-// Copyright (C) 2007-2012 CEA/DEN, EDF R&D, OPEN CASCADE
+// Copyright (C) 2007-2013 CEA/DEN, EDF R&D, OPEN CASCADE
//
// Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN,
// CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS
#include "SMESH_Gen.hxx"
#include "SMESH_HypoFilter.hxx"
#include "SMESH_Mesh.hxx"
+#include "SMESH_MeshAlgos.hxx"
#include "SMESH_TypeDefs.hxx"
+#include "SMESH_subMesh.hxx"
#include <Basics_OCCTVersion.hxx>
#include <GCPnts_AbscissaPoint.hxx>
#include <GeomAdaptor_Curve.hxx>
#include <Geom_Surface.hxx>
+#include <LDOMParser.hxx>
#include <TopExp.hxx>
+#include <TopExp_Explorer.hxx>
#include <TopLoc_Location.hxx>
#include <TopTools_ListIteratorOfListOfShape.hxx>
#include <TopTools_ListOfShape.hxx>
#include <TopoDS_Edge.hxx>
#include <TopoDS_Face.hxx>
#include <TopoDS_Vertex.hxx>
+#include <TopoDS_Wire.hxx>
#include <gp_Pnt.hxx>
#include <gp_Pnt2d.hxx>
#include <gp_Vec.hxx>
#include <algorithm>
#include <limits>
+#include "SMESH_ProxyMesh.hxx"
+#include "SMESH_MesherHelper.hxx"
using namespace std;
+//================================================================================
+/*!
+ * \brief Returns \a true if two algorithms (described by \a this and the given
+ * algo data) are compatible by their output and input types of elements.
+ */
+//================================================================================
+
+bool SMESH_Algo::Features::IsCompatible( const SMESH_Algo::Features& algo2 ) const
+{
+ if ( _dim > algo2._dim ) return algo2.IsCompatible( *this );
+ // algo2 is of highter dimension
+ if ( _outElemTypes.empty() || algo2._inElemTypes.empty() )
+ return false;
+ bool compatible = true;
+ set<SMDSAbs_GeometryType>::const_iterator myOutType = _outElemTypes.begin();
+ for ( ; myOutType != _outElemTypes.end() && compatible; ++myOutType )
+ compatible = algo2._inElemTypes.count( *myOutType );
+ return compatible;
+}
+
+//================================================================================
+/*!
+ * \brief Return Data of the algorithm
+ */
+//================================================================================
+
+const SMESH_Algo::Features& SMESH_Algo::GetFeatures( const std::string& algoType )
+{
+ static map< string, SMESH_Algo::Features > theFeaturesByName;
+ if ( theFeaturesByName.empty() )
+ {
+ // Read Plugin.xml files
+ vector< string > xmlPaths = SMESH_Gen::GetPluginXMLPaths();
+ LDOMParser xmlParser;
+ for ( size_t iXML = 0; iXML < xmlPaths.size(); ++iXML )
+ {
+ bool error = xmlParser.parse( xmlPaths[iXML].c_str() );
+ if ( error )
+ {
+ TCollection_AsciiString data;
+ INFOS( xmlParser.GetError(data) );
+ continue;
+ }
+ // <algorithm type="Regular_1D"
+ // ...
