-// static bool writeGMFFile(const char* theMeshFileName,
-// const char* theRequiredFileName,
-// const char* theSolFileName,
-// SMESH_MesherHelper& theHelper,
-// const SMESH_ProxyMesh& theProxyMesh,
-// std::map <int,int> & theNodeId2NodeIndexMap,
-// std::map <int,int> & theSmdsToHybridIdMap,
-// std::map <int,const SMDS_MeshNode*> & theHybridIdToNodeMap,
-// TIDSortedNodeSet & theEnforcedNodes,
-// TIDSortedElemSet & theEnforcedEdges,
-// TIDSortedElemSet & theEnforcedTriangles,
-// // TIDSortedElemSet & theEnforcedQuadrangles,
-// HYBRIDPlugin_Hypothesis::THYBRIDEnforcedVertexCoordsValues & theEnforcedVertices)
-// {
-// MESSAGE("writeGMFFile with geometry");
-// int idx, idxRequired, idxSol;
-// int nbv, nbev, nben, aHybridID = 0;
-// const int dummyint = 0;
-// HYBRIDPlugin_Hypothesis::THYBRIDEnforcedVertexCoordsValues::const_iterator vertexIt;
-// std::vector<double> enfVertexSizes;
-// TIDSortedNodeSet::const_iterator enfNodeIt;
-// const SMDS_MeshNode* node;
-// SMDS_NodeIteratorPtr nodeIt;
-//
-// idx = GmfOpenMesh(theMeshFileName, GmfWrite, GMFVERSION, GMFDIMENSION);
-// if (!idx)
-// return false;
-//
-// SMESHDS_Mesh * theMeshDS = theHelper.GetMeshDS();
-//
-// /* ========================== NODES ========================== */
-// // NB_NODES
-// nbv = theMeshDS->NbNodes();
-// if ( nbv == 0 )
-// return false;
-// nbev = theEnforcedVertices.size();
-// nben = theEnforcedNodes.size();
-//
-// // Issue 020674: EDF 870 SMESH: Mesh generated by Netgen not usable by HYBRID
-// // The problem is in nodes on degenerated edges, we need to skip nodes which are free
-// // and replace not-free nodes on edges by the node on vertex
-// TNodeNodeMap n2nDegen; // map a node on degenerated edge to a node on vertex
-// TNodeNodeMap::iterator n2nDegenIt;
-// if ( theHelper.HasDegeneratedEdges() )
-// {
-// set<int> checkedSM;
-// for (TopExp_Explorer e(theMeshDS->ShapeToMesh(), TopAbs_EDGE ); e.More(); e.Next())
-// {
-// SMESH_subMesh* sm = theHelper.GetMesh()->GetSubMesh( e.Current() );
-// if ( checkedSM.insert( sm->GetId() ).second && theHelper.IsDegenShape(sm->GetId() ))
-// {
-// if ( SMESHDS_SubMesh* smDS = sm->GetSubMeshDS() )
-// {
-// TopoDS_Shape vertex = TopoDS_Iterator( e.Current() ).Value();
-// const SMDS_MeshNode* vNode = SMESH_Algo::VertexNode( TopoDS::Vertex( vertex ), theMeshDS);
-// {
-// SMDS_NodeIteratorPtr nIt = smDS->GetNodes();
-// while ( nIt->more() )
-// n2nDegen.insert( std::make_pair( nIt->next(), vNode ));
-// }
-// }
-// }
-// }
-// }
-//
-// const bool isQuadMesh =
-// theHelper.GetMesh()->NbEdges( ORDER_QUADRATIC ) ||
-// theHelper.GetMesh()->NbFaces( ORDER_QUADRATIC ) ||
-// theHelper.GetMesh()->NbVolumes( ORDER_QUADRATIC );
-//
-// std::vector<std::vector<double> > VerTab;
-// std::set<std::vector<double> > VerMap;
-// VerTab.clear();
-// std::vector<double> aVerTab;
-// // Loop from 1 to NB_NODES
-//
-// nodeIt = theMeshDS->nodesIterator();
-//
-// while ( nodeIt->more() )
-// {
-// node = nodeIt->next();
-// if ( isQuadMesh && theHelper.IsMedium( node )) // Issue 0021238
-// continue;
-// if ( n2nDegen.count( node ) ) // Issue 0020674
-// continue;
-//
-// std::vector<double> coords;
-// coords.push_back(node->X());
-// coords.push_back(node->Y());
-// coords.push_back(node->Z());
-// if (VerMap.find(coords) != VerMap.end()) {
-// aHybridID = theSmdsToHybridIdMap[node->GetID()];
-// theHybridIdToNodeMap[theSmdsToHybridIdMap[node->GetID()]] = node;
-// continue;
-// }
-// VerTab.push_back(coords);
-// VerMap.insert(coords);
-// aHybridID++;
-// theSmdsToHybridIdMap.insert( std::make_pair( node->GetID(), aHybridID ));
-// theHybridIdToNodeMap.insert( std::make_pair( aHybridID, node ));
-// }
-//
-//
-// /* ENFORCED NODES ========================== */
-// if (nben) {
-// std::cout << "Add " << nben << " enforced nodes to input .mesh file" << std::endl;
-// for(enfNodeIt = theEnforcedNodes.begin() ; enfNodeIt != theEnforcedNodes.end() ; ++enfNodeIt) {
-// double x = (*enfNodeIt)->X();
-// double y = (*enfNodeIt)->Y();
-// double z = (*enfNodeIt)->Z();
-// // Test if point is inside shape to mesh
-// gp_Pnt myPoint(x,y,z);
-// BRepClass3d_SolidClassifier scl(theMeshDS->ShapeToMesh());
-// scl.Perform(myPoint, 1e-7);
-// TopAbs_State result = scl.State();
-// if ( result != TopAbs_IN )
-// continue;
-// std::vector<double> coords;
-// coords.push_back(x);
-// coords.push_back(y);
-// coords.push_back(z);
-// if (theEnforcedVertices.find(coords) != theEnforcedVertices.end())
-// continue;
-// if (VerMap.find(coords) != VerMap.end())
-// continue;
-// VerTab.push_back(coords);
-// VerMap.insert(coords);
-// aHybridID++;
-// theNodeId2NodeIndexMap.insert( std::make_pair( (*enfNodeIt)->GetID(), aHybridID ));
-// }
-// }
-//
-//
-// /* ENFORCED VERTICES ========================== */
-// int solSize = 0;
-// std::vector<std::vector<double> > ReqVerTab;
-// ReqVerTab.clear();
-// if (nbev) {
