X-Git-Url: http://git.salome-platform.org/gitweb/?p=modules%2Fsmesh.git;a=blobdiff_plain;f=src%2FSMESH%2FSMESH_Gen.cxx;h=864f50c21449346cb49b5ccccdfd2e718d5b4af9;hp=01d864c6f3747157c2a7e939eb07c647f6642727;hb=52d825495306f72048c8754aa5c86c6a390f8262;hpb=ed456586bfb1411c5bff73b221658766689a6253 diff --git a/src/SMESH/SMESH_Gen.cxx b/src/SMESH/SMESH_Gen.cxx index 01d864c6f..864f50c21 100644 --- a/src/SMESH/SMESH_Gen.cxx +++ b/src/SMESH/SMESH_Gen.cxx @@ -1,246 +1,559 @@ -// SMESH SMESH : implementaion of SMESH idl descriptions -// -// Copyright (C) 2003 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN, -// CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS +// Copyright (C) 2007-2014 CEA/DEN, EDF R&D, OPEN CASCADE // -// 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. +// Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN, +// CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS // -// 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. +// 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, or (at your option) any later version. // -// 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.opencascade.org/SALOME/ or email : webmaster.salome@opencascade.org +// 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 // + +// SMESH SMESH : implementaion of SMESH idl descriptions // File : SMESH_Gen.cxx // Author : Paul RASCLE, EDF // Module : SMESH -// $Header$ +// + +//#define CHRONODEF #include "SMESH_Gen.hxx" -#include "SMESH_subMesh.hxx" + +#include "SMDS_Mesh.hxx" #include "SMDS_MeshElement.hxx" #include "SMDS_MeshNode.hxx" +#include "SMESHDS_Document.hxx" +#include "SMESH_HypoFilter.hxx" +#include "SMESH_MesherHelper.hxx" +#include "SMESH_subMesh.hxx" #include "utilities.h" #include "OpUtil.hxx" #include "Utils_ExceptHandlers.hxx" -#include -#include -#include -#include +#include +#include + +#include "memoire.h" + +#ifdef WIN32 + #include +#endif using namespace std; +//#include + + //============================================================================= /*! - * default constructor: + * Constructor */ //============================================================================= SMESH_Gen::SMESH_Gen() { - MESSAGE("SMESH_Gen::SMESH_Gen"); - _localId = 0; - _hypId = 0; + MESSAGE("SMESH_Gen::SMESH_Gen"); + _localId = 0; + _hypId = 0; + _segmentation = _nbSegments = 10; + SMDS_Mesh::_meshList.clear(); + MESSAGE(SMDS_Mesh::_meshList.size()); + //_counters = new counters(100); + _compute_canceled = false; + _sm_current = NULL; + //vtkDebugLeaks::SetExitError(0); } //============================================================================= /*! - * + * Destructor */ //============================================================================= SMESH_Gen::~SMESH_Gen() { - MESSAGE("SMESH_Gen::~SMESH_Gen"); + MESSAGE("SMESH_Gen::~SMESH_Gen"); + std::map < int, StudyContextStruct * >::iterator i_sc = _mapStudyContext.begin(); + for ( ; i_sc != _mapStudyContext.end(); ++i_sc ) + { + delete i_sc->second->myDocument; + delete i_sc->second; + } } //============================================================================= /*! - * + * Creates a mesh in a study. + * if (theIsEmbeddedMode) { mesh modification commands are not logged } */ //============================================================================= -/*SMESH_Hypothesis *SMESH_Gen::CreateHypothesis(const char *anHyp, int studyId) - throw(SALOME_Exception) +SMESH_Mesh* SMESH_Gen::CreateMesh(int theStudyId, bool theIsEmbeddedMode) + throw(SALOME_Exception) { + Unexpect