+ // input="EDGE"
+ // output="QUAD,TRIA">
+ //
+ LDOM_Document xmlDoc = xmlParser.getDocument();
+ LDOM_NodeList algoNodeList = xmlDoc.getElementsByTagName( "algorithm" );
+ for ( int i = 0; i < algoNodeList.getLength(); ++i )
+ {
+ LDOM_Node algoNode = algoNodeList.item( i );
+ LDOM_Element& algoElem = (LDOM_Element&) algoNode;
+ TCollection_AsciiString algoType = algoElem.getAttribute("type");
+ TCollection_AsciiString input = algoElem.getAttribute("input");
+ TCollection_AsciiString output = algoElem.getAttribute("output");
+ TCollection_AsciiString dim = algoElem.getAttribute("dim");
+ TCollection_AsciiString label = algoElem.getAttribute("label-id");
+ if ( algoType.IsEmpty() ) continue;
+
+ Features & data = theFeaturesByName[ algoType.ToCString() ];
+ data._dim = dim.IntegerValue();
+ data._label = label.ToCString();
+ for ( int isInput = 0; isInput < 2; ++isInput )
+ {
+ TCollection_AsciiString& typeStr = isInput ? input : output;
+ set<SMDSAbs_GeometryType>& typeSet = isInput ? data._inElemTypes : data._outElemTypes;
+ int beg = 1, end;
+ while ( beg <= typeStr.Length() )
+ {
+ while ( beg < typeStr.Length() && !isalpha( typeStr.Value( beg ) ))
+ ++beg;
+ end = beg;
+ while ( end < typeStr.Length() && isalpha( typeStr.Value( end + 1 ) ))
+ ++end;
+ if ( end > beg )
+ {
+ TCollection_AsciiString typeName = typeStr.SubString( beg, end );
+ if ( typeName == "EDGE" ) typeSet.insert( SMDSGeom_EDGE );
+ else if ( typeName == "TRIA" ) typeSet.insert( SMDSGeom_TRIANGLE );
+ else if ( typeName == "QUAD" ) typeSet.insert( SMDSGeom_QUADRANGLE );
+ }
+ beg = end + 1;
+ }
+ }
+ }
+ }
+ }
+ return theFeaturesByName[ algoType ];
+}
+
//=============================================================================
/*!
*
SMESH_Algo::SMESH_Algo (int hypId, int studyId, SMESH_Gen * gen)
: SMESH_Hypothesis(hypId, studyId, gen)
{
- gen->_mapAlgo[hypId] = this;
+ //gen->_mapAlgo[hypId] = this;
_onlyUnaryInput = _requireDiscreteBoundary = _requireShape = true;
_quadraticMesh = _supportSubmeshes = false;
_error = COMPERR_OK;
+ for ( int i = 0; i < 4; ++i )
+ _neededLowerHyps[ i ] = false;
}
//=============================================================================
{
}
+//=============================================================================
+/*!
+ *
+ */
+//=============================================================================
+
+SMESH_0D_Algo::SMESH_0D_Algo(int hypId, int studyId, SMESH_Gen* gen)
+ : SMESH_Algo(hypId, studyId, gen)
+{
+ _shapeType = (1 << TopAbs_VERTEX);
+ _type = ALGO_0D;
+ //gen->_map0D_Algo[hypId] = this;
+}
+SMESH_1D_Algo::SMESH_1D_Algo(int hypId, int studyId, SMESH_Gen* gen)
+ : SMESH_Algo(hypId, studyId, gen)
+{
+ _shapeType = (1 << TopAbs_EDGE);
+ _type = ALGO_1D;
+ //gen->_map1D_Algo[hypId] = this;
+}
+SMESH_2D_Algo::SMESH_2D_Algo(int hypId, int studyId, SMESH_Gen* gen)
+ : SMESH_Algo(hypId, studyId, gen)
+{
+ _shapeType = (1 << TopAbs_FACE);
+ _type = ALGO_2D;
+ //gen->_map2D_Algo[hypId] = this;
+}
+SMESH_3D_Algo::SMESH_3D_Algo(int hypId, int studyId, SMESH_Gen* gen)
+ : SMESH_Algo(hypId, studyId, gen)
+{
+ _shapeType = (1 << TopAbs_SOLID);
+ _type = ALGO_3D;
+ //gen->_map3D_Algo[hypId] = this;
+}
+
//=============================================================================
/*!