-// std::cout << "Add " << nbev << " enforced vertices to input .mesh file" << std::endl;
-// for(vertexIt = theEnforcedVertices.begin() ; vertexIt != theEnforcedVertices.end() ; ++vertexIt) {
-// double x = vertexIt->first[0];
-// double y = vertexIt->first[1];
-// double z = vertexIt->first[2];
-// // Test if point is inside shape to mesh
-// gp_Pnt myPoint(x,y,z);
-// BRepClass3d_SolidClassifier scl(theMeshDS->ShapeToMesh());
-// scl.Perform(myPoint, 1e-7);
-// TopAbs_State result = scl.State();
-// if ( result != TopAbs_IN )
-// continue;
-// enfVertexSizes.push_back(vertexIt->second);
-// std::vector<double> coords;
-// coords.push_back(x);
-// coords.push_back(y);
-// coords.push_back(z);
-// if (VerMap.find(coords) != VerMap.end())
-// continue;
-// ReqVerTab.push_back(coords);
-// VerMap.insert(coords);
-// solSize++;
-// }
-// }
-//
-//
-// /* ========================== FACES ========================== */
-//
-// int nbTriangles = 0/*, nbQuadrangles = 0*/, aSmdsID;
-// TopTools_IndexedMapOfShape facesMap, trianglesMap/*, quadranglesMap*/;
-// TIDSortedElemSet::const_iterator elemIt;
-// const SMESHDS_SubMesh* theSubMesh;
-// TopoDS_Shape aShape;
-// SMDS_ElemIteratorPtr itOnSubMesh, itOnSubFace;
-// const SMDS_MeshElement* aFace;
-// map<int,int>::const_iterator itOnMap;
-// std::vector<std::vector<int> > tt, qt,et;
-// tt.clear();
-// qt.clear();
-// et.clear();
-// std::vector<int> att, aqt, aet;
-//
-// TopExp::MapShapes( theMeshDS->ShapeToMesh(), TopAbs_FACE, facesMap );
-//
-// for ( int i = 1; i <= facesMap.Extent(); ++i )
-// if (( theSubMesh = theProxyMesh.GetSubMesh( facesMap(i))))
-// {
-// SMDS_ElemIteratorPtr it = theSubMesh->GetElements();
-// while (it->more())
-// {
-// const SMDS_MeshElement *elem = it->next();
-// int nbCornerNodes = elem->NbCornerNodes();
-// if (nbCornerNodes == 3)
-// {
-// trianglesMap.Add(facesMap(i));
-// nbTriangles ++;
-// }
-// // else if (nbCornerNodes == 4)
-// // {
-// // quadranglesMap.Add(facesMap(i));
-// // nbQuadrangles ++;
-// // }
-// }
-// }
-//
-// /* TRIANGLES ========================== */
-// if (nbTriangles) {
-// for ( int i = 1; i <= trianglesMap.Extent(); i++ )
-// {
-// aShape = trianglesMap(i);
-// theSubMesh = theProxyMesh.GetSubMesh(aShape);
-// if ( !theSubMesh ) continue;
-// itOnSubMesh = theSubMesh->GetElements();
-// while ( itOnSubMesh->more() )
-// {
-// aFace = itOnSubMesh->next();
-// itOnSubFace = aFace->nodesIterator();
-// att.clear();
-// for ( int j = 0; j < 3; ++j ) {
-// // find HYBRID ID
-// node = castToNode( itOnSubFace->next() );
-// if (( n2nDegenIt = n2nDegen.find( node )) != n2nDegen.end() )
-// node = n2nDegenIt->second;
-// aSmdsID = node->GetID();
-// itOnMap = theSmdsToHybridIdMap.find( aSmdsID );
-// ASSERT( itOnMap != theSmdsToHybridIdMap.end() );
-// att.push_back((*itOnMap).second);
-// }
-// tt.push_back(att);
-// }
-// }
-// }
-//
-// if (theEnforcedTriangles.size()) {
-// std::cout << "Add " << theEnforcedTriangles.size() << " enforced triangles to input .mesh file" << std::endl;
-// // Iterate over the enforced triangles
-// for(elemIt = theEnforcedTriangles.begin() ; elemIt != theEnforcedTriangles.end() ; ++elemIt) {
-// aFace = (*elemIt);
-// itOnSubFace = aFace->nodesIterator();
-// bool isOK = true;
-// att.clear();
-//
-// for ( int j = 0; j < 3; ++j ) {
-// node = castToNode( itOnSubFace->next() );
-// if (( n2nDegenIt = n2nDegen.find( node )) != n2nDegen.end() )
-// node = n2nDegenIt->second;
-// // std::cout << node;
-// double x = node->X();
-// double y = node->Y();
-// double z = node->Z();
-// // Test if point is inside shape to mesh
-// gp_Pnt myPoint(x,y,z);
-// BRepClass3d_SolidClassifier scl(theMeshDS->ShapeToMesh());
-// scl.Perform(myPoint, 1e-7);
-// TopAbs_State result = scl.State();
-// if ( result != TopAbs_IN ) {
-// isOK = false;
-// theEnforcedTriangles.erase(elemIt);
-// continue;
-// }
-// std::vector<double> coords;
-// coords.push_back(x);
-// coords.push_back(y);
-// coords.push_back(z);
-// if (VerMap.find(coords) != VerMap.end()) {
-// att.push_back(theNodeId2NodeIndexMap[node->GetID()]);
-// continue;
-// }
-// VerTab.push_back(coords);
-// VerMap.insert(coords);
-// aHybridID++;
-// theNodeId2NodeIndexMap.insert( std::make_pair( node->GetID(), aHybridID ));
-// att.push_back(aHybridID);
-// }
-// if (isOK)
-// tt.push_back(att);
-// }
-// }
-//
-//
-// /* ========================== EDGES ========================== */
-//
-// if (theEnforcedEdges.size()) {
-// // Iterate over the enforced edges
-// std::cout << "Add " << theEnforcedEdges.size() << " enforced edges to input .mesh file" << std::endl;
-// for(elemIt = theEnforcedEdges.begin() ; elemIt != theEnforcedEdges.end() ; ++elemIt) {
-// aFace = (*elemIt);
-// bool isOK = true;
-// itOnSubFace = aFace->nodesIterator();
-// aet.clear();
-// for ( int j = 0; j < 2; ++j ) {
-// node = castToNode( itOnSubFace->next() );
-// if (( n2nDegenIt = n2nDegen.find( node )) != n2nDegen.end() )
-// node = n2nDegenIt->second;
