master-d36125/doxygen/mesh_8cc_source.html

 /*!
  *
  * Copyright (C) 2015 Technical University of Liberec.  All rights reserved.
  *
  * This program is free software; you can redistribute it and/or modify it under
  * the terms of the GNU General Public License version 3 as published by the
  * Free Software Foundation. (http://www.gnu.org/licenses/gpl-3.0.en.html)
  *
  * This program is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
  * FOR A PARTICULAR PURPOSE.  See the GNU General Public License for more details.
  *
  *
  * @file    mesh.cc
  * @ingroup mesh
  * @brief   Mesh construction
  */

 #include <unistd.h>
 #include <set>
 #include <unordered_map>

 #include "system/system.hh"
 #include "system/exceptions.hh"
 #include "system/index_types.hh"
 #include "input/reader_to_storage.hh"
 #include "input/input_type.hh"
 #include "input/accessors.hh"
 #include "system/sys_profiler.hh"
 #include "la/distribution.hh"

 #include "mesh/mesh.h"
 #include "mesh/bc_mesh.hh"
 #include "mesh/ref_element.hh"
 #include "mesh/region_set.hh"
 #include "mesh/range_wrapper.hh"

 // think about following dependencies
 #include "mesh/accessors.hh"
 #include "mesh/node_accessor.hh"
 #include "mesh/partitioning.hh"
 #include "mesh/neighbours.h"


 #include "mesh/bih_tree.hh"
 #include "mesh/duplicate_nodes.h"
 #include "mesh/mesh_optimizer.hh"

 #include "intersection/mixed_mesh_intersections.hh"


 //TODO: sources, concentrations, initial condition  and similarly boundary conditions should be
 // instances of a Element valued field
 // concentrations is in fact reimplemented in transport REMOVE it HERE

 // After removing non-geometrical things from mesh, this should be part of mash initializing.
 #include "mesh/region.hh"

 #define NDEF  -1

 namespace IT = Input::Type;

 const Input::Type::Selection & Mesh::get_input_intersection_variant() {
     return Input::Type::Selection("Types of search algorithm for finding intersection candidates.")
         .add_value(Mesh::BIHsearch, "BIHsearch",
             "Use BIH for finding initial candidates, then continue by prolongation.")
         .add_value(Mesh::BIHonly, "BIHonly",
             "Use BIH for finding all candidates.")
         .add_value(Mesh::BBsearch, "BBsearch",
             "Use bounding boxes for finding initial candidates, then continue by prolongation.")
         .close();
 }

 const IT::Record & Mesh::get_input_type() {
     return IT::Record("Mesh","Record with mesh related data." )
         .allow_auto_conversion("mesh_file")
         .declare_key("mesh_file", IT::FileName::input(), IT::Default::obligatory(),
                 "Input file with mesh description.")
         .declare_key("regions", IT::Array( RegionSetBase::get_input_type() ), IT::Default::optional(),
                 "List of additional region and region set definitions not contained in the mesh. "
                 "There are three region sets implicitly defined:\n\n"
                 "- ALL (all regions of the mesh)\n"
                 "- .BOUNDARY (all boundary regions)\n"
                 "- BULK (all bulk regions)")
         .declare_key("partitioning", Partitioning::get_input_type(), IT::Default("\"any_neighboring\""), "Parameters of mesh partitioning algorithms.\n" )
         .declare_key("print_regions", IT::Bool(), IT::Default("true"), "If true, print table of all used regions.")
         .declare_key("intersection_search", Mesh::get_input_intersection_variant(),
                      IT::Default("\"BIHsearch\""), "Search algorithm for element intersections.")
         .declare_key("global_snap_radius", IT::Double(0.0), IT::Default("1E-3"),
                      "Maximal snapping distance from the mesh in various search operations. In particular, it is used "
                      "to find the closest mesh element of an observe point; and in FieldFormula to find closest surface "
                      "element in plan view (Z projection).")
         .declare_key("raw_ngh_output", IT::FileName::output(), IT::Default::optional(),
                      "Output file with neighboring data from mesh.")
         .declare_key("optimize_mesh", IT::Bool(), IT::Default("true"), "If true, make optimization of nodes and elements order. "
                      "This will speed up the calculations in assembations.")
         .close();
 }

 const unsigned int Mesh::undef_idx;

 Mesh::Mesh()
 : tree(nullptr),
   bulk_size_(0),
   nodes_(3, 1, 0),
   row_4_el(nullptr),
   el_4_loc(nullptr),
   el_ds(nullptr),
   node_4_loc_(nullptr),
   node_ds_(nullptr),
   bc_mesh_(nullptr)

 {}


 Mesh::Mesh(Input::Record in_record, MPI_Comm com)
 : tree(nullptr),
   in_record_(in_record),
   comm_(com),
   bulk_size_(0),
   nodes_(3, 1, 0),
   row_4_el(nullptr),
   el_4_loc(nullptr),
   el_ds(nullptr),
   node_4_loc_(nullptr),
   node_ds_(nullptr),
   bc_mesh_(nullptr)
 {
     // set in_record_, if input accessor is empty
     if (in_record_.is_empty()) {
         istringstream is("{mesh_file=\"\"}");
         Input::ReaderToStorage reader;
         IT::Record &in_rec = const_cast<IT::Record &>(Mesh::get_input_type());
         in_rec.finish();
         reader.read_stream(is, in_rec, Input::FileFormat::format_JSON);
         in_record_ = reader.get_root_interface<Input::Record>();
     }

         int rank;
         MPI_Comm_rank(MPI_COMM_WORLD, &rank);
         if (rank == 0) {
             // optionally open raw output file
             FilePath raw_output_file_path;
             if (in_record_.opt_val("raw_ngh_output", raw_output_file_path)) {
                 MessageOut() << "Opening raw ngh output: " << raw_output_file_path << "\n";
                 try {
                     raw_output_file_path.open_stream(raw_ngh_output_file);
                 } INPUT_CATCH(FilePath::ExcFileOpen, FilePath::EI_Address_String, (in_record_))
             }

         }
     init();
 }

 Mesh::IntersectionSearch Mesh::get_intersection_search()
 {
     return in_record_.val<Mesh::IntersectionSearch>("intersection_search");
 }


 void Mesh::init()
 {

     n_insides = NDEF;
     n_exsides = NDEF;
     n_sides_ = NDEF;

     // number of element of particular dimension
     n_lines = 0;
     n_triangles = 0;
     n_tetrahedras = 0;

     for (int d=0; d<3; d++) max_edge_sides_[d] = 0;

     // Initialize numbering of nodes on sides.
     // This is temporary solution, until class Element is templated
     // by dimension. Then we can replace Mesh::side_nodes by
     // RefElement<dim>::side_nodes.

     // indices of side nodes in element node array
     // Currently this is made ad libitum
     // with some ordering here we can get sides with correct orientation.
     // This speedup normal calculation.

     side_nodes.resize(3); // three side dimensions
     for(int dim=0; dim < 3; dim++) {
         side_nodes[dim].resize(dim+2); // number of sides
         for(int i_side=0; i_side < dim+2; i_side++)
             side_nodes[dim][i_side].resize(dim+1);
     }

     for (unsigned int sid=0; sid<RefElement<1>::n_sides; sid++)
         for (unsigned int nid=0; nid<RefElement<1>::n_nodes_per_side; nid++)
             side_nodes[0][sid][nid] = RefElement<1>::interact(Interaction<0,0>(sid))[nid];

     for (unsigned int sid=0; sid<RefElement<2>::n_sides; sid++)
             for (unsigned int nid=0; nid<RefElement<2>::n_nodes_per_side; nid++)
                 side_nodes[1][sid][nid] = RefElement<2>::interact(Interaction<0,1>(sid))[nid];

     for (unsigned int sid=0; sid<RefElement<3>::n_sides; sid++)
             for (unsigned int nid=0; nid<RefElement<3>::n_nodes_per_side; nid++)
                 side_nodes[2][sid][nid] = RefElement<3>::interact(Interaction<0,2>(sid))[nid];
 }


 Mesh::~Mesh() {
     for(EdgeData &edg : this->edges)
         if (edg.side_) delete[] edg.side_;

     for (unsigned int idx=0; idx < bulk_size_; idx++) {
         Element *ele=&(element_vec_[idx]);
         if (ele->boundary_idx_) delete[] ele->boundary_idx_;
         if (ele->neigh_vb) delete[] ele->neigh_vb;
     }

     for(unsigned int idx=bulk_size_; idx < element_vec_.size(); idx++) {
         Element *ele=&(element_vec_[idx]);
         if (ele->boundary_idx_) delete[] ele->boundary_idx_;
     }

     if (row_4_el != nullptr) delete[] row_4_el;
     if (el_4_loc != nullptr) delete[] el_4_loc;
     if (el_ds != nullptr) delete el_ds;
     if (node_4_loc_ != nullptr) delete[] node_4_loc_;
     if (node_ds_ != nullptr) delete node_ds_;
     if (bc_mesh_ != nullptr) delete bc_mesh_;
     if (tree != nullptr) delete tree;
 }


 unsigned int Mesh::n_sides() const
 {
     if (n_sides_ == NDEF) {
         n_sides_=0;
         for (auto ele : this->elements_range()) n_sides_ += ele->n_sides();
     }
     return n_sides_;
 }

 unsigned int Mesh::n_vb_neighbours() const {
      return vb_neighbours_.size();
  }


 unsigned int Mesh::n_corners() {
     unsigned int li, count = 0;
     for (auto ele : this->elements_range()) {
         for (li=0; li<ele->n_nodes(); li++) {
             count++;
         }
     }
     return count;
 }

 Edge Mesh::edge(uint edge_idx) const
 {
     ASSERT_LT_DBG(edge_idx, edges.size());
     return Edge(this, edge_idx);
 }

 Boundary Mesh::boundary(uint bc_idx) const
 {
     ASSERT_LT_DBG(bc_idx, boundary_.size());
     return Boundary(&boundary_[bc_idx]);
 }

 Partitioning *Mesh::get_part() {
     return part_.get();
 }

 const LongIdx *Mesh::get_local_part() {
     return (LongIdx*)this->get_part()->get_loc_part();
 }