* Usually an algoritm has nothing to save
const list <const SMESHDS_Hypothesis *> &
SMESH_Algo::GetUsedHypothesis(SMESH_Mesh & aMesh,
const TopoDS_Shape & aShape,
- const bool ignoreAuxiliary)
+ const bool ignoreAuxiliary) const
{
- _usedHypList.clear();
+ SMESH_Algo* me = const_cast< SMESH_Algo* >( this );
+ me->_usedHypList.clear();
SMESH_HypoFilter filter;
if ( InitCompatibleHypoFilter( filter, ignoreAuxiliary ))
{
- aMesh.GetHypotheses( aShape, filter, _usedHypList, true );
+ aMesh.GetHypotheses( aShape, filter, me->_usedHypList, true );
if ( ignoreAuxiliary && _usedHypList.size() > 1 )
- _usedHypList.clear(); //only one compatible hypothesis allowed
+ me->_usedHypList.clear(); //only one compatible hypothesis allowed
}
return _usedHypList;
}
const list<const SMESHDS_Hypothesis *> &
SMESH_Algo::GetAppliedHypothesis(SMESH_Mesh & aMesh,
const TopoDS_Shape & aShape,
- const bool ignoreAuxiliary)
+ const bool ignoreAuxiliary) const
{
- _appliedHypList.clear();
+ SMESH_Algo* me = const_cast< SMESH_Algo* >( this );
+ me->_appliedHypList.clear();
SMESH_HypoFilter filter;
if ( InitCompatibleHypoFilter( filter, ignoreAuxiliary ))
- aMesh.GetHypotheses( aShape, filter, _appliedHypList, false );
+ aMesh.GetHypotheses( aShape, filter, me->_appliedHypList, false );
return _appliedHypList;
}
double SMESH_Algo::EdgeLength(const TopoDS_Edge & E)
{
double UMin = 0, UMax = 0;
- if (BRep_Tool::Degenerated(E))
- return 0;
TopLoc_Location L;
Handle(Geom_Curve) C = BRep_Tool::Curve(E, L, UMin, UMax);
+ if ( C.IsNull() )
+ return 0.;
GeomAdaptor_Curve AdaptCurve(C, UMin, UMax); //range is important for periodic curves
double length = GCPnts_AbscissaPoint::Length(AdaptCurve, UMin, UMax);
return length;
}
-//================================================================================
-/*!
- * \brief Calculate normal of a mesh face
- */
-//================================================================================
-
-bool SMESH_Algo::FaceNormal(const SMDS_MeshElement* F, gp_XYZ& normal, bool normalized)
-{
- if ( !F || F->GetType() != SMDSAbs_Face )
- return false;
-
- normal.SetCoord(0,0,0);
- int nbNodes = F->IsQuadratic() ? F->NbNodes()/2 : F->NbNodes();
- for ( int i = 0; i < nbNodes-2; ++i )
- {
- gp_XYZ p[3];
- for ( int n = 0; n < 3; ++n )
- {
- const SMDS_MeshNode* node = F->GetNode( i + n );
- p[n].SetCoord( node->X(), node->Y(), node->Z() );
- }
- normal += ( p[2] - p[1] ) ^ ( p[0] - p[1] );
- }
- double size2 = normal.SquareModulus();
- bool ok = ( size2 > numeric_limits<double>::min() * numeric_limits<double>::min());
- if ( normalized && ok )
- normal /= sqrt( size2 );
-
- return ok;
-}
-
-//================================================================================
-/*!