-// double x = node->X();
-// double y = node->Y();
-// double z = node->Z();
-// // Test if point is inside shape to mesh
-// gp_Pnt myPoint(x,y,z);
-// BRepClass3d_SolidClassifier scl(theMeshDS->ShapeToMesh());
-// scl.Perform(myPoint, 1e-7);
-// TopAbs_State result = scl.State();
-// if ( result != TopAbs_IN ) {
-// isOK = false;
-// theEnforcedEdges.erase(elemIt);
-// continue;
-// }
-// std::vector<double> coords;
-// coords.push_back(x);
-// coords.push_back(y);
-// coords.push_back(z);
-// if (VerMap.find(coords) != VerMap.end()) {
-// aet.push_back(theNodeId2NodeIndexMap[node->GetID()]);
-// continue;
-// }
-// VerTab.push_back(coords);
-// VerMap.insert(coords);
-//
-// aHybridID++;
-// theNodeId2NodeIndexMap.insert( std::make_pair( node->GetID(), aHybridID ));
-// aet.push_back(aHybridID);
-// }
-// if (isOK)
-// et.push_back(aet);
-// }
-// }
-//
-//
-// /* Write vertices number */
-// MESSAGE("Number of vertices: "<<aHybridID);
-// MESSAGE("Size of vector: "<<VerTab.size());
-// GmfSetKwd(idx, GmfVertices, aHybridID/*+solSize*/);
-// for (int i=0;i<aHybridID;i++)
-// GmfSetLin(idx, GmfVertices, VerTab[i][0], VerTab[i][1], VerTab[i][2], dummyint);
-// // for (int i=0;i<solSize;i++) {
-// // std::cout << ReqVerTab[i][0] <<" "<< ReqVerTab[i][1] << " "<< ReqVerTab[i][2] << std::endl;
-// // GmfSetLin(idx, GmfVertices, ReqVerTab[i][0], ReqVerTab[i][1], ReqVerTab[i][2], dummyint);
-// // }
-//
-// if (solSize) {
-// idxRequired = GmfOpenMesh(theRequiredFileName, GmfWrite, GMFVERSION, GMFDIMENSION);
-// if (!idxRequired) {
-// GmfCloseMesh(idx);
-// return false;
-// }
-// idxSol = GmfOpenMesh(theSolFileName, GmfWrite, GMFVERSION, GMFDIMENSION);
-// if (!idxSol){
-// GmfCloseMesh(idx);
-// if (idxRequired)
-// GmfCloseMesh(idxRequired);
-// return false;
-// }
-//
-// int TypTab[] = {GmfSca};
-// GmfSetKwd(idxRequired, GmfVertices, solSize);
-// GmfSetKwd(idxSol, GmfSolAtVertices, solSize, 1, TypTab);
-//
-// for (int i=0;i<solSize;i++) {
-// double solTab[] = {enfVertexSizes.at(i)};
-// GmfSetLin(idxRequired, GmfVertices, ReqVerTab[i][0], ReqVerTab[i][1], ReqVerTab[i][2], dummyint);
-// GmfSetLin(idxSol, GmfSolAtVertices, solTab);
-// }
-// GmfCloseMesh(idxRequired);
-// GmfCloseMesh(idxSol);
-// }
-//
-// /* Write triangles number */
-// if (tt.size()) {
-// GmfSetKwd(idx, GmfTriangles, tt.size());
-// for (int i=0;i<tt.size();i++)
-// GmfSetLin(idx, GmfTriangles, tt[i][0], tt[i][1], tt[i][2], dummyint);
-// }
-//
-// /* Write edges number */
-// if (et.size()) {
-// GmfSetKwd(idx, GmfEdges, et.size());
-// for (int i=0;i<et.size();i++)
-// GmfSetLin(idx, GmfEdges, et[i][0], et[i][1], dummyint);
-// }
-//
-// /* QUADRANGLES ========================== */
-// // TODO: add pyramids ?
-// // if (nbQuadrangles) {
-// // for ( int i = 1; i <= quadranglesMap.Extent(); i++ )
-// // {
-// // aShape = quadranglesMap(i);
-// // theSubMesh = theProxyMesh.GetSubMesh(aShape);
-// // if ( !theSubMesh ) continue;
-// // itOnSubMesh = theSubMesh->GetElements();
-// // for ( int j = 0; j < 4; ++j )
-// // {
-// // aFace = itOnSubMesh->next();
-// // itOnSubFace = aFace->nodesIterator();
-// // aqt.clear();
-// // while ( itOnSubFace->more() ) {
-// // // find HYBRID ID
-// // aSmdsID = itOnSubFace->next()->GetID();
-// // itOnMap = theSmdsToHybridIdMap.find( aSmdsID );
-// // ASSERT( itOnMap != theSmdsToHybridIdMap.end() );
-// // aqt.push_back((*itOnMap).second);
-// // }
-// // qt.push_back(aqt);
-// // }
-// // }
-// // }
-// //
-// // if (theEnforcedQuadrangles.size()) {
-// // // Iterate over the enforced triangles
-// // for(elemIt = theEnforcedQuadrangles.begin() ; elemIt != theEnforcedQuadrangles.end() ; ++elemIt) {
-// // aFace = (*elemIt);
-// // bool isOK = true;
-// // itOnSubFace = aFace->nodesIterator();
-// // aqt.clear();
-// // for ( int j = 0; j < 4; ++j ) {
-// // int aNodeID = itOnSubFace->next()->GetID();
-// // itOnMap = theNodeId2NodeIndexMap.find(aNodeID);
-// // if (itOnMap != theNodeId2NodeIndexMap.end())
-// // aqt.push_back((*itOnMap).second);
-// // else {
-// // isOK = false;
-// // theEnforcedQuadrangles.erase(elemIt);
-// // break;
-// // }
-// // }
-// // if (isOK)
-// // qt.push_back(aqt);
-// // }
-// // }
-// //
-//
-// // /* Write quadrilaterals number */
-// // if (qt.size()) {
-// // GmfSetKwd(idx, GmfQuadrilaterals, qt.size());
-// // for (int i=0;i<qt.size();i++)
-// // GmfSetLin(idx, GmfQuadrilaterals, qt[i][0], qt[i][1], qt[i][2], qt[i][3], dummyint);
-// // }
-//
-// GmfCloseMesh(idx);
-// return true;
-// }
-
-
-//=======================================================================
-//function : writeFaces
-//purpose :
-//=======================================================================
-
-// static bool writeFaces (ofstream & theFile,
-// const SMESH_ProxyMesh& theMesh,
-// const TopoDS_Shape& theShape,
-// const std::map <int,int> & theSmdsToHybridIdMap,
-// const std::map <int,int> & theEnforcedNodeIdToHybridIdMap,
