X-Git-Url: http://git.salome-platform.org/gitweb/?p=modules%2Fsmesh.git;a=blobdiff_plain;f=src%2FStdMeshers%2FStdMeshers_Prism_3D.cxx;h=fbc5704bd593eb2e66cc9112afab729a84c327da;hp=6019723a70d581e3811def71d7c2751cec3a0ea4;hb=54ea8ad8bb8eec2dfb66fe733675c7aa8e266d6e;hpb=b0a908c0d20341651771d0249fb10882f54b2aad diff --git a/src/StdMeshers/StdMeshers_Prism_3D.cxx b/src/StdMeshers/StdMeshers_Prism_3D.cxx index 6019723a7..fbc5704bd 100644 --- a/src/StdMeshers/StdMeshers_Prism_3D.cxx +++ b/src/StdMeshers/StdMeshers_Prism_3D.cxx @@ -65,18 +65,19 @@ using namespace std; #define RETURN_BAD_RESULT(msg) { MESSAGE(")-: Error: " << msg); return false; } -#define gpXYZ(n) gp_XYZ(n->X(),n->Y(),n->Z()) -#define SHOWYXZ(msg, xyz) // {\ -// gp_Pnt p (xyz); \ -// cout << msg << " ("<< p.X() << "; " <GetGen() ); return algo; } + const NSProjUtils::TNodeNodeMap& GetNodesMap() + { + return _src2tgtNodes; + } }; + //======================================================================= + /*! + * \brief Returns already computed EDGEs + */ + void getPrecomputedEdges( SMESH_MesherHelper& theHelper, + const TopoDS_Shape& theShape, + vector< TopoDS_Edge >& theEdges) + { + theEdges.clear(); + + SMESHDS_Mesh* meshDS = theHelper.GetMeshDS(); + SMESHDS_SubMesh* sm; + + TopTools_IndexedMapOfShape edges; + TopExp::MapShapes( theShape, TopAbs_EDGE, edges ); + for ( int iE = 1; iE <= edges.Extent(); ++iE ) + { + const TopoDS_Shape edge = edges( iE ); + if (( ! ( sm = meshDS->MeshElements( edge ))) || + ( sm->NbElements() == 0 )) + continue; + + // there must not be FACEs meshed with triangles and sharing a computed EDGE + // as the precomputed EDGEs are used for propagation other to 'vertical' EDGEs + bool faceFound = false; + PShapeIteratorPtr faceIt = + theHelper.GetAncestors( edge, *theHelper.GetMesh(), TopAbs_FACE ); + while ( const TopoDS_Shape* face = faceIt->next() ) + + if (( sm = meshDS->MeshElements( *face )) && + ( sm->NbElements() > 0 ) && + ( !theHelper.IsSameElemGeometry( sm, SMDSGeom_QUADRANGLE ) )) + { + faceFound = true; + break; + } + if ( !faceFound ) + theEdges.push_back( TopoDS::Edge( edge )); + } + } //================================================================================ /*! @@ -172,6 +217,7 @@ namespace { quad->side[ QUAD_TOP_SIDE ].grid->Reverse(); quad->side[ QUAD_LEFT_SIDE ].grid->Reverse(); int edgeIndex = 0; + bool isComposite = false; for ( size_t i = 0; i < quad->side.size(); ++i ) { StdMeshers_FaceSidePtr quadSide = quad->side[i]; @@ -179,7 +225,7 @@ namespace { if ( botE.IsSame( quadSide->Edge( iE ))) { if ( quadSide->NbEdges() > 1 ) - return false; + isComposite = true; //return false; edgeIndex = i; i = quad->side.size(); // to quit from the outer loop break; @@ -190,7 +236,7 @@ namespace { quad->face = TopoDS::Face( face ); - return true; + return !isComposite; } //================================================================================ @@ -385,10 +431,10 @@ namespace { */ //================================================================================ - double normAngle(const TopoDS_Edge & E1, const TopoDS_Edge & E2, const TopoDS_Face & F) - { - return SMESH_MesherHelper::GetAngle( E1, E2, F ) / ( 0.5 * M_PI ); - } + // double normAngle(const TopoDS_Edge & E1, const TopoDS_Edge & E2, const TopoDS_Face & F) + // { + // return SMESH_MesherHelper::GetAngle( E1, E2, F ) / ( 0.5 * M_PI ); + // } //================================================================================ /*! @@ -497,7 +543,7 @@ StdMeshers_Prism_3D::StdMeshers_Prism_3D(int hypId, int studyId, SMESH_Gen* gen) { _name = "Prism_3D"; _shapeType = (1 << TopAbs_SOLID); // 1 bit per shape type - _onlyUnaryInput = false; // accept all SOLIDs at once + _onlyUnaryInput = false; // mesh all SOLIDs at once _requireDiscreteBoundary = false; // mesh FACEs and EDGEs by myself _supportSubmeshes = true; // "source" FACE must be meshed by other algo _neededLowerHyps[ 1 ] = true; // suppress warning on hiding a global 1D algo @@ -536,12 +582,12 @@ bool StdMeshers_Prism_3D::CheckHypothesis(SMESH_Mesh& a for ( ; exp.More(); exp.Next() ) { ++nbFace; const TopoDS_Shape& face = exp.Current(); - nbEdge = TAssocTool::Count( face, TopAbs_EDGE, 0 ); - nbWire = TAssocTool::Count( face, TopAbs_WIRE, 0 ); + nbEdge = NSProjUtils::Count( face, TopAbs_EDGE, 0 ); + nbWire = NSProjUtils::Count( face, TopAbs_WIRE, 0 ); if ( nbEdge!= 4 || nbWire!= 1 ) { if ( !notQuadFaces.empty() ) { - if ( TAssocTool::Count( notQuadFaces.back(), TopAbs_EDGE, 0 ) != nbEdge || - TAssocTool::Count( notQuadFaces.back(), TopAbs_WIRE, 0 ) != nbWire ) + if ( NSProjUtils::Count( notQuadFaces.back(), TopAbs_EDGE, 0 ) != nbEdge || + NSProjUtils::Count( notQuadFaces.back(), TopAbs_WIRE, 0 ) != nbWire ) RETURN_BAD_RESULT("Different not quad faces"); } notQuadFaces.push_back( face ); @@ -553,7 +599,7 @@ bool StdMeshers_Prism_3D::CheckHypothesis(SMESH_Mesh& a RETURN_BAD_RESULT("Bad nb not quad faces: " << notQuadFaces.size()); // check total nb faces - nbEdge = TAssocTool::Count( notQuadFaces.back(), TopAbs_EDGE, 0 ); + nbEdge = NSProjUtils::Count( notQuadFaces.back(), TopAbs_EDGE, 0 ); if ( nbFace != nbEdge + 2 ) RETURN_BAD_RESULT("Bad nb of faces: " << nbFace << " but must be " << nbEdge + 2); } @@ -614,6 +660,7 @@ bool StdMeshers_Prism_3D::Compute(SMESH_Mesh& theMesh, const TopoDS_Shape& theSh meshedFaces.splice( meshedFaces.begin(), notQuadMeshedFaces ); Prism_3D::TPrismTopo prism; + myPropagChains = 0; if ( nbSolids == 1 ) { @@ -623,6 +670,21 @@ bool StdMeshers_Prism_3D::Compute(SMESH_Mesh& theMesh, const TopoDS_Shape& theSh compute( prism )); } + // find propagation chains from already computed EDGEs + vector< TopoDS_Edge > computedEdges; + getPrecomputedEdges( helper, theShape, computedEdges ); + myPropagChains = new TopTools_IndexedMapOfShape[ computedEdges.size() + 1 ]; + SMESHUtils::ArrayDeleter< TopTools_IndexedMapOfShape > pcDel( myPropagChains ); + for ( size_t i = 0, nb = 0; i < computedEdges.size(); ++i ) + { + StdMeshers_ProjectionUtils::GetPropagationEdge( &theMesh, TopoDS_Edge(), + computedEdges[i], myPropagChains + nb ); + if ( myPropagChains[ nb ].Extent() < 2 ) // an empty map is a termination sign + myPropagChains[ nb ].Clear(); + else + nb++; + } + TopTools_MapOfShape meshedSolids; list< Prism_3D::TPrismTopo > meshedPrism; TopTools_ListIteratorOfListOfShape solidIt; @@ -650,7 +712,11 @@ bool StdMeshers_Prism_3D::Compute(SMESH_Mesh& theMesh, const TopoDS_Shape& theSh !compute( prism )) return false; - meshedFaces.push_front( prism.myTop ); + SMESHDS_SubMesh* smDS = theMesh.GetMeshDS()->MeshElements( prism.myTop ); + if ( !myHelper->IsSameElemGeometry( smDS, SMDSGeom_QUADRANGLE )) + { + meshedFaces.push_front( prism.myTop ); + } meshedPrism.push_back( prism ); } } @@ -691,6 +757,7 @@ bool StdMeshers_Prism_3D::Compute(SMESH_Mesh& theMesh, const TopoDS_Shape& theSh prism.myBottom = candidateF; mySetErrorToSM = false; if ( !myHelper->IsSubShape( candidateF, prismIt->myShape3D ) && + myHelper->IsSubShape( candidateF, solid ) && !myHelper->GetMesh()->GetSubMesh( candidateF )->IsMeshComputed() && initPrism( prism, solid ) && project2dMesh( prismIt->myBottom, candidateF)) @@ -698,8 +765,12 @@ bool StdMeshers_Prism_3D::Compute(SMESH_Mesh& theMesh, const TopoDS_Shape& theSh mySetErrorToSM = true; if ( !compute( prism )) return false; - meshedFaces.push_front( prism.myTop ); - meshedFaces.push_front( prism.myBottom ); + SMESHDS_SubMesh* smDS = theMesh.GetMeshDS()->MeshElements( prism.myTop ); + if ( !myHelper->IsSameElemGeometry( smDS, SMDSGeom_QUADRANGLE )) + { + meshedFaces.push_front( prism.myTop ); + meshedFaces.push_front( prism.myBottom ); + } meshedPrism.push_back( prism ); meshedSolids.Add( solid ); } @@ -841,10 +912,17 @@ bool StdMeshers_Prism_3D::getWallFaces( Prism_3D::TPrismTopo & thePrism, if ( !quadList.back() ) return toSM( error(TCom("Side face #") << shapeID( face ) << " not meshable with quadrangles")); - if ( ! setBottomEdge( *edge, quadList.back(), face )) - return toSM( error(TCom("Composite 'horizontal' edges are not supported"))); - thePrism.myWallQuads.push_back( quadList ); - faceMap.Add( face ); + bool isCompositeBase = ! setBottomEdge( *edge, quadList.back(), face ); + if ( isCompositeBase ) + { + // it's OK if all EDGEs of the bottom side belongs to the bottom FACE + StdMeshers_FaceSidePtr botSide = quadList.back()->side[ QUAD_BOTTOM_SIDE ]; + for ( int iE = 0; iE < botSide->NbEdges(); ++iE ) + if ( !myHelper->IsSubShape( botSide->Edge(iE), thePrism.myBottom )) + return toSM( error(TCom("Composite 'horizontal' edges are not supported"))); + } + if ( faceMap.Add( face )) + thePrism.myWallQuads.push_back( quadList ); break; } } @@ -909,6 +987,7 @@ bool StdMeshers_Prism_3D::getWallFaces( Prism_3D::TPrismTopo & thePrism, // find wall FACEs adjacent to each of thePrism.myWallQuads by the top side EDGE if ( totalNbFaces - faceMap.Extent() > 2 ) { + const int nbFoundWalls = faceMap.Extent(); for ( size_t i = 0; i < thePrism.myWallQuads.size(); ++i ) { StdMeshers_FaceSidePtr topSide = thePrism.myWallQuads[i].back()->side[ QUAD_TOP_SIDE ]; @@ -935,6 +1014,9 @@ bool StdMeshers_Prism_3D::getWallFaces( Prism_3D::TPrismTopo & thePrism, } } } + if ( nbFoundWalls == faceMap.Extent() ) + return toSM( error("Failed to find wall faces")); + } } // while ( totalNbFaces - faceMap.Extent() > 2 ) @@ -983,6 +1065,8 @@ bool StdMeshers_Prism_3D::compute(const Prism_3D::TPrismTopo& thePrism) return false; // Analyse mesh and geometry to find all block sub-shapes and submeshes + // (after fixing IPAL52499 myBlock is used only as a holder of boundary nodes + // and location of internal nodes is computed by StdMeshers_Sweeper) if ( !myBlock.Init( myHelper, thePrism )) return toSM( error( myBlock.GetError())); @@ -993,10 +1077,10 @@ bool StdMeshers_Prism_3D::compute(const Prism_3D::TPrismTopo& thePrism) // Try to get gp_Trsf to get all nodes from bottom ones vector trsf; gp_Trsf bottomToTopTrsf; - if ( !myBlock.GetLayersTransformation( trsf, thePrism )) - trsf.clear(); - else if ( !trsf.empty() ) - bottomToTopTrsf = trsf.back(); + // if ( !myBlock.GetLayersTransformation( trsf, thePrism )) + // trsf.clear(); + // else if ( !trsf.empty() ) + // bottomToTopTrsf = trsf.back(); // To compute coordinates of a node inside a block, it is necessary to know // 1. normalized parameters of the node by which @@ -1012,37 +1096,36 @@ bool StdMeshers_Prism_3D::compute(const Prism_3D::TPrismTopo& thePrism) // Projections on the top and bottom faces are taken from nodes existing // on these faces; find correspondence between bottom and top nodes myBotToColumnMap.clear(); - if ( !assocOrProjBottom2Top( bottomToTopTrsf ) ) // it also fills myBotToColumnMap + if ( !assocOrProjBottom2Top( bottomToTopTrsf, thePrism ) ) // it also fills myBotToColumnMap return false; // Create nodes inside the block - // try to use transformation (issue 0020680) - if ( !trsf.empty() ) + // use transformation (issue 0020680, IPAL0052499) + StdMeshers_Sweeper sweeper; + + // load boundary nodes + bool dummy; + list< TopoDS_Edge >::const_iterator edge = thePrism.myBottomEdges.begin(); + for ( ; edge != thePrism.myBottomEdges.end(); ++edge ) { - // loop on nodes inside the bottom face - TNode2ColumnMap::iterator bot_column = myBotToColumnMap.begin(); - for ( ; bot_column != myBotToColumnMap.end(); ++bot_column ) - { - const Prism_3D::TNode& tBotNode = bot_column->first; // bottom TNode - if ( tBotNode.GetPositionType() != SMDS_TOP_FACE ) - continue; // node is not inside face + int edgeID = meshDS->ShapeToIndex( *edge ); + TParam2ColumnMap* u2col = const_cast + ( myBlock.GetParam2ColumnMap( edgeID, dummy )); + TParam2ColumnMap::iterator u2colIt = u2col->begin(); + for ( ; u2colIt != u2col->end(); ++u2colIt ) + sweeper.myBndColumns.push_back( & u2colIt->second ); + } + // load node columns inside the bottom face + TNode2ColumnMap::iterator bot_column = myBotToColumnMap.begin(); + for ( ; bot_column != myBotToColumnMap.end(); ++bot_column ) + sweeper.myIntColumns.push_back( & bot_column->second ); - // column nodes; middle part of the column are zero pointers - TNodeColumn& column = bot_column->second; - TNodeColumn::iterator columnNodes = column.begin(); - for ( int z = 0; columnNodes != column.end(); ++columnNodes, ++z) - { - const SMDS_MeshNode* & node = *columnNodes; - if ( node ) continue; // skip bottom or top node + const double tol = getSweepTolerance( thePrism ); - gp_XYZ coords = tBotNode.GetCoords(); - trsf[z-1].Transforms( coords ); - node = meshDS->AddNode( coords.X(), coords.Y(), coords.Z() ); - meshDS->SetNodeInVolume( node, volumeID ); - } - } // loop on bottom nodes + if ( sweeper.ComputeNodes( *myHelper, tol )) + { } else // use block approach { @@ -1053,7 +1136,7 @@ bool StdMeshers_Prism_3D::compute(const Prism_3D::TPrismTopo& thePrism) { const Prism_3D::TNode& tBotNode = bot_column->first; // bottom TNode if ( tBotNode.GetPositionType() != SMDS_TOP_FACE ) - continue; // node is not inside the FACE + continue; // node is not inside the FACE // column nodes; middle part of the column are zero pointers TNodeColumn& column = bot_column->second; @@ -1129,6 +1212,9 @@ bool StdMeshers_Prism_3D::compute(const Prism_3D::TPrismTopo& thePrism) // create a node node = meshDS->AddNode( coords.X(), coords.Y(), coords.Z() ); meshDS->SetNodeInVolume( node, volumeID ); + + if ( _computeCanceled ) + return false; } } // loop on bottom nodes } @@ -1187,37 +1273,39 @@ bool StdMeshers_Prism_3D::computeWalls(const Prism_3D::TPrismTopo& thePrism) SMESHDS_Mesh* meshDS = myHelper->GetMeshDS(); DBGOUT( endl << "COMPUTE Prism " << meshDS->ShapeToIndex( thePrism.myShape3D )); - TProjction1dAlgo* projector1D = TProjction1dAlgo::instance( this ); + TProjction1dAlgo* projector1D = TProjction1dAlgo::instance( this ); StdMeshers_Quadrangle_2D* quadAlgo = TQuadrangleAlgo::instance( this, myHelper ); - SMESH_HypoFilter hyp1dFilter( SMESH_HypoFilter::IsAlgo(),/*not=*/true); - hyp1dFilter.And( SMESH_HypoFilter::HasDim( 1 )); - hyp1dFilter.And( SMESH_HypoFilter::IsMoreLocalThan( thePrism.myShape3D, *mesh )); + // SMESH_HypoFilter hyp1dFilter( SMESH_HypoFilter::IsAlgo(),/*not=*/true); + // hyp1dFilter.And( SMESH_HypoFilter::HasDim( 1 )); + // hyp1dFilter.And( SMESH_HypoFilter::IsMoreLocalThan( thePrism.myShape3D, *mesh )); // Discretize equally 'vertical' EDGEs // ----------------------------------- // find source FACE sides for projection: either already computed ones or // the 'most composite' ones - multimap< int, int > wgt2quad; - for ( size_t iW = 0; iW != thePrism.myWallQuads.size(); ++iW ) + const size_t nbWalls = thePrism.myWallQuads.size(); + vector< int > wgt( nbWalls, 0 ); // "weight" of