From: eap Date: Thu, 16 May 2013 16:35:18 +0000 (+0000) Subject: 0022098: EDF 2036 SMESH: Create groups from none conected parts of a mesh X-Git-Tag: V7_3_0a1~465 X-Git-Url: http://git.salome-platform.org/gitweb/?a=commitdiff_plain;h=b73a05d5eca9385dcc9156d3890b9d90bdac3f03;p=modules%2Fsmesh.git 0022098: EDF 2036 SMESH: Create groups from none conected parts of a mesh Move SMESH_ElementSearcher to from SMESH/SMESH_MeshEditor.hxx SMESHUtils/SMESH_MeshAlgos.hxx in order to make SMESH_ElementSearcher accessible from Controls/SMESH_Controls.cxx + SMESH_MeshAlgos.cxx --- diff --git a/src/SMESHUtils/Makefile.am b/src/SMESHUtils/Makefile.am index e01259e9f..414ab25ff 100644 --- a/src/SMESHUtils/Makefile.am +++ b/src/SMESHUtils/Makefile.am @@ -34,7 +34,8 @@ salomeinclude_HEADERS = \ SMESH_ComputeError.hxx \ SMESH_File.hxx \ SMESH_Utils.hxx \ - SMESH_TryCatch.hxx + SMESH_TryCatch.hxx \ + SMESH_MeshAlgos.hxx # Libraries targets @@ -46,7 +47,8 @@ dist_libSMESHUtils_la_SOURCES = \ SMESH_Octree.cxx \ SMESH_OctreeNode.cxx \ SMESH_TryCatch.cxx \ - SMESH_File.cxx + SMESH_File.cxx \ + SMESH_MeshAlgos.cxx # additionnal information to compile and link file libSMESHUtils_la_CPPFLAGS = \ diff --git a/src/SMESHUtils/SMESH_MeshAlgos.cxx b/src/SMESHUtils/SMESH_MeshAlgos.cxx new file mode 100644 index 000000000..d0d6008d3 --- /dev/null +++ b/src/SMESHUtils/SMESH_MeshAlgos.cxx @@ -0,0 +1,1531 @@ +// 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 +// +// This library is free software; you can redistribute it and/or +// modify it under the terms of the GNU Lesser General Public +// License as published by the Free Software Foundation; either +// version 2.1 of the License. +// +// This library is distributed in the hope that it will be useful, +// but WITHOUT ANY WARRANTY; without even the implied warranty of +// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU +// Lesser General Public License for more details. +// +// You should have received a copy of the GNU Lesser General Public +// License along with this library; if not, write to the Free Software +// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA +// +// See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com +// +// File : SMESH_MeshAlgos.hxx +// Created : Tue Apr 30 18:00:36 2013 +// Author : Edward AGAPOV (eap) + +// This file holds some low level algorithms extracted from SMESH_MeshEditor +// to make them accessible from Controls package + +#include "SMESH_MeshAlgos.hxx" + +#include "SMDS_LinearEdge.hxx" +#include "SMDS_VolumeTool.hxx" +#include "SMDS_Mesh.hxx" +#include "SMESH_OctreeNode.hxx" + +#include +#include +#include +#include +#include +#include +#include + +#include +#include + +using namespace std; + +//======================================================================= +/*! + * \brief Implementation of search for the node closest to point + */ +//======================================================================= + +struct SMESH_NodeSearcherImpl: public SMESH_NodeSearcher +{ + //--------------------------------------------------------------------- + /*! + * \brief Constructor + */ + SMESH_NodeSearcherImpl( const SMDS_Mesh* theMesh ) + { + myMesh = ( SMDS_Mesh* ) theMesh; + + TIDSortedNodeSet nodes; + if ( theMesh ) { + SMDS_NodeIteratorPtr nIt = theMesh->nodesIterator(/*idInceasingOrder=*/true); + while ( nIt->more() ) + nodes.insert( nodes.end(), nIt->next() ); + } + myOctreeNode = new SMESH_OctreeNode(nodes) ; + + // get max size of a leaf box + SMESH_OctreeNode* tree = myOctreeNode; + while ( !tree->isLeaf() ) + { + SMESH_OctreeNodeIteratorPtr cIt = tree->GetChildrenIterator(); + if ( cIt->more() ) + tree = cIt->next(); + } + myHalfLeafSize = tree->maxSize() / 2.; + } + + //--------------------------------------------------------------------- + /*! + * \brief Move node and update myOctreeNode accordingly + */ + void MoveNode( const SMDS_MeshNode* node, const gp_Pnt& toPnt ) + { + myOctreeNode->UpdateByMoveNode( node, toPnt ); + myMesh->MoveNode( node, toPnt.X(), toPnt.Y(), toPnt.Z() ); + } + + //--------------------------------------------------------------------- + /*! + * \brief Do it's job + */ + const SMDS_MeshNode* FindClosestTo( const gp_Pnt& thePnt ) + { + map dist2Nodes; + myOctreeNode->NodesAround( thePnt.Coord(), dist2Nodes, myHalfLeafSize ); + if ( !dist2Nodes.empty() ) + return dist2Nodes.begin()->second; + list nodes; + //myOctreeNode->NodesAround( &tgtNode, &nodes, myHalfLeafSize ); + + double minSqDist = DBL_MAX; + if ( nodes.empty() ) // get all nodes of OctreeNode's closest to thePnt + { + // sort leafs by their distance from thePnt + typedef map< double, SMESH_OctreeNode* > TDistTreeMap; + TDistTreeMap treeMap; + list< SMESH_OctreeNode* > treeList; + list< SMESH_OctreeNode* >::iterator trIt; + treeList.push_back( myOctreeNode ); + + gp_XYZ pointNode( thePnt.X(), thePnt.Y(), thePnt.Z() ); + bool pointInside = myOctreeNode->isInside( pointNode, myHalfLeafSize ); + for ( trIt = treeList.begin(); trIt != treeList.end(); ++trIt) + { + SMESH_OctreeNode* tree = *trIt; + if ( !tree->isLeaf() ) // put children to the queue + { + if ( pointInside && !tree->isInside( pointNode, myHalfLeafSize )) continue; + SMESH_OctreeNodeIteratorPtr cIt = tree->GetChildrenIterator(); + while ( cIt->more() ) + treeList.push_back( cIt->next() ); + } + else if ( tree->NbNodes() ) // put a tree to the treeMap + { + const Bnd_B3d& box = *tree->getBox(); + double sqDist = thePnt.SquareDistance( 0.5 * ( box.CornerMin() + box.CornerMax() )); + pair it_in = treeMap.insert( make_pair( sqDist, tree )); + if ( !it_in.second ) // not unique distance to box center + treeMap.insert( it_in.first, make_pair( sqDist + 1e-13*treeMap.size(), tree )); + } + } + // find distance after which there is no sense to check tree's + double sqLimit = DBL_MAX; + TDistTreeMap::iterator sqDist_tree = treeMap.begin(); + if ( treeMap.size() > 5 ) { + SMESH_OctreeNode* closestTree = sqDist_tree->second; + const Bnd_B3d& box = *closestTree->getBox(); + double limit = sqrt( sqDist_tree->first ) + sqrt ( box.SquareExtent() ); + sqLimit = limit * limit; + } + // get all nodes from trees + for ( ; sqDist_tree != treeMap.end(); ++sqDist_tree) { + if ( sqDist_tree->first > sqLimit ) + break; + SMESH_OctreeNode* tree = sqDist_tree->second; + tree->NodesAround( tree->GetNodeIterator()->next(), &nodes ); + } + } + // find closest among nodes + minSqDist = DBL_MAX; + const SMDS_MeshNode* closestNode = 0; + list::iterator nIt = nodes.begin(); + for ( ; nIt != nodes.end(); ++nIt ) { + double sqDist = thePnt.SquareDistance( SMESH_TNodeXYZ( *nIt ) ); + if ( minSqDist > sqDist ) { + closestNode = *nIt; + minSqDist = sqDist; + } + } + return