-// HYBRIDPlugin_Hypothesis::TIDSortedElemGroupMap & theEnforcedEdges,
-// HYBRIDPlugin_Hypothesis::TIDSortedElemGroupMap & theEnforcedTriangles)
-// {
-// // record structure:
-// //
-// // NB_ELEMS DUMMY_INT
-// // Loop from 1 to NB_ELEMS
-// // NB_NODES NODE_NB_1 NODE_NB_2 ... (NB_NODES + 1) times: DUMMY_INT
-
-// TopoDS_Shape aShape;
-// const SMESHDS_SubMesh* theSubMesh;
-// const SMDS_MeshElement* aFace;
-// const char* space = " ";
-// const int dummyint = 0;
-// std::map<int,int>::const_iterator itOnMap;
-// SMDS_ElemIteratorPtr itOnSubMesh, itOnSubFace;
-// int nbNodes, aSmdsID;
-
-// TIDSortedElemSet::const_iterator elemIt;
-// int nbEnforcedEdges = theEnforcedEdges.size();
-// int nbEnforcedTriangles = theEnforcedTriangles.size();
-
-// // count triangles bound to geometry
-// int nbTriangles = 0;
-
-// TopTools_IndexedMapOfShape facesMap, trianglesMap;
-// TopExp::MapShapes( theShape, TopAbs_FACE, facesMap );
-
-// int nbFaces = facesMap.Extent();
-
-// for ( int i = 1; i <= nbFaces; ++i )
-// if (( theSubMesh = theMesh.GetSubMesh( facesMap(i))))
-// nbTriangles += theSubMesh->NbElements();
-// std::string tmpStr;
-// (nbFaces == 0 || nbFaces == 1) ? tmpStr = " shape " : tmpStr = " shapes " ;
-// std::cout << " " << nbFaces << tmpStr << "of 2D dimension";
-// int nbEnforcedElements = nbEnforcedEdges+nbEnforcedTriangles;
-// if (nbEnforcedElements > 0) {
-// (nbEnforcedElements == 1) ? tmpStr = "shape:" : tmpStr = "shapes:";
-// std::cout << " and" << std::endl;
-// std::cout << " " << nbEnforcedElements
-// << " enforced " << tmpStr << std::endl;
-// }
-// else
-// std::cout << std::endl;
-// if (nbEnforcedEdges) {
-// (nbEnforcedEdges == 1) ? tmpStr = "edge" : tmpStr = "edges";
-// std::cout << " " << nbEnforcedEdges << " enforced " << tmpStr << std::endl;
-// }
-// if (nbEnforcedTriangles) {
-// (nbEnforcedTriangles == 1) ? tmpStr = "triangle" : tmpStr = "triangles";
-// std::cout << " " << nbEnforcedTriangles << " enforced " << tmpStr << std::endl;
-// }
-// std::cout << std::endl;
-
-// // theFile << space << nbTriangles << space << dummyint << std::endl;
-// std::ostringstream globalStream, localStream, aStream;
-
-// for ( int i = 1; i <= facesMap.Extent(); i++ )
-// {
-// aShape = facesMap(i);
-// theSubMesh = theMesh.GetSubMesh(aShape);
-// if ( !theSubMesh ) continue;
-// itOnSubMesh = theSubMesh->GetElements();
-// while ( itOnSubMesh->more() )
-// {
-// aFace = itOnSubMesh->next();
-// nbNodes = aFace->NbCornerNodes();
-
-// localStream << nbNodes << space;
-
-// itOnSubFace = aFace->nodesIterator();
-// for ( int j = 0; j < 3; ++j ) {
-// // find HYBRID ID
-// aSmdsID = itOnSubFace->next()->GetID();
-// itOnMap = theSmdsToHybridIdMap.find( aSmdsID );
-// // if ( itOnMap == theSmdsToHybridIdMap.end() ) {
-// // cout << "not found node: " << aSmdsID << endl;
-// // return false;
-// // }
-// ASSERT( itOnMap != theSmdsToHybridIdMap.end() );
-
-// localStream << (*itOnMap).second << space ;
-// }
-
-// // (NB_NODES + 1) times: DUMMY_INT
-// for ( int j=0; j<=nbNodes; j++)
-// localStream << dummyint << space ;
-
-// localStream << std::endl;
-// }
-// }
-
-// globalStream << localStream.str();
-// localStream.str("");
-
-// //
-// // FACES : END
-// //
-
-// // //
-// // // ENFORCED EDGES : BEGIN
-// // //
-// //
-// // // Iterate over the enforced edges
-// // int usedEnforcedEdges = 0;
-// // bool isOK;
-// // for(elemIt = theEnforcedEdges.begin() ; elemIt != theEnforcedEdges.end() ; ++elemIt) {
-// // aFace = (*elemIt);
-// // isOK = true;
-// // itOnSubFace = aFace->nodesIterator();
-// // aStream.str("");
-// // aStream << "2" << space ;
-// // for ( int j = 0; j < 2; ++j ) {
-// // aSmdsID = itOnSubFace->next()->GetID();
-// // itOnMap = theEnforcedNodeIdToHybridIdMap.find(aSmdsID);
-// // if (itOnMap != theEnforcedNodeIdToHybridIdMap.end())
-// // aStream << (*itOnMap).second << space;
-// // else {
-// // isOK = false;
-// // break;
-// // }
-// // }
-// // if (isOK) {
-// // for ( int j=0; j<=2; j++)
-// // aStream << dummyint << space ;
-// // // aStream << dummyint << space << dummyint;
-// // localStream << aStream.str() << std::endl;
-// // usedEnforcedEdges++;
-// // }
-// // }
-// //
-// // if (usedEnforcedEdges) {
-// // globalStream << localStream.str();
-// // localStream.str("");
-// // }
-// //
-// // //
-// // // ENFORCED EDGES : END
-// // //
-// // //
-// //
-// // //
-// // // ENFORCED TRIANGLES : BEGIN
-// // //
-// // // Iterate over the enforced triangles
-// // int usedEnforcedTriangles = 0;
-// // for(elemIt = theEnforcedTriangles.begin() ; elemIt != theEnforcedTriangles.end() ; ++elemIt) {
-// // aFace = (*elemIt);
-// // nbNodes = aFace->NbCornerNodes();
-// // isOK = true;
-// // itOnSubFace = aFace->nodesIterator();
-// // aStream.str("");
-// // aStream << nbNodes << space ;
-// // for ( int j = 0; j < 3; ++j ) {
-// // aSmdsID = itOnSubFace->next()->GetID();
-// // itOnMap = theEnforcedNodeIdToHybridIdMap.find(aSmdsID);