a wall + for ( size_t iW = 0; iW != nbWalls; ++iW ) { Prism_3D::TQuadList::const_iterator quad = thePrism.myWallQuads[iW].begin(); - int wgt = 0; // "weight" for ( ; quad != thePrism.myWallQuads[iW].end(); ++quad ) { StdMeshers_FaceSidePtr lftSide = (*quad)->side[ QUAD_LEFT_SIDE ]; for ( int i = 0; i < lftSide->NbEdges(); ++i ) { - ++wgt; + ++wgt[ iW ]; const TopoDS_Edge& E = lftSide->Edge(i); if ( mesh->GetSubMesh( E )->IsMeshComputed() ) - wgt += 10; - else if ( mesh->GetHypothesis( E, hyp1dFilter, true )) // local hypothesis! - wgt += 100; + { + wgt[ iW ] += 100; + wgt[ myHelper->WrapIndex( iW+1, nbWalls)] += 10; + wgt[ myHelper->WrapIndex( iW-1, nbWalls)] += 10; + } + // else if ( mesh->GetHypothesis( E, hyp1dFilter, true )) // local hypothesis! + // wgt += 100; } } - wgt2quad.insert( make_pair( wgt, iW )); - // in quadratic mesh, pass ignoreMediumNodes to quad sides if ( myHelper->GetIsQuadratic() ) { @@ -1227,6 +1315,9 @@ bool StdMeshers_Prism_3D::computeWalls(const Prism_3D::TPrismTopo& thePrism) (*quad)->side[ i ].grid->SetIgnoreMediumNodes( true ); } } + multimap< int, int > wgt2quad; + for ( size_t iW = 0; iW != nbWalls; ++iW ) + wgt2quad.insert( make_pair( wgt[ iW ], iW )); // Project 'vertical' EDGEs, from left to right multimap< int, int >::reverse_iterator w2q = wgt2quad.rbegin(); @@ -1252,8 +1343,17 @@ bool StdMeshers_Prism_3D::computeWalls(const Prism_3D::TPrismTopo& thePrism) SMESH_subMesh* srcSM = mesh->GetSubMesh( srcE ); if ( !srcSM->IsMeshComputed() ) { DBGOUT( "COMPUTE V edge " << srcSM->GetId() ); - srcSM->ComputeSubMeshStateEngine( SMESH_subMesh::COMPUTE ); - srcSM->ComputeStateEngine ( SMESH_subMesh::COMPUTE ); + TopoDS_Edge prpgSrcE = findPropagationSource( srcE ); + if ( !prpgSrcE.IsNull() ) { + srcSM->ComputeSubMeshStateEngine( SMESH_subMesh::COMPUTE ); + projector1D->myHyp.SetSourceEdge( prpgSrcE ); + projector1D->Compute( *mesh, srcE ); + srcSM->ComputeStateEngine( SMESH_subMesh::CHECK_COMPUTE_STATE ); + } + else { + srcSM->ComputeSubMeshStateEngine( SMESH_subMesh::COMPUTE ); + srcSM->ComputeStateEngine ( SMESH_subMesh::COMPUTE ); + } if ( !srcSM->IsMeshComputed() ) return toSM( error( "Can't compute 1D mesh" )); } @@ -1266,7 +1366,11 @@ bool StdMeshers_Prism_3D::computeWalls(const Prism_3D::TPrismTopo& thePrism) { const TopoDS_Edge& tgtE = rgtSide->Edge(i); SMESH_subMesh* tgtSM = mesh->GetSubMesh( tgtE ); - if (( isTgtEdgeComputed[ i ] = tgtSM->IsMeshComputed() )) { + if ( !( isTgtEdgeComputed[ i ] = tgtSM->IsMeshComputed() )) { + tgtSM->ComputeSubMeshStateEngine( SMESH_subMesh::COMPUTE ); + tgtSM->ComputeStateEngine ( SMESH_subMesh::COMPUTE ); + } + if ( tgtSM->IsMeshComputed() ) { ++nbTgtMeshed; nbTgtSegments += tgtSM->GetSubMeshDS()->NbElements(); } @@ -1275,16 +1379,33 @@ bool StdMeshers_Prism_3D::computeWalls(const Prism_3D::TPrismTopo& thePrism) { if ( nbTgtSegments != nbSrcSegments ) { - for ( int i = 0; i < lftSide->NbEdges(); ++i ) - addBadInputElements( meshDS->MeshElements( lftSide->Edge( i ))); + bool badMeshRemoved = false; + // remove just computed segments for ( int i = 0; i < rgtSide->NbEdges(); ++i ) - addBadInputElements( meshDS->MeshElements( rgtSide->Edge( i ))); - return toSM( error( TCom("Different nb of segment on logically vertical edges #") - << shapeID( lftSide->Edge(0) ) << " and #" - << shapeID( rgtSide->Edge(0) ) << ": " - << nbSrcSegments << " != " << nbTgtSegments )); + if ( !isTgtEdgeComputed[ i ]) + { + const TopoDS_Edge& tgtE = rgtSide->Edge(i); + SMESH_subMesh* tgtSM = mesh->GetSubMesh( tgtE ); + tgtSM->ComputeStateEngine( SMESH_subMesh::CLEAN ); + badMeshRemoved = true; + nbTgtMeshed--; + } + if ( !badMeshRemoved ) + { + for ( int i = 0; i < lftSide->NbEdges(); ++i ) + addBadInputElements( meshDS->MeshElements( lftSide->Edge( i ))); + for ( int i = 0; i < rgtSide->NbEdges(); ++i ) + addBadInputElements( meshDS->MeshElements( rgtSide->Edge( i ))); + return toSM( error( TCom("Different nb of segment on logically vertical edges #") + << shapeID( lftSide->Edge(0) ) << " and #" + << shapeID( rgtSide->Edge(0) ) << ": " + << nbSrcSegments << " != " << nbTgtSegments )); + } + } + else // if ( nbTgtSegments == nbSrcSegments ) + { + continue; } - continue; } // Compute 'vertical projection' if ( nbTgtMeshed == 0 ) @@ -1326,13 +1447,22 @@ bool StdMeshers_Prism_3D::computeWalls(const Prism_3D::TPrismTopo& thePrism) // new nodes are on different EDGEs; put one of them on VERTEX const int edgeIndex = rgtSide->EdgeIndex( srcNodeStr[ iN-1 ].normParam ); const double vertexParam = rgtSide->LastParameter( edgeIndex ); - const gp_Pnt p = BRep_Tool::Pnt( rgtSide->LastVertex( edgeIndex )); + TopoDS_Vertex vertex = rgtSide->LastVertex( edgeIndex ); + const SMDS_MeshNode* vn = SMESH_Algo::VertexNode( vertex, meshDS ); + const gp_Pnt p = BRep_Tool::Pnt( vertex ); const int isPrev = ( Abs( srcNodeStr[ iN-1 ].normParam - vertexParam ) < Abs( srcNodeStr[ iN ].normParam - vertexParam )); meshDS->UnSetNodeOnShape( newNodes[ iN-isPrev ] ); - meshDS->SetNodeOnVertex ( newNodes[ iN-isPrev ], rgtSide->LastVertex( edgeIndex )); + meshDS->SetNodeOnVertex ( newNodes[ iN-isPrev ], vertex ); meshDS->MoveNode ( newNodes[ iN-isPrev ], p.X(), p.Y(), p.Z() ); id2type.first = newNodes[ iN-(1-isPrev) ]->getshapeId(); + if ( vn ) + { + SMESH_MeshEditor::TListOfListOfNodes lln( 1, list< const SMDS_MeshNode* >() ); + lln.back().push_back ( vn ); + lln.back().push_front( newNodes[ iN-isPrev ] ); // to keep + SMESH_MeshEditor( mesh ).MergeNodes( lln ); + } } SMDS_MeshElement* newEdge = myHelper->AddEdge( newNodes[ iN-1 ], newNodes[ iN ] ); meshDS->SetMeshElementOnShape( newEdge, id2type.first ); @@ -1369,10 +1499,13 @@ bool StdMeshers_Prism_3D::computeWalls(const Prism_3D::TPrismTopo& thePrism) Prism_3D::TQuadList::const_iterator quad = thePrism.myWallQuads[iW].begin(); for ( ; quad != thePrism.myWallQuads[iW].end(); ++quad ) { - // Top EDGEs must be projections from the bottom ones - // to compute stuctured quad mesh on wall FACEs - // --------------------------------------------------- + const TopoDS_Face& face = (*quad)->face; + SMESH_subMesh* fSM = mesh->GetSubMesh( face ); + if ( ! fSM->IsMeshComputed() ) { + // Top EDGEs must be projections from the bottom ones + // to compute stuctured quad mesh on wall FACEs + // --------------------------------------------------- const TopoDS_Edge& botE = (*quad)->side[ QUAD_BOTTOM_SIDE ].grid->Edge(0); const TopoDS_Edge& topE = (*quad)->side[ QUAD_TOP_SIDE ].grid->Edge(0); SMESH_subMesh* botSM = mesh->GetSubMesh( botE ); @@ -1414,7 +1547,7 @@ bool StdMeshers_Prism_3D::computeWalls(const Prism_3D::TPrismTopo& thePrism) // compute nodes on VERTEXes SMESH_subMeshIteratorPtr smIt = tgtSM->getDependsOnIterator(/*includeSelf=*/false); while ( smIt->more() ) - smIt->next()->ComputeSubMeshStateEngine( SMESH_subMesh::COMPUTE ); + smIt->next()->ComputeStateEngine( SMESH_subMesh::COMPUTE ); // project segments DBGOUT( "COMPUTE H edge (proj) " << tgtSM->GetId()); projector1D->myHyp.SetSourceEdge( TopoDS::Edge( srcSM->GetSubShape() )); @@ -1429,14 +1562,11 @@ bool StdMeshers_Prism_3D::computeWalls(const Prism_3D::TPrismTopo& thePrism) } } tgtSM->ComputeStateEngine( SMESH_subMesh::CHECK_COMPUTE_STATE ); - } - // Compute quad mesh on wall FACEs - // ------------------------------- - const TopoDS_Face& face = (*quad)->face; - SMESH_subMesh* fSM = mesh->GetSubMesh( face ); - if ( ! fSM->IsMeshComputed() ) - { + + // Compute quad mesh on wall FACEs + // ------------------------------- + // make all EDGES meshed fSM->ComputeSubMeshStateEngine( SMESH_subMesh::COMPUTE ); if ( !fSM->SubMeshesComputed() ) @@ -1464,6 +1594,22 @@ bool StdMeshers_Prism_3D::computeWalls(const Prism_3D::TPrismTopo& thePrism) return true; } +//======================================================================= +/*! + * \brief Returns a source EDGE of propagation to a given EDGE + */ +//======================================================================= + +TopoDS_Edge StdMeshers_Prism_3D::findPropagationSource( const TopoDS_Edge& E ) +{ + if ( myPropagChains ) + for ( size_t i = 0; !myPropagChains[i].IsEmpty(); ++i ) + if ( myPropagChains[i].Contains( E )) + return TopoDS::Edge( myPropagChains[i].FindKey( 1 )); + + return TopoDS_Edge(); +} + //======================================================================= //function : Evaluate //purpose : @@ -1713,24 +1859,25 @@ void StdMeshers_Prism_3D::AddPrisms( vector & columns, */ //================================================================================ -bool StdMeshers_Prism_3D::assocOrProjBottom2Top( const gp_Trsf & bottomToTopTrsf ) +bool StdMeshers_Prism_3D::assocOrProjBottom2Top( const gp_Trsf & bottomToTopTrsf, + const Prism_3D::TPrismTopo& thePrism) { - SMESH_subMesh * botSM = myBlock.SubMesh( ID_BOT_FACE ); - SMESH_subMesh * topSM = myBlock.SubMesh( ID_TOP_FACE ); + SMESH_subMesh * botSM = myHelper->GetMesh()->GetSubMesh( thePrism.myBottom ); + SMESH_subMesh * topSM = myHelper->GetMesh()->GetSubMesh( thePrism.myTop ); SMESHDS_SubMesh * botSMDS = botSM->GetSubMeshDS(); SMESHDS_SubMesh * topSMDS = topSM->GetSubMeshDS(); if ( !botSMDS || botSMDS->NbElements() == 0 ) { - _gen->Compute( *myHelper->GetMesh(), botSM->GetSubShape() ); + _gen->Compute( *myHelper->GetMesh(), botSM->GetSubShape(), /*aShapeOnly=*/true ); botSMDS = botSM->GetSubMeshDS(); if ( !botSMDS || botSMDS->NbElements() == 0 ) return toSM( error(TCom("No elements on face #") << botSM->GetId() )); } bool needProject = !topSM->IsMeshComputed(); - if ( !needProject && + if ( !needProject && (botSMDS->NbElements() != topSMDS->NbElements() || botSMDS->NbNodes() != topSMDS->NbNodes())) { @@ -1747,35 +1894,90 @@ bool StdMeshers_Prism_3D::assocOrProjBottom2Top( const gp_Trsf & bottomToTopTrsf <<" and #"<< topSM->GetId() << " seems different" )); ///RETURN_BAD_RESULT("Need to project but not allowed"); + NSProjUtils::TNodeNodeMap n2nMap; + const NSProjUtils::TNodeNodeMap* n2nMapPtr = & n2nMap; if ( needProject ) { - return projectBottomToTop( bottomToTopTrsf ); + if ( !projectBottomToTop( bottomToTopTrsf, thePrism )) + return false; + n2nMapPtr = & TProjction2dAlgo::instance( this )->GetNodesMap(); } - TopoDS_Face botFace = TopoDS::Face( myBlock.Shape( ID_BOT_FACE )); - TopoDS_Face topFace = TopoDS::Face( myBlock.Shape( ID_TOP_FACE )); - // associate top and bottom faces - TAssocTool::TShapeShapeMap shape2ShapeMap; - if ( !TAssocTool::FindSubShapeAssociation( botFace, myBlock.Mesh(), - topFace, myBlock.Mesh(), - shape2ShapeMap) ) - return toSM( error(TCom("Topology of faces #") << botSM->GetId() - <<" and #"<< topSM->GetId() << " seems different" )); + if ( !n2nMapPtr || n2nMapPtr->size() < botSMDS->NbNodes() ) + { + // associate top and bottom faces + NSProjUtils::TShapeShapeMap shape2ShapeMap; + const bool sameTopo = + NSProjUtils::FindSubShapeAssociation( thePrism.myBottom, myHelper->GetMesh(), + thePrism.myTop, myHelper->GetMesh(), + shape2ShapeMap); + if ( !sameTopo ) + for ( size_t iQ = 0; iQ < thePrism.myWallQuads.size(); ++iQ ) + { + const Prism_3D::TQuadList& quadList = thePrism.myWallQuads[iQ]; + StdMeshers_FaceSidePtr botSide = quadList.front()->side[ QUAD_BOTTOM_SIDE ]; + StdMeshers_FaceSidePtr topSide = quadList.back ()->side[ QUAD_TOP_SIDE ]; + if ( botSide->NbEdges() == topSide->NbEdges() ) + { + for ( int iE = 0; iE < botSide->NbEdges(); ++iE ) + { + NSProjUtils::InsertAssociation( botSide->Edge( iE ), + topSide->Edge( iE ), shape2ShapeMap ); + NSProjUtils::InsertAssociation( myHelper->IthVertex( 0, botSide->Edge( iE )), + myHelper->IthVertex( 0, topSide->Edge( iE )), + shape2ShapeMap ); + } + } + else + { + TopoDS_Vertex vb, vt; + StdMeshers_FaceSidePtr sideB, sideT; + vb = myHelper->IthVertex( 0, botSide->Edge( 0 )); + vt = myHelper->IthVertex( 0, topSide->Edge( 0 )); + sideB = quadList.front()->side[ QUAD_LEFT_SIDE ]; + sideT = quadList.back ()->side[ QUAD_LEFT_SIDE ]; + if ( vb.IsSame( sideB->FirstVertex() ) && + vt.IsSame( sideT->LastVertex() )) + { + NSProjUtils::InsertAssociation( botSide->Edge( 0 ), + topSide->Edge( 0 ), shape2ShapeMap ); + NSProjUtils::InsertAssociation( vb, vt, shape2ShapeMap ); + } + vb = myHelper->IthVertex( 1, botSide->Edge( botSide->NbEdges()-1 )); + vt = myHelper->IthVertex( 1, topSide->Edge( topSide->NbEdges()-1 )); + sideB = quadList.front()->side[ QUAD_RIGHT_SIDE ]; + sideT = quadList.back ()->side[ QUAD_RIGHT_SIDE ]; + if ( vb.IsSame( sideB->FirstVertex() ) && + vt.IsSame( sideT->LastVertex() )) + { + NSProjUtils::InsertAssociation( botSide->Edge( botSide->NbEdges()-1 ), + topSide->Edge( topSide->NbEdges()-1 ), + shape2ShapeMap ); + NSProjUtils::InsertAssociation( vb, vt, shape2ShapeMap ); + } + } + } - // Find matching nodes of top and bottom faces - TNodeNodeMap n2nMap; - if ( ! TAssocTool::FindMatchingNodesOnFaces( botFace, myBlock.Mesh(), - topFace, myBlock.Mesh(), - shape2ShapeMap, n2nMap )) - return toSM( error(TCom("Mesh on faces #") << botSM->GetId() - <<" and #"<< topSM->GetId() << " seems different" )); + // Find matching nodes of top and bottom faces + n2nMapPtr = & n2nMap; + if ( ! NSProjUtils::FindMatchingNodesOnFaces( thePrism.myBottom, myHelper->GetMesh(), + thePrism.myTop, myHelper->GetMesh(), + shape2ShapeMap, n2nMap )) + { + if ( sameTopo ) + return toSM( error(TCom("Mesh on faces #") << botSM->GetId() + <<" and #"<< topSM->GetId() << " seems different" )); + else + return toSM( error(TCom("Topology of faces #") << botSM->GetId() + <<" and #"<< topSM->GetId() << " seems different" )); + } + } // Fill myBotToColumnMap int zSize = myBlock.VerticalSize(); - //TNode prevTNode; - TNodeNodeMap::iterator bN_tN = n2nMap.begin(); - for ( ; bN_tN != n2nMap.end(); ++bN_tN ) + TNodeNodeMap::const_iterator bN_tN = n2nMapPtr->begin(); + for ( ; bN_tN != n2nMapPtr->end(); ++bN_tN ) { const SMDS_MeshNode* botNode = bN_tN->first; const SMDS_MeshNode* topNode = bN_tN->second; @@ -1795,17 +1997,22 @@ bool StdMeshers_Prism_3D::assocOrProjBottom2Top( const gp_Trsf & bottomToTopTrsf //================================================================================ /*! - * \brief Remove quadrangles from the top face and - * create triangles there by projection from the bottom + * \brief Remove faces from the top face and re-create them by projection from the bottom * \retval bool - a success or not */ //================================================================================ -bool StdMeshers_Prism_3D::projectBottomToTop( const gp_Trsf & bottomToTopTrsf ) +bool StdMeshers_Prism_3D::projectBottomToTop( const gp_Trsf & bottomToTopTrsf, + const Prism_3D::TPrismTopo& thePrism ) { - SMESHDS_Mesh* meshDS = myBlock.MeshDS(); - SMESH_subMesh * botSM = myBlock.SubMesh( ID_BOT_FACE ); - SMESH_subMesh * topSM = myBlock.SubMesh( ID_TOP_FACE ); + if ( project2dMesh( thePrism.myBottom, thePrism.myTop )) + { + return true; + } + + SMESHDS_Mesh* meshDS = myHelper->GetMeshDS(); + SMESH_subMesh * botSM = myHelper->GetMesh()->GetSubMesh( thePrism.myBottom ); + SMESH_subMesh * topSM = myHelper->GetMesh()->GetSubMesh( thePrism.myTop ); SMESHDS_SubMesh * botSMDS = botSM->GetSubMeshDS(); SMESHDS_SubMesh * topSMDS = topSM->GetSubMeshDS(); @@ -1813,9 +2020,9 @@ bool StdMeshers_Prism_3D::projectBottomToTop( const gp_Trsf & bottomToTopTrsf ) if ( topSMDS && topSMDS->NbElements() > 0 ) topSM->ComputeStateEngine( SMESH_subMesh::CLEAN ); - const TopoDS_Face& botFace = TopoDS::Face( myBlock.Shape( ID_BOT_FACE )); // oriented within - const TopoDS_Face& topFace = TopoDS::Face( myBlock.Shape( ID_TOP_FACE )); // the 3D SHAPE - int topFaceID = meshDS->ShapeToIndex( topFace ); + const TopoDS_Face& botFace = thePrism.myBottom; // oriented within + const TopoDS_Face& topFace = thePrism.myTop; // the 3D SHAPE + int topFaceID = meshDS->ShapeToIndex( thePrism.myTop ); SMESH_MesherHelper botHelper( *myHelper->GetMesh() ); botHelper.SetSubShape( botFace ); @@ -1882,6 +2089,9 @@ bool StdMeshers_Prism_3D::projectBottomToTop( const gp_Trsf & bottomToTopTrsf ) column.resize( zSize ); column.front() = botNode; column.back() = topNode; + + if ( _computeCanceled ) + return toSM( error( SMESH_ComputeError::New(COMPERR_CANCELED))); } // Create top faces @@ -1946,6 +2156,77 @@ bool StdMeshers_Prism_3D::projectBottomToTop( const gp_Trsf & bottomToTopTrsf ) return true; } +//======================================================================= +//function : getSweepTolerance +//purpose : Compute tolerance to pass to StdMeshers_Sweeper +//======================================================================= + +double StdMeshers_Prism_3D::getSweepTolerance( const Prism_3D::TPrismTopo& thePrism ) +{ + SMESHDS_Mesh* meshDS = myHelper->GetMeshDS(); + SMESHDS_SubMesh * sm[2] = { meshDS->MeshElements( thePrism.myBottom ), + meshDS->MeshElements( thePrism.myTop ) }; + double minDist = 1e100; + + vector< SMESH_TNodeXYZ > nodes; + for ( int iSM = 0; iSM < 2; ++iSM ) + { + if ( !sm[ iSM ]) continue; + + SMDS_ElemIteratorPtr fIt = sm[ iSM ]->GetElements(); + while ( fIt->more() ) + { + const SMDS_MeshElement* face = fIt->next(); + const int nbNodes = face->NbCornerNodes(); + SMDS_ElemIteratorPtr nIt = face->nodesIterator(); + + nodes.resize( nbNodes + 1 ); + for ( int iN = 0; iN < nbNodes; ++iN ) + nodes[ iN ] = nIt->next(); + nodes.back() = nodes[0]; + + // loop on links + double dist2; + for ( int iN = 0; iN < nbNodes; ++iN ) + { + if ( nodes[ iN ]._node->GetPosition()->GetDim() < 2 && + nodes[ iN+1 ]._node->GetPosition()->GetDim() < 2 ) + { + // it's a boundary link; measure distance of other + // nodes to this link + gp_XYZ linkDir = nodes[ iN ] - nodes[ iN+1 ]; + double linkLen = linkDir.Modulus(); + bool isDegen = ( linkLen < numeric_limits::min() ); + if ( !isDegen ) linkDir /= linkLen; + for ( int iN2 = 0; iN2 < nbNodes; ++iN2 ) // loop on other nodes + { + if ( nodes[ iN2 ] == nodes[ iN ] || + nodes[ iN2 ] == nodes[ iN+1 ]) continue; + if ( isDegen ) + { + dist2 = ( nodes[ iN ] - nodes[ iN2 ]).SquareModulus(); + } + else + { + dist2 = linkDir.CrossSquareMagnitude( nodes[ iN ] - nodes[ iN2 ]); + } + if ( dist2 > numeric_limits::min() ) + minDist = Min ( minDist, dist2 ); + } + } + // measure length link + else if ( nodes[ iN ]._node < nodes[ iN+1 ]._node ) // not to measure same link twice + { + dist2 = ( nodes[ iN ] - nodes[ iN+1 ]).SquareModulus(); + if ( dist2 > numeric_limits::min() ) + minDist = Min ( minDist, dist2 ); + } + } + } + } + return 0.1 * Sqrt ( minDist ); +} + //======================================================================= //function : project2dMesh //purpose : Project mesh faces from a source FACE of one prism (theSrcFace) @@ -2037,6 +2318,347 @@ int StdMeshers_Prism_3D::shapeID( const TopoDS_Shape& S ) return myHelper->GetMeshDS()->ShapeToIndex( S ); } +namespace // utils used by StdMeshers_Prism_3D::IsApplicable() +{ + struct EdgeWithNeighbors + { + TopoDS_Edge _edge; + int _iL, _iR; + EdgeWithNeighbors(const TopoDS_Edge& E, int iE, int nbE, int shift = 0 ): + _edge( E ), + _iL( SMESH_MesherHelper::WrapIndex( iE-1, nbE ) + shift ), + _iR( SMESH_MesherHelper::WrapIndex( iE+1, nbE ) + shift ) + { + } + EdgeWithNeighbors() {} + }; + struct PrismSide + { + TopoDS_Face _face; + TopTools_IndexedMapOfShape *_faces; // pointer because its copy constructor is private + TopoDS_Edge _topEdge; + vector< EdgeWithNeighbors >*_edges; + int _iBotEdge; + vector< bool > _isCheckedEdge; + int _nbCheckedEdges; // nb of EDGEs whose location is defined + PrismSide *_leftSide; + PrismSide *_rightSide; + const TopoDS_Edge& Edge( int i ) const + { + return (*_edges)[ i ]._edge; + } + int FindEdge( const TopoDS_Edge& E ) const + { + for ( size_t i = 0; i < _edges->size(); ++i ) + if ( E.IsSame( Edge( i ))) return i; + return -1; + } + bool IsSideFace( const TopoDS_Shape& face ) const + { + if ( _faces->Contains( face )) // avoid returning true for a prism top FACE + return ( !_face.IsNull() || !( face.IsSame( _faces->FindKey( _faces->Extent() )))); + return false; + } + }; + //-------------------------------------------------------------------------------- + /*! + * \brief Return ordered edges of a face + */ + bool getEdges( const TopoDS_Face& face, + vector< EdgeWithNeighbors > & edges, + const bool noHolesAllowed) + { + list< TopoDS_Edge > ee; + list< int > nbEdgesInWires; + int nbW = SMESH_Block::GetOrderedEdges( face, ee, nbEdgesInWires ); + if ( nbW > 1 && noHolesAllowed ) + return false; + + int iE, nbTot = 0; + list< TopoDS_Edge >::iterator e = ee.begin(); + list< int >::iterator nbE = nbEdgesInWires.begin(); + for ( ; nbE != nbEdgesInWires.end(); ++nbE ) + for ( iE = 0; iE < *nbE; ++e, ++iE ) + if ( SMESH_Algo::isDegenerated( *e )) + { + ee.erase( e ); + --(*nbE); + --iE; + } + else + { + e->Orientation( TopAbs_FORWARD ); // for operator==() to work + } + + edges.clear(); + e = ee.begin(); + for ( nbE = nbEdgesInWires.begin(); nbE != nbEdgesInWires.end(); ++nbE ) + { + for ( iE = 0; iE < *nbE; ++e, ++iE ) + edges.push_back( EdgeWithNeighbors( *e, iE, *nbE, nbTot )); + nbTot += *nbE; + } + return edges.size(); + } + //-------------------------------------------------------------------------------- + /*! + * \brief Return another faces sharing an edge + */ + const TopoDS_Shape & getAnotherFace( const TopoDS_Face& face, + const TopoDS_Edge& edge, + TopTools_IndexedDataMapOfShapeListOfShape& facesOfEdge) + { + TopTools_ListIteratorOfListOfShape faceIt( facesOfEdge.FindFromKey( edge )); + for ( ; faceIt.More(); faceIt.Next() ) + if ( !face.IsSame( faceIt.Value() )) + return faceIt.Value(); + return face; + } +} + +//================================================================================ +/*! + * \brief Return true if the algorithm can mesh this shape + * \param [in] aShape - shape to check + * \param [in] toCheckAll - if true, this check returns OK if all shapes are OK, + * else, returns OK if at least one shape is OK + */ +//================================================================================ + +bool StdMeshers_Prism_3D::IsApplicable(const TopoDS_Shape & shape, bool