Documentation/OpenFlipper-3.1/a02118_source.html

 /*===========================================================================*\
  *                                                                           *
  *                            OpenVolumeMesh                                 *
  *        Copyright (C) 2011 by Computer Graphics Group, RWTH Aachen         *
  *                        www.openvolumemesh.org                             *
  *                                                                           *
  *---------------------------------------------------------------------------*
  *  This file is part of OpenVolumeMesh.                                     *
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  *  OpenVolumeMesh is free software: you can redistribute it and/or modify   *
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  *  link it with other files to produce an executable, this file does        *
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  *  GNU Lesser General Public License. This exception does not however       *
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 \*===========================================================================*/

 /*===========================================================================*\
  *                                                                           *
  *   $Revision$                                                         *
  *   $Date$                    *
  *   $LastChangedBy$                                                *
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 \*===========================================================================*/

 #include "TetrahedralMeshTopologyKernel.hh"

 #include <iostream>

 namespace OpenVolumeMesh {


 TetrahedralMeshTopologyKernel::TetrahedralMeshTopologyKernel() {

 }

 //========================================================================================


 TetrahedralMeshTopologyKernel::~TetrahedralMeshTopologyKernel() {

 }

 //========================================================================================


 FaceHandle TetrahedralMeshTopologyKernel::add_face(const std::vector<HalfEdgeHandle>& _halfedges, bool _topologyCheck) {

     if(_halfedges.size() != 3) {
 #ifndef NDEBUG
         std::cerr << "TetrahedralMeshTopologyKernel::add_face(): Face valence is not three! Returning" << std::endl;
         std::cerr << "invalid handle." << std::endl;
 #endif
         return TopologyKernel::InvalidFaceHandle;
     }

     return TopologyKernel::add_face(_halfedges, _topologyCheck);
 }

 //========================================================================================


 FaceHandle
 TetrahedralMeshTopologyKernel::add_face(const std::vector<VertexHandle>& _vertices) {

     if(_vertices.size() != 3) {
 #ifndef NDEBUG
         std::cerr << "TetrahedralMeshTopologyKernel::add_face(): Face valence is not three! Returning" << std::endl;
         std::cerr << "invalid handle." << std::endl;
 #endif
         return TopologyKernel::InvalidFaceHandle;
     }

     return TopologyKernel::add_face(_vertices);
 }

 //========================================================================================


 CellHandle
 TetrahedralMeshTopologyKernel::add_cell(const std::vector<HalfFaceHandle>& _halffaces, bool _topologyCheck) {

     if(_halffaces.size() != 4) {
 // To make this consistent with add_face
 #ifndef NDEBUG
         std::cerr << "Cell valence is not four! Aborting." << std::endl;
 #endif
         return TopologyKernel::InvalidCellHandle;
     }
     for(std::vector<HalfFaceHandle>::const_iterator it = _halffaces.begin();
             it != _halffaces.end(); ++it) {
         if(TopologyKernel::halfface(*it).halfedges().size() != 3) {
 #ifndef NDEBUG
             std::cerr << "Incident face does not have valence three! Aborting." << std::endl;
 #endif
             return TopologyKernel::InvalidCellHandle;
         }
     }

     return TopologyKernel::add_cell(_halffaces, _topologyCheck);
 }


 HalfEdgeHandle TetrahedralMeshTopologyKernel::add_halfedge(const VertexHandle& _fromVertex, const VertexHandle& _toVertex)
 {
     HalfEdgeHandle he = halfedge(_fromVertex, _toVertex);
     if (he != InvalidHalfEdgeHandle)
         return he;
     else
         return halfedge_handle(add_edge(_fromVertex, _toVertex), 0);
 }

 HalfFaceHandle TetrahedralMeshTopologyKernel::add_halfface(const std::vector<HalfEdgeHandle>& _halfedges, bool _topologyCheck)
 {
     HalfFaceHandle hf = halfface(_halfedges);
     if (hf != InvalidHalfFaceHandle)
         return hf;
     else
         return halfface_handle(add_face(_halfedges, _topologyCheck), 0);
 }

