1 // Copyright (C) 2007-2012 CEA/DEN, EDF R&D, OPEN CASCADE
3 // This library is free software; you can redistribute it and/or
4 // modify it under the terms of the GNU Lesser General Public
5 // License as published by the Free Software Foundation; either
6 // version 2.1 of the License.
8 // This library is distributed in the hope that it will be useful,
9 // but WITHOUT ANY WARRANTY; without even the implied warranty of
10 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
11 // Lesser General Public License for more details.
13 // You should have received a copy of the GNU Lesser General Public
14 // License along with this library; if not, write to the Free Software
15 // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
17 // See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
20 // File : StdMeshers_ViscousLayers2D.cxx
21 // Created : 23 Jul 2012
22 // Author : Edward AGAPOV (eap)
24 #include "StdMeshers_ViscousLayers2D.hxx"
26 #include "SMDS_EdgePosition.hxx"
27 #include "SMDS_FaceOfNodes.hxx"
28 #include "SMDS_FacePosition.hxx"
29 #include "SMDS_MeshNode.hxx"
30 #include "SMDS_SetIterator.hxx"
31 #include "SMESHDS_Group.hxx"
32 #include "SMESHDS_Hypothesis.hxx"
33 #include "SMESH_Algo.hxx"
34 #include "SMESH_ComputeError.hxx"
35 #include "SMESH_ControlsDef.hxx"
36 #include "SMESH_Gen.hxx"
37 #include "SMESH_Group.hxx"
38 #include "SMESH_HypoFilter.hxx"
39 #include "SMESH_Mesh.hxx"
40 #include "SMESH_MesherHelper.hxx"
41 #include "SMESH_ProxyMesh.hxx"
42 #include "SMESH_Quadtree.hxx"
43 #include "SMESH_subMesh.hxx"
44 #include "SMESH_subMeshEventListener.hxx"
45 #include "StdMeshers_FaceSide.hxx"
47 #include "utilities.h"
49 #include <BRepAdaptor_Curve.hxx>
50 #include <BRepAdaptor_Curve2d.hxx>
51 #include <BRep_Tool.hxx>
52 #include <Bnd_B2d.hxx>
53 #include <Bnd_B3d.hxx>
55 #include <GCPnts_AbscissaPoint.hxx>
56 #include <Geom2dAdaptor_Curve.hxx>
57 #include <Geom2dInt_GInter.hxx>
58 #include <Geom2d_Circle.hxx>
59 #include <Geom2d_Line.hxx>
60 #include <Geom2d_TrimmedCurve.hxx>
61 #include <GeomAdaptor_Curve.hxx>
62 #include <Geom_Circle.hxx>
63 #include <Geom_Curve.hxx>
64 #include <Geom_Line.hxx>
65 #include <Geom_TrimmedCurve.hxx>
66 #include <IntRes2d_IntersectionPoint.hxx>
67 #include <Precision.hxx>
68 #include <Standard_ErrorHandler.hxx>
69 #include <TColStd_Array1OfReal.hxx>
71 #include <TopExp_Explorer.hxx>
72 #include <TopTools_IndexedMapOfShape.hxx>
73 #include <TopTools_MapOfShape.hxx>
75 #include <TopoDS_Edge.hxx>
76 #include <TopoDS_Face.hxx>
77 #include <TopoDS_Vertex.hxx>
93 //================================================================================
98 //--------------------------------------------------------------------------------
100 * \brief Proxy Mesh of FACE with viscous layers. It's needed only to
101 * redefine newSubmesh().
103 struct _ProxyMeshOfFace : public SMESH_ProxyMesh
105 //---------------------------------------------------
106 // Proxy sub-mesh of an EDGE. It contains nodes in _uvPtStructVec.
107 struct _EdgeSubMesh : public SMESH_ProxyMesh::SubMesh
109 _EdgeSubMesh(int index=0): SubMesh(index) {}
110 //virtual int NbElements() const { return _elements.size()+1; }
111 virtual int NbNodes() const { return Max( 0, _uvPtStructVec.size()-2 ); }
112 void SetUVPtStructVec(UVPtStructVec& vec) { _uvPtStructVec.swap( vec ); }
114 _ProxyMeshOfFace(const SMESH_Mesh& mesh): SMESH_ProxyMesh(mesh) {}
115 _EdgeSubMesh* GetEdgeSubMesh(int ID) { return (_EdgeSubMesh*) getProxySubMesh(ID); }
116 virtual SubMesh* newSubmesh(int index=0) const { return new _EdgeSubMesh(index); }
118 //--------------------------------------------------------------------------------
120 * \brief SMESH_subMeshEventListener used to store _ProxyMeshOfFace, computed
121 * by _ViscousBuilder2D, in a SMESH_subMesh of the FACE.
122 * This is to delete _ProxyMeshOfFace when StdMeshers_ViscousLayers2D
123 * hypothesis is modified
125 struct _ProxyMeshHolder : public SMESH_subMeshEventListener
127 _ProxyMeshHolder( const TopoDS_Face& face,
128 SMESH_ProxyMesh::Ptr& mesh)
129 : SMESH_subMeshEventListener( /*deletable=*/true, Name() )
131 SMESH_subMesh* faceSM = mesh->GetMesh()->GetSubMesh( face );
132 faceSM->SetEventListener( this, new _Data( mesh ), faceSM );
134 // Finds a proxy mesh of face
135 static SMESH_ProxyMesh::Ptr FindProxyMeshOfFace( const TopoDS_Shape& face,
138 SMESH_ProxyMesh::Ptr proxy;
139 SMESH_subMesh* faceSM = mesh.GetSubMesh( face );
140 if ( EventListenerData* ld = faceSM->GetEventListenerData( Name() ))
141 proxy = static_cast< _Data* >( ld )->_mesh;
145 void ProcessEvent(const int event,
147 SMESH_subMesh* subMesh,
148 EventListenerData* data,
149 const SMESH_Hypothesis* /*hyp*/)
151 if ( event == SMESH_subMesh::CLEAN && eventType == SMESH_subMesh::COMPUTE_EVENT)
152 ((_Data*) data)->_mesh.reset();
155 // holder of a proxy mesh
156 struct _Data : public SMESH_subMeshEventListenerData
158 SMESH_ProxyMesh::Ptr _mesh;
159 _Data( SMESH_ProxyMesh::Ptr& mesh )
160 :SMESH_subMeshEventListenerData( /*isDeletable=*/true), _mesh( mesh )
163 // Returns identifier string
164 static const char* Name() { return "VISCOUS_2D::_ProxyMeshHolder"; }
168 //--------------------------------------------------------------------------------
170 * \brief Segment connecting inner ends of two _LayerEdge's.
174 const gp_XY* _uv[2]; // poiter to _LayerEdge::_uvIn
175 int _indexInLine; // position in _PolyLine
178 _Segment(const gp_XY& p1, const gp_XY& p2):_indexInLine(-1) { _uv[0] = &p1; _uv[1] = &p2; }
179 const gp_XY& p1() const { return *_uv[0]; }
180 const gp_XY& p2() const { return *_uv[1]; }
182 //--------------------------------------------------------------------------------
184 * \brief Tree of _Segment's used for a faster search of _Segment's.
186 struct _SegmentTree : public SMESH_Quadtree
188 typedef boost::shared_ptr< _SegmentTree > Ptr;
190 _SegmentTree( const vector< _Segment >& segments );
191 void GetSegmentsNear( const _Segment& seg, vector< const _Segment* >& found );
192 void GetSegmentsNear( const gp_Ax2d& ray, vector< const _Segment* >& found );
195 _SegmentTree* newChild() const { return new _SegmentTree; }
196 void buildChildrenData();
197 Bnd_B2d* buildRootBox();
199 static int maxNbSegInLeaf() { return 5; }
202 const _Segment* _seg;
204 void Set( const _Segment& seg )
207 _iMin[0] = ( seg._uv[1]->X() < seg._uv[0]->X() );
208 _iMin[1] = ( seg._uv[1]->Y() < seg._uv[0]->Y() );
210 bool IsOut( const _Segment& seg ) const;
211 bool IsOut( const gp_Ax2d& ray ) const;
213 vector< _SegBox > _segments;
215 //--------------------------------------------------------------------------------
217 * \brief Edge normal to FACE boundary, connecting a point on EDGE (_uvOut)
218 * and a point of a layer internal boundary (_uvIn)
222 gp_XY _uvOut; // UV on the FACE boundary
223 gp_XY _uvIn; // UV inside the FACE
224 double _length2D; // distance between _uvOut and _uvIn
226 bool _isBlocked;// is more inflation possible or not
228 gp_XY _normal2D; // to pcurve
229 double _len2dTo3dRatio; // to pass 2D <--> 3D
230 gp_Ax2d _ray; // a ray starting at _uvOut
232 vector<gp_XY> _uvRefined; // divisions by layers
234 bool SetNewLength( const double length );
236 //--------------------------------------------------------------------------------
238 * \brief Poly line composed of _Segment's of one EDGE.
