin radius interval for each ring_radii/subdomain
    const Real pin_radius_interval_length =
        l == 0 ? ring_radii[l] / ring_layers[l]
               : (ring_radii[l] - ring_radii[l - 1]) / ring_layers[l];

    // add rings in each pin subdomain
    for (unsigned int k = 0; k < ring_layers[l]; k++)
    {
      const Real bin_radial_distance =
          l == 0 ? (biased_terms[l][k] * ring_layers[l] *
                    pin_radius_interval_length) // this is from the cell/pin center to
                                                // the first circle
                 : (ring_radii[l - 1] +
                    biased_terms[l][k] * ring_layers[l] * pin_radius_interval_length);
      const Real pin_corner_p_x = corner_p[0][0] * bin_radial_distance / (0.5 * corner_to_corner);
      const Real pin_corner_p_y = corner_p[0][1] * bin_radial_distance / (0.5 * corner_to_corner);

      // pin_corner_p(s) are the points in the pin region, on the bins towards the six corners,
      // at different intervals
      mesh.add_point(Point(pin_corner_p_x, pin_corner_p_y, 0.0));

      for (unsigned int j = 1; j <= angle_number; j++)
      {
        const Real cell_boundary_p_x =
            corner_p[0][0] + (corner_p[1][0] - corner_p[0][0]) *
                                 (azimuthal_tangent.size() == 0 ? ((Real)j / (Real)angle_number)
                                                                : (azimuthal_tangent[j] / 2.0));
        const Real cell_boundary_p_y =
            corner_p[0][1] + (corner_p[1][1] - corner_p[0][1]) *
                                 (azimuthal_tangent.size() == 0 ? ((Real)j / (Real)angle_number)
                                                                : (azimuthal_tangent[j] / 2.0));
        // cell_boundary_p(s) are the points on the cell's six boundaries (flat sides) at
        // different azimuthal angles
        const Real pin_azimuthal_p_x =
            cell_boundary_p_x * bin_radial_distance /
            std::sqrt(Utility::pow<2>(cell_boundary_p_x) + Utility::pow<2>(cell_boundary_p_y));
        const Real pin_azimuthal_p_y =
            cell_boundary_p_y * bin_radial_distance /
            std::sqrt(Utility::pow<2>(cell_boundary_p_x) + Utility::pow<2>(cell_boundary_p_y));

        // pin_azimuthal_p are the points on the bins towards different azimuthal angles, at
        // different intervals; excluding the ones produced by pin_corner_p
        mesh.add_point(Point(pin_azimuthal_p_x, pin_azimuthal_p_y, 0.0));
      }
    }
  }
}

setRingExtraIDs()

void PolygonMeshGeneratorBase::setRingExtraIDs ( MeshBase &  mesh, const std::string  id_name, const unsigned int  num_sides, const std::vector< unsigned int >  num_sectors_per_side, const std::vector< unsigned int >  ring_intervals, const bool  ring_wise_id, const bool  quad_center_elements  )

protectedinherited

assign ring extra ids to polygon mesh

Parameters

mesh	input mesh where ring extra ids are assigned
id_name	ring extra id name
num_sides	number of polygon sides
num_sectors_per_side	number of sectors of each side of the polygon
ring_intervals	number of rings in each circle
ring_wise_id	whether ring ids are assigned to each ring or to each block
quad_center_elements	whether center elements are quad or triangular

Definition at line 1638 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonConcentricCircleMeshGeneratorBase::generate(), and generate().

{
  // this function assumes that elements are ordered by rings (inner) then by sectors (outer
  // ordering)
  const auto extra_id_index = mesh.add_elem_integer(id_name);
  auto elem_it = mesh.elements_begin();
  for (unsigned int is = 0; is < num_sides; ++is)
  {
    // number of elements in the current sector
    unsigned int nelem = mesh.n_elem() * num_sectors_per_side[is] /
                         (accumulate(num_sectors_per_side.begin(), num_sectors_per_side.end(), 0));
    if (!ring_wise_id)
    {
      for (unsigned int ir : index_range(ring_intervals))
      {
        // number of elements in the current ring and sector
        unsigned int nelem_annular_ring = num_sectors_per_side[is] * ring_intervals[ir];
        // if _quad_center_elements is true, the number of elements in center ring are
        // _num_sectors_per_side[is] * _num_sectors_per_side[is] / 4
        if (quad_center_elements && ir == 0)
          nelem_annular_ring = num_sectors_per_side[is] * (ring_intervals[ir] - 1) +
                               num_sectors_per_side[is] * num_sectors_per_side[is] / 4;
        // assign ring id
        for (unsigned i = 0; i < nelem_annular_ring; ++i, ++elem_it)
          (*elem_it)->set_extra_integer(extra_id_index, ir + 1);
        // update number of elements in background region of current side.
        nelem -= nelem_annular_ring;
      }
    }
    else
    {
      unsigned int ir = 0;
      for (unsigned int ir0 : index_range(ring_intervals))
      {
        for (unsigned int ir1 = 0; ir1 < ring_intervals[ir0]; ++ir1)
        {
          // number of elements in the current ring and sector
          unsigned int nelem_annular_ring = num_sectors_per_side[is];
          // if _quad_center_elements is true, the number of elements in center ring are
          // _num_sectors_per_side[is] * _num_sectors_per_side[is] / 4
          if (quad_center_elements && ir == 0)
            nelem_annular_ring = num_sectors_per_side[is] * num_sectors_per_side[is] / 4;
          // assign ring id
          for (unsigned i = 0; i < nelem_annular_ring; ++i, ++elem_it)
            (*elem_it)->set_extra_integer(extra_id_index, ir + 1);
          // update ring id
          ++ir;
          // update number of elements in background region of current side.
          nelem -= nelem_annular_ring;
        }
      }
    }
    // assign ring id of 0 to the background region
    for (unsigned i = 0; i < nelem; ++i, ++elem_it)
      (*elem_it)->set_extra_integer(extra_id_index, 0);
  }
}