 HalfFaceHandle TetrahedralMeshTopologyKernel::add_halfface(VertexHandle _vh0, VertexHandle _vh1, VertexHandle _vh2, bool _topologyCheck)
 {
     std::vector<HalfEdgeHandle> halfedges;
     halfedges.push_back(add_halfedge(_vh0, _vh1));
     halfedges.push_back(add_halfedge(_vh1, _vh2));
     halfedges.push_back(add_halfedge(_vh2, _vh0));
     return add_halfface(halfedges, _topologyCheck);
 }

 /*void TetrahedralMeshTopologyKernel::replaceHalfFace(CellHandle ch, HalfFaceHandle hf_del, HalfFaceHandle hf_ins)
 {
     Cell& c = cells_[ch.idx()];
     std::vector<HalfFaceHandle> hfs;
     for (unsigned int i = 0; i < c.halffaces().size(); ++i)
         if (c.halffaces()[i] != hf_del)
             hfs.push_back(c.halffaces()[i]);
         else
             hfs.push_back(hf_ins);
     c.set_halffaces(hfs);
 }

 void TetrahedralMeshTopologyKernel::replaceHalfEdge(HalfFaceHandle hfh, HalfEdgeHandle he_del, HalfEdgeHandle he_ins)
 {
     FaceHandle fh = face_handle(hfh);
     unsigned char oppF = hfh.idx() - halfface_handle(fh, 0);
     if (oppF == 1)
     {
         he_del = opposite_halfedge_handle(he_del);
         he_ins = opposite_halfedge_handle(he_ins);
     }
     Face& f = faces_[fh.idx()];
     std::vector<HalfEdgeHandle> hes;
     for (unsigned int i = 0; i < f.halfedges().size(); ++i)
         if (f.halfedges()[i] != he_del)
             hes.push_back(f.halfedges()[i]);
         else
             hes.push_back(he_ins);
     f.set_halfedges(hes);

 }*/

 /*
 void TetrahedralMeshTopologyKernel::collapse_edge(HalfEdgeHandle _heh)
 {

     std::vector<bool> deleteTagFaces(faces_.size(), false);
     std::vector<bool> deleteTagEdges(edges_.size(), false);
     std::vector<bool> deleteTagCells(cells_.size(), false);

     for (HalfEdgeHalfFaceIter hehf_it = hehf_iter(_heh); hehf_it.valid(); ++hehf_it)
     {
         CellHandle ch = incident_cell(*hehf_it);
         if (ch.is_valid())
         {
             HalfFaceHandle hf134 = *hehf_it;
             HalfFaceHandle hf143 = opposite_halfface_handle(hf143);
             HalfEdgeHandle he13  = prev_halfedge_in_halfface(_heh, hf134);
             HalfEdgeHandle he41  = next_halfedge_in_halfface(_heh, hf134);
             HalfFaceHandle hf123 = adjacent_halfface_in_cell(hf134, he13);
             HalfFaceHandle hf142 = adjacent_halfface_in_cell(hf134, he41);
             HalfFaceHandle hf132 = opposite_halfface_handle(hf123);
             CellHandle ch0123 = incident_cell(hf132);
             HalfEdgeHandle he32  = next_halfedge_in_halfface(he13, hf132);
             HalfEdgeHandle he23  = opposite_halfedge_handle(he32);
             HalfEdgeHandle he14  = opposite_halfedge_handle(he41);
             HalfEdgeHandle he31  = opposite_halfedge_handle(he13);
             HalfEdgeHandle he42  = next_halfedge_in_halfface(he14, hf142);
             HalfEdgeHandle he24  = opposite_halfedge_handle(he42);
             HalfFaceHandle hf243 = adjacent_halfface_in_cell(hf134, he41);
             HalfFaceHandle hf234 = opposite_halfface_handle(hf234);
             HalfEdgeHandle he12  = next_halfedge_in_halfface(he42, hf142);
             HalfEdgeHandle he21  = opposite_halfedge_handle(he12);

             if (ch0123.is_valid())
             {
                 HalfFaceHandle hf031 = adjacent_halfface_in_cell(hf132, he13);
                 HalfFaceHandle hf023 = adjacent_halfface_in_cell(hf132, he32);

                 replaceHalfEdge(hf031, he31, he41);
                 replaceHalfEdge(hf023, he23, he24);
                 replaceHalfFace(ch0123, hf132, hf142);
             }