aCatch(SalomeException); + MESSAGE("SMESH_Gen::CreateMesh"); - MESSAGE("CreateHypothesis("<GetID(); - myStudyContext->mapHypothesis[hypId] = myHypothesis; - SCRUTE(studyId); - SCRUTE(hypId); + // Get studyContext, create it if it does'nt exist, with a SMESHDS_Document + StudyContextStruct *aStudyContext = GetStudyContext(theStudyId); - // store hypothesis in SMESHDS document + // create a new SMESH_mesh object + SMESH_Mesh *aMesh = new SMESH_Mesh(_localId++, + theStudyId, + this, + theIsEmbeddedMode, + aStudyContext->myDocument); + aStudyContext->mapMesh[_localId-1] = aMesh; - myStudyContext->myDocument->AddHypothesis(myHypothesis); - return myHypothesis; -}*/ + return aMesh; +} //============================================================================= -/*! - * +/* + * Compute a mesh */ //============================================================================= -SMESH_Mesh* SMESH_Gen::CreateMesh(int studyId) -throw(SALOME_Exception) +bool SMESH_Gen::Compute(SMESH_Mesh & aMesh, + const TopoDS_Shape & aShape, + const bool aShapeOnly /*=false*/, + const bool anUpward /*=false*/, + const ::MeshDimension aDim /*=::MeshDim_3D*/, + TSetOfInt* aShapesId /*=0*/) { - Unexpect aCatch(SalomeException); - MESSAGE("SMESH_Gen::CreateMesh"); -// if (aShape.ShapeType() == TopAbs_COMPOUND) -// { -// INFOS("Mesh Compound not yet implemented!"); -// throw(SALOME_Exception(LOCALIZED("Mesh Compound not yet implemented!"))); -// } + MESSAGE("SMESH_Gen::Compute"); + MEMOSTAT; - // Get studyContext, create it if it does'nt exist, with a SMESHDS_Document + bool ret = true; + + SMESH_subMesh *sm = aMesh.GetSubMesh(aShape); + + const bool includeSelf = true; + const bool complexShapeFirst = true; + const int globalAlgoDim = 100; - StudyContextStruct *myStudyContext = GetStudyContext(studyId); + SMESH_subMeshIteratorPtr smIt; - // create a new SMESH_mesh object + // Fix of Issue 22150. Due to !BLSURF->OnlyUnaryInput(), BLSURF computes edges + // that must be computed by Projection 1D-2D when Projection asks to compute + // one face only. + SMESH_subMesh::compute_event computeEvent = + aShapeOnly ? SMESH_subMesh::COMPUTE_SUBMESH : SMESH_subMesh::COMPUTE; - SMESH_Mesh *mesh = new SMESH_Mesh(_localId++, - studyId, - this, - myStudyContext->myDocument); - myStudyContext->mapMesh[_localId] = mesh; + if ( anUpward ) // is called from the below code in this method + { + // =============================================== + // Mesh all the sub-shapes starting from vertices + // =============================================== + + smIt = sm->getDependsOnIterator(includeSelf, !complexShapeFirst); + while ( smIt->more() ) + { + SMESH_subMesh* smToCompute = smIt->next(); - // associate a TopoDS_Shape to the mesh + // do not mesh vertices of a pseudo shape + const TopoDS_Shape& shape = smToCompute->GetSubShape(); + const TopAbs_ShapeEnum shapeType = shape.ShapeType(); + if ( !aMesh.HasShapeToMesh() && shapeType == TopAbs_VERTEX ) + continue; -//mesh->ShapeToMesh(aShape); - return mesh; + // check for preview dimension limitations + if ( aShapesId && GetShapeDim( shapeType ) > (int)aDim ) + { + // clear compute state not to show previous compute errors + // if preview invoked less dimension less than previous + smToCompute->ComputeStateEngine( SMESH_subMesh::CHECK_COMPUTE_STATE ); + continue; + } + + if (smToCompute->GetComputeState() == SMESH_subMesh::READY_TO_COMPUTE) + { + if (_compute_canceled) + return false; + _sm_current = smToCompute; + smToCompute->ComputeStateEngine( computeEvent ); + _sm_current = NULL; + } + + // we check all the sub-meshes here and detect