// Copyright (C) 2007-2016 CEA/DEN, EDF R&D, OPEN CASCADE // // Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN, // CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS // // This library is free software; you can redistribute it and/or // modify it under the terms of the GNU Lesser General Public // License as published by the Free Software Foundation; either // version 2.1 of the License, or (at your option) any later version. // // This library 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 // Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public // License along with this library; if not, write to the Free Software // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA // // See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com // // SMESH SMESH : implementation of SMESH idl descriptions // File : StdMeshers_Projection_2D.cxx // Module : SMESH // Created : Fri Oct 20 11:37:07 2006 // Author : Edward AGAPOV (eap) // #include "StdMeshers_Projection_2D.hxx" #include "StdMeshers_ProjectionSource2D.hxx" #include "StdMeshers_ProjectionUtils.hxx" #include "StdMeshers_FaceSide.hxx" #include "SMDS_EdgePosition.hxx" #include "SMDS_FacePosition.hxx" #include "SMESHDS_Hypothesis.hxx" #include "SMESHDS_Mesh.hxx" #include "SMESHDS_SubMesh.hxx" #include "SMESH_Block.hxx" #include "SMESH_Comment.hxx" #include "SMESH_Gen.hxx" #include "SMESH_Mesh.hxx" #include "SMESH_MeshAlgos.hxx" #include "SMESH_MesherHelper.hxx" #include "SMESH_Pattern.hxx" #include "SMESH_subMesh.hxx" #include "SMESH_subMeshEventListener.hxx" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace std; #define RETURN_BAD_RESULT(msg) { MESSAGE(")-: Error: " << msg); return false; } #ifdef _DEBUG_ // enable printing algo + projection shapes while meshing //#define PRINT_WHO_COMPUTE_WHAT #endif namespace TAssocTool = StdMeshers_ProjectionUtils; //typedef StdMeshers_ProjectionUtils TAssocTool; //======================================================================= //function : StdMeshers_Projection_2D //purpose : //======================================================================= StdMeshers_Projection_2D::StdMeshers_Projection_2D(int hypId, int studyId, SMESH_Gen* gen) :SMESH_2D_Algo(hypId, studyId, gen) { _name = "Projection_2D"; _compatibleHypothesis.push_back("ProjectionSource2D"); _sourceHypo = 0; } //================================================================================ /*! * \brief Destructor */ //================================================================================ StdMeshers_Projection_2D::~StdMeshers_Projection_2D() {} //======================================================================= //function : CheckHypothesis //purpose : //======================================================================= bool StdMeshers_Projection_2D::CheckHypothesis(SMESH_Mesh& theMesh, const TopoDS_Shape& theShape, SMESH_Hypothesis::Hypothesis_Status& theStatus) { list ::const_iterator itl; const list &hyps = GetUsedHypothesis(theMesh, theShape); if ( hyps.size() == 0 ) { theStatus = HYP_MISSING; return false; // can't work with no hypothesis } if ( hyps.size() > 1 ) { theStatus = HYP_ALREADY_EXIST; return false; } const SMESHDS_Hypothesis *theHyp = hyps.front(); string hypName = theHyp->GetName(); theStatus = HYP_OK; if (hypName == "ProjectionSource2D") { _sourceHypo = static_cast(theHyp); // Check hypo parameters SMESH_Mesh* srcMesh = _sourceHypo->GetSourceMesh(); SMESH_Mesh* tgtMesh = & theMesh; if ( !srcMesh ) srcMesh = tgtMesh; // check vertices if ( _sourceHypo->HasVertexAssociation() ) { // source vertices TopoDS_Shape edge = TAssocTool::GetEdgeByVertices ( srcMesh, _sourceHypo->GetSourceVertex(1), _sourceHypo->GetSourceVertex(2) ); if ( edge.IsNull() || !SMESH_MesherHelper::IsSubShape( edge, srcMesh ) || !SMESH_MesherHelper::IsSubShape( edge, _sourceHypo->GetSourceFace() )) { theStatus = HYP_BAD_PARAMETER; error("Invalid source vertices"); SCRUTE((edge.IsNull())); SCRUTE((SMESH_MesherHelper::IsSubShape( edge, srcMesh ))); SCRUTE((SMESH_MesherHelper::IsSubShape( edge, _sourceHypo->GetSourceFace() ))); } else { // target vertices edge = TAssocTool::GetEdgeByVertices ( tgtMesh, _sourceHypo->GetTargetVertex(1), _sourceHypo->GetTargetVertex(2) ); if ( edge.IsNull() || !SMESH_MesherHelper::IsSubShape( edge, tgtMesh )) { theStatus = HYP_BAD_PARAMETER; error("Invalid target vertices"); SCRUTE((edge.IsNull())); SCRUTE((SMESH_MesherHelper::IsSubShape( edge, tgtMesh ))); } // PAL16203 else if ( !_sourceHypo->IsCompoundSource() && !SMESH_MesherHelper::IsSubShape( edge, theShape )) { theStatus = HYP_BAD_PARAMETER; error("Invalid target vertices"); SCRUTE((SMESH_MesherHelper::IsSubShape( edge, theShape ))); } } } // check a source face if ( !SMESH_MesherHelper::IsSubShape( _sourceHypo->GetSourceFace(), srcMesh ) || ( srcMesh == tgtMesh && theShape == _sourceHypo->GetSourceFace() )) { theStatus = HYP_BAD_PARAMETER; error("Invalid source face"); SCRUTE((SMESH_MesherHelper::IsSubShape( _sourceHypo->GetSourceFace(), srcMesh ))); SCRUTE((srcMesh == tgtMesh)); SCRUTE(( theShape == _sourceHypo->GetSourceFace() )); } } else { theStatus = HYP_INCOMPATIBLE; } return ( theStatus == HYP_OK ); } namespace { //================================================================================ /*! * \brief define if a node is new or old * \param node - node to check * \retval bool - true if the node existed before Compute() is called */ //================================================================================ bool isOldNode( const SMDS_MeshNode* node ) { // old nodes are shared by edges and new ones are shared // only by faces created by mapper //if ( is1DComputed ) { bool isOld = node->NbInverseElements(SMDSAbs_Edge) > 0; return isOld; } // else // { // SMDS_ElemIteratorPtr invFace = node->GetInverseElementIterator(SMDSAbs_Face); // bool isNew = invFace->more(); // return !isNew; // } } //================================================================================ /*! * \brief Class to remove mesh built by pattern mapper on edges * and vertices in the case of failure of projection algo. * It does it's job at destruction */ //================================================================================ class MeshCleaner { SMESH_subMesh* sm; public: MeshCleaner( SMESH_subMesh* faceSubMesh ): sm(faceSubMesh) {} ~MeshCleaner() { Clean(sm); } void Release() { sm = 0; } // mesh will not be removed static void Clean( SMESH_subMesh* sm, bool withSub=true ) { if ( !sm || !sm->GetSubMeshDS() ) return; // PAL16567, 18920. Remove face nodes as well // switch ( sm->GetSubShape().ShapeType() ) { // case TopAbs_VERTEX: // case TopAbs_EDGE: { SMDS_NodeIteratorPtr nIt = sm->GetSubMeshDS()->GetNodes(); SMESHDS_Mesh* mesh = sm->GetFather()->GetMeshDS(); while ( nIt->more() ) { const SMDS_MeshNode* node = nIt->next(); if ( !isOldNode( node ) ) mesh->RemoveNode( node ); } // do not break but iterate over DependsOn() // } // default: if ( !withSub ) return; SMESH_subMeshIteratorPtr smIt = sm->getDependsOnIterator(false,false); while ( smIt->more() ) Clean( smIt->next(), false ); // } } }; //================================================================================ /*! * \brief find new nodes belonging to one free border of mesh on face * \param sm - submesh on edge or vertex containing nodes to choose from * \param face - the face bound by the submesh * \param u2nodes - map to fill with nodes * \param seamNodes - set of found nodes * \retval bool - is a success */ //================================================================================ bool getBoundaryNodes ( SMESH_subMesh* sm, const TopoDS_Face& face, map< double, const SMDS_MeshNode* > & u2nodes, set< const SMDS_MeshNode* > & seamNodes) { u2nodes.clear(); seamNodes.clear(); if ( !sm || !sm->GetSubMeshDS() ) RETURN_BAD_RESULT("Null submesh"); SMDS_NodeIteratorPtr nIt = sm->GetSubMeshDS()->GetNodes(); switch ( sm->GetSubShape().ShapeType() ) { case TopAbs_VERTEX: { while ( nIt->more() ) { const SMDS_MeshNode* node = nIt->next(); if ( isOldNode( node ) ) continue; u2nodes.insert( make_pair( 0., node )); seamNodes.insert( node ); return true; } break; } case TopAbs_EDGE: { // Get submeshes of sub-vertices const map< int, SMESH_subMesh * >& subSM = sm->DependsOn(); if ( subSM.size() != 2 ) RETURN_BAD_RESULT("there must be 2 submeshes of sub-vertices" " but we have " << subSM.size()); SMESH_subMesh* smV1 = subSM.begin()->second; SMESH_subMesh* smV2 = subSM.rbegin()->second; if ( !smV1->IsMeshComputed() || !smV2->IsMeshComputed() ) RETURN_BAD_RESULT("Empty vertex submeshes"); const SMDS_MeshNode* nV1 = 0; const SMDS_MeshNode* nE = 0; // Look for nV1 - a new node on V1 nIt = smV1->GetSubMeshDS()->GetNodes(); while ( nIt->more() && !nE ) { const SMDS_MeshNode* node = nIt->next(); if ( isOldNode( node ) ) continue; nV1 = node; // Find nE - a new node connected to nV1 and belonging to edge submesh; SMESHDS_SubMesh* smDS = sm->GetSubMeshDS(); SMDS_ElemIteratorPtr vElems = nV1->GetInverseElementIterator(SMDSAbs_Face); while ( vElems->more() && !nE ) { const SMDS_MeshElement* elem = vElems->next(); int nbNodes = elem->NbNodes(); if ( elem->IsQuadratic() ) nbNodes /= 2; int iV1 = elem->GetNodeIndex( nV1 ); // try next after nV1 int iE = SMESH_MesherHelper::WrapIndex( iV1 + 1, nbNodes ); if ( smDS->Contains( elem->GetNode( iE ) )) nE = elem->GetNode( iE ); if ( !nE ) { // try node before nV1 iE = SMESH_MesherHelper::WrapIndex( iV1 - 1, nbNodes ); if ( smDS->Contains( elem->GetNode( iE ))) nE = elem->GetNode( iE ); } if ( nE && elem->IsQuadratic() ) { // find medium node between nV1 and nE if ( Abs( iV1 - iE ) == 1 ) nE = elem->GetNode( Min ( iV1, iE ) + nbNodes ); else nE = elem->GetNode( elem->NbNodes() - 1 ); } } } if ( !nV1 ) RETURN_BAD_RESULT("No new node found on V1"); if ( !nE ) RETURN_BAD_RESULT("new node on edge not found"); // Get the whole free border of a face list< const SMDS_MeshNode* > bordNodes; list< const SMDS_MeshElement* > bordFaces; if ( !SMESH_MeshEditor::FindFreeBorder (nV1, nE, nV1, bordNodes, bordFaces )) RETURN_BAD_RESULT("free border of a face not found by nodes " << nV1->GetID() << " " << nE->GetID() ); // Insert nodes of the free border to the map until node on V2 encountered SMESHDS_SubMesh* v2smDS = smV2->GetSubMeshDS(); list< const SMDS_MeshNode* >::iterator bordIt = bordNodes.begin(); bordIt++; // skip nV1 for ( ; bordIt != bordNodes.end(); ++bordIt ) { const SMDS_MeshNode* node = *bordIt; if ( v2smDS->Contains( node )) break; if ( node->GetPosition()->GetTypeOfPosition() != SMDS_TOP_EDGE ) RETURN_BAD_RESULT("Bad node position type: node " << node->GetID() << " pos type " << node->GetPosition()->GetTypeOfPosition()); const SMDS_EdgePosition* pos = static_cast(node->GetPosition()); u2nodes.insert( make_pair( pos->GetUParameter(), node )); seamNodes.insert( node ); } if ( u2nodes.size() != seamNodes.size() ) RETURN_BAD_RESULT("Bad node params on edge " << sm->GetId() << ", " << u2nodes.size() << " != " << seamNodes.size() ); return true; } default:; } RETURN_BAD_RESULT ("Unexpected submesh type"); } // bool getBoundaryNodes() //================================================================================ /*! * \brief Check if two consecutive EDGEs are connected in 2D * \param [in] E1 - a well oriented non-seam EDGE * \param [in] E2 - a possibly well oriented seam EDGE * \param [in] F - a FACE * \return bool - result */ //================================================================================ bool are2dConnected( const TopoDS_Edge & E1, const TopoDS_Edge & E2, const TopoDS_Face & F ) { double f,l; Handle(Geom2d_Curve) c1 = BRep_Tool::CurveOnSurface( E1, F, f, l ); gp_Pnt2d uvFirst1 = c1->Value( f ); gp_Pnt2d uvLast1 = c1->Value( l ); Handle(Geom2d_Curve) c2 = BRep_Tool::CurveOnSurface( E2, F, f, l ); gp_Pnt2d uvFirst2 = c2->Value( E2.Orientation() == TopAbs_REVERSED ? l : f ); double tol2 = Max( Precision::PConfusion() * Precision::PConfusion(), 1e-5 * uvLast1.SquareDistance( uvFirst1 )); return (( uvFirst2.SquareDistance( uvFirst1 ) < tol2 ) || ( uvFirst2.SquareDistance( uvLast1 ) < tol2 )); } //================================================================================ /*! * \brief Compose TSideVector for both FACEs keeping matching order of EDGEs * and fill src2tgtNodes map */ //================================================================================ TError getWires(const TopoDS_Face& tgtFace, const TopoDS_Face& srcFace, SMESH_Mesh * tgtMesh, SMESH_Mesh * srcMesh, SMESH_MesherHelper* tgtHelper, const TAssocTool::TShapeShapeMap& shape2ShapeMap, TSideVector& srcWires, TSideVector& tgtWires, TAssocTool::TNodeNodeMap& src2tgtNodes, bool& is1DComputed) { src2tgtNodes.clear(); // get ordered src EDGEs TError err; srcWires = StdMeshers_FaceSide::GetFaceWires( srcFace, *srcMesh,/*skipMediumNodes=*/0, err ); if (( err && !err->IsOK() ) || ( srcWires.empty() )) return err; #ifdef PRINT_WHO_COMPUTE_WHAT cout << "Projection_2D" << " F " << tgtMesh->GetMeshDS()->ShapeToIndex( tgtFace ) << " <- " << srcMesh->GetMeshDS()->ShapeToIndex( srcFace ) << endl; #endif // make corresponding sequence of tgt EDGEs tgtWires.resize( srcWires.size() ); for ( size_t iW = 0; iW < srcWires.size(); ++iW ) { StdMeshers_FaceSidePtr srcWire = srcWires[iW]; list< TopoDS_Edge > tgtEdges; TopTools_IndexedMapOfShape edgeMap; // to detect seam edges for ( int iE = 0; iE < srcWire->NbEdges(); ++iE ) { TopoDS_Edge srcE = srcWire->Edge( iE ); TopoDS_Edge tgtE = TopoDS::Edge( shape2ShapeMap( srcE, /*isSrc=*/true)); TopoDS_Shape srcEbis = shape2ShapeMap( tgtE, /*isSrc=*/false ); if ( srcE.Orientation() != srcEbis.Orientation() ) tgtE.Reverse(); // reverse a seam edge encountered for the second time const int index = edgeMap.Add( tgtE ); if ( index < edgeMap.Extent() ) // E is a seam { // check which of edges to reverse, E or one already being in tgtEdges if ( are2dConnected( tgtEdges.back(), tgtE, tgtFace )) { list< TopoDS_Edge >::iterator eIt = tgtEdges.begin(); std::advance( eIt, index-1 ); if ( are2dConnected( tgtEdges.back(), *eIt, tgtFace )) eIt->Reverse(); } else { tgtE.Reverse(); } } if ( srcWire->NbEdges() == 1 && tgtMesh == srcMesh ) // circle { // try to verify ori by propagation pair nE = StdMeshers_ProjectionUtils::GetPropagationEdge( srcMesh, tgtE, srcE ); if ( !nE.second.IsNull() ) tgtE = nE.second; } tgtEdges.push_back( tgtE ); } tgtWires[ iW ].reset( new StdMeshers_FaceSide( tgtFace, tgtEdges, tgtMesh, /*theIsForward = */ true, /*theIgnoreMediumNodes = */false, tgtHelper )); StdMeshers_FaceSidePtr tgtWire = tgtWires[ iW ]; // Fill map of src to tgt nodes with nodes on edges for ( int iE = 0; iE < srcWire->NbEdges(); ++iE ) { #ifdef PRINT_WHO_COMPUTE_WHAT if ( tgtMesh->GetSubMesh( tgtWire->Edge(iE) )->IsEmpty() ) cout << "Projection_2D" << " E " << tgtWire->EdgeID(iE) << " <- " << srcWire->EdgeID(iE) << endl; #endif