- * \brief Find out elements orientation on a geometrical face
- * \param theFace - The face correctly oriented in the shape being meshed
- * \param theMeshDS - The mesh data structure
- * \retval bool - true if the face normal and the normal of first element
- * in the correspoding submesh point in different directions
- */
-//================================================================================
-
-bool SMESH_Algo::IsReversedSubMesh (const TopoDS_Face& theFace,
- SMESHDS_Mesh* theMeshDS)
-{
- if ( theFace.IsNull() || !theMeshDS )
- return false;
-
- // find out orientation of a meshed face
- int faceID = theMeshDS->ShapeToIndex( theFace );
- TopoDS_Shape aMeshedFace = theMeshDS->IndexToShape( faceID );
- bool isReversed = ( theFace.Orientation() != aMeshedFace.Orientation() );
-
- const SMESHDS_SubMesh * aSubMeshDSFace = theMeshDS->MeshElements( faceID );
- if ( !aSubMeshDSFace )
- return isReversed;
-
- // find element with node located on face and get its normal
- const SMDS_FacePosition* facePos = 0;
- int vertexID = 0;
- gp_Pnt nPnt[3];
- gp_Vec Ne;
- bool normalOK = false;
- SMDS_ElemIteratorPtr iteratorElem = aSubMeshDSFace->GetElements();
- while ( iteratorElem->more() ) // loop on elements on theFace
- {
- const SMDS_MeshElement* elem = iteratorElem->next();
- if ( elem && elem->NbNodes() > 2 ) {
- SMDS_ElemIteratorPtr nodesIt = elem->nodesIterator();
- const SMDS_FacePosition* fPos = 0;
- int i = 0, vID = 0;
- while ( nodesIt->more() ) { // loop on nodes
- const SMDS_MeshNode* node
- = static_cast<const SMDS_MeshNode *>(nodesIt->next());
- if ( i == 3 ) i = 2;
- nPnt[ i++ ].SetCoord( node->X(), node->Y(), node->Z() );
- // check position
- const SMDS_PositionPtr& pos = node->GetPosition();
- if ( !pos ) continue;
- if ( pos->GetTypeOfPosition() == SMDS_TOP_FACE ) {
- fPos = dynamic_cast< const SMDS_FacePosition* >( pos );
- }
- else if ( pos->GetTypeOfPosition() == SMDS_TOP_VERTEX ) {
- vID = node->getshapeId();
- }
- }
- if ( fPos || ( !normalOK && vID )) {
- // compute normal
- gp_Vec v01( nPnt[0], nPnt[1] ), v02( nPnt[0], nPnt[2] );
- if ( v01.SquareMagnitude() > RealSmall() &&
- v02.SquareMagnitude() > RealSmall() )
- {
- Ne = v01 ^ v02;
- normalOK = ( Ne.SquareMagnitude() > RealSmall() );
- }
- // we need position on theFace or at least on vertex
- if ( normalOK ) {
- vertexID = vID;
- if ((facePos = fPos))
- break;
- }
- }
- }
- }
- if ( !normalOK )
- return isReversed;
-
- // node position on face
- double u,v;
- if ( facePos ) {
- u = facePos->GetUParameter();
- v = facePos->GetVParameter();
- }
- else if ( vertexID ) {
- TopoDS_Shape V = theMeshDS->IndexToShape( vertexID );
- if ( V.IsNull() || V.ShapeType() != TopAbs_VERTEX )
- return isReversed;
- gp_Pnt2d uv = BRep_Tool::Parameters( TopoDS::Vertex( V ), theFace );
- u = uv.X();
- v = uv.Y();
- }
- else
- {
- return isReversed;
- }
-
- // face normal at node position
- TopLoc_Location loc;
- Handle(Geom_Surface) surf = BRep_Tool::Surface( theFace, loc );
- if ( surf.IsNull() || surf->Continuity() < GeomAbs_C1 ) return isReversed;
- gp_Vec d1u, d1v;
- surf->D1( u, v, nPnt[0], d1u, d1v );
- gp_Vec Nf = (d1u ^ d1v).Transformed( loc );
-
- if ( theFace.Orientation() == TopAbs_REVERSED )
- Nf.Reverse();
-
- return Ne * Nf < 0.;
-}
-
//================================================================================
/*!
* \brief Just return false as the algorithm does not hold parameters values
return GeomAbs_C0;
}
+//================================================================================
+/*!