setSectorExtraIDs()

void PolygonMeshGeneratorBase::setSectorExtraIDs ( MeshBase &  mesh, const std::string  id_name, const unsigned int  num_sides, const std::vector< unsigned int >  num_sectors_per_side  )

protectedinherited

assign sector extra ids to polygon mesh

Parameters

mesh	input mesh where sector extra ids are assigned
id_name	sector extra ID name
num_side	number of polygon sides
num_sectors_per_side	number of sections of each side of the polygon

Definition at line 1613 of file PolygonMeshGeneratorBase.C.

Referenced by PolygonConcentricCircleMeshGeneratorBase::generate(), and generate().

{
  const auto extra_id_index = mesh.add_elem_integer(id_name);
  // vector to store sector ids for each element
  auto elem_it = mesh.elements_begin();
  unsigned int id = 1;
  // starting element id of the current sector
  for (unsigned int is = 0; is < num_sides; ++is)
  {
    // number of elements in the current sector
    unsigned int nelem_sector =
        mesh.n_elem() * num_sectors_per_side[is] /
        (accumulate(num_sectors_per_side.begin(), num_sectors_per_side.end(), 0));
    // assign sector ids to mesh
    for (unsigned i = 0; i < nelem_sector; ++i, ++elem_it)
      (*elem_it)->set_extra_integer(extra_id_index, id);
    // update sector id
    ++id;
  }
}

validParams()

InputParameters TriPinHexAssemblyGenerator::validParams ( )

static

Definition at line 19 of file TriPinHexAssemblyGenerator.C.

{
  InputParameters params = PolygonMeshGeneratorBase::validParams();
  params.addRequiredRangeCheckedParam<unsigned int>(
      "num_sectors_per_side", "num_sectors_per_side>0", "Number of azimuthal sectors per side.");
  params.addRangeCheckedParam<unsigned int>(
      "background_intervals",
      1,
      "background_intervals>0",
      "Number of radial meshing intervals in background "
      "region (region around the rings/pins in the assembly).");
  params.addRangeCheckedParam<std::vector<subdomain_id_type>>(
      "background_block_ids",
      "background_block_ids>0",
      "Optional block ids for the background regions in the pins.");
  params.addParam<std::vector<SubdomainName>>(
      "background_block_names", "Optional block names for the background regions in the pins.");
  params.addRangeCheckedParam<std::vector<std::vector<Real>>>(
      "ring_radii", "ring_radii>0", "Radii of the three sets of major concentric circles (pins).");
  params.addRangeCheckedParam<std::vector<std::vector<unsigned int>>>(
      "ring_intervals",
      "ring_intervals>0",
      "Number of radial mesh intervals within each set of major concentric circles (pins).");
  params.addRangeCheckedParam<std::vector<std::vector<subdomain_id_type>>>(
      "ring_block_ids", "ring_block_ids>0", "Optional block ids for the ring (pin) regions.");
  params.addParam<std::vector<std::vector<SubdomainName>>>(
      "ring_block_names", "Optional block names for the ring (pin) regions.");
  MooseEnum hexagon_size_style("apothem radius", "radius");
  params.addParam<MooseEnum>("hexagon_size_style",
                             hexagon_size_style,
                             "Style in which hexagon size is given (apothem = center to face, "
                             "radius = center to vertex).");
  params.addRequiredRangeCheckedParam<Real>(
      "hexagon_size", "hexagon_size>0", "Size parameter of the hexagon assembly to be generated.");
  params.addParam<Real>(
      "ring_offset", 0.0, "Offset of the ring (pin) center, shared by all three.");
  params.addParam<bool>(
      "preserve_volumes",
      true,
      "Volume of concentric circles (pins) can be preserved using this function.");
  MooseEnum assembly_orientation("pin_up pin_down", "pin_up");
  params.addParam<MooseEnum>(
      "assembly_orientation", assembly_orientation, "Orientation of the generated assembly.");
  params.addRangeCheckedParam<boundary_id_type>("external_boundary_id",
                                                "external_boundary_id>0",
                                                "Optional customized external boundary id.");
  params.addParam<std::string>("external_boundary_name",
                               "Optional customized external boundary name.");
  params.addParam<std::string>(
      "pin_id_name", "Name of extra integer ID to be assigned to each of the three pin domains.");
  params.addParam<std::vector<dof_id_type>>(
      "pin_id_values",
      "Values of extra integer ID to be assigned to each of the three pin domains.");
  params.addParamNamesToGroup("ring_block_ids ring_block_names background_block_ids "
                              "background_block_names external_boundary_id external_boundary_name",
                              "Customized Subdomain/Boundary ids/names");
  addRingAndSectorIDParams(params);
  params.addClassDescription(
      "This TriPinHexAssemblyGenerator object generates a hexagonal assembly "
      "mesh with three circular pins in a triangle at the center.");
  return params;
}