if ( srcMesh->GetSubMesh( srcWire->Edge(iE) )->IsEmpty() || tgtMesh->GetSubMesh( tgtWire->Edge(iE) )->IsEmpty() ) { // add nodes on VERTEXes for a case of not meshes EDGEs const SMDS_MeshNode* srcN = srcWire->VertexNode( iE ); const SMDS_MeshNode* tgtN = tgtWire->VertexNode( iE ); if ( srcN && tgtN ) src2tgtNodes.insert( make_pair( srcN, tgtN )); } else { const bool skipMedium = true, isFwd = true; StdMeshers_FaceSide srcEdge( srcFace, srcWire->Edge(iE), srcMesh, isFwd, skipMedium, srcWires[0]->FaceHelper() ); StdMeshers_FaceSide tgtEdge( tgtFace, tgtWire->Edge(iE), tgtMesh, isFwd, skipMedium, tgtHelper); vector< const SMDS_MeshNode* > srcNodes = srcEdge.GetOrderedNodes(); vector< const SMDS_MeshNode* > tgtNodes = tgtEdge.GetOrderedNodes(); if (( srcNodes.size() != tgtNodes.size() ) && tgtNodes.size() > 0 ) return SMESH_ComputeError::New( COMPERR_BAD_INPUT_MESH, "Different number of nodes on edges"); if ( !tgtNodes.empty() ) { vector< const SMDS_MeshNode* >::iterator tn = tgtNodes.begin(); //if ( srcWire->Edge(iE).Orientation() == tgtWire->Edge(iE).Orientation() ) { vector< const SMDS_MeshNode* >::iterator sn = srcNodes.begin(); for ( ; tn != tgtNodes.end(); ++tn, ++sn) src2tgtNodes.insert( make_pair( *sn, *tn )); } // else // { // vector< const SMDS_MeshNode* >::reverse_iterator sn = srcNodes.rbegin(); // for ( ; tn != tgtNodes.end(); ++tn, ++sn) // src2tgtNodes.insert( make_pair( *sn, *tn )); // } is1DComputed = true; } } } // loop on EDGEs of a WIRE } // loop on WIREs return TError(); } //================================================================================ /*! * \brief Perform projection in case if tgtFace.IsPartner( srcFace ) and in case * if projection by 3D transformation is possible */ //================================================================================ bool projectPartner(const TopoDS_Face& tgtFace, const TopoDS_Face& srcFace, const TSideVector& tgtWires, const TSideVector& srcWires, const TAssocTool::TShapeShapeMap& shape2ShapeMap, TAssocTool::TNodeNodeMap& src2tgtNodes, const bool is1DComputed) { SMESH_Mesh * tgtMesh = tgtWires[0]->GetMesh(); SMESH_Mesh * srcMesh = srcWires[0]->GetMesh(); SMESHDS_Mesh* tgtMeshDS = tgtMesh->GetMeshDS(); SMESHDS_Mesh* srcMeshDS = srcMesh->GetMeshDS(); SMESH_MesherHelper* helper = tgtWires[0]->FaceHelper(); const double tol = 1.e-7 * srcMeshDS->getMaxDim(); // transformation to get location of target nodes from source ones StdMeshers_ProjectionUtils::TrsfFinder3D trsf; bool trsfIsOK = false; if ( tgtFace.IsPartner( srcFace )) { gp_GTrsf srcTrsf = srcFace.Location().Transformation(); gp_GTrsf tgtTrsf = tgtFace.Location().Transformation(); gp_GTrsf t = srcTrsf.Inverted().Multiplied( tgtTrsf ); trsf.Set( t ); // check gp_Pnt srcP = BRep_Tool::Pnt( srcWires[0]->FirstVertex() ); gp_Pnt tgtP = BRep_Tool::Pnt( tgtWires[0]->FirstVertex() ); trsfIsOK = ( tgtP.Distance( trsf.Transform( srcP )) < tol ); if ( !trsfIsOK ) { trsf.Set( tgtTrsf.Inverted().Multiplied( srcTrsf )); trsfIsOK = ( tgtP.Distance( trsf.Transform( srcP )) < tol ); } } if ( !trsfIsOK ) { // Try to find the 3D transformation const int totNbSeg = 50; vector< gp_XYZ > srcPnts, tgtPnts; srcPnts.reserve( totNbSeg ); tgtPnts.reserve( totNbSeg ); gp_XYZ srcBC( 0,0,0 ), tgtBC( 0,0,0 ); for ( size_t iW = 0; iW < srcWires.size(); ++iW ) { const double minSegLen = srcWires[iW]->Length() / totNbSeg; for ( int iE = 0; iE < srcWires[iW]->NbEdges(); ++iE ) { size_t nbSeg = Max( 1, int( srcWires[iW]->EdgeLength( iE ) / minSegLen )); double srcU = srcWires[iW]->FirstParameter( iE ); double tgtU = tgtWires[iW]->FirstParameter( iE ); double srcDu = ( srcWires[iW]->LastParameter( iE )- srcU ) / nbSeg; double tgtDu = ( tgtWires[iW]->LastParameter( iE )- tgtU ) / nbSeg; for ( size_t i = 0; i < nbSeg; ++i ) { srcPnts.push_back( srcWires[iW]->Value3d( srcU ).XYZ() ); tgtPnts.push_back( tgtWires[iW]->Value3d( tgtU ).XYZ() ); srcU += srcDu; tgtU += tgtDu; srcBC += srcPnts.back(); tgtBC += tgtPnts.back(); } } } if ( !trsf.Solve( srcPnts, tgtPnts )) return false; // check trsf const int nbTestPnt = 20; const size_t iStep = Max( 1, int( srcPnts.size() / nbTestPnt )); // check boundary gp_Pnt trsfTgt = trsf.Transform( srcBC / srcPnts.size() ); trsfIsOK = ( trsfTgt.SquareDistance( tgtBC / tgtPnts.size() ) < tol*tol ); for ( size_t i = 0; ( i < srcPnts.size() && trsfIsOK ); i += iStep ) { gp_Pnt trsfTgt = trsf.Transform( srcPnts[i] ); trsfIsOK = ( trsfTgt.SquareDistance( tgtPnts[i] ) < tol*tol ); } // check an in-FACE point if ( trsfIsOK ) { BRepAdaptor_Surface srcSurf( srcFace ); gp_Pnt srcP = srcSurf.Value( 0.321 * ( srcSurf.FirstUParameter() + srcSurf.LastUParameter() ), 0.123 * ( srcSurf.FirstVParameter() + srcSurf.LastVParameter() )); gp_Pnt tgtTrsfP = trsf.Transform( srcP ); TopLoc_Location loc; GeomAPI_ProjectPointOnSurf& proj = helper->GetProjector( tgtFace, loc, 0.1*tol ); if ( !loc.IsIdentity() ) tgtTrsfP.Transform( loc.Transformation().Inverted() ); proj.Perform( tgtTrsfP ); trsfIsOK = ( proj.IsDone() && proj.NbPoints() > 0 && proj.LowerDistance() < tol ); } if ( !trsfIsOK ) return false; } // Make new faces // prepare the helper to adding quadratic elements if necessary helper->IsQuadraticSubMesh( tgtFace ); SMESHDS_SubMesh* srcSubDS = srcMeshDS->MeshElements( srcFace ); if ( !is1DComputed && srcSubDS->NbElements() ) helper->SetIsQuadratic( srcSubDS->GetElements()->next()->IsQuadratic() ); SMESH_MesherHelper* srcHelper = srcWires[0]->FaceHelper(); SMESH_MesherHelper edgeHelper( *tgtMesh ); edgeHelper.ToFixNodeParameters( true ); const SMDS_MeshNode* nullNode = 0; TAssocTool::TNodeNodeMap::iterator srcN_tgtN; // indices of nodes to create properly oriented faces bool isReverse = ( !trsf.IsIdentity() ); int tri1 = 1, tri2 = 2, quad1 = 1, quad3 = 3; if ( isReverse ) std::swap( tri1, tri2 ), std::swap( quad1, quad3 ); SMDS_ElemIteratorPtr elemIt = srcSubDS->GetElements(); vector< const SMDS_MeshNode* > tgtNodes; while ( elemIt->more() ) // loop on all mesh faces on srcFace { const SMDS_MeshElement* elem = elemIt->next(); const int nbN = elem->NbCornerNodes(); tgtNodes.resize( nbN ); helper->SetElementsOnShape( false ); for ( int i = 0; i < nbN; ++i ) // loop on nodes of the source element { const SMDS_MeshNode* srcNode = elem->GetNode(i); srcN_tgtN = src2tgtNodes.insert( make_pair( srcNode, nullNode )).first; if ( srcN_tgtN->second == nullNode ) { // create a new node gp_Pnt tgtP = trsf.Transform( SMESH_TNodeXYZ( srcNode )); SMDS_MeshNode* n = helper->AddNode( tgtP.X(), tgtP.Y(), tgtP.Z() ); srcN_tgtN->second = n; switch ( srcNode->GetPosition()->GetTypeOfPosition() ) { case SMDS_TOP_FACE: { gp_Pnt2d srcUV = srcHelper->GetNodeUV( srcFace, srcNode ); tgtMeshDS->SetNodeOnFace( n, helper->GetSubShapeID(), srcUV.X(), srcUV.Y() ); break; } case SMDS_TOP_EDGE: { const TopoDS_Edge& srcE = TopoDS::Edge( srcMeshDS->IndexToShape( srcNode->getshapeId())); const TopoDS_Edge& tgtE = TopoDS::Edge( shape2ShapeMap( srcE, /*isSrc=*/true )); double srcU = srcHelper->GetNodeU( srcE, srcNode ); tgtMeshDS->SetNodeOnEdge( n, tgtE, srcU ); if ( !tgtFace.IsPartner( srcFace )) { edgeHelper.SetSubShape( tgtE ); double tol = BRep_Tool::Tolerance( tgtE ); bool isOk = edgeHelper.CheckNodeU( tgtE, n, srcU, 2 * tol, /*force=*/true ); if ( !isOk ) // projection of n to tgtE failed (23395) { double sF, sL, tF, tL; BRep_Tool::Range( srcE, sF, sL ); BRep_Tool::Range( tgtE, tF, tL ); double srcR = ( srcU - sF ) / ( sL - sF ); double tgtU = tF + srcR * ( tL - tF ); tgtMeshDS->SetNodeOnEdge( n, tgtE, tgtU ); gp_Pnt newP = BRepAdaptor_Curve( tgtE ).Value( tgtU ); double dist = newP.Distance( tgtP ); if ( tol < dist && dist < 1000*tol ) tgtMeshDS->MoveNode( n, newP.X(), newP.Y(), newP.Z() ); } } break; } case SMDS_TOP_VERTEX: { const TopoDS_Shape & srcV = srcMeshDS->IndexToShape( srcNode->getshapeId() ); const TopoDS_Shape & tgtV = shape2ShapeMap( srcV, /*isSrc=*/true ); tgtMeshDS->SetNodeOnVertex( n, TopoDS::Vertex( tgtV )); break; } default:; } } tgtNodes[i] = srcN_tgtN->second; } // create a new face helper->SetElementsOnShape( true ); switch ( nbN ) { case 3: helper->AddFace(tgtNodes[0], tgtNodes[tri1], tgtNodes[tri2]); break; case 4: helper->AddFace(tgtNodes[0], tgtNodes[quad1], tgtNodes[2], tgtNodes[quad3]); break; default: if ( isReverse ) std::reverse( tgtNodes.begin(), tgtNodes.end() ); helper->AddPolygonalFace( tgtNodes ); } } // check node positions if ( !tgtFace.IsPartner( srcFace ) ) { helper->ToFixNodeParameters( true ); int nbOkPos = 0; const double tol2d = 1e-12; srcN_tgtN = src2tgtNodes.begin(); for ( ; srcN_tgtN != src2tgtNodes.end(); ++srcN_tgtN ) { const SMDS_MeshNode* n = srcN_tgtN->second; switch ( n->GetPosition()->GetTypeOfPosition() ) { case SMDS_TOP_FACE: { if ( nbOkPos > 10 ) break; gp_XY uv = helper->GetNodeUV( tgtFace, n ), uvBis = uv; if (( helper->CheckNodeUV( tgtFace, n, uv, tol )) && (( uv - uvBis ).SquareModulus() < tol2d )) ++nbOkPos; else nbOkPos = -((int) src2tgtNodes.size() ); break; } case SMDS_TOP_EDGE: { // const TopoDS_Edge & tgtE = TopoDS::Edge( tgtMeshDS->IndexToShape( n->getshapeId() )); // edgeHelper.SetSubShape( tgtE ); // edgeHelper.GetNodeU( tgtE, n, 0, &toCheck ); break; } default:; } } } return true; } // bool projectPartner() //================================================================================ /*! * \brief Perform projection in case if the faces are similar in 2D space */ //================================================================================ bool projectBy2DSimilarity(const TopoDS_Face& tgtFace, const TopoDS_Face& srcFace, const TSideVector& tgtWires, const TSideVector& srcWires, const TAssocTool::TShapeShapeMap& shape2ShapeMap, TAssocTool::TNodeNodeMap& src2tgtNodes, const bool is1DComputed) { SMESH_Mesh * tgtMesh = tgtWires[0]->GetMesh(); SMESH_Mesh * srcMesh = srcWires[0]->GetMesh(); // WARNING: we can have problems if the FACE is symmetrical in 2D, // then the projection can be mirrored relating to what is expected // 1) Find 2D transformation StdMeshers_ProjectionUtils::TrsfFinder2D trsf; { // get 2 pairs of corresponding UVs gp_Pnt2d srcP0 = srcWires[0]->Value2d(0.0); gp_Pnt2d srcP1 = srcWires[0]->Value2d(0.333); gp_Pnt2d tgtP0 = tgtWires[0]->Value2d(0.0); gp_Pnt2d tgtP1 = tgtWires[0]->Value2d(0.333); // make transformation gp_Trsf2d fromTgtCS, toSrcCS; // from/to global CS gp_Ax2d srcCS( srcP0, gp_Vec2d( srcP0, srcP1 )); gp_Ax2d tgtCS( tgtP0, gp_Vec2d( tgtP0, tgtP1 )); toSrcCS .SetTransformation( srcCS ); fromTgtCS.SetTransformation( tgtCS ); fromTgtCS.Invert(); trsf.Set( fromTgtCS * toSrcCS ); // check transformation bool trsfIsOK = true; const double tol = 1e-5 * gp_Vec2d( srcP0, srcP1 ).Magnitude(); for ( double u = 0.12; ( u < 1. && trsfIsOK ); u += 0.1 ) { gp_Pnt2d srcUV = srcWires[0]->Value2d( u ); gp_Pnt2d tgtUV = tgtWires[0]->Value2d( u ); gp_Pnt2d tgtUV2 = trsf.Transform( srcUV ); trsfIsOK = ( tgtUV.Distance( tgtUV2 ) < tol ); } // Find trsf using a least-square approximation if ( !trsfIsOK ) { // find trsf const int totNbSeg = 50; vector< gp_XY > srcPnts, tgtPnts; srcPnts.reserve( totNbSeg ); tgtPnts.reserve( totNbSeg ); for ( size_t iW = 0; iW < srcWires.size(); ++iW ) { const double minSegLen = srcWires[iW]->Length() / totNbSeg; for ( int iE = 0; iE < srcWires[iW]->NbEdges(); ++iE ) { size_t nbSeg = Max( 1, int( srcWires[iW]->EdgeLength( iE ) / minSegLen )); double srcU = srcWires[iW]->FirstParameter( iE ); double tgtU = tgtWires[iW]->FirstParameter( iE ); double srcDu = ( srcWires[iW]->LastParameter( iE )- srcU ) / nbSeg; double tgtDu = ( tgtWires[iW]->LastParameter( iE )- tgtU ) / nbSeg; for ( size_t i = 0; i < nbSeg; ++i, srcU += srcDu, tgtU += tgtDu ) { srcPnts.push_back( srcWires[iW]->Value2d( srcU ).XY() ); tgtPnts.push_back( tgtWires[iW]->Value2d( tgtU ).XY() ); } } } if ( !trsf.Solve( srcPnts, tgtPnts )) return false; // check trsf trsfIsOK = true; const int nbTestPnt = 10; const size_t iStep = Max( 1, int( srcPnts.size() / nbTestPnt )); for ( size_t i = 0; ( i < srcPnts.size() && trsfIsOK ); i += iStep ) { gp_Pnt2d trsfTgt = trsf.Transform( srcPnts[i] ); trsfIsOK = ( trsfTgt.Distance( tgtPnts[i] ) < tol ); } if ( !trsfIsOK ) return false; } } // "Find transformation" block // 2) Projection SMESHDS_SubMesh* srcSubDS = srcMesh->GetMeshDS()->MeshElements( srcFace ); SMESH_MesherHelper* helper = tgtWires[0]->FaceHelper(); if ( is1DComputed ) helper->IsQuadraticSubMesh( tgtFace ); else helper->SetIsQuadratic( srcSubDS->GetElements()->next()->IsQuadratic() ); helper->SetElementsOnShape( true ); Handle(Geom_Surface) tgtSurface = BRep_Tool::Surface( tgtFace ); SMESHDS_Mesh* tgtMeshDS = tgtMesh->GetMeshDS(); SMESH_MesherHelper* srcHelper = srcWires[0]->FaceHelper(); const SMDS_MeshNode* nullNode = 0; TAssocTool::TNodeNodeMap::iterator srcN_tgtN; SMDS_ElemIteratorPtr elemIt = srcSubDS->GetElements(); vector< const SMDS_MeshNode* > tgtNodes; bool uvOK; while ( elemIt->more() ) // loop on all mesh faces on srcFace { const SMDS_MeshElement* elem = elemIt->next(); const int nbN = elem->NbCornerNodes(); tgtNodes.resize( nbN ); for ( int i = 0; i < nbN; ++i ) // loop on nodes of the source element { const SMDS_MeshNode* srcNode = elem->GetNode(i); srcN_tgtN = src2tgtNodes.insert( make_pair( srcNode, nullNode )).first; if ( srcN_tgtN->second == nullNode ) { // create a new node gp_Pnt2d srcUV = srcHelper->GetNodeUV( srcFace, srcNode, elem->GetNode( helper->WrapIndex(i+1,nbN)), &uvOK); gp_Pnt2d tgtUV = trsf.Transform( srcUV ); gp_Pnt tgtP = tgtSurface->Value( tgtUV.X(), tgtUV.Y() ); SMDS_MeshNode* n = tgtMeshDS->AddNode( tgtP.X(), tgtP.Y(), tgtP.Z() ); switch ( srcNode->GetPosition()->GetTypeOfPosition() ) { case SMDS_TOP_FACE: { tgtMeshDS->SetNodeOnFace( n, helper->GetSubShapeID(), tgtUV.X(), tgtUV.Y() ); break; } case SMDS_TOP_EDGE: { TopoDS_Shape srcEdge = srcHelper->GetSubShapeByNode( srcNode, srcHelper->GetMeshDS() ); TopoDS_Edge tgtEdge = TopoDS::Edge( shape2ShapeMap( srcEdge, /*isSrc=*/true )); double U = Precision::Infinite(); helper->CheckNodeU( tgtEdge, n, U, Precision::PConfusion()); tgtMeshDS->SetNodeOnEdge( n, TopoDS::Edge( tgtEdge ), U ); break; } case SMDS_TOP_VERTEX: { TopoDS_Shape srcV = srcHelper->GetSubShapeByNode( srcNode, srcHelper->GetMeshDS() ); TopoDS_Shape tgtV = shape2ShapeMap( srcV, /*isSrc=*/true ); tgtMeshDS->SetNodeOnVertex( n, TopoDS::Vertex( tgtV )); break; } default:; } srcN_tgtN->second = n; } tgtNodes[i] = srcN_tgtN->second; } // create a new face (with reversed orientation) switch ( nbN ) { case 3: helper->AddFace(tgtNodes[0], tgtNodes[2], tgtNodes[1]); break; case 4: helper->AddFace(tgtNodes[0], tgtNodes[3], tgtNodes[2], tgtNodes[1]); break; } } // loop on all mesh faces on srcFace return true; } //================================================================================ /*! * \brief Perform projection in case of