239 * It's used to detect intersection of inflated layers by intersecting
244 StdMeshers_FaceSide* _wire;
245 int _edgeInd; // index of my EDGE in _wire
246 bool _advancable; // true if there is a viscous layer on my EDGE
247 bool _isStraight2D;// pcurve type
248 _PolyLine* _leftLine; // lines of neighbour EDGE's
249 _PolyLine* _rightLine;
250 int _firstPntInd; // index in vector<UVPtStruct> of _wire
253 vector< _LayerEdge > _lEdges; /* _lEdges[0] is usually is not treated
254 as it is equal to the last one of the _leftLine */
255 vector< _Segment > _segments; // segments connecting _uvIn's of _lEdges
256 _SegmentTree::Ptr _segTree;
258 vector< _PolyLine* > _reachableLines; // lines able to interfere with my layer
260 vector< const SMDS_MeshNode* > _leftNodes; // nodes built from a left VERTEX
261 vector< const SMDS_MeshNode* > _rightNodes; // nodes built from a right VERTEX
263 typedef vector< _Segment >::iterator TSegIterator;
264 typedef vector< _LayerEdge >::iterator TEdgeIterator;
266 TIDSortedElemSet _newFaces; // faces generated from this line
268 bool IsCommonEdgeShared( const _PolyLine& other );
269 size_t FirstLEdge() const
271 return ( _leftLine->_advancable && _lEdges.size() > 2 ) ? 1 : 0;
273 bool IsAdjacent( const _Segment& seg, const _LayerEdge* LE=0 ) const
275 if ( LE && seg._indexInLine < _lEdges.size() &&
276 ( seg._uv[0] == & LE->_uvIn ||
277 seg._uv[1] == & LE->_uvIn ))
279 return ( & seg == &_leftLine->_segments.back() ||
280 & seg == &_rightLine->_segments[0] );
283 //--------------------------------------------------------------------------------
285 * \brief Intersector of _Segment's
287 struct _SegmentIntersection
289 gp_XY _vec1, _vec2; // Vec( _seg.p1(), _seg.p2() )
290 gp_XY _vec21; // Vec( _seg2.p1(), _seg1.p1() )
291 double _D; // _vec1.Crossed( _vec2 )
292 double _param1, _param2; // intersection param on _seg1 and _seg2
294 bool Compute(const _Segment& seg1, const _Segment& seg2, bool seg2IsRay = false )
296 const double eps = 1e-10;
297 _vec1 = seg1.p2() - seg1.p1();
298 _vec2 = seg2.p2() - seg2.p1();
299 _vec21 = seg1.p1() - seg2.p1();
300 _D = _vec1.Crossed(_vec2);
301 if ( fabs(_D) < std::numeric_limits<double>::min())
303 _param1 = _vec2.Crossed(_vec21) / _D;
304 if (_param1 < -eps || _param1 > 1 + eps )
306 _param2 = _vec1.Crossed(_vec21) / _D;
307 if (_param2 < -eps || ( !seg2IsRay && _param2 > 1 + eps ))
311 bool Compute( const _Segment& seg1, const gp_Ax2d& ray )
313 gp_XY segEnd = ray.Location().XY() + ray.Direction().XY();
314 _Segment seg2( ray.Location().XY(), segEnd );
315 return Compute( seg1, seg2, true );
317 //gp_XY GetPoint() { return _seg1.p1() + _param1 * _vec1; }
319 //--------------------------------------------------------------------------------
321 typedef map< const SMDS_MeshNode*, _LayerEdge*, TIDCompare > TNode2Edge;
323 //--------------------------------------------------------------------------------
325 * \brief Builder of viscous layers
327 class _ViscousBuilder2D
330 _ViscousBuilder2D(SMESH_Mesh& theMesh,
331 const TopoDS_Face& theFace,
332 const StdMeshers_ViscousLayers2D* theHyp);
333 SMESH_ComputeErrorPtr GetError() const { return _error; }
335 SMESH_ProxyMesh::Ptr Compute();
339 bool findEdgesWithLayers();
340 bool makePolyLines();
342 bool fixCollisions();
346 bool toShrinkForAdjacent( const TopoDS_Face& adjFace,
347 const TopoDS_Edge& E,
348 const TopoDS_Vertex& V);
349 void setLenRatio( _LayerEdge& LE, const gp_Pnt& pOut );
350 void setLayerEdgeData( _LayerEdge& lEdge,
352 Handle(Geom2d_Curve)& pcurve,
354 void adjustCommonEdge( _PolyLine& LL, _PolyLine& LR );
355 void calcLayersHeight(const double totalThick,
356 vector<double>& heights);
357 bool removeMeshFaces(const TopoDS_Shape& face);
359 bool error( const string& text );
360 SMESHDS_Mesh* getMeshDS() { return _mesh->GetMeshDS(); }
361 _ProxyMeshOfFace* getProxyMesh();
364 //void makeGroupOfLE();
371 const StdMeshers_ViscousLayers2D* _hyp;
374 SMESH_ProxyMesh::Ptr _proxyMesh;
375 SMESH_ComputeErrorPtr _error;
378 Handle(Geom_Surface) _surface;
379 SMESH_MesherHelper _helper;
380 TSideVector _faceSideVec; // wires (StdMeshers_FaceSide) of _face
381 vector<_PolyLine> _polyLineVec; // fronts to advance
383 double _fPowN; // to compute thickness of layers
384 double _thickness; // required or possible layers thickness
386 // sub-shapes of _face
387 set<TGeomID> _ignoreShapeIds; // ids of EDGEs w/o layers
388 set<TGeomID> _noShrinkVert; // ids of VERTEXes that are extremities
389 // of EDGEs along which _LayerEdge can't be inflated because no viscous layers
390 // defined on neighbour FACEs sharing an EDGE. Nonetheless _LayerEdge's
391 // are inflated along such EDGEs but then such _LayerEdge's are turned into
392 // a node on VERTEX, i.e. all nodes on a _LayerEdge are melded into one node.
396 //================================================================================
398 * \brief Returns StdMeshers_ViscousLayers2D for the FACE
400 const StdMeshers_ViscousLayers2D* findHyp(SMESH_Mesh& theMesh,
401 const TopoDS_Face& theFace)
403 SMESH_HypoFilter hypFilter
404 ( SMESH_HypoFilter::HasName( StdMeshers_ViscousLayers2D::GetHypType() ));
405 const SMESH_Hypothesis * hyp =
406 theMesh.GetHypothesis( theFace, hypFilter, /*ancestors=*/true );
407 return dynamic_cast< const StdMeshers_ViscousLayers2D* > ( hyp );
410 } // namespace VISCOUS_2D
412 //================================================================================
413 // StdMeshers_ViscousLayers hypothesis
415 StdMeshers_ViscousLayers2D::StdMeshers_ViscousLayers2D(int hypId, int studyId, SMESH_Gen* gen)
416 :StdMeshers_ViscousLayers(hypId, studyId, gen)
418 _name = StdMeshers_ViscousLayers2D::GetHypType();
419 _param_algo_dim = -2; // auxiliary hyp used by 2D algos
421 // --------------------------------------------------------------------------------
422 bool StdMeshers_ViscousLayers2D::SetParametersByMesh(const SMESH_Mesh* theMesh,
423 const TopoDS_Shape& theShape)
428 // --------------------------------------------------------------------------------
430 StdMeshers_ViscousLayers2D::Compute(SMESH_Mesh& theMesh,
431 const TopoDS_Face& theFace)
433 SMESH_ProxyMesh::Ptr pm;
435 const StdMeshers_ViscousLayers2D* vlHyp = VISCOUS_2D::findHyp( theMesh, theFace );
438 VISCOUS_2D::_ViscousBuilder2D builder( theMesh, theFace, vlHyp );
439 pm = builder.Compute();
440 SMESH_ComputeErrorPtr error = builder.GetError();
441 if ( error && !error->IsOK() )
442 theMesh.GetSubMesh( theFace )->GetComputeError() = error;
444 pm.reset( new SMESH_ProxyMesh( theMesh ));
445 if ( getenv("ONLY_VL2D"))
450 pm.reset( new SMESH_ProxyMesh( theMesh ));
454 // --------------------------------------------------------------------------------
455 void StdMeshers_ViscousLayers2D::RestoreListeners() const
457 StudyContextStruct* sc = _gen->GetStudyContext( _studyId );
458 std::map < int, SMESH_Mesh * >::iterator i_smesh = sc->mapMesh.begin();
459 for ( ; i_smesh != sc->mapMesh.end(); ++i_smesh )
461 SMESH_Mesh* smesh = i_smesh->second;
463 !smesh->HasShapeToMesh() ||
464 !smesh->GetMeshDS() ||
465 !smesh->GetMeshDS()->IsUsedHypothesis( this ))
468 // set event listeners to EDGE's of FACE where this hyp is used
469 TopoDS_Shape shape = i_smesh->second->GetShapeToMesh();
470 for ( TopExp_Explorer face( shape, TopAbs_FACE); face.More(); face.Next() )
471 if ( SMESH_Algo* algo = _gen->GetAlgo( *smesh, face.Current() ))
473 const std::list <const SMESHDS_Hypothesis *> & usedHyps =
474 algo->GetUsedHypothesis( *smesh, face.Current(), /*ignoreAuxiliary=*/false );
475 if ( std::find( usedHyps.begin(), usedHyps.end(), this ) != usedHyps.end() )
476 for ( TopExp_Explorer edge( face.Current(), TopAbs_EDGE); edge.More(); edge.Next() )
477 VISCOUS_3D::ToClearSubWithMain( smesh->GetSubMesh( edge.Current() ), face.Current() );
481 // END StdMeshers_ViscousLayers2D hypothesis
482 //================================================================================
484 using namespace VISCOUS_2D;
486 //================================================================================
488 * \brief Constructor of _ViscousBuilder2D
490 //================================================================================
492 _ViscousBuilder2D::_ViscousBuilder2D(SMESH_Mesh& theMesh,
493 const TopoDS_Face& theFace,
494 const StdMeshers_ViscousLayers2D* theHyp):
495 _mesh( &theMesh ), _face( theFace ), _hyp( theHyp ), _helper( theMesh )
497 _helper.SetSubShape( _face );
498 _helper.SetElementsOnShape(true);
500 _surface = BRep_Tool::Surface( theFace );
503 _fPowN = pow( _hyp->GetStretchFactor(), _hyp->GetNumberLayers() );
506 //================================================================================
508 * \brief Stores error description and returns false
510 //================================================================================
512 bool _ViscousBuilder2D::error(const string& text )
514 cout << "_ViscousBuilder2D::error " << text << endl;
515 _error->myName = COMPERR_ALGO_FAILED;
516 _error->myComment = string("Viscous layers builder 2D: ") + text;
517 if ( SMESH_subMesh* sm = _mesh->GetSubMesh( _face ) )
519 SMESH_ComputeErrorPtr& smError = sm->GetComputeError();
520 if ( smError && smError->myAlgo )
521 _error->myAlgo = smError->myAlgo;
524 //makeGroupOfLE(); // debug
529 //================================================================================
531 * \brief Does its job
533 //================================================================================
535 SMESH_ProxyMesh::Ptr _ViscousBuilder2D::Compute()
537 _error = SMESH_ComputeError::New(COMPERR_OK);
538 _faceSideVec = StdMeshers_FaceSide::GetFaceWires( _face, *_mesh, true, _error );
539 if ( !_error->IsOK() )
542 if ( !findEdgesWithLayers() ) // analysis of a shape
545 if ( ! makePolyLines() ) // creation of fronts
548 if ( ! inflate() ) // advance fronts
551 // remove elements and nodes from _face
552 removeMeshFaces( _face );
554 if ( !shrink() ) // shrink segments on edges w/o layers
557 if ( ! refine() ) // make faces
565 //================================================================================
567 * \brief Finds EDGE's to make viscous layers on.
