#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 "utilities.h"
+#include <utilities.h>
#include <BRepAdaptor_Surface.hxx>
+#include <BRepMesh_Delaun.hxx>
#include <BRep_Tool.hxx>
#include <Bnd_B2d.hxx>
#include <GeomAPI_ProjectPointOnSurf.hxx>
//================================================================================
/*!
* \brief find new nodes belonging to one free border of mesh on face
- * \param sm - submesh on edge or vertex containg nodes to choose from
+ * \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
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;
+ // 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
- 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++ ];
+ // // load EDGEs to SMESH_Block
- 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 withing the quadrilateral srcFace
- if ( !block.ComputeParameters( SMESH_TNodeXYZ( srcNode ),
- tgtNodeOrXY.second, srcFaceBID ))
- return false;
- }
- }
- tgtNodes[ i ] = & tgtNodeOrXY;
- }
- }
+ // 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 withing 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
+ // // as all XY are computed, create tgt nodes and faces
- SMESH_MesherHelper helper( *tgtMesh );
- helper.SetSubShape( tgtFace );
- 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 helper( *tgtMesh );
+ // helper.SetSubShape( tgtFace );
+ // 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( *srcMesh );
- srcHelper.SetSubShape( srcFace );
+ // SMESH_MesherHelper srcHelper( *srcMesh );
+ // srcHelper.SetSubShape( srcFace );
- vector< const SMDS_MeshNode* > tgtNodes;
- gp_XY uv;
+ // 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 true;
+ // 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(...)
{
SMESH_subMesh* faceSM = helper.GetMesh()->GetSubMesh( helper.GetSubShape() );
- if ( helper.IsDistorted2D( faceSM, /*checkUV=*/false ))
+ if ( helper.IsDistorted2D( faceSM, /*checkUV=*/true ))
{
SMESH_MeshEditor editor( helper.GetMesh() );
SMESHDS_SubMesh* smDS = faceSM->GetSubMeshDS();
return true;
}
+ typedef list< pair< const SMDS_MeshNode*, const BRepMesh_Triangle* > > TNodeTriaList;
+
+ //================================================================================
+ /*!
+ * \brief Add in-FACE nodes surrounding a given node to a queue
+ */
+ //================================================================================
+
+ void addCloseNodes( const SMDS_MeshNode* srcNode,
+ const BRepMesh_Triangle* bmTria,
+ const int srcFaceID,
+ TNodeTriaList & noTriQueue )
+ {
+ // find in-FACE nodes
+ SMDS_ElemIteratorPtr elems = srcNode->GetInverseElementIterator(SMDSAbs_Face);
+ while ( elems->more() )
+ {
+ const SMDS_MeshElement* elem = elems->next();
+ if ( elem->getshapeId() == srcFaceID )
+ {
+ for ( int i = 0, nb = elem->NbNodes(); i < nb; ++i )
+ {
+ const SMDS_MeshNode* n = elem->GetNode( i );
+ if ( !n->isMarked() )
+ noTriQueue.push_back( make_pair( n, bmTria ));
+ }
+ }
+ }
+ }
+
+ //================================================================================
+ /*!