quadrilateral faces */ //================================================================================ bool projectQuads(const TopoDS_Face& tgtFace, const TopoDS_Face& srcFace, const TSideVector& tgtWires, const TSideVector& srcWires, const TAssocTool::TShapeShapeMap& shape2ShapeMap, TAssocTool::TNodeNodeMap& src2tgtNodes, const bool is1DComputed) { // SMESH_Mesh * tgtMesh = tgtWires[0]->GetMesh(); // SMESH_Mesh * srcMesh = srcWires[0]->GetMesh(); // //SMESHDS_Mesh * tgtMeshDS = tgtMesh->GetMeshDS(); // SMESHDS_Mesh * srcMeshDS = srcMesh->GetMeshDS(); // if ( srcWires[0]->NbEdges() != 4 ) // return false; // if ( !is1DComputed ) // return false; // for ( int iE = 0; iE < 4; ++iE ) // { // SMESHDS_SubMesh* sm = srcMeshDS->MeshElements( srcWires[0]->Edge( iE )); // if ( !sm ) return false; // if ( sm->NbNodes() + sm->NbElements() == 0 ) return false; // } // if ( BRepAdaptor_Surface( tgtFace ).GetType() != GeomAbs_Plane ) // return false; // // if ( BRepAdaptor_Surface( tgtFace ).GetType() == GeomAbs_Plane && // // BRepAdaptor_Surface( srcFace ).GetType() == GeomAbs_Plane ) // // return false; // too easy // // load EDGEs to SMESH_Block // SMESH_Block block; // TopTools_IndexedMapOfOrientedShape blockSubShapes; // { // const TopoDS_Solid& box = srcMesh->PseudoShape(); // TopoDS_Shell shell = TopoDS::Shell( TopExp_Explorer( box, TopAbs_SHELL ).Current() ); // TopoDS_Vertex v; // block.LoadBlockShapes( shell, v, v, blockSubShapes ); // fill all since operator[] is missing // } // const SMESH_Block::TShapeID srcFaceBID = SMESH_Block::ID_Fxy0; // const SMESH_Block::TShapeID tgtFaceBID = SMESH_Block::ID_Fxy1; // vector< int > edgeBID; // block.GetFaceEdgesIDs( srcFaceBID, edgeBID ); // u0, u1, 0v, 1v // blockSubShapes.Substitute( edgeBID[0], srcWires[0]->Edge(0) ); // blockSubShapes.Substitute( edgeBID[1], srcWires[0]->Edge(2) ); // blockSubShapes.Substitute( edgeBID[2], srcWires[0]->Edge(3) ); // blockSubShapes.Substitute( edgeBID[3], srcWires[0]->Edge(1) ); // block.GetFaceEdgesIDs( tgtFaceBID, edgeBID ); // u0, u1, 0v, 1v // blockSubShapes.Substitute( edgeBID[0], tgtWires[0]->Edge(0) ); // blockSubShapes.Substitute( edgeBID[1], tgtWires[0]->Edge(2) ); // blockSubShapes.Substitute( edgeBID[2], tgtWires[0]->Edge(3) ); // blockSubShapes.Substitute( edgeBID[3], tgtWires[0]->Edge(1) ); // block.LoadFace( srcFace, srcFaceBID, blockSubShapes ); // block.LoadFace( tgtFace, tgtFaceBID, blockSubShapes ); // // remember connectivity of new faces in terms of ( node-or-XY ) // typedef std::pair< const SMDS_MeshNode*, gp_XYZ > TNodeOrXY; // node-or-XY // typedef std::vector< TNodeOrXY* > TFaceConn; // face connectivity // std::vector< TFaceConn > newFacesVec; // connectivity of all faces // std::map< const SMDS_MeshNode*, TNodeOrXY > srcNode2tgtNXY; // src node -> node-or-XY // TAssocTool::TNodeNodeMap::iterator srcN_tgtN; // std::map< const SMDS_MeshNode*, TNodeOrXY >::iterator srcN_tgtNXY; // std::pair< std::map< const SMDS_MeshNode*, TNodeOrXY >::iterator, bool > n2n_isNew; // TNodeOrXY nullNXY( (SMDS_MeshNode*)NULL, gp_XYZ(0,0,0) ); // SMESHDS_SubMesh* srcSubDS = srcMeshDS->MeshElements( srcFace ); // newFacesVec.resize( srcSubDS->NbElements() ); // int iFaceSrc = 0; // SMDS_ElemIteratorPtr elemIt = srcSubDS->GetElements(); // while ( elemIt->more() ) // loop on all mesh faces on srcFace // { // const SMDS_MeshElement* elem = elemIt->next(); // TFaceConn& tgtNodes = newFacesVec[ iFaceSrc++ ]; // const int nbN = elem->NbCornerNodes(); // tgtNodes.resize( nbN ); // for ( int i = 0; i < nbN; ++i ) // loop on nodes of the source element // { // const SMDS_MeshNode* srcNode = elem->GetNode(i); // n2n_isNew = srcNode2tgtNXY.insert( make_pair( srcNode, nullNXY )); // TNodeOrXY & tgtNodeOrXY = n2n_isNew.first->second; // if ( n2n_isNew.second ) // new src node encounters // { // srcN_tgtN = src2tgtNodes.find( srcNode ); // if ( srcN_tgtN != src2tgtNodes.end() ) // { // tgtNodeOrXY.first = srcN_tgtN->second; // tgt node exists // } // else // { // // find XY of src node within the quadrilateral srcFace // if ( !block.ComputeParameters( SMESH_TNodeXYZ( srcNode ), // tgtNodeOrXY.second, srcFaceBID )) // return false; // } // } // tgtNodes[ i ] = & tgtNodeOrXY; // } // } // // as all XY are computed, create tgt nodes and faces // SMESH_MesherHelper helper = *tgtWires[0]->FaceHelper(); // if ( is1DComputed ) // helper.IsQuadraticSubMesh( tgtFace ); // else // helper.SetIsQuadratic( srcSubDS->GetElements()->next()->IsQuadratic() ); // helper.SetElementsOnShape( true ); // Handle(Geom_Surface) tgtSurface = BRep_Tool::Surface( tgtFace ); // SMESH_MesherHelper srcHelper = *srcWires[0]->FaceHelper(); // vector< const SMDS_MeshNode* > tgtNodes; // gp_XY uv; // for ( size_t iFaceTgt = 0; iFaceTgt < newFacesVec.size(); ++iFaceTgt ) // { // TFaceConn& tgtConn = newFacesVec[ iFaceTgt ]; // tgtNodes.resize( tgtConn.size() ); // for ( size_t iN = 0; iN < tgtConn.size(); ++iN ) // { // const SMDS_MeshNode* & tgtN = tgtConn[ iN ]->first; // if ( !tgtN ) // create a node // { // if ( !block.FaceUV( tgtFaceBID, tgtConn[iN]->second, uv )) // return false; // gp_Pnt p = tgtSurface->Value( uv.X(), uv.Y() ); // tgtN = helper.AddNode( p.X(), p.Y(), p.Z(), uv.X(), uv.Y() ); // } // tgtNodes[ tgtNodes.size() - iN - 1] = tgtN; // reversed orientation // } // switch ( tgtNodes.size() ) // { // case 3: helper.AddFace(tgtNodes[0], tgtNodes[1], tgtNodes[2]); break; // case 4: helper.AddFace(tgtNodes[0], tgtNodes[1], tgtNodes[2], tgtNodes[3]); break; // default: // if ( tgtNodes.size() > 4 ) // helper.AddPolygonalFace( tgtNodes ); // } // } return false; //true; } // bool projectQuads(...) //================================================================================ /*! * \brief Fix bad faces by smoothing */ //================================================================================ bool fixDistortedFaces( SMESH_MesherHelper& helper, TSideVector& tgtWires ) { SMESH_subMesh* faceSM = helper.GetMesh()->GetSubMesh( helper.GetSubShape() ); //if ( helper.IsDistorted2D( faceSM, /*checkUV=*/true )) { SMESH_MeshEditor editor( helper.GetMesh() ); SMESHDS_SubMesh* smDS = faceSM->GetSubMeshDS(); const TopoDS_Face& F = TopoDS::Face( faceSM->GetSubShape() ); TIDSortedElemSet faces; SMDS_ElemIteratorPtr faceIt = smDS->GetElements(); for ( faceIt = smDS->GetElements(); faceIt->more(); ) faces.insert( faces.end(), faceIt->next() ); // choose smoothing algo //SMESH_MeshEditor:: SmoothMethod algo = SMESH_MeshEditor::CENTROIDAL; bool isConcaveBoundary = false; for ( size_t iW = 0; iW < tgtWires.size() && !isConcaveBoundary; ++iW ) { TopoDS_Edge prevEdge = tgtWires[iW]->Edge( tgtWires[iW]->NbEdges() - 1 ); for ( int iE = 0; iE < tgtWires[iW]->NbEdges() && !isConcaveBoundary; ++iE ) { double angle = helper.GetAngle( prevEdge, tgtWires[iW]->Edge( iE ), F, tgtWires[iW]->FirstVertex( iE )); isConcaveBoundary = ( angle < -5. * M_PI / 180. ); prevEdge = tgtWires[iW]->Edge( iE ); } } SMESH_MeshEditor:: SmoothMethod algo = isConcaveBoundary ? SMESH_MeshEditor::CENTROIDAL : SMESH_MeshEditor::LAPLACIAN; // smooth in 2D or 3D? TopLoc_Location loc; Handle(Geom_Surface) surface = BRep_Tool::Surface( F, loc ); bool isPlanar = GeomLib_IsPlanarSurface( surface ).IsPlanar(); // smoothing set fixedNodes; editor.Smooth( faces, fixedNodes, algo, /*nbIterations=*/ 10, /*theTgtAspectRatio=*/1.0, /*the2D=*/!isPlanar); helper.ToFixNodeParameters( true ); return !helper.IsDistorted2D( faceSM, /*checkUV=*/true ); } return true; } //======================================================================= /* * Set initial association of VERTEXes for the case of projection * from a quadrangle FACE to a closed FACE, where opposite src EDGEs * have different nb of segments */ //======================================================================= void initAssoc4Quad2Closed(const TopoDS_Shape& tgtFace, SMESH_MesherHelper& tgtHelper, const TopoDS_Shape& srcFace, SMESH_Mesh* srcMesh, TAssocTool::TShapeShapeMap & assocMap) { if ( !tgtHelper.HasRealSeam() || srcFace.ShapeType() != TopAbs_FACE ) return; // no seam edge list< TopoDS_Edge > tgtEdges, srcEdges; list< int > tgtNbEW, srcNbEW; int tgtNbW = SMESH_Block::GetOrderedEdges( TopoDS::Face( tgtFace ), tgtEdges, tgtNbEW ); int srcNbW = SMESH_Block::GetOrderedEdges( TopoDS::Face( srcFace ), srcEdges, srcNbEW ); if ( tgtNbW != 1 || srcNbW != 1 || tgtNbEW.front() != 4 || srcNbEW.front() != 4 ) return; // not quads int srcNbSeg[4]; list< TopoDS_Edge >::iterator edgeS = srcEdges.begin(), edgeT = tgtEdges.begin(); for ( int i = 0; edgeS != srcEdges.end(); ++i, ++edgeS ) if ( SMESHDS_SubMesh* sm = srcMesh->GetMeshDS()->MeshElements( *edgeS )) srcNbSeg[ i ] = sm->NbNodes(); else return; // not meshed if ( srcNbSeg[0] == srcNbSeg[2] && srcNbSeg[1] == srcNbSeg[3] ) return; // same nb segments if ( srcNbSeg[0] != srcNbSeg[2] && srcNbSeg[1] != srcNbSeg[3] ) return; // all different nb segments edgeS = srcEdges.begin(); if ( srcNbSeg[0] != srcNbSeg[2] ) ++edgeS; TAssocTool::InsertAssociation( tgtHelper.IthVertex( 0,*edgeT ), tgtHelper.IthVertex( 0,*edgeS ), assocMap ); TAssocTool::InsertAssociation( tgtHelper.IthVertex( 1,*edgeT ), tgtHelper.IthVertex( 1,*edgeS ), assocMap ); } } // namespace //======================================================================= //function : Compute //purpose : //======================================================================= bool StdMeshers_Projection_2D::Compute(SMESH_Mesh& theMesh, const TopoDS_Shape& theShape) { _src2tgtNodes.clear(); if ( !_sourceHypo ) return false; SMESH_Mesh * srcMesh = _sourceHypo->GetSourceMesh(); SMESH_Mesh * tgtMesh = & theMesh; if ( !srcMesh ) srcMesh = tgtMesh; SMESHDS_Mesh * meshDS = theMesh.GetMeshDS(); SMESH_MesherHelper helper( theMesh ); // --------------------------- // Make sub-shapes association // --------------------------- TopoDS_Face tgtFace = TopoDS::Face( theShape.Oriented(TopAbs_FORWARD)); TopoDS_Shape srcShape = _sourceHypo->GetSourceFace().Oriented(TopAbs_FORWARD); helper.SetSubShape( tgtFace ); TAssocTool::TShapeShapeMap shape2ShapeMap; TAssocTool::InitVertexAssociation( _sourceHypo, shape2ShapeMap ); if ( shape2ShapeMap.IsEmpty() ) initAssoc4Quad2Closed( tgtFace, helper, srcShape, srcMesh, shape2ShapeMap ); if ( !TAssocTool::FindSubShapeAssociation( tgtFace, tgtMesh, srcShape, srcMesh, shape2ShapeMap) || !shape2ShapeMap.IsBound( tgtFace )) { if ( srcShape.ShapeType() == TopAbs_FACE ) { int nbE1 = helper.Count( tgtFace, TopAbs_EDGE, /*ignoreSame=*/true ); int nbE2 = helper.Count( srcShape, TopAbs_EDGE, /*ignoreSame=*/true ); if ( nbE1 != nbE2 ) return error(COMPERR_BAD_SHAPE, SMESH_Comment("Different number of edges in source and target faces: ") << nbE2 << " and " << nbE1 ); } return error(COMPERR_BAD_SHAPE,"Topology of source and target faces seems different" ); } TopoDS_Face srcFace = TopoDS::Face( shape2ShapeMap( tgtFace ).Oriented(TopAbs_FORWARD)); // ---------------------------------------------- // Assure that mesh on a source Face is computed // ---------------------------------------------- SMESH_subMesh* srcSubMesh = srcMesh->GetSubMesh( srcFace ); SMESH_subMesh* tgtSubMesh = tgtMesh->GetSubMesh( tgtFace ); string srcMeshError; if ( tgtMesh == srcMesh ) { if ( !TAssocTool::MakeComputed( srcSubMesh )) srcMeshError = TAssocTool::SourceNotComputedError( srcSubMesh, this ); } else { if ( !srcSubMesh->IsMeshComputed() ) srcMeshError = TAssocTool::SourceNotComputedError(); } if ( !srcMeshError.empty() ) return error(COMPERR_BAD_INPUT_MESH, srcMeshError ); // =========== // Projection // =========== // get ordered src and tgt EDGEs TSideVector srcWires, tgtWires; bool is1DComputed = false; // if any tgt EDGE is meshed TError err = getWires( tgtFace, srcFace, tgtMesh, srcMesh, &helper, shape2ShapeMap, srcWires, tgtWires, _src2tgtNodes, is1DComputed ); if ( err && !err->IsOK() ) return error( err ); bool projDone = false; if ( !projDone ) { // try to project from the same face with different location projDone = projectPartner( tgtFace, srcFace, tgtWires, srcWires, shape2ShapeMap, _src2tgtNodes, is1DComputed ); } if ( !projDone ) { // projection in case if the faces are similar in 2D space projDone = projectBy2DSimilarity( tgtFace, srcFace, tgtWires, srcWires, shape2ShapeMap, _src2tgtNodes, is1DComputed ); } if ( !projDone ) { // projection in case of quadrilateral faces // NOT IMPLEMENTED, returns false projDone = projectQuads( tgtFace, srcFace, tgtWires, srcWires, shape2ShapeMap, _src2tgtNodes, is1DComputed); } // it will remove mesh built on edges and vertices in failure case MeshCleaner cleaner( tgtSubMesh ); if ( !projDone ) { _src2tgtNodes.clear(); // -------------------- // Prepare to mapping // -------------------- // Check if node projection to a face is needed Bnd_B2d uvBox; SMDS_ElemIteratorPtr faceIt = srcSubMesh->GetSubMeshDS()->GetElements(); set< const SMDS_MeshNode* > faceNodes; for ( ; faceNodes.size() < 3 && faceIt->more(); ) { const SMDS_MeshElement* face = faceIt->next(); SMDS_ElemIteratorPtr nodeIt = face->nodesIterator(); while ( nodeIt->more() ) { const SMDS_MeshNode* node = static_cast( nodeIt->next() ); if ( node->GetPosition()->GetTypeOfPosition() == SMDS_TOP_FACE && faceNodes.insert( node ).second ) uvBox.Add( helper.GetNodeUV( srcFace, node )); } } bool toProjectNodes = false; if ( faceNodes.size() == 1 ) toProjectNodes = ( uvBox.IsVoid() || uvBox.CornerMin().IsEqual( gp_XY(0,0), 1e-12 )); else if ( faceNodes.size() > 1 ) toProjectNodes = ( uvBox.IsVoid() || uvBox.SquareExtent() < DBL_MIN ); // Find the corresponding source and target vertex // and flag needed to call mapper.Apply() TopoDS_Vertex srcV1, tgtV1; bool reverse = false; TopExp_Explorer vSrcExp( srcFace, TopAbs_VERTEX ); srcV1 = TopoDS::Vertex( vSrcExp.Current() ); tgtV1 = TopoDS::Vertex( shape2ShapeMap( srcV1, /*isSrc=*/true )); list< TopoDS_Edge > tgtEdges, srcEdges; list< int > nbEdgesInWires; SMESH_Block::GetOrderedEdges( tgtFace, tgtEdges, nbEdgesInWires, tgtV1 ); SMESH_Block::GetOrderedEdges( srcFace, srcEdges, nbEdgesInWires, srcV1 ); if ( nbEdgesInWires.front() > 1 ) // possible to find out orientation { TopoDS_Edge srcE1 = srcEdges.front(), tgtE1 = tgtEdges.front(); TopoDS_Shape srcE1bis = shape2ShapeMap( tgtE1 ); reverse = ( ! srcE1.IsSame( srcE1bis )); if ( ( reverse || srcE1.Orientation() != srcE1bis.Orientation() ) && nbEdgesInWires.front() > 2 && helper.IsRealSeam( tgtEdges.front() )) { if ( srcE1.Orientation() != srcE1bis.Orientation() ) reverse = true; // projection to a face with seam EDGE; pb is that GetOrderedEdges() // always puts a seam EDGE first (if possible) and as a result // we can't use only theReverse flag to correctly associate source // and target faces in the mapper. Thus we select srcV1 so that // GetOrderedEdges() to return EDGEs in a needed order TopoDS_Face tgtFaceBis = tgtFace; TopTools_MapOfShape checkedVMap( tgtEdges.size() ); checkedVMap.Add ( srcV1 ); for ( vSrcExp.Next(); vSrcExp.More(); ) { tgtFaceBis.Reverse(); tgtEdges.clear(); SMESH_Block::GetOrderedEdges( tgtFaceBis, tgtEdges, nbEdgesInWires, tgtV1 ); bool ok = true; list< TopoDS_Edge >::iterator edgeS = srcEdges.begin(), edgeT = tgtEdges.begin(); for ( ; edgeS != srcEdges.end() && ok ; ++edgeS, ++edgeT ) ok = edgeT->IsSame( shape2ShapeMap( *edgeS, /*isSrc=*/true )); if ( ok ) break; // FOUND! reverse = !reverse; if ( reverse ) { vSrcExp.Next(); while ( vSrcExp.More() && !checkedVMap.Add( vSrcExp.Current() )) vSrcExp.Next(); } else { srcV1 = TopoDS::Vertex( vSrcExp.Current() ); tgtV1 = TopoDS::Vertex( shape2ShapeMap( srcV1, /*isSrc=*/true )); srcEdges.clear(); SMESH_Block::GetOrderedEdges( srcFace, srcEdges, nbEdgesInWires, srcV1 ); } } } // for the case: project to a closed face from a non-closed face w/o vertex assoc; // avoid projecting to a seam from two EDGEs with different nb nodes on them // ( test mesh_Projection_2D_01/B1 ) if ( !