             //copyHalfFaceAndHalfEdgeProperties(hf132, 142);

             incident_cell_per_hf_[hf142.idx()] = ch0123;


             deleteTagCells[ch.idx()] = true;
             deleteTagFaces[face_handle(hf132).idx()] = true;
             deleteTagFaces[face_handle(*hehf_it).idx()] = true;
             deleteTagEdges[edge_handle(he13).idx()] = true;
             deleteTagEdges[edge_handle(he32).idx()] = true;

             std::set<HalfFaceHandle> excludeFaces;
             excludeFaces.insert(hf134);
             excludeFaces.insert(hf143);
             excludeFaces.insert(hf123);
             excludeFaces.insert(hf132);
             excludeFaces.insert(hf243);
             excludeFaces.insert(hf234);

             std::vector<std::pair<HalfEdgeHandle, HalfEdgeHandle> > joinpartners;
             joinpartners.push_back(std::make_pair(he41, he31));
             joinpartners.push_back(std::make_pair(he14, he13));
             joinpartners.push_back(std::make_pair(he42, he32));
             joinpartners.push_back(std::make_pair(he24, he23));

             for (unsigned int i = 0; i < joinpartners.size(); ++i)
             {
                 HalfEdgeHandle target = joinpartners[i].first;
                 HalfEdgeHandle source = joinpartners[i].second;
                 std::vector<HalfFaceHandle> incidentHfs;
                 for (unsigned int j = 0; j < incident_hfs_per_he_[target.idx()].size(); ++j)
                 {
                     HalfFaceHandle cur_hf = incident_hfs_per_he_[target.idx()][j];
                     if ((excludeFaces.find(cur_hf) == excludeFaces.end()) && !deleteTagFaces[face_handle(cur_hf).idx()])
                         incidentHfs.push_back(cur_hf);
                 }
                 for (unsigned int i = 0; i < incident_hfs_per_he_[source.idx()].size(); ++i)
                 {
                     HalfFaceHandle cur_hf = incident_hfs_per_he_[source.idx()][i];
                     if ((excludeFaces.find(cur_hf) == excludeFaces.end()) && !deleteTagFaces[face_handle(cur_hf).idx()])
                         incidentHfs.push_back(cur_hf);
                 }

                 std::swap(incident_hfs_per_he_[target], incidentHfs);
             }

             std::vector<HalfFaceHandle>& vec = incident_hfs_per_he_[he21];
             vec.erase(std::remove(vec.begin(), vec.end(), hf132), vec.end());
             std::vector<HalfFaceHandle>& vec2 = incident_hfs_per_he_[he12];
             vec2.erase(std::remove(vec2.begin(), vec2.end(), hf123), vec2.end());

         }
         else
         {
             deleteTagFaces[face_handle(*hehf_it).idx()] = true;
         }
     }


     VertexHandle from_vh = halfedge(_heh).from_vertex();
     VertexHandle to_vh = halfedge(_heh).to_vertex();
     for (VertexOHalfEdgeIter voh_it = voh_iter(from_vh); voh_it.valid(); ++voh_it )
     {
         Edge he = halfedge(*voh_it);
         if (he.to_vertex() == to_vh)
         {
             std::vector<HalfEdgeHandle>& vec = outgoing_hes_per_vertex_[to_vh];
             vec.erase(std::remove(vec.begin(), vec.end(), opposite_halfedge_handle(*voh_it)), vec.end());
         }
         EdgeHandle eh = edge_handle(*voh_it);
         if (!deleteTagEdges[eh.idx()])
         {
             std::vector<HalfEdgeHandle>& vec = outgoing_hes_per_vertex_[to_vh];
             vec.push_back(opposite_halfedge_handle(*voh_it));

             Edge& e = edges_[eh.idx()];
             if (e.from_vertex() == from_vh)
                 e.set_from_vertex(to_vh);
             if (e.to_vertex() == from_vh)
                 e.set_to_vertex(to_vh);

