32 #include "libmesh/bounding_box.h" 33 #include "libmesh/boundary_info.h" 34 #include "libmesh/mesh_tools.h" 35 #include "libmesh/parallel.h" 36 #include "libmesh/mesh_communication.h" 37 #include "libmesh/periodic_boundary_base.h" 38 #include "libmesh/fe_base.h" 39 #include "libmesh/fe_interface.h" 40 #include "libmesh/mesh_communication.h" 41 #include "libmesh/mesh_tools.h" 42 #include "libmesh/parallel.h" 43 #include "libmesh/parallel_elem.h" 44 #include "libmesh/parallel_node.h" 45 #include "libmesh/parallel_ghost_sync.h" 46 #include "libmesh/utility.h" 47 #include "libmesh/remote_elem.h" 48 #include "libmesh/linear_partitioner.h" 49 #include "libmesh/centroid_partitioner.h" 50 #include "libmesh/parmetis_partitioner.h" 51 #include "libmesh/hilbert_sfc_partitioner.h" 52 #include "libmesh/morton_sfc_partitioner.h" 53 #include "libmesh/edge_edge2.h" 54 #include "libmesh/mesh_refinement.h" 55 #include "libmesh/quadrature.h" 56 #include "libmesh/boundary_info.h" 57 #include "libmesh/periodic_boundaries.h" 58 #include "libmesh/quadrature_gauss.h" 59 #include "libmesh/point_locator_base.h" 60 #include "libmesh/default_coupling.h" 61 #include "libmesh/ghost_point_neighbors.h" 62 #include "libmesh/fe_type.h" 63 #include "libmesh/enum_to_string.h" 64 #include "libmesh/elem_side_builder.h" 69 #if NANOFLANN_VERSION < 0x150 74 template <
typename T,
typename U>
86 MooseEnum parallel_type(
"DEFAULT REPLICATED DISTRIBUTED",
"DEFAULT");
89 "DEFAULT: Use libMesh::ReplicatedMesh unless --distributed-mesh is " 90 "specified on the command line " 91 "REPLICATED: Always use libMesh::ReplicatedMesh " 92 "DISTRIBUTED: Always use libMesh::DistributedMesh");
97 "If allow_renumbering=false, node and element numbers are kept fixed until deletion");
102 "Specifies a mesh partitioner to use when splitting the mesh for a parallel computation.");
106 "Specifies the sort direction if using the centroid partitioner. " 107 "Available options: x, y, z, radial");
109 MooseEnum patch_update_strategy(
"never always auto iteration",
"never");
111 "patch_update_strategy",
112 patch_update_strategy,
113 "How often to update the geometric search 'patch'. The default is to " 114 "never update it (which is the most efficient but could be a problem " 115 "with lots of relative motion). 'always' will update the patch for all " 116 "secondary nodes at the beginning of every timestep which might be time " 117 "consuming. 'auto' will attempt to determine at the start of which " 118 "timesteps the patch for all secondary nodes needs to be updated automatically." 119 "'iteration' updates the patch at every nonlinear iteration for a " 120 "subset of secondary nodes for which penetration is not detected. If there " 121 "can be substantial relative motion between the primary and secondary surfaces " 122 "during the nonlinear iterations within a timestep, it is advisable to use " 123 "'iteration' option to ensure accurate contact detection.");
127 "construct_node_list_from_side_list",
129 "Whether or not to generate nodesets from the sidesets (currently often required).");
131 "displace_node_list_by_side_list",
133 "Whether to renumber existing nodesets with ids matching sidesets that " 134 "lack names matching sidesets, when constructing nodesets from sidesets via the default " 135 "'construct_node_list_from_side_list' option, rather than to merge them with the sideset.");
137 "patch_size", 40,
"The number of nodes to consider in the NearestNode neighborhood.");
138 params.
addParam<
unsigned int>(
"ghosting_patch_size",
139 "The number of nearest neighbors considered " 140 "for ghosting purposes when 'iteration' " 141 "patch update strategy is used. Default is " 143 params.
addParam<
unsigned int>(
"max_leaf_size",
145 "The maximum number of points in each leaf of the KDTree used in " 146 "the nearest neighbor search. As the leaf size becomes larger," 147 "KDTree construction becomes faster but the nearest neighbor search" 150 params.
addParam<
bool>(
"build_all_side_lowerd_mesh",
152 "True to build the lower-dimensional mesh for all sides.");
154 params.
addParam<
bool>(
"skip_refine_when_use_split",
156 "True to skip uniform refinements when using a pre-split mesh.");
158 params.
addParam<std::vector<SubdomainID>>(
160 "The listed subdomain ids will be assumed valid for the mesh. This permits setting up " 161 "subdomain restrictions for subdomains initially containing no elements, which can occur, " 162 "for example, in additive manufacturing simulations which dynamically add and remove " 163 "elements. Names for this subdomains may be provided using add_subdomain_names. In this case " 164 "this list and add_subdomain_names must contain the same number of items.");
165 params.
addParam<std::vector<SubdomainName>>(
166 "add_subdomain_names",
167 "The listed subdomain names will be assumed valid for the mesh. This permits setting up " 168 "subdomain restrictions for subdomains initially containing no elements, which can occur, " 169 "for example, in additive manufacturing simulations which dynamically add and remove " 170 "elements. IDs for this subdomains may be provided using add_subdomain_ids. Otherwise IDs " 171 "are automatically assigned. In case add_subdomain_ids is set too, both lists must contain " 172 "the same number of items.");
174 params.
addParam<std::vector<BoundaryID>>(
176 "The listed sideset ids will be assumed valid for the mesh. This permits setting up boundary " 177 "restrictions for sidesets initially containing no sides. Names for this sidesets may be " 178 "provided using add_sideset_names. In this case this list and add_sideset_names must contain " 179 "the same number of items.");
180 params.
addParam<std::vector<BoundaryName>>(
182 "The listed sideset names will be assumed valid for the mesh. This permits setting up " 183 "boundary restrictions for sidesets initially containing no sides. Ids for this sidesets may " 184 "be provided using add_sideset_ids. In this case this list and add_sideset_ids must contain " 185 "the same number of items.");
187 params.
addParam<std::vector<BoundaryID>>(
189 "The listed nodeset ids will be assumed valid for the mesh. This permits setting up boundary " 190 "restrictions for node initially containing no sides. Names for this nodesets may be " 191 "provided using add_nodeset_names. In this case this list and add_nodeset_names must contain " 192 "the same number of items.");
193 params.
addParam<std::vector<BoundaryName>>(
195 "The listed nodeset names will be assumed valid for the mesh. This permits setting up " 196 "boundary restrictions for nodesets initially containing no sides. Ids for this nodesets may " 197 "be provided using add_nodesets_ids. In this case this list and add_nodesets_ids must " 198 "contain the same number of items.");
204 params.addPrivateParam<
bool>(
"_mesh_generator_mesh",
false);
207 params.addPrivateParam<
bool>(
"_is_split",
false);
209 params.registerBase(
"MooseMesh");
212 params.addParamNamesToGroup(
"patch_update_strategy patch_size max_leaf_size",
"Geometric search");
213 params.addParamNamesToGroup(
"add_subdomain_ids add_subdomain_names add_sideset_ids " 214 "add_sideset_names add_nodeset_ids add_nodeset_names",
215 "Pre-declaration of future mesh sub-entities");
216 params.addParamNamesToGroup(
"construct_node_list_from_side_list build_all_side_lowerd_mesh " 217 "displace_node_list_by_side_list",
218 "Automatic definition of mesh element sides entities");
219 params.addParamNamesToGroup(
"partitioner centroid_partitioner_direction",
"Partitioning");
229 _use_distributed_mesh(false),
230 _distribution_overridden(false),
231 _parallel_type_overridden(false),
233 _partitioner_name(getParam<
MooseEnum>(
"partitioner")),
234 _partitioner_overridden(false),
235 _custom_partitioner_requested(false),
236 _uniform_refine_level(0),
237 _skip_refine_when_use_split(getParam<bool>(
"skip_refine_when_use_split")),
238 _skip_deletion_repartition_after_refine(false),
240 _patch_size(getParam<unsigned
int>(
"patch_size")),
241 _ghosting_patch_size(isParamValid(
"ghosting_patch_size")
242 ? getParam<unsigned
int>(
"ghosting_patch_size")
244 _max_leaf_size(getParam<unsigned
int>(
"max_leaf_size")),
245 _patch_update_strategy(
247 _regular_orthogonal_mesh(false),
248 _is_split(getParam<bool>(
"_is_split")),
249 _allow_recovery(true),
250 _construct_node_list_from_side_list(getParam<bool>(
"construct_node_list_from_side_list")),
251 _displace_node_list_by_side_list(getParam<bool>(
"displace_node_list_by_side_list")),
253 _allow_remote_element_removal(true),
254 _need_ghost_ghosted_boundaries(true),
255 _is_displaced(false),
258 _rz_coord_axis(getParam<
MooseEnum>(
"rz_coord_axis")),
259 _coord_system_set(false),
260 _doing_p_refinement(false)
263 mooseError(
"Ghosting patch size parameter has to be set in the mesh block " 264 "only when 'iteration' patch update strategy is used.");
270 "You set both 'Mesh/block' and 'Mesh/coord_block'. The value of " 271 "'Mesh/coord_block' will be used.");
278 if (getParam<bool>(
"build_all_side_lowerd_mesh"))
284 #ifdef MOOSE_KOKKOS_ENABLED 286 _kokkos_mesh = std::make_unique<Moose::Kokkos::Mesh>(*
this);
294 _built_from_other_mesh(true),
295 _parallel_type(other_mesh._parallel_type),
296 _use_distributed_mesh(other_mesh._use_distributed_mesh),
297 _distribution_overridden(other_mesh._distribution_overridden),
298 _parallel_type_overridden(other_mesh._parallel_type_overridden),
299 _mesh(other_mesh.getMesh().clone()),
300 _partitioner_name(other_mesh._partitioner_name),
301 _partitioner_overridden(other_mesh._partitioner_overridden),
302 _custom_partitioner_requested(other_mesh._custom_partitioner_requested),
303 _uniform_refine_level(other_mesh.uniformRefineLevel()),
304 _skip_refine_when_use_split(other_mesh._skip_refine_when_use_split),
305 _skip_deletion_repartition_after_refine(other_mesh._skip_deletion_repartition_after_refine),
306 _is_nemesis(other_mesh._is_nemesis),
307 _patch_size(other_mesh._patch_size),
308 _ghosting_patch_size(other_mesh._ghosting_patch_size),
309 _max_leaf_size(other_mesh._max_leaf_size),
310 _patch_update_strategy(other_mesh._patch_update_strategy),
311 _regular_orthogonal_mesh(false),
312 _is_split(other_mesh._is_split),
313 _lower_d_interior_blocks(other_mesh._lower_d_interior_blocks),
314 _lower_d_boundary_blocks(other_mesh._lower_d_boundary_blocks),
315 _allow_recovery(other_mesh._allow_recovery),
316 _construct_node_list_from_side_list(other_mesh._construct_node_list_from_side_list),
317 _displace_node_list_by_side_list(other_mesh._displace_node_list_by_side_list),
318 _need_delete(other_mesh._need_delete),
319 _allow_remote_element_removal(other_mesh._allow_remote_element_removal),
320 _need_ghost_ghosted_boundaries(other_mesh._need_ghost_ghosted_boundaries),
321 _coord_sys(other_mesh._coord_sys),
322 _rz_coord_axis(other_mesh._rz_coord_axis),
323 _subdomain_id_to_rz_coord_axis(other_mesh._subdomain_id_to_rz_coord_axis),
324 _coord_system_set(other_mesh._coord_system_set),
325 _provided_coord_blocks(other_mesh._provided_coord_blocks),
326 _doing_p_refinement(other_mesh._doing_p_refinement)
329 for (std::size_t i = 0; i <
_bounds.size(); ++i)
332 for (std::size_t j = 0; j <
_bounds[i].size(); ++j)
338 #ifdef MOOSE_KOKKOS_ENABLED 340 _kokkos_mesh = std::make_unique<Moose::Kokkos::Mesh>(*
this);
387 TIME_SECTION(
"prepare", 2,
"Preparing Mesh",
true);
389 parallel_object_only();
391 bool libmesh_mesh_prepared =
false;
393 mooseAssert(
_mesh,
"The MeshBase has not been constructed");
402 "The mesh we wish to clone from must already be prepared");
406 else if (!
_mesh->is_prepared())
408 _mesh->complete_preparation();
410 libmesh_mesh_prepared =
true;
414 return libmesh_mesh_prepared;
418 for (
const auto &
elem :
getMesh().element_ptr_range())
421 bool need_subdomain_name_map_sync =
false;
426 const auto & add_subdomain_id = getParam<std::vector<SubdomainID>>(
"add_subdomain_ids");
431 const auto add_subdomain =
432 getParam<SubdomainID, SubdomainName>(
"add_subdomain_ids",
"add_subdomain_names");
433 for (
const auto & [sub_id, sub_name] : add_subdomain)
440 need_subdomain_name_map_sync =
true;
445 const auto & add_subdomain_names = getParam<std::vector<SubdomainName>>(
"add_subdomain_names");
453 for (
const SubdomainName & sub_name : add_subdomain_names)
458 const auto sub_id = ++offset;
464 need_subdomain_name_map_sync =
true;
466 if (need_subdomain_name_map_sync)
467 _mesh->sync_subdomain_name_map();
476 const std::set<BoundaryID> & local_node_bids =
480 const std::set<BoundaryID> & local_side_bids =
486 auto add_sets = [
this](
const bool sidesets,
auto & set_ids)
488 const std::string
type = sidesets ?