closestNode; + } + + //--------------------------------------------------------------------- + /*! + * \brief Destructor + */ + ~SMESH_NodeSearcherImpl() { delete myOctreeNode; } + + //--------------------------------------------------------------------- + /*! + * \brief Return the node tree + */ + const SMESH_OctreeNode* getTree() const { return myOctreeNode; } + +private: + SMESH_OctreeNode* myOctreeNode; + SMDS_Mesh* myMesh; + double myHalfLeafSize; // max size of a leaf box +}; + +// ======================================================================== +namespace // Utils used in SMESH_ElementSearcherImpl::FindElementsByPoint() +{ + const int MaxNbElemsInLeaf = 10; // maximal number of elements in a leaf of tree + const int MaxLevel = 7; // maximal tree height -> nb terminal boxes: 8^7 = 2097152 + const double NodeRadius = 1e-9; // to enlarge bnd box of element + + //======================================================================= + /*! + * \brief Octal tree of bounding boxes of elements + */ + //======================================================================= + + class ElementBndBoxTree : public SMESH_Octree + { + public: + + ElementBndBoxTree(const SMDS_Mesh& mesh, + SMDSAbs_ElementType elemType, + SMDS_ElemIteratorPtr theElemIt = SMDS_ElemIteratorPtr(), + double tolerance = NodeRadius ); + void getElementsNearPoint( const gp_Pnt& point, TIDSortedElemSet& foundElems ); + void getElementsNearLine ( const gp_Ax1& line, TIDSortedElemSet& foundElems); + void getElementsInSphere ( const gp_XYZ& center, + const double radius, TIDSortedElemSet& foundElems); + size_t getSize() { return std::max( _size, _elements.size() ); } + ~ElementBndBoxTree(); + + protected: + ElementBndBoxTree():_size(0) {} + SMESH_Octree* newChild() const { return new ElementBndBoxTree; } + void buildChildrenData(); + Bnd_B3d* buildRootBox(); + private: + //!< Bounding box of element + struct ElementBox : public Bnd_B3d + { + const SMDS_MeshElement* _element; + int _refCount; // an ElementBox can be included in several tree branches + ElementBox(const SMDS_MeshElement* elem, double tolerance); + }; + vector< ElementBox* > _elements; + size_t _size; + }; + + //================================================================================ + /*! + * \brief ElementBndBoxTree creation + */ + //================================================================================ + + ElementBndBoxTree::ElementBndBoxTree(const SMDS_Mesh& mesh, SMDSAbs_ElementType elemType, SMDS_ElemIteratorPtr theElemIt, double tolerance) + :SMESH_Octree( new SMESH_TreeLimit( MaxLevel, /*minSize=*/0. )) + { + int nbElems = mesh.GetMeshInfo().NbElements( elemType ); + _elements.reserve( nbElems ); + + SMDS_ElemIteratorPtr elemIt = theElemIt ? theElemIt : mesh.elementsIterator( elemType ); + while ( elemIt->more() ) + _elements.push_back( new ElementBox( elemIt->next(),tolerance )); + + compute(); + } + + //================================================================================ + /*! + * \brief Destructor + */ + //================================================================================ + + ElementBndBoxTree::~ElementBndBoxTree() + { + for ( int i = 0; i < _elements.size(); ++i ) + if ( --_elements[i]->_refCount <= 0 ) + delete _elements[i]; + } + + //================================================================================ + /*! + * \brief Return the maximal box + */ + //================================================================================ + + Bnd_B3d* ElementBndBoxTree::buildRootBox() + { + Bnd_B3d* box = new Bnd_B3d; + for ( int i = 0; i < _elements.size(); ++i ) + box->Add( *_elements[i] ); + return box; + } + + //================================================================================ + /*! + * \brief Redistrubute element boxes among children + */ + //================================================================================ + + void ElementBndBoxTree::buildChildrenData() + { + for ( int i = 0; i < _elements.size(); ++i ) + { + for (int j = 0; j < 8; j++) + { + if ( !_elements[i]->IsOut( *myChildren[j]->getBox() )) + { + _elements[i]->_refCount++; + ((ElementBndBoxTree*)myChildren[j])->_elements.push_back( _elements[i]); + } + } + _elements[i]->_refCount--; + } + _size = _elements.size(); + SMESHUtils::FreeVector( _elements ); // = _elements.clear() + free memory + + for (int j = 0; j < 8; j++) + { + ElementBndBoxTree* child = static_cast( myChildren[j]); + if ( child->_elements.size() <= MaxNbElemsInLeaf ) + child->myIsLeaf = true; + + if ( child->_elements.capacity() - child->_elements.size() > 1000 ) + SMESHUtils::CompactVector( child->_elements ); + } + } + + //================================================================================ + /*! + * \brief Return elements which can include the point + */ + //================================================================================ + + void ElementBndBoxTree::getElementsNearPoint( const gp_Pnt& point, + TIDSortedElemSet& foundElems) + { + if ( getBox()->IsOut( point.XYZ() )) + return; + + if ( isLeaf() ) + { + for ( int i = 0; i < _elements.size(); ++i ) + if ( !_elements[i]->IsOut( point.XYZ() )) + foundElems.insert( _elements[i]->_element ); + } + else + { + for (int i = 0; i < 8; i++) + ((ElementBndBoxTree*) myChildren[i])->getElementsNearPoint( point, foundElems ); + } + } + + //================================================================================ + /*! + * \brief Return elements which can be intersected by the line + */ + //================================================================================ + + void ElementBndBoxTree::getElementsNearLine( const gp_Ax1& line, + TIDSortedElemSet& foundElems) + { + if ( getBox()->IsOut( line )) + return; + + if ( isLeaf() ) + { + for ( int i = 0; i < _elements.size(); ++i ) + if ( !_elements[i]->IsOut( line )) + foundElems.insert( _elements[i]->_element ); + } + else + { + for (int i = 0; i < 8; i++) + ((ElementBndBoxTree*) myChildren[i])->getElementsNearLine( line, foundElems ); + } + } + + //================================================================================ + /*! + * \brief Return elements from leaves intersecting the sphere + */ + //================================================================================ + + void ElementBndBoxTree::getElementsInSphere ( const gp_XYZ& center, + const double radius, + TIDSortedElemSet& foundElems) + { + if ( getBox()->IsOut( center, radius )) + return; + + if ( isLeaf() ) + { + for ( int i = 0; i < _elements.size(); ++i ) + if ( !