569 //================================================================================
571 bool _ViscousBuilder2D::findEdgesWithLayers()
573 // collect all EDGEs to ignore defined by hyp
574 int nbMyEdgesIgnored = 0;
575 vector<TGeomID> ids = _hyp->GetBndShapesToIgnore();
576 for ( size_t i = 0; i < ids.size(); ++i )
578 const TopoDS_Shape& s = getMeshDS()->IndexToShape( ids[i] );
579 if ( !s.IsNull() && s.ShapeType() == TopAbs_EDGE ) {
580 _ignoreShapeIds.insert( ids[i] );
581 nbMyEdgesIgnored += ( _helper.IsSubShape( s, _face ));
585 // check all EDGEs of the _face
586 int totalNbEdges = 0;
587 for ( size_t iWire = 0; iWire < _faceSideVec.size(); ++iWire )
589 StdMeshers_FaceSidePtr wire = _faceSideVec[ iWire ];
590 totalNbEdges += wire->NbEdges();
591 for ( int iE = 0; iE < wire->NbEdges(); ++iE )
592 if ( _helper.NbAncestors( wire->Edge( iE ), *_mesh, TopAbs_FACE ) > 1 )
594 // ignore internal EDGEs (shared by several FACEs)
595 TGeomID edgeID = getMeshDS()->ShapeToIndex( wire->Edge( iE ));
596 _ignoreShapeIds.insert( edgeID );
598 // check if ends of an EDGE are to be added to _noShrinkVert
599 PShapeIteratorPtr faceIt = _helper.GetAncestors( wire->Edge( iE ), *_mesh, TopAbs_FACE );
600 while ( const TopoDS_Shape* neighbourFace = faceIt->next() )
602 if ( neighbourFace->IsSame( _face )) continue;
603 SMESH_Algo* algo = _mesh->GetGen()->GetAlgo( *_mesh, *neighbourFace );
604 if ( !algo ) continue;
606 const StdMeshers_ViscousLayers2D* viscHyp = 0;
607 const list <const SMESHDS_Hypothesis *> & allHyps =
608 algo->GetUsedHypothesis(*_mesh, *neighbourFace, /*noAuxiliary=*/false);
609 list< const SMESHDS_Hypothesis *>::const_iterator hyp = allHyps.begin();
610 for ( ; hyp != allHyps.end() && !viscHyp; ++hyp )
611 viscHyp = dynamic_cast<const StdMeshers_ViscousLayers2D*>( *hyp );
613 set<TGeomID> neighbourIgnoreEdges;
615 vector<TGeomID> ids = _hyp->GetBndShapesToIgnore();
616 neighbourIgnoreEdges.insert( ids.begin(), ids.end() );
618 for ( int iV = 0; iV < 2; ++iV )
620 TopoDS_Vertex vertex = iV ? wire->LastVertex(iE) : wire->FirstVertex(iE);
622 _noShrinkVert.insert( getMeshDS()->ShapeToIndex( vertex ));
625 PShapeIteratorPtr edgeIt = _helper.GetAncestors( vertex, *_mesh, TopAbs_EDGE );
626 while ( const TopoDS_Shape* edge = edgeIt->next() )
627 if ( !edge->IsSame( wire->Edge( iE )) &&
628 neighbourIgnoreEdges.count( getMeshDS()->ShapeToIndex( *edge )))
629 _noShrinkVert.insert( getMeshDS()->ShapeToIndex( vertex ));
635 return ( nbMyEdgesIgnored < totalNbEdges );
638 //================================================================================
640 * \brief Create the inner front of the viscous layers and prepare data for infation
642 //================================================================================
644 bool _ViscousBuilder2D::makePolyLines()
646 // Create _PolyLines and _LayerEdge's
648 // count total nb of EDGEs to allocate _polyLineVec
650 for ( size_t iWire = 0; iWire < _faceSideVec.size(); ++iWire )
651 nbEdges += _faceSideVec[ iWire ]->NbEdges();
652 _polyLineVec.resize( nbEdges );
654 // Assign data to _PolyLine's
655 // ---------------------------
658 for ( size_t iWire = 0; iWire < _faceSideVec.size(); ++iWire )
660 StdMeshers_FaceSidePtr wire = _faceSideVec[ iWire ];
661 const vector<UVPtStruct>& points = wire->GetUVPtStruct();
662 if ( points.empty() && wire->NbPoints() > 0 )
663 return error("Invalid node parameters on some EDGE");
665 for ( int iE = 0; iE < wire->NbEdges(); ++iE )
667 _PolyLine& L = _polyLineVec[ iPoLine++ ];
668 L._wire = wire.get();
670 L._advancable = !_ignoreShapeIds.count( wire->EdgeID( iE ));
672 int iRight = iPoLine - (( iE+1 < wire->NbEdges() ) ? 0 : wire->NbEdges() );
673 L._rightLine = &_polyLineVec[ iRight ];
674 _polyLineVec[ iRight ]._leftLine = &L;
676 L._firstPntInd = iPnt;
677 double lastNormPar = wire->LastParameter( iE ) - 1e-10;
678 while ( points[ iPnt ].normParam < lastNormPar )
680 L._lastPntInd = iPnt;
681 L._lEdges.resize( Max( 3, L._lastPntInd - L._firstPntInd + 1 )); // 3 edges minimum
683 // TODO: add more _LayerEdge's to strongly curved EDGEs
684 // in order not to miss collisions
686 Handle(Geom2d_Curve) pcurve = L._wire->Curve2d( L._edgeInd );
687 const bool reverse = ( L._wire->Edge( iE ).Orientation() == TopAbs_REVERSED );
688 for ( int i = L._firstPntInd; i <= L._lastPntInd; ++i )
690 _LayerEdge& lEdge = L._lEdges[ i - L._firstPntInd ];
691 const double u = ( i == L._firstPntInd ? wire->FirstU(iE) : points[ i ].param );
692 setLayerEdgeData( lEdge, u, pcurve, reverse );
693 setLenRatio( lEdge, SMESH_TNodeXYZ( points[ i ].node ) );
695 if ( L._lastPntInd - L._firstPntInd + 1 < 3 ) // add 3d _LayerEdge in the middle
697 L._lEdges[2] = L._lEdges[1];
698 const double u = 0.5 * ( wire->FirstU(iE) + wire->LastU(iE) );
699 setLayerEdgeData( L._lEdges[1], u, pcurve, reverse );
700 gp_Pnt p = 0.5 * ( SMESH_TNodeXYZ( points[ L._firstPntInd ].node ) +
701 SMESH_TNodeXYZ( points[ L._lastPntInd ].node ));
702 setLenRatio( L._lEdges[1], p );
707 // Fill _PolyLine's with _segments
708 // --------------------------------
710 double maxLen2dTo3dRatio = 0;
711 for ( iPoLine = 0; iPoLine < _polyLineVec.size(); ++iPoLine )
713 _PolyLine& L = _polyLineVec[ iPoLine ];
714 L._segments.resize( L._lEdges.size() - 1 );
715 for ( size_t i = 1; i < L._lEdges.size(); ++i )
717 _Segment & S = L._segments[i-1];
718 S._uv[0] = & L._lEdges[i-1]._uvIn;
719 S._uv[1] = & L._lEdges[i ]._uvIn;
720 S._indexInLine = i-1;
721 if ( maxLen2dTo3dRatio < L._lEdges[i]._len2dTo3dRatio )
722 maxLen2dTo3dRatio = L._lEdges[i]._len2dTo3dRatio;
724 // // connect _PolyLine's with segments, the 1st _LayerEdge of every _PolyLine
725 // // becomes not connected to any segment
726 // if ( L._leftLine->_advancable )
727 // L._segments[0]._uv[0] = & L._leftLine->_lEdges.back()._uvIn;
729 L._segTree.reset( new _SegmentTree( L._segments ));
732 // Evaluate max possible _thickness if required layers thickness seems too high
733 // ----------------------------------------------------------------------------
735 _thickness = _hyp->GetTotalThickness();
736 _SegmentTree::box_type faceBndBox2D;
737 for ( iPoLine = 0; iPoLine < _polyLineVec.size(); ++iPoLine )
738 faceBndBox2D.Add( *_polyLineVec[ iPoLine]._segTree->getBox() );
739 double boxTol = 1e-3 * sqrt( faceBndBox2D.SquareExtent() );
741 if ( _thickness * maxLen2dTo3dRatio > sqrt( faceBndBox2D.SquareExtent() ) / 10 )
743 vector< const _Segment* > foundSegs;
744 double maxPossibleThick = 0;
745 _SegmentIntersection intersection;
746 for ( size_t iL1 = 0; iL1 < _polyLineVec.size(); ++iL1 )
748 _PolyLine& L1 = _polyLineVec[ iL1 ];
749 _SegmentTree::box_type boxL1 = * L1._segTree->getBox();
750 boxL1.Enlarge( boxTol );
751 for ( size_t iL2 = iL1+1; iL2 < _polyLineVec.size(); ++iL2 )
753 _PolyLine& L2 = _polyLineVec[ iL2 ];
754 _SegmentTree::box_type boxL2 = * L2._segTree->getBox();
755 boxL2.Enlarge( boxTol );
756 if ( boxL1.IsOut( boxL2 ))
758 for ( size_t iLE = 1; iLE < L1._lEdges.size(); ++iLE )
761 L2._segTree->GetSegmentsNear( L1._lEdges[iLE]._ray, foundSegs );
762 for ( size_t i = 0; i < foundSegs.size(); ++i )
763 if ( intersection.Compute( *foundSegs[i], L1._lEdges[iLE]._ray ))
765 double distToL2 = intersection._param2 / L1._lEdges[iLE]._len2dTo3dRatio;
766 double psblThick = distToL2 / ( 1 + L1._advancable + L2._advancable );
767 if ( maxPossibleThick < psblThick )
768 maxPossibleThick = psblThick;
773 _thickness = Min( _hyp->GetTotalThickness(), maxPossibleThick );
776 // Adjust _LayerEdge's at _PolyLine's extremities
777 // -----------------------------------------------
779 for ( iPoLine = 0; iPoLine < _polyLineVec.size(); ++iPoLine )
781 _PolyLine& LL = _polyLineVec[ iPoLine ];
782 _PolyLine& LR = *LL._rightLine;
783 adjustCommonEdge( LL, LR );
785 // recreate _segments if some _LayerEdge's have been removed by adjustCommonEdge()
786 for ( iPoLine = 0; iPoLine < _polyLineVec.size(); ++iPoLine )
788 _PolyLine& L = _polyLineVec[ iPoLine ];
789 // if ( L._segments.size() == L._lEdges.size() - 1 )
791 L._segments.resize( L._lEdges.size() - 1 );
792 for ( size_t i = 1; i < L._lEdges.size(); ++i )
794 _Segment & S = L._segments[i-1];
795 S._uv[0] = & L._lEdges[i-1]._uvIn;
796 S._uv[1] = & L._lEdges[i ]._uvIn;
797 S._indexInLine = i-1;
799 L._segTree.reset( new _SegmentTree( L._segments ));
801 // connect _PolyLine's with segments, the 1st _LayerEdge of every _PolyLine
802 // becomes not connected to any segment
803 for ( iPoLine = 0; iPoLine < _polyLineVec.size(); ++iPoLine )
805 _PolyLine& L = _polyLineVec[ iPoLine ];
806 if ( L._leftLine->_advancable )
807 L._segments[0]._uv[0] = & L._leftLine->_lEdges.back()._uvIn;
810 // Fill _reachableLines.