 //=============================================================================
 // COUNT ELEMENT TYPES
 //=============================================================================

 void Mesh::count_element_types() {
     for (auto elm : this->elements_range())
     switch (elm->dim()) {
         case 1:
             n_lines++;
             break;
         case 2:
             n_triangles++;
             break;
         case 3:
             n_tetrahedras++;
             break;
         }
 }


 void Mesh::modify_element_ids(const RegionDB::MapElementIDToRegionID &map) {

     // get dim of the first element in the map, if it exists
     uint dim_to_check = RegionDB::undefined_dim;
     std::string reg_name = "UndefinedRegion";
     if(map.size() > 0){
         Element &ele = element_vec_[ elem_index(map.begin()->first) ];
         dim_to_check = ele.dim();
         reg_name = region_db_.find_id(map.begin()->second).label();
     }

     for (auto elem_to_region : map) {
         Element &ele = element_vec_[ elem_index(elem_to_region.first) ];

         if( ele.dim() != dim_to_check){
             THROW(ExcRegionElmDiffDim() << EI_Region(reg_name) << EI_RegIdx(elem_to_region.second) << EI_Dim(dim_to_check)
                     << EI_DimOther(ele.dim()) << EI_ElemId(elem_to_region.first) );
         }

         ele.region_idx_ = region_db_.get_region( elem_to_region.second, ele.dim() );
         region_db_.mark_used_region(ele.region_idx_.idx());
     }
 }


 void Mesh::check_mesh_on_read() {
     std::vector<uint> nodes_new_idx( this->n_nodes(), Mesh::undef_idx );

     // check element quality and flag used nodes
     for (auto ele : this->elements_range()) {
         // element quality
         double quality = ele.quality_measure_smooth();
         if ( quality< 0.001)
             WarningOut().fmt("Bad quality (<0.001) of the element {}.\n", ele.idx());

         // flag used nodes
         for (uint ele_node=0; ele_node<ele->n_nodes(); ele_node++) {
             uint inode = ele->node_idx(ele_node);
             nodes_new_idx[inode] = inode;
         }
     }

     // possibly build new node ids map
     BidirectionalMap<int> new_node_ids_;
     new_node_ids_.reserve(node_ids_.size());

     // remove unused nodes from the mesh
     uint inode_new = 0;
     for(uint inode = 0; inode < nodes_new_idx.size(); inode++) {
         if(nodes_new_idx[inode] == Mesh::undef_idx){
             WarningOut().fmt("A node {} does not belong to any element "
                          " and will be removed.",
                          find_node_id(inode));
         }
         else{
             // map new node numbering
             nodes_new_idx[inode] = inode_new;

             // possibly move the nodes
             nodes_.vec<3>(inode_new) = nodes_.vec<3>(inode);
             new_node_ids_.add_item(node_ids_[inode]);

             inode_new++;
         }
     }

     uint n_nodes_new = inode_new;

     // if some node erased, update node ids in elements
     if(n_nodes_new < nodes_new_idx.size()){

         DebugOut() << "Updating node-element numbering due to unused nodes: "
             << print_var(n_nodes_new) << print_var(nodes_new_idx.size()) << "\n";

         // throw away unused nodes
         nodes_.resize(n_nodes_new);
         node_ids_ = new_node_ids_;

         // update node-element numbering
         for (auto ele : this->elements_range()) {
             for (uint ele_node=0; ele_node<ele->n_nodes(); ele_node++) {
                 uint inode_orig = ele->node_idx(ele_node);
                 uint inode = nodes_new_idx[inode_orig];
                 ASSERT_DBG(inode != Mesh::undef_idx);
                 const_cast<Element*>(ele.element())->nodes_[ele_node] = inode;
             }
         }
     }
 }

 void Mesh::setup_topology() {
     if ( in_record_.val<bool>("optimize_mesh") ) {
         START_TIMER("MESH - optimizer");
         this->optimize();
         END_TIMER("MESH - optimizer");
     }

     START_TIMER("MESH - setup topology");

     count_element_types();
     check_mesh_on_read();

     make_neighbours_and_edges();
     element_to_neigh_vb();
     make_edge_permutations();
     count_side_types();

     tree = new DuplicateNodes(this);

     part_ = std::make_shared<Partitioning>(this, in_record_.val<Input::Record>("partitioning") );

     // create parallel distribution and numbering of elements
     LongIdx *id_4_old = new LongIdx[n_elements()];
     int i = 0;
     for (auto ele : this->elements_range())
         id_4_old[i++] = ele.idx();
     part_->id_maps(n_elements(), id_4_old, el_ds, el_4_loc, row_4_el);

     delete[] id_4_old;

     this->distribute_nodes();

     output_internal_ngh_data();
 }


 void Mesh::optimize() {
     MeshOptimizer<3> mo(this);
     mo.calculate_sizes();
     mo.calculate_node_curve_values_as_hilbert();
     mo.calculate_element_curve_values_as_hilbert_of_centers();

     this->sort_permuted_nodes_elements( mo.sort_nodes(this->node_permutation_), mo.sort_elements(this->elem_permutation_) );
 }


 void Mesh::sort_permuted_nodes_elements(std::vector<int> new_node_ids, std::vector<int> new_elem_ids) {
     BidirectionalMap<int> node_ids_backup = this->node_ids_;
     this->node_ids_.clear();
     this->node_ids_.reserve(this->n_nodes());
     Armor::Array<double> nodes_backup = this->nodes_;
     for (uint i = 0; i < this->element_vec_.size(); ++i) {
         for (uint j = 0; j < this->element_vec_[i].dim() + 1; ++j) {
             this->element_vec_[i].nodes_[j] = this->node_permutation_[this->element_vec_[i].nodes_[j]];
         }
     }
     for (uint i = 0; i < this->n_nodes(); ++i) {
         this->nodes_.set(node_permutation_[i]) = nodes_backup.vec<3>(i);
         this->node_ids_.add_item( node_ids_backup[new_node_ids[i]] );
     }

     BidirectionalMap<int> elem_ids_backup = this->element_ids_;
     this->element_ids_.clear();
     this->element_ids_.reserve(bulk_size_);
     std::vector<Element> elements_backup = this->element_vec_;
     for (uint i = 0; i < bulk_size_; ++i) {
         this->element_vec_[elem_permutation_[i]] = elements_backup[i];
         this->element_ids_.add_item( elem_ids_backup[new_elem_ids[i]] );
     }
 }


 //
 void Mesh::count_side_types()
 {

     n_insides = 0;
     n_exsides = 0;
     for (auto ele : this->elements_range())
         for(SideIter sde = ele.side(0); sde->side_idx() < ele->n_sides(); ++sde) {
             if (sde->is_external()) n_exsides++;
             else n_insides++;
         }
 }


 void Mesh::create_node_element_lists() {
     // for each node we make a list of elements that use this node
     node_elements_.resize( this->n_nodes() );

     for (auto ele : this->elements_range())
         for (unsigned int n=0; n<ele->n_nodes(); n++)
             node_elements_[ele.node(n).idx()].push_back(ele.idx());

     for (vector<vector<unsigned int> >::iterator n=node_elements_.begin(); n!=node_elements_.end(); n++)
         stable_sort(n->begin(), n->end());
 }


 void Mesh::intersect_element_lists(vector<unsigned int> const &nodes_list, vector<unsigned int> &intersection_element_list)
 {
     if (node_elements_.size() == 0) {
         this->create_node_element_lists();
     }

     if (nodes_list.size() == 0) {
         intersection_element_list.clear();
     } else if (nodes_list.size() == 1) {
         intersection_element_list = node_elements_[ nodes_list[0] ];
     } else {
         vector<unsigned int>::const_iterator it1=nodes_list.begin();
         vector<unsigned int>::const_iterator it2=it1+1;
         intersection_element_list.resize( node_elements_[*it1].size() ); // make enough space

         it1=set_intersection(
                 node_elements_[*it1].begin(), node_elements_[*it1].end(),
                 node_elements_[*it2].begin(), node_elements_[*it2].end(),
                 intersection_element_list.begin());
         intersection_element_list.resize(it1-intersection_element_list.begin()); // resize to true size

         for(;it2<nodes_list.end();++it2) {
             it1=set_intersection(
                     intersection_element_list.begin(), intersection_element_list.end(),
                     node_elements_[*it2].begin(), node_elements_[*it2].end(),
                     intersection_element_list.begin());
             intersection_element_list.resize(it1-intersection_element_list.begin()); // resize to true size
         }
     }
 }


 bool Mesh::find_lower_dim_element( vector<unsigned int> &element_list, unsigned int dim, unsigned int &element_idx) {
     bool is_neighbour = false;

     vector<unsigned int>::iterator e_dest=element_list.begin();
     for( vector<unsigned int>::iterator ele = element_list.begin(); ele!=element_list.end(); ++ele) {
         if (element_vec_[*ele].dim() == dim) { // keep only indexes of elements of same dimension
             *e_dest=*ele;
             ++e_dest;
         } else if (element_vec_[*ele].dim() == dim-1) { // get only first element of lower dimension
             if (is_neighbour) THROW(ExcTooMatchingIds() << EI_ElemId(this->elem_index(*ele)) << EI_ElemIdOther(this->elem_index(element_idx)) );

             is_neighbour = true;
             element_idx = *ele;
         }
     }
     element_list.resize( e_dest - element_list.begin());
     return is_neighbour;
 }

 bool Mesh::same_sides(const SideIter &si, vector<unsigned int> &side_nodes) {
     // check if nodes lists match (this is slow and will be faster only when we convert whole mesh into hierarchical design like in deal.ii)
     unsigned int ni=0;
     while ( ni < si->n_nodes()
         && find(side_nodes.begin(), side_nodes.end(), si->node(ni).idx() ) != side_nodes.end() ) ni++;
     return ( ni == si->n_nodes() );
 }

 /**
  * TODO:
  * - use std::is_any for setting is_neigbour
  * - possibly make appropriate constructors for Edge and Neighbour
  * - check side!=-1 when searching neigbouring element
  * - process boundary elements first, there should be no Neigh, but check it
  *   set Edge and boundary there
  */

 void Mesh::make_neighbours_and_edges()
 {
     ASSERT(bc_element_tmp_.size()==0)
             .error("Temporary structure of boundary element data is not empty. Did you call create_boundary_elements?");

     Neighbour neighbour;
     EdgeData *edg = nullptr;
     unsigned int ngh_element_idx;
     unsigned int last_edge_idx = Mesh::undef_idx;

     neighbour.mesh_ = this;

     create_node_element_lists();

     // pointers to created edges
     //vector<Edge *> tmp_edges;
     edges.resize(0); // be sure that edges are empty

     vector<unsigned int> side_nodes;
     vector<unsigned int> intersection_list; // list of elements in intersection of node element lists

     for( unsigned int i=bulk_size_; i<element_vec_.size(); ++i) {

         ElementAccessor<3> bc_ele = this->element_accessor(i);
         ASSERT(bc_ele.region().is_boundary());
         // Find all elements that share this side.
         side_nodes.resize(bc_ele->n_nodes());
         for (unsigned n=0; n<bc_ele->n_nodes(); n++) side_nodes[n] = bc_ele->node_idx(n);
         intersect_element_lists(side_nodes, intersection_list);
         bool is_neighbour = find_lower_dim_element(intersection_list, bc_ele->dim() +1, ngh_element_idx);
         if (is_neighbour) {
             THROW( ExcBdrElemMatchRegular() << EI_ElemId(bc_ele.idx()) << EI_ElemIdOther(this->elem_index(ngh_element_idx)) );
         } else {
             if (intersection_list.size() == 0) {
                 // no matching dim+1 element found
                 WarningOut().fmt("Lonely boundary element, id: {}, region: {}, dimension {}.\n",
                         bc_ele.idx(), bc_ele.region().id(), bc_ele->dim());
                 continue; // skip the boundary element
             }
             last_edge_idx=edges.size();
             edges.resize(last_edge_idx+1);
             edg = &( edges.back() );
             edg->n_sides = 0;
             edg->side_ = new struct SideIter[ intersection_list.size() ];