"sideset" :
"nodeset";
489 const std::string id_param =
"add_" +
type +
"_ids";
494 const auto & add_ids = getParam<std::vector<BoundaryID>>(id_param);
496 set_ids.insert(add_ids.begin(), add_ids.end());
499 const auto & add_names = getParam<std::vector<BoundaryName>>(
name_param);
500 mooseAssert(add_names.size() == add_ids.size(),
501 "Id and name sets must be the same size when adding.");
509 const auto & add_names = getParam<std::vector<BoundaryName>>(
name_param);
515 if (!mesh_ids.empty())
516 offset = *mesh_ids.rbegin();
521 for (
const auto &
name : add_names)
526 const auto id = ++offset;
554 "Trying to set coordinate system type information based on the user input file, but " 555 "the coordinate system type information has already been set programmatically! " 556 "Either remove your coordinate system type information from the input file, or contact " 557 "your application developer");
564 const auto rz_coord_blocks = getParam<std::vector<SubdomainName>>(
"rz_coord_blocks");
565 const auto rz_coord_origins = getParam<std::vector<Point>>(
"rz_coord_origins");
566 const auto rz_coord_directions = getParam<std::vector<RealVectorValue>>(
"rz_coord_directions");
567 if (rz_coord_origins.size() == rz_coord_blocks.size() &&
568 rz_coord_directions.size() == rz_coord_blocks.size())
570 std::vector<std::pair<Point, RealVectorValue>> rz_coord_axes;
571 for (
unsigned int i = 0; i < rz_coord_origins.size(); ++i)
572 rz_coord_axes.push_back(std::make_pair(rz_coord_origins[i], rz_coord_directions[i]));
577 mooseError(
"The parameter 'rz_coord_axis' may not be provided if 'rz_coord_blocks', " 578 "'rz_coord_origins', and 'rz_coord_directions' are provided.");
581 mooseError(
"The parameters 'rz_coord_blocks', 'rz_coord_origins', and " 582 "'rz_coord_directions' must all have the same size.");
586 mooseError(
"If any of the parameters 'rz_coord_blocks', 'rz_coord_origins', and " 587 "'rz_coord_directions' are provided, then all must be provided.");
598 return libmesh_mesh_prepared;
608 mooseAssert(
_node_to_elem_map.empty(),
"If it hasn't been built, it better well be empty");
621 TIME_SECTION(
"update", 3,
"Updating Mesh",
true);
635 for (
const auto &
elem :
getMesh().active_local_element_ptr_range())
650 #ifdef MOOSE_KOKKOS_ENABLED 668 "Hybrid finite element method must use replicated mesh.\nCurrently lower-dimensional mesh " 669 "does not support mesh re-partitioning and a debug assertion being hit related with " 670 "neighbors of lower-dimensional element, with distributed mesh.");
677 unsigned int max_n_sides = 0;
680 std::set<Elem *> deleteable_elems;
681 for (
auto &
elem :
mesh.element_ptr_range())
684 deleteable_elems.insert(
elem);
688 for (
auto &
elem : deleteable_elems)
699 deleteable_elems.clear();
702 std::set<int> interior_side_types;
703 std::set<int> boundary_side_types;
704 for (
const auto &
elem :
mesh.active_element_ptr_range())
710 interior_side_types.insert(side_elem->type());
712 boundary_side_types.insert(side_elem->type());
718 std::map<ElemType, SubdomainID> interior_block_ids;
719 std::map<ElemType, SubdomainID> boundary_block_ids;
722 for (
const auto & tpid : interior_side_types)
726 interior_block_ids[
type] = id;
729 mooseError(
"Trying to add a mesh block with id ",
id,
" that has existed in the mesh");
733 for (
const auto & tpid : boundary_side_types)
737 boundary_block_ids[
type] = id;
740 mooseError(
"Trying to add a mesh block with id ",
id,
" that has existed in the mesh");
748 std::vector<Elem *> side_elems;
750 for (
const auto &
elem :
mesh.active_element_ptr_range())
760 bool build_side =
false;
765 mooseAssert(!neig->
is_remote(),
"We error if the mesh is not serial");
781 side_elem->subdomain_id() = interior_block_ids.at(side_elem->type());
783 side_elem->subdomain_id() = boundary_block_ids.at(side_elem->type());
786 side_elem->set_id(max_elem_id +
elem->
id() * max_n_sides + side);
787 side_elem->set_unique_id(max_unique_id +
elem->
id() * max_n_sides + side);
792 side_elem->set_interior_parent(
elem);
794 side_elems.push_back(side_elem.release());
797 auto pair = std::make_pair(
elem, side);
798 auto link = std::make_pair(pair, side_elems.back());
799 auto ilink = std::make_pair(side_elems.back(), side);
810 for (
auto &
elem : side_elems)
826 mooseDeprecated(
"MooseMesh::node() is deprecated, please use MooseMesh::nodeRef() instead");
833 mooseDeprecated(
"MooseMesh::node() is deprecated, please use MooseMesh::nodeRef() instead");
841 mooseAssert(node_ptr,
"Missing node");
866 if (i >
getMesh().max_node_id())
871 auto & node_ptr = it->second;
872 mooseAssert(node_ptr,
"Uninitialized quadrature node");
888 TIME_SECTION(
"meshChanged", 3,
"Updating Because Mesh Changed");
919 TIME_SECTION(
"cacheChangedLists", 5,
"Caching Changed Lists");
923 Threads::parallel_reduce(elem_range, cclt);
946 const std::vector<const Elem *> &
951 return elem_to_child_pair->second;
957 TIME_SECTION(
"updateActiveSemiLocalNodeRange", 5,
"Updating ActiveSemiLocalNode Range");
963 for (
const auto &
elem : *active_local_elems)
979 for (
const auto & ghost_elem_id : ghosted_elems)
1031 TIME_SECTION(
"buildNodeList", 5,
"Building Node List");
1037 int n = bc_tuples.size();
1040 for (
const auto & t : bc_tuples)
1042 auto node_id = std::get<0>(t);
1043 auto bc_id = std::get<1>(t);
1076 for (
unsigned int side = 0; side <
elem->
n_sides(); ++side)
1099 for (
const auto &
elem :
getMesh().active_local_element_ptr_range())
1100 for (
unsigned int i = 0; i < n; ++i)
1108 for (
unsigned int j = 0; j < n; ++j)
1116 for (
unsigned int i = 0; i < n; ++i)
1126 std::unordered_map<dof_id_type, std::set<dof_id_type>>
1131 if (!mesh_base.has_elem_integer(from_id_name))
1132 mooseError(
"Mesh does not have the element integer name '", from_id_name,
"'");
1133 if (!mesh_base.has_elem_integer(to_id_name))
1134 mooseError(
"Mesh does not have the element integer name '", to_id_name,
"'");
1136 const auto id1 = mesh_base.get_elem_integer_index(from_id_name);
1137 const auto id2 = mesh_base.get_elem_integer_index(to_id_name);
1139 std::unordered_map<dof_id_type, std::set<dof_id_type>> id_map;
1141 id_map[id] = std::set<dof_id_type>();
1143 for (
const auto &
elem : mesh_base.active_local_element_ptr_range())
1146 for (
auto & [
id, ids] : id_map)
1155 std::set<dof_id_type>
1158 std::set<dof_id_type> unique_ids;
1160 for (
auto &
id : pair.second)
1161 unique_ids.insert(
id);
1165 std::set<dof_id_type>
1168 std::set<dof_id_type> unique_ids;
1169 for (
auto & blk : blks)
1173 mooseError(
"Block ", blk,
" is not available on the mesh");
1175 for (
auto & mid : it->second)
1176 unique_ids.insert(mid);
1184 TIME_SECTION(
"buildBndElemList", 5,
"Building Boundary Elements List");
1190 int n = bc_tuples.size();
1193 for (
const auto & t : bc_tuples)
1195 auto elem_id = std::get<0>(t);
1196 auto side_id = std::get<1>(t);
1197 auto bc_id = std::get<2>(t);
1204 std::unordered_map<dof_id_type, std::vector<dof_id_type>> &
1209 Threads::spin_mutex::scoped_lock lock(Threads::spin_mtx);
1218 Threads::in_threads =
false;
1219 TIME_SECTION(
"nodeToElemMap", 5,
"Building Node To Elem Map");
1223 for (
const auto &
elem :
getMesh().active_element_ptr_range())
1224 for (
unsigned int n = 0; n <
elem->
n_nodes(); n++)
1233 const std::unordered_map<dof_id_type, std::vector<dof_id_type>> &
1244 TIME_SECTION(
"getActiveLocalElementRange", 5);
1247 getMesh().active_local_elements_begin(),
getMesh().active_local_elements_end());
1258 TIME_SECTION(
"getActiveNodeRange", 5);
1261 std::make_unique<NodeRange>(
getMesh().active_nodes_begin(),
getMesh().active_nodes_end());
1271 "_active_semilocal_node_range has not been created yet!");
1281 TIME_SECTION(
"getLocalNodeRange", 5);
1295 TIME_SECTION(
"getBoundaryNodeRange", 5);
1308 TIME_SECTION(
"getBoundaryElementRange", 5);
1316 const std::unordered_map<boundary_id_type, std::unordered_set<dof_id_type>> &
1320 "use MooseMesh::getBoundariesToActiveSemiLocalElemIds");
1324 const std::unordered_map<boundary_id_type, std::unordered_set<dof_id_type>> &
1330 std::unordered_set<dof_id_type>
1337 return std::unordered_set<dof_id_type>{};
1341 std::unordered_set<dof_id_type>
1345 std::unordered_set<dof_id_type> neighbor_elems;
1348 const auto & [elem_ptr, elem_side, elem_bid] = *bnd_elem;
1349 if (elem_bid == bid)
1351 const auto * neighbor = elem_ptr->neighbor_ptr(elem_side);
1356 if (neighbor->active())
1357 neighbor_elems.insert(neighbor->id());
1360 std::vector<const Elem *> family;
1361 neighbor->active_family_tree_by_neighbor(family, elem_ptr);
1362 for (
const auto & child_neighbor : family)
1363 neighbor_elems.insert(child_neighbor->id());
1369 return neighbor_elems;
1374 const std::set<SubdomainID> & blk_group)
const 1376 mooseAssert(
_bnd_elem_range,
"Boundary element range is not initialized");
1381 const auto & [elem_ptr, elem_side, elem_bid] = *bnd_elem;
1382 if (elem_bid == bid)
1385 if (blk_group.find(elem_ptr->subdomain_id()) != blk_group.end())
1387 const auto *
const neighbor = elem_ptr->neighbor_ptr(elem_side);
1391 mooseError(
"Insufficient level of geometrical ghosting to determine " 1392 "if a boundary is internal to the mesh");
1398 if (blk_group.find(neighbor->subdomain_id()) != blk_group.end())
1409 TIME_SECTION(
"cacheInfo", 3);
1422 for (
const auto &
elem :
mesh.element_ptr_range())
1433 auto pair = std::make_pair(ip_elem, ip_side);
1435 std::pair<std::pair<const Elem *, unsigned short int>,
const Elem *>(pair,
elem));
1437 std::pair<const Elem *, unsigned short int>(
elem, ip_side));
1442 if (
mesh.
subdomain_name(
id).find(
"INTERNAL_SIDE_LOWERD_SUBDOMAIN_") != std::string::npos)
1447 if (
mesh.
subdomain_name(
id).find(
"BOUNDARY_SIDE_LOWERD_SUBDOMAIN_") != std::string::npos)
1453 for (
unsigned int nd = 0; nd <
elem->
n_nodes(); ++nd)
1463 for (
const auto &
elem :
mesh.active_local_element_ptr_range())
1468 for (
unsigned int side = 0; side <
elem->
n_sides(); side++)
1470 const auto & boundary_ids = elem_boundary_ids[side];
1471 sub_data.boundary_ids.insert(boundary_ids.begin(), boundary_ids.end());
1477 boundary_ids.end());
1479 if (neighbor_subdomain_id != subdomain_id)
1480 sub_data.neighbor_subs.insert(neighbor_subdomain_id);
1494 const std::set<SubdomainID> &
1582 for (
const auto &
node :
getMesh().node_ptr_range())
1587 for (
unsigned int i = 0; i <
_node_map.size(); ++i)
1595 if (
node ==
nullptr)
1601 mooseAssert(
node !=
nullptr,
"Node is NULL");
1607 const unsigned short int side,
1608 const unsigned int qp,
1627 if (new_id <=
getMesh().max_node_id())
1628 mooseError(
"Quadrature node id collides with existing node id!");
1656 const unsigned short int side,
1657 const unsigned int qp)
1661 "Elem has no quadrature nodes!");
1664 "Side has no quadrature nodes!");
1667 "qp not found on side!");
1689 if (boundary_name ==
"ANY_BOUNDARY_ID")
1690 mooseError(
"Please use getBoundaryIDs() when passing \"ANY_BOUNDARY_ID\"");
1717 std::vector<BoundaryID>
1719 bool generate_unknown)
const 1731 std::vector<SubdomainID>
1737 std::set<SubdomainID>
1746 mooseAssert(
name !=
"ANY_BLOCK_ID",
"Cannot set subdomain name to 'ANY_BLOCK_ID'");
1753 mooseAssert(
name !=
"ANY_BLOCK_ID",
"Cannot set subdomain name to 'ANY_BLOCK_ID'");
1763 std::vector<SubdomainName>
1766 std::vector<SubdomainName> names(subdomain_ids.size());
1768 for (
unsigned int i = 0; i < subdomain_ids.size(); i++)
1802 return name.size() ?