811 // ----------------------
813 // compute bnd boxes taking into account the layers total thickness
814 vector< _SegmentTree::box_type > lineBoxes( _polyLineVec.size() );
815 for ( iPoLine = 0; iPoLine < _polyLineVec.size(); ++iPoLine )
817 lineBoxes[ iPoLine ] = *_polyLineVec[ iPoLine ]._segTree->getBox();
818 if ( _polyLineVec[ iPoLine ]._advancable )
819 lineBoxes[ iPoLine ].Enlarge( maxLen2dTo3dRatio * _thickness * 2 );
822 for ( iPoLine = 0; iPoLine < _polyLineVec.size(); ++iPoLine )
824 _PolyLine& L1 = _polyLineVec[ iPoLine ];
825 for ( size_t iL2 = 0; iL2 < _polyLineVec.size(); ++iL2 )
827 _PolyLine& L2 = _polyLineVec[ iL2 ];
828 if ( iPoLine == iL2 || lineBoxes[ iPoLine ].IsOut( lineBoxes[ iL2 ]))
830 if ( !L1._advancable && ( L1._leftLine == &L2 || L1._rightLine == &L2 ))
832 // check reachability by _LayerEdge's
833 int iDelta = 1; //Max( 1, L1._lEdges.size() / 100 );
834 for ( size_t iLE = 1; iLE < L1._lEdges.size(); iLE += iDelta )
836 _LayerEdge& LE = L1._lEdges[iLE];
837 if ( !lineBoxes[ iL2 ].IsOut ( LE._uvOut,
838 LE._uvOut + LE._normal2D *_thickness * LE._len2dTo3dRatio ))
840 L1._reachableLines.push_back( & L2 );
845 // add self to _reachableLines
846 Geom2dAdaptor_Curve pcurve( L1._wire->Curve2d( L1._edgeInd ));
847 L1._isStraight2D = ( pcurve.GetType() == GeomAbs_Line );
848 if ( !L1._isStraight2D )
850 // TODO: check carefully
851 L1._reachableLines.push_back( & L1 );
858 //================================================================================
860 * \brief adjust common _LayerEdge of two adjacent _PolyLine's
861 * \param LL - left _PolyLine
862 * \param LR - right _PolyLine
864 //================================================================================
866 void _ViscousBuilder2D::adjustCommonEdge( _PolyLine& LL, _PolyLine& LR )
868 int nbAdvancableL = LL._advancable + LR._advancable;
869 if ( nbAdvancableL == 0 )
872 _LayerEdge& EL = LL._lEdges.back();
873 _LayerEdge& ER = LR._lEdges.front();
874 gp_XY normL = EL._normal2D;
875 gp_XY normR = ER._normal2D;
876 gp_XY tangL ( normL.Y(), -normL.X() );
878 // set common direction to a VERTEX _LayerEdge shared by two _PolyLine's
879 gp_XY normCommon = ( normL * int( LL._advancable ) +
880 normR * int( LR._advancable )).Normalized();
881 EL._normal2D = normCommon;
882 EL._ray.SetLocation ( EL._uvOut );
883 EL._ray.SetDirection( EL._normal2D );
884 if ( nbAdvancableL == 1 ) { // _normal2D is true normal (not average)
885 EL._isBlocked = true; // prevent intersecting with _Segments of _advancable line
888 // update _LayerEdge::_len2dTo3dRatio according to a new direction
889 const vector<UVPtStruct>& points = LL._wire->GetUVPtStruct();
890 setLenRatio( EL, SMESH_TNodeXYZ( points[ LL._lastPntInd ].node ));
894 const double dotNormTang = normR * tangL;
895 const bool largeAngle = Abs( dotNormTang ) > 0.2;
896 if ( largeAngle ) // not 180 degrees
898 // recompute _len2dTo3dRatio to take into account angle between EDGEs
899 gp_Vec2d oldNorm( LL._advancable ? normL : normR );
900 double angleFactor = 1. / Max( 0.3, Cos( oldNorm.Angle( normCommon )));
901 EL._len2dTo3dRatio *= angleFactor;
902 ER._len2dTo3dRatio = EL._len2dTo3dRatio;
904 gp_XY normAvg = ( normL + normR ).Normalized(); // average normal at VERTEX
906 if ( dotNormTang < 0. ) // ---------------------------- CONVEX ANGLE
908 // Remove _LayerEdge's intersecting the normAvg to avoid collisions
911 // find max length of the VERTEX based _LayerEdge whose direction is normAvg
912 double maxLen2D = _thickness * EL._len2dTo3dRatio;
913 const gp_XY& pCommOut = ER._uvOut;
914 gp_XY pCommIn = pCommOut + normAvg * maxLen2D;
915 _Segment segCommon( pCommOut, pCommIn );
916 _SegmentIntersection intersection;
917 vector< const _Segment* > foundSegs;
918 for ( size_t iL1 = 0; iL1 < _polyLineVec.size(); ++iL1 )
920 _PolyLine& L1 = _polyLineVec[ iL1 ];
921 const _SegmentTree::box_type* boxL1 = L1._segTree->getBox();
922 if ( boxL1->IsOut ( pCommOut, pCommIn ))
924 for ( size_t iLE = 1; iLE < L1._lEdges.size(); ++iLE )
927 L1._segTree->GetSegmentsNear( segCommon, foundSegs );
928 for ( size_t i = 0; i < foundSegs.size(); ++i )
929 if ( intersection.Compute( *foundSegs[i], segCommon ) &&
930 intersection._param2 > 1e-10 )
932 double len2D = intersection._param2 * maxLen2D / ( 2 + L1._advancable );
933 if ( len2D < maxLen2D ) {
935 pCommIn = pCommOut + normAvg * maxLen2D; // here length of segCommon changes
941 // remove _LayerEdge's intersecting segCommon
942 for ( int isR = 0; isR < 2; ++isR ) // loop on [ LL, LR ]
944 _PolyLine& L = isR ? LR : LL;
945 _PolyLine::TEdgeIterator eIt = isR ? L._lEdges.begin()+1 : L._lEdges.end()-2;
946 int dIt = isR ? +1 : -1;
947 if ( nbAdvancableL == 1 && L._advancable && normL * normR > -0.01 )
948 continue; // obtuse internal angle
949 // at least 3 _LayerEdge's should remain in a _PolyLine
950 if ( L._lEdges.size() < 4 ) continue;
952 _SegmentIntersection lastIntersection;
953 for ( ; iLE < L._lEdges.size(); ++iLE, eIt += dIt )
955 gp_XY uvIn = eIt->_uvOut + eIt->_normal2D * _thickness * eIt->_len2dTo3dRatio;
956 _Segment segOfEdge( eIt->_uvOut, uvIn );
957 if ( !intersection.Compute( segCommon, segOfEdge ))
959 lastIntersection._param1 = intersection._param1;
960 lastIntersection._param2 = intersection._param2;
962 if ( iLE >= L._lEdges.size () - 1 )
964 // all _LayerEdge's intersect the segCommon, limit inflation
965 // of remaining 2 _LayerEdge's
966 vector< _LayerEdge > newEdgeVec( Min( 3, L._lEdges.size() ));
967 newEdgeVec.front() = L._lEdges.front();
968 newEdgeVec.back() = L._lEdges.back();
969 if ( newEdgeVec.size() == 3 )
970 newEdgeVec[1] = L._lEdges[ L._lEdges.size() / 2 ];
971 L._lEdges.swap( newEdgeVec );
972 if ( !isR ) std::swap( lastIntersection._param1 , lastIntersection._param2 );
973 L._lEdges.front()._len2dTo3dRatio *= lastIntersection._param1; // ??
974 L._lEdges.back ()._len2dTo3dRatio *= lastIntersection._param2;
978 // eIt points to the _LayerEdge not intersecting with segCommon
980 LR._lEdges.erase( LR._lEdges.begin()+1, eIt );
982 LL._lEdges.erase( eIt, --LL._lEdges.end() );
983 // eIt = isR ? L._lEdges.begin()+1 : L._lEdges.end()-2;
984 // for ( size_t i = 1; i < iLE; ++i, eIt += dIt )
985 // eIt->_isBlocked = true;
989 else // ------------------------------------------ CONCAVE ANGLE
991 if ( nbAdvancableL == 1 )
993 // make that the _LayerEdge at VERTEX is not shared by LL and LR:
994 // different normals is a sign that they are not shared
995 _LayerEdge& notSharedEdge = LL._advancable ? LR._lEdges[0] : LL._lEdges.back();
996 _LayerEdge& sharedEdge = LR._advancable ? LR._lEdges[0] : LL._lEdges.back();
998 notSharedEdge._normal2D.SetCoord( 0.,0. );
999 sharedEdge._normal2D = normAvg;
1000 sharedEdge._isBlocked = false;
1001 notSharedEdge._isBlocked = true;
1007 //================================================================================
1009 * \brief initialize data of a _LayerEdge
1011 //================================================================================
1013 void _ViscousBuilder2D::setLayerEdgeData( _LayerEdge& lEdge,
1015 Handle(Geom2d_Curve)& pcurve,
1018 gp_Pnt2d uv; gp_Vec2d tangent;
1019 pcurve->D1( u, uv, tangent );
1020 tangent.Normalize();
1023 lEdge._uvOut = lEdge._uvIn = uv.XY();
1024 lEdge._normal2D.SetCoord( -tangent.Y(), tangent.X() );
1025 lEdge._ray.SetLocation( lEdge._uvOut );
1026 lEdge._ray.SetDirection( lEdge._normal2D );
1027 lEdge._isBlocked = false;
1028 lEdge._length2D = 0;
1031 //================================================================================
1033 * \brief Compute and set _LayerEdge::_len2dTo3dRatio
1035 //================================================================================
1037 void _ViscousBuilder2D::setLenRatio( _LayerEdge& LE, const gp_Pnt& pOut )
1039 const double probeLen2d = 1e-3;
1041 gp_Pnt2d p2d = LE._uvOut + LE._normal2D * probeLen2d;
1042 gp_Pnt p3d = _surface->Value( p2d.X(), p2d.Y() );
1043 double len3d = p3d.Distance( pOut );
1044 if ( len3d < std::numeric_limits<double>::min() )
1045 LE._len2dTo3dRatio = std::numeric_limits<double>::min();
1047 LE._len2dTo3dRatio = probeLen2d / len3d;
1050 //================================================================================
1052 * \brief Increase length of _LayerEdge's to reach the required thickness of layers
1054 //================================================================================
1056 bool _ViscousBuilder2D::inflate()
1058 // Limit size of inflation step by geometry size found by
1059 // itersecting _LayerEdge's with _Segment's
1060 double minSize = _thickness, maxSize = 0;
1061 vector< const _Segment* > foundSegs;
1062 _SegmentIntersection intersection;
1063 for ( size_t iL1 = 0; iL1 < _polyLineVec.size(); ++iL1 )
1065 _PolyLine& L1 = _polyLineVec[ iL1 ];
1066 for ( size_t iL2 = 0; iL2 < L1._reachableLines.size(); ++iL2 )
1068 _PolyLine& L2 = * L1._reachableLines[ iL2 ];
1069 for ( size_t iLE = 1; iLE < L1._lEdges.size(); ++iLE )
1072 L2._segTree->GetSegmentsNear( L1._lEdges[iLE]._ray, foundSegs );
1073 for ( size_t i = 0; i < foundSegs.size(); ++i )
1074 if ( ! L1.IsAdjacent( *foundSegs[i], & L1._lEdges[iLE] ) &&
1075 intersection.Compute( *foundSegs[i], L1._lEdges[iLE]._ray ))
1077 double distToL2 = intersection._param2 / L1._lEdges[iLE]._len2dTo3dRatio;
1078 double size = distToL2 / ( 1 + L1._advancable + L2._advancable );
1079 if ( size < minSize )
1081 if ( size > maxSize )
1087 if ( minSize > maxSize ) // no collisions possible
1088 maxSize = _thickness;
1090 cout << "-- minSize = " << minSize << ", maxSize = " << maxSize << endl;
1093 double curThick = 0, stepSize = minSize;
1095 if ( maxSize > _thickness )
1096 maxSize = _thickness;
1097 while ( curThick < maxSize )
1099 curThick += stepSize * 1.25;
1100 if ( curThick > _thickness )
1101 curThick = _thickness;
1103 // Elongate _LayerEdge's
1104 for ( size_t iL = 0; iL < _polyLineVec.size(); ++iL )
1106 _PolyLine& L = _polyLineVec[ iL ];
1107 if ( !L._advancable ) continue;
1108 bool lenChange = false;
1109 for ( size_t iLE = L.FirstLEdge(); iLE < L._lEdges.size(); ++iLE )
1110 lenChange |= L._lEdges[iLE].SetNewLength( curThick );
1111 // for ( int k=0; k<L._segments.size(); ++k)
1112 // cout << "( " << L._segments[k].p1().X() << ", " <<L._segments[k].p1().Y() << " ) "
1113 // << "( " << L._segments[k].p2().X() << ", " <<L._segments[k].p2().Y() << " ) "
1116 L._segTree.reset( new _SegmentTree( L._segments ));
1119 // Avoid intersection of _Segment's
1120 bool allBlocked = fixCollisions();
1123 break; // no more inflating possible
1125 stepSize = Max( stepSize , _thickness / 10. );
1129 // if (nbSteps == 0 )
1130 // return error("failed at the very first inflation step");
1133 // remove _LayerEdge's of one line intersecting with each other
1134 for ( size_t iL = 0; iL < _polyLineVec.size(); ++iL )
1136 _PolyLine& L = _polyLineVec[ iL ];
1137 if ( !L._advancable ) continue;
1139 // replace an inactive (1st) _LayerEdge with an active one of a neighbour _PolyLine
1140 if ( /*!L._leftLine->_advancable &&*/ L.IsCommonEdgeShared( *L._leftLine ) ) {
1141 L._lEdges[0] = L._leftLine->_lEdges.back();
1143 if ( !L._rightLine->_advancable && L.IsCommonEdgeShared( *L._rightLine ) ) {
1144 L._lEdges.back() = L._rightLine->_lEdges[0];
1147 _SegmentIntersection intersection;
1148 for ( int isR = 0; ( isR < 2 && L._lEdges.size() > 2 ); ++isR )
1150 int nbRemove = 0, deltaIt = isR ? -1 : +1;
1151 _PolyLine::TEdgeIterator eIt = isR ? L._lEdges.end()-1 : L._lEdges.begin();
1152 if ( eIt->_length2D == 0 ) continue;
1153 _Segment seg1( eIt->_uvOut, eIt->_uvIn );
1154 for ( eIt += deltaIt; nbRemove < L._lEdges.size()-1; eIt += deltaIt )
1156 _Segment seg2( eIt->_uvOut, eIt->_uvIn );
1157 if ( !intersection.Compute( seg1, seg2 ))
1161 if ( nbRemove > 0 ) {
1162 if ( nbRemove == L._lEdges.size()-1 ) // 1st and last _LayerEdge's intersect
1165 _LayerEdge& L0 = L._lEdges.front();
1166 _LayerEdge& L1 = L._lEdges.back();
1167 L0._length2D *= intersection._param1 * 0.5;
1168 L1._length2D *= intersection._param2 * 0.5;
1169 L0._uvIn = L0._uvOut + L0._normal2D * L0._length2D;
1170 L1._uvIn = L1._uvOut + L1._normal2D * L1._length2D;
1171 if ( L.IsCommonEdgeShared( *L._leftLine ))
1172 L._leftLine->_lEdges.back() = L0;
1175 L._lEdges.erase( L._lEdges.end()-nbRemove-1,
1176 L._lEdges.end()-nbRemove );
1178 L._lEdges.erase( L._lEdges.begin()+1,
1179 L._lEdges.begin()+1+nbRemove );
1186 //================================================================================
1188 * \brief Remove intersection of _PolyLine's
1190 //================================================================================
1192 bool _ViscousBuilder2D::fixCollisions()
1194 // look for intersections of _Segment's by intersecting _LayerEdge's with
1196 //double maxStep = 0, minStep = 1e+100;
1197 vector< const _Segment* > foundSegs;
1198 _SegmentIntersection intersection;
1200 list< pair< _LayerEdge*, double > > edgeLenLimitList;
1201 list< _LayerEdge* > blockedEdgesList;
1203 for ( size_t iL1 = 0; iL1 < _polyLineVec.size(); ++iL1 )
1205 _PolyLine& L1 = _polyLineVec[ iL1 ];
1206 //if ( !L1._advancable ) continue;
1207 for ( size_t iL2 = 0; iL2 < L1._reachableLines.size(); ++iL2 )
1209 _PolyLine& L2 = * L1._reachableLines[ iL2 ];
1210 for ( size_t iLE = L1.FirstLEdge(); iLE < L1._lEdges.size(); ++iLE )
1212 _LayerEdge& LE1 = L1._lEdges[iLE];
1213 if ( LE1._isBlocked ) continue;
1215 L2._segTree->GetSegmentsNear( LE1._ray, foundSegs );
1216 for ( size_t i = 0; i < foundSegs.size(); ++i )
1218 if ( ! L1.IsAdjacent( *foundSegs[i], &LE1 ) &&
1219 intersection.Compute( *foundSegs[i], LE1._ray ))
1221 const double dist2DToL2 = intersection._param2;
1222 double newLen2D = dist2DToL2 / 2;
1223 if ( newLen2D < 1.1 * LE1._length2D ) // collision!