             // common boundary object
             unsigned int bdr_idx=boundary_.size();
             boundary_.resize(bdr_idx+1);
             BoundaryData &bdr=boundary_.back();
             bdr.bc_ele_idx_ = i;
             bdr.edge_idx_ = last_edge_idx;
             bdr.mesh_=this;

             // for 1d boundaries there can be more then one 1d elements connected to the boundary element
             // we do not detect this case later in the main search over bulk elements
             for( vector<unsigned int>::iterator isect = intersection_list.begin(); isect!=intersection_list.end(); ++isect)  {
                 ElementAccessor<3> elem = this->element_accessor(*isect);
                 for (unsigned int ecs=0; ecs<elem->n_sides(); ecs++) {
                     SideIter si = elem.side(ecs);
                     if ( same_sides( si, side_nodes) ) {
                         if (elem->edge_idx(ecs) != Mesh::undef_idx) {
                             OLD_ASSERT(elem->boundary_idx_!=nullptr, "Null boundary idx array.\n");
                             int last_bc_ele_idx=this->boundary_[elem->boundary_idx_[ecs]].bc_ele_idx_;
                             int new_bc_ele_idx=i;
                             THROW( ExcDuplicateBoundary()
                                     << EI_ElemLast(this->find_elem_id(last_bc_ele_idx))
                                     << EI_RegLast(this->element_accessor(last_bc_ele_idx).region().label())
                                     << EI_ElemNew(this->find_elem_id(new_bc_ele_idx))
                                     << EI_RegNew(this->element_accessor(new_bc_ele_idx).region().label())
                                     );
                         }
                         element_vec_[*isect].edge_idx_[ecs] = last_edge_idx;
                         edg->side_[ edg->n_sides++ ] = si;

                         if (elem->boundary_idx_ == NULL) {
                             Element *el = &(element_vec_[*isect]);
                             el->boundary_idx_ = new unsigned int [ el->n_sides() ];
                             std::fill( el->boundary_idx_, el->boundary_idx_ + el->n_sides(), Mesh::undef_idx);
                         }
                         elem->boundary_idx_[ecs] = bdr_idx;
                         break; // next element in intersection list
                     }
                 }
             }

         }

     }
     // Now we go through all element sides and create edges and neighbours
     unsigned int new_bc_elem_idx = element_vec_.size();  //Mesh_idx of new boundary element generated in following block
     for (auto e : this->elements_range()) {
         for (unsigned int s=0; s<e->n_sides(); s++)
         {
             // skip sides that were already found
             if (e->edge_idx(s) != Mesh::undef_idx) continue;


             // Find all elements that share this side.
             side_nodes.resize(e.side(s)->n_nodes());
             for (unsigned n=0; n<e.side(s)->n_nodes(); n++) side_nodes[n] = e.side(s)->node(n).idx();
             intersect_element_lists(side_nodes, intersection_list);

             bool is_neighbour = find_lower_dim_element(intersection_list, e->dim(), ngh_element_idx);

             if (is_neighbour) { // edge connects elements of different dimensions
                 // Initialize for the neighbour case.
                 neighbour.elem_idx_ = ngh_element_idx;
             } else { // edge connects only elements of the same dimension
                 // Initialize for the edge case.
                 last_edge_idx=edges.size();
                 edges.resize(last_edge_idx+1);
                 edg = &( edges.back() );
                 edg->n_sides = 0;
                 edg->side_ = new struct SideIter[ intersection_list.size() ];
                 if (intersection_list.size() > max_edge_sides_[e->dim()-1])
                     max_edge_sides_[e->dim()-1] = intersection_list.size();

                 if (intersection_list.size() == 1) {
                     // outer edge, create boundary object as well
                     Element &elm = element_vec_[e.idx()];
                     edg->n_sides=1;
                     edg->side_[0] = e.side(s);
                     element_vec_[e.idx()].edge_idx_[s] = last_edge_idx;

                     if (e->boundary_idx_ == NULL) {
                         elm.boundary_idx_ = new unsigned int [ e->n_sides() ];
                         std::fill( elm.boundary_idx_, elm.boundary_idx_ + e->n_sides(), Mesh::undef_idx);
                     }

                     unsigned int bdr_idx=boundary_.size()+1; // need for VTK mesh that has no boundary elements
                                                              // and bulk elements are indexed from 0
                     boundary_.resize(bdr_idx+1);
                     BoundaryData &bdr=boundary_.back();
                     elm.boundary_idx_[s] = bdr_idx;

                     // fill boundary element
                     Element * bc_ele = add_element_to_vector(-bdr_idx);
                     bc_ele->init(e->dim()-1, region_db_.implicit_boundary_region() );
                     region_db_.mark_used_region( bc_ele->region_idx_.idx() );
                     for(unsigned int ni = 0; ni< side_nodes.size(); ni++) bc_ele->nodes_[ni] = side_nodes[ni];

                     // fill Boundary object
                     bdr.edge_idx_ = last_edge_idx;
                     bdr.bc_ele_idx_ = new_bc_elem_idx; //elem_index(-bdr_idx);
                     bdr.mesh_=this;
                     new_bc_elem_idx++;

                     continue; // next side of element e
                 }
             }

             // go through the elements connected to the edge or neighbour
             // setup neigbour or edge
             for( vector<unsigned int>::iterator isect = intersection_list.begin(); isect!=intersection_list.end(); ++isect) {
                 ElementAccessor<3> elem = this->element_accessor(*isect);
                 for (unsigned int ecs=0; ecs<elem->n_sides(); ecs++) {
                     if (elem->edge_idx(ecs) != Mesh::undef_idx) continue; // ??? This should not happen.
                     SideIter si = elem.side(ecs);
                     if ( same_sides( si, side_nodes) ) {
                         if (is_neighbour) {
                             // create a new edge and neighbour for this side, and element to the edge
                             last_edge_idx=edges.size();
                             edges.resize(last_edge_idx+1);
                             edg = &( edges.back() );
                             edg->n_sides = 1;
                             edg->side_ = new struct SideIter[1];
                             edg->side_[0] = si;
                             element_vec_[elem.idx()].edge_idx_[ecs] = last_edge_idx;

                             neighbour.edge_idx_ = last_edge_idx;

                             vb_neighbours_.push_back(neighbour); // copy neighbour with this edge setting
                         } else {
                             // connect the side to the edge, and side to the edge
                             ASSERT_PTR_DBG(edg);
                             edg->side_[ edg->n_sides++ ] = si;
                             ASSERT_DBG(last_edge_idx != Mesh::undef_idx);
                             element_vec_[elem.idx()].edge_idx_[ecs] = last_edge_idx;
                         }
                         break; // next element from intersection list
                     }
                 } // search for side of other connected element
             } // connected elements

             if (! is_neighbour)
                 ASSERT_EQ( (unsigned int) edg->n_sides, intersection_list.size())(e.index())(s).error("Missing edge sides.");
         } // for element sides
     }   // for elements

     MessageOut().fmt( "Created {} edges and {} neighbours.\n", edges.size(), vb_neighbours_.size() );
 }


 void Mesh::make_edge_permutations()
 {
     // node numbers is the local index of the node on the last side
     // this maps the side nodes to the nodes of the reference side(0)
     std::unordered_map<unsigned int,unsigned int> node_numbers;

     for (auto edg : edge_range())
     {
         unsigned int n_side_nodes = edg.side(0)->n_nodes();
         // side 0 is reference, so its permutation is 0
         edg.side(0)->element()->permutation_idx_[edg.side(0)->side_idx()] = 0;

         if (edg.n_sides() > 1)
         {
             // For every node on the reference side(0) give its local idx on the current side.
             unsigned int permutation[n_side_nodes];


             node_numbers.clear();
             for (uint i=0; i<n_side_nodes; i++)
                 node_numbers[edg.side(0)->node(i).idx()] = i;

             for (uint sid=1; sid<edg.n_sides(); sid++)
             {
                 for (uint i=0; i<n_side_nodes; i++)
                     permutation[node_numbers[edg.side(sid)->node(i).idx()]] = i;

                 switch (edg.side(0)->dim())
                 {
                 case 0:
                     edg.side(sid)->element()->permutation_idx_[edg.side(sid)->side_idx()] = RefElement<1>::permutation_index(permutation);
                     break;
                 case 1:
                     edg.side(sid)->element()->permutation_idx_[edg.side(sid)->side_idx()] = RefElement<2>::permutation_index(permutation);
                     break;
                 case 2:
                     edg.side(sid)->element()->permutation_idx_[edg.side(sid)->side_idx()] = RefElement<3>::permutation_index(permutation);
                     break;
                 }
             }
         }
     }

     for (vector<Neighbour>::iterator nb=vb_neighbours_.begin(); nb!=vb_neighbours_.end(); nb++)
     {
         // node numbers is the local index of the node on the last side
         // this maps the side nodes to the nodes of the side(0)
         unsigned int n_side_nodes = nb->element()->n_nodes();
         unsigned int permutation[n_side_nodes];
         node_numbers.clear();

         // element of lower dimension is reference, so
         // we calculate permutation for the adjacent side
         for (unsigned int i=0; i<n_side_nodes; i++)
             node_numbers[nb->element().node(i).idx()] = i;

         for (unsigned int i=0; i<n_side_nodes; i++)
             permutation[node_numbers[nb->side()->node(i).idx()]] = i;

         switch (nb->side()->dim())
         {
         case 0:
             nb->side()->element()->permutation_idx_[nb->side()->side_idx()] = RefElement<1>::permutation_index(permutation);
             break;
         case 1:
             nb->side()->element()->permutation_idx_[nb->side()->side_idx()] = RefElement<2>::permutation_index(permutation);
             break;
         case 2:
             nb->side()->element()->permutation_idx_[nb->side()->side_idx()] = RefElement<3>::permutation_index(permutation);
             break;
         }
     }

     for (vector<BoundaryData>::iterator bdr=boundary_.begin(); bdr!=boundary_.end(); bdr++)
     {
         if (bdr->bc_ele_idx_ >= element_vec_.size()) continue; // skip invalid boundary item
         Edge edg = this->edge(bdr->edge_idx_);
         ElementAccessor<3> bdr_elm = this->element_accessor(bdr->bc_ele_idx_);

         // node numbers is the local index of the node on the last side
         // this maps the side nodes to the nodes of the side(0)
         unsigned int n_side_nodes = bdr_elm->n_nodes();
         unsigned int permutation[n_side_nodes];
         node_numbers.clear();