name : std::to_string(boundary_id);
1807 inline const Point &
1811 return *(item.first);
1816 unsigned int var_number,
1819 TIME_SECTION(
"buildPeriodicNodeMap", 5);
1822 periodic_node_map.clear();
1825 std::vector<PeriodicNodeInfo> periodic_nodes;
1826 for (
const auto & t :
getMesh().get_boundary_info().build_node_list())
1829 auto node =
_mesh->node_ptr(std::get<0>(t));
1830 mooseAssert(
node !=
nullptr,
1831 "libMesh::BoundaryInfo::build_node_list() returned an ID for a non-existing node");
1832 auto bc_id = std::get<1>(t);
1833 periodic_nodes.emplace_back(
node, bc_id);
1837 std::sort(periodic_nodes.begin(),
1838 periodic_nodes.end(),
1840 {
return a.second > b.second; });
1843 using KDTreeType = nanoflann::KDTreeSingleIndexAdaptor<
1844 nanoflann::L2_Simple_Adaptor<Real, PointListAdaptor<PeriodicNodeInfo>,
Real, std::size_t>,
1848 const unsigned int max_leaf_size = 20;
1851 auto kd_tree = std::make_unique<KDTreeType>(
1852 LIBMESH_DIM, point_list, nanoflann::KDTreeSingleIndexAdaptorParams(max_leaf_size));
1853 mooseAssert(kd_tree !=
nullptr,
"KDTree was not properly initialized.");
1854 kd_tree->buildIndex();
1858 std::vector<nanoflann::ResultItem<std::size_t, Real>> ret_matches;
1862 BoundaryID current_bc_id = BoundaryInfo::invalid_id;
1863 for (
auto & pair : periodic_nodes)
1866 if (pair.second != current_bc_id)
1868 current_bc_id = pair.second;
1869 periodic = pbs->
boundary(current_bc_id);
1879 ret_matches.clear();
1882 const auto id = pair.first->id();
1888 kd_tree->radiusSearch(&(search_point)(0),
libMesh::TOLERANCE, ret_matches, search_params);
1889 for (
auto & match_pair : ret_matches)
1891 const auto & match = periodic_nodes[match_pair.first];
1894 periodic_node_map.emplace(
id, match.first->id());
1901 unsigned int var_number,
1904 TIME_SECTION(
"buildPeriodicNodeSets", 5);
1906 periodic_node_sets.clear();
1909 for (
const auto & t :
getMesh().get_boundary_info().build_node_list())
1911 auto node_id = std::get<0>(t);
1912 auto bc_id = std::get<1>(t);
1915 if (periodic_node_sets.find(bc_id) != periodic_node_sets.end())
1916 periodic_node_sets[bc_id].insert(node_id);
1921 periodic_node_sets[bc_id].insert(node_id);
1929 TIME_SECTION(
"detectOrthogonalDimRanges", 5);
1939 for (
const auto &
node :
getMesh().node_ptr_range())
1945 min[i] = (*node)(i);
1947 max[i] = (*node)(i);
1955 std::vector<bool> extreme_matches(8,
false);
1956 std::vector<unsigned int> comp_map(3);
1957 for (
const auto &
node :
getMesh().node_ptr_range())
1960 unsigned int coord_match = 0;
1976 if (coord_match == LIBMESH_DIM)
1979 extreme_matches[comp_map[
X] * 4 + comp_map[
Y] * 2 + comp_map[
Z]] =
true;
1984 this->
comm().
max(extreme_matches);
1985 if (std::count(extreme_matches.begin(), extreme_matches.end(),
true) == (1 <<
dim))
2003 TIME_SECTION(
"detectPairedSidesets", 5);
2020 static constexpr std::array<std::size_t, 3> unit_dims{0, 1, 2};
2022 static const std::array<std::string, 3> unit_dim_names{
"x",
"y",
"z"};
2028 std::array<std::array<std::array<std::set<BoundaryID>, 2>, 3>, 3> ids{};
2031 std::array<std::unique_ptr<FEBase>, 3> fe_faces{};
2032 std::array<std::unique_ptr<libMesh::QGauss>, 3> qfaces{};
2033 for (
const auto side_dim :
make_range(mesh_dim))
2041 fe_faces[side_dim]->attach_quadrature_rule(qfaces[side_dim].
get());
2042 fe_faces[side_dim]->get_normals();
2048 std::vector<boundary_id_type> face_ids;
2051 std::set<unsigned int> side_dims;
2061 const auto side_dim =
elem->
dim() - 1;
2062 side_dims.insert(side_dim);
2069 fe_faces[side_dim]->reinit(
elem, s);
2070 const auto & normal = fe_faces[side_dim]->get_normals()[0];
2076 boundary_info.boundary_ids(
elem, s, face_ids);
2079 for (
const auto unit_dim : unit_dims)
2083 nonzero_dims[unit_dim] =
true;
2085 for (
const auto plus : {
false,
true})
2089 ids[side_dim][unit_dim][plus].insert(face_ids.begin(), face_ids.end());
2109 std::vector<std::tuple<unsigned int, unsigned int, unsigned char, boundary_id_type>> id_data;
2110 for (
const auto side_dim : side_dims)
2111 for (
const auto unit_dim : unit_dims)
2112 for (
const auto plus : {
false,
true})
2113 for (
const auto bd : ids[side_dim][unit_dim][plus])
2114 id_data.emplace_back(side_dim, unit_dim, plus, bd);
2116 for (
const auto & [side_dim, unit_dim, plus_char, bd] : id_data)
2117 ids[side_dim][unit_dim][bool(plus_char)].insert(bd);
2120 for (
auto & entry : nonzero_dims)
2128 std::ostringstream oss_found, oss_missing;
2129 for (
const auto side_dim : side_dims)
2131 for (
const auto unit_dim : unit_dims)
2132 if (nonzero_dims[unit_dim])
2134 const auto & unit_name = unit_dim_names[unit_dim];
2135 const auto & minus = ids[side_dim][unit_dim][
false];
2136 const auto & plus = ids[side_dim][unit_dim][
true];
2138 if (minus.size() == 1 && plus.size() == 1)
2140 const auto get_boundary_name = [
this](
const auto id)
2143 return name.size() ?
name : std::to_string(
id);
2146 oss_found <<
"\n " << side_dim + 1 <<
"D " << unit_name
2147 <<
"-direction: " << get_boundary_name(*minus.begin()) <<
" <-> " 2148 << get_boundary_name(*plus.begin());
2149 _paired_boundary->emplace_back(std::make_pair(*minus.begin(), *plus.begin()));
2152 oss_missing <<
"\n " << side_dim + 1 <<
"D -" << unit_name <<
"/+" << unit_name
2153 <<
": Found " << minus.size() <<
" -" << unit_name <<
" boundaries and " 2154 << plus.size() <<
" +" << unit_name <<
" boundaries";
2158 std::ostringstream oss;
2159 const auto found = oss_found.str();
2160 const auto missing = oss_missing.str();
2162 oss <<
"The following paired boundaries were automatically detected for periodicity:\n" 2168 oss <<
"Paired boundaries were not automatically detected for the following:\n" 2170 <<
"\n\nAutomatic detection requires that exactly one boundary is found in each unit " 2186 mooseAssert(
_mesh,
"The MeshBase has not been constructed");
2187 mooseAssert(component <
_bounds.size(),
"Requested dimension out of bounds");
2195 mooseAssert(
_mesh,
"The MeshBase has not been constructed");
2196 mooseAssert(component <
_bounds.size(),
"Requested dimension out of bounds");
2203 const unsigned int var_num,
2210 const auto key = std::make_pair(sys_num, var_num);
2215 bool component_found =
false;
2220 if (boundary_ids && ((boundary_ids->first == primary && boundary_ids->second == secondary) ||
2221 (boundary_ids->first == secondary && boundary_ids->second == primary)))
2223 entry[component] =
true;
2224 component_found =
true;
2228 if (!component_found)
2229 mooseWarning(
"Could not find a match between boundary '",
2233 "' to set periodic boundary conditions for variable (index:",
2235 ") in either the X, Y or Z direction. The periodic dimension of the mesh for this " 2236 "variable will not be stored.");
2239 const std::array<bool, 3> &
2242 const auto key = std::make_pair(sys_num, var_num);
2248 const std::array<bool, 3> &
2256 const unsigned int var_num,
2257 const unsigned int component)
const 2259 mooseAssert(component <
dimension(),
"Requested dimension out of bounds");
2273 "MooseMesh::isTranslatedPeriodic(const unsigned int, const unsigned int) is deprecated. Use " 2274 "the method that additionally takes the system number or the MooseVariableBase instead."));
2280 const unsigned int var_num,
2289 if (periodic_dims[i])
2317 mooseDoOnce(
mooseDeprecated(
"MooseMesh::minPeriodicVector(const unsigned int, const Point &, " 2318 "const Point &) is deprecated. Use the method that additionally " 2319 "takes the system number or the MooseVariableBase instead."));
2325 const unsigned int var_num,
2327 const Point & q)
const 2335 const Point & q)
const 2343 mooseDoOnce(
mooseDeprecated(
"MooseMesh::minPeriodicDistance(const unsigned int, const Point &, " 2344 "const Point &) is deprecated. Use the method that additionally " 2345 "takes the system number or the MooseVariableBase instead."));
2349 const std::pair<BoundaryID, BoundaryID> *
2353 mooseError(
"Trying to retrieve automatic paired mapping for a mesh that is not regular and " 2356 mooseAssert(component <
dimension(),
"Requested dimension out of bounds");
2359 mooseError(
"MooseMesh::getPairedBoundaryMapping(): Paired boundaries not built; must call " 2360 "detectPairedSidesets() first");
2362 if (component < _paired_boundary->size())
2363 return &(*_paired_boundary)[component];
2371 std::map<ElemType, Elem *> canonical_elems;
2375 for (
const auto &
elem :
getMesh().element_ptr_range())
2379 if (canonical_elems.find(
type) ==
2380 canonical_elems.end())
2384 Elem * stored = canonical_elems[
type];
2391 for (
const auto & can_it : canonical_elems)
2409 for (
unsigned int side = 0; side <
elem->
n_sides(); side++)
2417 for (
unsigned int child = 0; child <
elem->
n_children(); ++child)
2418 for (
unsigned int side = 0; side <
elem->
n_sides();
2433 std::map<ElemType, std::pair<Elem *, unsigned int>> elems_and_max_p_level;
2435 for (
const auto &
elem :
getMesh().active_element_ptr_range())
2438 auto & [picked_elem, max_p_level] = elems_and_max_p_level[
type];
2446 std::vector<Point> volume_ref_points_coarse, volume_ref_points_fine, face_ref_points_coarse,
2447 face_ref_points_fine;
2448 std::vector<unsigned int> p_levels;
2450 for (
auto & [elem_type, elem_p_level_pair] : elems_and_max_p_level)
2452 auto & [moose_elem, max_p_level] = elem_p_level_pair;
2453 const auto dim = moose_elem->dim();
2456 assembly->
reinit(moose_elem);
2457 assembly->
reinit(moose_elem, 0);
2464 for (
const auto & nd : moose_elem->node_ref_range())
2473 const auto & face_phys_points = fe_face->get_xyz();
2474 fe_face->attach_quadrature_rule(qrule_face);
2477 volume_ref_points_coarse = qrule->get_points();
2478 fe_face->reinit(
elem, (
unsigned int)0);
2481 p_levels.resize(max_p_level + 1);
2482 std::iota(p_levels.begin(), p_levels.end(), 0);
2485 for (
const auto p_level : p_levels)
2487 mesh_refinement.uniformly_p_refine(1);
2489 volume_ref_points_fine = qrule->get_points();
2490 fe_face->reinit(
elem, (
unsigned int)0);
2493 const auto map_key = std::make_pair(elem_type, p_level);
2499 auto fill_maps = [
this](
const auto & coarse_ref_points,
2500 const auto & fine_ref_points,
2504 mapPoints(fine_ref_points, coarse_ref_points, refine_map);
2505 mapPoints(coarse_ref_points, fine_ref_points, coarsen_map);
2509 volume_ref_points_coarse, volume_ref_points_fine, volume_coarsen_map, volume_refine_map);
2510 fill_maps(face_ref_points_coarse, face_ref_points_fine, face_coarsen_map, face_refine_map);
2513 volume_ref_points_fine.swap(volume_ref_points_coarse);
2514 face_ref_points_fine.swap(face_ref_points_coarse);
2522 TIME_SECTION(
"buildRefinementAndCoarseningMaps", 5,
"Building Refinement And Coarsening Maps");
2537 TIME_SECTION(
"buildRefinementMap", 5,
"Building Refinement Map");
2541 mooseAssert(parent_side == child_side,
2542 "Parent side must match child_side if not passing a specific child!");
2544 std::pair<int, ElemType> the_pair(parent_side,
elem.
type());
2547 mooseError(
"Already built a qp refinement map!");
2549 std::vector<std::pair<unsigned int, QpMap>> coarsen_map;
2552 &
elem, qrule, qrule_face, refinement_map, coarsen_map, parent_side, child, child_side);
2556 std::pair<int, int> child_pair(child, child_side);
2562 mooseError(
"Already built a qp refinement map!");
2564 std::vector<std::pair<unsigned int, QpMap>> coarsen_map;
2565 std::vector<std::vector<QpMap>> & refinement_map =
2568 &
elem, qrule, qrule_face, refinement_map, coarsen_map, parent_side, child, child_side);
2572 const std::vector<std::vector<QpMap>> &
2577 mooseAssert(parent_side == child_side,
2578 "Parent side must match child_side if not passing a specific child!");
2580 std::pair<int, ElemType> the_pair(parent_side,
elem.
type());
2583 mooseError(
"Could not find a suitable qp refinement map!");
2589 std::pair<int, int> child_pair(child, child_side);
2595 mooseError(
"Could not find a suitable qp refinement map!");
2611 TIME_SECTION(
"buildCoarseningMap", 5,
"Building Coarsening Map");
2613 std::pair<int, ElemType> the_pair(input_side,
elem.
type());
2616 mooseError(
"Already built a qp coarsening map!");
2618 std::vector<std::vector<QpMap>> refinement_map;
2619 std::vector<std::pair<unsigned int, QpMap>> & coarsen_map =
2626 &
elem, qrule, qrule_face, refinement_map, coarsen_map, input_side, -1, input_side);
2636 const std::vector<std::pair<unsigned int, QpMap>> &
2639 std::pair<int, ElemType> the_pair(input_side,
elem.
type());
2642 mooseError(
"Could not find a suitable qp refinement map!");
2649 const std::vector<Point> & to,
2650 std::vector<QpMap> & qp_map)
2652 unsigned int n_from = from.size();
2653 unsigned int n_to = to.size();
2655 qp_map.resize(n_from);
2657 for (
unsigned int i = 0; i < n_from; ++i)
2659 const Point & from_point = from[i];
2661 QpMap & current_map = qp_map[i];
2663 for (
unsigned int j = 0; j < n_to; ++j)
2665 const Point & to_point = to[j];
2671 current_map.