         }
     }

     outgoing_hes_per_vertex_[from_vh].clear();

     deleteTagEdges[edge_handle(_heh).idx()] = true;

     delete_multiple_cells(deleteTagCells);
     delete_multiple_faces(deleteTagFaces);
     delete_multiple_edges(deleteTagEdges);
     delete_vertex(from_vh);
 }
 */


 //void TetrahedralMeshTopologyKernel::swapCellProperties(CellHandle source, CellHandle destination)
 //{
 //    swapPropertyElements(cell_props_begin(), cell_props_end(), source, destination);
 //}

 //void TetrahedralMeshTopologyKernel::swapHalfFaceProperties(HalfFaceHandle source, HalfFaceHandle destination)
 //{
 //    swapPropertyElements(halfface_props_begin(), halfface_props_end(), source, destination);
 //}

 //void TetrahedralMeshTopologyKernel::swapHalfEdgeProperties(HalfEdgeHandle source, HalfEdgeHandle destination)
 //{
 //    swapPropertyElements(halfedge_props_begin(), halfedge_props_end(), source, destination);
 //}

 VertexHandle TetrahedralMeshTopologyKernel::collapse_edge(HalfEdgeHandle _heh)
 {
     bool deferred_deletion_tmp = deferred_deletion_enabled();

     if (!deferred_deletion_tmp)
         enable_deferred_deletion(true);

     VertexHandle from_vh = halfedge(_heh).from_vertex();
     VertexHandle to_vh   = halfedge(_heh).to_vertex();


     // find cells that will collapse, i.e. are incident to the collapsing halfedge
     std::set<CellHandle> collapsingCells;
     for (HalfEdgeHalfFaceIter hehf_it = hehf_iter(_heh); hehf_it.valid(); ++hehf_it)
     {
         HalfFaceHandle hfh = *hehf_it;
         CellHandle ch = incident_cell(hfh);
         if (ch.is_valid())
             collapsingCells.insert(ch);
     }

     std::vector<CellHandle> incidentCells;
     for (VertexCellIter vc_it = vc_iter(from_vh); vc_it.valid(); ++vc_it)
         incidentCells.push_back(*vc_it);

     for (unsigned int i = 0; i < incidentCells.size(); ++i)
     {
         CellHandle ch = incidentCells[i];

         if (collapsingCells.find(ch) != collapsingCells.end())
             continue;

         Cell c = cell(ch);

         std::vector<HalfFaceHandle> newHalffaces;

         for (unsigned int i = 0; i < 4; ++i)
         {
             Face hf = halfface(c.halffaces()[i]);
             std::vector<HalfEdgeHandle> newHalfedges;

             for (unsigned int j = 0; j < 3; ++j)
             {
                 Edge e = halfedge(hf.halfedges()[j]);
                 VertexHandle newStart = (e.from_vertex() == from_vh) ? to_vh: e.from_vertex();
                 VertexHandle newEnd   = (e.to_vertex()   == from_vh) ? to_vh : e.to_vertex();

                 HalfEdgeHandle heh = add_halfedge(newStart, newEnd);
                 newHalfedges.push_back(heh);
                 swap_halfedge_properties(hf.halfedges()[j], heh);
             }

             HalfFaceHandle hfh = add_halfface(newHalfedges);
             newHalffaces.push_back(hfh);
             swap_halfface_properties(c.halffaces()[i], hfh);
         }

         delete_cell(ch);

         CellHandle newCell = add_cell(newHalffaces);

         swap_cell_properties(ch, newCell);

     }


     VertexHandle survivingVertex = to_vh;

     if (!deferred_deletion_tmp)
     {
         if (fast_deletion_enabled())
         {
             // from_vh is swapped with last vertex and then deleted
             if (to_vh.idx() == (int)n_vertices() - 1)
                 survivingVertex = from_vh;
         }
         else
         {
             // from_vh is deleted and every vertex id larger than from_vh is reduced by one
             if (from_vh.idx() < to_vh.idx())
                 survivingVertex = VertexHandle(to_vh.idx() - 1);
         }
     }

     delete_vertex(from_vh);

     enable_deferred_deletion(deferred_deletion_tmp);

     return survivingVertex;