         // boundary element (lower dim) is reference, so
         // we calculate permutation for the adjacent side
         for (unsigned int i=0; i<n_side_nodes; i++) {
             node_numbers[bdr_elm.node(i).idx()] = i;
         }

         for (uint sid=0; sid<edg.n_sides(); sid++)
         {
             for (uint i=0; i<n_side_nodes; i++) {
                 permutation[node_numbers[edg.side(sid)->node(i).idx()]] = i;
             }

             switch (bdr_elm.dim())
             {
             case 0:
                 edg.side(sid)->element()->permutation_idx_[edg.side(sid)->side_idx()] = RefElement<1>::permutation_index(permutation);
                 break;
             case 1:
                 edg.side(sid)->element()->permutation_idx_[edg.side(sid)->side_idx()] = RefElement<2>::permutation_index(permutation);
                 break;
             case 2:
                 edg.side(sid)->element()->permutation_idx_[edg.side(sid)->side_idx()] = RefElement<3>::permutation_index(permutation);
                 break;
             }
         }
     }
 }


 //=============================================================================
 //
 //=============================================================================
 void Mesh::element_to_neigh_vb()
 {

     //MessageOut() << "Element to neighbours of vb2 type... "/*orig verb 5*/;

     for (vector<Element>::iterator ele = element_vec_.begin(); ele!= element_vec_.begin()+bulk_size_; ++ele)
         ele->n_neighs_vb_ =0;

     // count vb neighs per element
     for (auto & ngh : this->vb_neighbours_)  ngh.element()->n_neighs_vb_++;

     // Allocation of the array per element
     for (vector<Element>::iterator ele = element_vec_.begin(); ele!= element_vec_.begin()+bulk_size_; ++ele)
         if( ele->n_neighs_vb() > 0 ) {
             ele->neigh_vb = new struct Neighbour* [ele->n_neighs_vb()];
             ele->n_neighs_vb_=0;
         }

     // fill
     ElementAccessor<3> ele;
     for (auto & ngh : this->vb_neighbours_) {
         ele = ngh.element();
         ele->neigh_vb[ ele->n_neighs_vb_++ ] = &ngh;
     }

     //MessageOut() << "... O.K.\n"/*orig verb 6*/;
 }


 MixedMeshIntersections & Mesh::mixed_intersections() {
     /* Algorithm:
      *
      * 1) create BIH tree
      * 2) for every 1D, find list of candidates
      * 3) compute intersections for 1d, store it to master_elements
      *
      */
     if (! intersections) {
         intersections = std::make_shared<MixedMeshIntersections>(this);
         intersections->compute_intersections();
     }
     return *intersections;
 }


 ElementAccessor<3> Mesh::element_accessor(unsigned int idx) const {
     return ElementAccessor<3>(this, idx);
 }


 NodeAccessor<3> Mesh::node(unsigned int idx) const {
     return NodeAccessor<3>(this, idx);
 }


 void Mesh::elements_id_maps( vector<LongIdx> & bulk_elements_id, vector<LongIdx> & boundary_elements_id) const
 {
     if (bulk_elements_id.size() ==0) {
         std::vector<LongIdx>::iterator map_it;
         LongIdx last_id;

         bulk_elements_id.resize(n_elements());
         map_it = bulk_elements_id.begin();
         last_id = -1;
         for(unsigned int idx=0; idx < n_elements(); idx++, ++map_it) {
             LongIdx id = this->find_elem_id(idx);
             last_id=*map_it = id;
         }
         std::sort(bulk_elements_id.begin(), bulk_elements_id.end());

         boundary_elements_id.resize(element_ids_.size()-bulk_size_);
         map_it = boundary_elements_id.begin();
         last_id = -1;
         for(unsigned int idx=bulk_size_; idx<element_ids_.size(); idx++, ++map_it) {
             LongIdx id = this->find_elem_id(idx);
             // We set ID for boundary elements created by the mesh itself to "-1"
             // this force gmsh reader to skip all remaining entries in boundary_elements_id
             // and thus report error for any remaining data lines
             if (id < 0) last_id=*map_it=-1;
             else {
                 if (last_id >= id) THROW( ExcElmWrongOrder() << EI_ElemId(id) );
                 last_id=*map_it = id;
             }
         }
     }
 }


 bool compare_points(const arma::vec3 &p1, const arma::vec3 &p2) {
     static const double point_tolerance = 1E-10;
     return fabs(p1[0]-p2[0]) < point_tolerance
         && fabs(p1[1]-p2[1]) < point_tolerance
         && fabs(p1[2]-p2[2]) < point_tolerance;
 }


 std::shared_ptr<std::vector<LongIdx>> Mesh::check_compatible_mesh( Mesh & input_mesh)
 {
     std::vector<unsigned int> node_ids; // allow mapping ids of nodes from source mesh to target mesh
     std::vector<unsigned int> node_list;
     std::vector<unsigned int> candidate_list; // returned by intersect_element_lists
     std::vector<unsigned int> result_list; // list of elements with same dimension as vtk element
     unsigned int i; // counter over vectors
     std::shared_ptr<std::vector<LongIdx>> map_ptr = std::make_shared<std::vector<LongIdx>>(element_vec_.size());
     std::vector<LongIdx> &element_ids_map = *(map_ptr.get());

     {
         // iterates over node vector of \p this object
         // to each node must be found just only one node in target \p mesh
         // store orders (mapping between source and target meshes) into node_ids vector
         std::vector<unsigned int> searched_elements; // for BIH tree
         unsigned int i_node, i_elm_node;
         const BIHTree &bih_tree=this->get_bih_tree();

         // create nodes of mesh
         node_ids.resize( this->n_nodes(), Mesh::undef_idx );
         i=0;
         for (auto nod : input_mesh.node_range()) {
             uint found_i_node = Mesh::undef_idx;
             bih_tree.find_point(*nod, searched_elements);

             for (std::vector<unsigned int>::iterator it = searched_elements.begin(); it!=searched_elements.end(); it++) {
                 ElementAccessor<3> ele = this->element_accessor( *it );
                 for (i_node=0; i_node<ele->n_nodes(); i_node++)
                 {
                     static const double point_tolerance = 1E-10;
                     if ( arma::norm(*ele.node(i_node) - *nod, 1) < point_tolerance) {
                         i_elm_node = ele.node(i_node).idx();
                         if (found_i_node == Mesh::undef_idx) found_i_node = i_elm_node;
                         else if (found_i_node != i_elm_node) {
                             // duplicate nodes in target mesh - not compatible
                             return std::make_shared<std::vector<LongIdx>>(0);
                         }
                     }
                 }
             }
             if (found_i_node!=Mesh::undef_idx) node_ids[found_i_node] = i;
             searched_elements.clear();
             i++;
         }
     }
     {
         // iterates over bulk elements of \p this object
         // elements in both meshes must be in ratio 1:1
         // store orders (mapping between both mesh files) into bulk_elements_id vector
         // iterate trough bulk part of element vector, to each element in source mesh must exist only one element in target mesh
         i=0;
         unsigned int n_found=0; // number of found equivalent elements
         bool valid_nodes;
         for (auto elm : this->elements_range()) {
             valid_nodes = true;
             for (unsigned int j=0; j<elm->n_nodes(); j++) { // iterate trough all nodes of any element
                 if (node_ids[ elm->node_idx(j) ] == Mesh::undef_idx) valid_nodes = false;
                 node_list.push_back( node_ids[ elm->node_idx(j) ] );
             }
             if (valid_nodes) {
                 input_mesh.intersect_element_lists(node_list, candidate_list);
                 for (auto i_elm : candidate_list) {
                     if ( input_mesh.element_accessor(i_elm)->dim() == elm.dim() ) result_list.push_back(i_elm);
                 }
             }
             if (result_list.size() == 1) {
                 element_ids_map[i] = (LongIdx)result_list[0];
                 n_found++;
             } else {
                 element_ids_map[i] = (LongIdx)Mesh::undef_idx;
             }
             node_list.clear();
             result_list.clear();
             i++;
         }

         if (n_found==0) {
             // no equivalent bulk element found - mesh is not compatible
             return std::make_shared<std::vector<LongIdx>>(0);
         }
     }

     {
         // iterates over boundary elements of \p this object
         // elements in both meshes must be in ratio 1:1
         // store orders (mapping between both mesh files) into boundary_elements_id vector
         auto bc_mesh = this->get_bc_mesh();
         auto input_bc_mesh = input_mesh.get_bc_mesh();
         // iterate trough boundary part of element vector, to each element in source mesh must exist only one element in target mesh
         // fill boundary_elements_id vector
         bool valid_nodes;
         i=this->n_elements();
         for (auto elm : bc_mesh->elements_range()) {
             valid_nodes = true;
             for (unsigned int j=0; j<elm->n_nodes(); j++) { // iterate trough all nodes of any element
                 if (node_ids[ elm->node_idx(j) ] == Mesh::undef_idx) valid_nodes = false;
                 node_list.push_back( node_ids[ elm->node_idx(j) ] );
             }
             if (valid_nodes) {
                 input_bc_mesh->intersect_element_lists(node_list, candidate_list);
                 for (auto i_elm : candidate_list) {
                     if ( input_bc_mesh->element_accessor(i_elm)->dim() == elm.dim() ) result_list.push_back(i_elm);
                 }
             }
             if (result_list.size() == 1) {
                 element_ids_map[i] = (LongIdx)result_list[0];
             } else {
                 element_ids_map[i] = (LongIdx)Mesh::undef_idx;
             }
             node_list.clear();
             result_list.clear();
             i++;
         }
     }

     return map_ptr;
 }

 void Mesh::read_regions_from_input(Input::Array region_list)
 {
     for (Input::Iterator<Input::AbstractRecord> it = region_list.begin<Input::AbstractRecord>();
                 it != region_list.end();
                 ++it) {
         // constructor has side effect in the mesh - create new region or set and store them to Mesh::region_db_
         (*it).factory< RegionSetBase, const Input::Record &, Mesh * >(*it, this);
     }
 }

 void Mesh::check_and_finish()
 {
     modify_element_ids(region_db_.el_to_reg_map_);
     region_db_.el_to_reg_map_.clear();
     region_db_.close();
     region_db_.check_regions();

     if ( in_record_.val<bool>("print_regions") ) {
         stringstream ss;
         region_db_.print_region_table(ss);
         MessageOut() << ss.str();
     }
 }


 std::vector<BoundingBox> Mesh::get_element_boxes() {
     START_TIMER("Mesh::compute_element_boxes");
     std::vector<BoundingBox> boxes;