+ * \brief Return true if an edge can be considered straight
+ */
+//================================================================================
+
+bool SMESH_Algo::isStraight( const TopoDS_Edge & E,
+ const bool degenResult)
+{
+ {
+ double f,l;
+ if ( BRep_Tool::Curve( E, f, l ).IsNull())
+ return degenResult;
+ }
+ BRepAdaptor_Curve curve( E );
+ switch( curve.GetType() )
+ {
+ case GeomAbs_Line:
+ return true;
+ case GeomAbs_Circle:
+ case GeomAbs_Ellipse:
+ case GeomAbs_Hyperbola:
+ case GeomAbs_Parabola:
+ return false;
+ // case GeomAbs_BezierCurve:
+ // case GeomAbs_BSplineCurve:
+ // case GeomAbs_OtherCurve:
+ default:;
+ }
+ const double f = curve.FirstParameter();
+ const double l = curve.LastParameter();
+ const gp_Pnt pf = curve.Value( f );
+ const gp_Pnt pl = curve.Value( l );
+ const gp_Vec v1( pf, pl );
+ const double v1Len = v1.Magnitude();
+ if ( v1Len < std::numeric_limits< double >::min() )
+ return false; // E seems closed
+ const double tol = Min( 10 * curve.Tolerance(), v1Len * 1e-2 );
+ const int nbSamples = 7;
+ for ( int i = 0; i < nbSamples; ++i )
+ {
+ const double r = ( i + 1 ) / nbSamples;
+ const gp_Pnt pi = curve.Value( f * r + l * ( 1 - r ));
+ const gp_Vec vi( pf, pi );
+ const double h = 0.5 * v1.Crossed( vi ).Magnitude() / v1Len;
+ if ( h > tol )
+ return false;
+ }
+ return true;
+}
+
+//================================================================================
+/*!
+ * \brief Return true if an edge has no 3D curve
+ */
+//================================================================================
+
+bool SMESH_Algo::isDegenerated( const TopoDS_Edge & E )
+{
+ double f,l;
+ TopLoc_Location loc;
+ Handle(Geom_Curve) C = BRep_Tool::Curve( E, loc, f,l );
+ return C.IsNull();
+}
+
//================================================================================
/*!
* \brief Return the node built on a vertex
return 0;
}
-//=======================================================================
-//function : GetCommonNodes
-//purpose : Return nodes common to two elements
-//=======================================================================
-
-vector< const SMDS_MeshNode*> SMESH_Algo::GetCommonNodes(const SMDS_MeshElement* e1,
- const SMDS_MeshElement* e2)
-{
- vector< const SMDS_MeshNode*> common;
- for ( int i = 0 ; i < e1->NbNodes(); ++i )
- if ( e2->GetNodeIndex( e1->GetNode( i )) >= 0 )
- common.push_back( e1->GetNode( i ));
- return common;
-}
-
//=======================================================================
//function : GetMeshError
//purpose : Finds topological errors of a sub-mesh
_error = COMPERR_CANCELED;
}
+//================================================================================
+/*
+ * If possible, returns progress of computation [0.,1.]
+ */
+//================================================================================
+
+double SMESH_Algo::GetProgress() const
+{
+ return _progress;
+}
+
//================================================================================
/*!
* \brief store error and comment and then return ( error == COMPERR_OK )
//================================================================================
/*!
- * \brief initialize compute error
+ * \brief initialize compute error before call of Compute()
*/
//================================================================================
_badInputElements.clear();
_computeCanceled = false;
+ _progressTic = 0;
+ _progress = 0.;
+}
+
+//================================================================================
+/*!
+ * \brief Return compute progress by nb of calls of this method
+ */
+//================================================================================
+
+double SMESH_Algo::GetProgressByTic() const
+{
+ int computeCost = 0;
+ for ( size_t i = 0; i < _smToCompute.size(); ++i )
+ computeCost += _smToCompute[i]->GetComputeCost();
+
+ const_cast<SMESH_Algo*>( this )->_progressTic++;
+
+ double x = 5 * _progressTic;
+ x = ( x < computeCost ) ? ( x / computeCost ) : 1.;
+ return 0.9 * sin( x * M_PI / 2 );
}
//================================================================================
if ( elem )
_badInputElements.push_back( elem );
}
+
+//=======================================================================
+//function : addBadInputElements
+//purpose : store a bad input elements or nodes preventing computation
+//=======================================================================
+
+void SMESH_Algo::addBadInputElements(const SMESHDS_SubMesh* sm,
+ const bool addNodes)
+{
+ if ( sm )
+ {
+ if ( addNodes )
+ {
+ SMDS_NodeIteratorPtr nIt = sm->GetNodes();
+ while ( nIt->more() ) addBadInputElement( nIt->next() );
+ }
+ else
+ {
+ SMDS_ElemIteratorPtr eIt = sm->GetElements();
+ while ( eIt->more() ) addBadInputElement( eIt->next() );
+ }
+ }
+}
+
+//=============================================================================
+/*!