Member Data Documentation

_assembly_orientation

enum TriPinHexAssemblyGenerator::AssmOrient TriPinHexAssemblyGenerator::_assembly_orientation

protected

Referenced by generate().

_background_block_ids

const std::vector<subdomain_id_type> TriPinHexAssemblyGenerator::_background_block_ids

protected

Block ids of the background region.

Definition at line 53 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_background_block_names

const std::vector<SubdomainName> TriPinHexAssemblyGenerator::_background_block_names

protected

Block names of the background region.

Definition at line 55 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_background_intervals

const unsigned int TriPinHexAssemblyGenerator::_background_intervals

protected

Numbers of radial intervals of the background regions.

Definition at line 51 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_external_boundary_id

const boundary_id_type TriPinHexAssemblyGenerator::_external_boundary_id

protected

Boundary ID of mesh's external boundary.

Definition at line 57 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_external_boundary_name

const std::string TriPinHexAssemblyGenerator::_external_boundary_name

protected

Boundary name of mesh's external boundary.

Definition at line 59 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_has_rings

const std::vector<bool> TriPinHexAssemblyGenerator::_has_rings

protected

Whether the generated mesh contains ring regions.

Definition at line 31 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_hexagon_size_style

const PolygonSizeStyle TriPinHexAssemblyGenerator::_hexagon_size_style

protected

Type of hexagon_size parameter.

Definition at line 39 of file TriPinHexAssemblyGenerator.h.

_node_id_background_meta

dof_id_type& TriPinHexAssemblyGenerator::_node_id_background_meta

protected

MeshMetaData: maximum node id of the background region.

Definition at line 65 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_num_sectors_per_side

const unsigned int TriPinHexAssemblyGenerator::_num_sectors_per_side

protected

Mesh sector number of each polygon side.

Definition at line 49 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_pin_id_name

const std::string TriPinHexAssemblyGenerator::_pin_id_name

protected

Name of extra integer ID to be assigned to each of the three pin domains.

Definition at line 61 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_pin_id_values

const std::vector<dof_id_type> TriPinHexAssemblyGenerator::_pin_id_values

protected

Values of extra integer ID to be assigned to each of the three pin domains.

Definition at line 63 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_preserve_volumes

const bool TriPinHexAssemblyGenerator::_preserve_volumes

protected

Whether the radii need to be corrected for polygonization during meshing.

Definition at line 45 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_ring_block_ids

const std::vector<std::vector<subdomain_id_type> > TriPinHexAssemblyGenerator::_ring_block_ids

protected

Block ids of the ring regions in the three diamond sections.

Definition at line 35 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_ring_block_names

const std::vector<std::vector<SubdomainName> > TriPinHexAssemblyGenerator::_ring_block_names

protected

Block names of the ring regions in the three diamond sections.

Definition at line 37 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_ring_intervals

const std::vector<std::vector<unsigned int> > TriPinHexAssemblyGenerator::_ring_intervals

protected

Numbers of radial layers in each ring region in the three diamond sections.

Definition at line 33 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_ring_offset

const Real TriPinHexAssemblyGenerator::_ring_offset

protected

Offset distance of the circle centers from the center of each diamond section.

Definition at line 43 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

_ring_radii

const std::vector<std::vector<Real> > TriPinHexAssemblyGenerator::_ring_radii

protected

Radii of concentric circles in the three diamond sections.

Definition at line 29 of file TriPinHexAssemblyGenerator.h.

Referenced by generate(), and TriPinHexAssemblyGenerator().

_side_length

const Real TriPinHexAssemblyGenerator::_side_length

protected

Length of the side of the hexagon.

Definition at line 41 of file TriPinHexAssemblyGenerator.h.

Referenced by generate().

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

• reactor/include/meshgenerators/TriPinHexAssemblyGenerator.h
• reactor/src/meshgenerators/TriPinHexAssemblyGenerator.C