_from = i;
2672 current_map.
_to = j;
2682 std::vector<std::vector<QpMap>> & refinement_map,
2683 std::vector<std::pair<unsigned int, QpMap>> & coarsen_map,
2688 TIME_SECTION(
"findAdaptivityQpMaps", 5);
2693 unsigned int dim = template_elem->
dim();
2696 for (
unsigned int i = 0; i < template_elem->
n_nodes(); ++i)
2701 for (
unsigned int i = 0; i < template_elem->
n_nodes(); ++i)
2706 const std::vector<Point> & q_points_volume = fe->get_xyz();
2710 const std::vector<Point> & q_points_face = fe_face->get_xyz();
2712 fe->attach_quadrature_rule(&qrule);
2713 fe_face->attach_quadrature_rule(&qrule_face);
2716 const std::vector<Point> * q_points;
2718 if (parent_side != -1)
2720 fe_face->reinit(
elem, parent_side);
2721 q_points = &q_points_face;
2726 q_points = &q_points_volume;
2729 std::vector<Point> parent_ref_points;
2733 mesh_refinement.uniformly_refine(1);
2738 std::map<unsigned int, std::vector<Point>> child_to_ref_points;
2742 refinement_map.resize(n_children);
2744 std::vector<unsigned int> children;
2747 children.push_back(child);
2750 children.resize(n_children);
2751 for (
unsigned int child = 0; child < n_children; ++child)
2752 children[child] = child;
2755 for (
unsigned int i = 0; i < children.size(); ++i)
2757 unsigned int child = children[i];
2764 if (child_side != -1)
2766 fe_face->reinit(child_elem, child_side);
2767 q_points = &q_points_face;
2771 fe->reinit(child_elem);
2772 q_points = &q_points_volume;
2775 std::vector<Point> child_ref_points;
2778 child_to_ref_points[child] = child_ref_points;
2780 std::vector<QpMap> & qp_map = refinement_map[child];
2783 mapPoints(child_ref_points, parent_ref_points, qp_map);
2786 coarsen_map.resize(parent_ref_points.size());
2789 for (
unsigned int child = 0; child < n_children; child++)
2794 std::vector<Point> & child_ref_points = child_to_ref_points[child];
2796 std::vector<QpMap> qp_map;
2799 mapPoints(parent_ref_points, child_ref_points, qp_map);
2802 for (
unsigned int parent_qp = 0; parent_qp < parent_ref_points.size(); ++parent_qp)
2804 std::pair<unsigned int, QpMap> & child_and_map = coarsen_map[parent_qp];
2805 unsigned int & closest_child = child_and_map.first;
2806 QpMap & closest_map = child_and_map.second;
2808 QpMap & current_map = qp_map[parent_qp];
2812 closest_child = child;
2813 closest_map = current_map;
2824 TIME_SECTION(
"changeBoundaryId", 6);
2838 std::vector<boundary_id_type> old_ids;
2844 for (
unsigned int s = 0; s != n_sides; ++s)
2847 if (
std::find(old_ids.begin(), old_ids.end(), old_id) != old_ids.end())
2849 std::vector<boundary_id_type> new_ids(old_ids);
2850 std::replace(new_ids.begin(), new_ids.end(), old_id, new_id);
2885 mooseError(
"MooseMesh::clone() is no longer supported, use MooseMesh::safeClone() instead.");
2916 std::unique_ptr<MeshBase>
2919 std::unique_ptr<MeshBase>
mesh;
2921 mesh = buildTypedMesh<DistributedMesh>(
dim);
2923 mesh = buildTypedMesh<ReplicatedMesh>(
dim);
2931 _mesh = std::move(mesh_base);
2948 mooseError(
"You cannot use the mesh splitter capability with DistributedMesh!");
2950 TIME_SECTION(
"init", 2);
2965 TIME_SECTION(
"readRecoveredMesh", 2);
2979 if (getParam<bool>(
"build_all_side_lowerd_mesh"))
2993 const Real abs_zero = 1e-12;
2997 for (
unsigned int dim = LIBMESH_DIM;
dim >= 1; --
dim)
3012 return *elem_dims.begin();
3014 unsigned short dim = 0;
3016 const std::set<SubdomainID> subdomain_ids_set(subdomain_ids.begin(), subdomain_ids.end());
3025 std::vector<BoundaryID>
3028 std::vector<BoundaryID> ids;
3033 std::vector<std::vector<BoundaryID>>
3036 std::vector<std::vector<BoundaryID>> ids;
3041 const std::set<BoundaryID> &
3066 if (!node_bcids.empty())
3067 next_bcid =
std::max(next_bcid, cast_int<boundary_id_type>(*node_bcids.rbegin() + 1));
3068 if (!side_bcids.empty())
3069 next_bcid =
std::max(next_bcid, cast_int<boundary_id_type>(*side_bcids.rbegin() + 1));
3079 if (next_bcid > 1000 || next_bcid <= 0)
3085 for (
auto bcid : side_bcids)
3086 if (node_bcids.count(bcid) &&
3093 }
while (node_bcids.count(next_bcid) || side_bcids.count(next_bcid));
3108 std::vector<std::tuple<dof_id_type, unsigned short int, boundary_id_type>>
3114 std::vector<std::tuple<dof_id_type, unsigned short int, boundary_id_type>>
3129 return getMesh().local_nodes_begin();
3135 return getMesh().local_nodes_end();
3138 MeshBase::const_node_iterator
3141 return getMesh().local_nodes_begin();
3144 MeshBase::const_node_iterator
3147 return getMesh().local_nodes_end();
3150 MeshBase::element_iterator
3153 return getMesh().active_local_elements_begin();
3156 const MeshBase::element_iterator
3159 return getMesh().active_local_elements_end();
3162 MeshBase::const_element_iterator
3165 return getMesh().active_local_elements_begin();
3168 const MeshBase::const_element_iterator
3171 return getMesh().active_local_elements_end();
3201 mooseDeprecated(
"MooseMesh::elem() is deprecated, please use MooseMesh::elemPtr() instead");
3208 mooseDeprecated(
"MooseMesh::elem() is deprecated, please use MooseMesh::elemPtr() instead");
3246 mooseError(
"We don't have any right to tell the libmesh mesh that it *is* prepared. Only a " 3247 "call to prepare_for_use should tell us that");
3252 _mesh->unset_is_prepared();
3270 const std::set<SubdomainID> &
3276 const std::set<BoundaryID> &
3282 const std::set<BoundaryID> &
3288 const std::set<BoundaryID> &
3302 std::unique_ptr<std::map<BoundaryID, RealVectorValue>> boundary_map)
3310 mooseDeprecated(
"setBoundaryToNormalMap(std::map<BoundaryID, RealVectorValue> * boundary_map) is " 3311 "deprecated, use the unique_ptr version instead");
3340 const std::set<unsigned int> &
3346 const std::vector<Real> &
3360 template <
typename T>
3361 struct extra_ghost_elem_inserter
3363 using iterator_category = std::output_iterator_tag;
3364 using value_type = T;
3368 void operator=(
const Elem * e) {
mesh.add_extra_ghost_elem(const_cast<Elem *>(e)); }
3374 extra_ghost_elem_inserter &
operator++() {
return *
this; }
3376 extra_ghost_elem_inserter
operator++(
int) {
return extra_ghost_elem_inserter(*
this); }
3382 extra_ghost_elem_inserter &
operator*() {
return *
this; }
3398 struct CompareElemsByLevel
3400 bool operator()(
const Elem * a,
const Elem * b)
const 3404 const unsigned int al = a->
level(), bl = b->
level();
3407 return (al == bl) ? aid < bid : al < bl;
3423 TIME_SECTION(
"GhostGhostedBoundaries", 3);
3425 parallel_object_only();
3435 std::set<const Elem *, CompareElemsByLevel> boundary_elems_to_ghost;
3436 std::set<Node *> connected_nodes_to_ghost;
3442 auto elem_id = std::get<0>(t);
3443 auto bc_id = std::get<2>(t);
3449 #ifdef LIBMESH_ENABLE_AMR 3455 parent = parent->
parent();
3463 boundary_elems_to_ghost.insert(felem);
3471 for (
unsigned int n = 0; n < felem->n_nodes(); ++n)
3472 connected_nodes_to_ghost.insert(const_cast<Node *>(felem->node_ptr(n)));
3478 const auto prior_ghost_elems =
mesh.extra_ghost_elems();
3481 connected_nodes_to_ghost.begin(),
3482 connected_nodes_to_ghost.end(),
3483 extra_ghost_elem_inserter<Node>(
mesh));
3486 boundary_elems_to_ghost.begin(),
3487 boundary_elems_to_ghost.end(),
3488 extra_ghost_elem_inserter<Elem>(
mesh));
3490 const auto & current_ghost_elems =
mesh.extra_ghost_elems();
3492 std::set_difference(current_ghost_elems.begin(),
3493 current_ghost_elems.end(),
3494 prior_ghost_elems.begin(),
3495 prior_ghost_elems.end(),
3528 Real inflation_amount = inflation_multiplier * (bbox.
max() - bbox.
min()).
norm();
3529 Point inflation(inflation_amount, inflation_amount, inflation_amount);
3531 bbox.first -= inflation;
3532 bbox.second += inflation;
3550 mooseAssert(
_mesh,
"Mesh hasn't been created");
3557 mooseAssert(
_mesh,
"Mesh hasn't been created");
3569 const std::vector<dof_id_type> &
3572 std::map<boundary_id_type, std::vector<dof_id_type>>::const_iterator it =
3582 static const std::vector<dof_id_type> empty_vec;
3589 mooseError(
"Unable to nodeset ID: ", nodeset_id,
'.');
3596 const std::set<BoundaryID> &
3602 mooseError(
"Unable to find subdomain ID: ", subdomain_id,
'.');
3604 return it->second.boundary_ids;
3607 std::set<BoundaryID>
3611 std::set<BoundaryID> boundary_ids(bnd_ids.begin(), bnd_ids.end());
3612 std::unordered_map<SubdomainID, std::set<BoundaryID>>::const_iterator it =
3615 boundary_ids.insert(it->second.begin(), it->second.end());
3617 return boundary_ids;
3620 std::set<SubdomainID>
3623 std::set<SubdomainID> subdomain_ids;
3625 if (data.boundary_ids.find(bid) != data.boundary_ids.end())
3626 subdomain_ids.insert(sub_id);
3628 return subdomain_ids;
3631 std::set<SubdomainID>
3634 std::set<SubdomainID> subdomain_ids;
3636 if (it.second.find(bid) != it.second.end())
3637 subdomain_ids.insert(it.first);
3639 return subdomain_ids;
3642 std::set<SubdomainID>
3647 if (it.second.find(bid) != it.second.end())
3648 subdomain_ids.insert(it.first);
3650 return subdomain_ids;
3653 const std::set<SubdomainID> &
3659 mooseError(
"Unable to find subdomain ID: ", subdomain_id,
'.');
3661 return it->second.neighbor_subs;
3667 bool found_node =
false;
3670 if (it.second.find(node_id) != it.second.end())
3682 bool found_node =
false;
3683 std::map<boundary_id_type, std::set<dof_id_type>>::const_iterator it =
_bnd_node_ids.find(bnd_id);
3685 if (it->second.find(node_id) != it->second.end())
3693 bool found_elem =
false;
3696 if (it.second.find(elem_id) != it.second.end())
3708 bool found_elem =
false;
3711 if (it->second.find(elem_id) != it->second.end())
3722 " with DistributedMesh!\n",
3723 "Consider specifying parallel_type = 'replicated' in your input file\n",
3724 "to prevent it from being run with DistributedMesh.");
3742 bool use_distributed_mesh,
3747 switch (partitioner)
3751 if (use_distributed_mesh)
3752 partitioner =
"parmetis";
3754 partitioner =
"metis";
3768 if (!params.
isParamValid(
"centroid_partitioner_direction"))
3770 "centroid_partitioner_direction",
3771 "If using the centroid partitioner you _must_ specify centroid_partitioner_direction!");
3775 if (direction ==
"x")
3778 else if (direction ==
"y")
3781 else if (direction ==
"z")
3784 else if (direction ==
"radial")
3817 bool mesh_has_second_order_elements =
false;
3819 if ((*it)->default_order() ==
SECOND)
3821 mesh_has_second_order_elements =
true;
3826 comm().