-// // if (itOnMap != theEnforcedNodeIdToHybridIdMap.end())
-// // aStream << (*itOnMap).second << space;
-// // else {
-// // isOK = false;
-// // break;
-// // }
-// // }
-// // if (isOK) {
-// // for ( int j=0; j<=3; j++)
-// // aStream << dummyint << space ;
-// // localStream << aStream.str() << std::endl;
-// // usedEnforcedTriangles++;
-// // }
-// // }
-// //
-// // if (usedEnforcedTriangles) {
-// // globalStream << localStream.str();
-// // localStream.str("");
-// // }
-// //
-// // //
-// // // ENFORCED TRIANGLES : END
-// // //
-
-// theFile
-// << nbTriangles/*+usedEnforcedTriangles+usedEnforcedEdges*/
-// << " 0" << std::endl
-// << globalStream.str();
-
-// return true;
-// }
-
-//=======================================================================
-//function : writePoints
-//purpose :
-//=======================================================================
-
-// static bool writePoints (ofstream & theFile,
-// SMESH_MesherHelper& theHelper,
-// std::map <int,int> & theSmdsToHybridIdMap,
-// std::map <int,int> & theEnforcedNodeIdToHybridIdMap,
-// std::map <int,const SMDS_MeshNode*> & theHybridIdToNodeMap,
-// HYBRIDPlugin_Hypothesis::TID2SizeMap & theNodeIDToSizeMap,
-// HYBRIDPlugin_Hypothesis::THYBRIDEnforcedVertexCoordsValues & theEnforcedVertices,
-// HYBRIDPlugin_Hypothesis::TIDSortedNodeGroupMap & theEnforcedNodes,
-// HYBRIDPlugin_Hypothesis::TIDSortedElemGroupMap & theEnforcedEdges,
-// HYBRIDPlugin_Hypothesis::TIDSortedElemGroupMap & theEnforcedTriangles)
-// {
-// // record structure:
-// //
-// // NB_NODES
-// // Loop from 1 to NB_NODES
-// // X Y Z DUMMY_INT
-
-// SMESHDS_Mesh * theMeshDS = theHelper.GetMeshDS();
-// int nbNodes = theMeshDS->NbNodes();
-// if ( nbNodes == 0 )
-// return false;
-
-// int nbEnforcedVertices = theEnforcedVertices.size();
-// int nbEnforcedNodes = theEnforcedNodes.size();
-
-// const TopoDS_Shape shapeToMesh = theMeshDS->ShapeToMesh();
-
-// int aHybridID = 1;
-// SMDS_NodeIteratorPtr nodeIt = theMeshDS->nodesIterator();
-// const SMDS_MeshNode* node;
-
-// // Issue 020674: EDF 870 SMESH: Mesh generated by Netgen not usable by HYBRID
-// // The problem is in nodes on degenerated edges, we need to skip nodes which are free
-// // and replace not-free nodes on degenerated edges by the node on vertex
-// TNodeNodeMap n2nDegen; // map a node on degenerated edge to a node on vertex
-// TNodeNodeMap::iterator n2nDegenIt;
-// if ( theHelper.HasDegeneratedEdges() )
-// {
-// std::set<int> checkedSM;
-// for (TopExp_Explorer e(theMeshDS->ShapeToMesh(), TopAbs_EDGE ); e.More(); e.Next())
-// {
-// SMESH_subMesh* sm = theHelper.GetMesh()->GetSubMesh( e.Current() );
-// if ( checkedSM.insert( sm->GetId() ).second && theHelper.IsDegenShape(sm->GetId() ))
-// {
-// if ( SMESHDS_SubMesh* smDS = sm->GetSubMeshDS() )
-// {
-// TopoDS_Shape vertex = TopoDS_Iterator( e.Current() ).Value();
-// const SMDS_MeshNode* vNode = SMESH_Algo::VertexNode( TopoDS::Vertex( vertex ), theMeshDS);
-// {
-// SMDS_NodeIteratorPtr nIt = smDS->GetNodes();
-// while ( nIt->more() )
-// n2nDegen.insert( std::make_pair( nIt->next(), vNode ));
-// }
-// }
-// }
-// }
-// nbNodes -= n2nDegen.size();
-// }
-
-// const bool isQuadMesh =
-// theHelper.GetMesh()->NbEdges( ORDER_QUADRATIC ) ||
-// theHelper.GetMesh()->NbFaces( ORDER_QUADRATIC ) ||
-// theHelper.GetMesh()->NbVolumes( ORDER_QUADRATIC );
-// if ( isQuadMesh )
-// {
-// // descrease nbNodes by nb of medium nodes
-// while ( nodeIt->more() )
-// {
-// node = nodeIt->next();
-// if ( !theHelper.IsDegenShape( node->getshapeId() ))
-// nbNodes -= int( theHelper.IsMedium( node ));
-// }
-// nodeIt = theMeshDS->nodesIterator();
-// }
-
-// const char* space = " ";
-// const int dummyint = 0;
-
-// std::string tmpStr;
-// (nbNodes == 0 || nbNodes == 1) ? tmpStr = " node" : tmpStr = " nodes";
-// // NB_NODES
-// std::cout << std::endl;
-// std::cout << "The initial 2D mesh contains :" << std::endl;
-// std::cout << " " << nbNodes << tmpStr << std::endl;
-// if (nbEnforcedVertices > 0) {
-// (nbEnforcedVertices == 1) ? tmpStr = "vertex" : tmpStr = "vertices";
-// std::cout << " " << nbEnforcedVertices << " enforced " << tmpStr << std::endl;
-// }
-// if (nbEnforcedNodes > 0) {
-// (nbEnforcedNodes == 1) ? tmpStr = "node" : tmpStr = "nodes";
-// std::cout << " " << nbEnforcedNodes << " enforced " << tmpStr << std::endl;
-// }
-// std::cout << std::endl;
-// std::cout << "Start writing in 'points' file ..." << std::endl;
-
-// theFile << nbNodes << std::endl;
-
-// // Loop from 1 to NB_NODES
-
-// while ( nodeIt->more() )
-// {
-// node = nodeIt->next();
-// if ( isQuadMesh && theHelper.IsMedium( node )) // Issue 0021238
-// continue;
-// if ( n2nDegen.count( node ) ) // Issue 0020674
-// continue;
-
-// theSmdsToHybridIdMap.insert( std::make_pair( node->GetID(), aHybridID ));
-// theHybridIdToNodeMap.insert( std::make_pair( aHybridID, node ));
-// aHybridID++;
-