_elements[i]->IsOut( center, radius )) + foundElems.insert( _elements[i]->_element ); + } + else + { + for (int i = 0; i < 8; i++) + ((ElementBndBoxTree*) myChildren[i])->getElementsInSphere( center, radius, foundElems ); + } + } + + //================================================================================ + /*! + * \brief Construct the element box + */ + //================================================================================ + + ElementBndBoxTree::ElementBox::ElementBox(const SMDS_MeshElement* elem, double tolerance) + { + _element = elem; + _refCount = 1; + SMDS_ElemIteratorPtr nIt = elem->nodesIterator(); + while ( nIt->more() ) + Add( SMESH_TNodeXYZ( nIt->next() )); + Enlarge( tolerance ); + } + +} // namespace + +//======================================================================= +/*! + * \brief Implementation of search for the elements by point and + * of classification of point in 2D mesh + */ +//======================================================================= + +struct SMESH_ElementSearcherImpl: public SMESH_ElementSearcher +{ + SMDS_Mesh* _mesh; + SMDS_ElemIteratorPtr _meshPartIt; + ElementBndBoxTree* _ebbTree; + SMESH_NodeSearcherImpl* _nodeSearcher; + SMDSAbs_ElementType _elementType; + double _tolerance; + bool _outerFacesFound; + set _outerFaces; // empty means "no internal faces at all" + + SMESH_ElementSearcherImpl( SMDS_Mesh& mesh, SMDS_ElemIteratorPtr elemIt=SMDS_ElemIteratorPtr()) + : _mesh(&mesh),_meshPartIt(elemIt),_ebbTree(0),_nodeSearcher(0),_tolerance(-1),_outerFacesFound(false) {} + ~SMESH_ElementSearcherImpl() + { + if ( _ebbTree ) delete _ebbTree; _ebbTree = 0; + if ( _nodeSearcher ) delete _nodeSearcher; _nodeSearcher = 0; + } + virtual int FindElementsByPoint(const gp_Pnt& point, + SMDSAbs_ElementType type, + vector< const SMDS_MeshElement* >& foundElements); + virtual TopAbs_State GetPointState(const gp_Pnt& point); + virtual const SMDS_MeshElement* FindClosestTo( const gp_Pnt& point, + SMDSAbs_ElementType type ); + + void GetElementsNearLine( const gp_Ax1& line, + SMDSAbs_ElementType type, + vector< const SMDS_MeshElement* >& foundElems); + double getTolerance(); + bool getIntersParamOnLine(const gp_Lin& line, const SMDS_MeshElement* face, + const double tolerance, double & param); + void findOuterBoundary(const SMDS_MeshElement* anyOuterFace); + bool isOuterBoundary(const SMDS_MeshElement* face) const + { + return _outerFaces.empty() || _outerFaces.count(face); + } + struct TInters //!< data of intersection of the line and the mesh face (used in GetPointState()) + { + const SMDS_MeshElement* _face; + gp_Vec _faceNorm; + bool _coincides; //!< the line lays in face plane + TInters(const SMDS_MeshElement* face, const gp_Vec& faceNorm, bool coinc=false) + : _face(face), _faceNorm( faceNorm ), _coincides( coinc ) {} + }; + struct TFaceLink //!< link and faces sharing it (used in findOuterBoundary()) + { + SMESH_TLink _link; + TIDSortedElemSet _faces; + TFaceLink( const SMDS_MeshNode* n1, const SMDS_MeshNode* n2, const SMDS_MeshElement* face) + : _link( n1, n2 ), _faces( &face, &face + 1) {} + }; +}; + +ostream& operator<< (ostream& out, const SMESH_ElementSearcherImpl::TInters& i) +{ + return out << "TInters(face=" << ( i._face ? i._face->GetID() : 0) + << ", _coincides="<GetMeshInfo(); + + _tolerance = 0; + if ( _nodeSearcher && meshInfo.NbNodes() > 1 ) + { + double boxSize = _nodeSearcher->getTree()->maxSize(); + _tolerance = 1e-8 * boxSize/* / meshInfo.NbNodes()*/; + } + else if ( _ebbTree && meshInfo.NbElements() > 0 ) + { + double boxSize = _ebbTree->maxSize(); + _tolerance = 1e-8 * boxSize/* / meshInfo.NbElements()*/; + } + if ( _tolerance == 0 ) + { + // define tolerance by size of a most complex element + int complexType = SMDSAbs_Volume; + while ( complexType > SMDSAbs_All && + meshInfo.NbElements( SMDSAbs_ElementType( complexType )) < 1 ) + --complexType; + if ( complexType == SMDSAbs_All ) return 0; // empty mesh + double elemSize; + if ( complexType == int( SMDSAbs_Node )) + { + SMDS_NodeIteratorPtr nodeIt = _mesh->nodesIterator(); + elemSize = 1; + if ( meshInfo.NbNodes() > 2 ) + elemSize = SMESH_TNodeXYZ( nodeIt->next() ).Distance( nodeIt->next() ); + } + else + { + SMDS_ElemIteratorPtr elemIt = + _mesh->elementsIterator( SMDSAbs_ElementType( complexType )); + const SMDS_MeshElement* elem = elemIt->next(); + SMDS_ElemIteratorPtr nodeIt = elem->nodesIterator(); + SMESH_TNodeXYZ n1( nodeIt->next() ); + elemSize = 0; + while ( nodeIt->more() ) + { + double dist = n1.Distance( static_cast( nodeIt->next() )); + elemSize = max( dist, elemSize ); + } + } + _tolerance = 1e-4 * elemSize; + } + } + return _tolerance; +} + +//================================================================================ +/*! + * \brief Find intersection of the line and an edge of face and return parameter on line + */ +//================================================================================ + +bool SMESH_ElementSearcherImpl::getIntersParamOnLine(const gp_Lin& line, + const SMDS_MeshElement* face, + const double tol, + double & param) +{ + int nbInts = 0; + param = 0; + + GeomAPI_ExtremaCurveCurve anExtCC; + Handle(Geom_Curve) lineCurve = new Geom_Line( line ); + + int nbNodes = face->IsQuadratic() ? face->NbNodes()/2 : face->NbNodes(); + for ( int i = 0; i < nbNodes && nbInts < 2; ++i ) + { + GC_MakeSegment edge( SMESH_TNodeXYZ( face->GetNode( i )), + SMESH_TNodeXYZ( face->GetNode( (i+1)%nbNodes) )); + anExtCC.Init( lineCurve, edge); + if ( anExtCC.NbExtrema() > 0 && anExtCC.LowerDistance() <= tol) + { + Quantity_Parameter pl, pe; + anExtCC.LowerDistanceParameters( pl, pe ); + param += pl; + if ( ++nbInts == 2 ) + break; + } + } + if ( nbInts > 0 ) param /= nbInts; + return nbInts > 0; +} +//================================================================================ +/*! + * \brief Find all faces belonging to the outer boundary of mesh + */ +//================================================================================ + +void SMESH_ElementSearcherImpl::findOuterBoundary(const SMDS_MeshElement* outerFace) +{ + if ( _outerFacesFound ) return; + + // Collect all outer faces by passing from one outer face to another via their links + // and BTW find out if there are internal faces at all. + + // checked links and links where outer boundary meets internal one + set< SMESH_TLink > visitedLinks, seamLinks; + + // links to treat with already visited faces sharing them + list < TFaceLink > startLinks; + + // load startLinks with the first outerFace + startLinks.push_back( TFaceLink( outerFace->GetNode(0), outerFace->GetNode(1), outerFace)); + _outerFaces.insert( outerFace ); + + TIDSortedElemSet emptySet; + while ( !startLinks.empty() ) + { + const SMESH_TLink& link = startLinks.front()._link; + TIDSortedElemSet& faces = startLinks.front()._faces; + + outerFace = *faces.begin(); + // find other faces sharing the link + const