max(mesh_has_second_order_elements);
3827 return mesh_has_second_order_elements;
3836 std::unique_ptr<libMesh::PointLocatorBase>
3845 mooseAssert(!Threads::in_threads,
3846 "This routine has not been implemented for threads. Please query this routine before " 3847 "a threaded region or contact a MOOSE developer to discuss.");
3850 using Keytype = std::pair<const Elem *, unsigned short int>;
3853 std::vector<std::tuple<dof_id_type, unsigned short int, boundary_id_type>> side_list =
3855 std::map<Keytype, std::set<boundary_id_type>> side_map;
3856 for (
auto & [elem_id, side, bc_id] : side_list)
3859 Keytype key(
elem, side);
3860 auto & bc_set = side_map[key];
3861 bc_set.insert(bc_id);
3875 auto begin =
getMesh().active_elements_begin();
3876 auto end =
getMesh().active_elements_end();
3881 unsigned int num_sides = 0;
3896 for (
unsigned int side = 0; side <
elem->
n_sides(); ++side)
3907 "If the neighbor is coarser than the element, we expect that the neighbor must " 3911 mooseAssert(
elem->
default_order() < 4,
"Did not expect such high element orders in FV");
3919 std::set<boundary_id_type> & boundary_ids = fi.boundaryIDs();
3920 boundary_ids.clear();
3926 fi.computeBoundaryCoefficients();
3930 auto lit = side_map.find(Keytype(&fi.elem(), fi.elemSideID()));
3931 if (lit != side_map.end())
3932 boundary_ids.insert(lit->second.begin(), lit->second.end());
3934 if (fi.neighborPtr())
3936 auto rit = side_map.find(Keytype(fi.neighborPtr(), fi.neighborSideID()));
3937 if (rit != side_map.end())
3938 boundary_ids.insert(rit->second.begin(), rit->second.end());
3952 const Elem *
const elem = &fi.elem();
3953 const auto side = fi.elemSideID();
3959 mooseAssert(pair_it.second,
"We should be adding unique FaceInfo objects.");
3963 if (fi.elem().processor_id() == this->
processor_id() ||
3964 (fi.neighborPtr() && (fi.neighborPtr()->processor_id() == this->
processor_id())))
3970 if (ei.second.elem()->processor_id() == this->
processor_id())
3983 mooseAssert(it->second,
3984 "For some reason, the FaceInfo object is NULL! Try calling " 3985 "`buildFiniteVolumeInfo()` before using this accessor!");
4000 mooseError(
"Trying to compute face- and elem-info coords when the information is dirty");
4005 const SubdomainID elem_subdomain_id = fi.elemSubdomainID();
4006 const SubdomainID neighbor_subdomain_id = fi.neighborSubdomainID();
4009 *
this, elem_subdomain_id, fi.faceCentroid(), fi.faceCoord(), neighbor_subdomain_id);
4014 *
this, ei.second.subdomain_id(), ei.second.centroid(), ei.second.coordFactor());
4021 "default=-3 metis=-2 parmetis=-1 linear=0 centroid hilbert_sfc morton_sfc custom",
"default");
4029 "EDGE EDGE2 EDGE3 EDGE4 QUAD QUAD4 QUAD8 QUAD9 TRI3 TRI6 HEX HEX8 HEX20 HEX27 TET4 TET10 " 4030 "PRISM6 PRISM15 PRISM18 PYRAMID5 PYRAMID13 PYRAMID14");
4039 _mesh->allow_remote_element_removal(allow_remote_element_removal);
4041 if (!allow_remote_element_removal)
4053 mooseError(
"Cannot delete remote elements because we have not yet attached a MeshBase");
4055 _mesh->allow_remote_element_removal(
true);
4057 _mesh->delete_remote_elements();
4064 !Threads::in_threads,
4065 "Performing writes to faceInfo variable association maps. This must be done unthreaded!");
4069 auto face_lambda = [
this](
const SubdomainID elem_subdomain_id,
4072 std::vector<std::vector<FaceInfo::VarFaceNeighbors>> & face_type_vector)
4075 const auto & variables = sys.getVariables(0);
4077 for (
const auto & var : variables)
4079 const unsigned int var_num = var->
number();
4080 const unsigned int sys_num = var->
sys().
number();
4081 std::set<SubdomainID> var_subdomains = var->
blockIDs();
4091 bool var_defined_elem = var_subdomains.find(elem_subdomain_id) != var_subdomains.end();
4092 bool var_defined_neighbor =
4093 var_subdomains.find(neighbor_subdomain_id) != var_subdomains.end();
4094 if (var_defined_elem && var_defined_neighbor)
4096 else if (!var_defined_elem && !var_defined_neighbor)
4101 if (var_defined_elem)
4103 else if (var_defined_neighbor)
4115 const SubdomainID elem_subdomain_id = face.elemSubdomainID();
4116 const SubdomainID neighbor_subdomain_id = face.neighborSubdomainID();
4118 auto & face_type_vector = face.faceType();
4120 face_type_vector.clear();
4121 face_type_vector.resize(num_eqs);
4125 face_lambda(elem_subdomain_id,
4126 neighbor_subdomain_id,
4131 face_lambda(elem_subdomain_id,
4132 neighbor_subdomain_id,
4141 mooseAssert(!Threads::in_threads,
4142 "Performing writes to elemInfo dof indices. This must be done unthreaded!");
4144 auto elem_lambda = [](
const ElemInfo & elem_info,
4146 std::vector<std::vector<dof_id_type>> & dof_vector)
4148 if (sys.nFVVariables())
4151 const auto & variables = sys.getVariables(0);
4153 for (
const auto & var : variables)
4156 const auto & var_subdomains = var->
blockIDs();
4159 if (var_subdomains.find(elem_info.
subdomain_id()) != var_subdomains.end())
4161 std::vector<dof_id_type> indices;
4163 mooseAssert(indices.size() == 1,
"We expect to have only one dof per element!");
4164 dof_vector[sys.number()][var->
number()] = indices[0];
4176 auto & elem_info = ei_pair.second;
4180 dof_vector.resize(num_eqs);
4204 TIME_SECTION(
"setCoordSystem", 5,
"Setting Coordinate System");
4207 const std::string param_name =
isParamValid(
"coord_block") ?
"coord_block" :
"block";
4208 mooseWarning(
"Supplied blocks in the 'setCoordSystem' method do not match the value of the " 4211 "' parameter. Did you provide different parameter values for 'Mesh/",
4213 "' and 'Problem/block'?. We will honor the parameter value from 'Mesh/",
4217 "If we are arriving here due to a bad specification in the Problem block, then we " 4218 "should have already set our coordinate system subdomains from the Mesh block");
4222 mooseError(
"Supplied coordinate systems in the 'setCoordSystem' method do not match the value " 4223 "of the 'Mesh/coord_type' parameter. Did you provide different parameter values for " 4224 "'coord_type' to 'Mesh' and 'Problem'?");
4231 if (coord_sys.
size() > 1)
4232 mooseError(
"If you specify ANY_BLOCK_ID as the only block, you must also specify a single " 4233 "coordinate system for it.");
4234 if (!
_mesh->is_prepared())
4236 "You cannot set the coordinate system for ANY_BLOCK_ID before the mesh is prepared. " 4237 "Please call this method after the mesh is prepared.");
4238 const auto coord_type = coord_sys.
size() == 0
4240 : Moose::stringToEnum<Moose::CoordinateSystemType>(coord_sys[0]);
4248 mooseError(
"You cannot specify ANY_BLOCK_ID together with other blocks in the " 4249 "setCoordSystem() method. If you want to set the same coordinate system for all " 4250 "blocks, use ANY_BLOCK_ID as the only block.");
4255 for (
const auto & sub_name :
blocks)
4258 subdomains.insert(sub_id);
4261 if (coord_sys.
size() <= 1)
4264 const auto coord_type = coord_sys.
size() == 0
4266 : Moose::stringToEnum<Moose::CoordinateSystemType>(coord_sys[0]);
4267 for (
const auto sid : subdomains)
4273 mooseError(
"Number of blocks and coordinate systems does not match.");
4279 Moose::stringToEnum<Moose::CoordinateSystemType>(coord_sys[i]);
4283 for (
const auto & sid : subdomains)
4286 "' does not have a coordinate system specified.");
4299 return (*it).second;
4301 mooseError(
"Requested subdomain ", sid,
" does not exist.");
4309 bool result = std::all_of(
4313 typename std::unordered_map<SubdomainID, Moose::CoordinateSystemType>::const_reference
4314 item) {
return (item.second == unique_system); });
4316 mooseError(
"The unique coordinate system of the mesh was requested by the mesh contains " 4317 "multiple blocks with different coordinate systems");
4320 mooseError(
"General axisymmetric coordinate axes are being used, and it is currently " 4321 "conservatively assumed that in this case there is no unique coordinate system.");
4323 return unique_system;
4326 const std::map<SubdomainID, Moose::CoordinateSystemType> &
4342 const std::vector<SubdomainName> &
blocks,
4343 const std::vector<std::pair<Point, RealVectorValue>> & axes)
4346 mooseAssert(
blocks.size() == axes.size(),
"Blocks and axes vectors must be the same length.");
4350 const auto it =
_coord_sys.find(subdomain_id);
4354 "' has not set a coordinate system. Make sure to call setCoordSystem() before " 4355 "setGeneralAxisymmetricCoordAxes().");
4360 const auto direction = axes[i].second;
4361 if (direction.is_zero())
4362 mooseError(
"Only nonzero vectors may be supplied for RZ directions.");
4365 std::make_pair(axes[i].first, direction.unit());
4370 "' was provided in setGeneralAxisymmetricCoordAxes(), but the coordinate system " 4371 "for this block is not 'RZ'.");
4377 for (
const auto subdomain_id : all_subdomain_ids)
4382 "' was specified to use the 'RZ' coordinate system but was not given in " 4383 "setGeneralAxisymmetricCoordAxes().");
4388 const std::pair<Point, RealVectorValue> &
4393 return (*it).second;
4395 mooseError(
"Requested subdomain ", subdomain_id,
" does not exist.");
4417 mooseError(
"getAxisymmetricRadialCoord() should not be called if " 4418 "setGeneralAxisymmetricCoordAxes() has been called.");
4429 for (
const auto &
elem :
getMesh().element_ptr_range())
4434 " which contains 3D elements.");
4436 mooseError(
"An RSPHERICAL coordinate system was requested for subdomain " +
4459 std::map<SubdomainName, SubdomainID> subdomain;
4463 if (!sub_name.empty() && subdomain.count(sub_name) > 0)
4466 " is used for both subdomain with ID=",
4467 subdomain[sub_name],
4470 ", Please rename one of them!");
4472 subdomain[sub_name] = sbd_id;
4476 const std::vector<QpMap> &
4479 const std::map<std::pair<ElemType, unsigned int>, std::vector<QpMap>> & map)
const 4483 return libmesh_map_find(map,
4487 const std::vector<QpMap> &
4490 const std::map<std::pair<ElemType, unsigned int>, std::vector<QpMap>> & map)
const 4493 "These are the conditions that should be met for requesting a coarsening map");
4497 const std::vector<QpMap> &
4503 const std::vector<QpMap> &
4509 const std::vector<QpMap> &
4515 const std::vector<QpMap> &
4524 return _mesh->skip_noncritical_partitioning();
ParallelType _parallel_type
Can be set to DISTRIBUTED, REPLICATED, or DEFAULT.
bool hasDetectedPairedSidesets() const
Whether or not detectedPairedSidesets() has been called.
static InputParameters validParams()
Typical "Moose-style" constructor and copy constructor.
virtual bnd_node_iterator bndNodesEnd()
virtual bnd_elem_iterator bndElemsEnd()
std::vector< std::vector< Real > > _bounds
The bounds in each dimension of the mesh for regular orthogonal meshes.
std::set< Node * > _semilocal_node_list
Used for generating the semilocal node range.
void remove_id(boundary_id_type id, bool global=false)
std::map< dof_id_type, Node * > _quadrature_nodes
const std::vector< QpMap > & getPCoarseningSideMap(const Elem &elem) const
Get the map describing for each side quadrature point (qp) on the coarse level which qp on the previo...
virtual Real getMaxInDimension(unsigned int component) const
static const std::string & checkpointSuffix()
The file suffix for the checkpoint mesh.
bool _node_to_elem_map_built
Whether _node_to_elem_map has been built.
std::unique_ptr< libMesh::NodeRange > _active_node_range
MetaPhysicL::DualNumber< V, D, asd > abs(const MetaPhysicL::DualNumber< V, D, asd > &a)
std::vector< Node * > _extreme_nodes
A vector containing the nodes at the corners of a regular orthogonal mesh.
RealVectorValue minPeriodicVector(const unsigned int sys_num, const unsigned int var_num, Point p, Point q) const
Returns the minimum vector between two points on the mesh taking into account periodicity for the giv...
Node * addQuadratureNode(const Elem *elem, const unsigned short int side, const unsigned int qp, BoundaryID bid, const Point &point)
Adds a fictitious "QuadratureNode".
std::vector< std::tuple< dof_id_type, unsigned short int, boundary_id_type > > buildSideList()
Calls BoundaryInfo::build_side_list(), returns a std::vector of (elem-id, side-id, bc-id) tuples.
void computeMaxPerElemAndSide()
Compute the maximum numbers per element and side.
const std::set< BoundaryID > & meshNodesetIds() const
Returns a read-only reference to the set of nodesets currently present in the Mesh.
void buildElemIDInfo()
Build extra data for faster access to the information of extra element integers.
std::vector< FaceInfo > _all_face_info
FaceInfo object storing information for face based loops.
std::unique_ptr< FEGenericBase< Real > > build(const unsigned int dim, const FEType &fet)
void allgather(const T &send_data, std::vector< T, A > &recv_data) const
std::vector< const FaceInfo * > _face_info
Holds only those FaceInfo objects that have processor_id equal to this process's id, e.g.
bool allowRemoteElementRemoval() const
Whether we are allow remote element removal.
virtual Real getMinInDimension(unsigned int component) const
Returns the min or max of the requested dimension respectively.
bool possiblyRebuildNodeToElemMap()
rebuild the node to element map if it's been requsted previously
bool elemHasFaceInfo(const Elem &elem, const Elem *const neighbor)
This function infers based on elements if the faceinfo between them belongs to the element or not...
libMesh::ConstElemRange * getActiveLocalElementRange()
Return pointers to range objects for various types of ranges (local nodes, boundary elems...
virtual void onMeshChanged()
Declares a callback function that is executed at the conclusion of meshChanged(). ...
bool prepared() const
Setter/getter for whether the mesh is prepared.
void needsPrepareForUse()
If this method is called, we will call libMesh's prepare_for_use method when we call Moose's prepare ...
const std::set< boundary_id_type > & get_side_boundary_ids() const
const std::set< BoundaryID > & getBoundaryIDs() const
Returns a const reference to a set of all user-specified boundary IDs.
bool _is_nemesis
True if a Nemesis Mesh was read in.
static const std::string name_param
The name of the parameter that contains the object name.
std::vector< SubdomainName > _provided_coord_blocks
Set for holding user-provided coordinate system type block names.
virtual MooseMesh & clone() const
Clone method.
KOKKOS_INLINE_FUNCTION const T * find(const T &target, const T *const begin, const T *const end)
Find a value in an array.
const Elem * parent() const
const std::vector< QpMap > & getPCoarseningMapHelper(const Elem &elem, const std::map< std::pair< libMesh::ElemType, unsigned int >, std::vector< QpMap >> &) const
bool isCustomPartitionerRequested() const
Setter and getter for _custom_partitioner_requested.
bool _need_ghost_ghosted_boundaries
A parallel mesh generator such as DistributedRectilinearMeshGenerator already make everything ready...