 }

 void TetrahedralMeshTopologyKernel::split_edge(HalfEdgeHandle _heh, VertexHandle _vh)
 {
     bool deferred_deletion_tmp = deferred_deletion_enabled();

     if (!deferred_deletion_tmp)
         enable_deferred_deletion(true);

     for (HalfEdgeHalfFaceIter hehf_it = hehf_iter(_heh); hehf_it.valid(); ++hehf_it)
     {
         CellHandle ch = incident_cell(*hehf_it);
         if (ch.is_valid())
         {
             std::vector<VertexHandle> vertices = get_cell_vertices(*hehf_it, _heh);

             delete_cell(ch);

             add_cell(vertices[0], _vh, vertices[2], vertices[3]);
             add_cell(_vh, vertices[1], vertices[2], vertices[3]);
         }

     }

     delete_edge(edge_handle(_heh));

     enable_deferred_deletion(deferred_deletion_tmp);

 }

 void TetrahedralMeshTopologyKernel::split_face(FaceHandle _fh, VertexHandle _vh)
 {
     bool deferred_deletion_tmp = deferred_deletion_enabled();

     if (!deferred_deletion_tmp)
         enable_deferred_deletion(true);

     for (unsigned int i = 0; i < 2; ++i)
     {
         HalfFaceHandle hfh = halfface_handle(_fh, i);
         CellHandle ch = incident_cell(hfh);
         if (ch.is_valid())
         {
             std::vector<VertexHandle> vertices = get_cell_vertices(hfh);

             delete_cell(ch);

             add_cell(vertices[0], vertices[1], _vh, vertices[3]);
             add_cell(vertices[0], _vh, vertices[2], vertices[3]);
             add_cell(_vh, vertices[1], vertices[2], vertices[3]);
         }
     }

     delete_face(_fh);

     enable_deferred_deletion(deferred_deletion_tmp);

 }


 std::vector<VertexHandle> TetrahedralMeshTopologyKernel::get_cell_vertices(CellHandle ch) const
 {
     return get_cell_vertices(cell(ch).halffaces().front());
 }

 std::vector<VertexHandle> TetrahedralMeshTopologyKernel::get_cell_vertices(CellHandle ch, VertexHandle vh) const
 {
     HalfFaceHandle hfh = cell(ch).halffaces()[0];
     Face f = halfface(hfh);
     HalfEdgeHandle heh;
     for (unsigned int i = 0; i < 3; ++i)
     {
         Edge e = halfedge(f.halfedges()[i]);
         if (e.from_vertex() == vh)
         {
             heh = f.halfedges()[i];
             break;
         }
     }
     if (!heh.is_valid())
     {
         hfh = adjacent_halfface_in_cell(hfh, f.halfedges()[0]);
         heh = prev_halfedge_in_halfface(opposite_halfedge_handle(f.halfedges()[0]), hfh);
     }

     return get_cell_vertices(hfh,heh);

 }

 std::vector<VertexHandle> TetrahedralMeshTopologyKernel::get_cell_vertices(HalfFaceHandle hfh) const
 {
     return get_cell_vertices(hfh, halfface(hfh).halfedges().front());
 }

 std::vector<VertexHandle> TetrahedralMeshTopologyKernel::get_cell_vertices(HalfFaceHandle hfh, HalfEdgeHandle heh) const
 {
     std::vector<VertexHandle> vertices;

     // add vertices of halfface
     for (unsigned int i = 0; i < 3; ++i)
     {
         Edge e = halfedge(heh);
         vertices.push_back(e.from_vertex());
         heh = next_halfedge_in_halfface(heh, hfh);
     }

     Cell c = cell(incident_cell(hfh));
     HalfFaceHandle otherHfh = c.halffaces()[0];
     if (otherHfh == hfh)
         otherHfh = c.halffaces()[1];