SMDS_MeshElement* f; + while (( f = SMESH_MeshAlgos::FindFaceInSet(link.node1(), link.node2(), emptySet, faces ))) + faces.insert( f ); + + // select another outer face among the found + const SMDS_MeshElement* outerFace2 = 0; + if ( faces.size() == 2 ) + { + outerFace2 = (outerFace == *faces.begin() ? *faces.rbegin() : *faces.begin()); + } + else if ( faces.size() > 2 ) + { + seamLinks.insert( link ); + + // link direction within the outerFace + gp_Vec n1n2( SMESH_TNodeXYZ( link.node1()), + SMESH_TNodeXYZ( link.node2())); + int i1 = outerFace->GetNodeIndex( link.node1() ); + int i2 = outerFace->GetNodeIndex( link.node2() ); + bool rev = ( abs(i2-i1) == 1 ? i1 > i2 : i2 > i1 ); + if ( rev ) n1n2.Reverse(); + // outerFace normal + gp_XYZ ofNorm, fNorm; + if ( SMESH_MeshAlgos::FaceNormal( outerFace, ofNorm, /*normalized=*/false )) + { + // direction from the link inside outerFace + gp_Vec dirInOF = gp_Vec( ofNorm ) ^ n1n2; + // sort all other faces by angle with the dirInOF + map< double, const SMDS_MeshElement* > angle2Face; + set< const SMDS_MeshElement*, TIDCompare >::const_iterator face = faces.begin(); + for ( ; face != faces.end(); ++face ) + { + if ( !SMESH_MeshAlgos::FaceNormal( *face, fNorm, /*normalized=*/false )) + continue; + gp_Vec dirInF = gp_Vec( fNorm ) ^ n1n2; + double angle = dirInOF.AngleWithRef( dirInF, n1n2 ); + if ( angle < 0 ) angle += 2. * M_PI; + angle2Face.insert( make_pair( angle, *face )); + } + if ( !angle2Face.empty() ) + outerFace2 = angle2Face.begin()->second; + } + } + // store the found outer face and add its links to continue seaching from + if ( outerFace2 ) + { + _outerFaces.insert( outerFace ); + int nbNodes = outerFace2->NbNodes()/( outerFace2->IsQuadratic() ? 2 : 1 ); + for ( int i = 0; i < nbNodes; ++i ) + { + SMESH_TLink link2( outerFace2->GetNode(i), outerFace2->GetNode((i+1)%nbNodes)); + if ( visitedLinks.insert( link2 ).second ) + startLinks.push_back( TFaceLink( link2.node1(), link2.node2(), outerFace2 )); + } + } + startLinks.pop_front(); + } + _outerFacesFound = true; + + if ( !seamLinks.empty() ) + { + // There are internal boundaries touching the outher one, + // find all faces of internal boundaries in order to find + // faces of boundaries of holes, if any. + + } + else + { + _outerFaces.clear(); + } +} + +//======================================================================= +/*! + * \brief Find elements of given type where the given point is IN or ON. + * Returns nb of found elements and elements them-selves. + * + * 'ALL' type means elements of any type excluding nodes, balls and 0D elements + */ +//======================================================================= + +int SMESH_ElementSearcherImpl:: +FindElementsByPoint(const gp_Pnt& point, + SMDSAbs_ElementType type, + vector< const SMDS_MeshElement* >& foundElements) +{ + foundElements.clear(); + + double tolerance = getTolerance(); + + // ================================================================================= + if ( type == SMDSAbs_Node || type == SMDSAbs_0DElement || type == SMDSAbs_Ball) + { + if ( !_nodeSearcher ) + _nodeSearcher = new SMESH_NodeSearcherImpl( _mesh ); + + const SMDS_MeshNode* closeNode = _nodeSearcher->FindClosestTo( point ); + if ( !closeNode ) return foundElements.size(); + + if ( point.Distance( SMESH_TNodeXYZ( closeNode )) > tolerance ) + return foundElements.size(); // to far from any node + + if ( type == SMDSAbs_Node ) + { + foundElements.push_back( closeNode ); + } + else + { + SMDS_ElemIteratorPtr elemIt = closeNode->GetInverseElementIterator( type ); + while ( elemIt->more() ) + foundElements.push_back( elemIt->next() ); + } + } + // ================================================================================= + else // elements more complex than 0D + { + if ( !_ebbTree || _elementType != type ) + { + if ( _ebbTree ) delete _ebbTree; + _ebbTree = new ElementBndBoxTree( *_mesh, _elementType = type, _meshPartIt, tolerance ); + } + TIDSortedElemSet suspectElems; + _ebbTree->getElementsNearPoint( point, suspectElems ); + TIDSortedElemSet::iterator elem = suspectElems.begin(); + for ( ; elem != suspectElems.end(); ++elem ) + if ( !SMESH_MeshAlgos::IsOut( *elem, point, tolerance )) + foundElements.push_back( *elem ); + } + return foundElements.size(); +} + +//======================================================================= +/*! + * \brief Find an element of given type most close to the given point + * + * WARNING: Only face search is implemeneted so far + */ +//======================================================================= + +const SMDS_MeshElement* +SMESH_ElementSearcherImpl::FindClosestTo( const gp_Pnt& point, + SMDSAbs_ElementType type ) +{ + const SMDS_MeshElement* closestElem = 0; + + if ( type == SMDSAbs_Face ) + { + if ( !_ebbTree || _elementType != type ) + { + if ( _ebbTree ) delete _ebbTree; + _ebbTree = new ElementBndBoxTree( *_mesh, _elementType = type, _meshPartIt ); + } + TIDSortedElemSet suspectElems; + _ebbTree->getElementsNearPoint( point, suspectElems ); + + if ( suspectElems.empty() && _ebbTree->maxSize() > 0 ) + { + gp_Pnt boxCenter = 0.5 * ( _ebbTree->getBox()->CornerMin() + + _ebbTree->getBox()->CornerMax() ); + double radius; + if ( _ebbTree->getBox()->IsOut( point.XYZ() )) + radius = point.Distance( boxCenter ) - 0.5 * _ebbTree->maxSize(); + else + radius = _ebbTree->maxSize() / pow( 2., _ebbTree->getHeight()) / 2; + while ( suspectElems.empty() ) + { + _ebbTree->getElementsInSphere( point.XYZ(), radius, suspectElems ); + radius *= 1.1; + } + } + double minDist = std::numeric_limits::max(); + multimap< double, const SMDS_MeshElement* > dist2face; + TIDSortedElemSet::iterator elem = suspectElems.begin(); + for ( ; elem != suspectElems.end(); ++elem ) + { + double dist = SMESH_MeshAlgos::GetDistance( dynamic_cast(*elem), + point ); + if ( dist < minDist + 1e-10) + { + minDist = dist; + dist2face.insert( dist2face.begin(), make_pair( dist, *elem )); + } + } + if ( !dist2face.empty() ) + { + multimap< double, const SMDS_MeshElement* >::iterator d2f = dist2face.begin(); + closestElem = d2f->second; + // if there are several elements at the same distance, select one + // with GC closest to the point + typedef SMDS_StdIterator< SMESH_TNodeXYZ, SMDS_ElemIteratorPtr > TXyzIterator; + double minDistToGC = 0; + for ( ++d2f; d2f != dist2face.end() && fabs( d2f->first - minDist ) < 1e-10; ++d2f ) + { + if ( minDistToGC == 0 ) + { + gp_XYZ gc(0,0,0); + gc = accumulate( TXyzIterator(closestElem->nodesIterator()), + TXyzIterator(), gc ) / closestElem->NbNodes(); + minDistToGC = point.SquareDistance( gc ); + } + gp_XYZ gc(0,0,0); + gc = accumulate( TXyzIterator( d2f->second->nodesIterator()), + TXyzIterator(), gc ) / d2f->second->NbNodes(); + double d = point.SquareDistance( gc ); + if ( d < minDistToGC ) + { + minDistToGC = d; + closestElem = d2f->second; + } + } + // cout << "FindClosestTo( " <GetID() << " DIST " << minDist << endl; + } + } + else + { + // NOT IMPLEMENTED SO FAR + } + return closestElem; +} + + +//================================================================================ +/*! + * \brief Classify the given point in the closed 2D mesh + */ +//================================================================================ + +TopAbs_State SMESH_ElementSearcherImpl::GetPointState(const gp_Pnt& point) +{ + double tolerance = getTolerance(); + if ( !