+ *
+ */
+//=============================================================================
+
+// int SMESH_Algo::NumberOfWires(const TopoDS_Shape& S)
+// {
+// int i = 0;
+// for (TopExp_Explorer exp(S,TopAbs_WIRE); exp.More(); exp.Next())
+// i++;
+// return i;
+// }
+
+//=============================================================================
+/*!
+ *
+ */
+//=============================================================================
+
+int SMESH_Algo::NumberOfPoints(SMESH_Mesh& aMesh, const TopoDS_Wire& W)
+{
+ int nbPoints = 0;
+ for (TopExp_Explorer exp(W,TopAbs_EDGE); exp.More(); exp.Next()) {
+ const TopoDS_Edge& E = TopoDS::Edge(exp.Current());
+ int nb = aMesh.GetSubMesh(E)->GetSubMeshDS()->NbNodes();
+ if(_quadraticMesh)
+ nb = nb/2;
+ nbPoints += nb + 1; // internal points plus 1 vertex of 2 (last point ?)
+ }
+ return nbPoints;
+}
+
+
+//================================================================================
+/*!
+ * Method in which an algorithm generating a structured mesh
+ * fixes positions of in-face nodes after there movement
+ * due to insertion of viscous layers.
+ */
+//================================================================================
+
+bool SMESH_2D_Algo::FixInternalNodes(const SMESH_ProxyMesh& mesh,
+ const TopoDS_Face& face)
+{
+ const SMESHDS_SubMesh* smDS = mesh.GetSubMesh(face);
+ if ( !smDS || smDS->NbElements() < 1 )
+ return false;
+
+ SMESH_MesherHelper helper( *mesh.GetMesh() );
+
+ // get all faces from a proxy sub-mesh
+ typedef SMDS_StdIterator< const SMDS_MeshElement*, SMDS_ElemIteratorPtr > TIterator;
+ TIDSortedElemSet allFaces( TIterator( smDS->GetElements() ), TIterator() );
+ TIDSortedElemSet avoidSet, firstRowQuads;
+
+ // indices of nodes to pass to a neighbour quad using SMESH_MeshAlgos::FindFaceInSet()
+ int iN1, iN2;
+
+ // get two first rows of nodes by passing through the first row of faces
+ vector< vector< const SMDS_MeshNode* > > nodeRows;
+ int iRow1 = 0, iRow2 = 1;
+ const SMDS_MeshElement* quad;
+ {
+ // look for a corner quadrangle and it's corner node
+ const SMDS_MeshElement* cornerQuad = 0;
+ int cornerNodeInd = -1;
+ SMDS_ElemIteratorPtr fIt = smDS->GetElements();
+ while ( !cornerQuad && fIt->more() )
+ {
+ cornerQuad = fIt->next();
+ if ( cornerQuad->NbCornerNodes() != 4 )
+ return false;
+ SMDS_NodeIteratorPtr nIt = cornerQuad->nodeIterator();
+ for ( int i = 0; i < 4; ++i )
+ {
+ int nbInverseQuads = 0;
+ SMDS_ElemIteratorPtr fIt = nIt->next()->GetInverseElementIterator(SMDSAbs_Face);
+ while ( fIt->more() )
+ nbInverseQuads += allFaces.count( fIt->next() );