     Face otherF = halfface(otherHfh);

     for (unsigned int i = 0; i < otherF.halfedges().size(); ++i)
     {
         HalfEdgeHandle he = otherF.halfedges()[i];
         Edge e = halfedge(he);
         if (std::find(vertices.begin(), vertices.end(), e.to_vertex()) == vertices.end())
         {
             vertices.push_back(e.to_vertex());
             return vertices;
         }
     }

     return vertices;
 }

 std::vector<VertexHandle> TetrahedralMeshTopologyKernel::get_halfface_vertices(HalfFaceHandle hfh) const
 {
     return get_halfface_vertices(hfh, halfface(hfh).halfedges().front());
 }

 std::vector<VertexHandle> TetrahedralMeshTopologyKernel::get_halfface_vertices(HalfFaceHandle hfh, VertexHandle vh) const
 {
     Face hf = halfface(hfh);
     for (unsigned int i = 0; i < 3; ++i)
         if (halfedge(hf.halfedges()[i]).from_vertex() == vh)
             return get_halfface_vertices(hfh, hf.halfedges()[i]);

     return std::vector<VertexHandle>();
 }

 std::vector<VertexHandle> TetrahedralMeshTopologyKernel::get_halfface_vertices(HalfFaceHandle hfh, HalfEdgeHandle heh) const
 {
     std::vector<VertexHandle> vertices;

     // add vertices of halfface
     for (unsigned int i = 0; i < 3; ++i)
     {
         Edge e = halfedge(heh);
         vertices.push_back(e.from_vertex());
         heh = next_halfedge_in_halfface(heh, hfh);
     }

     return vertices;
 }


 //========================================================================================

 CellHandle
 TetrahedralMeshTopologyKernel::add_cell(const std::vector<VertexHandle>& _vertices, bool _topologyCheck) {

     // debug mode checks
     assert(TopologyKernel::has_full_bottom_up_incidences());
     assert(_vertices.size() == 4);

     // release mode checks
     if(!TopologyKernel::has_full_bottom_up_incidences()) {
         return CellHandle(-1);
     }

     if(_vertices.size() != 4) {
         return CellHandle(-1);
     }

     HalfFaceHandle hf0, hf1, hf2, hf3;

     std::vector<VertexHandle> vs;

     vs.push_back(_vertices[0]);
     vs.push_back(_vertices[1]);
     vs.push_back(_vertices[2]);
     hf0 = TopologyKernel::halfface(vs);
     if(!hf0.is_valid()) {
         FaceHandle fh = TopologyKernel::add_face(vs);
         hf0 = halfface_handle(fh, 0);
     }
     vs.clear();

     vs.push_back(_vertices[0]);
     vs.push_back(_vertices[2]);
     vs.push_back(_vertices[3]);
     hf1 = TopologyKernel::halfface(vs);
     if(!hf1.is_valid()) {
         FaceHandle fh = TopologyKernel::add_face(vs);
         hf1 = halfface_handle(fh, 0);
     }
     vs.clear();

     vs.push_back(_vertices[0]);
     vs.push_back(_vertices[3]);
     vs.push_back(_vertices[1]);
     hf2 = TopologyKernel::halfface(vs);
     if(!hf2.is_valid()) {
         FaceHandle fh = TopologyKernel::add_face(vs);
         hf2 = halfface_handle(fh, 0);
     }
     vs.clear();

     vs.push_back(_vertices[1]);
     vs.push_back(_vertices[3]);
     vs.push_back(_vertices[2]);
     hf3 = TopologyKernel::halfface(vs);
     if(!hf3.is_valid()) {
         FaceHandle fh = TopologyKernel::add_face(vs);
         hf3 = halfface_handle(fh, 0);
     }
     vs.clear();

     assert(hf0.is_valid());
     assert(hf1.is_valid());
     assert(hf2.is_valid());
     assert(hf3.is_valid());


     std::vector<HalfFaceHandle> hfs;
     hfs.push_back(hf0);
     hfs.push_back(hf1);
     hfs.push_back(hf2);
     hfs.push_back(hf3);

     if (_topologyCheck) {
         /*
         * Test if all halffaces are connected and form a two-manifold
         * => Cell is closed
         *
         * This test is simple: The number of involved half-edges has to be
         * exactly twice the number of involved edges.
         */

         std::set<HalfEdgeHandle> incidentHalfedges;
         std::set<EdgeHandle>     incidentEdges;

         for(std::vector<HalfFaceHandle>::const_iterator it = hfs.begin(),
                 end = hfs.end(); it != end; ++it) {