1225 if ( newLen2D < LE1._length2D )
1227 blockedEdgesList.push_back( &LE1 );
1228 if ( L1._advancable )
1230 edgeLenLimitList.push_back( make_pair( &LE1, newLen2D ));
1231 blockedEdgesList.push_back( &L2._lEdges[ foundSegs[i]->_indexInLine ]);
1232 blockedEdgesList.push_back( &L2._lEdges[ foundSegs[i]->_indexInLine + 1 ]);
1234 else // here dist2DToL2 < 0 and LE1._length2D == 0
1236 _LayerEdge LE2[2] = { L2._lEdges[ foundSegs[i]->_indexInLine ],
1237 L2._lEdges[ foundSegs[i]->_indexInLine + 1 ] };
1238 _Segment outSeg2( LE2[0]._uvOut, LE2[1]._uvOut );
1239 intersection.Compute( outSeg2, LE1._ray );
1240 newLen2D = intersection._param2 / 2;
1242 edgeLenLimitList.push_back( make_pair( &LE2[0], newLen2D ));
1243 edgeLenLimitList.push_back( make_pair( &LE2[1], newLen2D ));
1253 // set limited length to _LayerEdge's
1254 list< pair< _LayerEdge*, double > >::iterator edge2Len = edgeLenLimitList.begin();
1255 for ( ; edge2Len != edgeLenLimitList.end(); ++edge2Len )
1257 _LayerEdge* LE = edge2Len->first;
1258 LE->SetNewLength( edge2Len->second / LE->_len2dTo3dRatio );
1259 LE->_isBlocked = true;
1262 // block inflation of _LayerEdge's
1263 list< _LayerEdge* >::iterator edge = blockedEdgesList.begin();
1264 for ( ; edge != blockedEdgesList.end(); ++edge )
1265 (*edge)->_isBlocked = true;
1267 // find a not blocked _LayerEdge
1268 for ( size_t iL = 0; iL < _polyLineVec.size(); ++iL )
1270 _PolyLine& L = _polyLineVec[ iL ];
1271 if ( !L._advancable ) continue;
1272 for ( size_t iLE = L.FirstLEdge(); iLE < L._lEdges.size(); ++iLE )
1273 if ( !L._lEdges[ iLE ]._isBlocked )
1280 //================================================================================
1282 * \brief Create new edges and shrink edges existing on a non-advancable _PolyLine
1283 * adjacent to an advancable one.
1285 //================================================================================
1287 bool _ViscousBuilder2D::shrink()
1289 gp_Pnt2d uv; //gp_Vec2d tangent;
1290 _SegmentIntersection intersection;
1293 for ( size_t iL1 = 0; iL1 < _polyLineVec.size(); ++iL1 )
1295 _PolyLine& L = _polyLineVec[ iL1 ]; // line with no layers
1296 if ( L._advancable )
1298 const int nbAdvancable = ( L._rightLine->_advancable + L._leftLine->_advancable );
1299 if ( nbAdvancable == 0 )
1302 const TopoDS_Edge& E = L._wire->Edge ( L._edgeInd );
1303 const int edgeID = L._wire->EdgeID ( L._edgeInd );
1304 const double edgeLen = L._wire->EdgeLength( L._edgeInd );
1305 Handle(Geom2d_Curve) pcurve = L._wire->Curve2d ( L._edgeInd );
1306 const bool edgeReversed = ( E.Orientation() == TopAbs_REVERSED );
1308 SMESH_MesherHelper helper( *_mesh ); // to create nodes and edges on E
1309 helper.SetSubShape( E );
1310 helper.SetElementsOnShape( true );
1312 // Check a FACE adjacent to _face by E
1313 bool existingNodesFound = false;
1314 TopoDS_Face adjFace;
1315 PShapeIteratorPtr faceIt = _helper.GetAncestors( E, *_mesh, TopAbs_FACE );
1316 while ( const TopoDS_Shape* f = faceIt->next() )
1317 if ( !_face.IsSame( *f ))
1319 adjFace = TopoDS::Face( *f );
1320 SMESH_ProxyMesh::Ptr pm = _ProxyMeshHolder::FindProxyMeshOfFace( adjFace, *_mesh );
1321 if ( !pm || pm->NbProxySubMeshes() == 0 )
1323 // There are no viscous layers on an adjacent FACE, clear it's 2D mesh
1324 removeMeshFaces( adjFace );
1328 // There are viscous layers on the adjacent FACE; shrink must be already done;
1332 const vector<UVPtStruct>& points = L._wire->GetUVPtStruct();
1333 int iPFrom = L._firstPntInd, iPTo = L._lastPntInd;
1334 if ( L._leftLine->_advancable )
1336 vector<gp_XY>& uvVec = L._lEdges.front()._uvRefined;
1337 for ( int i = 0; i < _hyp->GetNumberLayers(); ++i ) {
1338 const UVPtStruct& uvPt = points[ iPFrom + i + 1 ];
1339 L._leftNodes.push_back( uvPt.node );
1340 uvVec.push_back ( pcurve->Value( uvPt.param ).XY() );
1343 if ( L._rightLine->_advancable )
1345 vector<gp_XY>& uvVec = L._lEdges.back()._uvRefined;
1346 for ( int i = 0; i < _hyp->GetNumberLayers(); ++i ) {
1347 const UVPtStruct& uvPt = points[ iPTo - i - 1 ];
1348 L._rightNodes.push_back( uvPt.node );
1349 uvVec.push_back ( pcurve->Value( uvPt.param ).XY() );
1352 // make proxy sub-mesh data of present nodes
1354 if ( L._leftLine->_advancable ) iPFrom += _hyp->GetNumberLayers();
1355 if ( L._rightLine->_advancable ) iPTo -= _hyp->GetNumberLayers();
1356 UVPtStructVec nodeDataVec( & points[ iPFrom ], & points[ iPTo + 1 ]);
1358 double normSize = nodeDataVec.back().normParam - nodeDataVec.front().normParam;
1359 for ( int iP = nodeDataVec.size()-1; iP >= 0 ; --iP )
1360 nodeDataVec[iP].normParam =
1361 ( nodeDataVec[iP].normParam - nodeDataVec[0].normParam ) / normSize;
1363 const SMDS_MeshNode* n = nodeDataVec.front().node;
1364 if ( n->GetPosition()->GetTypeOfPosition() == SMDS_TOP_VERTEX )
1365 nodeDataVec.front().param = L._wire->FirstU( L._edgeInd );
1366 n = nodeDataVec.back().node;
1367 if ( n->GetPosition()->GetTypeOfPosition() == SMDS_TOP_VERTEX )
1368 nodeDataVec.back().param = L._wire->LastU( L._edgeInd );
1370 _ProxyMeshOfFace::_EdgeSubMesh* myEdgeSM = getProxyMesh()->GetEdgeSubMesh( edgeID );
1371 myEdgeSM->SetUVPtStructVec( nodeDataVec );
1373 existingNodesFound = true;
1375 } // loop on FACEs sharing E
1377 if ( existingNodesFound )
1378 continue; // nothing more to do in this case
1380 double u1 = L._wire->FirstU( L._edgeInd ), uf = u1;
1381 double u2 = L._wire->LastU ( L._edgeInd ), ul = u2;
1383 // a ratio to pass 2D <--> 1D
1384 const double len1D = 1e-3;
1385 const double len2D = pcurve->Value(uf).Distance( pcurve->Value(uf+len1D));
1386 double len1dTo2dRatio = len1D / len2D;
1388 // create a vector of proxy nodes
1389 const vector<UVPtStruct>& points = L._wire->GetUVPtStruct();
1390 UVPtStructVec nodeDataVec( & points[ L._firstPntInd ],
1391 & points[ L._lastPntInd + 1 ]);
1392 nodeDataVec.front().param = u1; // U on vertex is correct on only one of shared edges
1393 nodeDataVec.back ().param = u2;
1394 nodeDataVec.front().normParam = 0;
1395 nodeDataVec.back ().normParam = 1;
1397 // Get length of existing segments (from an edge start to a node) and their nodes
1398 vector< double > segLengths( nodeDataVec.size() - 1 );
1399 BRepAdaptor_Curve curve( E );
1400 for ( size_t iP = 1; iP < nodeDataVec.size(); ++iP )
1402 const double len = GCPnts_AbscissaPoint::Length( curve, uf, nodeDataVec[iP].param );
1403 segLengths[ iP-1 ] = len;
1406 // Move first and last parameters on EDGE (U of n1) according to layers' thickness
1407 // and create nodes of layers on EDGE ( -x-x-x )
1411 // x-----x-----x-----x-----
1416 // x-x-x-x-----x-----x----
1419 int isRShrinkedForAdjacent;
1420 UVPtStructVec nodeDataForAdjacent;
1421 for ( int isR = 0; isR < 2; ++isR )
1423 _PolyLine* L2 = isR ? L._rightLine : L._leftLine; // line with layers
1424 if ( !L2->_advancable &&
1425 !toShrinkForAdjacent( adjFace, E, L._wire->FirstVertex( L._edgeInd + isR )))
1428 double & u = isR ? u2 : u1; // param to move
1429 double u0 = isR ? ul : uf; // init value of the param to move
1430 int iPEnd = isR ? nodeDataVec.size() - 1 : 0;
1432 _LayerEdge& nearLE = isR ? L._lEdges.back() : L._lEdges.front();
1433 _LayerEdge& farLE = isR ? L._lEdges.front() : L._lEdges.back();
1435 // try to find length of advancement along L by intersecting L with
1436 // an adjacent _Segment of L2
1438 double& length2D = nearLE._length2D;
1439 double length1D = 0;
1440 sign = ( isR ^ edgeReversed ) ? -1. : 1.;
1442 bool isConvex = false;
1443 if ( L2->_advancable )
1445 int iFSeg2 = isR ? 0 : L2->_segments.size() - 1;
1446 int iLSeg2 = isR ? 1 : L2->_segments.size() - 2;
1447 gp_XY uvLSeg2In = L2->_lEdges[ iLSeg2 ]._uvIn;
1448 gp_XY uvLSeg2Out = L2->_lEdges[ iLSeg2 ]._uvOut;
1449 gp_XY uvFSeg2Out = L2->_lEdges[ iFSeg2 ]._uvOut;
1450 Handle(Geom2d_Line) seg2Line = new Geom2d_Line( uvLSeg2In, uvFSeg2Out - uvLSeg2Out );
1452 Geom2dAdaptor_Curve edgeCurve( pcurve, Min( uf, ul ), Max( uf, ul ));
1453 Geom2dAdaptor_Curve seg2Curve( seg2Line );
1454 Geom2dInt_GInter curveInt( edgeCurve, seg2Curve, 1e-7, 1e-7 );
1455 isConvex = ( curveInt.IsDone() && !curveInt.IsEmpty() );
1458 length1D = Abs( u - curveInt.Point( 1 ).ParamOnFirst() );
1459 double maxDist2d = 2 * L2->_lEdges[ iLSeg2 ]._length2D;
1460 isConvex = ( length1D < maxDist2d * len1dTo2dRatio );
1467 if ( !isConvex ) { /* concave VERTEX */ /* o-----o---
1473 length2D = L2->_lEdges[ iFSeg2 ]._length2D;
1474 //if ( L2->_advancable ) continue;
1477 else // L2 is advancable but in the face adjacent by L
1479 length2D = farLE._length2D;
1480 if ( length2D == 0 ) {
1481 _LayerEdge& neighborLE =
1482 ( isR ? L._leftLine->_lEdges.back() : L._rightLine->_lEdges.front() );
1483 length2D = neighborLE._length2D;
