From ac69e1629b1b13430b93339cea889fe1ed4f1090 Mon Sep 17 00:00:00 2001 From: eap Date: Tue, 9 Sep 2014 18:12:47 +0400 Subject: [PATCH] IPAL52478: Too thin viscous layers are constructed + a fix of Mesh dialog for 22483 + allow white-space-separated IDs for RangeOdIDs filter + docs improved --- .../SMESH/input/constructing_submeshes.doc | 28 +- .../SMESH/input/selection_filter_library.doc | 2 +- src/Controls/SMESH_Controls.cxx | 9 +- src/SMESH/SMESH_Mesh.hxx | 10 +- src/SMESHGUI/SMESHGUI_MeshOp.cxx | 32 +- src/StdMeshers/StdMeshers_ViscousLayers.cxx | 1354 +++++++++++++---- 6 files changed, 1128 insertions(+), 307 deletions(-) diff --git a/doc/salome/gui/SMESH/input/constructing_submeshes.doc b/doc/salome/gui/SMESH/input/constructing_submeshes.doc index 230903449..782b5662e 100644 --- a/doc/salome/gui/SMESH/input/constructing_submeshes.doc +++ b/doc/salome/gui/SMESH/input/constructing_submeshes.doc @@ -2,9 +2,21 @@ \page constructing_submeshes_page Constructing sub-meshes -Sub-mesh is a mesh on a geometrical sub-object created with meshing algorithms -and/or hypotheses other than the algorithms and hypotheses assigned to -the parent mesh on the parent geometrical object. +Sub-mesh is a mesh on a geometrical sub-object (sub-shape) used to assign +different meshing algorithms and/or hypotheses than the algorithms and +hypotheses assigned to the parent mesh on the parent geometrical +object, that allows getting a local mesh refinement. + +A sub-shape to create a sub-mesh on should be retrieved from the shape +of the parent mesh one of the following ways: If a geometrical sub-object belongs to several geometrical objects having different meshes or sub-meshes, it will be meshed with the @@ -56,6 +68,7 @@ sub-mesh. You can select meshing algorithms and hypotheses in the same way as in \ref constructing_meshes_page "Create mesh" menu. \par +\anchor subshape_by_mesh_elem If the parent mesh is already computed, then you can define the \b Geometry by picking mesh elements computed on a sub-shape of interest in the 3D Viewer, i.e. you do not have to extract this sub-shape @@ -77,12 +90,13 @@ Browser. \image html find_geom_by_mesh_elem.png \par -In this dialog, Element Type defines kind of element to pick in the -Viewer. +In this dialog, Element Type defines a kind of element to pick in the +Viewer. Instead of picking an element in the Viewer, you can type its ID in Element ID field. - Geometry name field allows defining a name of the sub-shape. - + Geometry name field allows defining a name of the sub-shape +with which the sub-shape will appear in the Object Browser (if not yet +there). \par In the Object Browser the structure of the new sub-mesh will be diff --git a/doc/salome/gui/SMESH/input/selection_filter_library.doc b/doc/salome/gui/SMESH/input/selection_filter_library.doc index c06fb6ec5..02d39a541 100644 --- a/doc/salome/gui/SMESH/input/selection_filter_library.doc +++ b/doc/salome/gui/SMESH/input/selection_filter_library.doc @@ -237,7 +237,7 @@ See also \ref filter_double_elements "Double Elements quality control". Bad oriented volume selects mesh volumes, which are incorrectly oriented from the point of view of MED convention.
  • -Over-constrained volumes selects mesh volumes having only one border shared +Over-constrained volumes selects mesh volumes having only one facet shared with other volumes. See also \ref over_constrained_volumes_page "Over-constrained volumes quality control".
  • diff --git a/src/Controls/SMESH_Controls.cxx b/src/Controls/SMESH_Controls.cxx index 213dc236d..1ad00533a 100644 --- a/src/Controls/SMESH_Controls.cxx +++ b/src/Controls/SMESH_Controls.cxx @@ -3134,11 +3134,14 @@ bool RangeOfIds::SetRangeStr( const TCollection_AsciiString& theStr ) myIds.Clear(); TCollection_AsciiString aStr = theStr; - aStr.RemoveAll( ' ' ); - aStr.RemoveAll( '\t' ); + //aStr.RemoveAll( ' ' ); + //aStr.RemoveAll( '\t' ); + for ( int i = 1; i <= aStr.Length(); ++i ) + if ( isspace( aStr.Value( i ))) + aStr.SetValue( i, ','); for ( int aPos = aStr.Search( ",," ); aPos != -1; aPos = aStr.Search( ",," ) ) - aStr.Remove( aPos, 2 ); + aStr.Remove( aPos, 1 ); TCollection_AsciiString tmpStr = aStr.Token( ",", 1 ); int i = 1; diff --git a/src/SMESH/SMESH_Mesh.hxx b/src/SMESH/SMESH_Mesh.hxx index 0cf3e0949..c603c6a41 100644 --- a/src/SMESH/SMESH_Mesh.hxx +++ b/src/SMESH/SMESH_Mesh.hxx @@ -63,15 +63,15 @@ typedef std::list TListOfListOfInt; class SMESH_EXPORT SMESH_Mesh { -public: - SMESH_Mesh(int theLocalId, - int theStudyId, + public: + SMESH_Mesh(int theLocalId, + int theStudyId, SMESH_Gen* theGen, bool theIsEmbeddedMode, SMESHDS_Document* theDocument); - + virtual ~SMESH_Mesh(); - + /*! * \brief Set geometry to be meshed */ diff --git a/src/SMESHGUI/SMESHGUI_MeshOp.cxx b/src/SMESHGUI/SMESHGUI_MeshOp.cxx index ab8b437a6..1fc82405f 100644 --- a/src/SMESHGUI/SMESHGUI_MeshOp.cxx +++ b/src/SMESHGUI/SMESHGUI_MeshOp.cxx @@ -847,7 +847,7 @@ void SMESHGUI_MeshOp::availableHyps( const int theDim, theDataList.clear(); theHyps.clear(); bool isAlgo = ( theHypType == Algo ); - bool isAux = ( theHypType == AddHyp ); + bool isAux = ( theHypType >= AddHyp ); QStringList aHypTypeNameList = SMESH::GetAvailableHypotheses( isAlgo, theDim, isAux, myIsOnGeometry, !myIsMesh ); QStringList::const_iterator anIter; @@ -906,7 +906,7 @@ void SMESHGUI_MeshOp::existingHyps( const int theDim, else aPart = theHypType == Algo ? SMESH::Tag_AlgorithmsRoot : SMESH::Tag_HypothesisRoot; - const bool isAux = ( theHypType == AddHyp ); + const bool isAux = ( theHypType >= AddHyp ); const bool allHyps = ( !isMesh && theHypType != Algo && theDim > -1); if ( theFather->FindSubObject( aPart, aHypRoot ) ) @@ -1489,14 +1489,24 @@ void SMESHGUI_MeshOp::onAlgoSelected( const int theIndex, { if ( !isAccessibleDim( dim )) continue; - for ( int dlgType = MainHyp; dlgType < nbDlgHypTypes(dim); dlgType++ ) + + // get indices of selected hyps + const int nbTypes = nbDlgHypTypes(dim); + std::vector hypIndexByType( nbTypes, -1 ); + for ( int dlgType = MainHyp; dlgType < nbTypes; dlgType++ ) + { + hypIndexByType[ dlgType ] = currentHyp( dim, dlgType ); + } + + // update hyps + for ( int dlgType = MainHyp; dlgType < nbTypes; dlgType++ ) { const int type = Min( dlgType, AddHyp ); myAvailableHypData[ dim ][ type ].clear(); QStringList anAvailable, anExisting; HypothesisData* curAlgo = algoByDim[ dim ]; - int hypIndex = currentHyp( dim, dlgType ); + int hypIndex = hypIndexByType[ dlgType ]; SMESH::SMESH_Hypothesis_var curHyp; if ( hypIndex >= 0 && hypIndex < myExistingHyps[ dim ][ type ].count() ) @@ -1535,9 +1545,11 @@ void SMESHGUI_MeshOp::onAlgoSelected( const int theIndex, defaulHypAvlbl = (type == MainHyp && !curAlgo->IsAuxOrNeedHyp ); } // set list of hypotheses - myDlg->tab( dim )->setAvailableHyps( type, anAvailable ); - myDlg->tab( dim )->setExistingHyps( type, anExisting, defaulHypAvlbl ); - + if ( dlgType <= AddHyp ) + { + myDlg->tab( dim )->setAvailableHyps( type, anAvailable ); + myDlg->tab( dim )->setExistingHyps( type, anExisting, defaulHypAvlbl ); + } // set current existing hypothesis if ( !curHyp->_is_nil() && !anExisting.isEmpty() ) hypIndex = this->find( curHyp, myExistingHyps[ dim ][ type ]); @@ -1548,11 +1560,11 @@ void SMESHGUI_MeshOp::onAlgoSelected( const int theIndex, CORBA::String_var hypTypeName = myExistingHyps[ dim ][ type ].first().first->GetName(); bool isOptional = true; if ( algoByDim[ dim ] && - SMESH::IsAvailableHypothesis( algoByDim[ dim ], hypTypeName.in(), isOptional ) && - !isOptional ) + SMESH::IsAvailableHypothesis( algoByDim[ dim ], hypTypeName.in(), isOptional ) && + !isOptional ) hypIndex = 0; } - setCurrentHyp( dim, type, hypIndex ); + setCurrentHyp( dim, dlgType, hypIndex ); } } } diff --git a/src/StdMeshers/StdMeshers_ViscousLayers.cxx b/src/StdMeshers/StdMeshers_ViscousLayers.cxx index db5469ea2..c04a6326f 100644 --- a/src/StdMeshers/StdMeshers_ViscousLayers.cxx +++ b/src/StdMeshers/StdMeshers_ViscousLayers.cxx @@ -83,7 +83,10 @@ #include #include -#define __myDEBUG +#ifdef _DEBUG_ +//#define __myDEBUG +//#define __NOT_INVALIDATE_BAD_SMOOTH +#endif using namespace std; @@ -97,6 +100,10 @@ namespace VISCOUS_3D const double theMinSmoothCosin = 0.1; const double theSmoothThickToElemSizeRatio = 0.3; + // what part of thickness is allowed till intersection + // defined by SALOME_TESTS/Grids/smesh/viscous_layers_00/A5 + const double theThickToIntersection = 1.5; + bool needSmoothing( double cosin, double tgtThick, double elemSize ) { return cosin * tgtThick > theSmoothThickToElemSizeRatio * elemSize; @@ -109,7 +116,8 @@ namespace VISCOUS_3D struct _MeshOfSolid : public SMESH_ProxyMesh, public SMESH_subMeshEventListenerData { - bool _n2nMapComputed; + bool _n2nMapComputed; + SMESH_ComputeErrorPtr _warning; _MeshOfSolid( SMESH_Mesh* mesh) :SMESH_subMeshEventListenerData( /*isDeletable=*/true),_n2nMapComputed(false) @@ -173,7 +181,8 @@ namespace