+ if ( nbInverseQuads == 1 )
+ cornerNodeInd = i, i = 4;
+ }
+ if ( cornerNodeInd < 0 )
+ cornerQuad = 0;
+ }
+ if ( !cornerQuad || cornerNodeInd < 0 )
+ return false;
+
+ iN1 = helper.WrapIndex( cornerNodeInd + 1, 4 );
+ iN2 = helper.WrapIndex( cornerNodeInd + 2, 4 );
+ int iN3 = helper.WrapIndex( cornerNodeInd + 3, 4 );
+ nodeRows.resize(2);
+ nodeRows[iRow1].push_back( cornerQuad->GetNode( cornerNodeInd ));
+ nodeRows[iRow1].push_back( cornerQuad->GetNode( iN1 ));
+ nodeRows[iRow2].push_back( cornerQuad->GetNode( iN3 ));
+ nodeRows[iRow2].push_back( cornerQuad->GetNode( iN2 ));
+ firstRowQuads.insert( cornerQuad );
+
+ // pass through the rest quads in a face row
+ quad = cornerQuad;
+ while ( quad )
+ {
+ avoidSet.clear();
+ avoidSet.insert( quad );
+ if (( quad = SMESH_MeshAlgos::FindFaceInSet( nodeRows[iRow1].back(),
+ nodeRows[iRow2].back(),
+ allFaces, avoidSet, &iN1, &iN2)))
+ {
+ nodeRows[iRow1].push_back( quad->GetNode( helper.WrapIndex( iN2 + 2, 4 )));
+ nodeRows[iRow2].push_back( quad->GetNode( helper.WrapIndex( iN1 + 2, 4 )));
+ if ( quad->NbCornerNodes() != 4 )
+ return false;
+ }
+ }
+ if ( nodeRows[iRow1].size() < 3 )
+ return true; // there is nothing to fix
+ }
+
+ nodeRows.reserve( smDS->NbElements() / nodeRows[iRow1].size() );
+
+ // get the rest node rows
+ while ( true )
+ {
+ ++iRow1, ++iRow2;
+
+ // get the first quad in the next face row
+ if (( quad = SMESH_MeshAlgos::FindFaceInSet( nodeRows[iRow1][0],
+ nodeRows[iRow1][1],
+ allFaces, /*avoid=*/firstRowQuads,
+ &iN1, &iN2)))
+ {
+ if ( quad->NbCornerNodes() != 4 )
+ return false;
+ nodeRows.resize( iRow2+1 );
+ nodeRows[iRow2].push_back( quad->GetNode( helper.WrapIndex( iN2 + 2, 4 )));
+ nodeRows[iRow2].push_back( quad->GetNode( helper.WrapIndex( iN1 + 2, 4 )));
+ firstRowQuads.insert( quad );
+ }
+ else
+ {
+ break; // no more rows
+ }
+
+ // pass through the rest quads in a face row
+ while ( quad )
+ {
+ avoidSet.clear();
+ avoidSet.insert( quad );
+ if (( quad = SMESH_MeshAlgos::FindFaceInSet( nodeRows[iRow1][ nodeRows[iRow2].size()-1 ],
+ nodeRows[iRow2].back(),
+ allFaces, avoidSet, &iN1, &iN2)))
+ {
+ if ( quad->NbCornerNodes() != 4 )
+ return false;
+ nodeRows[iRow2].push_back( quad->GetNode( helper.WrapIndex( iN1 + 2, 4 )));
+ }
+ }
+ if ( nodeRows[iRow1].size() != nodeRows[iRow2].size() )
+ return false;
+ }
+ if ( nodeRows.size() < 3 )
+ return true; // there is nothing to fix
+
+ // get params of the first (bottom) and last (top) node rows
+ UVPtStructVec uvB( nodeRows[0].size() ), uvT( nodeRows[0].size() );