_ebbTree || _elementType != SMDSAbs_Face ) + { + if ( _ebbTree ) delete _ebbTree; + _ebbTree = new ElementBndBoxTree( *_mesh, _elementType = SMDSAbs_Face, _meshPartIt ); + } + // Algo: analyse transition of a line starting at the point through mesh boundary; + // try three lines parallel to axis of the coordinate system and perform rough + // analysis. If solution is not clear perform thorough analysis. + + const int nbAxes = 3; + gp_Dir axisDir[ nbAxes ] = { gp::DX(), gp::DY(), gp::DZ() }; + map< double, TInters > paramOnLine2TInters[ nbAxes ]; + list< TInters > tangentInters[ nbAxes ]; // of faces whose plane includes the line + multimap< int, int > nbInt2Axis; // to find the simplest case + for ( int axis = 0; axis < nbAxes; ++axis ) + { + gp_Ax1 lineAxis( point, axisDir[axis]); + gp_Lin line ( lineAxis ); + + TIDSortedElemSet suspectFaces; // faces possibly intersecting the line + _ebbTree->getElementsNearLine( lineAxis, suspectFaces ); + + // Intersect faces with the line + + map< double, TInters > & u2inters = paramOnLine2TInters[ axis ]; + TIDSortedElemSet::iterator face = suspectFaces.begin(); + for ( ; face != suspectFaces.end(); ++face ) + { + // get face plane + gp_XYZ fNorm; + if ( !SMESH_MeshAlgos::FaceNormal( *face, fNorm, /*normalized=*/false)) continue; + gp_Pln facePlane( SMESH_TNodeXYZ( (*face)->GetNode(0)), fNorm ); + + // perform intersection + IntAna_IntConicQuad intersection( line, IntAna_Quadric( facePlane )); + if ( !intersection.IsDone() ) + continue; + if ( intersection.IsInQuadric() ) + { + tangentInters[ axis ].push_back( TInters( *face, fNorm, true )); + } + else if ( ! intersection.IsParallel() && intersection.NbPoints() > 0 ) + { + gp_Pnt intersectionPoint = intersection.Point(1); + if ( !SMESH_MeshAlgos::IsOut( *face, intersectionPoint, tolerance )) + u2inters.insert(make_pair( intersection.ParamOnConic(1), TInters( *face, fNorm ))); + } + } + // Analyse intersections roughly + + int nbInter = u2inters.size(); + if ( nbInter == 0 ) + return TopAbs_OUT; + + double f = u2inters.begin()->first, l = u2inters.rbegin()->first; + if ( nbInter == 1 ) // not closed mesh + return fabs( f ) < tolerance ? TopAbs_ON : TopAbs_UNKNOWN; + + if ( fabs( f ) < tolerance || fabs( l ) < tolerance ) + return TopAbs_ON; + + if ( (f<0) == (l<0) ) + return TopAbs_OUT; + + int nbIntBeforePoint = std::distance( u2inters.begin(), u2inters.lower_bound(0)); + int nbIntAfterPoint = nbInter - nbIntBeforePoint; + if ( nbIntBeforePoint == 1 || nbIntAfterPoint == 1 ) + return TopAbs_IN; + + nbInt2Axis.insert( make_pair( min( nbIntBeforePoint, nbIntAfterPoint ), axis )); + + if ( _outerFacesFound ) break; // pass to thorough analysis + + } // three attempts - loop on CS axes + + // Analyse intersections thoroughly. + // We make two loops maximum, on the first one we only exclude touching intersections, + // on the second, if situation is still unclear, we gather and use information on + // position of faces (internal or outer). If faces position is already gathered, + // we make the second loop right away. + + for ( int hasPositionInfo = _outerFacesFound; hasPositionInfo < 2; ++hasPositionInfo ) + { + multimap< int, int >::const_iterator nb_axis = nbInt2Axis.begin(); + for ( ; nb_axis != nbInt2Axis.end(); ++nb_axis ) + { + int axis = nb_axis->second; + map< double, TInters > & u2inters = paramOnLine2TInters[ axis ]; + + gp_Ax1 lineAxis( point, axisDir[axis]); + gp_Lin line ( lineAxis ); + + // add tangent intersections to u2inters + double param; + list< TInters >::const_iterator tgtInt = tangentInters[ axis ].begin(); + for ( ; tgtInt != tangentInters[ axis ].end(); ++tgtInt ) + if ( getIntersParamOnLine( line, tgtInt->_face, tolerance, param )) + u2inters.insert(make_pair( param, *tgtInt )); + tangentInters[ axis ].clear(); + + // Count intersections before and after the point excluding touching ones. + // If hasPositionInfo we count intersections of outer boundary only + + int nbIntBeforePoint = 0, nbIntAfterPoint = 0; + double f = numeric_limits::max(), l = -numeric_limits::max(); + map< double, TInters >::iterator u_int1 = u2inters.begin(), u_int2 = u_int1; + bool ok = ! u_int1->second._coincides; + while ( ok && u_int1 != u2inters.end() ) + { + double u = u_int1->first; + bool touchingInt = false; + if ( ++u_int2 != u2inters.end() ) + { + // skip intersections at the same point (if the line passes through edge or node) + int nbSamePnt = 0; + while ( u_int2 != u2inters.end() && fabs( u_int2->first - u ) < tolerance ) + { + ++nbSamePnt; + ++u_int2; + } + + // skip tangent intersections + int nbTgt = 0; + const SMDS_MeshElement* prevFace = u_int1->second._face; + while ( ok && u_int2->second._coincides ) + { + if ( SMESH_MeshAlgos::GetCommonNodes(prevFace , u_int2->second._face).empty() ) + ok = false; + else + { + nbTgt++; + u_int2++; + ok = ( u_int2 != u2inters.end() ); + } + } + if ( !ok ) break; + + // skip intersections at the same point after tangent intersections + if ( nbTgt > 0 ) + { + double u2 = u_int2->first; + ++u_int2; + while ( u_int2 != u2inters.end() && fabs( u_int2->first - u2 ) < tolerance ) + { + ++nbSamePnt; + ++u_int2; + } + } + // decide if we skipped a touching intersection + if ( nbSamePnt + nbTgt > 0 ) + { + double minDot = numeric_limits::max(), maxDot = -numeric_limits::max(); + map< double, TInters >::iterator u_int = u_int1; + for ( ; u_int != u_int2; ++u_int ) + { + if ( u_int->second._coincides ) continue; + double dot = u_int->second._faceNorm * line.Direction(); + if ( dot > maxDot ) maxDot = dot; + if ( dot < minDot ) minDot = dot; + } + touchingInt = ( minDot*maxDot < 0 ); + } + } + if ( !touchingInt ) + { + if ( !hasPositionInfo || isOuterBoundary( u_int1->second._face )) + { + if ( u < 0 ) + ++nbIntBeforePoint; + else + ++nbIntAfterPoint; + } + if ( u < f ) f = u; + if ( u > l ) l = u; + } + + u_int1 = u_int2; // to next intersection + + } // loop on intersections with one line + + if ( ok ) + { + if ( fabs( f ) < tolerance || fabs( l ) < tolerance ) + return TopAbs_ON; + + if ( nbIntBeforePoint == 0 || nbIntAfterPoint == 0) + return TopAbs_OUT; + + if ( nbIntBeforePoint + nbIntAfterPoint == 1 ) // not closed mesh + return fabs( f ) < tolerance ? TopAbs_ON : TopAbs_UNKNOWN; + + if ( nbIntBeforePoint == 1 || nbIntAfterPoint == 1 ) + return TopAbs_IN; + + if ( (f<0) == (l<0) ) + return TopAbs_OUT; + + if ( hasPositionInfo ) + return nbIntBeforePoint % 2 ? TopAbs_IN : TopAbs_OUT; + } + } // loop on intersections of the tree lines - thorough analysis + + if ( !hasPositionInfo ) + { + // gather info on faces position - is face in the outer boundary or not + map< double, TInters > & u2inters = paramOnLine2TInters[ 0 ]; + findOuterBoundary( u2inters.begin()->second._face ); + } + + } // two attempts - with and w/o faces position info in the mesh + + return TopAbs_UNKNOWN; +} + +//======================================================================= +/*! + * \brief Return elements possibly intersecting the line + */ +//======================================================================= + +void SMESH_ElementSearcherImpl::GetElementsNearLine( const gp_Ax1& line, + SMDSAbs_ElementType type, + vector< const SMDS_MeshElement* >& foundElems) +{ + if ( !_ebbTree || _elementType != type ) + { + if ( _ebbTree ) delete _ebbTree; + _ebbTree = new ElementBndBoxTree( *_mesh, _elementType = type, _meshPartIt ); + } + TIDSortedElemSet suspectFaces; // elements possibly intersecting the line + _ebbTree->getElementsNearLine( line, suspectFaces ); + foundElems.assign( suspectFaces.begin(), suspectFaces.end()); +} + +//======================================================================= +/*! + * \brief Return true if the point is IN or ON of the element + */ +//======================================================================= + +bool SMESH_MeshAlgos::IsOut( const SMDS_MeshElement* element, const gp_Pnt& point, double tol ) +{ + if ( element->GetType() == SMDSAbs_Volume) + { + return SMDS_VolumeTool( element ).IsOut( point.X(), point.Y(), point.Z(), tol ); + } + + // get ordered nodes + + vector< gp_XYZ > xyz; + vector nodeList; + + SMDS_ElemIteratorPtr nodeIt = element->nodesIterator(); + if ( element->IsQuadratic() ) { + nodeIt = element->interlacedNodesElemIterator(); + // if (const SMDS_VtkFace* f=dynamic_cast(element)) + // nodeIt = f->interlacedNodesElemIterator(); + // else if (const SMDS_VtkEdge* e =dynamic_cast(element)) + // nodeIt = e->interlacedNodesElemIterator(); + } + while ( nodeIt->more() ) + { + SMESH_TNodeXYZ node = nodeIt->next(); + xyz.push_back( node ); + nodeList.push_back(node._node); + } + + int i, nbNodes = (int) nodeList.size(); // central node of biquadratic is missing + + if ( element->GetType() == SMDSAbs_Face ) // -------------------------------------------------- + { + // compute face normal + gp_Vec faceNorm(0,0,0); + xyz.push_back( xyz.front() ); + nodeList.push_back( nodeList.front() ); + for ( i = 0; i < nbNodes; ++i ) + { + gp_Vec edge1( xyz[i+1], xyz[i]); + gp_Vec edge2( xyz[i+1], xyz[(i+2)%nbNodes] ); + faceNorm += edge1 ^ edge2; + } + double normSize = faceNorm.Magnitude(); + if ( normSize <= tol ) + { + // degenerated face: point is out if it is out of all face edges + for ( i = 0; i < nbNodes; ++i ) + { + SMDS_LinearEdge edge( nodeList[i], nodeList[i+1] ); + if ( !IsOut( &edge, point, tol )) + return false; + } + return true; + } + faceNorm /= normSize; + + // check if the point lays on face plane + gp_Vec n2p( xyz[0], point ); + if ( fabs( n2p * faceNorm ) > tol ) + return true; // not on face plane + + // check if point is out of face boundary: + // define it by closest transition of a ray point->infinity through face boundary + // on the face plane. + // First, find normal of a plane perpendicular to face plane, to be used as a cutting tool + // to find intersections of the ray with the boundary. + gp_Vec ray = n2p; + gp_Vec plnNorm = ray ^ faceNorm; + normSize = plnNorm.Magnitude(); + if ( normSize <= tol ) return false; // point coincides with the first node + plnNorm /= normSize; + // for each node of the face, compute its signed distance to the plane + vector dist( nbNodes + 1); + for ( i = 0; i < nbNodes; ++i ) + { + gp_Vec n2p( xyz[i], point ); + dist[i] = n2p * plnNorm; + } + dist.back() = dist.front(); + // find the closest intersection + int iClosest = -1; + double rClosest, distClosest = 1e100;; + gp_Pnt pClosest; + for ( i = 0; i < nbNodes; ++i ) + { + double r; + if ( fabs( dist[i]) < tol ) + r = 0.; + else if ( fabs( dist[i+1]) < tol ) + r = 1.; + else if ( dist[i] * dist[i+1] < 0 ) + r = dist[i] / ( dist[i] - dist[i+1] ); + else + continue; // no intersection + gp_Pnt pInt = xyz[i] * (1.-r) + xyz[i+1] * r; + gp_Vec p2int ( point, pInt); + if ( p2int * ray > -tol ) // right half-space + { + double intDist = p2int.SquareMagnitude(); + if ( intDist < distClosest ) + { + iClosest = i; + rClosest = r; + pClosest = pInt; + distClosest = intDist; + } + } + } + if ( iClosest < 0 ) + return true; // no intesections - out + + // analyse transition + gp_Vec edge( xyz[iClosest], xyz[iClosest+1] ); + gp_Vec edgeNorm = -( edge ^ faceNorm ); // normal to intersected edge pointing out of face + gp_Vec p2int ( point, pClosest ); + bool out = (edgeNorm * p2int) < -tol; + if ( rClosest > 0. && rClosest < 1. ) // not node intersection + return out; + + // ray pass through a face node; analyze transition through an adjacent edge + gp_Pnt p1 = xyz[ (rClosest == 0.) ? ((iClosest+nbNodes-1) % nbNodes) : (iClosest+1) ]; + gp_Pnt p2 = xyz[ (rClosest == 0.) ? iClosest : ((iClosest+2) % nbNodes) ]; + gp_Vec edgeAdjacent( p1, p2 ); + gp_Vec edgeNorm2 = -( edgeAdjacent ^ faceNorm ); + bool out2 = (edgeNorm2 * p2int) < -tol; + + bool covexCorner = ( edgeNorm * edgeAdjacent * (rClosest==1. ? 