     // make element boxes
     unsigned int i=0;
     boxes.resize(this->n_elements());
     for (auto element : this->elements_range()) {
         boxes[i] = element.bounding_box();
         i++;
     }

     return boxes;
 }

 const BIHTree &Mesh::get_bih_tree() {
     if (! this->bih_tree_) {
         bih_tree_ = std::make_shared<BIHTree>();
         bih_tree_->add_boxes( this->get_element_boxes() );
         bih_tree_->construct();
     }
     return *bih_tree_;
 }

 double Mesh::global_snap_radius() const {
     return in_record_.val<double>("global_snap_radius");
 }

 void Mesh::add_physical_name(unsigned int dim, unsigned int id, std::string name) {
     region_db_.add_region(id, name, dim, "$PhysicalNames");
 }


 void Mesh::add_node(unsigned int node_id, arma::vec3 coords) {

     nodes_.append(coords);
     node_ids_.add_item(node_id);
     node_permutation_.push_back(node_permutation_.size());
 }


 void Mesh::add_element(unsigned int elm_id, unsigned int dim, unsigned int region_id, unsigned int partition_id,
         std::vector<unsigned int> node_ids) {
     RegionIdx region_idx = region_db_.get_region( region_id, dim );
     if ( !region_idx.is_valid() ) {
         region_idx = region_db_.add_region( region_id, region_db_.create_label_from_id(region_id), dim, "$Element" );
     }
     region_db_.mark_used_region(region_idx.idx());

     if (region_idx.is_boundary()) {
         bc_element_tmp_.push_back( ElementTmpData(elm_id, dim, region_idx, partition_id, node_ids) );
     } else {
         if(dim == 0 ) {
             WarningOut().fmt("Bulk elements of zero size(dim=0) are not supported. Element ID: {}.\n", elm_id);
         }
         else {
             Element *ele = add_element_to_vector(elm_id);
             bulk_size_++;
             this->init_element(ele, elm_id, dim, region_idx, partition_id, node_ids);
         }
     }
 }


 void Mesh::init_element(Element *ele, unsigned int elm_id, unsigned int dim, RegionIdx region_idx, unsigned int partition_id,
         std::vector<unsigned int> node_ids) {
     ele->init(dim, region_idx);
     ele->pid_ = partition_id;

     for (unsigned int ni=0; ni<ele->n_nodes(); ni++) {
         ele->nodes_[ni] = this->node_index(node_ids[ni]);
     }

     // check that tetrahedron element is numbered correctly and is not degenerated
     if(ele->dim() == 3)
     {
         ElementAccessor<3> ea = this->element_accessor( this->elem_index(elm_id) );
         double jac = ea.tetrahedron_jacobian();
         if( ! (jac > 0) ) {
             WarningOut().fmt("Tetrahedron element with id {} has wrong numbering or is degenerated (Jacobian = {}).",elm_id, jac);
         }
     }
 }


 vector<vector<unsigned int> > const & Mesh::node_elements() {
     if (node_elements_.size() == 0) {
         this->create_node_element_lists();
     }
     return node_elements_;
 }


 void Mesh::init_element_vector(unsigned int size) {
     element_vec_.clear();
     element_ids_.clear();
     elem_permutation_.clear();
     element_vec_.reserve(size);
     element_ids_.reserve(size);
     elem_permutation_.reserve(size);
     bc_element_tmp_.clear();
     bc_element_tmp_.reserve(size);
     bulk_size_ = 0;
     boundary_loaded_size_ = 0;
 }


 void Mesh::init_node_vector(unsigned int size) {
     nodes_.reinit(size);
     node_ids_.clear();
     node_ids_.reserve(size);
     node_permutation_.clear();
     node_permutation_.reserve(size);
 }


 Element * Mesh::add_element_to_vector(int id) {
     element_vec_.push_back( Element() );
     Element * elem = &element_vec_.back(); //[element_vec_.size()-1];
     element_ids_.add_item((unsigned int)(id));
     elem_permutation_.push_back(elem_permutation_.size());
     return elem;
 }

 Range<ElementAccessor<3>> Mesh::elements_range() const {
     auto bgn_it = make_iter<ElementAccessor<3>>( ElementAccessor<3>(this, 0) );
     auto end_it = make_iter<ElementAccessor<3>>( ElementAccessor<3>(this, bulk_size_) );
     return Range<ElementAccessor<3>>(bgn_it, end_it);
 }

 Range<NodeAccessor<3>> Mesh::node_range() const {
     auto bgn_it = make_iter<NodeAccessor<3>>( NodeAccessor<3>(this, 0) );
     auto end_it = make_iter<NodeAccessor<3>>( NodeAccessor<3>(this, n_nodes()) );
     return Range<NodeAccessor<3>>(bgn_it, end_it);
 }

 Range<Edge> Mesh::edge_range() const {
     auto bgn_it = make_iter<Edge>( Edge(this, 0) );
     auto end_it = make_iter<Edge>( Edge(this, edges.size()) );
     return Range<Edge>(bgn_it, end_it);
 }

 inline void Mesh::check_element_size(unsigned int elem_idx) const
 {
     ASSERT(elem_idx < element_vec_.size())(elem_idx)(element_vec_.size()).error("Index of element is out of bound of element vector!");
 }

 /*
  * Output of internal flow data.
  */
 void Mesh::output_internal_ngh_data()
 {
     START_TIMER("Mesh::output_internal_ngh_data");

     if (! raw_ngh_output_file.is_open()) return;

     // header
     raw_ngh_output_file <<  "// fields:\n//ele_id    n_sides    ns_side_neighbors[n]    neighbors[n*ns]    n_vb_neighbors    vb_neighbors[n_vb]\n";
     raw_ngh_output_file <<  fmt::format("{}\n" , n_elements());

     int cit = 0;

     // map from higher dim elements to its lower dim neighbors, using gmsh IDs: ele->id()
     unsigned int undefined_ele_id = -1;
     std::map<unsigned int, std::vector<unsigned int>> neigh_vb_map;
     for (auto ele : this->elements_range()) {
         if(ele->n_neighs_vb() > 0){
             for (unsigned int i = 0; i < ele->n_neighs_vb(); i++){
                 ElementAccessor<3> higher_ele = ele->neigh_vb[i]->side()->element();

                 auto search = neigh_vb_map.find(higher_ele.idx());
                 if(search != neigh_vb_map.end()){
                     // if found, add id to correct local side idx
                     search->second[ele->neigh_vb[i]->side()->side_idx()] = ele.idx();
                 }
                 else{
                     // if not found, create new vector, each side can have one vb neighbour
                     std::vector<unsigned int> higher_ele_side_ngh(higher_ele->n_sides(), undefined_ele_id);
                     higher_ele_side_ngh[ele->neigh_vb[i]->side()->side_idx()] = ele.idx();
                     neigh_vb_map[higher_ele.idx()] = higher_ele_side_ngh;
                 }
             }
         }
     }

     for (auto ele : this->elements_range()) {
         raw_ngh_output_file << ele.idx() << " ";
         raw_ngh_output_file << ele->n_sides() << " ";

         auto search_neigh = neigh_vb_map.end();
         for (unsigned int i = 0; i < ele->n_sides(); i++) {
             unsigned int n_side_neighs = ele.side(i)->edge().n_sides()-1;  //n_sides - the current one
             // check vb neighbors (lower dimension)
             if(n_side_neighs == 0){
                 //update search
                 if(search_neigh == neigh_vb_map.end())
                     search_neigh = neigh_vb_map.find(ele.idx());

                 if(search_neigh != neigh_vb_map.end())
                     if(search_neigh->second[i] != undefined_ele_id)
                         n_side_neighs = 1;
             }
             raw_ngh_output_file << n_side_neighs << " ";
         }

         for (unsigned int i = 0; i < ele->n_sides(); i++) {
             Edge edge = ele.side(i)->edge();
             if(edge.n_sides() > 1){
                 for (uint j = 0; j < edge.n_sides(); j++) {
                     if(edge.side(j) != ele.side(i))
                         raw_ngh_output_file << edge.side(j)->element().idx() << " ";
                 }
             }
             //check vb neighbour
             else if(search_neigh != neigh_vb_map.end()
                     && search_neigh->second[i] != undefined_ele_id){
                 raw_ngh_output_file << search_neigh->second[i] << " ";
             }
         }

         // list higher dim neighbours
         raw_ngh_output_file << ele->n_neighs_vb() << " ";
         for (unsigned int i = 0; i < ele->n_neighs_vb(); i++)
             raw_ngh_output_file << ele->neigh_vb[i]->side()->element().idx() << " ";

         raw_ngh_output_file << endl;
         cit ++;
     }
     raw_ngh_output_file << "$EndFlowField\n" << endl;
 }


 unsigned int Mesh::create_boundary_elements() {
     // Copy boundary elements in temporary storage to the second part of the element vector
     for(ElementTmpData &e_data : bc_element_tmp_) {
         Element *ele = add_element_to_vector(e_data.elm_id);
         this->init_element(ele, e_data.elm_id, e_data.dim, e_data.region_idx,
                 e_data.partition_id, e_data.node_ids);
     }
     // release memory
     unsigned int bdr_size = bc_element_tmp_.size();
     vector<ElementTmpData>().swap(bc_element_tmp_);
     return bdr_size;
 }


 void Mesh::permute_tetrahedron(unsigned int elm_idx, std::vector<unsigned int> permutation_vec)
 {
     ASSERT_LT_DBG(elm_idx, element_vec_.size());
     ASSERT_EQ_DBG(permutation_vec.size(), 4);

     std::array<unsigned int, 4> tmp_nodes;
     Element &elem = element_vec_[elm_idx];
     ASSERT_EQ_DBG(elem.dim(), 3);

     for(unsigned int i=0; i<elem.n_nodes(); i++)
     {
         tmp_nodes[i] = elem.nodes_[permutation_vec[i]];
     }
     elem.nodes_ = tmp_nodes;
 }


 void Mesh::permute_triangle(unsigned int elm_idx, std::vector<unsigned int> permutation_vec)
 {
     ASSERT_LT_DBG(elm_idx, element_vec_.size());
     ASSERT_EQ_DBG(permutation_vec.size(), 3);

     std::array<unsigned int, 4> tmp_nodes;
     Element &elem = element_vec_[elm_idx];
     ASSERT_EQ_DBG(elem.dim(), 2);

     for(unsigned int i=0; i<elem.n_nodes(); i++)
     {
         tmp_nodes[i] = elem.nodes_[permutation_vec[i]];
     }
     elem.nodes_ = tmp_nodes;
 }


 BCMesh *Mesh::get_bc_mesh() {
     if (bc_mesh_ == nullptr) bc_mesh_ = new BCMesh(this);
     return bc_mesh_;
 }


 void Mesh::distribute_nodes() {
     ASSERT_PTR(el_4_loc).error("Array 'el_4_loc' is not initialized. Did you call Partitioning::id_maps?\n");

     unsigned int i_proc, i_node, i_ghost_node, elm_node;
     unsigned int my_proc = el_ds->myp();
     unsigned int n_proc = el_ds->np();