VISCOUS_3D SMESH_subMeshEventListenerData* data, const SMESH_Hypothesis* hyp) { - if ( SMESH_subMesh::COMPUTE_EVENT == eventType ) + if ( SMESH_subMesh::COMPUTE_EVENT == eventType && + SMESH_subMesh::CHECK_COMPUTE_STATE != event) { // delete SMESH_ProxyMesh containing temporary faces subMesh->DeleteEventListener( this ); @@ -228,6 +237,7 @@ namespace VISCOUS_3D sub->SetEventListener( _ShrinkShapeListener::Get(), data, /*whereToListenTo=*/mainSM ); } } + struct _SolidData; //-------------------------------------------------------------------------------- /*! * \brief Simplex (triangle or tetrahedron) based on 1 (tria) or 2 (tet) nodes of @@ -243,19 +253,19 @@ namespace VISCOUS_3D const SMDS_MeshNode* nNext=0, const SMDS_MeshNode* nOpp=0) : _nPrev(nPrev), _nNext(nNext), _nOpp(nOpp) {} - bool IsForward(const SMDS_MeshNode* nSrc, const gp_XYZ* pntTgt) const + bool IsForward(const SMDS_MeshNode* nSrc, const gp_XYZ* pntTgt, double& vol) const { const double M[3][3] = {{ _nNext->X() - nSrc->X(), _nNext->Y() - nSrc->Y(), _nNext->Z() - nSrc->Z() }, { pntTgt->X() - nSrc->X(), pntTgt->Y() - nSrc->Y(), pntTgt->Z() - nSrc->Z() }, { _nPrev->X() - nSrc->X(), _nPrev->Y() - nSrc->Y(), _nPrev->Z() - nSrc->Z() }}; - double determinant = ( + M[0][0]*M[1][1]*M[2][2] - + M[0][1]*M[1][2]*M[2][0] - + M[0][2]*M[1][0]*M[2][1] - - M[0][0]*M[1][2]*M[2][1] - - M[0][1]*M[1][0]*M[2][2] - - M[0][2]*M[1][1]*M[2][0]); - return determinant > 1e-100; + vol = ( + M[0][0]*M[1][1]*M[2][2] + + M[0][1]*M[1][2]*M[2][0] + + M[0][2]*M[1][0]*M[2][1] + - M[0][0]*M[1][2]*M[2][1] + - M[0][1]*M[1][0]*M[2][2] + - M[0][2]*M[1][1]*M[2][0]); + return vol > 1e-100; } bool IsForward(const gp_XY& tgtUV, const SMDS_MeshNode* smoothedNode, @@ -273,6 +283,12 @@ namespace VISCOUS_3D { return _nPrev == other._nNext || _nNext == other._nPrev; } + static void GetSimplices( const SMDS_MeshNode* node, + vector<_Simplex>& simplices, + const set& ingnoreShapes, + const _SolidData* dataToCheckOri = 0, + const bool toSort = false); + static void SortSimplices(vector<_Simplex>& simplices); }; //-------------------------------------------------------------------------------- /*! @@ -301,7 +317,12 @@ namespace VISCOUS_3D double lenDelta(double len) const { return _k * ( _r + len ); } double lenDeltaByDist(double dist) const { return dist * _h2lenRatio; } }; + //-------------------------------------------------------------------------------- + struct _2NearEdges; + struct _LayerEdge; + typedef map< const SMDS_MeshNode*, _LayerEdge*, TIDCompare > TNode2Edge; + //-------------------------------------------------------------------------------- /*! * \brief Edge normal to surface, connecting a node on solid surface (_nodes[0]) @@ -309,6 +330,8 @@ namespace VISCOUS_3D */ struct _LayerEdge { + typedef gp_XYZ (_LayerEdge::*PSmooFun)(); + vector< const SMDS_MeshNode*> _nodes; gp_XYZ _normal; // to solid surface @@ -322,6 +345,7 @@ namespace VISCOUS_3D // simplices connected to the source node (_nodes[0]); // used for smoothing and quality check of _LayerEdge's based on the FACE vector<_Simplex> _simplices; + PSmooFun _smooFunction; // smoothing function // data for smoothing of _LayerEdge's based on the EDGE _2NearEdges* _2neibors; @@ -336,7 +360,9 @@ namespace VISCOUS_3D const SMDS_MeshNode* n2, SMESH_MesherHelper& helper); void InvalidateStep( int curStep, bool restoreLength=false ); - bool Smooth(int& badNb); + void ChooseSmooFunction(const set< TGeomID >& concaveVertices, + const TNode2Edge& n2eMap); + bool Smooth(int& badNb, const int step, const bool isConcaveFace); bool SmoothOnEdge(Handle(Geom_Surface)& surface, const TopoDS_Face& F, SMESH_MesherHelper& helper); @@ -356,7 +382,30 @@ namespace VISCOUS_3D gp_XYZ Copy( _LayerEdge& other, SMESH_MesherHelper& helper ); void SetCosin( double cosin ); int NbSteps() const { return _pos.size() - 1; } // nb inlation steps + + gp_XYZ smoothLaplacian(); + gp_XYZ smoothAngular(); + gp_XYZ smoothLengthWeighted(); + gp_XYZ smoothCentroidal(); + gp_XYZ smoothNefPolygon(); + + enum { FUN_LAPLACIAN, FUN_LENWEIGHTED, FUN_CENTROIDAL, FUN_NEFPOLY, FUN_ANGULAR, FUN_NB }; + static const int theNbSmooFuns = FUN_NB; + static PSmooFun _funs[theNbSmooFuns]; + static const char* _funNames[theNbSmooFuns+1]; + int smooFunID( PSmooFun fun=0) const; }; + _LayerEdge::PSmooFun _LayerEdge::_funs[theNbSmooFuns] = { &_LayerEdge::smoothLaplacian, + &_LayerEdge::smoothLengthWeighted, + &_LayerEdge::smoothCentroidal, + &_LayerEdge::smoothNefPolygon, + &_LayerEdge::smoothAngular }; + const char* _LayerEdge::_funNames[theNbSmooFuns+1] = { "Laplacian", + "LengthWeighted", + "Centroidal", + "NefPolygon", + "Angular", + "None"}; struct _LayerEdgeCmp { bool operator () (const _LayerEdge* e1, const _LayerEdge* e2) const @@ -365,7 +414,29 @@ namespace VISCOUS_3D return cmpNodes ? ( e1->_nodes[0]->GetID() < e2->_nodes[0]->GetID()) : ( e1 < e2 ); } }; - struct _LayerEdge; + //-------------------------------------------------------------------------------- + /*! + * A 2D half plane used by _LayerEdge::smoothNefPolygon() + */ + struct _halfPlane + { + gp_XY _pos, _dir, _inNorm; + bool IsOut( const gp_XY p, const double tol ) const + { + return _inNorm * ( p - _pos ) < -tol; + } + bool FindInterestion( const _halfPlane& hp, gp_XY & intPnt ) + { + const double eps = 1e-10; + double D = _dir.Crossed( hp._dir ); + if ( fabs(D) < std::numeric_limits::min()) + return false; + gp_XY vec21 = _pos - hp._pos; + double u = hp._dir.Crossed( vec21 ) / D; + intPnt = _pos + _dir * u; + return true; + } + }; //-------------------------------------------------------------------------------- /*! * Structure used to smooth a _LayerEdge based on an EDGE. @@ -433,7 +504,7 @@ namespace VISCOUS_3D _nbHyps++; _nbLayers = hyp->GetNumberLayers(); //_thickness += hyp->GetTotalThickness(); - _thickness = Max( _thickness, hyp->GetTotalThickness() ); + _thickness = Max( _thickness, hyp->GetTotalThickness() ); _stretchFactor += hyp->GetStretchFactor(); } } @@ -445,10 +516,6 @@ namespace VISCOUS_3D double _thickness, _stretchFactor; }; - //-------------------------------------------------------------------------------- - - typedef map< const SMDS_MeshNode*, _LayerEdge*, TIDCompare > TNode2Edge; - //-------------------------------------------------------------------------------- /*! * \brief Data of a SOLID @@ -485,7 +552,7 @@ namespace VISCOUS_3D // Convex FACEs whose radius of curvature is less than the thickness of layers map< TGeomID, _ConvexFace > _convexFaces; - // shapes (EDGEs and VERTEXes) srink from which is forbiden due to collisions with + // shapes (EDGEs and VERTEXes) srink from which is forbidden due to collisions with // the adjacent SOLID set< TGeomID > _noShrinkShapes; @@ -495,6 +562,7 @@ namespace VISCOUS_3D // end indices in _edges of _LayerEdge on each shape, first go shapes to smooth vector< int > _endEdgeOnShape; int _nbShapesToSmooth; + set< TGeomID > _concaveFaces; // data of averaged StdMeshers_ViscousLayers parameters for each shape with _LayerEdge's vector< AverageHyp > _hypOnShape; @@ -511,15 +579,17 @@ namespace VISCOUS_3D Handle(Geom_Curve) CurveForSmooth( const TopoDS_Edge& E, const int iFrom, const int iTo, - Handle(Geom_Surface)& surface, const TopoDS_Face& F, - SMESH_MesherHelper& helper); + SMESH_MesherHelper& helper, + vector<_LayerEdge* >* edges=0); void SortOnEdge( const TopoDS_Edge& E, const int iFrom, const int iTo, SMESH_MesherHelper& helper); + void Sort2NeiborsOnEdge( const int iFrom, const int iTo); + _ConvexFace* GetConvexFace( const TGeomID faceID ) { map< TGeomID, _ConvexFace >::iterator id2face = _convexFaces.find( faceID ); @@ -534,6 +604,11 @@ namespace VISCOUS_3D bool GetShapeEdges(const TGeomID shapeID, size_t& iEdgeEnd, int* iBeg=0, int* iEnd=0 ) const; void AddShapesToSmooth( const set< TGeomID >& shapeIDs ); + + void PrepareEdgesToSmoothOnFace( _LayerEdge** edgeBeg, + _LayerEdge** edgeEnd, + const TopoDS_Face& face, + bool substituteSrcNodes ); }; //-------------------------------------------------------------------------------- /*! @@ -626,15 +701,11 @@ namespace VISCOUS_3D bool shiftInside=false); gp_XYZ getWeigthedNormal( const SMDS_MeshNode* n, std::pair< TGeomID, gp_XYZ > fId2Normal[], - const int nbFaces ); + int nbFaces ); bool findNeiborsOnEdge(const _LayerEdge* edge, const SMDS_MeshNode*& n1, const SMDS_MeshNode*& n2, _SolidData& data); - void getSimplices( const SMDS_MeshNode* node, vector<_Simplex>& simplices, - const set& ingnoreShapes, - const _SolidData* dataToCheckOri = 0, - const bool toSort = false); void findSimplexTestEdges( _SolidData& data, vector< vector<_LayerEdge*> >& edgesByGeom); void computeGeomSize( _SolidData& data ); @@ -833,6 +904,14 @@ StdMeshers_ViscousLayers::Compute(SMESH_Mesh& theMesh, return SMESH_ProxyMesh::Ptr(); components.push_back( SMESH_ProxyMesh::Ptr( pm )); pm->myIsDeletable = false; // it will de deleted by boost::shared_ptr + + if ( pm->_warning && !pm->_warning->IsOK() ) + { + SMESH_subMesh* sm = theMesh.GetSubMesh( exp.Current() ); + SMESH_ComputeErrorPtr& smError = sm->GetComputeError(); + if ( !smError || smError->IsOK() ) + smError = pm->_warning; + } } _ViscousListener::RemoveSolidMesh ( &theMesh, exp.Current() ); } @@ -899,7 +978,7 @@ bool StdMeshers_ViscousLayers::IsShapeWithLayers(int shapeIndex) const // END StdMeshers_ViscousLayers hypothesis //================================================================================ -namespace +namespace VISCOUS_3D { gp_XYZ getEdgeDir( const TopoDS_Edge& E, const TopoDS_Vertex& fromV ) { @@ -1038,14 +1117,56 @@ namespace return dir; } + + //================================================================================ + /*! + * \brief Finds concave VERTEXes of a FACE + */ + //================================================================================ + + bool getConcaveVertices( const TopoDS_Face& F, + SMESH_MesherHelper& helper, + set< TGeomID >* vertices = 0) + { + // check angles at VERTEXes + TError error; + TSideVector wires = StdMeshers_FaceSide::GetFaceWires( F, *helper.GetMesh(), 0, error ); + for ( size_t iW = 0; iW < wires.size(); ++iW ) + { + const int nbEdges = wires[iW]->NbEdges(); + if ( nbEdges < 2 && SMESH_Algo::isDegenerated( wires[iW]->Edge(0))) + continue; + for ( int iE1 = 0; iE1 < nbEdges; ++iE1 ) + { + if ( SMESH_Algo::isDegenerated( wires[iW]->Edge( iE1 ))) continue; + int iE2 = ( iE1 + 1 ) % nbEdges; + while ( SMESH_Algo::isDegenerated( wires[iW]->Edge( iE2 ))) + iE2 = ( iE2 + 1 ) % nbEdges; + TopoDS_Vertex V = wires[iW]->FirstVertex( iE2 ); + double angle = helper.GetAngle( wires[iW]->Edge( iE1 ), + wires[iW]->Edge( iE2 ), F, V ); + if ( angle < -5. * M_PI / 180. ) + { + if ( !vertices ) + return true; + vertices->insert( helper.GetMeshDS()->ShapeToIndex( V )); + } + } + } + return vertices ? !vertices->empty() : false; + } + //================================================================================ /*! * \brief Returns true if a FACE is bound by a concave EDGE */ //================================================================================ - bool isConcave( const TopoDS_Face& F, SMESH_MesherHelper& helper ) + bool isConcave( const TopoDS_Face& F, + SMESH_MesherHelper& helper, + set< TGeomID >* vertices = 0 ) { + bool isConcv = false; // if ( helper.Count( F, TopAbs_WIRE, /*useMap=*/false) > 1 ) // return true; gp_Vec2d drv1, drv2; @@ -1074,32 +1195,21 @@ namespace if ( !isConvex ) { //cout << "Concave FACE " << helper.GetMeshDS()->ShapeToIndex( F ) << endl; - return true; - } - } - // check angles at VERTEXes - TError error; - TSideVector wires = StdMeshers_FaceSide::GetFaceWires( F, *helper.GetMesh(), 0, error ); - for ( size_t iW = 0; iW < wires.size(); ++iW ) - { - const int nbEdges = wires[iW]->NbEdges(); - if ( nbEdges < 2 && SMESH_Algo::isDegenerated( wires[iW]->Edge(0))) - continue; - for ( int iE1 = 0; iE1 < nbEdges; ++iE1 ) - { - if ( SMESH_Algo::isDegenerated( wires[iW]->Edge( iE1 ))) continue; - int iE2 = ( iE1 + 1 ) % nbEdges; - while ( SMESH_Algo::isDegenerated( wires[iW]->Edge( iE2 ))) - iE2 = ( iE2 + 1 ) % nbEdges; - double angle = helper.GetAngle( wires[iW]->Edge( iE1 ), - wires[iW]->Edge( iE2 ), F, - wires[iW]->FirstVertex( iE2 )); - if ( angle < -5. * M_PI / 180. ) + isConcv = true; + if ( vertices ) + break; + else return true; } } - return false; + + // check angles at VERTEXes + if ( getConcaveVertices( F, helper, vertices )) + isConcv = true; + + return isConcv; } + //================================================================================ /*! * \brief Computes mimimal distance of face in-FACE nodes from an EDGE @@ -1159,18 +1269,19 @@ namespace // construction steps of viscous layers #ifdef __myDEBUG ofstream* py; - int theNbFunc; + int theNbPyFunc; struct PyDump { - PyDump() { + PyDump(SMESH_Mesh& m) { + int tag = 3 + m.GetId(); const char* fname = "/tmp/viscous.py"; cout << "execfile('"<GetID()<< ", "<< n->X() - << ", "<Y()<<", "<< n->Z()<< ")\t\t # "<< ln <Y()<<", "<< n->Z()<< ")\t\t # "<< ln <<" "<< txt << endl; } void _dumpCmd(const string& txt, int ln) { if (py) *py<< " "<GetNode( f->NbNodes()-1 )->GetID() << " ])"<< endl; }} #define debugMsg( txt ) { cout << txt << " (line: " << __LINE__ << ")" << endl; } #else - struct PyDump { void Finish() {} }; + struct PyDump { PyDump(SMESH_Mesh&) {} void Finish() {} }; #define dumpFunction(f) f #define dumpMove(n) +#define dumpMoveComm(n,txt) #define dumpCmd(txt) #define dumpFunctionEnd() #define dumpChangeNodes(f) @@ -1342,7 +1455,7 @@ SMESH_ComputeErrorPtr _ViscousBuilder::Compute(SMESH_Mesh& theMesh, if ( _ViscousListener::GetSolidMesh( _mesh, exp.Current(), /*toCreate=*/false)) return SMESH_ComputeErrorPtr(); // everything already computed - PyDump debugDump; + PyDump debugDump( theMesh ); // TODO: ignore already computed SOLIDs if ( !findSolidsWithLayers()) @@ -1547,26 +1660,27 @@ bool _ViscousBuilder::findFacesWithLayers(const bool onlyWith) { _sdVec[i]._ignoreFaceIds.swap( ignoreFacesOfHyps.back().first ); } + } // loop on _sdVec + + if ( onlyWith ) // is called to check hypotheses compatibility only + return true; - // fill _SolidData::_reversedFaceIds + // fill _SolidData::_reversedFaceIds + for ( size_t i = 0; i < _sdVec.size(); ++i ) + { + exp.Init( _sdVec[i]._solid.Oriented( TopAbs_FORWARD ), TopAbs_FACE ); + for ( ; exp.More(); exp.Next() ) { - exp.Init( _sdVec[i]._solid.Oriented( TopAbs_FORWARD ), TopAbs_FACE ); - for ( ; exp.More(); exp.Next() ) + const TopoDS_Face& face = TopoDS::Face( exp.Current() ); + const TGeomID faceID = getMeshDS()->ShapeToIndex( face ); + if ( //!sdVec[i]._ignoreFaceIds.count( faceID ) && + helper.NbAncestors( face, *_mesh, TopAbs_SOLID ) > 1 && + helper.IsReversedSubMesh( face )) { - const TopoDS_Face& face = TopoDS::Face( exp.Current() ); - const TGeomID faceID = getMeshDS()->ShapeToIndex( face ); - if ( //!sdVec[i]._ignoreFaceIds.count( faceID ) && ??????? - helper.NbAncestors( face, *_mesh, TopAbs_SOLID ) > 1 && - helper.IsReversedSubMesh( face )) - { - _sdVec[i]._reversedFaceIds.insert( faceID ); - } + _sdVec[i]._reversedFaceIds.insert( faceID ); } } - } // loop on _sdVec - - if ( onlyWith ) // is called to check hypotheses compatibility only - return true; + } // Find faces to shrink mesh on (solution 2 in issue 0020832); TopTools_IndexedMapOfShape shapes; @@ -2066,6 +2180,16 @@ bool _ViscousBuilder::makeLayer(_SolidData& data) } } + // fix _LayerEdge::_2neibors on EDGEs to smooth + map< TGeomID,Handle(Geom_Curve)>::iterator e2c = data._edge2curve.begin(); + for ( ; e2c != data._edge2curve.end(); ++e2c ) + if ( !e2c->second.IsNull() ) + { + size_t iEdgeEnd; int iBeg, iEnd; + if ( data.GetShapeEdges( e2c->first, iEdgeEnd, &iBeg, &iEnd )) + data.Sort2NeiborsOnEdge( iBeg, iEnd ); + } + dumpFunctionEnd(); return true; } @@ -2168,7 +2292,8 @@ void _ViscousBuilder::limitStepSizeByCurvature( _SolidData& data ) else continue; // check concavity and curvature and limit data._stepSize - const double minCurvature = 0.9 / data._hypOnShape[ edgesEnd ].GetTotalThickness(); + const double minCurvature = + 1. / ( data._hypOnShape[ edgesEnd ].GetTotalThickness() * ( 1+theThickToIntersection )); int nbLEdges = iEnd - iBeg; int iStep = Max( 1, nbLEdges / nbTestPnt ); for ( ; iBeg < iEnd; iBeg += iStep ) @@ -2239,7 +2364,7 @@ void _ViscousBuilder::limitStepSizeByCurvature( _SolidData& data ) const SMDS_MeshNode* srcNode = ledge->_nodes[0]; if ( !usedNodes.insert( srcNode ).second ) continue; - getSimplices( srcNode, ledge->_simplices, data._ignoreFaceIds, &data ); + _Simplex::GetSimplices( srcNode, ledge->_simplices, data._ignoreFaceIds, &data ); for ( size_t i = 0; i < ledge->_simplices.size(); ++i ) { usedNodes.insert( ledge->_simplices[i]._nPrev ); @@ -2278,104 +2403,133 @@ bool _ViscousBuilder::sortEdges( _SolidData& data, // boundry inclined to the shape at a sharp angle list< TGeomID > shapesToSmooth; - + TopTools_MapOfShape edgesOfSmooFaces; + SMESH_MesherHelper helper( *_mesh ); bool ok = true; - for ( size_t iS = 0; iS < edgesByGeom.size(); ++iS ) + for ( int isEdge = 0; isEdge < 2; ++isEdge ) // loop on [ FACEs, EDGEs ] { - vector<_LayerEdge*>& eS = edgesByGeom[iS]; - if ( eS.empty() ) continue; - const TopoDS_Shape& S = getMeshDS()->IndexToShape( iS ); - bool needSmooth = false; - switch ( S.ShapeType() ) + const int dim = isEdge ? 