1484 if ( length2D == 0 )
1485 length2D = _thickness * nearLE._len2dTo3dRatio;
1489 // move u to the internal boundary of layers
1491 // x-x-x-x-----x-----x----
1492 double maxLen3D = Min( _thickness, edgeLen / ( 1 + nbAdvancable ));
1493 double maxLen2D = maxLen3D * nearLE._len2dTo3dRatio;
1494 if ( !length2D ) length2D = length1D / len1dTo2dRatio;
1495 if ( Abs( length2D ) > maxLen2D )
1496 length2D = maxLen2D;
1497 nearLE._uvIn = nearLE._uvOut + nearLE._normal2D * length2D;
1499 u += length2D * len1dTo2dRatio * sign;
1500 nodeDataVec[ iPEnd ].param = u;
1502 gp_Pnt2d newUV = pcurve->Value( u );
1503 nodeDataVec[ iPEnd ].u = newUV.X();
1504 nodeDataVec[ iPEnd ].v = newUV.Y();
1506 // compute params of layers on L
1507 vector<double> heights;
1508 calcLayersHeight( u - u0, heights );
1510 vector< double > params( heights.size() );
1511 for ( size_t i = 0; i < params.size(); ++i )
1512 params[ i ] = u0 + heights[ i ];
1514 // create nodes of layers and edges between them
1516 vector< const SMDS_MeshNode* >& layersNode = isR ? L._rightNodes : L._leftNodes;
1517 vector<gp_XY>& nodeUV = ( isR ? L._lEdges.back() : L._lEdges[0] )._uvRefined;
1518 nodeUV.resize ( _hyp->GetNumberLayers() );
1519 layersNode.resize( _hyp->GetNumberLayers() );
1520 const SMDS_MeshNode* vertexNode = nodeDataVec[ iPEnd ].node;
1521 const SMDS_MeshNode * prevNode = vertexNode;
1522 for ( size_t i = 0; i < params.size(); ++i )
1524 gp_Pnt p = curve.Value( params[i] );
1525 layersNode[ i ] = helper.AddNode( p.X(), p.Y(), p.Z(), /*id=*/0, params[i] );
1526 nodeUV [ i ] = pcurve->Value( params[i] ).XY();
1527 helper.AddEdge( prevNode, layersNode[ i ] );
1528 prevNode = layersNode[ i ];
1531 // store data of layer nodes made for adjacent FACE
1532 if ( !L2->_advancable )
1534 isRShrinkedForAdjacent = isR;
1535 nodeDataForAdjacent.resize( _hyp->GetNumberLayers() );
1537 size_t iFrw = 0, iRev = nodeDataForAdjacent.size()-1, *i = isR ? &iRev : &iFrw;
1538 nodeDataForAdjacent[ *i ] = points[ isR ? L._lastPntInd : L._firstPntInd ];
1539 nodeDataForAdjacent[ *i ].param = u0;
1540 nodeDataForAdjacent[ *i ].normParam = isR;
1541 for ( ++iFrw, --iRev; iFrw < layersNode.size(); ++iFrw, --iRev )
1543 nodeDataForAdjacent[ *i ].node = layersNode[ iFrw - 1 ];
1544 nodeDataForAdjacent[ *i ].u = nodeUV [ iFrw - 1 ].X();
1545 nodeDataForAdjacent[ *i ].v = nodeUV [ iFrw - 1 ].Y();
1546 nodeDataForAdjacent[ *i ].param = params [ iFrw - 1 ];
1549 // replace a node on vertex by a node of last (most internal) layer
1550 // in a segment on E
1551 SMDS_ElemIteratorPtr segIt = vertexNode->GetInverseElementIterator( SMDSAbs_Edge );
1552 const SMDS_MeshNode* segNodes[3];
1553 while ( segIt->more() )
1555 const SMDS_MeshElement* segment = segIt->next();
1556 if ( segment->getshapeId() != edgeID ) continue;
1558 const int nbNodes = segment->NbNodes();
1559 for ( int i = 0; i < nbNodes; ++i )
1561 const SMDS_MeshNode* n = segment->GetNode( i );
1562 segNodes[ i ] = ( n == vertexNode ? layersNode.back() : n );
1564 getMeshDS()->ChangeElementNodes( segment, segNodes, nbNodes );
1567 nodeDataVec[ iPEnd ].node = layersNode.back();
1569 } // loop on the extremities of L
1571 // Shrink edges to fit in between the layers at EDGE ends
1573 double newLength = GCPnts_AbscissaPoint::Length( curve, u1, u2 );
1574 double lenRatio = newLength / edgeLen * ( edgeReversed ? -1. : 1. );
1575 for ( size_t iP = 1; iP < nodeDataVec.size()-1; ++iP )
1577 const SMDS_MeshNode* oldNode = nodeDataVec[iP].node;
1579 GCPnts_AbscissaPoint discret( curve, segLengths[iP-1] * lenRatio, u1 );
1580 if ( !discret.IsDone() )
1581 throw SALOME_Exception(LOCALIZED("GCPnts_AbscissaPoint failed"));
1583 nodeDataVec[iP].param = discret.Parameter();
1584 if ( oldNode->GetPosition()->GetTypeOfPosition() != SMDS_TOP_EDGE )
1585 throw SALOME_Exception(SMESH_Comment("ViscousBuilder2D: not SMDS_TOP_EDGE node position: ")
1586 << oldNode->GetPosition()->GetTypeOfPosition()
1587 << " of node " << oldNode->GetID());
1588 SMDS_EdgePosition* pos = static_cast<SMDS_EdgePosition*>( oldNode->GetPosition() );
1589 pos->SetUParameter( nodeDataVec[iP].param );
1591 gp_Pnt newP = curve.Value( nodeDataVec[iP].param );
1592 getMeshDS()->MoveNode( oldNode, newP.X(), newP.Y(), newP.Z() );
1594 gp_Pnt2d newUV = pcurve->Value( nodeDataVec[iP].param ).XY();
1595 nodeDataVec[iP].u = newUV.X();
1596 nodeDataVec[iP].v = newUV.Y();
1597 nodeDataVec[iP].normParam = segLengths[iP-1] / edgeLen;
1598 // nodeDataVec[iP].x = segLengths[iP-1] / edgeLen;
1599 // nodeDataVec[iP].y = segLengths[iP-1] / edgeLen;
1602 // Add nodeDataForAdjacent to nodeDataVec
1604 if ( !nodeDataForAdjacent.empty() )
1606 const double par1 = isRShrinkedForAdjacent ? u2 : uf;
1607 const double par2 = isRShrinkedForAdjacent ? ul : u1;
1608 const double shrinkLen = GCPnts_AbscissaPoint::Length( curve, par1, par2 );
1610 // compute new normParam for nodeDataVec
1611 for ( size_t iP = 0; iP < nodeDataVec.size()-1; ++iP )
1612 nodeDataVec[iP+1].normParam = segLengths[iP] / ( edgeLen + shrinkLen );
1613 double normDelta = 1 - nodeDataVec.back().normParam;
1614 if ( !isRShrinkedForAdjacent )
1615 for ( size_t iP = 0; iP < nodeDataVec.size(); ++iP )
1616 nodeDataVec[iP].normParam += normDelta;
1618 // compute new normParam for nodeDataForAdjacent
1619 const double deltaR = isRShrinkedForAdjacent ? nodeDataVec.back().normParam : 0;
1620 for ( size_t iP = !isRShrinkedForAdjacent; iP < nodeDataForAdjacent.size(); ++iP )
1622 double lenFromPar1 =
1623 GCPnts_AbscissaPoint::Length( curve, par1, nodeDataForAdjacent[iP].param );
1624 nodeDataForAdjacent[iP].normParam = deltaR + normDelta * lenFromPar1 / shrinkLen;
1626 // concatenate nodeDataVec and nodeDataForAdjacent
1627 nodeDataVec.insert(( isRShrinkedForAdjacent ? nodeDataVec.end() : nodeDataVec.begin() ),
1628 nodeDataForAdjacent.begin(), nodeDataForAdjacent.end() );
1631 // Extend nodeDataVec by a node located at the end of not shared _LayerEdge
1632 /* n - to add to nodeDataVec
1641 for ( int isR = 0; isR < 2; ++isR )
1643 _PolyLine& L2 = *( isR ? L._rightLine : L._leftLine ); // line with layers
1644 if ( ! L2._advancable || L.IsCommonEdgeShared( L2 ) )
1646 vector< const SMDS_MeshNode* >& layerNodes2 = isR ? L2._leftNodes : L2._rightNodes;
1647 _LayerEdge& LE2 = isR ? L2._lEdges.front() : L2._lEdges.back();
1648 if ( layerNodes2.empty() )
1650 // refine the not shared _LayerEdge
1651 vector<double> layersHeight;
1652 calcLayersHeight( LE2._length2D, layersHeight );
1654 vector<gp_XY>& nodeUV2 = LE2._uvRefined;
1655 nodeUV2.resize ( _hyp->GetNumberLayers() );
1656 layerNodes2.resize( _hyp->GetNumberLayers() );
1657 for ( size_t i = 0; i < layersHeight.size(); ++i )
1659 gp_XY uv = LE2._uvOut + LE2._normal2D * layersHeight[i];
1660 gp_Pnt p = _surface->Value( uv.X(), uv.Y() );
1662 layerNodes2[ i ] = _helper.AddNode( p.X(), p.Y(), p.Z(), /*id=*/0, uv.X(), uv.Y() );
1665 UVPtStruct ptOfNode;
1666 ptOfNode.u = LE2._uvRefined.back().X();
1667 ptOfNode.v = LE2._uvRefined.back().Y();
1668 ptOfNode.node = layerNodes2.back();
1669 ptOfNode.param = isR ? ul : uf;
1670 ptOfNode.normParam = isR ? 1 : 0;
1672 nodeDataVec.insert(( isR ? nodeDataVec.end() : nodeDataVec.begin() ), ptOfNode );
1674 // recompute normParam of nodes in nodeDataVec
1675 newLength = GCPnts_AbscissaPoint::Length( curve,
1676 nodeDataVec.front().param,
1677 nodeDataVec.back().param);
1678 for ( size_t iP = 1; iP < nodeDataVec.size(); ++iP )
1680 const double len = GCPnts_AbscissaPoint::Length( curve,
1681 nodeDataVec.front().param,
1682 nodeDataVec[iP].param );
1683 nodeDataVec[iP].normParam = len / newLength;
1687 // create a proxy sub-mesh containing the moved nodes
1688 _ProxyMeshOfFace::_EdgeSubMesh* edgeSM = getProxyMesh()->GetEdgeSubMesh( edgeID );
1689 edgeSM->SetUVPtStructVec( nodeDataVec );
1691 // set a sub-mesh event listener to remove just created edges when
1692 // "ViscousLayers2D" hypothesis is modified
1693 VISCOUS_3D::ToClearSubWithMain( _mesh->GetSubMesh( E ), _face );
1695 } // loop on _polyLineVec
1700 //================================================================================
1702 * \brief Returns true if there will be a shrinked mesh on EDGE E of FACE adjFace
1705 //================================================================================
1707 bool _ViscousBuilder2D::toShrinkForAdjacent( const TopoDS_Face& adjFace,
1708 const TopoDS_Edge& E,
1709 const TopoDS_Vertex& V)
1711 if ( const StdMeshers_ViscousLayers2D* vlHyp = findHyp( *_mesh, adjFace ))
1713 VISCOUS_2D::_ViscousBuilder2D builder( *_mesh, adjFace, vlHyp );
1714 builder.findEdgesWithLayers();
1716 PShapeIteratorPtr edgeIt = _helper.GetAncestors( V, *_mesh, TopAbs_EDGE );