+ * \brief Find a delauney triangle containing a given 2D point and return
+ * barycentric coordinates within the found triangle
+ */
+ //================================================================================
+
+ const BRepMesh_Triangle* findTriangle( const gp_XY& uv,
+ const BRepMesh_Triangle* bmTria,
+ Handle(BRepMesh_DataStructureOfDelaun)& triaDS,
+ double bc[3] )
+ {
+ int nodeIDs[3];
+ gp_XY nodeUVs[3];
+ int linkIDs[3];
+ Standard_Boolean ori[3];
+
+ while ( bmTria )
+ {
+ // check bmTria
+
+ triaDS->ElementNodes( *bmTria, nodeIDs );
+ nodeUVs[0] = triaDS->GetNode( nodeIDs[0] ).Coord();
+ nodeUVs[1] = triaDS->GetNode( nodeIDs[1] ).Coord();
+ nodeUVs[2] = triaDS->GetNode( nodeIDs[2] ).Coord();
+
+ SMESH_MeshAlgos::GetBarycentricCoords( uv,
+ nodeUVs[0], nodeUVs[1], nodeUVs[2],
+ bc[0], bc[1] );
+ if ( bc[0] >= 0 && bc[1] >= 0 && bc[0] + bc[1] <= 1 )
+ {
+ bc[2] = 1 - bc[0] - bc[1];
+ return bmTria;
+ }
+
+ // look for a neighbor triangle, which is adjacent to a link intersected
+ // by a segment( triangle center -> uv )
+
+ gp_XY gc = ( nodeUVs[0] + nodeUVs[1] + nodeUVs[2] ) / 3.;
+ gp_XY seg = uv - gc;
+
+ bmTria->Edges( linkIDs, ori );
+ int triaID = triaDS->IndexOf( *bmTria );
+ bmTria = 0;
+
+ for ( int i = 0; i < 3; ++i )
+ {
+ const BRepMesh_PairOfIndex & triIDs = triaDS->ElementsConnectedTo( linkIDs[i] );
+ if ( triIDs.Extent() < 2 )
+ continue; // no neighbor triangle
+
+ // check if a link intersects gc2uv
+ const BRepMesh_Edge & link = triaDS->GetLink( linkIDs[i] );
+ const BRepMesh_Vertex & n1 = triaDS->GetNode( link.FirstNode() );
+ const BRepMesh_Vertex & n2 = triaDS->GetNode( link.LastNode() );
+ gp_XY uv1 = n1.Coord();
+ gp_XY lin = n2.Coord() - uv1; // link direction
+
+ double crossSegLin = seg ^ lin;
+ if ( Abs( crossSegLin ) < std::numeric_limits<double>::min() )
+ continue; // parallel
+
+ double uSeg = ( uv1 - gc ) ^ lin / crossSegLin;
+ if ( 0. <= uSeg && uSeg <= 1. )
+ {
+ bmTria = & triaDS->GetElement( triIDs.Index( 1 + ( triIDs.Index(1) == triaID )));
+ break;
+ }
+ }
+ }
+ return bmTria;
+ }
+
+ //================================================================================
+ /*!
+ * \brief Morph mesh on the target face to lie within FACE boundary w/o distortion
+ *
+ * algo:
+ * - make a CDT on the src FACE
+ * - find a triangle containing a src node and get its barycentric coordinates
+ * - move the node to a point with the same barycentric coordinates in a corresponding
+ * tgt triangle
+ */
+ //================================================================================
+
+ bool morph( SMESH_MesherHelper& tgtHelper,
+ const TopoDS_Face& tgtFace,
+ const TopoDS_Face& srcFace,
+ const TSideVector& tgtWires,
+ const TSideVector& srcWires,
+ const TAssocTool::TNodeNodeMap& src2tgtNodes )
+ {
+ if ( srcWires.size() != tgtWires.size() ) return false;
+
+ // count boundary points
+ int iP = 1, nbP = 0;
+ for ( size_t iW = 0; iW < srcWires.size(); ++iW )
+ nbP += srcWires[iW]->NbPoints() - 1; // 1st and last points coincide
+
+ // fill boundary points
+ BRepMesh::Array1OfVertexOfDelaun srcVert( 1, 1 + nbP ), tgtVert( 1, 1 + nbP );