toCheckAll) +{ + TopExp_Explorer sExp( shape, TopAbs_SOLID ); + if ( !sExp.More() ) + return false; + + for ( ; sExp.More(); sExp.Next() ) + { + // check nb shells + TopoDS_Shape shell; + TopExp_Explorer shExp( sExp.Current(), TopAbs_SHELL ); + if ( shExp.More() ) { + shell = shExp.Current(); + shExp.Next(); + if ( shExp.More() ) + shell.Nullify(); + } + if ( shell.IsNull() ) { + if ( toCheckAll ) return false; + continue; + } + // get all faces + TopTools_IndexedMapOfShape allFaces; + TopExp::MapShapes( shell, TopAbs_FACE, allFaces ); + if ( allFaces.Extent() < 3 ) { + if ( toCheckAll ) return false; + continue; + } + // is a box? + if ( allFaces.Extent() == 6 ) + { + TopTools_IndexedMapOfOrientedShape map; + bool isBox = SMESH_Block::FindBlockShapes( TopoDS::Shell( shell ), + TopoDS_Vertex(), TopoDS_Vertex(), map ); + if ( isBox ) { + if ( !toCheckAll ) return true; + continue; + } + } +#ifdef _DEBUG_ + TopTools_IndexedMapOfShape allShapes; + TopExp::MapShapes( shape, allShapes ); +#endif + + TopTools_IndexedDataMapOfShapeListOfShape facesOfEdge; + TopTools_ListIteratorOfListOfShape faceIt; + TopExp::MapShapesAndAncestors( sExp.Current(), TopAbs_EDGE, TopAbs_FACE , facesOfEdge ); + if ( facesOfEdge.IsEmpty() ) { + if ( toCheckAll ) return false; + continue; + } + + typedef vector< EdgeWithNeighbors > TEdgeWithNeighborsVec; + vector< TEdgeWithNeighborsVec > faceEdgesVec( allFaces.Extent() + 1 ); + TopTools_IndexedMapOfShape* facesOfSide = new TopTools_IndexedMapOfShape[ faceEdgesVec.size() ]; + SMESHUtils::ArrayDeleter delFacesOfSide( facesOfSide ); + + // try to use each face as a bottom one + bool prismDetected = false; + for ( int iF = 1; iF < allFaces.Extent() && !prismDetected; ++iF ) + { + const TopoDS_Face& botF = TopoDS::Face( allFaces( iF )); + + TEdgeWithNeighborsVec& botEdges = faceEdgesVec[ iF ]; + if ( botEdges.empty() ) + if ( !getEdges( botF, botEdges, /*noHoles=*/false )) + break; + if ( allFaces.Extent()-1 <= (int) botEdges.size() ) + continue; // all faces are adjacent to botF - no top FACE + + // init data of side FACEs + vector< PrismSide > sides( botEdges.size() ); + for ( int iS = 0; iS < botEdges.size(); ++iS ) + { + sides[ iS ]._topEdge = botEdges[ iS ]._edge; + sides[ iS ]._face = botF; + sides[ iS ]._leftSide = & sides[ botEdges[ iS ]._iR ]; + sides[ iS ]._rightSide = & sides[ botEdges[ iS ]._iL ]; + sides[ iS ]._faces = & facesOfSide[ iS ]; + sides[ iS ]._faces->Clear(); + } + + bool isOK = true; // ok for a current botF + bool isAdvanced = true; // is new data found in a current loop + int nbFoundSideFaces = 0; + for ( int iLoop = 0; isOK && isAdvanced; ++iLoop ) + { + isAdvanced = false; + for ( size_t iS = 0; iS < sides.size() && isOK; ++iS ) + { + PrismSide& side = sides[ iS ]; + if ( side._face.IsNull() ) + continue; // probably the prism top face is the last of side._faces + + if ( side._topEdge.IsNull() ) + { + // find vertical EDGEs --- EGDEs shared with neighbor side FACEs + for ( int is2nd = 0; is2nd < 2 && isOK; ++is2nd ) // 2 adjacent neighbors + { + int di = is2nd ? 1 : -1; + const PrismSide* adjSide = is2nd ? side._rightSide : side._leftSide; + for ( size_t i = 1; i < side._edges->size(); ++i ) + { + int iE = SMESH_MesherHelper::WrapIndex( i*di + side._iBotEdge, side._edges->size()); + if ( side._isCheckedEdge[ iE ] ) continue; + const TopoDS_Edge& vertE = side.Edge( iE ); + const TopoDS_Shape& neighborF = getAnotherFace( side._face, vertE, facesOfEdge ); + bool isEdgeShared = adjSide->IsSideFace( neighborF ); + if ( isEdgeShared ) + { + isAdvanced = true; + side._isCheckedEdge[ iE ] = true; + side._nbCheckedEdges++; + int nbNotCheckedE = side._edges->size() - side._nbCheckedEdges; + if ( nbNotCheckedE == 1 ) + break; + } + else + { + if ( i == 1 && iLoop == 0 ) isOK = false; + break; + } + } + } + // find a top EDGE + int nbNotCheckedE = side._edges->size() - side._nbCheckedEdges; + if ( nbNotCheckedE == 1 ) + { + vector::iterator ii = std::find( side._isCheckedEdge.begin(), + side._isCheckedEdge.end(), false ); + if ( ii != side._isCheckedEdge.end() ) + { + size_t iE = std::distance( side._isCheckedEdge.begin(), ii ); + side._topEdge = side.Edge( iE ); + } + } + isOK = ( nbNotCheckedE >= 1 ); + } + else //if ( !side._topEdge.IsNull() ) + { + // get a next face of a side + const TopoDS_Shape& f = getAnotherFace( side._face, side._topEdge, facesOfEdge ); + side._faces->Add( f ); + bool stop = false; + if ( f.IsSame( side._face ) || // _topEdge is a seam + SMESH_MesherHelper::Count( f, TopAbs_WIRE, false ) != 1 ) + { + stop = true; + } + else if ( side._leftSide != & side ) // not closed side face + { + if ( side._leftSide->_faces->Contains( f )) + { + stop = true; // probably f is the prism top face + side._leftSide->_face.Nullify(); + side._leftSide->_topEdge.Nullify(); + } + if ( side._rightSide->_faces->Contains( f )) + { + stop = true; // probably f is the prism top face + side._rightSide->_face.Nullify(); + side._rightSide->_topEdge.Nullify(); + } + } + if ( stop ) + { + side._face.Nullify(); + side._topEdge.Nullify(); + continue; + } + side._face = TopoDS::Face( f ); + int faceID = allFaces.FindIndex( side._face ); + side._edges = & faceEdgesVec[ faceID ]; + if ( side._edges->empty() ) + if ( !getEdges( side._face, * side._edges, /*noHoles=*/true )) + break; + const int nbE = side._edges->size(); + if ( nbE >= 4 ) + { + isAdvanced = true; + ++nbFoundSideFaces; + side._iBotEdge = side.FindEdge( side._topEdge ); + side._isCheckedEdge.clear(); + side._isCheckedEdge.resize( nbE, false ); + side._isCheckedEdge[ side._iBotEdge ] = true; + side._nbCheckedEdges = 1; // bottom EDGE is known + } + side._topEdge.Nullify(); + isOK = ( !side._edges->empty() || side._faces->Extent() > 1 ); + + } //if ( !side._topEdge.IsNull() ) + + } // loop on prism sides + + if ( nbFoundSideFaces > allFaces.Extent() ) + { + isOK = false; + } + if ( iLoop > allFaces.Extent() * 10 ) + { + isOK = false; +#ifdef _DEBUG_ + cerr << "BUG: infinite loop in StdMeshers_Prism_3D::IsApplicable()" << endl; +#endif + } + } // while isAdvanced + + if ( isOK && sides[0]._faces->Extent() > 1 ) + { + const int nbFaces = sides[0]._faces->Extent(); + if ( botEdges.size() == 1 ) // cylinder + { + prismDetected = ( nbFaces == allFaces.Extent()-1 ); + } + else + { + const TopoDS_Shape& topFace = sides[0]._faces->FindKey( nbFaces ); + size_t iS; + for ( iS = 1; iS < sides.size(); ++iS ) + if ( !sides[ iS ]._faces->Contains( topFace )) + break; + prismDetected = ( iS == sides.size() ); + } + } + } // loop on allFaces + + if ( !prismDetected && toCheckAll ) return false; + if ( prismDetected && !toCheckAll ) return true; + + } // loop on solids + + return toCheckAll; +} + namespace Prism_3D { //================================================================================ @@ -2073,6 +2695,29 @@ namespace Prism_3D myWallQuads.clear(); } + //================================================================================ + /*! + * \brief Set upside-down + */ + //================================================================================ + + void TPrismTopo::SetUpsideDown() + { + std::swap( myBottom, myTop ); + myBottomEdges.clear(); + std::reverse( myBottomEdges.begin(), myBottomEdges.end() ); + for ( size_t i = 0; i < myWallQuads.size(); ++i ) + { + myWallQuads[i].reverse(); + TQuadList::iterator