             OpenVolumeMeshFace hface = halfface(*it);
             for(std::vector<HalfEdgeHandle>::const_iterator he_it = hface.halfedges().begin(),
                     he_end = hface.halfedges().end(); he_it != he_end; ++he_it) {
                 incidentHalfedges.insert(*he_it);
                 incidentEdges.insert(edge_handle(*he_it));
             }
         }

         if(incidentHalfedges.size() != (incidentEdges.size() * 2u)) {
 #ifndef NDEBUG
             std::cerr << "The specified halffaces are not connected!" << std::endl;
 #endif
             return InvalidCellHandle;
         }
         // The halffaces are now guaranteed to form a two-manifold

         if(has_face_bottom_up_incidences()) {

             for(std::vector<HalfFaceHandle>::const_iterator it = hfs.begin(),
                     end = hfs.end(); it != end; ++it) {
                 if(incident_cell(*it) != InvalidCellHandle) {
 #ifndef NDEBUG
                     std::cerr << "Warning: One of the specified half-faces is already incident to another cell!" << std::endl;
 #endif
                     return InvalidCellHandle;
                 }
             }

         }

     }

     return TopologyKernel::add_cell(hfs, false);
 }

 CellHandle TetrahedralMeshTopologyKernel::add_cell(VertexHandle _vh0, VertexHandle _vh1, VertexHandle _vh2, VertexHandle _vh3, bool _topologyCheck)
 {
     std::vector<HalfFaceHandle> halffaces;
     halffaces.push_back(add_halfface(_vh0, _vh1, _vh2));
     halffaces.push_back(add_halfface(_vh0, _vh2, _vh3));
     halffaces.push_back(add_halfface(_vh0, _vh3, _vh1));
     halffaces.push_back(add_halfface(_vh1, _vh3, _vh2));
     return add_cell(halffaces, _topologyCheck);
 }

 //========================================================================================

 } // Namespace OpenVolumeMesh
OpenVolumeMesh::TopologyKernel::halfedge
Edge halfedge(const HalfEdgeHandle &_halfEdgeHandle) const
Get edge that corresponds to halfedge with handle _halfEdgeHandle.
Definition: TopologyKernel.cc:2054

OpenVolumeMesh::TopologyKernel::delete_vertex
virtual VertexIter delete_vertex(const VertexHandle &_h)
Delete vertex from mesh.
Definition: TopologyKernel.cc:593

OpenVolumeMesh::OpenVolumeMeshFace
Definition: BaseEntities.hh:90

OpenVolumeMesh::VertexCellIter
Definition: Iterators.hh:334

OpenVolumeMesh::TetrahedralMeshTopologyKernel::add_face
virtual FaceHandle add_face(const std::vector< HalfEdgeHandle > &_halfedges, bool _topologyCheck=false)
Add face via incident edges.
Definition: TetrahedralMeshTopologyKernel.cc:64

OpenVolumeMesh::VertexHandle
Definition: OpenVolumeMeshHandle.hh:98

OpenVolumeMesh::FaceHandle
Definition: OpenVolumeMeshHandle.hh:100

OpenVolumeMesh::TopologyKernel::prev_halfedge_in_halfface
HalfEdgeHandle prev_halfedge_in_halfface(const HalfEdgeHandle &_heh, const HalfFaceHandle &_hfh) const
Get previous halfedge within a halfface.
Definition: TopologyKernel.cc:2245

OpenVolumeMesh
Definition: ColorAttrib.hh:53

OpenVolumeMesh::TopologyKernel::add_cell
virtual CellHandle add_cell(const std::vector< HalfFaceHandle > &_halffaces, bool _topologyCheck=false)
Add cell via incident halffaces.
Definition: TopologyKernel.cc:379

OpenVolumeMesh::TopologyKernel::delete_cell
virtual CellIter delete_cell(const CellHandle &_h)
Delete cell from mesh.
Definition: TopologyKernel.cc:713