1 : 2; + + for ( size_t iS = 0; iS < edgesByGeom.size(); ++iS ) { - case TopAbs_EDGE: { + vector<_LayerEdge*>& eS = edgesByGeom[iS]; + if ( eS.empty() ) continue; + if ( eS[0]->_nodes[0]->GetPosition()->GetDim() != dim ) continue; - if ( SMESH_Algo::isDegenerated( TopoDS::Edge( S ))) - break; - //bool isShrinkEdge = !eS[0]->_sWOL.IsNull(); - for ( TopoDS_Iterator vIt( S ); vIt.More() && !needSmooth; vIt.Next() ) + const TopoDS_Shape& S = getMeshDS()->IndexToShape( iS ); + bool needSmooth = false; + switch ( S.ShapeType() ) { - TGeomID iV = getMeshDS()->ShapeToIndex( vIt.Value() ); - vector<_LayerEdge*>& eV = edgesByGeom[ iV ]; - if ( eV.empty() ) continue; - gp_Vec eDir = getEdgeDir( TopoDS::Edge( S ), TopoDS::Vertex( vIt.Value() )); - double angle = eDir.Angle( eV[0]->_normal ); - double cosin = Cos( angle ); - if ( cosin > theMinSmoothCosin ) + case TopAbs_EDGE: { + + const TopoDS_Edge& E = TopoDS::Edge( S ); + if ( SMESH_Algo::isDegenerated( E ) || !edgesOfSmooFaces.Contains( E )) + break; + + TopoDS_Face F; + if ( !eS[0]->_sWOL.IsNull() && eS[0]->_sWOL.ShapeType() == TopAbs_FACE ) + F = TopoDS::Face( eS[0]->_sWOL ); + + for ( TopoDS_Iterator vIt( S ); vIt.More() && !needSmooth; vIt.Next() ) { - // compare tgtThick with the length of an end segment - SMDS_ElemIteratorPtr eIt = eV[0]->_nodes[0]->GetInverseElementIterator(SMDSAbs_Edge); - while ( eIt->more() ) + TGeomID iV = getMeshDS()->ShapeToIndex( vIt.Value() ); + vector<_LayerEdge*>& eV = edgesByGeom[ iV ]; + if ( eV.empty() ) continue; + gp_Vec eDir = getEdgeDir( TopoDS::Edge( S ), TopoDS::Vertex( vIt.Value() )); + double angle = eDir.Angle( eV[0]->_normal ); + double cosin = Cos( angle ); + double cosinAbs = Abs( cosin ); + if ( cosinAbs > theMinSmoothCosin ) { - const SMDS_MeshElement* endSeg = eIt->next(); - if ( endSeg->getshapeId() == iS ) + // always smooth analytic EDGEs + needSmooth = ! data.CurveForSmooth( E, 0, eS.size(), F, helper, &eS ).IsNull(); + + // compare tgtThick with the length of an end segment + SMDS_ElemIteratorPtr eIt = eV[0]->_nodes[0]->GetInverseElementIterator(SMDSAbs_Edge); + while ( eIt->more() && !needSmooth ) { - double segLen = - SMESH_TNodeXYZ( endSeg->GetNode(0) ).Distance( endSeg->GetNode(1 )); - needSmooth = needSmoothing( cosin, tgtThick, segLen ); - break; + const SMDS_MeshElement* endSeg = eIt->next(); + if ( endSeg->getshapeId() == iS ) + { + double segLen = + SMESH_TNodeXYZ( endSeg->GetNode(0) ).Distance( endSeg->GetNode(1 )); + needSmooth = needSmoothing( cosinAbs, tgtThick, segLen ); + } } } } + break; } - break; - } - case TopAbs_FACE: { + case TopAbs_FACE: { - for ( TopExp_Explorer eExp( S, TopAbs_EDGE ); eExp.More() && !needSmooth; eExp.Next() ) - { - TGeomID iE = getMeshDS()->ShapeToIndex( eExp.Current() ); - vector<_LayerEdge*>& eE = edgesByGeom[ iE ]; - if ( eE.empty() ) continue; - // TopLoc_Location loc; - // Handle(Geom_Surface) surface = BRep_Tool::Surface( TopoDS::Face( S ), loc ); - // bool isPlane = GeomLib_IsPlanarSurface( surface ).IsPlanar(); - //if ( eE[0]->_sWOL.IsNull() ) + for ( TopExp_Explorer eExp( S, TopAbs_EDGE ); eExp.More() && !needSmooth; eExp.Next() ) { - double faceSize; - for ( size_t i = 0; i < eE.size() && !needSmooth; ++i ) - if ( eE[i]->_cosin > theMinSmoothCosin ) - { - SMDS_ElemIteratorPtr fIt = eE[i]->_nodes[0]->GetInverseElementIterator(SMDSAbs_Face); - while ( fIt->more() && !needSmooth ) + TGeomID iE = getMeshDS()->ShapeToIndex( eExp.Current() ); + vector<_LayerEdge*>& eE = edgesByGeom[ iE ]; + if ( eE.empty() ) continue; + // TopLoc_Location loc; + // Handle(Geom_Surface) surface = BRep_Tool::Surface( TopoDS::Face( S ), loc ); + // bool isPlane = GeomLib_IsPlanarSurface( surface ).IsPlanar(); + //if ( eE[0]->_sWOL.IsNull() ) + { + double faceSize; + for ( size_t i = 0; i < eE.size() && !needSmooth; ++i ) + if ( eE[i]->_cosin > theMinSmoothCosin ) { - const SMDS_MeshElement* face = fIt->next(); - if ( getDistFromEdge( face, eE[i]->_nodes[0], faceSize )) - needSmooth = needSmoothing( eE[i]->_cosin, tgtThick, faceSize ); + SMDS_ElemIteratorPtr fIt = eE[i]->_nodes[0]->GetInverseElementIterator(SMDSAbs_Face); + while ( fIt->more() && !needSmooth ) + { + const SMDS_MeshElement* face = fIt->next(); + if ( getDistFromEdge( face, eE[i]->_nodes[0], faceSize )) + needSmooth = needSmoothing( eE[i]->_cosin, tgtThick, faceSize ); + } } - } + } + // else + // { + // const TopoDS_Face& F1 = TopoDS::Face( S ); + // const TopoDS_Face& F2 = TopoDS::Face( eE[0]->_sWOL ); + // const TopoDS_Edge& E = TopoDS::Edge( eExp.Current() ); + // for ( size_t i = 0; i < eE.size() && !needSmooth; ++i ) + // { + // gp_Vec dir1 = getFaceDir( F1, E, eE[i]->_nodes[0], helper, ok ); + // gp_Vec dir2 = getFaceDir( F2, E, eE[i]->_nodes[0], helper, ok ); + // double angle = dir1.Angle( ); + // double cosin = cos( angle ); + // needSmooth = ( cosin > theMinSmoothCosin ); + // } + // } } - // else - // { - // const TopoDS_Face& F1 = TopoDS::Face( S ); - // const TopoDS_Face& F2 = TopoDS::Face( eE[0]->_sWOL ); - // const TopoDS_Edge& E = TopoDS::Edge( eExp.Current() ); - // for ( size_t i = 0; i < eE.size() && !needSmooth; ++i ) - // { - // gp_Vec dir1 = getFaceDir( F1, E, eE[i]->_nodes[0], helper, ok ); - // gp_Vec dir2 = getFaceDir( F2, E, eE[i]->_nodes[0], helper, ok ); - // double angle = dir1.Angle( ); - // double cosin = cos( angle ); - // needSmooth = ( cosin > theMinSmoothCosin ); - // } - // } + if ( needSmooth ) + for ( TopExp_Explorer eExp( S, TopAbs_EDGE ); eExp.More(); eExp.Next() ) + edgesOfSmooFaces.Add( eExp.Current() ); + + break; + } + case TopAbs_VERTEX: + continue; + default:; } - break; - } - case TopAbs_VERTEX: - continue; - default:; - } - if ( needSmooth ) - { - if ( S.ShapeType() == TopAbs_EDGE ) shapesToSmooth.push_front( iS ); - else shapesToSmooth.push_back ( iS ); - } + if ( needSmooth ) + { + if ( S.ShapeType() == TopAbs_EDGE ) shapesToSmooth.push_front( iS ); + else shapesToSmooth.push_back ( iS ); - } // loop on edgesByGeom + // preparation for smoothing + if ( S.ShapeType() == TopAbs_FACE ) + { + data.PrepareEdgesToSmoothOnFace( & eS[0], + & eS[0] + eS.size(), + TopoDS::Face( S ), + /*substituteSrcNodes=*/false); + } + } + + } // loop on edgesByGeom + } // // loop on [ FACEs, EDGEs ] data._edges.reserve( data._n2eMap.size() ); data._endEdgeOnShape.clear(); @@ -2573,7 +2727,7 @@ bool _ViscousBuilder::setEdgeData(_LayerEdge& edge, TopoDS_Edge E = TopoDS::Edge( helper.GetSubShapeByNode( node, getMeshDS())); gp_Vec inFaceDir = getFaceDir( F, E, node, helper, normOK ); double angle = inFaceDir.Angle( edge._normal ); // [0,PI] - edge._cosin = cos( angle ); + edge._cosin = Cos( angle ); //cout << "Cosin on EDGE " << edge._cosin << " node " << node->GetID() << endl; break; } @@ -2581,7 +2735,17 @@ bool _ViscousBuilder::setEdgeData(_LayerEdge& edge, TopoDS_Vertex V = TopoDS::Vertex( helper.GetSubShapeByNode( node, getMeshDS())); gp_Vec inFaceDir = getFaceDir( F, V, node, helper, normOK ); double angle = inFaceDir.Angle( edge._normal ); // [0,PI] - edge._cosin = cos( angle ); + edge._cosin = Cos( angle ); + if ( totalNbFaces > 2 || helper.IsSeamShape( node->getshapeId() )) + for ( int iF = totalNbFaces-2; iF >=0; --iF ) + { + F = TopoDS::Face( getMeshDS()->IndexToShape( id2Norm[ iF ].first )); + inFaceDir = getFaceDir( F, V, node, helper, normOK ); + if ( normOK ) { + double angle = inFaceDir.Angle( edge._normal ); + edge._cosin = Max( edge._cosin, Cos( angle )); + } + } //cout << "Cosin on VERTEX " << edge._cosin << " node " << node->GetID() << endl; break; } @@ -2630,17 +2794,7 @@ bool _ViscousBuilder::setEdgeData(_LayerEdge& edge, if ( posType == SMDS_TOP_FACE ) { - getSimplices( node, edge._simplices, data._ignoreFaceIds, &data ); - double avgNormProj = 0, avgLen = 0; - for ( size_t i = 0; i < edge._simplices.size(); ++i ) - { - gp_XYZ vec = edge._pos.back() - SMESH_TNodeXYZ( edge._simplices[i]._nPrev ); - avgNormProj += edge._normal * vec; - avgLen += vec.Modulus(); - } - avgNormProj /= edge._simplices.size(); - avgLen /= edge._simplices.size(); - edge._curvature = _Curvature::New( avgNormProj, avgLen ); + _Simplex::GetSimplices( node, edge._simplices, data._ignoreFaceIds, &data ); } } @@ -2793,14 +2947,31 @@ gp_XYZ _ViscousBuilder::getFaceNormal(const SMDS_MeshNode* node, gp_XYZ _ViscousBuilder::getWeigthedNormal( const SMDS_MeshNode* n, std::pair< TGeomID, gp_XYZ > fId2Normal[], - const int nbFaces ) + int nbFaces ) { gp_XYZ resNorm(0,0,0); TopoDS_Shape V = SMESH_MesherHelper::GetSubShapeByNode( n, getMeshDS() ); if ( V.ShapeType() != TopAbs_VERTEX ) { for ( int i = 0; i < nbFaces; ++i ) - resNorm += fId2Normal[i].second / nbFaces ; + resNorm += fId2Normal[i].second; + return resNorm; + } + + // exclude equal normals + int nbUniqNorms = nbFaces; + for ( int i = 0; i < nbFaces; ++i ) + for ( int j = i+1; j < nbFaces; ++j ) + if ( fId2Normal[i].second.IsEqual( fId2Normal[j].second, 0.1 )) + { + fId2Normal[i].second.SetCoord( 0,0,0 ); + --nbUniqNorms; + break; + } + //if ( nbUniqNorms < 3 ) + { + for ( int i = 0; i < nbFaces; ++i ) + resNorm += fId2Normal[i].second; return resNorm; } @@ -3015,11 +3186,11 @@ void _LayerEdge::SetCosin( double cosin ) */ //================================================================================ -void _ViscousBuilder::getSimplices( const SMDS_MeshNode* node, - vector<_Simplex>& simplices, - const set& ingnoreShapes, - const _SolidData* dataToCheckOri, - const bool