1717 while ( const TopoDS_Shape* edgeAtV = edgeIt->next() )
1719 if ( !edgeAtV->IsSame( E ) &&
1720 _helper.IsSubShape( *edgeAtV, adjFace ) &&
1721 !builder._ignoreShapeIds.count( getMeshDS()->ShapeToIndex( *edgeAtV )))
1730 //================================================================================
1734 //================================================================================
1736 bool _ViscousBuilder2D::refine()
1738 // store a proxyMesh in a sub-mesh
1739 // make faces on each _PolyLine
1740 vector< double > layersHeight;
1741 double prevLen2D = -1;
1742 for ( size_t iL = 0; iL < _polyLineVec.size(); ++iL )
1744 _PolyLine& L = _polyLineVec[ iL ];
1745 if ( !L._advancable ) continue;
1747 // replace an inactive (1st) _LayerEdge with an active one of a neighbour _PolyLine
1748 size_t iLE = 0, nbLE = L._lEdges.size();
1749 const bool leftEdgeShared = L.IsCommonEdgeShared( *L._leftLine );
1750 const bool rightEdgeShared = L.IsCommonEdgeShared( *L._rightLine );
1751 if ( /*!L._leftLine->_advancable &&*/ leftEdgeShared )
1753 L._lEdges[0] = L._leftLine->_lEdges.back();
1754 iLE += int( !L._leftLine->_advancable );
1756 if ( !L._rightLine->_advancable && rightEdgeShared )
1758 L._lEdges.back() = L._rightLine->_lEdges[0];
1762 // limit length of neighbour _LayerEdge's to avoid sharp change of layers thickness
1763 vector< double > segLen( L._lEdges.size() );
1765 for ( size_t i = 1; i < segLen.size(); ++i )
1767 // accumulate length of segments
1768 double sLen = (L._lEdges[i-1]._uvOut - L._lEdges[i]._uvOut ).Modulus();
1769 segLen[i] = segLen[i-1] + sLen;
1771 for ( int isR = 0; isR < 2; ++isR )
1773 size_t iF = 0, iL = L._lEdges.size()-1;
1774 size_t *i = isR ? &iL : &iF;
1776 _LayerEdge* prevLE = & L._lEdges[ *i ];
1778 for ( ++iF, --iL; iF < L._lEdges.size()-1; ++iF, --iL )
1780 _LayerEdge& LE = L._lEdges[*i];
1781 if ( prevLE->_length2D > 0 ) {
1782 gp_XY tangent ( LE._normal2D.Y(), -LE._normal2D.X() );
1783 weight += Abs( tangent * ( prevLE->_uvIn - LE._uvIn )) / segLen.back();
1784 gp_XY prevTang = ( LE._uvOut - prevLE->_uvOut );
1785 gp_XY prevNorm = gp_XY( -prevTang.Y(), prevTang.X() );
1786 double prevProj = prevNorm * ( prevLE->_uvIn - prevLE->_uvOut );
1787 if ( prevProj > 0 ) {
1788 prevProj /= prevTang.Modulus();
1789 if ( LE._length2D < prevProj )
1790 weight += 0.75 * ( 1 - weight ); // length decrease is more preferable
1791 LE._length2D = weight * LE._length2D + ( 1 - weight ) * prevProj;
1792 LE._uvIn = LE._uvOut + LE._normal2D * LE._length2D;
1799 // calculate intermediate UV on _LayerEdge's ( _LayerEdge::_uvRefined )
1800 for ( ; iLE < nbLE; ++iLE )
1802 _LayerEdge& LE = L._lEdges[iLE];
1803 if ( fabs( LE._length2D - prevLen2D ) > LE._length2D / 100. )
1805 calcLayersHeight( LE._length2D, layersHeight );
1806 prevLen2D = LE._length2D;
1808 for ( size_t i = 0; i < layersHeight.size(); ++i )
1809 LE._uvRefined.push_back( LE._uvOut + LE._normal2D * layersHeight[i] );
1812 // nodes to create 1 layer of faces
1813 vector< const SMDS_MeshNode* > outerNodes( L._lastPntInd - L._firstPntInd + 1 );
1814 vector< const SMDS_MeshNode* > innerNodes( L._lastPntInd - L._firstPntInd + 1 );
1816 // initialize outerNodes by node on the L._wire
1817 const vector<UVPtStruct>& points = L._wire->GetUVPtStruct();
1818 for ( int i = L._firstPntInd; i <= L._lastPntInd; ++i )
1819 outerNodes[ i-L._firstPntInd ] = points[i].node;
1821 // compute normalized [0;1] node parameters of outerNodes
1822 vector< double > normPar( L._lastPntInd - L._firstPntInd + 1 );
1824 normF = L._wire->FirstParameter( L._edgeInd ),
1825 normL = L._wire->LastParameter ( L._edgeInd ),
1826 normDist = normL - normF;
1827 for ( int i = L._firstPntInd; i <= L._lastPntInd; ++i )
1828 normPar[ i - L._firstPntInd ] = ( points[i].normParam - normF ) / normDist;
1830 // Create layers of faces
1832 bool hasLeftNode = ( !L._leftLine->_rightNodes.empty() && leftEdgeShared );
1833 bool hasRightNode = ( !L._rightLine->_leftNodes.empty() && rightEdgeShared );
1834 bool hasOwnLeftNode = ( !L._leftNodes.empty() );
1835 bool hasOwnRightNode = ( !L._rightNodes.empty() );
1837 iN0 = ( hasLeftNode || hasOwnLeftNode || _polyLineVec.size() == 1 ),
1838 nbN = innerNodes.size() - ( hasRightNode || hasOwnRightNode );
1839 L._leftNodes .reserve( _hyp->GetNumberLayers() );
1840 L._rightNodes.reserve( _hyp->GetNumberLayers() );
1841 for ( int iF = 0; iF < _hyp->GetNumberLayers(); ++iF ) // loop on layers of faces
1843 // get accumulated length of intermediate segments
1844 for ( iS = 1; iS < segLen.size(); ++iS )
1846 double sLen = (L._lEdges[iS-1]._uvRefined[iF] - L._lEdges[iS]._uvRefined[iF] ).Modulus();
1847 segLen[iS] = segLen[iS-1] + sLen;
1849 // normalize the accumulated length
1850 for ( iS = 1; iS < segLen.size(); ++iS )
1851 segLen[iS] /= segLen.back();
1853 // create innerNodes of a current layer
1855 for ( size_t i = iN0; i < nbN; ++i )
1857 while ( normPar[i] > segLen[iS+1] )
1859 double r = ( normPar[i] - segLen[iS] ) / ( segLen[iS+1] - segLen[iS] );
1860 gp_XY uv = r * L._lEdges[iS+1]._uvRefined[iF] + (1-r) * L._lEdges[iS]._uvRefined[iF];
1861 gp_Pnt p = _surface->Value( uv.X(), uv.Y() );
1862 innerNodes[i] = _helper.AddNode( p.X(), p.Y(), p.Z(), /*id=*/0, uv.X(), uv.Y() );
1864 // use nodes created for adjacent _PolyLine's
1865 if ( hasOwnLeftNode ) innerNodes.front() = L._leftNodes [ iF ];
1866 else if ( hasLeftNode ) innerNodes.front() = L._leftLine->_rightNodes[ iF ];
1867 if ( hasOwnRightNode ) innerNodes.back() = L._rightNodes[ iF ];
1868 else if ( hasRightNode ) innerNodes.back() = L._rightLine->_leftNodes[ iF ];
1869 if ( _polyLineVec.size() == 1 ) innerNodes.front() = innerNodes.back(); // circle
1870 if ( !hasOwnLeftNode ) L._leftNodes.push_back( innerNodes.front() );
1871 if ( !hasOwnRightNode ) L._rightNodes.push_back( innerNodes.back() );
1874 // TODO care of orientation
1875 for ( size_t i = 1; i < innerNodes.size(); ++i )
1876 if ( SMDS_MeshElement* f = _helper.AddFace( outerNodes[ i-1 ], outerNodes[ i ],
1877 innerNodes[ i ], innerNodes[ i-1 ]))
1878 L._newFaces.insert( L._newFaces.end(), f );
1880 outerNodes.swap( innerNodes );
1882 // faces between not shared _LayerEdge's (at concave VERTEX)
1883 for ( int isR = 0; isR < 2; ++isR )
1885 if ( isR ? rightEdgeShared : leftEdgeShared )
1887 vector< const SMDS_MeshNode* > &
1888 lNodes = (isR ? L._rightNodes : L._leftLine->_rightNodes ),
1889 rNodes = (isR ? L._rightLine->_leftNodes : L._leftNodes );
1890 if ( lNodes.empty() || rNodes.empty() || lNodes.size() != rNodes.size() )
1893 for ( size_t i = 1; i < lNodes.size(); ++i )
1894 _helper.AddFace( lNodes[ i-1 ], rNodes[ i-1 ],
1895 rNodes[ i ], lNodes[ i ]);
1897 const UVPtStruct& ptOnVertex = points[ isR ? L._lastPntInd : L._firstPntInd ];
1898 _helper.AddFace( ptOnVertex.node, rNodes[ 0 ], lNodes[ 0 ]);
1901 // Fill the _ProxyMeshOfFace
1903 UVPtStructVec nodeDataVec( outerNodes.size() ); // outerNodes swapped with innerNodes
1904 for ( size_t i = 0; i < outerNodes.size(); ++i )
1906 gp_XY uv = _helper.GetNodeUV( _face, outerNodes[i] );
1907 nodeDataVec[i].u = uv.X();
1908 nodeDataVec[i].v = uv.Y();
1909 nodeDataVec[i].node = outerNodes[i];
1910 nodeDataVec[i].param = points [i + L._firstPntInd].param;
1911 nodeDataVec[i].normParam = normPar[i];
1912 nodeDataVec[i].x = normPar[i];
1913 nodeDataVec[i].y = normPar[i];
1915 nodeDataVec.front().param = L._wire->FirstU( L._edgeInd );
1916 nodeDataVec.back() .param = L._wire->LastU ( L._edgeInd );
1918 _ProxyMeshOfFace::_EdgeSubMesh* edgeSM
1919 = getProxyMesh()->GetEdgeSubMesh( L._wire->EdgeID( L._edgeInd ));
1920 edgeSM->SetUVPtStructVec( nodeDataVec );
1922 } // loop on _PolyLine's
1927 //================================================================================
1929 * \brief Improve quality of the created mesh elements
1931 //================================================================================
1933 bool _ViscousBuilder2D::improve()
1938 // fixed nodes on EDGE's
1939 std::set<const SMDS_MeshNode*> fixedNodes;
1940 for ( size_t iWire = 0; iWire < _faceSideVec.size(); ++iWire )
1942 StdMeshers_FaceSidePtr wire = _faceSideVec[ iWire ];
1943 const vector<UVPtStruct>& points = wire->GetUVPtStruct();
1944 for ( size_t i = 0; i < points.size(); ++i )
1945 fixedNodes.insert( fixedNodes.end(), points[i].node );
1947 // fixed proxy nodes
1948 for ( size_t iL = 0; iL < _polyLineVec.size(); ++iL )
1950 _PolyLine& L = _polyLineVec[ iL ];
1951 const TopoDS_Edge& E = L._wire->Edge( L._edgeInd );
1952 if ( const SMESH_ProxyMesh::SubMesh* sm = _proxyMesh->GetProxySubMesh( E ))
1954 const UVPtStructVec& points = sm->GetUVPtStructVec();