OpenVolumeMesh::CellHandle
Definition: OpenVolumeMeshHandle.hh:101

OpenVolumeMesh::TopologyKernel::halfface_handle
static HalfFaceHandle halfface_handle(const FaceHandle &_h, const unsigned char _subIdx)
Conversion function.
Definition: TopologyKernel.hh:881

OpenVolumeMesh::TopologyKernel::add_edge
virtual EdgeHandle add_edge(const VertexHandle &_fromVertex, const VertexHandle &_toHandle, bool _allowDuplicates=false)
Add edge.
Definition: TopologyKernel.cc:97

OpenVolumeMesh::TopologyKernel::cell
const Cell & cell(const CellHandle &_cellHandle) const
Get cell with handle _cellHandle.
Definition: TopologyKernel.cc:2008

OpenVolumeMesh::OpenVolumeMeshEdge
Definition: BaseEntities.hh:52

OpenVolumeMesh::TetrahedralMeshTopologyKernel::add_cell
virtual CellHandle add_cell(const std::vector< HalfFaceHandle > &_halffaces, bool _topologyCheck=false)
Add cell via incident halffaces.
Definition: TetrahedralMeshTopologyKernel.cc:98

OpenVolumeMesh::TopologyKernel::incident_cell
CellHandle incident_cell(const HalfFaceHandle &_halfFaceHandle) const
Get cell that is incident to the given halfface.
Definition: TopologyKernel.cc:2309

OpenVolumeMesh::TopologyKernel::halfedge_handle
static HalfEdgeHandle halfedge_handle(const EdgeHandle &_h, const unsigned char _subIdx)
Conversion function.
Definition: TopologyKernel.hh:872

OpenVolumeMesh::TopologyKernel::edge_handle
static EdgeHandle edge_handle(const HalfEdgeHandle &_h)
Handle conversion.
Definition: TopologyKernel.hh:890

OpenVolumeMesh::HalfFaceHandle
Definition: OpenVolumeMeshHandle.hh:103

OpenVolumeMesh::TopologyKernel::halfface
Face halfface(const HalfFaceHandle &_halfFaceHandle) const
Get face that corresponds to halfface with handle _halfFaceHandle.
Definition: TopologyKernel.cc:2071

OpenVolumeMesh::TopologyKernel::n_vertices
virtual size_t n_vertices() const
Get number of vertices in mesh.
Definition: TopologyKernel.hh:302

OpenVolumeMesh::HalfEdgeHalfFaceIter
Definition: Iterators.hh:276

OpenVolumeMesh::OpenVolumeMeshCell
Definition: BaseEntities.hh:119

OpenVolumeMesh::TopologyKernel::add_face
virtual FaceHandle add_face(const std::vector< HalfEdgeHandle > &_halfedges, bool _topologyCheck=false)
Add face via incident edges.
Definition: TopologyKernel.cc:162

OpenVolumeMesh::TopologyKernel::delete_edge
virtual EdgeIter delete_edge(const EdgeHandle &_h)
Delete edge from mesh.
Definition: TopologyKernel.cc:643

OpenVolumeMesh::TopologyKernel::adjacent_halfface_in_cell
HalfFaceHandle adjacent_halfface_in_cell(const HalfFaceHandle &_halfFaceHandle, const HalfEdgeHandle &_halfEdgeHandle) const
Get halfface that is adjacent (w.r.t. a common halfedge) within the same cell.
Definition: TopologyKernel.cc:2266

OpenVolumeMesh::TopologyKernel::delete_face
virtual FaceIter delete_face(const FaceHandle &_h)
Delete face from mesh.
Definition: TopologyKernel.cc:684

OpenVolumeMesh::TopologyKernel::next_halfedge_in_halfface
HalfEdgeHandle next_halfedge_in_halfface(const HalfEdgeHandle &_heh, const HalfFaceHandle &_hfh) const
Get next halfedge within a halfface.
Definition: TopologyKernel.cc:2225

OpenVolumeMesh::HalfEdgeHandle
Definition: OpenVolumeMeshHandle.hh:102