toSort) +void _Simplex::GetSimplices( const SMDS_MeshNode* node, + vector<_Simplex>& simplices, + const set& ingnoreShapes, + const _SolidData* dataToCheckOri, + const bool toSort) { simplices.clear(); SMDS_ElemIteratorPtr fIt = node->GetInverseElementIterator(SMDSAbs_Face); @@ -3039,23 +3210,32 @@ void _ViscousBuilder::getSimplices( const SMDS_MeshNode* node, } if ( toSort ) + SortSimplices( simplices ); +} + +//================================================================================ +/*! + * \brief Set neighbor simplices side by side + */ +//================================================================================ + +void _Simplex::SortSimplices(vector<_Simplex>& simplices) +{ + vector<_Simplex> sortedSimplices( simplices.size() ); + sortedSimplices[0] = simplices[0]; + int nbFound = 0; + for ( size_t i = 1; i < simplices.size(); ++i ) { - vector<_Simplex> sortedSimplices( simplices.size() ); - sortedSimplices[0] = simplices[0]; - int nbFound = 0; - for ( size_t i = 1; i < simplices.size(); ++i ) - { - for ( size_t j = 1; j < simplices.size(); ++j ) - if ( sortedSimplices[i-1]._nNext == simplices[j]._nPrev ) - { - sortedSimplices[i] = simplices[j]; - nbFound++; - break; - } - } - if ( nbFound == simplices.size() - 1 ) - simplices.swap( sortedSimplices ); + for ( size_t j = 1; j < simplices.size(); ++j ) + if ( sortedSimplices[i-1]._nNext == simplices[j]._nPrev ) + { + sortedSimplices[i] = simplices[j]; + nbFound++; + break; + } } + if ( nbFound == simplices.size() - 1 ) + simplices.swap( sortedSimplices ); } //================================================================================ @@ -3093,11 +3273,13 @@ void _ViscousBuilder::makeGroupOfLE() dumpFunctionEnd(); dumpFunction( SMESH_Comment("makeTmpFaces_") << i ); + dumpCmd( "faceId1 = mesh.NbElements()" ); TopExp_Explorer fExp( _sdVec[i]._solid, TopAbs_FACE ); for ( ; fExp.More(); fExp.Next() ) { if (const SMESHDS_SubMesh* sm = _sdVec[i]._proxyMesh->GetProxySubMesh( fExp.Current())) { + if ( sm->NbElements() == 0 ) continue; SMDS_ElemIteratorPtr fIt = sm->GetElements(); while ( fIt->more()) { @@ -3109,6 +3291,10 @@ void _ViscousBuilder::makeGroupOfLE() } } } + dumpCmd( "faceId2 = mesh.NbElements()" ); + dumpCmd( SMESH_Comment( "mesh.MakeGroup( 'tmpFaces_" ) << i << "'," + << "SMESH.FACE, SMESH.FT_RangeOfIds,'='," + << "'%s-%s' % (faceId1+1, faceId2))"); dumpFunctionEnd(); } #endif @@ -3163,6 +3349,8 @@ bool _ViscousBuilder::inflate(_SolidData& data) debugMsg( "-- geomSize = " << data._geomSize << ", stepSize = " << data._stepSize ); + const double safeFactor = ( 2*data._maxThickness < data._geomSize ) ? 1 : theThickToIntersection; + double avgThick = 0, curThick = 0, distToIntersection = Precision::Infinite(); int nbSteps = 0, nbRepeats = 0; int iBeg, iEnd, iS; @@ -3196,6 +3384,10 @@ bool _ViscousBuilder::inflate(_SolidData& data) { if ( nbSteps > 0 ) { +#ifdef __NOT_INVALIDATE_BAD_SMOOTH + debugMsg("NOT INVALIDATED STEP!"); + return error("Smoothing failed", data._index); +#endif dumpFunction(SMESH_Comment("invalidate")<GetSubMeshContaining( data._index )) + { + if ( !data._proxyMesh->_warning || data._proxyMesh->_warning->IsOK() ) { - SMESH_ComputeErrorPtr& smError = sm->GetComputeError(); - if ( !smError || smError->IsOK() ) - smError.reset - ( new SMESH_ComputeError (COMPERR_WARNING, - SMESH_Comment("Thickness ") << tgtThick << - " of viscous layers not reached," - " average reached thickness is " << avgThick*tgtThick)); + data._proxyMesh->_warning.reset + ( new SMESH_ComputeError (COMPERR_WARNING, + SMESH_Comment("Thickness ") << tgtThick << + " of viscous layers not reached," + " average reached thickness is " << avgThick*tgtThick)); } - + } // Restore position of src nodes moved by infaltion on _noShrinkShapes dumpFunction(SMESH_Comment("restoNoShrink_So")<NbSteps() >= nbSteps+1; - // if ( !toSmooth ) - // { - // if ( iS+1 == data._nbShapesToSmooth ) - // data._nbShapesToSmooth--; - // continue; // target length reached some steps before - // } + // need to smooth this shape? + bool toSmooth = ( data._hyps.front() == data._hyps.back() ); + for ( int i = iBeg; i < iEnd && !toSmooth; ++i ) + toSmooth = ( data._edges[ iBeg ]->NbSteps() >= nbSteps+1 ); + if ( !toSmooth ) + { + if ( iS+1 == data._nbShapesToSmooth ) + data._nbShapesToSmooth--; + continue; // target length reached some steps before + } + // prepare data if ( !data._edges[ iBeg ]->_sWOL.IsNull() && data._edges[ iBeg ]->_sWOL.ShapeType() == TopAbs_FACE ) { @@ -3316,7 +3509,9 @@ bool _ViscousBuilder::smoothAndCheck(_SolidData& data, { F.Nullify(); surface.Nullify(); } - TGeomID sInd = data._edges[ iBeg ]->_nodes[0]->getshapeId(); + const TGeomID sInd = data._edges[ iBeg ]->_nodes[0]->getshapeId(); + + // perform smoothing if ( data._edges[ iBeg ]->IsOnEdge() ) { @@ -3342,6 +3537,9 @@ bool _ViscousBuilder::smoothAndCheck(_SolidData& data, else { // smooth on FACE's + + const bool isConcaveFace = data._concaveFaces.count( sInd ); + int step = 0, stepLimit = 5, badNb = 0; moved = true; while (( ++step <= stepLimit && moved ) || improved ) { @@ -3352,27 +3550,28 @@ bool _ViscousBuilder::smoothAndCheck(_SolidData& data, moved = false; if ( step % 2 ) for ( int i = iBeg; i < iEnd; ++i ) // iterate forward - moved |= data._edges[i]->Smooth(badNb); + moved |= data._edges[i]->Smooth( badNb, step, isConcaveFace ); else for ( int i = iEnd-1; i >= iBeg; --i ) // iterate backward - moved |= data._edges[i]->Smooth(badNb); + moved |= data._edges[i]->Smooth( badNb, step, isConcaveFace ); improved = ( badNb < oldBadNb ); // issue 22576 -- no bad faces but still there are intersections to fix - if ( improved && badNb == 0 ) - stepLimit = step + 3; + // if ( improved && badNb == 0 ) + // stepLimit = step + 3; dumpFunctionEnd(); } if ( badNb > 0 ) { #ifdef __myDEBUG + double vol = 0; for ( int i = iBeg; i < iEnd; ++i ) { _LayerEdge* edge = data._edges[i]; SMESH_TNodeXYZ tgtXYZ( edge->_nodes.back() ); for ( size_t j = 0; j < edge->_simplices.size(); ++j ) - if ( !edge->_simplices[j].IsForward( edge->_nodes[0], &tgtXYZ )) + if ( !edge->_simplices[j].IsForward( edge->_nodes[0], &tgtXYZ, vol )) { cout << "Bad simplex ( " << edge->_nodes[0]->GetID()<< " "<< tgtXYZ._node->GetID() << " "<< edge->_simplices[j]._nPrev->GetID() @@ -3425,6 +3624,11 @@ bool _ViscousBuilder::smoothAndCheck(_SolidData& data, if ( convFace->_subIdToEdgeEnd.count ( data._edges[i]->_nodes[0]->getshapeId() )) continue; + // ignore intersection of a _LayerEdge based on a FACE with an element on this FACE + // ( avoid limiting the thickness on the case of issue 22576) + if ( intFace->getshapeId() == data._edges[i]->_nodes[0]->getshapeId() ) + continue; + distToIntersection = dist; iLE = i; closestFace = intFace; @@ -3454,9 +3658,9 @@ bool _ViscousBuilder::smoothAndCheck(_SolidData& data, Handle(Geom_Curve) _SolidData::CurveForSmooth( const TopoDS_Edge& E, const int iFrom, const int iTo, - Handle(Geom_Surface)& surface, const TopoDS_Face& F, - SMESH_MesherHelper& helper) + SMESH_MesherHelper& helper, + vector<_LayerEdge* >* edges) { TGeomID eIndex = helper.GetMeshDS()->ShapeToIndex( E ); @@ -3464,6 +3668,9 @@ Handle(Geom_Curve) _SolidData::CurveForSmooth( const TopoDS_Edge& E, if ( i2curve == _edge2curve.end() ) { + if ( edges ) + _edges.swap( *edges ); + // sort _LayerEdge's by position on the EDGE SortOnEdge( E, iFrom, iTo, helper ); @@ -3494,11 +3701,21 @@ Handle(Geom_Curve) _SolidData::CurveForSmooth( const TopoDS_Edge& E, bndBox.Add( SMESH_TNodeXYZ( nIt->next() )); gp_XYZ size = bndBox.CornerMax() - bndBox.CornerMin(); - SMESH_TNodeXYZ p0( _edges[iFrom]->_2neibors->tgtNode(0) ); - SMESH_TNodeXYZ p1( _edges[iFrom]->_2neibors->tgtNode(1) ); - const double lineTol = 1e-2 * ( p0 - p1 ).Modulus(); + gp_Pnt p0, p1; + if ( iTo-iFrom > 1 ) { + p0 = SMESH_TNodeXYZ( _edges[iFrom]->_nodes[0] ); + p1 = SMESH_TNodeXYZ( _edges[iFrom+1]->_nodes[0] ); + } + else { + p0 = curve->Value( f ); + p1 = curve->Value( l ); + } + const double lineTol = 1e-2 * p0.Distance( p1 ); for ( int i = 0; i < 3 && !isLine; ++i ) isLine = ( size.Coord( i+1 ) <= lineTol ); + + if ( isLine ) + line = new Geom_Line( gp::OX() ); // only type does matter } if ( !isLine && !isCirc && iTo-iFrom > 2) // Check if the EDGE is close to a circle { @@ -3545,6 +3762,9 @@ Handle(Geom_Curve) _SolidData::CurveForSmooth( const TopoDS_Edge& E, } } + if ( edges ) + _edges.swap( *edges ); + Handle(Geom_Curve)& res = _edge2curve[ eIndex ]; if ( isLine ) res = line; @@ -3576,11 +3796,21 @@ void _SolidData::SortOnEdge( const TopoDS_Edge& E, for ( int i = iFrom; i < iTo; ++i, ++u2e ) _edges[i] = u2e->second; - // set _2neibors according to the new order + Sort2NeiborsOnEdge( iFrom, iTo ); +} + +//================================================================================ +/*! + * \brief Set _2neibors according to the order of _LayerEdge on EDGE + */ +//================================================================================ + +void _SolidData::Sort2NeiborsOnEdge( const int iFrom, const int iTo) +{ for ( int i = iFrom; i < iTo-1; ++i ) if ( _edges[i]->_2neibors->tgtNode(1) != _edges[i+1]->_nodes.back() ) _edges[i]->_2neibors->reverse(); - if ( u2edge.size() > 1 && + if ( iTo - iFrom > 1 && _edges[iTo-1]->_2neibors->tgtNode(0) != _edges[iTo-2]->_nodes.back() ) _edges[iTo-1]->_2neibors->reverse(); } @@ -3612,6 +3842,53 @@ bool _SolidData::GetShapeEdges(const TGeomID shapeID, return false; } +//================================================================================ +/*! + * \brief Prepare data of the _LayerEdge for smoothing on FACE + */ +//================================================================================ + +void _SolidData::PrepareEdgesToSmoothOnFace( _LayerEdge** edgeBeg, + _LayerEdge** edgeEnd, + const TopoDS_Face& face, + bool substituteSrcNodes ) +{ + set< TGeomID > vertices; + SMESH_MesherHelper helper( *_proxyMesh->GetMesh() ); + if ( isConcave( face, helper, &vertices )) + _concaveFaces.insert( (*edgeBeg)->_nodes[0]->getshapeId() ); + + for ( _LayerEdge** edge = edgeBeg; edge != edgeEnd; ++edge ) + (*edge)->_smooFunction = 0; + + for ( ; edgeBeg != edgeEnd; ++edgeBeg ) + { + _LayerEdge* edge = *edgeBeg; + _Simplex::GetSimplices + ( edge->_nodes[0], edge->_simplices, _ignoreFaceIds, this, /*sort=*/true ); + + edge->ChooseSmooFunction( vertices, _n2eMap ); + + double avgNormProj = 0, avgLen = 0; + for ( size_t i = 0; i < edge->_simplices.size(); ++i ) + { + _Simplex& s = edge->_simplices[i]; + + gp_XYZ vec = edge->_pos.back() - SMESH_TNodeXYZ( s._nPrev ); + avgNormProj += edge->_normal * vec; + avgLen += vec.Modulus(); + if ( substituteSrcNodes ) + { + s._nNext = _n2eMap[ s._nNext ]->_nodes.back(); + s._nPrev = _n2eMap[ s._nPrev ]->_nodes.back(); + } + } + avgNormProj /= edge->_simplices.size(); + avgLen /= edge->_simplices.size(); + edge->_curvature = _Curvature::New( avgNormProj, avgLen ); + } +} + //================================================================================ /*! * \brief Add faces for smoothing @@ -3648,10 +3925,25 @@ void _SolidData::AddShapesToSmooth( const set< TGeomID >& faceIDs ) int iBeg, iEnd; for ( size_t i = _nbShapesToSmooth; i <= lastSmooth; ++i ) { - vector< _LayerEdge* > & edgesVec = iEnds.count(i) ? smoothLE : nonSmoothLE; + bool toSmooth = iEnds.count(i); + vector< _LayerEdge* > & edgesVec = toSmooth ? smoothLE : nonSmoothLE; iBeg = i ? _endEdgeOnShape[ i-1 ] : 0; iEnd = _endEdgeOnShape[ i ]; - edgesVec.insert( edgesVec.end(), _edges.begin() + iBeg, _edges.begin() + iEnd ); + edgesVec.insert( edgesVec.end(), _edges.begin() + iBeg, _edges.begin() + iEnd ); + + // preparation for smoothing on FACE + if ( toSmooth && _edges[iBeg]->_nodes[0]->GetPosition()->GetDim() == 2 ) + { + TopoDS_Shape S = SMESH_MesherHelper::GetSubShapeByNode( _edges[iBeg]->_nodes[0], + _proxyMesh->GetMeshDS() ); + if ( !S.IsNull() && S.ShapeType() == TopAbs_FACE ) + { + PrepareEdgesToSmoothOnFace( &_edges[ iBeg ], + &_edges[ iEnd ], + TopoDS::Face( S ), + /*substituteSrcNodes=*/true ); + } + } } iBeg = _nbShapesToSmooth ? _endEdgeOnShape[ _nbShapesToSmooth-1 ] : 0; @@ -3688,7 +3980,7 @@ bool _ViscousBuilder::smoothAnalyticEdge( _SolidData& data, helper.GetMeshDS()); TopoDS_Edge E = TopoDS::Edge( S ); - Handle(Geom_Curve) curve = data.CurveForSmooth( E, iFrom, iTo, surface, F, helper ); + Handle(Geom_Curve) curve = data.CurveForSmooth( E, iFrom, iTo, F, helper ); if ( curve.IsNull() ) return false; // compute a relative length of segments @@ -4509,12 +4801,13 @@ bool _ConvexFace::GetCenterOfCurvature( _LayerEdge* ledge, bool _ConvexFace::CheckPrisms() const { + double vol = 0; for ( size_t i = 0; i < _simplexTestEdges.size(); ++i ) { const _LayerEdge* edge = _simplexTestEdges[i]; SMESH_TNodeXYZ tgtXYZ( edge->_nodes.back() ); for ( size_t j = 0; j < edge->_simplices.size(); ++j ) - if ( !edge->_simplices[j].IsForward( edge->_nodes[0], &tgtXYZ )) + if ( !edge->_simplices[j].IsForward( edge->_nodes[0], &tgtXYZ, vol )) { debugMsg( "Bad simplex of _simplexTestEdges (" << " "<< edge->_nodes[0]->GetID()<< " "<< tgtXYZ._node->GetID() @@ -4686,10 +4979,11 @@ gp_Ax1 _LayerEdge::LastSegment(double& segLen) const gp_XYZ orig = _pos.back(); gp_XYZ dir; int iPrev = _pos.size() - 2; + const double tol = ( _len > 0 ) ? 0.3*_len : 1e-100; // adjusted for IPAL52478 + PAL22576 while ( iPrev >= 0 ) { dir = orig - _pos[iPrev]; - if ( dir.SquareModulus() > 1e-100 ) + if ( dir.SquareModulus() > tol*tol ) break; else iPrev--; @@ -4772,15 +5066,15 @@ bool _LayerEdge::SegTriaInter( const gp_Ax1& lastSegment, { //const double EPSILON = 1e-6; - gp_XYZ orig = lastSegment.Location().XYZ(); - gp_XYZ dir = lastSegment.Direction().XYZ(); + const gp_Pnt& orig = lastSegment.Location(); + const gp_Dir& dir = lastSegment.Direction(); SMESH_TNodeXYZ vert0( n0 ); SMESH_TNodeXYZ vert1( n1 ); SMESH_TNodeXYZ vert2( n2 ); /* calculate distance from vert0 to ray origin */ - gp_XYZ tvec = orig - vert0; + gp_XYZ tvec = orig.XYZ() - vert0; //if ( tvec * dir > EPSILON ) // intersected face is at back side of the temporary face this _LayerEdge belongs to @@ -4790,17 +5084,16 @@ bool _LayerEdge::SegTriaInter( const gp_Ax1& lastSegment, gp_XYZ edge2 = vert2 - vert0; /* begin calculating determinant - also used to calculate U parameter */ - gp_XYZ pvec = dir ^ edge2; + gp_XYZ pvec = dir.XYZ() ^ edge2; /* if determinant is near zero, ray lies in plane of triangle */ double det = edge1 * pvec; if (det > -EPSILON && det < EPSILON) return false; - double inv_det = 1.0 / det; /* calculate U parameter and test bounds */ - double u = ( tvec * pvec ) * inv_det; + double u = ( tvec * pvec ) / det; //if (u < 0.0 || u > 1.0) if (u < -EPSILON || u > 1.0 + EPSILON) return false; @@ -4809,13 +5102,13 @@ bool _LayerEdge::SegTriaInter( const gp_Ax1& lastSegment, gp_XYZ qvec = tvec ^ edge1; /* calculate V parameter and test bounds */ - double v = (dir * qvec) * inv_det; + double v = (dir.XYZ() * qvec) / det; //if ( v < 0.0 || u + v > 1.0 ) if ( v < -EPSILON || u + v > 1.0 + EPSILON) return false; /* calculate t, ray intersects triangle */ - t = (edge2 * qvec) * inv_det; + t = (edge2 * qvec) / det; //return true; return t > 0.; @@ -4876,12 +5169,13 @@ bool _LayerEdge::SmoothOnEdge(Handle(Geom_Surface)& surface, tgtNode->setXYZ( newPos.X(), newPos.Y(), newPos.Z() ); } - if ( _curvature && lenDelta < 0 ) - { - gp_Pnt prevPos( _pos[ _pos.size()-2 ]); - _len -= prevPos.Distance( oldPos ); - _len += prevPos.Distance( newPos ); - } + // commented for IPAL0052478 + // if ( _curvature && lenDelta < 0 ) + // { + // gp_Pnt prevPos( _pos[ _pos.size()-2 ]); + // _len -= prevPos.Distance( oldPos ); + // _len += prevPos.Distance( newPos ); + // } bool moved = distNewOld > dist01/50; //if ( moved ) dumpMove( tgtNode ); // debug @@ -4896,59 +5190,554 @@ bool _LayerEdge::SmoothOnEdge(Handle(Geom_Surface)& surface, */ //================================================================================ -bool _LayerEdge::Smooth(int& badNb) +bool _LayerEdge::Smooth(int& badNb, const int step, const bool isConcaveFace ) { + bool moved = false; if ( _simplices.size() < 2 ) - return false; // _LayerEdge inflated along EDGE or FACE + return moved; // _LayerEdge inflated along EDGE or FACE + + const gp_XYZ& curPos ( _pos.back() ); + const gp_XYZ& prevPos( _pos[ _pos.size()-2 ]); + + // quality metrics (orientation) of tetras around _tgtNode + int nbOkBefore = 0; + double vol, minVolBefore = 1e100; + for ( size_t i = 0; i < _simplices.size(); ++i ) + { + nbOkBefore += _simplices[i].IsForward( _nodes[0], &curPos, vol ); + minVolBefore = Min( minVolBefore, vol ); + } + int nbBad = _simplices.size() - nbOkBefore; + + // compute new position for the last _pos using different _funs + gp_XYZ newPos, bestNewPos; + for ( int iFun = -1; iFun < theNbSmooFuns; ++iFun ) + { + if ( iFun < 0 ) + newPos = (this->*_smooFunction)(); // fun chosen by ChooseSmooFunction() + else if ( _funs[ iFun ] == _smooFunction ) + continue; // _smooFunction again + else if ( step > 0 ) + newPos = (this->*_funs[ iFun ])(); // try other smoothing fun + else + break; // let "easy" functions improve elements around distorted ones + + if ( _curvature ) + { + double delta = _curvature->lenDelta( _len ); + if ( delta > 0 ) + newPos += _normal * delta; + else + { + double segLen = _normal * ( newPos - prevPos ); + if ( segLen + delta > 0 ) + newPos += _normal * delta; + } + // double segLenChange = _normal * ( curPos - newPos ); + // newPos += 0.5 * _normal * segLenChange; + } - // compute new position for the last _pos + int nbOkAfter = 0; + double minVolAfter = 1e100; + for ( size_t i = 0; i < _simplices.size(); ++i ) + { + nbOkAfter += _simplices[i].IsForward( _nodes[0], &newPos, vol ); + minVolAfter = Min( minVolAfter, vol ); + } + // get worse? + if ( nbOkAfter < nbOkBefore ) + continue; + if (( isConcaveFace ) && + ( nbOkAfter == nbOkBefore ) && + //( iFun > -1 || nbOkAfter < _simplices.size() ) && + ( minVolAfter <= minVolBefore )) + continue; + + SMDS_MeshNode* n = const_cast< SMDS_MeshNode* >( _nodes.back() ); + + // commented for IPAL0052478 + // _len -= prevPos.Distance(SMESH_TNodeXYZ( n )); + // _len += prevPos.Distance(newPos); + + n->setXYZ( newPos.X(), newPos.Y(), newPos.Z()); + _pos.back() = newPos; + moved = true; + dumpMoveComm( n, _funNames[ iFun < 0 ? smooFunID() : iFun ]); + + nbBad = _simplices.size() - nbOkAfter; + + if ( iFun > -1 ) + { + //_smooFunction = _funs[ iFun ]; + // cout << "# " << _funNames[ iFun ] << "\t N:" << _nodes.back()->GetID() + // << "\t nbBad: " << _simplices.size() - nbOkAfter + // << " minVol: " << minVolAfter + // << " " << newPos.X() << " " << newPos.Y() << " " << newPos.Z() + // << endl; + minVolBefore = minVolAfter; + nbOkBefore = nbOkAfter; + continue; // look for a better function + } + + break; + + } // loop on smoothing functions + + badNb += nbBad; + return moved; +} + +//================================================================================ +/*! + * \brief Chooses a smoothing technic giving a position most close to an initial one. + * For a correct result, _simplices must contain nodes lying on geometry. + */ +//================================================================================ + +void _LayerEdge::ChooseSmooFunction( const set< TGeomID >& concaveVertices, + const TNode2Edge& n2eMap) +{ + if ( _smooFunction ) return; + + // use smoothNefPolygon() near concaveVertices + if ( !concaveVertices.empty() ) + { + for ( size_t i = 0; i < _simplices.size(); ++i ) + { + if ( concaveVertices.count( _simplices[i]._nPrev->getshapeId() )) + { + _smooFunction = _funs[ FUN_NEFPOLY ]; + + // set FUN_CENTROIDAL to neighbor edges + TNode2Edge::const_iterator n2e; + for ( i = 0; i < _simplices.size(); ++i ) + { + if (( _simplices[i]._nPrev->GetPosition()->GetDim() == 2 ) && + (( n2e = n2eMap.find( _simplices[i]._nPrev )) != n2eMap.end() )) + { + n2e->second->_smooFunction = _funs[ FUN_CENTROIDAL ]; + } + } + return; + } + } + //} + + // this coice is done only if ( !concaveVertices.empty() ) for Grids/smesh/bugs_19/X1 + // where the nodes are smoothed too far along a sphere thus creating + // inverted _simplices + double dist[theNbSmooFuns]; + //double coef[theNbSmooFuns] = { 1., 1.2, 1.4, 1.4 }; + double coef[theNbSmooFuns] = { 1., 1., 1., 1. }; + + double minDist = Precision::Infinite(); + gp_Pnt p = SMESH_TNodeXYZ( _nodes[0] ); + for ( int i = 0; i < FUN_NEFPOLY; ++i ) + { + gp_Pnt newP = (this->*_funs[i])(); + dist[i] = p.SquareDistance( newP ); + if ( dist[i]*coef[i] < minDist ) + { + _smooFunction = _funs[i]; + minDist = dist[i]*coef[i]; + } + } + } + else + { + _smooFunction = _funs[ FUN_LAPLACIAN ]; + } + // int minDim = 3; + // for ( size_t i = 0; i < _simplices.size(); ++i ) + // minDim = Min( minDim, _simplices[i]._nPrev->GetPosition()->GetDim() ); + // if ( minDim == 0 ) + // _smooFunction = _funs[ FUN_CENTROIDAL ]; + // else if ( minDim == 1 ) + // _smooFunction = _funs[ FUN_CENTROIDAL ]; + + + // int iMin; + // for ( int i = 0; i < FUN_NB; ++i ) + // { + // //cout << dist[i] << " "; + // if ( _smooFunction == _funs[i] ) { + // iMin = i; + // //debugMsg( fNames[i] ); + // break; + // } + // } + // cout << _funNames[ iMin ] << "\t N:" << _nodes.back()->GetID() << endl; +} + +//================================================================================ +/*! + * \brief Returns a name of _SmooFunction + */ +//================================================================================ + +int _LayerEdge::smooFunID( _LayerEdge::PSmooFun fun) const +{ + if ( !fun ) + fun = _smooFunction; + for ( int i = 0; i < theNbSmooFuns; ++i ) + if ( fun == _funs[i] ) + return i; + + return theNbSmooFuns; +} + +//================================================================================ +/*! + * \brief Computes a new node position using Laplacian smoothing + */ +//================================================================================ + +gp_XYZ _LayerEdge::smoothLaplacian() +{ gp_XYZ newPos (0,0,0); for ( size_t i = 0; i < _simplices.size(); ++i ) newPos += SMESH_TNodeXYZ( _simplices[i]._nPrev ); newPos /= _simplices.size(); - const gp_XYZ& curPos ( _pos.back() ); - const gp_Pnt prevPos( _pos[ _pos.size()-2 ]); - if ( _curvature ) + return newPos; +} + +//================================================================================ +/*! + * \brief Computes a new node position using angular-based smoothing + */ +//================================================================================ + +gp_XYZ _LayerEdge::smoothAngular() +{ + vector< gp_Vec > edgeDir; edgeDir. reserve( _simplices.size() + 1); + vector< double > edgeSize; edgeSize.reserve( _simplices.size() ); + vector< gp_XYZ > points; points. reserve( _simplices.size() ); + + gp_XYZ pPrev = SMESH_TNodeXYZ( _simplices.back()._nPrev ); + gp_XYZ pN( 0,0,0 ); + for ( size_t i = 0; i < _simplices.size(); ++i ) { - double delta = _curvature->lenDelta( _len ); - if ( delta > 0 ) - newPos += _normal * delta; + gp_XYZ p = SMESH_TNodeXYZ( _simplices[i]._nPrev ); + edgeDir.push_back( p - pPrev ); + edgeSize.push_back( edgeDir.back().Magnitude() ); + //double edgeSize = edgeDir.back().Magnitude(); + if ( edgeSize.back() < numeric_limits::min() ) + { + edgeDir.pop_back(); + edgeSize.pop_back(); + } else { - double segLen = _normal * ( newPos - prevPos.XYZ() ); - if ( segLen + delta > 0 ) - newPos += _normal * delta; + edgeDir.back() /= edgeSize.back(); + points.push_back( p ); + pN += p; } - // double segLenChange = _normal * ( curPos - newPos ); - // newPos += 0.5 * _normal * segLenChange; + pPrev = p; } + edgeDir.push_back ( edgeDir[0] ); + edgeSize.push_back( edgeSize[0] ); + pN /= points.size(); - // count quality metrics (orientation) of tetras around _tgtNode - int nbOkBefore = 0; + gp_XYZ newPos(0,0,0); + //gp_XYZ pN = SMESH_TNodeXYZ( _nodes.back() ); + double sumSize = 0; + for ( size_t i = 0; i < points.size(); ++i ) + { + gp_Vec toN( pN - points[i]); + double toNLen = toN.Magnitude(); + if ( toNLen < numeric_limits::min() ) + { + newPos += pN; + continue; + } + gp_Vec bisec = edgeDir[i] + edgeDir[i+1]; + double bisecLen = bisec.SquareMagnitude(); + if ( bisecLen < numeric_limits::min() ) + { + gp_Vec norm = edgeDir[i] ^ toN; + bisec = norm ^ edgeDir[i]; + bisecLen = bisec.SquareMagnitude(); + } + bisecLen = Sqrt( bisecLen ); + bisec /= bisecLen; + +#if 1 + //bisecLen = 1.; + gp_XYZ pNew = ( points[i] + bisec.XYZ() * toNLen ) * bisecLen; + sumSize += bisecLen; +#else + gp_XYZ pNew = ( points[i] + bisec.XYZ() * toNLen ) * ( edgeSize[i] + edgeSize[i+1] ); + sumSize += ( edgeSize[i] + edgeSize[i+1] ); +#endif + newPos += pNew; + } + newPos /= sumSize; + + return newPos; +} + +//================================================================================ +/*! + * \brief Computes a new node position using weigthed node positions + */ +//================================================================================ + +gp_XYZ _LayerEdge::smoothLengthWeighted() +{ + vector< double > edgeSize; edgeSize.reserve( _simplices.size() + 1); + vector< gp_XYZ > points; points. reserve( _simplices.size() ); + + gp_XYZ pPrev = SMESH_TNodeXYZ( _simplices.back()._nPrev ); for ( size_t i = 0; i < _simplices.size(); ++i ) - nbOkBefore += _simplices[i].IsForward( _nodes[0], &curPos ); + { + gp_XYZ p = SMESH_TNodeXYZ( _simplices[i]._nPrev ); + edgeSize.push_back( ( p - pPrev ).Modulus() ); + if ( edgeSize.back() < numeric_limits::min() ) + { + edgeSize.pop_back(); + } + else + { + points.push_back( p ); + } + pPrev = p; + } + edgeSize.push_back( edgeSize[0] ); - int nbOkAfter = 0; + gp_XYZ newPos(0,0,0); + double sumSize = 0; + for ( size_t i = 0; i < points.size(); ++i ) + { + newPos += points[i] * ( edgeSize[i] + edgeSize[i+1] ); + sumSize += edgeSize[i] + edgeSize[i+1]; + } + newPos /= sumSize; + return newPos; +} + +//================================================================================ +/*! + * \brief Computes a new node position using angular-based smoothing + */ +//================================================================================ + +gp_XYZ _LayerEdge::smoothCentroidal() +{ + gp_XYZ newPos(0,0,0); + gp_XYZ pN = SMESH_TNodeXYZ( _nodes.back() ); + double sumSize = 0; for ( size_t i = 0; i < _simplices.size(); ++i ) - nbOkAfter += _simplices[i].IsForward( _nodes[0], &newPos ); + { + gp_XYZ p1 = SMESH_TNodeXYZ( _simplices[i]._nPrev ); + gp_XYZ p2 = SMESH_TNodeXYZ( _simplices[i]._nNext ); + gp_XYZ gc = ( pN + p1 + p2 ) / 3.; + double size = (( p1 - pN ) ^ ( p2 - pN )).Modulus(); - if ( nbOkAfter < nbOkBefore ) - return false; + sumSize += size; + newPos += gc * size; + } + newPos /= sumSize; - SMDS_MeshNode* n = const_cast< SMDS_MeshNode* >( _nodes.back() ); + return newPos; +} - _len -= prevPos.Distance(SMESH_TNodeXYZ( n )); - _len += prevPos.Distance(newPos); +//================================================================================ +/*! + * \brief Computes a new node position located inside a Nef polygon + */ +//================================================================================ - n->setXYZ( newPos.X(), newPos.Y(), newPos.Z()); - _pos.back() = newPos; +gp_XYZ _LayerEdge::smoothNefPolygon() +{ + gp_XYZ newPos(0,0,0); - badNb += _simplices.size() - nbOkAfter; + // get a plane to seach a solution on + + vector< gp_XYZ > vecs( _simplices.size() + 1 ); + size_t i; + const double tol = numeric_limits::min(); + gp_XYZ center(0,0,0); + for ( i = 0; i < _simplices.size(); ++i ) + { + vecs[i] = ( SMESH_TNodeXYZ( _simplices[i]._nNext ) - + SMESH_TNodeXYZ( _simplices[i]._nPrev )); + center += SMESH_TNodeXYZ( _simplices[i]._nPrev ); + } + vecs.back() = vecs[0]; + center /= _simplices.size(); - dumpMove( n ); + gp_XYZ zAxis(0,0,0); + for ( i = 0; i < _simplices.size(); ++i ) + zAxis += vecs[i] ^ vecs[i+1]; - return true; + gp_XYZ yAxis; + for ( i = 0; i < _simplices.size(); ++i ) + { + yAxis = vecs[i]; + if ( yAxis.SquareModulus() > tol ) + break; + } + gp_XYZ xAxis = yAxis ^ zAxis; + // SMESH_TNodeXYZ p0( _simplices[0]._nPrev ); + // const double tol = 1e-6 * ( p0.Distance( _simplices[1]._nPrev ) + + // p0.Distance( _simplices[2]._nPrev )); + // gp_XYZ center = smoothLaplacian(); + // gp_XYZ xAxis, yAxis, zAxis; + // for ( i = 0; i < _simplices.size(); ++i ) + // { + // xAxis = SMESH_TNodeXYZ( _simplices[i]._nPrev ) - center; + // if ( xAxis.SquareModulus() > tol*tol ) + // break; + // } + // for ( i = 1; i < _simplices.size(); ++i ) + // { + // yAxis = SMESH_TNodeXYZ( _simplices[i]._nPrev ) - center; + // zAxis = xAxis ^ yAxis; + // if ( zAxis.SquareModulus() > tol*tol ) + // break; + // } + // if ( i == _simplices.size() ) return newPos; + + yAxis = zAxis ^ xAxis; + xAxis /= xAxis.Modulus(); + yAxis /= yAxis.Modulus(); + + // get half-planes of _simplices + + vector< _halfPlane > halfPlns( _simplices.size() ); + int nbHP = 0; + for ( size_t i = 0; i < _simplices.size(); ++i ) + { + gp_XYZ OP1 = SMESH_TNodeXYZ( _simplices[i]._nPrev ) - center; + gp_XYZ OP2 = SMESH_TNodeXYZ( _simplices[i]._nNext ) - center; + gp_XY p1( OP1 * xAxis, OP1 * yAxis ); + gp_XY p2( OP2 * xAxis, OP2 * yAxis ); + gp_XY vec12 = p2 - p1; + double dist12 = vec12.Modulus(); + if ( dist12 < tol ) + continue; + vec12 /= dist12; + halfPlns[ nbHP ]._pos = p1; + halfPlns[ nbHP ]._dir = vec12; + halfPlns[ nbHP ]._inNorm.SetCoord( -vec12.Y(), vec12.X() ); + ++nbHP; + } + + // intersect boundaries of half-planes, define state of intersection points + // in relation to all half-planes and calculate internal point of a 2D polygon + + double sumLen = 0; + gp_XY newPos2D (0,0); + + enum { UNDEF = -1, NOT_OUT, IS_OUT, NO_INT }; + typedef std::pair< gp_XY, int > TIntPntState; // coord and isOut state + TIntPntState undefIPS( gp_XY(1e100,1e100), UNDEF ); + + vector< vector< TIntPntState > > allIntPnts( nbHP ); + for ( int iHP1 = 0; iHP1 < nbHP; ++iHP1 ) + { + vector< TIntPntState > & intPnts1 = allIntPnts[ iHP1 ]; + if ( intPnts1.empty() ) intPnts1.resize( nbHP, undefIPS ); + + int iPrev = SMESH_MesherHelper::WrapIndex( iHP1 - 1, nbHP ); + int iNext = SMESH_MesherHelper::WrapIndex( iHP1 + 1, nbHP ); + + int nbNotOut = 0; + const gp_XY* segEnds[2] = { 0, 0 }; // NOT_OUT points + + for ( int iHP2 = 0; iHP2 < nbHP; ++iHP2 ) + { + if ( iHP1 == iHP2 ) continue; + + TIntPntState & ips1 = intPnts1[ iHP2 ]; + if ( ips1.second == UNDEF ) + { + // find an intersection point of boundaries of iHP1 and iHP2 + + if ( iHP2 == iPrev ) // intersection with neighbors is known + ips1.first = halfPlns[ iHP1 ]._pos; + else if ( iHP2 == iNext ) + ips1.first = halfPlns[ iHP2 ]._pos; + else if ( !halfPlns[ iHP1 ].FindInterestion( halfPlns[ iHP2 ], ips1.first )) + ips1.second = NO_INT; + + // classify the found intersection point + if ( ips1.second != NO_INT ) + { + ips1.second = NOT_OUT; + for ( int i = 0; i < nbHP && ips1.second == NOT_OUT; ++i ) + if ( i != iHP1 && i != iHP2 && + halfPlns[ i ].IsOut( ips1.first, tol )) + ips1.second = IS_OUT; + } + vector< TIntPntState > & intPnts2 = allIntPnts[ iHP2 ]; + if ( intPnts2.empty() ) intPnts2.resize( nbHP, undefIPS ); + TIntPntState & ips2 = intPnts2[ iHP1 ]; + ips2 = ips1; + } + if ( ips1.second == NOT_OUT ) + { + ++nbNotOut; + segEnds[ bool(segEnds[0]) ] = & ips1.first; + } + } + + // find a NOT_OUT segment of boundary which is located between + // two NOT_OUT int points + + if ( nbNotOut < 2 ) + continue; // no such a segment + + if ( nbNotOut > 2 ) + { + // sort points along the boundary + map< double, TIntPntState* > ipsByParam; + for ( int iHP2 = 0; iHP2 < nbHP; ++iHP2 ) + { + TIntPntState & ips1 = intPnts1[ iHP2 ]; + if ( ips1.second != NO_INT ) + { + gp_XY op = ips1.first - halfPlns[ iHP1 ]._pos; + double param = op * halfPlns[ iHP1 ]._dir; + ipsByParam.insert( make_pair( param, & ips1 )); + } + } + // look for two neighboring NOT_OUT points + nbNotOut = 0; + map< double, TIntPntState* >::iterator u2ips = ipsByParam.begin(); + for ( ; u2ips != ipsByParam.end(); ++u2ips ) + { + TIntPntState & ips1 = *(u2ips->second); + if ( ips1.second == NOT_OUT ) + segEnds[ bool( nbNotOut++ ) ] = & ips1.first; + else if ( nbNotOut >= 2 ) + break; + else + nbNotOut = 0; + } + } + + if ( nbNotOut >= 2 ) + { + double len = ( *segEnds[0] - *segEnds[1] ).Modulus(); + sumLen += len; + + newPos2D += 0.5 * len * ( *segEnds[0] + *segEnds[1] ); + } + } + + if ( sumLen > 0 ) + { + newPos2D /= sumLen; + newPos = center + xAxis * newPos2D.X() + yAxis * newPos2D.Y(); + } + else + { + newPos = center; + } + + return newPos; } //================================================================================ @@ -5483,7 +6272,7 @@ bool _ViscousBuilder::shrink() if ( !smoothNodes.empty() ) { vector<_Simplex> simplices; - getSimplices( smoothNodes[0], simplices, ignoreShapes ); + _Simplex::GetSimplices( smoothNodes[0], simplices, ignoreShapes ); helper.GetNodeUV( F, simplices[0]._nPrev, 0, &isOkUV ); // fix UV of silpmex nodes helper.GetNodeUV( F, simplices[0]._nNext, 0, &isOkUV ); gp_XY uv = helper.GetNodeUV( F, smoothNodes[0], 0, &isOkUV ); @@ -5524,6 +6313,7 @@ bool _ViscousBuilder::shrink() while ( fIt->more() ) if ( const SMDS_MeshElement* f = fIt->next() ) dumpChangeNodes( f ); + dumpFunctionEnd(); // Replace source nodes by target nodes in mesh faces to shrink dumpFunction(SMESH_Comment("replNodesOnFace")<first); // debug @@ -5549,6 +6339,7 @@ bool _ViscousBuilder::shrink() dumpChangeNodes( f ); } } + dumpFunctionEnd(); // find out if a FACE is concave const bool isConcaveFace = isConcave( F, helper ); @@ -5563,11 +6354,12 @@ bool _ViscousBuilder::shrink() const SMDS_MeshNode* n = smoothNodes[i]; nodesToSmooth[ i ]._node = n; // src nodes must be replaced by tgt nodes to have tgt nodes in _simplices - getSimplices( n, nodesToSmooth[ i ]._simplices, ignoreShapes, NULL, sortSimplices ); + _Simplex::GetSimplices( n, nodesToSmooth[ i ]._simplices, ignoreShapes, 0, sortSimplices); // fix up incorrect uv of nodes on the FACE helper.GetNodeUV( F, n, 0, &isOkUV); dumpMove( n ); } + dumpFunctionEnd(); } //if ( nodesToSmooth.empty() ) continue; @@ -5588,7 +6380,7 @@ bool _ViscousBuilder::shrink() // srinked while srinking another FACE srinker.RestoreParams(); } - getSimplices( /*tgtNode=*/edge->_nodes.back(), edge->_simplices, ignoreShapes ); + _Simplex::GetSimplices( /*tgtNode=*/edge->_nodes.back(), edge->_simplices, ignoreShapes ); } } @@ -5678,10 +6470,10 @@ bool _ViscousBuilder::shrink() n = usedNodes.find( nodesToSmooth[ i ]._node ); if ( n != usedNodes.end()) { - getSimplices( nodesToSmooth[ i ]._node, - nodesToSmooth[ i ]._simplices, - ignoreShapes, NULL, - /*sortSimplices=*/ smoothType == _SmoothNode::ANGULAR ); + _Simplex::GetSimplices( nodesToSmooth[ i ]._node, + nodesToSmooth[ i ]._simplices, + ignoreShapes, NULL, + /*sortSimplices=*/ smoothType == _SmoothNode::ANGULAR ); usedNodes.erase( n ); } } @@ -5690,9 +6482,9 @@ bool _ViscousBuilder::shrink() n = usedNodes.find( /*tgtNode=*/ lEdges[i]->_nodes.back() ); if ( n != usedNodes.end()) { - getSimplices( lEdges[i]->_nodes.back(), - lEdges[i]->_simplices, - ignoreShapes ); + _Simplex::GetSimplices( lEdges[i]->_nodes.back(), + lEdges[i]->_simplices, + ignoreShapes ); usedNodes.erase( n ); } } @@ -6259,7 +7051,7 @@ gp_XY _SmoothNode::computeAngularPos(vector& uv, edgeSize.back() = edgeSize.front(); gp_XY newPos(0,0); - int nbEdges = 0; + //int nbEdges = 0; double sumSize = 0; for ( size_t i = 1; i < edgeDir.size(); ++i ) { @@ -6285,7 +7077,7 @@ gp_XY _SmoothNode::computeAngularPos(vector& uv, distToN = -distToN; newPos += ( p + bisec * distToN ) * ( edgeSize[i1] + edgeSize[i] ); - ++nbEdges; + //++nbEdges; sumSize += edgeSize[i1] + edgeSize[i]; } newPos /= /*nbEdges * */sumSize; -- 2.39.2