1. : -1.)) < 0; + return covexCorner ? (out || out2) : (out && out2); + } + if ( element->GetType() == SMDSAbs_Edge ) // -------------------------------------------------- + { + // point is out of edge if it is NOT ON any straight part of edge + // (we consider quadratic edge as being composed of two straight parts) + for ( i = 1; i < nbNodes; ++i ) + { + gp_Vec edge( xyz[i-1], xyz[i]); + gp_Vec n1p ( xyz[i-1], point); + double dist = ( edge ^ n1p ).Magnitude() / edge.Magnitude(); + if ( dist > tol ) + continue; + gp_Vec n2p( xyz[i], point ); + if ( fabs( edge.Magnitude() - n1p.Magnitude() - n2p.Magnitude()) > tol ) + continue; + return false; // point is ON this part + } + return true; + } + // Node or 0D element ------------------------------------------------------------------------- + { + gp_Vec n2p ( xyz[0], point ); + return n2p.Magnitude() <= tol; + } + return true; +} + +//======================================================================= +namespace +{ + // Position of a point relative to a segment + // . . + // . LEFT . + // . . + // VERTEX 1 o----ON-----> VERTEX 2 + // . . + // . RIGHT . + // . . + enum PositionName { POS_LEFT = 1, POS_VERTEX = 2, POS_RIGHT = 4, //POS_ON = 8, + POS_ALL = POS_LEFT | POS_RIGHT | POS_VERTEX }; + struct PointPos + { + PositionName _name; + int _index; // index of vertex or segment + + PointPos( PositionName n, int i=-1 ): _name(n), _index(i) {} + bool operator < (const PointPos& other ) const + { + if ( _name == other._name ) + return ( _index < 0 || other._index < 0 ) ? false : _index < other._index; + return _name < other._name; + } + }; + + //================================================================================ + /*! + * \brief Return of a point relative to a segment + * \param point2D - the point to analyze position of + * \param xyVec - end points of segments + * \param index0 - 0-based index of the first point of segment + * \param posToFindOut - flags of positions to detect + * \retval PointPos - point position + */ + //================================================================================ + + PointPos getPointPosition( const gp_XY& point2D, + const gp_XY* segEnds, + const int index0 = 0, + const int posToFindOut = POS_ALL) + { + const gp_XY& p1 = segEnds[ index0 ]; + const gp_XY& p2 = segEnds[ index0+1 ]; + const gp_XY grad = p2 - p1; + + if ( posToFindOut & POS_VERTEX ) + { + // check if the point2D is at "vertex 1" zone + gp_XY pp1[2] = { p1, gp_XY( p1.X() - grad.Y(), + p1.Y() + grad.X() ) }; + if ( getPointPosition( point2D, pp1, 0, POS_LEFT|POS_RIGHT )._name == POS_LEFT ) + return PointPos( POS_VERTEX, index0 ); + + // check if the point2D is at "vertex 2" zone + gp_XY pp2[2] = { p2, gp_XY( p2.X() - grad.Y(), + p2.Y() + grad.X() ) }; + if ( getPointPosition( point2D, pp2, 0, POS_LEFT|POS_RIGHT )._name == POS_RIGHT ) + return PointPos( POS_VERTEX, index0 + 1); + } + double edgeEquation = + ( point2D.X() - p1.X() ) * grad.Y() - ( point2D.Y() - p1.Y() ) * grad.X(); + return PointPos( edgeEquation < 0 ? POS_LEFT : POS_RIGHT, index0 ); + } +} + +//======================================================================= +/*! + * \brief Return minimal distance from a point to a face + * + * Currently we ignore non-planarity and 2nd order of face + */ +//======================================================================= + +double SMESH_MeshAlgos::GetDistance( const SMDS_MeshFace* face, + const gp_Pnt& point ) +{ + double badDistance = -1; + if ( !face ) return badDistance; + + // coordinates of nodes (medium nodes, if any, ignored) + typedef SMDS_StdIterator< SMESH_TNodeXYZ, SMDS_ElemIteratorPtr > TXyzIterator; + vector xyz( TXyzIterator( face->nodesIterator()), TXyzIterator() ); + xyz.resize( face->NbCornerNodes()+1 ); + + // transformation to get xyz[0] lies on the origin, xyz[1] lies on the Z axis, + // and xyz[2] lies in the XZ plane. This is to pass to 2D space on XZ plane. + gp_Trsf trsf; + gp_Vec OZ ( xyz[0], xyz[1] ); + gp_Vec OX ( xyz[0], xyz[2] ); + if ( OZ.Magnitude() < std::numeric_limits::min() ) + { + if ( xyz.size() < 4 ) return badDistance; + OZ = gp_Vec ( xyz[0], xyz[2] ); + OX = gp_Vec ( xyz[0], xyz[3] ); + } + gp_Ax3 tgtCS; + try { + tgtCS = gp_Ax3( xyz[0], OZ, OX ); + } + catch ( Standard_Failure ) { + return badDistance; + } + trsf.SetTransformation( tgtCS ); + + // move all the nodes to 2D + vector xy( xyz.size() ); + for ( size_t i = 0;i < xyz.size()-1; ++i ) + { + gp_XYZ p3d = xyz[i]; + trsf.Transforms( p3d ); + xy[i].SetCoord( p3d.X(), p3d.Z() ); + } + xyz.back() = xyz.front(); + xy.back() = xy.front(); + + // // move the point in 2D + gp_XYZ tmpPnt = point.XYZ(); + trsf.Transforms( tmpPnt ); + gp_XY point2D( tmpPnt.X(), tmpPnt.Z() ); + + // loop on segments of the face to analyze point position ralative to the face + set< PointPos > pntPosSet; + for ( size_t i = 1; i < xy.size(); ++i ) + { + PointPos pos = getPointPosition( point2D, &xy[0], i-1 ); + pntPosSet.insert( pos ); + } + + // compute distance + PointPos pos = *pntPosSet.begin(); + // cout << "Face " << face->GetID() << " DIST: "; + switch ( pos._name ) + { + case POS_LEFT: { + // point is most close to a segment + gp_Vec p0p1( point, xyz[ pos._index ] ); + gp_Vec p1p2( xyz[ pos._index ], xyz[ pos._index+1 ]); // segment vector + p1p2.Normalize(); + double projDist = p0p1 * p1p2; // distance projected to the segment + gp_Vec projVec = p1p2 * projDist; + gp_Vec distVec = p0p1 - projVec; + // cout << distVec.Magnitude() << ", SEG " << face->GetNode(pos._index)->GetID() + // << " - " << face->GetNodeWrap(pos._index+1)->GetID() << endl; + return distVec.Magnitude(); + } + case POS_RIGHT: { + // point is inside the face + double distToFacePlane = tmpPnt.Y(); + // cout << distToFacePlane << ", INSIDE " << endl; + return Abs( distToFacePlane ); + } + case POS_VERTEX: { + // point is most close to a node + gp_Vec distVec( point, xyz[ pos._index ]); + // cout << distVec.Magnitude() << " VERTEX " << face->GetNode(pos._index)->GetID() << endl; + return distVec.Magnitude(); + } + } + return badDistance; +} + +//======================================================================= +//function : FindFaceInSet +//purpose : Return a face having linked nodes n1 and n2 and which is +// - not in avoidSet, +// - in elemSet provided that !elemSet.empty() +// i1 and i2 optionally returns indices of n1 and n2 +//======================================================================= + +const SMDS_MeshElement* +SMESH_MeshAlgos::FindFaceInSet(const SMDS_MeshNode* n1, + const SMDS_MeshNode* n2, + const TIDSortedElemSet& elemSet, + const TIDSortedElemSet& avoidSet, + int* n1ind, + int* n2ind) + +{ + int i1, i2; + const SMDS_MeshElement* face = 0; + + SMDS_ElemIteratorPtr invElemIt = n1->GetInverseElementIterator(SMDSAbs_Face); + //MESSAGE("n1->GetInverseElementIterator(SMDSAbs_Face) " << invElemIt); + while ( invElemIt->more() && !face ) // loop on inverse faces of n1 + { + //MESSAGE("in while ( invElemIt->more() && !face )"); + const SMDS_MeshElement* elem = invElemIt->next(); + if (avoidSet.count( elem )) + continue; + if ( !elemSet.empty() && !elemSet.count( elem )) + continue; + // index of n1 + i1 = elem->GetNodeIndex( n1 ); + // find a n2 linked to n1 + int nbN = elem->IsQuadratic() ? elem->NbNodes()/2 : elem->NbNodes(); + for ( int di = -1; di < 2 && !face; di += 2 ) + { + i2 = (i1+di+nbN) % nbN; + if ( elem->GetNode( i2 ) == n2 ) + face = elem; + } + if ( !face && elem->IsQuadratic()) + { + // analysis for quadratic elements using all nodes + // const SMDS_VtkFace* F = dynamic_cast(elem); + // if (!F) throw SALOME_Exception(LOCALIZED("not an SMDS_VtkFace")); + // use special nodes iterator + SMDS_ElemIteratorPtr