A class for creating restricted objects.
bool isUltimateMaster() const
Whether or not this app is the ultimate master app.
std::vector< BCTuple > build_active_side_list() const
unsigned int _uniform_refine_level
The level of uniform refinement requested (set to zero if AMR is disabled)
virtual Node *& set_node(const unsigned int i)
const std::vector< QpMap > & getPRefinementMapHelper(const Elem &elem, const std::map< std::pair< libMesh::ElemType, unsigned int >, std::vector< QpMap >> &) const
unsigned int n_systems() const
std::vector< dof_id_type > _min_ids
Minimum integer ID for each extra element integer.
Helper class for sorting Boundary Nodes so that we always get the same order of application for bound...
const InputParameters & _pars
The object's parameters.
libMesh::QBase *const & writeableQRule()
Returns the reference to the current quadrature being used.
virtual unique_id_type parallel_max_unique_id() const=0
std::unordered_set< dof_id_type > getBoundaryActiveSemiLocalElemIds(BoundaryID bid) const
Return all ids of elements which have a side which is part of a sideset.
std::string & nodeset_name(boundary_id_type id)
const MooseUnits & lengthUnit() const
void checkDuplicateSubdomainNames()
Loop through all subdomain IDs and check if there is name duplication used for the subdomains with sa...
const unsigned int invalid_uint
const std::set< BoundaryID > & getSubdomainBoundaryIds(const SubdomainID subdomain_id) const
Get the list of boundary ids associated with the given subdomain id.
std::unique_ptr< PointLocatorBase > sub_point_locator() const
RealVectorValue _half_range
A convenience vector used to hold values in each dimension representing half of the range...
Keeps track of stuff related to assembling.
std::map< libMesh::ElemType, std::map< std::pair< int, int >, std::vector< std::vector< QpMap > > > > _elem_type_to_child_side_refinement_map
Holds mappings for "internal" child sides to parent volume. The second key is (child, child_side).
void setCoordData(const MooseMesh &other_mesh)
Set the coordinate system data to that of other_mesh.
virtual void read(const std::string &name, void *mesh_data=nullptr, bool skip_renumber_nodes_and_elements=false, bool skip_find_neighbors=false, bool skip_detect_interior_parents=false)=0
const Elem * interior_parent() const
void paramError(const std::string ¶m, Args... args) const
Emits an error prefixed with the file and line number of the given param (from the input file) along ...
const T & getParam(const std::string &name) const
Retrieve a parameter for the object.
bool _finite_volume_info_dirty
virtual Elem * elemPtr(const dof_id_type i)
void allow_renumbering(bool allow)
The definition of the bnd_elem_iterator struct.
std::map< SubdomainID, Moose::CoordinateSystemType > & _coord_sys
Type of coordinate system per subdomain.
bool isBoundaryNode(dof_id_type node_id) const
Returns true if the requested node is in the list of boundary nodes, false otherwise.
face_info_iterator ownedFaceInfoBegin()
Iterators to owned faceInfo objects.
std::vector< std::tuple< dof_id_type, unsigned short int, boundary_id_type > > buildActiveSideList() const
Calls BoundaryInfo::build_active_side_list.
IntRange< unsigned short > side_index_range() const
static void setPartitioner(MeshBase &mesh_base, MooseEnum &partitioner, bool use_distributed_mesh, const InputParameters ¶ms, MooseObject &context_obj)
Method for setting the partitioner on the passed in mesh_base object.
void skip_partitioning(bool skip)
void dof_indices(const Elem *const elem, std::vector< dof_id_type > &di) const
void buildLowerDMesh()
Build lower-d mesh for all sides.
const std::set< BoundaryID > & meshSidesetIds() const
Returns a read-only reference to the set of sidesets currently present in the Mesh.
void side_boundary_ids(const Elem *const elem, std::vector< std::vector< boundary_id_type >> &vec_to_fill) const
virtual std::unique_ptr< Elem > build_side_ptr(const unsigned int i)=0
unsigned int number() const
Get variable number coming from libMesh.
std::unordered_map< const Elem *, unsigned short int > _lower_d_elem_to_higher_d_elem_side
const BoundaryID INVALID_BOUNDARY_ID
void cacheFVElementalDoFs() const
Cache the DoF indices for FV variables on each element.
static constexpr Real TOLERANCE
void cacheFaceInfoVariableOwnership() const
Cache if variables live on the elements connected by the FaceInfo objects.
bool _custom_partitioner_requested
unsigned int _max_nodes_per_side
The maximum number of nodes per side.
const std::unordered_map< boundary_id_type, std::unordered_set< dof_id_type > > & getBoundariesToElems() const
Returns a map of boundaries to ids of elements on the boundary.
Moose::CoordinateSystemType getUniqueCoordSystem() const
Get the coordinate system from the mesh, it must be the same in all subdomains otherwise this will er...
static Point inverse_map(const unsigned int dim, const Elem *elem, const Point &p, const Real tolerance=TOLERANCE, const bool secure=true, const bool extra_checks=true)
unsigned int _max_sides_per_elem
The maximum number of sides per element.
bool isSemiLocal(Node *const node) const
Returns true if the node is semi-local.
const libMesh::DofMap & dofMap() const
The DofMap associated with the system this variable is in.
unsigned int which_side_am_i(const Elem *e) const
KOKKOS_SCALAR_FUNCTION auto operator*(const T &left, const Scalar< U > &right) -> decltype(left *static_cast< const U &>(right))
virtual bool is_child_on_side(const unsigned int c, const unsigned int s) const=0
const Elem * getLowerDElem(const Elem *, unsigned short int) const
Returns a const pointer to a lower dimensional element that corresponds to a side of a higher dimensi...
std::unique_ptr< libMesh::StoredRange< MooseMesh::const_bnd_elem_iterator, const BndElement * > > _bnd_elem_range
const std::vector< std::pair< unsigned int, QpMap > > & getCoarseningMap(const Elem &elem, int input_side)
Get the coarsening map for a given element type.
std::unordered_map< boundary_id_type, std::unordered_set< dof_id_type > > _bnd_elem_ids
Map of set of elem IDs connected to each boundary.
void prepare_for_use(const bool skip_renumber_nodes_and_elements, const bool skip_find_neighbors)
RefinementState p_refinement_flag() const
bool _doing_p_refinement
Whether we have p-refinement (whether exclusively p- or hp-refinement)
const Elem * elem() const
void build_node_list_from_side_list(const std::set< boundary_id_type > &sideset_list={})
void determineUseDistributedMesh()
Determine whether to use a distributed mesh.
const std::vector< std::vector< QpMap > > & getRefinementMap(const Elem &elem, int parent_side, int child, int child_side)
Get the refinement map for a given element type.
const boundary_id_type side_id
void cacheChangedLists()
Cache information about what elements were refined and coarsened in the previous step.
void coordTransformFactor(const SubProblem &s, SubdomainID sub_id, const P &point, C &factor, SubdomainID neighbor_sub_id=libMesh::Elem::invalid_subdomain_id)
Computes a conversion multiplier for use when computing integraals for the current coordinate system ...
virtual void find_neighbors(const bool reset_remote_elements=false, const bool reset_current_list=true, const bool assert_valid=true)=0
const Point & getPoint(const PointObject &item) const
get a Point reference from the PointData object at index idx in the list
const std::map< boundary_id_type, std::string > & get_sideset_name_map() const
void family_tree(std::vector< const Elem * > &family, bool reset=true) const
unsigned int side_with_boundary_id(const Elem *const elem, const boundary_id_type boundary_id) const
The definition of the bnd_node_iterator struct.
const std::string & getBoundaryName(const BoundaryID boundary_id) const
Return the name of the boundary given the id.
unsigned int n_elem_integers() const
std::vector< const ElemInfo * > _elem_info
Holds only those ElemInfo objects that have processor_id equal to this process's id, e.g.
void buildHRefinementAndCoarseningMaps(Assembly *assembly)
boundary_id_type pairedboundary
PeriodicBoundaryBase * boundary(boundary_id_type id)
bool usingGeneralAxisymmetricCoordAxes() const
Returns true if general axisymmetric coordinate axes are being used.
std::map< std::pair< int, libMesh::ElemType >, std::vector< std::vector< QpMap > > > _elem_type_to_refinement_map
Holds mappings for volume to volume and parent side to child side Map key:
const std::set< SubdomainID > & getBlockConnectedBlocks(const SubdomainID subdomain_id) const
Get the list of subdomains neighboring a given subdomain.
virtual const Node * queryNodePtr(const dof_id_type i) const
virtual std::unique_ptr< Partitioner > & partitioner()
void addPeriodicVariable(const unsigned int sys_num, const unsigned int var_num, const BoundaryID primary, const BoundaryID secondary)
For "regular orthogonal" meshes, determine if variable var_num is periodic with respect to the primar...
std::unordered_map< std::pair< const Elem *, unsigned short int >, const Elem * > _higher_d_elem_side_to_lower_d_elem
Holds a map from a high-order element side to its corresponding lower-d element.
Helper object for holding qp mapping info.
unsigned int size() const
Return the number of active items in the MultiMooseEnum.
void mooseInfoRepeated(Args &&... args)
Emit an informational message with the given stringified, concatenated args.
const std::vector< Real > & getGhostedBoundaryInflation() const
Return a writable reference to the _ghosted_boundaries_inflation vector.
std::unique_ptr< ConstElemPointerRange > _refined_elements
The elements that were just refined.
std::vector< std::vector< bool > > _id_identical_flag
Flags to indicate whether or not any two extra element integers are the same.
virtual dof_id_type maxElemId() const
static constexpr std::size_t dim
This is the dimension of all vector and tensor datastructures used in MOOSE.
const Parallel::Communicator & comm() const
virtual bnd_elem_iterator bndElemsBegin()
Return iterators to the beginning/end of the boundary elements list.
void setUniformRefineLevel(unsigned int, bool deletion=true)
Set uniform refinement level.
virtual unsigned int n_children() const=0
unsigned int p_level() const
void allgather_packed_range(Context *context, Iter range_begin, const Iter range_end, OutputIter out, std::size_t approx_buffer_size=1000000) const
MooseEnum _partitioner_name
The partitioner used on this mesh.
std::unique_ptr< libMesh::ConstElemRange > _active_local_elem_range
A range for use with threading.
std::map< dof_id_type, std::set< SubdomainID > > _block_node_list
list of nodes that belongs to a specified block (domain)
std::map< boundary_id_type, std::set< dof_id_type > > _bnd_node_ids
Map of sets of node IDs in each boundary.
virtual void init()
Initialize the Mesh object.
ConstElemPointerRange * refinedElementRange() const
Return a range that is suitable for threaded execution over elements that were just refined...
void boundary_ids(const Node *node, std::vector< boundary_id_type > &vec_to_fill) const
unsigned int getHigherDSide(const Elem *elem) const
Returns the local side ID of the interior parent aligned with the lower dimensional element...
std::unordered_map< std::pair< const Elem *, unsigned int >, FaceInfo * > _elem_side_to_face_info
Map from elem-side pair to FaceInfo.
void detectPairedSidesets()
This routine detects paired sidesets of a regular orthogonal mesh (.i.e.
const std::set< SubdomainID > & getNodeBlockIds(const Node &node) const
Return list of blocks to which the given node belongs.
virtual std::unique_ptr< Partitioner > clone() const=0
const Parallel::Communicator & _communicator
std::map< std::pair< libMesh::ElemType, unsigned int >, std::vector< QpMap > > _elem_type_to_p_coarsening_side_map
virtual const std::set< SubdomainID > & blockIDs() const
Return the block subdomain ids for this object Note, if this is not block restricted, this function returns all mesh subdomain ids.
void setMeshBoundaryIDs(std::set< BoundaryID > boundary_IDs)
Sets the set of BoundaryIDs Is called by AddAllSideSetsByNormals.
std::map< boundary_id_type, std::vector< dof_id_type > > _node_set_nodes
list of nodes that belongs to a specified nodeset: indexing [nodeset_id] -> [array of node ids] ...
std::vector< subdomain_id_type > getSubdomainIDs(const libMesh::MeshBase &mesh, const std::vector< SubdomainName > &subdomain_name)
Get the associated subdomainIDs for the subdomain names that are passed in.
The following methods are specializations for using the libMesh::Parallel::packed_range_* routines fo...
std::set< SubdomainID > _lower_d_boundary_blocks
Mesh blocks for boundary lower-d elements in different types.
std::basic_ostream< charT, traits > * os
void changeBoundaryId(const boundary_id_type old_id, const boundary_id_type new_id, bool delete_prev)
Change all the boundary IDs for a given side from old_id to new_id.
Base class for a system (of equations)
const BoundaryInfo & get_boundary_info() const
std::set< Elem * > _ghost_elems_from_ghost_boundaries
Set of elements ghosted by ghostGhostedBoundaries.
virtual void buildMesh()=0
Must be overridden by child classes.
void setPartitionerHelper(MeshBase *mesh=nullptr)
void deleteRemoteElements()
Delete remote elements.
bool isSplitMesh() const
Whether or not this is a split mesh operation.
unsigned int _to
The qp to map to.
BoundaryID _bnd_id
boundary id for the node
std::vector< BCTuple > build_side_list(BCTupleSortBy sort_by=BCTupleSortBy::ELEM_ID) const
libMesh::ConstNodeRange * getLocalNodeRange()
virtual std::unique_ptr< MeshBase > clone() const=0
Real distance(const Point &p)
virtual const Node & nodeRef(const dof_id_type i) const
bool _allow_recovery
Whether or not this Mesh is allowed to read a recovery file.
virtual Node * add_point(const Point &p, const dof_id_type id=DofObject::invalid_id, const processor_id_type proc_id=DofObject::invalid_processor_id)=0
std::vector< SubdomainID > getSubdomainIDs(const std::vector< SubdomainName > &subdomain_names) const
Get the associated subdomainIDs for the subdomain names that are passed in.
bool operator()(const BndNode *const &lhs, const BndNode *const &rhs)
void buildNodeListFromSideList()
Calls BoundaryInfo::build_node_list_from_side_list().