     // distribute nodes between processes, every node is assigned to minimal process of elements that own node
     // fill node_proc vector with same values on all processes
     std::vector<unsigned int> node_proc( this->n_nodes(), n_proc );
     std::vector<bool> local_node_flag( this->n_nodes(), false );

     for ( auto elm : this->elements_range() ) {
         i_proc = elm.proc();
         for (elm_node=0; elm_node<elm->n_nodes(); elm_node++) {
             i_node = elm->node_idx(elm_node);
             if (i_proc == my_proc) local_node_flag[i_node] = true;
             if (i_proc < node_proc[i_node]) node_proc[i_node] = i_proc;
         }
     }

     unsigned int n_own_nodes=0, n_local_nodes=0; // number of own and ghost nodes
     for(uint loc_flag : local_node_flag) if (loc_flag) n_local_nodes++;
     for(uint i_proc : node_proc) {
         if (i_proc == my_proc)
             n_own_nodes++;
         else if (i_proc == n_proc)
             ASSERT(0)(find_node_id(n_own_nodes)).error("A node does not belong to any element!");
     }

     //DebugOut() << print_var(n_own_nodes) << print_var(n_local_nodes) << this->n_nodes();
     // create and fill node_4_loc_ (mapping local to global indexes)
     node_4_loc_ = new LongIdx [ n_local_nodes ];
     i_node=0;
     i_ghost_node = n_own_nodes;
     for (unsigned int i=0; i<this->n_nodes(); ++i) {
         if (local_node_flag[i]) {
             if (node_proc[i]==my_proc)
                 node_4_loc_[i_node++] = i;
             else
                 node_4_loc_[i_ghost_node++] = i;
         }
     }

     // Construct node distribution object, set number of local nodes (own+ghost)
     node_ds_ = new Distribution(n_own_nodes, PETSC_COMM_WORLD);
     node_ds_->get_lsizes_array(); // need to initialize lsizes data member
     n_local_nodes_ = n_local_nodes;

 }

 //-----------------------------------------------------------------------------
 // vim: set cindent:
Mesh::n_triangles
int n_triangles
Definition: mesh.h:291

Mesh::el_ds
Distribution * el_ds
Parallel distribution of elements.
Definition: mesh.h:609

Partitioning
Class for the mesh partitioning. This should provide:
Definition: partitioning.hh:52

Input::Array::begin
Iterator< ValueType > begin() const
Definition: accessors_impl.hh:145

Input::ReaderToStorage::read_stream
void read_stream(istream &in, const Type::TypeBase &root_type, FileFormat format)
This method actually reads the given stream in.
Definition: reader_to_storage.cc:110

Edge::n_sides
unsigned int n_sides() const
Returns number of sides aligned with the edge.
Definition: accessors.hh:300

mesh_optimizer.hh

Mesh::output_internal_ngh_data
void output_internal_ngh_data()
Output of neighboring data into raw output.
Definition: mesh.cc:1267

ElementAccessor::element
const Element * element() const
Definition: accessors.hh:160

Armor::Array::resize
void resize(uint size)
Definition: armor.hh:710

Element::n_nodes
unsigned int n_nodes() const
Definition: elements.h:126

Input::Iterator
Definition: accessors.hh:143

Element::nodes_
std::array< unsigned int, 4 > nodes_
indices to element&#39;s nodes
Definition: elements.h:111

Mesh::element_vec_
vector< Element > element_vec_
Definition: mesh.h:555

Mesh::node_ids_
BidirectionalMap< int > node_ids_
Maps node ids to indexes into vector node_vec_.
Definition: mesh.h:575

Mesh::node_elements
vector< vector< unsigned int > > const & node_elements()
Definition: mesh.cc:1202

bc_mesh.hh

ASSERT_EQ_DBG
#define ASSERT_EQ_DBG(a, b)
Definition of comparative assert macro (EQual) only for debug mode.
Definition: asserts.hh:332

BidirectionalMap::size
unsigned int size() const
Return size of map.
Definition: bidirectional_map.hh:80

arma::vec3
Definition: doxy_dummy_defs.hh:17

Input::Array
Accessor to input data conforming to declared Array.
Definition: accessors.hh:566

BidirectionalMap::reserve
void reserve(unsigned int init_size=0)
Reset data of map, reserve space for given size.
Definition: bidirectional_map.hh:139

Mesh::n_local_nodes_
unsigned int n_local_nodes_
Hold number of local nodes (own + ghost), value is equal with size of node_4_loc array.
Definition: mesh.h:615

Element::boundary_idx_
unsigned int * boundary_idx_
Definition: elements.h:80

Mesh::permute_tetrahedron
void permute_tetrahedron(unsigned int elm_idx, std::vector< unsigned int > permutation_vec)
Permute nodes of 3D elements of given elm_idx.
Definition: mesh.cc:1363

RegionIdx::is_boundary
bool is_boundary() const
Returns true if it is a Boundary region and false if it is a Bulk region.
Definition: region.hh:74

uint
unsigned int uint
Definition: mh_dofhandler.hh:101

BoundaryData::bc_ele_idx_
unsigned int bc_ele_idx_
Definition: mesh_data.hh:53

mixed_mesh_intersections.hh

Mesh::sort_permuted_nodes_elements
void sort_permuted_nodes_elements(std::vector< int > new_node_ids, std::vector< int > new_elem_ids)
Sort elements and nodes by order stored in permutation vectors.
Definition: mesh.cc:435

Mesh::Element
friend class Element
Definition: mesh.h:590

Mesh::count_side_types
void count_side_types()
Definition: mesh.cc:462

MPI_Comm
int MPI_Comm
Definition: mpi.h:141

Mesh::bc_mesh_
BCMesh * bc_mesh_
Boundary mesh, object is created only if it&#39;s necessary.
Definition: mesh.h:617

MeshOptimizer::sort_nodes
std::vector< int > sort_nodes(std::vector< unsigned int > &node_permutation)
Definition: mesh_optimizer.hh:104

Mesh::BIHsearch
Definition: mesh.h:111

Side::side_idx
unsigned int side_idx() const
Returns local index of the side on the element.
Definition: accessors.hh:415

Mesh::check_and_finish
void check_and_finish()
Definition: mesh.cc:1102

RegionDB::el_to_reg_map_
MapElementIDToRegionID el_to_reg_map_
Definition: region.hh:571

Input::ReaderToStorage
Reader for (slightly) modified input files.
Definition: reader_to_storage.hh:96

Mesh::init_element_vector
void init_element_vector(unsigned int size)
Initialize element_vec_, set size and reset counters of boundary and bulk elements.
Definition: mesh.cc:1210

Mesh::get_local_part
virtual const LongIdx * get_local_part()
Definition: mesh.cc:273

Mesh::mixed_intersections
MixedMeshIntersections & mixed_intersections()
Definition: mesh.cc:904

Input::Type::Default
Class Input::Type::Default specifies default value of keys of a Input::Type::Record.
Definition: type_record.hh:61

Mesh::element_ids_
BidirectionalMap< int > element_ids_
Maps element ids to indexes into vector element_vec_.
Definition: mesh.h:567

Input::Type::Bool
Class for declaration of the input of type Bool.
Definition: type_base.hh:452

Side::edge
Edge edge() const
Returns pointer to the edge connected to the side.
Definition: accessors_impl.hh:242

Armor::Array::append
void append(const ArmaMat< Type, nr, nc > &item)
Definition: armor.hh:736

region_set.hh

Mesh::add_node
void add_node(unsigned int node_id, arma::vec3 coords)
Add new node of given id and coordinates to mesh.
Definition: mesh.cc:1150

Mesh::node_4_loc_
LongIdx * node_4_loc_
Index set assigning to local node index its global index.
Definition: mesh.h:611

accessors.hh

MessageOut
#define MessageOut()
Macro defining &#39;message&#39; record of log.
Definition: logger.hh:267

Mesh::elem_permutation_
std::vector< unsigned int > elem_permutation_
Vector of element permutations of optimized mesh (see class MeshOptimizer)
Definition: mesh.h:584

Mesh::tree
DuplicateNodes * tree
Definition: mesh.h:279

Mesh::check_compatible_mesh
virtual std::shared_ptr< std::vector< LongIdx > > check_compatible_mesh(Mesh &input_mesh)
Definition: mesh.cc:974

std::map< unsigned int, unsigned int >

Neighbour::elem_idx_
unsigned int elem_idx_
Index of element in Mesh::element_vec_.
Definition: neighbours.h:137

Mesh::n_lines
int n_lines
Definition: mesh.h:290

Mesh::create_boundary_elements
unsigned int create_boundary_elements()
Create boundary elements from data of temporary structure, this method MUST be call after read mesh f...
Definition: mesh.cc:1349

Partitioning::get_input_type
static const Input::Type::Record & get_input_type()
Definition: partitioning.cc:49

Mesh::undef_idx
static const unsigned int undef_idx
Definition: mesh.h:121

Mesh::get_element_boxes
std::vector< BoundingBox > get_element_boxes()
Compute bounding boxes of elements contained in mesh.
Definition: mesh.cc:1117

Mesh::init
void init()
Definition: mesh.cc:163

Mesh::raw_ngh_output_file
ofstream raw_ngh_output_file
Definition: mesh.h:619

Mesh::n_elements
virtual unsigned int n_elements() const
Returns count of boundary or bulk elements.
Definition: mesh.h:361

fmt::format
std::string format(CStringRef format_str, ArgList args)
Definition: format.h:3141

INPUT_CATCH
#define INPUT_CATCH(ExceptionType, AddressEITag, input_accessor)
Definition: accessors.hh:63

Range
Range helper class.
Definition: range_wrapper.hh:65

Mesh::create_node_element_lists
void create_node_element_lists()
Definition: mesh.cc:476

RefElement::permutation_index
static unsigned int permutation_index(unsigned int p[n_nodes_per_side])
Definition: ref_element.cc:552

Mesh::get_bc_mesh
BCMesh * get_bc_mesh()
Create boundary mesh if doesn&#39;t exist and return it.
Definition: mesh.cc:1397

ElementAccessor< 3 >

system.hh

Mesh::get_input_type
static const Input::Type::Record & get_input_type()
Definition: mesh.cc:75

Mesh::elem_index
int elem_index(int elem_id) const
For element of given elem_id returns index in element_vec_ or (-1) if element doesn&#39;t exist...
Definition: mesh.h:369

node_accessor.hh

Input::Type::Default::obligatory
static Default obligatory()
The factory function to make an empty default value which is obligatory.
Definition: type_record.hh:110

mesh.h

Mesh::intersections
std::shared_ptr< MixedMeshIntersections > intersections
Definition: mesh.h:271

Mesh::global_snap_radius
double global_snap_radius() const
Maximal distance of observe point from Mesh relative to its size.
Definition: mesh.cc:1141

Mesh::max_edge_sides_
unsigned int max_edge_sides_[3]
Maximal number of sides per one edge in the actual mesh (set in make_neighbours_and_edges()).
Definition: mesh.h:509