q = myWallQuads[i].begin(); + for ( ; q != myWallQuads[i].end(); ++q ) + { + (*q)->shift( 2, /*keepUnitOri=*/true ); + } + myBottomEdges.push_back( myWallQuads[i].front()->side[ QUAD_BOTTOM_SIDE ].grid->Edge(0) ); + } + } + } // namespace Prism_3D //================================================================================ @@ -2179,7 +2824,7 @@ bool StdMeshers_Prism_3D::initPrism(Prism_3D::TPrismTopo& thePrism, SMESH_subMesh * botSM = 0; SMESH_subMesh * topSM = 0; - if ( hasNotQuad ) // can chose a bottom FACE + if ( hasNotQuad ) // can choose a bottom FACE { if ( nbNotQuadMeshed > 0 ) botSM = notQuadElemSubMesh.front(); else botSM = notQuadGeomSubMesh.front(); @@ -2258,8 +2903,9 @@ bool StdMeshers_Prism_3D::initPrism(Prism_3D::TPrismTopo& thePrism, thePrism.myShape3D = shape3D; if ( thePrism.myBottom.IsNull() ) thePrism.myBottom = TopoDS::Face( botSM->GetSubShape() ); - thePrism.myBottom.Orientation( myHelper->GetSubShapeOri( shape3D, - thePrism.myBottom )); + thePrism.myBottom.Orientation( myHelper->GetSubShapeOri( shape3D, thePrism.myBottom )); + thePrism.myTop. Orientation( myHelper->GetSubShapeOri( shape3D, thePrism.myTop )); + // Get ordered bottom edges TopoDS_Face reverseBottom = // to have order of top EDGEs as in the top FACE TopoDS::Face( thePrism.myBottom.Reversed() ); @@ -2287,6 +2933,12 @@ bool StdMeshers_Prism_3D::initPrism(Prism_3D::TPrismTopo& thePrism, "Non-quadrilateral faces are not opposite")); } + if ( thePrism.myBottomEdges.size() > thePrism.myWallQuads.size() ) + { + // composite bottom sides => set thePrism upside-down + thePrism.SetUpsideDown(); + } + return true; } @@ -3211,8 +3863,8 @@ gp_Pnt StdMeshers_PrismAsBlock::TSideFace::Value(const Standard_Real U, } if ( !edge.IsNull() ) { - double u1 = myHelper.GetNodeU( edge, nn[0] ); - double u3 = myHelper.GetNodeU( edge, nn[2] ); + double u1 = myHelper.GetNodeU( edge, nn[0], nn[2] ); + double u3 = myHelper.GetNodeU( edge, nn[2], nn[0] ); double u = u1 * ( 1 - hR ) + u3 * hR; TopLoc_Location loc; double f,l; Handle(Geom_Curve) curve = BRep_Tool::Curve( edge,loc,f,l ); @@ -3592,6 +4244,8 @@ TPCurveOnHorFaceAdaptor::TPCurveOnHorFaceAdaptor( const TSideFace* sideFace, const int Z = isTop ? sideFace->ColumnHeight() - 1 : 0; map u2nodes; sideFace->GetNodesAtZ( Z, u2nodes ); + if ( u2nodes.empty() ) + return; SMESH_MesherHelper helper( *sideFace->GetMesh() ); helper.SetSubShape( horFace ); @@ -3656,7 +4310,7 @@ gp_Pnt2d StdMeshers_PrismAsBlock::TPCurveOnHorFaceAdaptor::Value(const Standard_ map< double, gp_XY >::const_iterator i1 = myUVmap.upper_bound( U ); if ( i1 == myUVmap.end() ) - return myUVmap.rbegin()->second; + return myUVmap.empty() ? gp_XY(0,0) : myUVmap.rbegin()->second; if ( i1 == myUVmap.begin() ) return (*i1).second; @@ -3666,3 +4320,355 @@ gp_Pnt2d StdMeshers_PrismAsBlock::TPCurveOnHorFaceAdaptor::Value(const Standard_ double r = ( U - i1->first ) / ( i2->first - i1->first ); return i1->second * ( 1 - r ) + i2->second * r; } + +//================================================================================ +/*! + * \brief Projects internal nodes using transformation found by boundary nodes + */ +//================================================================================ + +bool StdMeshers_Sweeper::projectIntPoints(const vector< gp_XYZ >& fromBndPoints, + const vector< gp_XYZ >& toBndPoints, + const vector< gp_XYZ >& fromIntPoints, + vector< gp_XYZ >& toIntPoints, + NSProjUtils::TrsfFinder3D& trsf, + vector< gp_XYZ > * bndError) +{ + // find transformation + if ( trsf.IsIdentity() && !trsf.Solve( fromBndPoints, toBndPoints )) + return false; + + // compute internal points using the found trsf + for ( size_t iP = 0; iP < fromIntPoints.size(); ++iP ) + { + toIntPoints[ iP ] = trsf.Transform( fromIntPoints[ iP ]); + } + + // compute boundary error + if ( bndError ) + { + bndError->resize( fromBndPoints.size() ); + gp_XYZ fromTrsf; + for ( size_t iP = 0; iP < fromBndPoints.size(); ++iP ) + { + fromTrsf = trsf.Transform( fromBndPoints[ iP ] ); + (*bndError)[ iP ] = toBndPoints[ iP ] - fromTrsf; + } + } + return true; +} + +//================================================================================ +/*! + * \brief Add boundary error to ineternal points + */ +//================================================================================ + +void StdMeshers_Sweeper::applyBoundaryError(const vector< gp_XYZ >& bndPoints, + const vector< gp_XYZ >& bndError1, + const vector< gp_XYZ >& bndError2, + const double r, + vector< gp_XYZ >& intPoints, + vector< double >& int2BndDist) +{ + // fix each internal point + const double eps = 1e-100; + for ( size_t iP = 0; iP < intPoints.size(); ++iP ) + { + gp_XYZ & intPnt = intPoints[ iP ]; + + // compute distance from intPnt to each boundary node + double int2BndDistSum = 0; + for ( size_t iBnd = 0; iBnd < bndPoints.size(); ++iBnd ) + { + int2BndDist[ iBnd ] = 1 / (( intPnt - bndPoints[ iBnd ]).SquareModulus() + eps ); + int2BndDistSum += int2BndDist[ iBnd ]; + } + + // apply bndError + for ( size_t iBnd = 0; iBnd < bndPoints.size(); ++iBnd ) + { + intPnt += bndError1[ iBnd ] * ( 1 - r ) * int2BndDist[ iBnd ] / int2BndDistSum; + intPnt += bndError2[ iBnd ] * r * int2BndDist[ iBnd ] / int2BndDistSum; + } + } +} + +//================================================================================ +/*! + * \brief Creates internal nodes of the prism + */ +//================================================================================ + +bool StdMeshers_Sweeper::ComputeNodes( SMESH_MesherHelper& helper, + const double tol) +{ + const size_t zSize = myBndColumns[0]->size(); + const size_t zSrc = 0, zTgt = zSize-1; + if ( zSize < 3 ) return true; + + vector< vector< gp_XYZ > > intPntsOfLayer( zSize ); // node coodinates to compute + // set coordinates of src and tgt nodes + for ( size_t z = 0; z < intPntsOfLayer.size(); ++z ) + intPntsOfLayer[ z ].resize( myIntColumns.size() ); + for ( size_t iP = 0; iP < myIntColumns.size(); ++iP ) + { + intPntsOfLayer[ zSrc ][ iP ] = intPoint( iP, zSrc ); + intPntsOfLayer[ zTgt ][ iP ] = intPoint( iP, zTgt ); + } + + // compute coordinates of internal nodes by projecting (transfroming) src and tgt + // nodes towards the central layer + + vector< NSProjUtils::TrsfFinder3D > trsfOfLayer( zSize ); + vector< vector< gp_XYZ > > bndError( zSize ); + + // boundary points used to compute an affine transformation from a layer to a next one + vector< gp_XYZ > fromSrcBndPnts( myBndColumns.size() ), fromTgtBndPnts( myBndColumns.size() ); + vector< gp_XYZ > toSrcBndPnts ( myBndColumns.size() ), toTgtBndPnts ( myBndColumns.size() ); + for ( size_t iP = 0; iP < myBndColumns.size(); ++iP ) + { + fromSrcBndPnts[ iP ] = bndPoint( iP, zSrc ); + fromTgtBndPnts[ iP ] = bndPoint( iP, zTgt ); + } + + size_t zS = zSrc + 1; + size_t zT = zTgt - 1; + for ( ; zS < zT; ++zS, --zT ) // vertical loop on layers + { + for ( size_t iP = 0; iP < myBndColumns.size(); ++iP ) + { + toSrcBndPnts[ iP ] = bndPoint( iP, zS ); + toTgtBndPnts[ iP ] = bndPoint( iP, zT ); + } + if (! projectIntPoints( fromSrcBndPnts, toSrcBndPnts, + intPntsOfLayer[ zS-1 ], intPntsOfLayer[ zS ], + trsfOfLayer [ zS-1 ], & bndError[ zS-1 ])) + return false; + if (! projectIntPoints( fromTgtBndPnts, toTgtBndPnts, + intPntsOfLayer[ zT+1 ], intPntsOfLayer[ zT ], + trsfOfLayer [ zT+1 ], & bndError[ zT+1 ])) + return false; + + // if ( zT == zTgt - 1 ) + // { + // for ( size_t iP = 0; iP < myBndColumns.size(); ++iP ) + // { + // gp_XYZ fromTrsf = trsfOfLayer [ zT+1].Transform( fromTgtBndPnts[ iP ] ); + // cout << "mesh.AddNode( " + // << fromTrsf.X() << ", " + // << fromTrsf.Y() << ", " + // << fromTrsf.Z() << ") " << endl; + // } + // for ( size_t iP = 0; iP < myIntColumns.size(); ++iP ) + // cout << "mesh.AddNode( " + // << intPntsOfLayer[ zT ][ iP ].X() << ", " + // << intPntsOfLayer[ zT ][ iP ].Y() << ", " + // << intPntsOfLayer[ zT ][ iP ].Z() << ") " << endl; + // } + + fromTgtBndPnts.swap( toTgtBndPnts ); + fromSrcBndPnts.swap( toSrcBndPnts ); + } + + // Compute two projections of internal points to the central layer + // in order to evaluate an error of internal points + + bool centerIntErrorIsSmall; + vector< gp_XYZ > centerSrcIntPnts( myIntColumns.size() ); + vector< gp_XYZ > centerTgtIntPnts( myIntColumns.size() ); + + for ( size_t iP = 0; iP < myBndColumns.size(); ++iP ) + { + toSrcBndPnts[ iP ] = bndPoint( iP, zS ); + toTgtBndPnts[ iP ] = bndPoint( iP, zT ); + } + if (! projectIntPoints( fromSrcBndPnts, toSrcBndPnts, + intPntsOfLayer[ zS-1 ], centerSrcIntPnts, + trsfOfLayer [ zS-1 ], & bndError[ zS-1 ])) + return false; + if (! projectIntPoints( fromTgtBndPnts, toTgtBndPnts, + intPntsOfLayer[ zT+1 ], centerTgtIntPnts, + trsfOfLayer [ zT+1 ], & bndError[ zT+1 ])) + return false; + + // evaluate an error of internal points on the central layer + centerIntErrorIsSmall = true; + if ( zS == zT ) // odd zSize + { + for ( size_t iP = 0; ( iP < myIntColumns.size() && centerIntErrorIsSmall ); ++iP ) + centerIntErrorIsSmall = + (centerSrcIntPnts[ iP ] - centerTgtIntPnts[ iP ]).SquareModulus() < tol*tol; + } + else // even zSize + { + for ( size_t iP = 0; ( iP < myIntColumns.size() && centerIntErrorIsSmall ); ++iP ) + centerIntErrorIsSmall = + (intPntsOfLayer[ zS-1 ][ iP ] - centerTgtIntPnts[ iP ]).SquareModulus() < tol*tol; + } + + // Evaluate an error of boundary points + + bool bndErrorIsSmall = true; + for ( size_t iP = 0; ( iP < myBndColumns.size() && bndErrorIsSmall ); ++iP ) + { + double sumError = 0; + for ( size_t z = 1; z < zS; ++z ) // loop on layers + sumError += ( bndError[ z-1 ][ iP ].Modulus() + + bndError[ zSize-z ][ iP ].Modulus() ); + + bndErrorIsSmall = ( sumError < tol ); + } + + // compute final points on the central layer + std::vector< double > int2BndDist( myBndColumns.size() ); // work array of applyBoundaryError() + double r = zS / ( zSize - 1.); + if ( zS == zT ) + { + for ( size_t iP = 0; iP < myIntColumns.size(); ++iP ) + { + intPntsOfLayer[ zS ][ iP ] = + ( 1 - r ) * centerSrcIntPnts[ iP ] + r * centerTgtIntPnts[ iP ]; + } + if ( !bndErrorIsSmall ) + { + applyBoundaryError( toSrcBndPnts, bndError[ zS-1 ], bndError[ zS+1 ], r, + intPntsOfLayer[ zS ], int2BndDist ); + } + } + else + { + for ( size_t iP = 0; iP < myIntColumns.size(); ++iP ) + { + intPntsOfLayer[ zS ][ iP ] = + r * intPntsOfLayer[ zS ][ iP ] + ( 1 - r ) * centerSrcIntPnts[ iP ]; + intPntsOfLayer[ zT ][ iP ] = + r * intPntsOfLayer[ zT ][ iP ] + ( 1 - r ) * centerTgtIntPnts[ iP ]; + } + if ( !bndErrorIsSmall ) + { + applyBoundaryError( toSrcBndPnts, bndError[ zS-1 ], bndError[ zS+1 ], r, + intPntsOfLayer[ zS ], int2BndDist ); + applyBoundaryError( toTgtBndPnts, bndError[ zT+1 ], bndError[ zT-1 ], r, + intPntsOfLayer[ zT ], int2BndDist ); + } + } + + //centerIntErrorIsSmall = true; + //bndErrorIsSmall = true; + if ( !centerIntErrorIsSmall ) + { + // Compensate the central error; continue adding projection + // by going from central layer to the source and target ones + + vector< gp_XYZ >& fromSrcIntPnts = centerSrcIntPnts; + vector< gp_XYZ >& fromTgtIntPnts = centerTgtIntPnts; + vector< gp_XYZ > toSrcIntPnts( myIntColumns.size() ); + vector< gp_XYZ > toTgtIntPnts( myIntColumns.size() ); + vector< gp_XYZ > srcBndError( myBndColumns.size() ); + vector< gp_XYZ > tgtBndError( myBndColumns.size() ); + + fromTgtBndPnts.swap( toTgtBndPnts ); + fromSrcBndPnts.swap( toSrcBndPnts ); + + for ( ++zS, --zT; zS < zTgt; ++zS, --zT ) // vertical loop on layers + { + // invert transformation + if ( !trsfOfLayer[ zS+1 ].Invert() ) + trsfOfLayer[ zS+1 ] = NSProjUtils::TrsfFinder3D(); // to recompute + if ( !trsfOfLayer[ zT-1 ].Invert() ) + trsfOfLayer[ zT-1 ] = NSProjUtils::TrsfFinder3D(); + + // project internal nodes and compute bnd error + for ( size_t iP = 0; iP < myBndColumns.size(); ++iP ) + { + toSrcBndPnts[ iP ] = bndPoint( iP, zS ); + toTgtBndPnts[ iP ] = bndPoint( iP, zT ); + } + projectIntPoints( fromSrcBndPnts, toSrcBndPnts, + fromSrcIntPnts, toSrcIntPnts, + trsfOfLayer[ zS+1 ], & srcBndError ); + projectIntPoints( fromTgtBndPnts, toTgtBndPnts, + fromTgtIntPnts, toTgtIntPnts, + trsfOfLayer[ zT-1 ], & tgtBndError ); + + // if ( zS == zTgt - 1 ) + // { + // cout << "mesh2 = smesh.Mesh()" << endl; + // for ( size_t iP = 0; iP < myBndColumns.size(); ++iP ) + // { + // gp_XYZ fromTrsf = trsfOfLayer [ zS+1].Transform( fromSrcBndPnts[ iP ] ); + // cout << "mesh2.AddNode( " + // << fromTrsf.X() << ", " + // << fromTrsf.Y() << ", " + // << fromTrsf.Z() << ") " << endl; + // } + // for ( size_t iP = 0; iP < myIntColumns.size(); ++iP ) + // cout << "mesh2.AddNode( " + // << toSrcIntPnts[ iP ].X() << ", " + // << toSrcIntPnts[ iP ].Y() << ", " + // << toSrcIntPnts[ iP ].Z() << ") " << endl; + // } + + // sum up 2 projections + r = zS / ( zSize - 1.); + vector< gp_XYZ >& zSIntPnts = intPntsOfLayer[ zS ]; + vector< gp_XYZ >& zTIntPnts = intPntsOfLayer[ zT ]; + for ( size_t iP = 0; iP < myIntColumns.size(); ++iP ) + { + zSIntPnts[ iP ] = r * zSIntPnts[ iP ] + ( 1 - r ) * toSrcIntPnts[ iP ]; + zTIntPnts[ iP ] = r * zTIntPnts[ iP ] + ( 1 - r ) * toTgtIntPnts[ iP ]; + } + + // compensate bnd error + if ( !bndErrorIsSmall ) + { + applyBoundaryError( toSrcBndPnts, srcBndError, bndError[ zS+1 ], r, + intPntsOfLayer[ zS ], int2BndDist ); + applyBoundaryError( toTgtBndPnts, tgtBndError, bndError[ zT-1 ], r, + intPntsOfLayer[ zT ], int2BndDist ); + } + + fromSrcBndPnts.swap( toSrcBndPnts ); + fromSrcIntPnts.swap( toSrcIntPnts ); + fromTgtBndPnts.swap( toTgtBndPnts ); + fromTgtIntPnts.swap( toTgtIntPnts ); + } + } // if ( !centerIntErrorIsSmall ) + + else if ( !bndErrorIsSmall ) + { + zS = zSrc + 1; + zT = zTgt - 1; + for ( ; zS < zT; ++zS, --zT ) // vertical loop on layers + { + for ( size_t iP = 0; iP < myBndColumns.size(); ++iP ) + { + toSrcBndPnts[ iP ] = bndPoint( iP, zS ); + toTgtBndPnts[ iP ] = bndPoint( iP, zT ); + } + // compensate bnd error + applyBoundaryError( toSrcBndPnts, bndError[ zS-1 ], bndError[ zS-1 ], 0.5, + intPntsOfLayer[ zS ], int2BndDist ); + applyBoundaryError( toTgtBndPnts, bndError[ zT+1 ], bndError[ zT+1 ], 0.5, + intPntsOfLayer[ zT ], int2BndDist ); + } + } + + // cout << "centerIntErrorIsSmall = " << centerIntErrorIsSmall<< endl; + // cout << "bndErrorIsSmall = " << bndErrorIsSmall<< endl; + + // Create nodes + for ( size_t iP = 0; iP < myIntColumns.size(); ++iP ) + { + vector< const SMDS_MeshNode* > & nodeCol = *myIntColumns[ iP ]; + for ( size_t z = zSrc + 1; z < zTgt; ++z ) // vertical loop on layers + { + const gp_XYZ & xyz = intPntsOfLayer[ z ][ iP ]; + if ( !( nodeCol[ z ] = helper.AddNode( xyz.X(), xyz.Y(), xyz.Z() ))) + return false; + } + } + + return true; +}