FEProblemBase & feProblem() const
const std::string & getSubdomainName(SubdomainID subdomain_id) const
Return the name of a block given an id.
void setPatchUpdateStrategy(Moose::PatchUpdateType patch_update_strategy)
Set the patch size update strategy.
void buildFiniteVolumeInfo() const
Builds the face and elem info vectors that store meta-data needed for looping over and doing calculat...
std::unordered_map< SubdomainID, std::set< BoundaryID > > _neighbor_subdomain_boundary_ids
Holds a map from neighbor subomdain ids to the boundary ids that are attached to it.
const std::pair< Point, RealVectorValue > & getGeneralAxisymmetricCoordAxis(SubdomainID subdomain_id) const
Gets the general axisymmetric coordinate axis for a block.
void reinit(const Elem *elem)
Reinitialize objects (JxW, q_points, ...) for an elements.
SubdomainID getSubdomainID(const SubdomainName &subdomain_name, const MeshBase &mesh)
Gets the subdomain ID associated with the given SubdomainName.
auto max(const L &left, const R &right)
const std::set< BoundaryID > & meshBoundaryIds() const
Returns a read-only reference to the set of boundary IDs currently present in the Mesh...
std::set< SubdomainID > _lower_d_interior_blocks
Mesh blocks for interior lower-d elements in different types.
virtual Elem * queryElemPtr(const dof_id_type i)
elem_info_iterator ownedElemInfoBegin()
Iterators to owned faceInfo objects.
void setIsCustomPartitionerRequested(bool cpr)
const std::set< boundary_id_type > & get_node_boundary_ids() const
unsigned int _max_h_level
Maximum h-refinement level of all elements.
virtual bnd_node_iterator bndNodesBegin()
Return iterators to the beginning/end of the boundary nodes list.
void mapPoints(const std::vector< Point > &from, const std::vector< Point > &to, std::vector< QpMap > &qp_map)
Find the closest points that map "from" to "to" and fill up "qp_map".
BoundaryID getBoundaryID(const BoundaryName &boundary_name, const MeshBase &mesh)
Gets the boundary ID associated with the given BoundaryName.
virtual Point get_corresponding_pos(const Point &pt) const=0
void errorIfDistributedMesh(std::string name) const
Generate a unified error message if the underlying libMesh mesh is a DistributedMesh.
const MeshBase * getMeshPtr() const
void mooseWarning(Args &&... args) const
bool getDistributedMeshOnCommandLine() const
Returns true if the user specified –distributed-mesh (or –parallel-mesh, for backwards compatibilit...
This data structure is used to store geometric and variable related metadata about each cell face in ...
const std::vector< const FaceInfo * > & faceInfo() const
Accessor for local FaceInfo objects.
void updateCoordTransform()
Update the coordinate transformation object based on our coordinate system data.
bool _use_distributed_mesh
False by default.
virtual bool is_serial() const
void libmesh_ignore(const Args &...)
std::unique_ptr< std::map< BoundaryID, RealVectorValue > > _boundary_to_normal_map
The boundary to normal map - valid only when AddAllSideSetsByNormals is active.
const dof_id_type n_nodes
const std::string & name() const
Get the name of the class.
static const std::array< bool, 3 > periodic_dim_default
Default value for the automatically detected paired boundaries for each unit dimension, in which the value for each unit dimension is false (not detected).
bool _built_from_other_mesh
Whether or not this mesh was built from another mesh.
bool _allow_remote_element_removal
Whether to allow removal of remote elements.
std::unique_ptr< Moose::Kokkos::Mesh > _kokkos_mesh
Pointer to Kokkos mesh object.
virtual bool skipNoncriticalPartitioning() const
SemiLocalNodeRange * getActiveSemiLocalNodeRange() const
std::unordered_set< dof_id_type > getBoundaryActiveNeighborElemIds(BoundaryID bid) const
Return all ids of neighbors of elements which have a side which is part of a sideset.
void setSubdomainName(SubdomainID subdomain_id, const SubdomainName &name)
This method sets the name for subdomain_id to name.
virtual void delete_elem(Elem *e)=0
void clearQuadratureNodes()
Clear out any existing quadrature nodes.
MeshBase & getMesh()
Accessor for the underlying libMesh Mesh object.
void min(const T &r, T &o, Request &req) const
const std::map< SubdomainID, Moose::CoordinateSystemType > & getCoordSystem() const
Get the map from subdomain ID to coordinate system type, e.g.
static constexpr dof_id_type invalid_id
std::vector< BndNode * > _bnd_nodes
array of boundary nodes
virtual unsigned int n_nodes() const=0
Every object that can be built by the factory should be derived from this class.
virtual unsigned int dimension() const
Returns MeshBase::mesh_dimension(), (not MeshBase::spatial_dimension()!) of the underlying libMesh me...
unsigned int _from
The qp to map from.
std::pair< const Node *, BoundaryID > PeriodicNodeInfo
Helper type for building periodic node maps.
std::unique_ptr< MeshBase > buildMeshBaseObject(unsigned int dim=libMesh::invalid_uint)
Method to construct a libMesh::MeshBase object that is normally set and used by the MooseMesh object ...
unsigned int getAxisymmetricRadialCoord() const
Returns the desired radial direction for RZ coordinate transformation.
const Point & min() const
virtual Elem * add_elem(Elem *e)=0
const std::set< unsigned int > & getGhostedBoundaries() const
Return a writable reference to the set of ghosted boundary IDs.
bool _construct_node_list_from_side_list
Whether or not to allow generation of nodesets from sidesets.
boundary_id_type BoundaryID
void print_info(std::ostream &os=libMesh::out, const unsigned int verbosity=0, const bool global=true) const
const std::array< bool, 3 > & queryPeriodicDimensions(const unsigned int sys_num, const unsigned int var_num) const
Query the translated periodic dimension flags for the given variable on the given system...
SimpleRange< IndexType > as_range(const std::pair< IndexType, IndexType > &p)
unsigned int sideWithBoundaryID(const Elem *const elem, const BoundaryID boundary_id) const
Calls BoundaryInfo::side_with_boundary_id().
const std::vector< dof_id_type > & getNodeList(boundary_id_type nodeset_id) const
Return a writable reference to a vector of node IDs that belong to nodeset_id.
std::map< std::pair< unsigned int, unsigned int >, std::array< bool, 3 > > _periodic_dim
A map from (system number, vector number) to which dimensions are periodic in a regular orthogonal me...
virtual const Node * nodePtr(const dof_id_type i) const
virtual const Node * query_node_ptr(const dof_id_type i) const=0
virtual libMesh::EquationSystems & es() override
std::vector< dof_id_type > _max_ids
Maximum integer ID for each extra element integer.
virtual dof_id_type max_elem_id() const=0
MooseMesh wraps a libMesh::Mesh object and enhances its capabilities by caching additional data and s...
void family_tree(T elem, std::vector< T > &family, bool reset=true)
void update()
Calls buildNodeListFromSideList(), buildNodeList(), and buildBndElemList().
void mooseDeprecated(Args &&... args) const
const std::string & type() const
Get the type of this class.
This is a "smart" enum class intended to replace many of the shortcomings in the C++ enum type It sho...
bool isKokkosAvailable() const
Get whether Kokkos is available.
std::set< BoundaryID > _mesh_nodeset_ids
virtual bool is_remote() const
std::unique_ptr< MooseAppCoordTransform > _coord_transform
A coordinate transformation object that describes how to transform this problem's coordinate system i...
std::set< SubdomainID > getBoundaryConnectedBlocks(const BoundaryID bid) const
Get the list of subdomains associated with the given boundary.
void checkCoordinateSystems()
Performs a sanity check for every element in the mesh.
std::vector< BoundaryID > getBoundaryIDs(const libMesh::MeshBase &mesh, const std::vector< BoundaryName > &boundary_name, bool generate_unknown, const std::set< BoundaryID > &mesh_boundary_ids)
Gets the boundary IDs with their names.
std::string & subdomain_name(subdomain_id_type id)
std::map< std::pair< libMesh::ElemType, unsigned int >, std::vector< QpMap > > _elem_type_to_p_refinement_side_map
const std::set< unsigned char > & elem_dimensions() const
std::map< std::pair< libMesh::ElemType, unsigned int >, std::vector< QpMap > > _elem_type_to_p_coarsening_map
const bool _is_split
Whether or not we are using a (pre-)split mesh (automatically DistributedMesh)
void setCoordSystem(const std::vector< SubdomainName > &blocks, const MultiMooseEnum &coord_sys)
Set the coordinate system for the provided blocks to coord_sys.
std::unique_ptr< ConstElemPointerRange > _coarsened_elements
The elements that were just coarsened.
void allow_find_neighbors(bool allow)
void set_mesh_dimension(unsigned char d)
std::set< dof_id_type > getAllElemIDs(unsigned int elem_id_index) const
Return all the unique element IDs for an extra element integer with its index.
std::set< BoundaryID > _mesh_boundary_ids
A set of boundary IDs currently present in the mesh.
const Node * addUniqueNode(const Point &p, Real tol=1e-6)
Add a new node to the mesh.
std::vector< BndNode > _extra_bnd_nodes
MooseApp & _app
The MOOSE application this is associated with.
unsigned int number() const
Gets the number of this system.
bool _moose_mesh_prepared
True if prepare has been called on the mesh.
void buildRefinementMap(const Elem &elem, libMesh::QBase &qrule, libMesh::QBase &qrule_face, int parent_side, int child, int child_side)
Build the refinement map for a given element type.
The definition of the face_info_iterator struct.
unsigned int uniformRefineLevel() const
Returns the level of uniform refinement requested (zero if AMR is disabled).
std::vector< BndElement * > _bnd_elems
array of boundary elems
std::string stringify(const T &t)
conversion to string
bool _coord_system_set
Whether the coordinate system has been set.
std::vector< SubdomainName > getSubdomainNames(const std::vector< SubdomainID > &subdomain_ids) const
Get the associated subdomainNames for the subdomain ids that are passed in.
const std::vector< QpMap > & getPRefinementMap(const Elem &elem) const
Get the map describing for each volumetric quadrature point (qp) on the refined level which qp on the...
virtual dof_id_type nActiveLocalElem() const
AuxiliarySystem & getAuxiliarySystem()
const std::pair< BoundaryID, BoundaryID > * getPairedBoundaryMapping(unsigned int component) const
This function attempts to return the paired boundary ids for the given component. ...
bool hasSecondOrderElements()
check if the mesh has SECOND order elements
unsigned int getPatchSize() const
Getter for the patch_size parameter.
void buildRefinementAndCoarseningMaps(Assembly *assembly)
Create the refinement and coarsening maps necessary for projection of stateful material properties wh...
std::string getBoundaryString(const BoundaryID boundary_id) const
Return the name of the boundary given the id, if it exists.
bool _parallel_type_overridden
const std::string & get_nodeset_name(boundary_id_type id) const
Interface for objects interacting with the PerfGraph.
MeshBase::element_iterator activeLocalElementsBegin()
Calls active_local_nodes_begin/end() on the underlying libMesh mesh object.
std::vector< Node * > _node_map
Vector of all the Nodes in the mesh for determining when to add a new point.
std::map< dof_id_type, std::map< unsigned int, std::map< dof_id_type, Node * > > > _elem_to_side_to_qp_to_quadrature_nodes
Executioner * getExecutioner() const
Retrieve the Executioner for this App.
const std::vector< QpMap > & getPRefinementSideMap(const Elem &elem) const
Get the map describing for each side quadrature point (qp) on the refined level which qp on the previ...
bool _displace_node_list_by_side_list
Whether or not to displace unrelated nodesets by nodesets constructed from sidesets.
std::unordered_map< dof_id_type, ElemInfo > _elem_to_elem_info
Map connecting elems with their corresponding ElemInfo, we use the element ID as the key...
libMesh::Node * _node
pointer to the node
Node * getQuadratureNode(const Elem *elem, const unsigned short int side, const unsigned int qp)
Get a specified quadrature node.
void printInfo(std::ostream &os=libMesh::out, const unsigned int verbosity=0) const
Calls print_info() on the underlying Mesh.
std::string & sideset_name(boundary_id_type id)
virtual dof_id_type nNodes() const
Calls n_nodes/elem() on the underlying libMesh mesh object.
void renumber_node_id(boundary_id_type old_id, boundary_id_type new_id)
std::pair< T, U > ResultItem
static MooseEnum partitioning()
returns MooseMesh partitioning options so other classes can use it
std::unordered_map< dof_id_type, std::vector< dof_id_type > > & internalNodeToElemMap()
If not already created, creates a map from every node to all elements to which they are connected...
const std::set< boundary_id_type > & get_boundary_ids() const
const std::vector< std::vector< dof_id_type > > & dofIndices() const
virtual Node * add_node(Node *n)=0
virtual const Elem * elem_ptr(const dof_id_type i) const=0
void buildCoarseningMap(const Elem &elem, libMesh::QBase &qrule, libMesh::QBase &qrule_face, int input_side)
Build the coarsening map for a given element type.
virtual unsigned int n_sides() const=0
const std::vector< const Elem * > & coarsenedElementChildren(const Elem *elem) const
Get the newly removed children element ids for an element that was just coarsened.
std::unordered_map< dof_id_type, std::set< dof_id_type > > getElemIDMapping(const std::string &from_id_name, const std::string &to_id_name) const
std::map< std::pair< int, libMesh::ElemType >, std::vector< std::pair< unsigned int, QpMap > > > _elem_type_to_coarsening_map
Holds mappings for volume to volume and parent side to child side Map key:
void setBoundaryName(BoundaryID boundary_id, BoundaryName name)
This method sets the boundary name of the boundary based on the id parameter.
const Elem * neighbor_ptr(unsigned int i) const
void remove_side(const Elem *elem, const unsigned short int side)
Moose::PatchUpdateType _patch_update_strategy
The patch update strategy.
const std::unordered_map< dof_id_type, std::vector< dof_id_type > > & nodeToElemMap()
If not already created, creates a map from every node to all elements to which they are connected...
infix_ostream_iterator< T, charT, traits > & operator=(T const &item)
Physical unit management class with runtime unit string parsing, unit checking, unit conversion...
bool absolute_fuzzy_equals(const T &var1, const T2 &var2, const Real tol=TOLERANCE *TOLERANCE)
unsigned int level() const
void setCurrentSubdomainID(SubdomainID i)
set the current subdomain ID
std::set< BoundaryID > _mesh_sideset_ids
void setGeneralAxisymmetricCoordAxes(const std::vector< SubdomainName > &blocks, const std::vector< std::pair< Point, RealVectorValue >> &axes)
Sets the general coordinate axes for axisymmetric blocks.
void setBoundaryToNormalMap(std::unique_ptr< std::map< BoundaryID, RealVectorValue >> boundary_map)
Sets the mapping between BoundaryID and normal vector Is called by AddAllSideSetsByNormals.