+ for ( int isBot = 0; isBot < 2; ++isBot )
+ {
+ UVPtStructVec & uvps = isBot ? uvB : uvT;
+ vector< const SMDS_MeshNode* >& nodes = nodeRows[ isBot ? 0 : nodeRows.size()-1 ];
+ for ( size_t i = 0; i < nodes.size(); ++i )
+ {
+ uvps[i].node = nodes[i];
+ gp_XY uv = helper.GetNodeUV( face, uvps[i].node );
+ uvps[i].u = uv.Coord(1);
+ uvps[i].v = uv.Coord(2);
+ uvps[i].x = 0;
+ }
+ // calculate x (normalized param)
+ for ( size_t i = 1; i < nodes.size(); ++i )
+ uvps[i].x = uvps[i-1].x + SMESH_TNodeXYZ( uvps[i-1].node ).Distance( uvps[i].node );
+ for ( size_t i = 1; i < nodes.size(); ++i )
+ uvps[i].x /= uvps.back().x;
+ }
+
+ // get params of the left and right node rows
+ UVPtStructVec uvL( nodeRows.size() ), uvR( nodeRows.size() );
+ for ( int isLeft = 0; isLeft < 2; ++isLeft )
+ {
+ UVPtStructVec & uvps = isLeft ? uvL : uvR;
+ const int iCol = isLeft ? 0 : nodeRows[0].size() - 1;
+ for ( size_t i = 0; i < nodeRows.size(); ++i )
+ {
+ uvps[i].node = nodeRows[i][iCol];
+ gp_XY uv = helper.GetNodeUV( face, uvps[i].node );
+ uvps[i].u = uv.Coord(1);
+ uvps[i].v = uv.Coord(2);
+ uvps[i].y = 0;
+ }
+ // calculate y (normalized param)
+ for ( size_t i = 1; i < nodeRows.size(); ++i )
+ uvps[i].y = uvps[i-1].y + SMESH_TNodeXYZ( uvps[i-1].node ).Distance( uvps[i].node );
+ for ( size_t i = 1; i < nodeRows.size(); ++i )
+ uvps[i].y /= uvps.back().y;
+ }
+
+ // update node coordinates
+ SMESHDS_Mesh* meshDS = mesh.GetMeshDS();
+ Handle(Geom_Surface) S = BRep_Tool::Surface( face );
+ gp_XY a0 ( uvB.front().u, uvB.front().v );
+ gp_XY a1 ( uvB.back().u, uvB.back().v );
+ gp_XY a2 ( uvT.back().u, uvT.back().v );
+ gp_XY a3 ( uvT.front().u, uvT.front().v );
+ for ( size_t iRow = 1; iRow < nodeRows.size()-1; ++iRow )
+ {
+ gp_XY p1 ( uvR[ iRow ].u, uvR[ iRow ].v );
+ gp_XY p3 ( uvL[ iRow ].u, uvL[ iRow ].v );
+ const double y0 = uvL[ iRow ].y;
+ const double y1 = uvR[ iRow ].y;
+ for ( size_t iCol = 1; iCol < nodeRows[0].size()-1; ++iCol )
+ {
+ gp_XY p0 ( uvB[ iCol ].u, uvB[ iCol ].v );
+ gp_XY p2 ( uvT[ iCol ].u, uvT[ iCol ].v );
+ const double x0 = uvB[ iCol ].x;
+ const double x1 = uvT[ iCol ].x;
+ double x = (x0 + y0 * (x1 - x0)) / (1 - (y1 - y0) * (x1 - x0));
+ double y = y0 + x * (y1 - y0);
+ gp_XY uv = helper.calcTFI( x, y, a0,a1,a2,a3, p0,p1,p2,p3 );
+ gp_Pnt p = S->Value( uv.Coord(1), uv.Coord(2));
+ const SMDS_MeshNode* n = nodeRows[iRow][iCol];
+ meshDS->MoveNode( n, p.X(), p.Y(), p.Z() );
+ if ( SMDS_FacePosition* pos = dynamic_cast< SMDS_FacePosition*>( n->GetPosition() ))
+ pos->SetParameters( uv.Coord(1), uv.Coord(2) );
+ }
+ }
+ return true;
+}