+ vector< const SMDS_MeshNode* > bndSrcNodes( nbP + 1 ); bndSrcNodes[0] = 0;
+ BRepMesh_Vertex v( 0, 0, BRepMesh_Frontier );
+ for ( size_t iW = 0; iW < srcWires.size(); ++iW )
+ {
+ const UVPtStructVec& srcPnt = srcWires[iW]->GetUVPtStruct();
+ const UVPtStructVec& tgtPnt = tgtWires[iW]->GetUVPtStruct();
+ if ( srcPnt.size() != tgtPnt.size() ) return false;
+
+ for ( int i = 0, nb = srcPnt.size() - 1; i < nb; ++i, ++iP )
+ {
+ bndSrcNodes[ iP ] = srcPnt[i].node;
+ srcPnt[i].node->setIsMarked( true );
+
+ v.ChangeCoord() = srcPnt[i].UV();
+ srcVert( iP ) = v;
+ v.ChangeCoord() = tgtPnt[i].UV();
+ tgtVert( iP ) = v;
+ }
+ }
+ // triangulate the srcFace in 2D
+ BRepMesh_Delaun delauney( srcVert );
+ Handle(BRepMesh_DataStructureOfDelaun) triaDS = delauney.Result();
+
+ Handle(ShapeAnalysis_Surface) tgtSurface = tgtHelper.GetSurface( tgtFace );
+ SMESHDS_Mesh* srcMesh = srcWires[0]->GetMesh()->GetMeshDS();
+ SMESHDS_Mesh* tgtMesh = tgtHelper.GetMeshDS();
+ const SMDS_MeshNode *srcNode, *tgtNode;
+ const BRepMesh_Triangle *bmTria;
+
+ // un-mark internal src nodes; later we will mark moved nodes
+ SMDS_NodeIteratorPtr nIt = srcMesh->MeshElements( srcFace )->GetNodes();
+ if ( !nIt || !nIt->more() ) return true;
+ while ( nIt->more() )
+ ( srcNode = nIt->next() )->setIsMarked( false );
+
+ // initialize a queue of nodes with starting triangles
+ const int srcFaceID = srcNode->getshapeId();
+ TNodeTriaList noTriQueue;
+ size_t iBndSrcN = 1;
+ for ( ; iBndSrcN < bndSrcNodes.size() && noTriQueue.empty(); ++iBndSrcN )
+ {
+ // get a triangle
+ const BRepMesh::ListOfInteger & linkIds = triaDS->LinksConnectedTo( iBndSrcN );
+ const BRepMesh_PairOfIndex & triaIds = triaDS->ElementsConnectedTo( linkIds.First() );
+ const BRepMesh_Triangle& tria = triaDS->GetElement( triaIds.Index(1) );
+
+ addCloseNodes( bndSrcNodes[ iBndSrcN ], &tria, srcFaceID, noTriQueue );
+ }
+
+ // Move tgt nodes
+
+ double bc[3]; // barycentric coordinates
+ int nodeIDs[3];
+ bool checkUV = true;
+ const SMDS_FacePosition* pos;
+
+ while ( !noTriQueue.empty() )
+ {
+ srcNode = noTriQueue.front().first;
+ bmTria = noTriQueue.front().second;
+ noTriQueue.pop_front();
+ if ( srcNode->isMarked() )
+ continue;
+ srcNode->setIsMarked( true );
+
+ // find a delauney triangle containing the src node
+ gp_XY uv = tgtHelper.GetNodeUV( srcFace, srcNode, NULL, &checkUV );
+ bmTria = findTriangle( uv, bmTria, triaDS, bc );
+ if ( !bmTria )
+ continue;
+
+ // compute new coordinates for a corresponding tgt node
+ gp_XY uvNew( 0., 0. ), nodeUV;
+ triaDS->ElementNodes( *bmTria, nodeIDs );
+ for ( int i = 0; i < 3; ++i )
+ uvNew += bc[i] * tgtVert( nodeIDs[i]).Coord();
+ gp_Pnt xyz = tgtSurface->Value( uvNew );
+
+ // find and move tgt node
+ TAssocTool::TNodeNodeMap::const_iterator n2n = src2tgtNodes.find( srcNode );
+ if ( n2n == src2tgtNodes.end() ) continue;
+ tgtNode = n2n->second;
+ tgtMesh->MoveNode( tgtNode, xyz.X(), xyz.Y(), xyz.Z() );
+
+ if (( pos = dynamic_cast< const SMDS_FacePosition* >( tgtNode->GetPosition() )))
+ const_cast<SMDS_FacePosition*>( pos )->SetParameters( uvNew.X(), uvNew.Y() );
+