DIE A HORRIBLE DEATH HERE typedef LIBMESH_DEFAULT_SCALAR_TYPE Real
bool _partitioner_overridden
bool detectOrthogonalDimRanges(Real tol=1e-6)
This routine determines whether the Mesh is a regular orthogonal mesh (i.e.
virtual std::unique_ptr< Elem > side_ptr(unsigned int i)=0
virtual const Elem * query_elem_ptr(const dof_id_type i) const=0
void updateActiveSemiLocalNodeRange(std::set< dof_id_type > &ghosted_elems)
Clears the "semi-local" node list and rebuilds it.
subdomain_id_type subdomain_id() const
std::map< const Elem *, std::vector< const Elem * > > _coarsened_element_children
Map of Parent elements to children elements for elements that were just coarsened.
std::set< dof_id_type > getElemIDsOnBlocks(unsigned int elem_id_index, const std::set< SubdomainID > &blks) const
Return all the unique element IDs for an extra element integer with its index on a set of subdomains...
unsigned int getBlocksMaxDimension(const std::vector< SubdomainName > &blocks) const
Returns the maximum element dimension on the given blocks.
std::unique_ptr< libMesh::MeshBase > _mesh
Pointer to underlying libMesh mesh object.
void max(const T &r, T &o, Request &req) const
libMesh::NodeRange * getActiveNodeRange()
virtual unsigned short dim() const=0
const Node * node_ptr(const unsigned int i) const
void setGhostedBoundaryInflation(const std::vector< Real > &inflation)
This sets the inflation amount for the bounding box for each partition for use in ghosting boundaries...
bool isTranslatedPeriodic(const unsigned int sys_num, const unsigned int var_num, const unsigned int component) const
Returns whether this generated mesh is periodic in the given dimension for the given variable on the ...
The definition of the elem_info_iterator struct.
Real dimensionWidth(unsigned int component) const
Returns the width of the requested dimension.
PatchUpdateType
Type of patch update strategy for modeling node-face constraints or contact.
bool is_my_variable(unsigned int var_num) const
bool _skip_deletion_repartition_after_refine
Whether or not skip remote deletion and repartition after uniform refinements.
std::set< SubdomainID > getBoundaryConnectedSecondaryBlocks(const BoundaryID bid) const
Get the list of subdomains associated with the given boundary of its secondary side.
void add_side(const dof_id_type elem, const unsigned short int side, const boundary_id_type id)
unsigned int _max_nodes_per_elem
The maximum number of nodes per element.
bool _need_delete
Whether we need to delete remote elements after init'ing the EquationSystems.
const std::string & get_sideset_name(boundary_id_type id) const
std::map< std::pair< libMesh::ElemType, unsigned int >, std::vector< QpMap > > _elem_type_to_p_refinement_map
void setAxisymmetricCoordAxis(const MooseEnum &rz_coord_axis)
For axisymmetric simulations, set the symmetry coordinate axis.
std::optional< std::vector< std::pair< BoundaryID, BoundaryID > > > _paired_boundary
A vector holding the paired boundaries for a regular orthogonal mesh.
std::set< BoundaryID > getSubdomainInterfaceBoundaryIds(const SubdomainID subdomain_id) const
Get the list of boundaries that contact the given subdomain.
std::vector< const Elem * > _refined_elements
The elements that were just refined.
IntRange< T > make_range(T beg, T end)
virtual const Node & node(const dof_id_type i) const
Various accessors (pointers/references) for Node "i".
infix_ostream_iterator< T, charT, traits > & operator++()
libMesh::BoundingBox getInflatedProcessorBoundingBox(Real inflation_multiplier=0.01) const
Get a (slightly inflated) processor bounding box.
void mooseError(Args &&... args) const
Emits an error prefixed with object name and type and optionally a file path to the top-level block p...
unsigned int mesh_dimension() const
void setMeshBase(std::unique_ptr< MeshBase > mesh_base)
Method to set the mesh_base object.
std::set< SubdomainID > getInterfaceConnectedBlocks(const BoundaryID bid) const
Get the list of subdomains contacting the given boundary.
Real minPeriodicDistance(const unsigned int sys_num, const unsigned int var_num, const Point &p, const Point &q) const
Returns the distance between two points on the mesh taking into account periodicity for the given var...
SolverSystem & getSolverSystem(unsigned int sys_num)
Get non-constant reference to a solver system.
void unset_has_boundary_id_sets()
std::vector< Real > _ghosted_boundaries_inflation
virtual SimpleRange< element_iterator > active_subdomain_set_elements_ptr_range(std::set< subdomain_id_type > ss)=0
std::vector< std::unordered_map< SubdomainID, std::set< dof_id_type > > > _block_id_mapping
Unique element integer IDs for each subdomain and each extra element integers.
IntRange< unsigned short > node_index_range() const
void findAdaptivityQpMaps(const Elem *template_elem, libMesh::QBase &qrule, libMesh::QBase &qrule_face, std::vector< std::vector< QpMap >> &refinement_map, std::vector< std::pair< unsigned int, QpMap >> &coarsen_map, int parent_side, int child, int child_side)
Given an elem type, get maps that tell us what qp's are closest to each other between a parent and it...
unsigned int _patch_size
The number of nodes to consider in the NearestNode neighborhood.
elem_info_iterator ownedElemInfoEnd()
void buildPeriodicNodeSets(std::map< BoundaryID, std::set< dof_id_type >> &periodic_node_sets, unsigned int var_number, libMesh::PeriodicBoundaries *pbs) const
This routine builds a datastructure of node ids organized by periodic boundary ids.
virtual std::unique_ptr< libMesh::PointLocatorBase > getPointLocator() const
Proxy function to get a (sub)PointLocator from either the underlying libMesh mesh (default)...
void addGhostedBoundary(BoundaryID boundary_id)
This will add the boundary ids to be ghosted to this processor.
virtual dof_id_type maxNodeId() const
Calls max_node/elem_id() on the underlying libMesh mesh object.
std::vector< NodeBCTuple > build_node_list(NodeBCTupleSortBy sort_by=NodeBCTupleSortBy::NODE_ID) const
virtual Elem * elem(const dof_id_type i)
Various accessors (pointers/references) for Elem "i".
libMesh::StoredRange< MooseMesh::const_bnd_elem_iterator, const BndElement * > * getBoundaryElementRange()
bool isParamValid(const std::string &name) const
Test if the supplied parameter is valid.
MOOSE now contains C++17 code, so give a reasonable error message stating what the user can do to add...
bool hasKokkosObjects() const
face_info_iterator ownedFaceInfoEnd()
This is a "smart" enum class intended to replace many of the shortcomings in the C++ enum type...
std::unordered_map< SubdomainID, std::pair< Point, RealVectorValue > > _subdomain_id_to_rz_coord_axis
Map of subdomain ID to general axisymmetric axis.
void paramWarning(const std::string ¶m, Args... args) const
Class used for caching additional information for elements such as the volume and centroid...
MeshBase::node_iterator localNodesEnd()
const RealVectorValue & getNormalByBoundaryID(BoundaryID id) const
Returns the normal vector associated with a given BoundaryID.
std::set< SubdomainID > _mesh_subdomains
A set of subdomain IDs currently present in the mesh.
ConstElemPointerRange * coarsenedElementRange() const
Return a range that is suitable for threaded execution over elements that were just coarsened...
static InputParameters validParams()
const Moose::PatchUpdateType & getPatchUpdateStrategy() const
Get the current patch update strategy.
bool doingPRefinement() const
Query whether the kind of adaptivity we're doing includes p-refinement.
const Point & max() const
void ghostGhostedBoundaries()
Actually do the ghosting of boundaries that need to be ghosted to this processor. ...
std::set< unsigned int > _ghosted_boundaries
MeshBase::node_iterator localNodesBegin()
Calls local_nodes_begin/end() on the underlying libMesh mesh object.
unsigned int _rz_coord_axis
Storage for RZ axis selection.
void computeFiniteVolumeCoords() const
Compute the face coordinate value for all FaceInfo and ElemInfo objects.
void buildNodeList()
Calls BoundaryInfo::build_node_list()/build_side_list() and makes separate copies of Nodes/Elems in t...
virtual dof_id_type max_node_id() const=0
std::unordered_map< SubdomainID, SubdomainData > _sub_to_data
Holds a map from subdomain ids to associated data.
std::unique_ptr< libMesh::Partitioner > _custom_partitioner
The custom partitioner.
bool isBoundaryElem(dof_id_type elem_id) const
Returns true if the requested element is in the list of boundary elements, false otherwise.
virtual dof_id_type n_elem() const=0
virtual const Node * node_ptr(const dof_id_type i) const=0
std::map< const Elem *, std::vector< const Elem * > > _coarsened_element_children
Map of Parent elements to child elements for elements that were just coarsened.
processor_id_type processor_id() const
static constexpr subdomain_id_type invalid_subdomain_id
virtual Order default_order() const=0
const std::vector< QpMap > & getPCoarseningMap(const Elem &elem) const
Get the map describing for each volumetric quadrature point (qp) on the coarse level which qp on the ...
bool isRecovering() const
Whether or not this is a "recover" calculation.
SystemBase & sys()
Get the system this variable is part of.
auto min(const L &left, const R &right)
virtual std::size_t numSolverSystems() const override
SearchParams SearchParameters
std::vector< const Elem * > _coarsened_elements
The elements that were just coarsened.
void buildPeriodicNodeMap(std::multimap< dof_id_type, dof_id_type > &periodic_node_map, unsigned int var_number, libMesh::PeriodicBoundaries *pbs) const
This routine builds a multimap of boundary ids to matching boundary ids across all periodic boundarie...
processor_id_type processor_id() const
std::string getRestartRecoverFileBase() const
The file_base for the recovery file.
virtual ElemType type() const=0
bool isParamSetByUser(const std::string &name) const
Test if the supplied parameter is set by a user, as opposed to not set or set to default.
dof_id_type node_id(const unsigned int i) const
const Point & point(const unsigned int i) const
const std::unordered_map< boundary_id_type, std::unordered_set< dof_id_type > > & getBoundariesToActiveSemiLocalElemIds() const
Returns a map of boundaries to ids of elements on the boundary.
const MeshBase::element_iterator activeLocalElementsEnd()
bool relative_fuzzy_equals(const TypeVector< Real > &rhs, Real tol=TOLERANCE) const
std::unique_ptr< libMesh::ConstNodeRange > _local_node_range
libMesh::StoredRange< MooseMesh::const_bnd_node_iterator, const BndNode * > * getBoundaryNodeRange()
void ErrorVector unsigned int
auto index_range(const T &sizable)
bool _regular_orthogonal_mesh
Boolean indicating whether this mesh was detected to be regular and orthogonal.
virtual dof_id_type n_nodes() const=0
bool prepare(const MeshBase *mesh_to_clone)
Calls prepare_for_use() if the underlying MeshBase object isn't prepared, then communicates various b...
const ElemInfo & elemInfo(const dof_id_type id) const
Accessor for the elemInfo object for a given element ID.
void setCustomPartitioner(libMesh::Partitioner *partitioner)
Setter for custom partitioner.
Real _distance
The distance between them.
SubdomainID subdomain_id() const
We return the subdomain ID of the corresponding libmesh element.
dof_id_type get_extra_integer(const unsigned int index) const
const Elem * child_ptr(unsigned int i) const
static MooseEnum elemTypes()
returns MooseMesh element type options
void meshChanged()
Declares that the MooseMesh has changed, invalidates cached data and rebuilds caches.
void buildPRefinementAndCoarseningMaps(Assembly *assembly)
BoundaryID getBoundaryID(const BoundaryName &boundary_name) const
Get the associated BoundaryID for the boundary name.
std::unordered_map< dof_id_type, std::vector< dof_id_type > > _node_to_elem_map
A map of all of the current nodes to the elements that they are connected to.
std::unique_ptr< libMesh::StoredRange< MooseMesh::const_bnd_node_iterator, const BndNode * > > _bnd_node_range
virtual dof_id_type nElem() const
libMesh::QBase *const & writeableQRuleFace()
Returns the reference to the current quadrature being used on a current face.
bool isBoundaryFullyExternalToSubdomains(BoundaryID bid, const std::set< SubdomainID > &blk_group) const
Returns whether a boundary (given by its id) is not crossing through a group of blocks, by which we mean that elements on both sides of the boundary are in those blocks.
std::unique_ptr< SemiLocalNodeRange > _active_semilocal_node_range
const std::set< SubdomainID > & meshSubdomains() const
Returns a read-only reference to the set of subdomains currently present in the Mesh.
SubdomainID getSubdomainID(const SubdomainName &subdomain_name) const
Get the associated subdomain ID for the subdomain name.
unsigned int _max_p_level
Maximum p-refinement level of all elements.
void setupFiniteVolumeMeshData() const
Sets up the additional data needed for finite volume computations.
void set_union(T &data, const unsigned int root_id) const
const RemoteElem * remote_elem
virtual unsigned int effectiveSpatialDimension() const
Returns the effective spatial dimension determined by the coordinates actually used by the mesh...