anIter = elem->interlacedNodesElemIterator(); + const SMDS_MeshNode* prevN = static_cast( anIter->next() ); + for ( i1 = -1, i2 = 0; anIter->more() && !face; i1++, i2++ ) + { + const SMDS_MeshNode* n = static_cast( anIter->next() ); + if ( n1 == prevN && n2 == n ) + { + face = elem; + } + else if ( n2 == prevN && n1 == n ) + { + face = elem; swap( i1, i2 ); + } + prevN = n; + } + } + } + if ( n1ind ) *n1ind = i1; + if ( n2ind ) *n2ind = i2; + return face; +} + +//================================================================================ +/*! + * \brief Calculate normal of a mesh face + */ +//================================================================================ + +bool SMESH_MeshAlgos::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::min() * numeric_limits::min()); + if ( normalized && ok ) + normal /= sqrt( size2 ); + + return ok; +} + +//======================================================================= +//function : GetCommonNodes +//purpose : Return nodes common to two elements +//======================================================================= + +vector< const SMDS_MeshNode*> SMESH_MeshAlgos::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; +} + +//======================================================================= +/*! + * \brief Return SMESH_NodeSearcher + */ +//======================================================================= + +SMESH_NodeSearcher* SMESH_MeshAlgos::GetNodeSearcher(SMDS_Mesh& mesh) +{ + return new SMESH_NodeSearcherImpl( &mesh ); +} + +//======================================================================= +/*! + * \brief Return SMESH_ElementSearcher + */ +//======================================================================= + +SMESH_ElementSearcher* SMESH_MeshAlgos::GetElementSearcher(SMDS_Mesh& mesh) +{ + return new SMESH_ElementSearcherImpl( mesh ); +} + +//======================================================================= +/*! + * \brief Return SMESH_ElementSearcher acting on a sub-set of elements + */ +//======================================================================= + +SMESH_ElementSearcher* SMESH_MeshAlgos::GetElementSearcher(SMDS_Mesh& mesh, + SMDS_ElemIteratorPtr elemIt) +{ + return new SMESH_ElementSearcherImpl( mesh, elemIt ); +} diff --git a/src/SMESHUtils/SMESH_MeshAlgos.hxx b/src/SMESHUtils/SMESH_MeshAlgos.hxx new file mode 100644 index 000000000..42ff8923a --- /dev/null +++ b/src/SMESHUtils/SMESH_MeshAlgos.hxx @@ -0,0 +1,137 @@ +// 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 +// +// This library is free software; you can redistribute it and/or +// modify it under the terms of the GNU Lesser General Public +// License as published by the Free Software Foundation; either +// version 2.1 of the License. +// +// This library is distributed in the hope that it will be useful, +// but WITHOUT ANY WARRANTY; without even the implied warranty of +// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU +// Lesser General Public License for more details. +// +// You should have received a copy of the GNU Lesser General Public +// License along with this library; if not, write to the Free Software +// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA +// +// See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com +// +// File : SMESH_MeshAlgos.hxx +// Created : Tue Apr 30 18:00:36 2013 +// Author : Edward AGAPOV (eap) + +// This file holds some low level algorithms extracted from SMESH_MeshEditor +// to make them accessible from Controls package + + +#ifndef __SMESH_MeshAlgos_HXX__ +#define __SMESH_MeshAlgos_HXX__ + +#include "SMDSAbs_ElementType.hxx" +#include "SMDS_ElemIterator.hxx" +#include "SMESH_TypeDefs.hxx" + +#include +#include + +class gp_Pnt; +class gp_Ax1; +class SMDS_MeshNode; +class SMDS_MeshElement; +class SMDS_Mesh; + +//======================================================================= +/*! + * \brief Searcher for the node closest to a point + */ +//======================================================================= + +struct SMESH_NodeSearcher +{ + virtual const SMDS_MeshNode* FindClosestTo( const gp_Pnt& pnt ) = 0; + virtual void MoveNode( const SMDS_MeshNode* node, const gp_Pnt& toPnt ) = 0; +}; + +//======================================================================= +/*! + * \brief Searcher for elements + */ +//======================================================================= + +struct SMESH_ElementSearcher +{ + /*! + * \brief Find elements of given type where the given point is IN or ON. + * Returns nb of found elements and elements them-selves. + * + * 'ALL' type means elements of any type excluding nodes and 0D elements + */ + virtual int FindElementsByPoint(const gp_Pnt& point, + SMDSAbs_ElementType type, + std::vector< const SMDS_MeshElement* >& foundElems) = 0; + /*! + * \brief Return an element most close to the given point + */ + virtual const SMDS_MeshElement* FindClosestTo( const gp_Pnt& point, + SMDSAbs_ElementType type) = 0; + /*! + * \brief Return elements possibly intersecting the line + */ + virtual void GetElementsNearLine( const gp_Ax1& line, + SMDSAbs_ElementType type, + std::vector< const SMDS_MeshElement* >& foundElems) = 0; + /*! + * \brief Find out if the given point is out of closed 2D mesh. + */ + virtual TopAbs_State GetPointState(const gp_Pnt& point) = 0; +}; + +namespace SMESH_MeshAlgos +{ + /*! + * \brief Return true if the point is IN or ON of the element + */ + bool IsOut( const SMDS_MeshElement* element, const gp_Pnt& point, double tol ); + + double GetDistance( const SMDS_MeshFace* face, const gp_Pnt& point ); + + /*! + * Return a face having linked nodes n1 and n2 and which is + * - not in avoidSet, + * - in elemSet provided that !elemSet.empty() + * i1 and i2 optionally returns indices of n1 and n2 + */ + const SMDS_MeshElement* FindFaceInSet(const SMDS_MeshNode* n1, + const SMDS_MeshNode* n2, + const TIDSortedElemSet& elemSet, + const TIDSortedElemSet& avoidSet, + int* i1=0, + int* i2=0); + /*! + * \brief Calculate normal of a mesh face + */ + bool FaceNormal(const SMDS_MeshElement* F, gp_XYZ& normal, bool normalized=true); + + /*! + * \brief Return nodes common to two elements + */ + std::vector< const SMDS_MeshNode*> GetCommonNodes(const SMDS_MeshElement* e1, + const SMDS_MeshElement* e2); + + /*! + * \brief Return SMESH_NodeSearcher. The caller is responsible for deleteing it + */ + SMESH_NodeSearcher* GetNodeSearcher( SMDS_Mesh& mesh ); + + /*! + * \brief Return SMESH_ElementSearcher. The caller is responsible for deleting it + */ + SMESH_ElementSearcher* GetElementSearcher( SMDS_Mesh& mesh ); + SMESH_ElementSearcher* GetElementSearcher( SMDS_Mesh& mesh, + SMDS_ElemIteratorPtr elemIt ); +} + +#endif