+ addCloseNodes( srcNode, bmTria, srcFaceID, noTriQueue );
+
+ // assure that all src nodes are visited
+ for ( ; iBndSrcN < bndSrcNodes.size() && noTriQueue.empty(); ++iBndSrcN )
+ {
+ const BRepMesh::ListOfInteger & linkIds = triaDS->LinksConnectedTo( iBndSrcN );
+ const BRepMesh_PairOfIndex & triaIds = triaDS->ElementsConnectedTo( linkIds.First() );
+ const BRepMesh_Triangle& tria = triaDS->GetElement( triaIds.Index(1) );
+ addCloseNodes( bndSrcNodes[ iBndSrcN ], &tria, srcFaceID, noTriQueue );
+ }
+ }
+
+ 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
{
_src2tgtNodes.clear();
- MESSAGE("Projection_2D Compute");
if ( !_sourceHypo )
return false;
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 ))
}
TopoDS_Face srcFace = TopoDS::Face( shape2ShapeMap( tgtFace ).Oriented(TopAbs_FORWARD));
- // orient faces
- // if ( srcMesh == tgtMesh )
- // {
- // TopoDS_Shape solid =
- // helper.GetCommonAncestor( srcFace, tgtFace, *tgtMesh, TopAbs_SOLID );
- // if ( !solid.IsNull() )
- // {
- // srcFace.Orientation( helper.GetSubShapeOri( solid, srcFace ));
- // tgtFace.Orientation( helper.GetSubShapeOri( solid, tgtFace ));
- // }
- // else if ( helper.NbAncestors( srcFace, *tgtMesh, TopAbs_SOLID ) == 1 &&
- // helper.NbAncestors( tgtFace, *tgtMesh, TopAbs_SOLID ) == 1 )
- // {
- // srcFace.Orientation( helper.GetSubShapeOri( tgtMesh->GetShapeToMesh(), srcFace ));
- // tgtFace.Orientation( helper.GetSubShapeOri( tgtMesh->GetShapeToMesh(), tgtFace ));
- // }
- // }
// ----------------------------------------------
// Assure that mesh on a source Face is computed
// ----------------------------------------------
{
// projection in case if the faces are similar in 2D space
projDone = projectBy2DSimilarity( tgtFace, srcFace, tgtWires, srcWires,
- shape2ShapeMap, _src2tgtNodes, is1DComputed);
+ shape2ShapeMap, _src2tgtNodes, is1DComputed );
}
if ( !projDone )
{
// projection in case of quadrilateral faces
- // projDone = projectQuads( tgtFace, srcFace, tgtWires, srcWires,
- // shape2ShapeMap, _src2tgtNodes, is1DComputed);
+ // NOT IMPLEMENTED, returns false
+ projDone = projectQuads( tgtFace, srcFace, tgtWires, srcWires,
+ shape2ShapeMap, _src2tgtNodes, is1DComputed);
}
- helper.SetSubShape( tgtFace );
-
// it will remove mesh built on edges and vertices in failure case
MeshCleaner cleaner( tgtSubMesh );
// Load pattern from the source face
SMESH_Pattern mapper;
- mapper.Load( srcMesh, srcFace, toProjectNodes, srcV1 );
+ 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");
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
{
// boundary, also bad face can be created if EDGEs already discretized
// --> fix bad faces by smoothing
// ----------------------------------------------------------------
- if ( !fixDistortedFaces( helper, tgtWires ))
- return error("Invalid mesh generated");
+ if ( helper.IsDistorted2D( tgtSubMesh, /*checkUV=*/false ))
+ {
+ morph( helper, tgtFace, srcFace, tgtWires, srcWires, _src2tgtNodes );
+ if ( !fixDistortedFaces( helper, tgtWires ))
+ return error("Invalid mesh generated");
+ }
// ---------------------------
// Check elements orientation
// ---------------------------