-// // X Y Z DUMMY_INT
-// theFile
-// << node->X() << space
-// << node->Y() << space
-// << node->Z() << space
-// << dummyint;
-
-// theFile << std::endl;
-
-// }
-
-// // Iterate over the enforced nodes
-// std::map<int,double> enfVertexIndexSizeMap;
-// if (nbEnforcedNodes) {
-// HYBRIDPlugin_Hypothesis::TIDSortedNodeGroupMap::const_iterator nodeIt = theEnforcedNodes.begin();
-// for( ; nodeIt != theEnforcedNodes.end() ; ++nodeIt) {
-// double x = nodeIt->first->X();
-// double y = nodeIt->first->Y();
-// double z = nodeIt->first->Z();
-// // Test if point is inside shape to mesh
-// gp_Pnt myPoint(x,y,z);
-// BRepClass3d_SolidClassifier scl(shapeToMesh);
-// scl.Perform(myPoint, 1e-7);
-// TopAbs_State result = scl.State();
-// if ( result != TopAbs_IN )
-// continue;
-// std::vector<double> coords;
-// coords.push_back(x);
-// coords.push_back(y);
-// coords.push_back(z);
-// if (theEnforcedVertices.find(coords) != theEnforcedVertices.end())
-// continue;
-
-// // double size = theNodeIDToSizeMap.find(nodeIt->first->GetID())->second;
-// // theHybridIdToNodeMap.insert( std::make_pair( nbNodes + i, (*nodeIt) ));
-// // MESSAGE("Adding enforced node (" << x << "," << y <<"," << z << ")");
-// // X Y Z PHY_SIZE DUMMY_INT
-// theFile
-// << x << space
-// << y << space
-// << z << space
-// << -1 << space
-// << dummyint << space;
-// theFile << std::endl;
-// theEnforcedNodeIdToHybridIdMap.insert( std::make_pair( nodeIt->first->GetID(), aHybridID ));
-// enfVertexIndexSizeMap[aHybridID] = -1;
-// aHybridID++;
-// // else
-// // MESSAGE("Enforced vertex (" << x << "," << y <<"," << z << ") is not inside the geometry: it was not added ");
-// }
-// }
-
-// if (nbEnforcedVertices) {
-// // Iterate over the enforced vertices
-// HYBRIDPlugin_Hypothesis::THYBRIDEnforcedVertexCoordsValues::const_iterator vertexIt = theEnforcedVertices.begin();
-// for( ; vertexIt != theEnforcedVertices.end() ; ++vertexIt) {
-// double x = vertexIt->first[0];
-// double y = vertexIt->first[1];
-// double z = vertexIt->first[2];
-// // Test if point is inside shape to mesh
-// gp_Pnt myPoint(x,y,z);
-// BRepClass3d_SolidClassifier scl(shapeToMesh);
-// scl.Perform(myPoint, 1e-7);
-// TopAbs_State result = scl.State();
-// if ( result != TopAbs_IN )
-// continue;
-// MESSAGE("Adding enforced vertex (" << x << "," << y <<"," << z << ") = " << vertexIt->second);
-// // X Y Z PHY_SIZE DUMMY_INT
-// theFile
-// << x << space
-// << y << space
-// << z << space
-// << vertexIt->second << space
-// << dummyint << space;
-// theFile << std::endl;
-// enfVertexIndexSizeMap[aHybridID] = vertexIt->second;
-// aHybridID++;
-// }
-// }
-
-
-// std::cout << std::endl;
-// std::cout << "End writing in 'points' file." << std::endl;
-
-// return true;
-// }
-
-//=======================================================================
-//function : readResultFile
-//purpose : readResultFile with geometry
-//=======================================================================
-
-// static bool readResultFile(const int fileOpen,
-// #ifdef WIN32
-// const char* fileName,
-// #endif
-// HYBRIDPlugin_HYBRID* theAlgo,
-// SMESH_MesherHelper& theHelper,
-// TopoDS_Shape tabShape[],
-// double** tabBox,
-// const int nbShape,
-// std::map <int,const SMDS_MeshNode*>& theHybridIdToNodeMap,
-// std::map <int,int> & theNodeId2NodeIndexMap,
-// bool toMeshHoles,
-// int nbEnforcedVertices,
-// int nbEnforcedNodes,
-// HYBRIDPlugin_Hypothesis::TIDSortedElemGroupMap & theEnforcedEdges,
-// HYBRIDPlugin_Hypothesis::TIDSortedElemGroupMap & theEnforcedTriangles,
-// bool toMakeGroupsOfDomains)
-// {
-// MESSAGE("HYBRIDPlugin_HYBRID::readResultFile()");
-// Kernel_Utils::Localizer loc;
-// struct stat status;
-// size_t length;
-
-// std::string tmpStr;
-
-// char *ptr, *mapPtr;
-// char *tetraPtr;
-// char *shapePtr;
-
-// SMESHDS_Mesh* theMeshDS = theHelper.GetMeshDS();
-
-// int nbElems, nbNodes, nbInputNodes;
-// int nbTriangle;
-// int ID, shapeID, hybridShapeID;
-// int IdShapeRef = 1;
-// int compoundID =
-// nbShape ? theMeshDS->ShapeToIndex( tabShape[0] ) : theMeshDS->ShapeToIndex( theMeshDS->ShapeToMesh() );
-
-// int *tab, *tabID, *nodeID, *nodeAssigne;
-// double *coord;
-// const SMDS_MeshNode **node;
-
-// tab = new int[3];
-// nodeID = new int[4];
-// coord = new double[3];
-// node = new const SMDS_MeshNode*[4];
-
-// TopoDS_Shape aSolid;
-// SMDS_MeshNode * aNewNode;
-// std::map <int,const SMDS_MeshNode*>::iterator itOnNode;
-// SMDS_MeshElement* aTet;
-// #ifdef _DEBUG_
-// std::set<int> shapeIDs;
-// #endif
-
-// // Read the file state
-// fstat(fileOpen, &status);
-// length = status.st_size;
-
-// // Mapping the result file into memory
-// #ifdef WIN32
-// HANDLE fd = CreateFile(fileName, GENERIC_READ, FILE_SHARE_READ,
-// NULL, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, NULL);
-// HANDLE hMapObject = CreateFileMapping(fd, NULL, PAGE_READONLY,
-// 0, (DWORD)length, NULL);