_sourceHypo->HasVertexAssociation() && nbEdgesInWires.front() > 2 && helper.IsRealSeam( tgtEdges.front() )) { TopoDS_Shape srcEdge1 = shape2ShapeMap( tgtEdges.front() ); list< TopoDS_Edge >::iterator srcEdge2 = std::find( srcEdges.begin(), srcEdges.end(), srcEdge1); list< TopoDS_Edge >::iterator srcEdge3 = std::find( srcEdges.begin(), srcEdges.end(), srcEdge1.Reversed()); if ( srcEdge2 == srcEdges.end() || srcEdge3 == srcEdges.end() ) // srcEdge1 is not a seam { // find srcEdge2 which also will be projected to tgtEdges.front() for ( srcEdge2 = srcEdges.begin(); srcEdge2 != srcEdges.end(); ++srcEdge2 ) if ( !srcEdge1.IsSame( *srcEdge2 ) && tgtEdges.front().IsSame( shape2ShapeMap( *srcEdge2, /*isSrc=*/true ))) break; // compare nb nodes on srcEdge1 and srcEdge2 if ( srcEdge2 != srcEdges.end() ) { int nbN1 = 0, nbN2 = 0; if ( SMESHDS_SubMesh* sm = srcMesh->GetMeshDS()->MeshElements( srcEdge1 )) nbN1 = sm->NbNodes(); if ( SMESHDS_SubMesh* sm = srcMesh->GetMeshDS()->MeshElements( *srcEdge2 )) nbN2 = sm->NbNodes(); if ( nbN1 != nbN2 ) srcV1 = helper.IthVertex( 1, srcEdges.front() ); } } } } else if ( nbEdgesInWires.front() == 1 ) // a sole edge in a wire { TopoDS_Edge srcE1 = srcEdges.front(), tgtE1 = tgtEdges.front(); for ( size_t iW = 0; iW < srcWires.size(); ++iW ) { StdMeshers_FaceSidePtr srcWire = srcWires[iW]; for ( int iE = 0; iE < srcWire->NbEdges(); ++iE ) if ( srcE1.IsSame( srcWire->Edge( iE ))) { reverse = ( tgtE1.Orientation() != tgtWires[iW]->Edge( iE ).Orientation() ); break; } } } else { RETURN_BAD_RESULT("Bad result from SMESH_Block::GetOrderedEdges()"); } // Load pattern from the source face SMESH_Pattern mapper; mapper.Load( srcMesh, srcFace, toProjectNodes, srcV1, /*keepNodes=*/true ); if ( mapper.GetErrorCode() != SMESH_Pattern::ERR_OK ) return error(COMPERR_BAD_INPUT_MESH,"Can't load mesh pattern from the source face"); // -------------------- // Perform 2D mapping // -------------------- // Compute mesh on a target face mapper.Apply( tgtFace, tgtV1, reverse ); if ( mapper.GetErrorCode() != SMESH_Pattern::ERR_OK ) { // std::ofstream file("/tmp/Pattern.smp" ); // mapper.Save( file ); return error("Can't apply source mesh pattern to the face"); } // Create the mesh const bool toCreatePolygons = false, toCreatePolyedrs = false; mapper.MakeMesh( tgtMesh, toCreatePolygons, toCreatePolyedrs ); if ( mapper.GetErrorCode() != SMESH_Pattern::ERR_OK ) return error("Can't make mesh by source mesh pattern"); // fill _src2tgtNodes std::vector< const SMDS_MeshNode* > *srcNodes, *tgtNodes; mapper.GetInOutNodes( srcNodes, tgtNodes ); size_t nbN = std::min( srcNodes->size(), tgtNodes->size() ); for ( size_t i = 0; i < nbN; ++i ) if ( (*srcNodes)[i] && (*tgtNodes)[i] ) _src2tgtNodes.insert( make_pair( (*srcNodes)[i], (*tgtNodes)[i] )); } // end of projection using Pattern mapping { // ------------------------------------------------------------------------- // mapper doesn't take care of nodes already existing on edges and vertices, // so we must merge nodes created by it with existing ones // ------------------------------------------------------------------------- SMESH_MeshEditor::TListOfListOfNodes groupsOfNodes; // Make groups of nodes to merge // loop on EDGE and VERTEX sub-meshes of a target FACE SMESH_subMeshIteratorPtr smIt = tgtSubMesh->getDependsOnIterator(/*includeSelf=*/false, /*complexShapeFirst=*/false); while ( smIt->more() ) { SMESH_subMesh* sm = smIt->next(); SMESHDS_SubMesh* smDS = sm->GetSubMeshDS(); if ( !smDS || smDS->NbNodes() == 0 ) continue; //if ( !is1DComputed && sm->GetSubShape().ShapeType() == TopAbs_EDGE ) // break; if ( helper.IsDegenShape( sm->GetId() ) ) // to merge all nodes on degenerated { if ( sm->GetSubShape().ShapeType() == TopAbs_EDGE ) { groupsOfNodes.push_back( list< const SMDS_MeshNode* >() ); SMESH_subMeshIteratorPtr smDegenIt = sm->getDependsOnIterator(/*includeSelf=*/true,/*complexShapeFirst=*/false); while ( smDegenIt->more() ) if (( smDS = smDegenIt->next()->GetSubMeshDS() )) { SMDS_NodeIteratorPtr nIt = smDS->GetNodes(); while ( nIt->more() ) groupsOfNodes.back().push_back( nIt->next() ); } } continue; // do not treat sm of degen VERTEX } // Sort new and old nodes of a sub-mesh separately bool isSeam = helper.IsRealSeam( sm->GetId() ); enum { NEW_NODES = 0, OLD_NODES }; map< double, const SMDS_MeshNode* > u2nodesMaps[2], u2nodesOnSeam; map< double, const SMDS_MeshNode* >::iterator u_oldNode, u_newNode, u_newOnSeam, newEnd; set< const SMDS_MeshNode* > seamNodes; // mapper changed, no more "mapper puts on a seam edge nodes from 2 edges" if ( isSeam && ! getBoundaryNodes ( sm, tgtFace, u2nodesOnSeam, seamNodes )) ;//RETURN_BAD_RESULT("getBoundaryNodes() failed"); SMDS_NodeIteratorPtr nIt = smDS->GetNodes(); while ( nIt->more() ) { const SMDS_MeshNode* node = nIt->next(); bool isOld = isOldNode( node ); if ( !isOld && isSeam ) { // new node on a seam edge if ( seamNodes.count( node ) ) continue; // node is already in the map } // sort nodes on edges by their position map< double, const SMDS_MeshNode* > & pos2nodes = u2nodesMaps[isOld ? OLD_NODES : NEW_NODES]; switch ( node->GetPosition()->GetTypeOfPosition() ) { case SMDS_TOP_VERTEX: { if ( !is1DComputed && !pos2nodes.empty() ) u2nodesMaps[isOld ? NEW_NODES : OLD_NODES].insert( make_pair( 0, node )); else pos2nodes.insert( make_pair( 0, node )); break; } case SMDS_TOP_EDGE: { const SMDS_EdgePosition* pos = static_cast(node->GetPosition()); pos2nodes.insert( make_pair( pos->GetUParameter(), node )); break; } default: RETURN_BAD_RESULT("Wrong node position type: "<< node->GetPosition()->GetTypeOfPosition()); } } const bool mergeNewToOld = ( u2nodesMaps[ NEW_NODES ].size() == u2nodesMaps[ OLD_NODES ].size() ); const bool mergeSeamToNew = ( u2nodesMaps[ NEW_NODES ].size() == u2nodesOnSeam.size() ); if ( !mergeNewToOld ) if ( u2nodesMaps[ NEW_NODES ].size() > 0 && u2nodesMaps[ OLD_NODES ].size() > 0 ) { u_oldNode = u2nodesMaps[ OLD_NODES ].begin(); newEnd = u2nodesMaps[ OLD_NODES ].end(); for ( ; u_oldNode != newEnd; ++u_oldNode ) SMESH_Algo::addBadInputElement( u_oldNode->second ); return error( COMPERR_BAD_INPUT_MESH, SMESH_Comment( "Existing mesh mismatches the projected 2D mesh on " ) << ( sm->GetSubShape().ShapeType() == TopAbs_EDGE ? "edge" : "vertex" ) << " #" << sm->GetId() ); } if ( isSeam && !mergeSeamToNew ) { const TopoDS_Shape& seam = sm->GetSubShape(); if ( u2nodesMaps[ NEW_NODES ].size() > 0 && u2nodesOnSeam.size() > 0 && seam.ShapeType() == TopAbs_EDGE ) { int nbE1 = helper.Count( tgtFace, TopAbs_EDGE, /*ignoreSame=*/true ); int nbE2 = helper.Count( srcFace, TopAbs_EDGE, /*ignoreSame=*/true ); if ( nbE1 != nbE2 ) // 2 EDGEs are mapped to a seam EDGE { // find the 2 EDGEs of srcFace TopTools_DataMapIteratorOfDataMapOfShapeShape src2tgtIt( shape2ShapeMap._map2to1 ); for ( ; src2tgtIt.More(); src2tgtIt.Next() ) if ( seam.IsSame( src2tgtIt.Value() )) SMESH_Algo::addBadInputElements ( srcMesh->GetMeshDS()->MeshElements( src2tgtIt.Key() )); return error( COMPERR_BAD_INPUT_MESH, "Different number of nodes on two edges projected to a seam edge" ); } } } // Make groups of nodes to merge u_oldNode = u2nodesMaps[ OLD_NODES ].begin(); u_newNode = u2nodesMaps[ NEW_NODES ].begin(); newEnd = u2nodesMaps[ NEW_NODES ].end(); u_newOnSeam = u2nodesOnSeam.begin(); if ( mergeNewToOld ) for ( ; u_newNode != newEnd; ++u_newNode, ++u_oldNode ) { groupsOfNodes.push_back( list< const SMDS_MeshNode* >() ); groupsOfNodes.back().push_back( u_oldNode->second ); groupsOfNodes.back().push_back( u_newNode->second ); if ( mergeSeamToNew ) groupsOfNodes.back().push_back( (u_newOnSeam++)->second ); } else if ( mergeSeamToNew ) for ( ; u_newNode != newEnd; ++u_newNode, ++u_newOnSeam ) { groupsOfNodes.push_back( list< const SMDS_MeshNode* >() ); groupsOfNodes.back().push_back( u_newNode->second ); groupsOfNodes.back().push_back( u_newOnSeam->second ); } } // loop on EDGE and VERTEX submeshes of a target FACE // Merge SMESH_MeshEditor editor( tgtMesh ); int nbFaceBeforeMerge = tgtSubMesh->GetSubMeshDS()->NbElements(); editor.MergeNodes( groupsOfNodes ); int nbFaceAtferMerge = tgtSubMesh->GetSubMeshDS()->NbElements(); if ( nbFaceBeforeMerge != nbFaceAtferMerge && !helper.HasDegeneratedEdges() ) return error(COMPERR_BAD_INPUT_MESH, "Probably invalid node parameters on geom faces"); // ---------------------------------------------------------------- // The mapper can't create quadratic elements, so convert if needed // ---------------------------------------------------------------- SMDS_ElemIteratorPtr faceIt; faceIt = srcSubMesh->GetSubMeshDS()->GetElements(); bool srcIsQuad = faceIt->next()->IsQuadratic(); faceIt = tgtSubMesh->GetSubMeshDS()->GetElements(); bool tgtIsQuad = faceIt->next()->IsQuadratic(); if ( srcIsQuad && !tgtIsQuad ) { TIDSortedElemSet tgtFaces; faceIt = tgtSubMesh->GetSubMeshDS()->GetElements(); while ( faceIt->more() ) tgtFaces.insert( tgtFaces.end(), faceIt->next() ); editor.ConvertToQuadratic(/*theForce3d=*/false, tgtFaces, false); } } // end of coincident nodes and quadratic elements treatment if ( !projDone || is1DComputed ) // ---------------------------------------------------------------- // The mapper can create distorted faces by placing nodes out of the FACE // boundary, also bad face can be created if EDGEs already discretized // --> fix bad faces by smoothing // ---------------------------------------------------------------- if ( helper.IsDistorted2D( tgtSubMesh, /*checkUV=*/false, &helper )) { TAssocTool::Morph morph( srcWires ); morph.Perform( helper, tgtWires, helper.GetSurface( tgtFace ), _src2tgtNodes, /*moveAll=*/true ); if ( !fixDistortedFaces( helper, tgtWires )) return error("Invalid mesh generated"); } // --------------------------- // Check elements orientation // --------------------------- TopoDS_Face face = TopoDS::Face( theShape ); if ( !theMesh.IsMainShape( tgtFace )) { // find the main shape TopoDS_Shape mainShape = meshDS->ShapeToMesh(); switch ( mainShape.ShapeType() ) { case TopAbs_SHELL: case TopAbs_SOLID: break; default: TopTools_ListIteratorOfListOfShape ancestIt = theMesh.GetAncestors( face ); for ( ; ancestIt.More(); ancestIt.Next() ) { TopAbs_ShapeEnum type = ancestIt.Value().ShapeType(); if ( type == TopAbs_SOLID ) { mainShape = ancestIt.Value(); break; } else if ( type == TopAbs_SHELL ) { mainShape = ancestIt.Value(); } } } // find tgtFace in the main solid or shell to know it's true orientation. TopExp_Explorer exp( mainShape, TopAbs_FACE ); for ( ; exp.More(); exp.Next() ) { if ( tgtFace.IsSame( exp.Current() )) { face = TopoDS::Face( exp.Current() ); break; } } } // Fix orientation if ( helper.IsReversedSubMesh( face )) { SMESH_MeshEditor editor( tgtMesh ); SMDS_ElemIteratorPtr eIt = meshDS->MeshElements( face )->GetElements(); while ( eIt->more() ) { const SMDS_MeshElement* e = eIt->next(); if ( e->GetType() == SMDSAbs_Face && !editor.Reorient( e )) RETURN_BAD_RESULT("Pb of SMESH_MeshEditor::Reorient()"); } } cleaner.Release(); // not to remove mesh return true; } //======================================================================= //function : Evaluate //purpose : //======================================================================= bool StdMeshers_Projection_2D::Evaluate(SMESH_Mesh& theMesh, const TopoDS_Shape& theShape, MapShapeNbElems& aResMap) { if ( !_sourceHypo ) return false; SMESH_Mesh * srcMesh = _sourceHypo->GetSourceMesh(); SMESH_Mesh * tgtMesh = & theMesh; if ( !srcMesh ) srcMesh = tgtMesh; // --------------------------- // Make sub-shapes association // --------------------------- TopoDS_Face tgtFace = TopoDS::Face( theShape.Oriented(TopAbs_FORWARD)); TopoDS_Shape srcShape = _sourceHypo->GetSourceFace().Oriented(TopAbs_FORWARD); TAssocTool::TShapeShapeMap shape2ShapeMap; TAssocTool::InitVertexAssociation( _sourceHypo, shape2ShapeMap ); if ( !TAssocTool::FindSubShapeAssociation( tgtFace, tgtMesh, srcShape, srcMesh, shape2ShapeMap) || !shape2ShapeMap.IsBound( tgtFace )) return error(COMPERR_BAD_SHAPE,"Topology of source and target faces seems different" ); TopoDS_Face srcFace = TopoDS::Face( shape2ShapeMap( tgtFace ).Oriented(TopAbs_FORWARD)); // ------------------------------------------------------- // Assure that mesh on a source Face is computed/evaluated // ------------------------------------------------------- std::vector aVec; SMESH_subMesh* srcSubMesh = srcMesh->GetSubMesh( srcFace ); if ( srcSubMesh->IsMeshComputed() ) { aVec.resize( SMDSEntity_Last, 0 ); aVec[SMDSEntity_Node] = srcSubMesh->GetSubMeshDS()->NbNodes(); SMDS_ElemIteratorPtr elemIt = srcSubMesh->GetSubMeshDS()->GetElements(); while ( elemIt->more() ) aVec[ elemIt->next()->GetEntityType() ]++; } else { MapShapeNbElems tmpResMap; MapShapeNbElems& srcResMap = (srcMesh == tgtMesh) ? aResMap : tmpResMap; if ( !_gen->Evaluate( *srcMesh, srcShape, srcResMap )) return error(COMPERR_BAD_INPUT_MESH,"Source mesh not evaluatable"); aVec = srcResMap[ srcSubMesh ]; if ( aVec.empty() ) return error(COMPERR_BAD_INPUT_MESH,"Source mesh is wrongly evaluated"); } SMESH_subMesh * sm = theMesh.GetSubMesh(theShape); aResMap.insert(std::make_pair(sm,aVec)); return true; } //============================================================================= /*! * \brief Sets a default event listener to submesh of the source face * \param subMesh - submesh where algo is set * * This method is called when a submesh gets HYP_OK algo_state. * After being set, event listener is notified on each event of a submesh. * Arranges that CLEAN event is translated from source submesh to * the submesh */ //============================================================================= void StdMeshers_Projection_2D::SetEventListener(SMESH_subMesh* subMesh) { TAssocTool::SetEventListener( subMesh, _sourceHypo->GetSourceFace(), _sourceHypo->GetSourceMesh() ); }