if any of them failed to compute + if (smToCompute->GetComputeState() == SMESH_subMesh::FAILED_TO_COMPUTE && + ( shapeType != TopAbs_EDGE || !SMESH_Algo::isDegenerated( TopoDS::Edge( shape )))) + ret = false; + else if ( aShapesId ) + aShapesId->insert( smToCompute->GetId() ); + } + //aMesh.GetMeshDS()->Modified(); + return ret; + } + else + { + // ================================================================ + // Apply algos that do NOT require discreteized boundaries + // ("all-dimensional") and do NOT support sub-meshes, starting from + // the most complex shapes and collect sub-meshes with algos that + // DO support sub-meshes + // ================================================================ + + list< SMESH_subMesh* > smWithAlgoSupportingSubmeshes[4]; // for each dim + + // map to sort sm with same dim algos according to dim of + // the shape the algo assigned to (issue 0021217). + // Other issues influenced the algo applying order: + // 21406, 21556, 21893, 20206 + multimap< int, SMESH_subMesh* > shDim2sm; + multimap< int, SMESH_subMesh* >::reverse_iterator shDim2smIt; + TopoDS_Shape algoShape; + int prevShapeDim = -1, aShapeDim; + + smIt = sm->getDependsOnIterator(includeSelf, complexShapeFirst); + while ( smIt->more() ) + { + SMESH_subMesh* smToCompute = smIt->next(); + if ( smToCompute->GetComputeState() != SMESH_subMesh::READY_TO_COMPUTE ) + continue; + + const TopoDS_Shape& aSubShape = smToCompute->GetSubShape(); + aShapeDim = GetShapeDim( aSubShape ); + if ( aShapeDim < 1 ) break; + + // check for preview dimension limitations + if ( aShapesId && aShapeDim > (int)aDim ) + continue; + + SMESH_Algo* algo = GetAlgo( smToCompute, &algoShape ); + if ( algo && !algo->NeedDiscreteBoundary() ) + { + if ( algo->SupportSubmeshes() ) + { + // reload sub-meshes from shDim2sm into smWithAlgoSupportingSubmeshes + // so that more local algos to go first + if ( prevShapeDim != aShapeDim ) + { + prevShapeDim = aShapeDim; + for ( shDim2smIt = shDim2sm.rbegin(); shDim2smIt != shDim2sm.rend(); ++shDim2smIt ) + if ( shDim2smIt->first == globalAlgoDim ) + smWithAlgoSupportingSubmeshes[ aShapeDim ].push_back( shDim2smIt->second ); + else + smWithAlgoSupportingSubmeshes[ aShapeDim ].push_front( shDim2smIt->second ); + shDim2sm.clear(); + } + // add smToCompute to shDim2sm map + if ( algoShape.IsSame( aMesh.GetShapeToMesh() )) + { + aShapeDim = globalAlgoDim; // to compute last + } + else + { + aShapeDim = GetShapeDim( algoShape ); + if ( algoShape.ShapeType() == TopAbs_COMPOUND ) + { + TopoDS_Iterator it( algoShape ); + aShapeDim += GetShapeDim( it.Value() ); + } + } + shDim2sm.insert( make_pair( aShapeDim, smToCompute )); + } + else // Compute w/o support of sub-meshes + { + if (_compute_canceled) + return false; + _sm_current = smToCompute; + smToCompute->ComputeStateEngine( computeEvent ); + _sm_current = NULL; + if ( aShapesId ) + aShapesId->insert( smToCompute->GetId() ); + } + } + } + // reload sub-meshes from shDim2sm into smWithAlgoSupportingSubmeshes + for ( shDim2smIt = shDim2sm.rbegin(); shDim2smIt != shDim2sm.rend(); ++shDim2smIt ) + if ( shDim2smIt->first == globalAlgoDim ) + smWithAlgoSupportingSubmeshes[3].push_back( shDim2smIt->second ); + else + smWithAlgoSupportingSubmeshes[0].push_front( shDim2smIt->second ); + + // ====================================================== + // Apply all-dimensional algorithms supporing sub-meshes + // ====================================================== + + std::vector< SMESH_subMesh* > smVec; + for ( aShapeDim = 0; aShapeDim < 4; ++aShapeDim ) + { + // ------------------------------------------------ + // sort list of sub-meshes according to mesh order + // ------------------------------------------------ + smVec.assign( smWithAlgoSupportingSubmeshes[ aShapeDim ].begin(), + smWithAlgoSupportingSubmeshes[ aShapeDim ].end() ); + aMesh.SortByMeshOrder( smVec ); + + // ------------------------------------------------------------ + // compute sub-meshes with local uni-dimensional algos under + // sub-meshes with all-dimensional algos + // ------------------------------------------------------------ + // start from lower shapes + for ( size_t i = 0; i < smVec.size(); ++i ) + { + sm = smVec[i]; + + // get a shape the algo is assigned to + if ( !GetAlgo( sm, & algoShape )) + continue; // strange... + + // look for more local algos + smIt = sm->getDependsOnIterator(!includeSelf, !complexShapeFirst); + while ( smIt->more() ) + { + SMESH_subMesh* smToCompute = smIt->next(); + + const TopoDS_Shape& aSubShape = smToCompute->GetSubShape(); + const int aShapeDim = GetShapeDim( aSubShape ); + //if ( aSubShape.ShapeType() == TopAbs_VERTEX ) continue; + if ( aShapeDim < 1 ) continue; + + // check for preview dimension limitations + if ( aShapesId && GetShapeDim( aSubShape.ShapeType() ) > (int)aDim ) + continue; + + SMESH_HypoFilter filter( SMESH_HypoFilter::IsAlgo() ); + filter + .And( SMESH_HypoFilter::IsApplicableTo( aSubShape )) + .And( SMESH_HypoFilter::IsMoreLocalThan( algoShape, aMesh )); + + if ( SMESH_Algo* subAlgo = (SMESH_Algo*) aMesh.GetHypothesis( smToCompute, filter, true)) + { + if ( ! subAlgo->NeedDiscreteBoundary() ) continue; + SMESH_Hypothesis::Hypothesis_Status status; + if ( subAlgo->CheckHypothesis( aMesh, aSubShape, status )) + // mesh a lower smToCompute starting from vertices + Compute( aMesh, aSubShape, aShapeOnly, /*anUpward=*/true, aDim, aShapesId ); + } + } + } + // -------------------------------- + // apply the all-dimensional algos + // -------------------------------- + for ( size_t i = 0; i < smVec.size(); ++i ) + { + sm = smVec[i]; + if ( sm->GetComputeState() == SMESH_subMesh::READY_TO_COMPUTE) + { + const TopAbs_ShapeEnum shapeType = sm->GetSubShape().ShapeType(); + // check for preview dimension limitations + if ( aShapesId && GetShapeDim( shapeType ) > (int)aDim ) + continue; + + if (_compute_canceled) + return false; + _sm_current = sm; + sm->ComputeStateEngine( computeEvent ); + _sm_current = NULL; + if ( aShapesId ) + aShapesId->insert( sm->GetId() ); + } + } + } // loop on shape dimensions + + // ----------------------------------------------- + // mesh the rest sub-shapes starting from vertices + // ----------------------------------------------- + ret = Compute( aMesh, aShape, aShapeOnly, /*anUpward=*/true, aDim, aShapesId ); + } + + MESSAGE( "VSR - SMESH_Gen::Compute() finished, OK = " << ret); + MEMOSTAT; + + SMESHDS_Mesh *myMesh = aMesh.GetMeshDS(); + MESSAGE("*** compactMesh after compute"); + myMesh->compactMesh(); + + // fix quadratic mesh by bending iternal links near concave boundary + if ( aShape.IsSame( aMesh.GetShapeToMesh() ) && + !aShapesId && // not preview + ret ) // everything is OK + { + SMESH_MesherHelper aHelper( aMesh ); + if ( aHelper.IsQuadraticMesh() != SMESH_MesherHelper::LINEAR ) + { + aHelper.FixQuadraticElements( sm->GetComputeError() ); + } + } + return ret; +} + +//============================================================================= +/*! + * Prepare Compute a mesh + */ +//============================================================================= +void