-// ptr = ( char* ) MapViewOfFile(hMapObject, FILE_MAP_READ, 0, 0, 0 );
-// #else
-// ptr = (char *) mmap(0,length,PROT_READ,MAP_PRIVATE,fileOpen,0);
-// #endif
-// mapPtr = ptr;
-
-// ptr = readMapIntLine(ptr, tab);
-// tetraPtr = ptr;
-
-// nbElems = tab[0];
-// nbNodes = tab[1];
-// nbInputNodes = tab[2];
-
-// nodeAssigne = new int[ nbNodes+1 ];
-
-// if (nbShape > 0)
-// aSolid = tabShape[0];
-
-// // Reading the nodeId
-// for (int i=0; i < 4*nbElems; i++)
-// strtol(ptr, &ptr, 10);
-
-// MESSAGE("nbInputNodes: "<<nbInputNodes);
-// MESSAGE("nbEnforcedVertices: "<<nbEnforcedVertices);
-// MESSAGE("nbEnforcedNodes: "<<nbEnforcedNodes);
-// // Reading the nodeCoor and update the nodeMap
-// for (int iNode=1; iNode <= nbNodes; iNode++) {
-// if(theAlgo->computeCanceled())
-// return false;
-// for (int iCoor=0; iCoor < 3; iCoor++)
-// coord[ iCoor ] = strtod(ptr, &ptr);
-// nodeAssigne[ iNode ] = 1;
-// if ( iNode > (nbInputNodes-(nbEnforcedVertices+nbEnforcedNodes)) ) {
-// // Creating SMESH nodes
-// // - for enforced vertices
-// // - for vertices of forced edges
-// // - for hybrid nodes
-// nodeAssigne[ iNode ] = 0;
-// aNewNode = theMeshDS->AddNode( coord[0],coord[1],coord[2] );
-// theHybridIdToNodeMap.insert(theHybridIdToNodeMap.end(), std::make_pair( iNode, aNewNode ));
-// }
-// }
-
-// // Reading the number of triangles which corresponds to the number of sub-domains
-// nbTriangle = strtol(ptr, &ptr, 10);
-
-// tabID = new int[nbTriangle];
-// for (int i=0; i < nbTriangle; i++) {
-// if(theAlgo->computeCanceled())
-// return false;
-// tabID[i] = 0;
-// // find the solid corresponding to HYBRID sub-domain following
-// // the technique proposed in HYBRID manual in chapter
-// // "B.4 Subdomain (sub-region) assignment"
-// int nodeId1 = strtol(ptr, &ptr, 10);
-// int nodeId2 = strtol(ptr, &ptr, 10);
-// int nodeId3 = strtol(ptr, &ptr, 10);
-// if ( nbTriangle > 1 ) {
-// const SMDS_MeshNode* n1 = theHybridIdToNodeMap[ nodeId1 ];
-// const SMDS_MeshNode* n2 = theHybridIdToNodeMap[ nodeId2 ];
-// const SMDS_MeshNode* n3 = theHybridIdToNodeMap[ nodeId3 ];
-// if (!n1 || !n2 || !n3) {
-// tabID[i] = HOLE_ID;
-// continue;
-// }
-// try {
-// OCC_CATCH_SIGNALS;
-// // tabID[i] = findShapeID( theHelper, n1, n2, n3, toMeshHoles );
-// tabID[i] = findShapeID( *theHelper.GetMesh(), n1, n2, n3, toMeshHoles );
-// // -- 0020330: Pb with hybrid as a submesh
-// // check that found shape is to be meshed
-// if ( tabID[i] > 0 ) {
-// const TopoDS_Shape& foundShape = theMeshDS->IndexToShape( tabID[i] );
-// bool isToBeMeshed = false;
-// for ( int iS = 0; !isToBeMeshed && iS < nbShape; ++iS )
-// isToBeMeshed = foundShape.IsSame( tabShape[ iS ]);
-// if ( !isToBeMeshed )
-// tabID[i] = HOLE_ID;
-// }
-// // END -- 0020330: Pb with hybrid as a submesh
-// #ifdef _DEBUG_
-// std::cout << i+1 << " subdomain: findShapeID() returns " << tabID[i] << std::endl;
-// #endif
-// }
-// catch ( Standard_Failure & ex)
-// {
-// #ifdef _DEBUG_
-// std::cout << i+1 << " subdomain: Exception caugt: " << ex.GetMessageString() << std::endl;
-// #endif
-// }
-// catch (...) {
-// #ifdef _DEBUG_
-// std::cout << i+1 << " subdomain: unknown exception caught " << std::endl;
-// #endif
-// }
-// }
-// }
-
-// shapePtr = ptr;
-
-// if ( nbTriangle <= nbShape ) // no holes
-// toMeshHoles = true; // not avoid creating tetras in holes
-
-// // IMP 0022172: [CEA 790] create the groups corresponding to domains
-// std::vector< std::vector< const SMDS_MeshElement* > > elemsOfDomain( Max( nbTriangle, nbShape ));
-
-// // Associating the tetrahedrons to the shapes
-// shapeID = compoundID;
-// for (int iElem = 0; iElem < nbElems; iElem++) {
-// if(theAlgo->computeCanceled())
-// return false;
-// for (int iNode = 0; iNode < 4; iNode++) {
-// ID = strtol(tetraPtr, &tetraPtr, 10);
-// itOnNode = theHybridIdToNodeMap.find(ID);
-// node[ iNode ] = itOnNode->second;
-// nodeID[ iNode ] = ID;
-// }
-// // We always run HYBRID with "to mesh holes"==TRUE but we must not create
-// // tetras within holes depending on hypo option,
-// // so we first check if aTet is inside a hole and then create it
-// //aTet = theMeshDS->AddVolume( node[1], node[0], node[2], node[3] );
-// hybridShapeID = 0; // domain ID
-// if ( nbTriangle > 1 ) {
-// shapeID = HOLE_ID; // negative shapeID means not to create tetras if !toMeshHoles
-// hybridShapeID = strtol(shapePtr, &shapePtr, 10) - IdShapeRef;
-// if ( tabID[ hybridShapeID ] == 0 ) {
-// TopAbs_State state;
-// aSolid = findShape(node, aSolid, tabShape, tabBox, nbShape, &state);
-// if ( toMeshHoles || state == TopAbs_IN )
-// shapeID = theMeshDS->ShapeToIndex( aSolid );
-// tabID[ hybridShapeID ] = shapeID;
-// }
-// else
-// shapeID = tabID[ hybridShapeID ];
-// }
-// else if ( nbShape > 1 ) {
-// // Case where nbTriangle == 1 while nbShape == 2 encountered
-// // with compound of 2 boxes and "To mesh holes"==False,
-// // so there are no subdomains specified for each tetrahedron.