1955 for ( size_t i = 0; i < points.size(); ++i )
1956 fixedNodes.insert( fixedNodes.end(), points[i].node );
1958 for ( size_t i = 0; i < L._rightNodes.size(); ++i )
1959 fixedNodes.insert( fixedNodes.end(), L._rightNodes[i] );
1963 SMESH_MeshEditor editor( _mesh );
1964 for ( size_t iL = 0; iL < _polyLineVec.size(); ++iL )
1966 _PolyLine& L = _polyLineVec[ iL ];
1967 if ( L._isStraight2D ) continue;
1968 // SMESH_MeshEditor::SmoothMethod how =
1969 // L._isStraight2D ? SMESH_MeshEditor::LAPLACIAN : SMESH_MeshEditor::CENTROIDAL;
1970 //editor.Smooth( L._newFaces, fixedNodes, how, /*nbIt = */3 );
1971 //editor.Smooth( L._newFaces, fixedNodes, SMESH_MeshEditor::LAPLACIAN, /*nbIt = */1 );
1972 editor.Smooth( L._newFaces, fixedNodes, SMESH_MeshEditor::CENTROIDAL, /*nbIt = */3 );
1977 //================================================================================
1979 * \brief Remove elements and nodes from a face
1981 //================================================================================
1983 bool _ViscousBuilder2D::removeMeshFaces(const TopoDS_Shape& face)
1985 // we don't use SMESH_subMesh::ComputeStateEngine() because of a listener
1986 // which clears EDGEs together with _face.
1987 bool thereWereElems = false;
1988 SMESH_subMesh* sm = _mesh->GetSubMesh( face );
1989 if ( SMESHDS_SubMesh* smDS = sm->GetSubMeshDS() )
1991 SMDS_ElemIteratorPtr eIt = smDS->GetElements();
1992 thereWereElems = eIt->more();
1993 while ( eIt->more() ) getMeshDS()->RemoveFreeElement( eIt->next(), smDS );
1994 SMDS_NodeIteratorPtr nIt = smDS->GetNodes();
1995 while ( nIt->more() ) getMeshDS()->RemoveFreeNode( nIt->next(), smDS );
1997 sm->ComputeStateEngine( SMESH_subMesh::CHECK_COMPUTE_STATE );
1999 return thereWereElems;
2002 //================================================================================
2004 * \brief Creates a _ProxyMeshOfFace and store it in a sub-mesh of FACE
2006 //================================================================================
2008 _ProxyMeshOfFace* _ViscousBuilder2D::getProxyMesh()
2010 if ( _proxyMesh.get() )
2011 return (_ProxyMeshOfFace*) _proxyMesh.get();
2013 _ProxyMeshOfFace* proxyMeshOfFace = new _ProxyMeshOfFace( *_mesh );
2014 _proxyMesh.reset( proxyMeshOfFace );
2015 new _ProxyMeshHolder( _face, _proxyMesh );
2017 return proxyMeshOfFace;
2020 //================================================================================
2022 * \brief Calculate height of layers for the given thickness. Height is measured
2023 * from the outer boundary
2025 //================================================================================
2027 void _ViscousBuilder2D::calcLayersHeight(const double totalThick,
2028 vector<double>& heights)
2030 heights.resize( _hyp->GetNumberLayers() );
2032 if ( _fPowN - 1 <= numeric_limits<double>::min() )
2033 h0 = totalThick / _hyp->GetNumberLayers();
2035 h0 = totalThick * ( _hyp->GetStretchFactor() - 1 )/( _fPowN - 1 );
2037 double hSum = 0, hi = h0;
2038 for ( int i = 0; i < _hyp->GetNumberLayers(); ++i )
2041 heights[ i ] = hSum;
2042 hi *= _hyp->GetStretchFactor();
2046 //================================================================================
2048 * \brief Elongate this _LayerEdge
2050 //================================================================================
2052 bool _LayerEdge::SetNewLength( const double length3D )
2054 if ( _isBlocked ) return false;
2056 //_uvInPrev = _uvIn;
2057 _length2D = length3D * _len2dTo3dRatio;
2058 _uvIn = _uvOut + _normal2D * _length2D;
2062 //================================================================================
2064 * \brief Return true if _LayerEdge at a common VERTEX between EDGEs with
2065 * and w/o layer is common to the both _PolyLine's. If this is true, nodes
2066 * of this _LayerEdge are inflated along a _PolyLine w/o layer, else the nodes
2067 * are inflated along _normal2D of _LayerEdge of EDGE with layer
2069 //================================================================================
2071 bool _PolyLine::IsCommonEdgeShared( const _PolyLine& other )
2073 const double tol = 1e-30;
2075 if ( & other == _leftLine )
2076 return _lEdges[0]._normal2D.IsEqual( _leftLine->_lEdges.back()._normal2D, tol );
2078 if ( & other == _rightLine )
2079 return _lEdges.back()._normal2D.IsEqual( _rightLine->_lEdges[0]._normal2D, tol );
2084 //================================================================================
2086 * \brief Constructor of SegmentTree
2088 //================================================================================
2090 _SegmentTree::_SegmentTree( const vector< _Segment >& segments ):
2093 _segments.resize( segments.size() );
2094 for ( size_t i = 0; i < segments.size(); ++i )
2095 _segments[i].Set( segments[i] );
2100 //================================================================================
2102 * \brief Return the maximal bnd box
2104 //================================================================================
2106 _SegmentTree::box_type* _SegmentTree::buildRootBox()
2108 _SegmentTree::box_type* box = new _SegmentTree::box_type;
2109 for ( size_t i = 0; i < _segments.size(); ++i )
2111 box->Add( *_segments[i]._seg->_uv[0] );
2112 box->Add( *_segments[i]._seg->_uv[1] );
2117 //================================================================================
2119 * \brief Redistrubute _segments among children
2121 //================================================================================
2123 void _SegmentTree::buildChildrenData()
2125 for ( int i = 0; i < _segments.size(); ++i )
2126 for (int j = 0; j < nbChildren(); j++)
2127 if ( !myChildren[j]->getBox()->IsOut( *_segments[i]._seg->_uv[0],
2128 *_segments[i]._seg->_uv[1] ))
2129 ((_SegmentTree*)myChildren[j])->_segments.push_back( _segments[i]);
2131 SMESHUtils::FreeVector( _segments ); // = _elements.clear() + free memory
2133 for (int j = 0; j < nbChildren(); j++)
2135 _SegmentTree* child = static_cast<_SegmentTree*>( myChildren[j]);
2136 child->myIsLeaf = ( child->_segments.size() <= maxNbSegInLeaf() );
2140 //================================================================================
2142 * \brief Return elements which can include the point
2144 //================================================================================
2146 void _SegmentTree::GetSegmentsNear( const _Segment& seg,
2147 vector< const _Segment* >& found )
2149 if ( getBox()->IsOut( *seg._uv[0], *seg._uv[1] ))
2154 for ( int i = 0; i < _segments.size(); ++i )
2155 if ( !_segments[i].IsOut( seg ))
2156 found.push_back( _segments[i]._seg );
2160 for (int i = 0; i < nbChildren(); i++)
2161 ((_SegmentTree*) myChildren[i])->GetSegmentsNear( seg, found );
2166 //================================================================================
2168 * \brief Return segments intersecting a ray
2170 //================================================================================
2172 void _SegmentTree::GetSegmentsNear( const gp_Ax2d& ray,
2173 vector< const _Segment* >& found )
2175 if ( getBox()->IsOut( ray ))
2180 for ( int i = 0; i < _segments.size(); ++i )
2181 if ( !_segments[i].IsOut( ray ))
2182 found.push_back( _segments[i]._seg );
2186 for (int i = 0; i < nbChildren(); i++)
2187 ((_SegmentTree*) myChildren[i])->GetSegmentsNear( ray, found );
2191 //================================================================================
2193 * \brief Classify a _Segment
2195 //================================================================================
2197 bool _SegmentTree::_SegBox::IsOut( const _Segment& seg ) const
2199 const double eps = std::numeric_limits<double>::min();
2200 for ( int iC = 0; iC < 2; ++iC )
2202 if ( seg._uv[0]->Coord(iC+1) < _seg->_uv[ _iMin[iC]]->Coord(iC+1)+eps &&
2203 seg._uv[1]->Coord(iC+1) < _seg->_uv[ _iMin[iC]]->Coord(iC+1)+eps )
2205 if ( seg._uv[0]->Coord(iC+1) > _seg->_uv[ 1-_iMin[iC]]->Coord(iC+1)-eps &&
2206 seg._uv[1]->Coord(iC+1) > _seg->_uv[ 1-_iMin[iC]]->Coord(iC+1)-eps )
2212 //================================================================================
2214 * \brief Classify a ray
2216 //================================================================================
2218 bool _SegmentTree::_SegBox::IsOut( const gp_Ax2d& ray ) const
2220 double distBoxCenter2Ray =
2221 ray.Direction().XY() ^ ( ray.Location().XY() - 0.5 * (*_seg->_uv[0] + *_seg->_uv[1]));
2223 double boxSectionDiam =
2224 Abs( ray.Direction().X() ) * ( _seg->_uv[1-_iMin[1]]->Y() - _seg->_uv[_iMin[1]]->Y() ) +
2225 Abs( ray.Direction().Y() ) * ( _seg->_uv[1-_iMin[0]]->X() - _seg->_uv[_iMin[0]]->X() );
2227 return Abs( distBoxCenter2Ray ) > 0.5 * boxSectionDiam;