Mesh
Definition: mesh.h:77

Mesh::n_local_nodes
unsigned int n_local_nodes() const
Definition: mesh.h:186

Armor::Array< double >

Mesh::edges
std::vector< EdgeData > edges
Vector of MH edges, this should not be part of the geometrical mesh.
Definition: mesh.h:578

Mesh::in_record_
Input::Record in_record_
Definition: mesh.h:543

Distribution
Definition: distribution.hh:50

RegionDB::create_label_from_id
std::string create_label_from_id(unsigned int id) const
Definition: region.cc:337

Mesh::side_nodes
vector< vector< vector< unsigned int > > > side_nodes
Definition: mesh.h:304

Edge
Definition: accessors.hh:265

ElementAccessor::side
SideIter side(const unsigned int loc_index)
Definition: accessors_impl.hh:160

Mesh::n_tetrahedras
int n_tetrahedras
Definition: mesh.h:292

ASSERT
#define ASSERT(expr)
Allow use shorter versions of macro names if these names is not used with external library...
Definition: asserts.hh:347

Mesh::n_nodes
virtual unsigned int n_nodes() const
Definition: mesh.h:143

Mesh::boundary_
vector< BoundaryData > boundary_
Definition: mesh.h:263

accessors.hh

Mesh::boundary
Boundary boundary(uint edge_idx) const
Definition: mesh.cc:263

std::vector< uint >

Mesh::add_physical_name
void add_physical_name(unsigned int dim, unsigned int id, std::string name)
Add new node of given id and coordinates to mesh.
Definition: mesh.cc:1145

Armor::Array::vec
ArmaVec< Type, nr > vec(uint mat_index) const
Definition: armor.hh:821

Mesh::node_permutation_
std::vector< unsigned int > node_permutation_
Vector of node permutations of optimized mesh (see class MeshOptimizer)
Definition: mesh.h:581

Mesh::node_index
int node_index(int node_id) const
For node of given node_id returns index in element_vec_ or (-1) if node doesn&#39;t exist.
Definition: mesh.h:387

Side::element
ElementAccessor< 3 > element() const
Returns iterator to the element of the side.
Definition: accessors_impl.hh:233

Mesh::get_part
virtual Partitioning * get_part()
Definition: mesh.cc:269

neighbours.h

ElementAccessor::node
NodeAccessor< 3 > node(unsigned int ni) const
Definition: accessors.hh:200

Input::Type::Record::close
Record & close() const
Close the Record for further declarations of keys.
Definition: type_record.cc:304

Input::Type::Array
Class for declaration of inputs sequences.
Definition: type_base.hh:339

Mesh::element_accessor
virtual ElementAccessor< 3 > element_accessor(unsigned int idx) const
Create and return ElementAccessor to element of given idx.
Definition: mesh.cc:921

Mesh::ElementTmpData
Definition: mesh.h:432

Mesh::n_exsides
int n_exsides
Definition: mesh.h:287

Mesh::check_mesh_on_read
void check_mesh_on_read()
Definition: mesh.cc:324

sys_profiler.hh

Element::init
void init(unsigned int dim, RegionIdx reg)
Definition: elements.cc:52

Boundary
Definition: accessors.hh:320

Input::Array::end
IteratorBase end() const
Definition: accessors_impl.hh:157

Distribution::get_lsizes_array
const unsigned int * get_lsizes_array()
get local sizes array
Definition: distribution.cc:142

Mesh::nodes_
Armor::Array< double > nodes_
Definition: mesh.h:572

RegionDB::get_region
Region get_region(unsigned int id, unsigned int dim)
Definition: region.cc:150

Element::dim
unsigned int dim() const
Definition: elements.h:121

Input::Type::Default::optional
static Default optional()
The factory function to make an empty default value which is optional.
Definition: type_record.hh:124

OLD_ASSERT
#define OLD_ASSERT(...)
Definition: global_defs.h:108

Mesh::n_vb_neighbours
unsigned int n_vb_neighbours() const
Definition: mesh.cc:242

Neighbour::element
ElementAccessor< 3 > element()
Definition: neighbours.h:161

FilePath::open_stream
void open_stream(Stream &stream) const
Definition: file_path.cc:211

Input::Record::opt_val
bool opt_val(const string &key, Ret &value) const
Definition: accessors_impl.hh:107

Neighbour::edge_idx_
unsigned int edge_idx_
Index of Edge in Mesh.
Definition: neighbours.h:138

Mesh::read_regions_from_input
void read_regions_from_input(Input::Array region_list)
Definition: mesh.cc:1092

Mesh::boundary_loaded_size_
unsigned int boundary_loaded_size_
Count of boundary elements loaded from mesh file.
Definition: mesh.h:564

Input::Type::Record::allow_auto_conversion
virtual Record & allow_auto_conversion(const string &from_key)
Allows shorter input of the Record providing only value of the from_key given as the parameter...
Definition: type_record.cc:133

Mesh::same_sides
bool same_sides(const SideIter &si, vector< unsigned int > &side_nodes)
Definition: mesh.cc:540

Input::Type::Double
Class for declaration of the input data that are floating point numbers.
Definition: type_base.hh:534

Mesh::find_elem_id
int find_elem_id(unsigned int pos) const
Return element id (in GMSH file) of element of given position in element vector.
Definition: mesh.h:375

Input::Type
Definition: balance.hh:41

BidirectionalMap::add_item
unsigned int add_item(T val)
Add new item at the end position of map.
Definition: bidirectional_map.hh:106

BoundaryData::mesh_
Mesh * mesh_
Definition: mesh_data.hh:54

SideIter
Definition: accessors.hh:461

input_type.hh

Element::node_idx
unsigned int node_idx(unsigned int ni) const
Return index (in Mesh::node_vec) of ni-th node.
Definition: elements.h:72

exceptions.hh

Mesh::check_element_size
void check_element_size(unsigned int elem_idx) const
Check if given index is in element_vec_.
Definition: mesh.cc:1259

Mesh::setup_topology
void setup_topology()
Definition: mesh.cc:389

Mesh::get_intersection_search
IntersectionSearch get_intersection_search()
Getter for input type selection for intersection search algorithm.
Definition: mesh.cc:157

Element::neigh_vb
Neighbour ** neigh_vb
Definition: elements.h:84

RegionDB::find_id
Region find_id(unsigned int id, unsigned int dim) const
Definition: region.cc:180

Mesh::el_4_loc
LongIdx * el_4_loc
Index set assigning to local element index its global index.
Definition: mesh.h:607

Mesh::BCMesh
friend class BCMesh
Definition: mesh.h:593

Input::ReaderToStorage::get_root_interface
T get_root_interface() const
Returns the root accessor.
Definition: reader_to_storage.cc:150

Element::edge_idx
unsigned int edge_idx(unsigned int edg_idx) const
Return edge_idx of given index.
Definition: elements.h:136

Mesh::RegionSetBase
friend class RegionSetBase
Definition: mesh.h:589

Mesh::get_input_intersection_variant
static const Input::Type::Selection & get_input_intersection_variant()
The definition of input record for selection of variant of file format.
Definition: mesh.cc:64

Input::Type::FileName::input
static FileName input()
The factory function for declaring type FileName for input files.
Definition: type_base.cc:524

Neighbour::side
SideIter side()
Definition: neighbours.h:145

Input::Record
Accessor to the data with type Type::Record.
Definition: accessors.hh:291

BoundaryData::edge_idx_
unsigned int edge_idx_
Definition: mesh_data.hh:49

NDEF
#define NDEF
Definition: mesh.cc:60

Input::Record::val
const Ret val(const string &key) const
Definition: accessors_impl.hh:31

Element::n_sides
unsigned int n_sides() const
Definition: elements.h:132

DuplicateNodes
Definition: duplicate_nodes.h:96

START_TIMER
#define START_TIMER(tag)
Starts a timer with specified tag.
Definition: sys_profiler.hh:115

Armor::Array::reinit
void reinit(uint size)
Definition: armor.hh:698

index_types.hh

BIHTree
Class for O(log N) lookup for intersections with a set of bounding boxes.
Definition: bih_tree.hh:38

Input::Type::Selection::add_value
Selection & add_value(const int value, const std::string &key, const std::string &description="", TypeBase::attribute_map attributes=TypeBase::attribute_map())
Adds one new value with name given by key to the Selection.
Definition: type_selection.cc:50

Mesh::n_corners
unsigned int n_corners()
Definition: mesh.cc:247

Neighbour
Definition: neighbours.h:117

Mesh::row_4_el
LongIdx * row_4_el
Index set assigning to global element index the local index used in parallel vectors.
Definition: mesh.h:605

ElementAccessor::bounding_box
BoundingBox bounding_box() const
Definition: accessors.hh:208

Mesh::BBsearch
Definition: mesh.h:113

Input::Type::Record::declare_key
Record & declare_key(const string &key, std::shared_ptr< TypeBase > type, const Default &default_value, const string &description, TypeBase::attribute_map key_attributes=TypeBase::attribute_map())
Declares a new key of the Record.
Definition: type_record.cc:503

RegionDB::close
void close()
Definition: region.cc:249

RegionIdx
Definition: region.hh:67

Input::Record::is_empty
bool is_empty() const
Definition: accessors.hh:365

Armor::Array::set
ArrayMatSet set(uint index)
Definition: armor.hh:838

RegionDB::implicit_boundary_region
Region implicit_boundary_region()
Definition: region.cc:75

Mesh::elements_range
virtual Range< ElementAccessor< 3 > > elements_range() const
Returns range of bulk elements.
Definition: mesh.cc:1241

Mesh::add_element_to_vector
Element * add_element_to_vector(int id)
Adds element to mesh data structures (element_vec_, element_ids_), returns pointer to this element...
Definition: mesh.cc:1233

Mesh::node
NodeAccessor< 3 > node(unsigned int idx) const
Create and return NodeAccessor to node of given idx.
Definition: mesh.cc:927

Element
Definition: elements.h:39

Distribution::np
unsigned int np() const
get num of processors
Definition: distribution.hh:105

Mesh::n_sides
unsigned int n_sides() const
Definition: mesh.cc:233

Mesh::bih_tree_
std::shared_ptr< BIHTree > bih_tree_
Definition: mesh.h:537

std::swap
void swap(nlohmann::json &j1, nlohmann::json &j2) noexcept(is_nothrow_move_constructible< nlohmann::json >::value andis_nothrow_move_assignable< nlohmann::json >::value)
exchanges the values of two JSON objects
Definition: json.hpp:8688

Mesh::node_elements_
vector< vector< unsigned int > > node_elements_
For each node the vector contains a list of elements that use this node.
Definition: mesh.h:366

MeshOptimizer::calculate_element_curve_values_as_hilbert_of_centers
void calculate_element_curve_values_as_hilbert_of_centers()
Definition: mesh_optimizer.hh:86

Side::node
NodeAccessor< 3 > node(unsigned int i) const
Returns node for given local index i on the side.
Definition: accessors_impl.hh:227

Element::permutation_idx_
std::vector< unsigned int > permutation_idx_
Definition: elements.h:104

bih_tree.hh

Mesh::Boundary
friend class Boundary
Definition: mesh.h:592

Input::AbstractRecord
Accessor to the polymorphic input data of a type given by an AbstracRecord object.
Definition: accessors.hh:458

ElementAccessor::region
Region region() const
Definition: accessors.hh:165

partitioning.hh

Mesh::elements_id_maps
void elements_id_maps(vector< LongIdx > &bulk_elements_id, vector< LongIdx > &boundary_elements_id) const
Definition: mesh.cc:933

duplicate_nodes.h

Input::format_JSON
Definition: reader_to_storage.hh:60

Mesh::count_element_types
void count_element_types()
Definition: mesh.cc:282

compare_points
bool compare_points(const arma::vec3 &p1, const arma::vec3 &p2)
Definition: mesh.cc:966

Mesh::get_bih_tree
const BIHTree & get_bih_tree()
Getter for BIH. Creates and compute BIH at first call.
Definition: mesh.cc:1132

MPI_Comm_rank
#define MPI_Comm_rank
Definition: mpi.h:236

RegionDB::check_regions
void check_regions()
Definition: region.cc:461

FilePath
Dedicated class for storing path to input and output files.
Definition: file_path.hh:54

Distribution::myp
unsigned int myp() const
get my processor
Definition: distribution.hh:107

RegionDB::mark_used_region
void mark_used_region(unsigned int idx)
Definition: region.cc:235

distribution.hh
Support classes for parallel programing.