-// // Try to guess a solid by a node already bound to shape
-// shapeID = 0;
-// for ( int i=0; i<4 && shapeID==0; i++ ) {
-// if ( nodeAssigne[ nodeID[i] ] == 1 &&
-// node[i]->GetPosition()->GetTypeOfPosition() == SMDS_TOP_3DSPACE &&
-// node[i]->getshapeId() > 1 )
-// {
-// shapeID = node[i]->getshapeId();
-// }
-// }
-// if ( shapeID==0 ) {
-// aSolid = findShape(node, aSolid, tabShape, tabBox, nbShape);
-// shapeID = theMeshDS->ShapeToIndex( aSolid );
-// }
-// }
-// // set new nodes and tetrahedron onto the shape
-// for ( int i=0; i<4; i++ ) {
-// if ( nodeAssigne[ nodeID[i] ] == 0 ) {
-// if ( shapeID != HOLE_ID )
-// theMeshDS->SetNodeInVolume( node[i], shapeID );
-// nodeAssigne[ nodeID[i] ] = shapeID;
-// }
-// }
-// if ( toMeshHoles || shapeID != HOLE_ID ) {
-// aTet = theHelper.AddVolume( node[1], node[0], node[2], node[3],
-// /*id=*/0, /*force3d=*/false);
-// theMeshDS->SetMeshElementOnShape( aTet, shapeID );
-// if ( toMakeGroupsOfDomains )
-// {
-// if ( int( elemsOfDomain.size() ) < hybridShapeID+1 )
-// elemsOfDomain.resize( hybridShapeID+1 );
-// elemsOfDomain[ hybridShapeID ].push_back( aTet );
-// }
-// }
-// #ifdef _DEBUG_
-// shapeIDs.insert( shapeID );
-// #endif
-// }
-// if ( toMakeGroupsOfDomains )
-// makeDomainGroups( elemsOfDomain, &theHelper );
-
-// // Add enforced elements
-// HYBRIDPlugin_Hypothesis::TIDSortedElemGroupMap::const_iterator elemIt;
-// const SMDS_MeshElement* anElem;
-// SMDS_ElemIteratorPtr itOnEnfElem;
-// std::map<int,int>::const_iterator itOnMap;
-// shapeID = compoundID;
-// // Enforced edges
-// if (theEnforcedEdges.size()) {
-// (theEnforcedEdges.size() <= 1) ? tmpStr = " enforced edge" : " enforced edges";
-// std::cout << "Add " << theEnforcedEdges.size() << tmpStr << std::endl;
-// std::vector< const SMDS_MeshNode* > node( 2 );
-// // Iterate over the enforced edges
-// for(elemIt = theEnforcedEdges.begin() ; elemIt != theEnforcedEdges.end() ; ++elemIt) {
-// anElem = elemIt->first;
-// bool addElem = true;
-// itOnEnfElem = anElem->nodesIterator();
-// for ( int j = 0; j < 2; ++j ) {
-// int aNodeID = itOnEnfElem->next()->GetID();
-// itOnMap = theNodeId2NodeIndexMap.find(aNodeID);
-// if (itOnMap != theNodeId2NodeIndexMap.end()) {
-// itOnNode = theHybridIdToNodeMap.find((*itOnMap).second);
-// if (itOnNode != theHybridIdToNodeMap.end()) {
-// node.push_back((*itOnNode).second);
-// // shapeID =(*itOnNode).second->getshapeId();
-// }
-// else
-// addElem = false;
-// }
-// else
-// addElem = false;
-// }
-// if (addElem) {
-// aTet = theHelper.AddEdge( node[0], node[1], 0, false);
-// theMeshDS->SetMeshElementOnShape( aTet, shapeID );
-// }
-// }
-// }
-// // Enforced faces
-// if (theEnforcedTriangles.size()) {
-// (theEnforcedTriangles.size() <= 1) ? tmpStr = " enforced triangle" : " enforced triangles";
-// std::cout << "Add " << theEnforcedTriangles.size() << " enforced triangles" << std::endl;
-// std::vector< const SMDS_MeshNode* > node( 3 );
-// // Iterate over the enforced triangles
-// for(elemIt = theEnforcedTriangles.begin() ; elemIt != theEnforcedTriangles.end() ; ++elemIt) {
-// anElem = elemIt->first;
-// bool addElem = true;
-// itOnEnfElem = anElem->nodesIterator();
-// for ( int j = 0; j < 3; ++j ) {
-// int aNodeID = itOnEnfElem->next()->GetID();
-// itOnMap = theNodeId2NodeIndexMap.find(aNodeID);
-// if (itOnMap != theNodeId2NodeIndexMap.end()) {
-// itOnNode = theHybridIdToNodeMap.find((*itOnMap).second);
-// if (itOnNode != theHybridIdToNodeMap.end()) {
-// node.push_back((*itOnNode).second);
-// // shapeID =(*itOnNode).second->getshapeId();
-// }
-// else
-// addElem = false;
-// }
-// else
-// addElem = false;
-// }
-// if (addElem) {
-// aTet = theHelper.AddFace( node[0], node[1], node[2], 0, false);
-// theMeshDS->SetMeshElementOnShape( aTet, shapeID );
-// }
-// }
-// }
-
-// // Remove nodes of tetras inside holes if !toMeshHoles
-// if ( !toMeshHoles ) {
-// itOnNode = theHybridIdToNodeMap.find( nbInputNodes );
-// for ( ; itOnNode != theHybridIdToNodeMap.end(); ++itOnNode) {
-// ID = itOnNode->first;
-// if ( nodeAssigne[ ID ] == HOLE_ID )
-// theMeshDS->RemoveFreeNode( itOnNode->second, 0 );
-// }
-// }
-
-
-// if ( nbElems ) {
-// (nbElems <= 1) ? tmpStr = " tetrahedra" : " tetrahedrons";
-// cout << nbElems << tmpStr << " have been associated to " << nbShape;
-// (nbShape <= 1) ? tmpStr = " shape" : " shapes";
-// cout << tmpStr << endl;
-// }
-// #ifdef WIN32
-// UnmapViewOfFile(mapPtr);
-// CloseHandle(hMapObject);
-// CloseHandle(fd);
-// #else
-// munmap(mapPtr, length);
-// #endif
-// close(fileOpen);
-
-// delete [] tab;
-// delete [] tabID;
-// delete [] nodeID;
-// delete [] coord;
-// delete [] node;
-// delete [] nodeAssigne;
-
-// #ifdef _DEBUG_
-// shapeIDs.erase(-1);
-// if ((int) shapeIDs.size() != nbShape ) {
-// (shapeIDs.size() <= 1) ? tmpStr = " solid" : " solids";
-// std::cout << "Only " << shapeIDs.size() << tmpStr << " of " << nbShape << " found" << std::endl;
-// for (int i=0; i<nbShape; i++) {
-// shapeID = theMeshDS->ShapeToIndex( tabShape[i] );
-// if ( shapeIDs.find( shapeID ) == shapeIDs.end() )
-// std::cout << " Solid #" << shapeID << " not found" << std::endl;
-// }
-// }
-// #endif
-
-// return true;
-// }
-
-