RegionDB::add_region
Region add_region(unsigned int id, const std::string &label, unsigned int dim, const std::string &address="implicit")
Definition: region.cc:85

Mesh::vb_neighbours_
vector< Neighbour > vb_neighbours_
Definition: mesh.h:284

LongIdx
int LongIdx
Define type that represents indices of large arrays (elements, nodes, dofs etc.)
Definition: index_types.hh:24

Mesh::node_ds_
Distribution * node_ds_
Parallel distribution of nodes. Depends on elements distribution.
Definition: mesh.h:613

Input::Type::Record::finish
FinishStatus finish(FinishStatus finish_type=FinishStatus::regular_) override
Finish declaration of the Record type.
Definition: type_record.cc:243

Mesh::distribute_nodes
void distribute_nodes()
Fill array node_4_loc_ and create object node_ds_ according to element distribution.
Definition: mesh.cc:1403

BIHTree::find_point
void find_point(const Space< 3 >::Point &point, std::vector< unsigned int > &result_list, bool full_list=false) const
Definition: bih_tree.cc:287

Mesh::n_sides_
int n_sides_
Definition: mesh.h:288

Element::region_idx_
RegionIdx region_idx_
Definition: elements.h:107

BCMesh
Class represents boundary part of mesh.
Definition: bc_mesh.hh:35

ASSERT_PTR
#define ASSERT_PTR(ptr)
Definition of assert macro checking non-null pointer (PTR)
Definition: asserts.hh:336

Input::Type::Selection::close
const Selection & close() const
Close the Selection, no more values can be added.
Definition: type_selection.cc:65

reader_to_storage.hh

MeshOptimizer
Definition: mesh_optimizer.hh:35

region.hh

Mesh::region_db_
RegionDB region_db_
Definition: mesh.h:528

Mesh::comm_
MPI_Comm comm_
Definition: mesh.h:548

ASSERT_DBG
#define ASSERT_DBG(expr)
Definition: include_fadbad.hh:28

Mesh::find_lower_dim_element
bool find_lower_dim_element(vector< unsigned int > &element_list, unsigned int dim, unsigned int &element_idx)
Definition: mesh.cc:521

Element::pid_
int pid_
Id # of mesh partition.
Definition: elements.h:89

Mesh::n_insides
int n_insides
Definition: mesh.h:286

RegionDB::print_region_table
void print_region_table(std::ostream &stream) const
Definition: region.cc:409

Mesh::intersect_element_lists
void intersect_element_lists(vector< unsigned int > const &nodes_list, vector< unsigned int > &intersection_element_list)
Definition: mesh.cc:489

Mesh::modify_element_ids
void modify_element_ids(const RegionDB::MapElementIDToRegionID &map)
Definition: mesh.cc:299

WarningOut
#define WarningOut()
Macro defining &#39;warning&#39; record of log.
Definition: logger.hh:270

MPI_COMM_WORLD
#define MPI_COMM_WORLD
Definition: mpi.h:123

Mesh::make_edge_permutations
void make_edge_permutations()
Definition: mesh.cc:751

END_TIMER
#define END_TIMER(tag)
Ends a timer with specified tag.
Definition: sys_profiler.hh:149

ElementAccessor::tetrahedron_jacobian
double tetrahedron_jacobian() const
Definition: accessors_impl.hh:69

ref_element.hh
Class RefElement defines numbering of vertices, sides, calculation of normal vectors etc...

RegionSetBase::get_input_type
static Input::Type::Abstract & get_input_type()
Definition: region_set.cc:25

Mesh::node_range
Range< NodeAccessor< 3 > > node_range() const
Returns range of nodes.
Definition: mesh.cc:1247

EdgeData::side_
SideIter * side_
Definition: mesh_data.hh:32

Mesh::edge
Edge edge(uint edge_idx) const
Definition: mesh.cc:257

Partitioning::get_loc_part
const LongIdx * get_loc_part() const
Definition: partitioning.cc:85

EdgeData
Definition: mesh_data.hh:25

Mesh::add_element
void add_element(unsigned int elm_id, unsigned int dim, unsigned int region_id, unsigned int partition_id, std::vector< unsigned int > node_ids)
Add new element of given id to mesh.
Definition: mesh.cc:1158

print_var
#define print_var(var)
Definition: logger.hh:284

Input::Type::Record
Record type proxy class.
Definition: type_record.hh:182

RegionDB::undefined_dim
static const unsigned int undefined_dim
Definition: region.hh:332

RegionIdx::is_valid
bool is_valid() const
Returns false if the region has undefined/invalid value.
Definition: region.hh:78

Mesh::IntersectionSearch
IntersectionSearch
Types of search algorithm for finding intersection candidates.
Definition: mesh.h:110

Mesh::element_to_neigh_vb
void element_to_neigh_vb()
Definition: mesh.cc:871

ElementAccessor::dim
unsigned int dim() const
Definition: accessors.hh:157

Mesh::init_element
void init_element(Element *ele, unsigned int elm_id, unsigned int dim, RegionIdx region_idx, unsigned int partition_id, std::vector< unsigned int > node_ids)
Initialize element.
Definition: mesh.cc:1181

Mesh::optimize
void optimize()
Definition: mesh.cc:425

Mesh::Edge
friend class Edge
Definition: mesh.h:587

Mesh::Mesh
Mesh()
Definition: mesh.cc:103

NodeAccessor
Definition: mesh.h:55

Input::Type::FileName::output
static FileName output()
The factory function for declaring type FileName for input files.
Definition: type_base.cc:531

Element::n_neighs_vb_
unsigned int n_neighs_vb_
of neighbours, V-B type (comp.)
Definition: elements.h:91

Mesh::permute_triangle
void permute_triangle(unsigned int elm_idx, std::vector< unsigned int > permutation_vec)
Permute nodes of 2D elements of given elm_idx.
Definition: mesh.cc:1380

MeshOptimizer::calculate_node_curve_values_as_hilbert
void calculate_node_curve_values_as_hilbert()
Definition: mesh_optimizer.hh:59

DebugOut
#define DebugOut()
Macro defining &#39;debug&#39; record of log.
Definition: logger.hh:276

ASSERT_PTR_DBG
#define ASSERT_PTR_DBG(ptr)
Definition of assert macro checking non-null pointer (PTR) only for debug mode.
Definition: asserts.hh:340

ElementAccessor::idx
unsigned int idx() const
Return local idx of element in boundary / bulk part of element vector.
Definition: accessors.hh:181

MeshOptimizer::calculate_sizes
void calculate_sizes()
Definition: mesh_optimizer.hh:40

THROW
#define THROW(whole_exception_expr)
Wrapper for throw. Saves the throwing point.
Definition: exceptions.hh:53

BidirectionalMap< int >

Edge::side
SideIter side(const unsigned int i) const
Gets side iterator of the i -th side.
Definition: accessors_impl.hh:192

BidirectionalMap::clear
void clear()
Clear the content. Do not release memory.
Definition: bidirectional_map.hh:121

Mesh::edge_range
Range< Edge > edge_range() const
Returns range of edges.
Definition: mesh.cc:1253

Input::Type::Selection
Template for classes storing finite set of named values.
Definition: type_selection.hh:65

range_wrapper.hh
Implementation of range helper class.

Mesh::bulk_size_
unsigned int bulk_size_
Count of bulk elements.
Definition: mesh.h:561

Mesh::part_
std::shared_ptr< Partitioning > part_
Definition: mesh.h:532

Mesh::BIHonly
Definition: mesh.h:112

RefElement
Definition: ref_element.hh:163

Mesh::make_neighbours_and_edges
void make_neighbours_and_edges()
Definition: mesh.cc:557

Mesh::bc_element_tmp_
vector< ElementTmpData > bc_element_tmp_
Hold data of boundary elements during reading mesh (allow to preserve correct order during reading of...
Definition: mesh.h:558

Neighbour::mesh_
Mesh * mesh_
Pointer to Mesh to which belonged.
Definition: neighbours.h:136

ASSERT_EQ
#define ASSERT_EQ(a, b)
Definition of comparative assert macro (EQual)
Definition: asserts.hh:328

Mesh::init_node_vector
void init_node_vector(unsigned int size)
Initialize node_vec_, set size.
Definition: mesh.cc:1224

Region::id
unsigned int id() const
Returns id of the region (using RegionDB)
Definition: region.cc:37

MixedMeshIntersections
Main class for computation of intersection of meshes of combined dimensions.
Definition: mixed_mesh_intersections.hh:64

Interaction
Definition: ref_element.hh:157

Mesh::find_node_id
int find_node_id(unsigned int pos) const
Return node id (in GMSH file) of node of given position in node vector.
Definition: mesh.h:393

Side::n_nodes
unsigned int n_nodes() const
Returns number of nodes of the side.
Definition: accessors.hh:407

Mesh::~Mesh
virtual ~Mesh()
Destructor.
Definition: mesh.cc:208

RegionIdx::idx
unsigned int idx() const
Returns a global index of the region.
Definition: region.hh:82

BoundaryData
Definition: mesh_data.hh:40

ASSERT_LT_DBG
#define ASSERT_LT_DBG(a, b)
Definition of comparative assert macro (Less Than) only for debug mode.
Definition: asserts.hh:300

MeshOptimizer::sort_elements
std::vector< int > sort_elements(std::vector< unsigned int > &elem_permutation)
Definition: mesh_optimizer.hh:108

EdgeData::n_sides
unsigned int n_sides
Definition: mesh_data.hh:29