SMESH_Gen::PrepareCompute(SMESH_Mesh & aMesh, + const TopoDS_Shape & aShape) +{ + _compute_canceled = false; + _sm_current = NULL; +} +//============================================================================= +/*! + * Cancel Compute a mesh + */ +//============================================================================= +void SMESH_Gen::CancelCompute(SMESH_Mesh & aMesh, + const TopoDS_Shape & aShape) +{ + _compute_canceled = true; + if(_sm_current) + { + _sm_current->ComputeStateEngine( SMESH_subMesh::COMPUTE_CANCELED ); + } } //============================================================================= /*! - * + * Evaluate a mesh */ //============================================================================= -bool SMESH_Gen::Compute(SMESH_Mesh & aMesh, const TopoDS_Shape & aShape) +bool SMESH_Gen::Evaluate(SMESH_Mesh & aMesh, + const TopoDS_Shape & aShape, + MapShapeNbElems& aResMap, + const bool anUpward, + TSetOfInt* aShapesId) { - MESSAGE("SMESH_Gen::Compute"); - // bool isDone = false; - /* - Algo : s'appuie ou non sur une geometrie - Si geometrie: - Vertex : rien à faire (range le point) - Edge, Wire, collection d'edge et wire : 1D - Face, Shell, collection de Face et Shells : 2D - Solid, Collection de Solid : 3D - */ - // *** corriger commentaires - // check hypothesis associated to the mesh : - // - only one algo : type compatible with the type of the shape - // - hypothesis = compatible with algo - // - check if hypothesis are applicable to this algo - // - check contradictions within hypothesis - // (test if enough hypothesis is done further) + MESSAGE("SMESH_Gen::Evaluate"); bool ret = true; -// if ( !CheckAlgoState( aMesh, aShape )) -// { -// INFOS( "ABORT MESHING: some algos or hypothesis are missing"); -// return false; -// } - SMESH_subMesh *sm = aMesh.GetSubMesh(aShape); - // ----------------------------------------------------------------- - // apply algos that do not require descretized boundaries, starting - // from the most complex shapes - // ----------------------------------------------------------------- - - // map containing all subshapes in the order: vertices, edges, faces... - const map& smMap = sm->DependsOn(); - map::const_reverse_iterator revItSub = smMap.rbegin(); + const bool includeSelf = true; + const bool complexShapeFirst = true; + SMESH_subMeshIteratorPtr smIt; + + if ( anUpward ) { // is called from below code here + // ----------------------------------------------- + // mesh all the sub-shapes starting from vertices + // ----------------------------------------------- + smIt = sm->getDependsOnIterator(includeSelf, !complexShapeFirst); + while ( smIt->more() ) { + SMESH_subMesh* smToCompute = smIt->next(); + + // do not mesh vertices of a pseudo shape + const TopAbs_ShapeEnum shapeType = smToCompute->GetSubShape().ShapeType(); + //if ( !aMesh.HasShapeToMesh() && shapeType == TopAbs_VERTEX ) + // continue; + if ( !aMesh.HasShapeToMesh() ) { + if( shapeType == TopAbs_VERTEX || shapeType == TopAbs_WIRE || + shapeType == TopAbs_SHELL ) + continue; + } - SMESH_subMesh* smToCompute = sm; - while ( smToCompute ) - { - const TopoDS_Shape& aSubShape = smToCompute->GetSubShape(); - if ( GetShapeDim( aSubShape ) < 1 ) break; - - SMESH_Algo* algo = GetAlgo( aMesh, aSubShape ); - if (algo && !algo->NeedDescretBoundary()) { - if (smToCompute->GetComputeState() == SMESH_subMesh::READY_TO_COMPUTE) { - ret = smToCompute->ComputeStateEngine( SMESH_subMesh::COMPUTE ); - } else if (smToCompute->GetComputeState() == SMESH_subMesh::FAILED_TO_COMPUTE) { - // JFA for PAL6524 - ret = false; - } else { + smToCompute->Evaluate(aResMap); + if( aShapesId ) + aShapesId->insert( smToCompute->GetId() ); + } + return ret; + } + else { + // ----------------------------------------------------------------- + // apply algos that DO NOT require Discreteized boundaries and DO NOT + // support sub-meshes, starting from the most complex shapes + // and collect sub-meshes with algos that DO support sub-meshes + // ----------------------------------------------------------------- + list< SMESH_subMesh* > smWithAlgoSupportingSubmeshes; + smIt = sm->getDependsOnIterator(includeSelf, complexShapeFirst); + while ( smIt->more() ) { + SMESH_subMesh* smToCompute = smIt->next(); + const TopoDS_Shape& aSubShape = smToCompute->GetSubShape(); + const int aShapeDim = GetShapeDim( aSubShape ); + if ( aShapeDim < 1 ) break; + + SMESH_Algo* algo = GetAlgo( smToCompute ); + if ( algo && !algo->NeedDiscreteBoundary() ) { + if ( algo->SupportSubmeshes() ) { + smWithAlgoSupportingSubmeshes.push_front( smToCompute ); + } + else { + smToCompute->Evaluate(aResMap); + if ( aShapesId ) + aShapesId->insert( smToCompute->GetId() ); + } } } - if (!ret) - return false; - // next subMesh - if (revItSub != smMap.rend()) + // ------------------------------------------------------------ + // sort list of meshes according to mesh order + // ------------------------------------------------------------ + std::vector< SMESH_subMesh* > smVec( smWithAlgoSupportingSubmeshes.begin(), + smWithAlgoSupportingSubmeshes.end() ); + aMesh.SortByMeshOrder( smVec ); + + // ------------------------------------------------------------ + // compute sub-meshes under shapes with algos that DO NOT require + // Discreteized boundaries and DO support sub-meshes + // ------------------------------------------------------------ + // start from lower shapes + for ( size_t i = 0; i < smVec.size(); ++i ) { - smToCompute = (*revItSub).second; - revItSub++; - } - else - smToCompute = 0; - } + sm = smVec[i]; - // ----------------------------------------------- - // mesh the rest subshapes starting from vertices - // ----------------------------------------------- + // get a shape the algo is assigned to + TopoDS_Shape algoShape; + if ( !GetAlgo( sm, & algoShape )) + continue; // strange... - int i, nbSub = smMap.size(); - map::const_iterator itSub = smMap.begin(); - for ( i = 0; i <= nbSub; ++i ) // loop on the whole map plus - { - if ( itSub == smMap.end() ) - smToCompute = sm; - else - smToCompute = (itSub++)->second; - if (smToCompute->GetComputeState() != SMESH_subMesh::READY_TO_COMPUTE) { - if (smToCompute->GetComputeState() == SMESH_subMesh::FAILED_TO_COMPUTE) - ret = false; - continue; - } - TopoDS_Shape subShape = smToCompute->GetSubShape(); - if ( subShape.ShapeType() != TopAbs_VERTEX ) - { - if ( !smToCompute->ComputeStateEngine(SMESH_subMesh::COMPUTE) ) - ret = false; + // look for more local algos + smIt = sm->getDependsOnIterator(!includeSelf, !complexShapeFirst); + while ( smIt->more() ) { + SMESH_subMesh* smToCompute = smIt->next(); + + const TopoDS_Shape& aSubShape = smToCompute->GetSubShape(); + const int aShapeDim = GetShapeDim( aSubShape ); + if ( aShapeDim < 1 ) continue; + + SMESH_HypoFilter filter( SMESH_HypoFilter::IsAlgo() ); + filter + .And( SMESH_HypoFilter::IsApplicableTo( aSubShape )) + .And( SMESH_HypoFilter::IsMoreLocalThan( algoShape, aMesh )); + + if ( SMESH_Algo* subAlgo = (SMESH_Algo*) aMesh.GetHypothesis( smToCompute, filter, true )) + { + if ( ! subAlgo->NeedDiscreteBoundary() ) continue; + SMESH_Hypothesis::Hypothesis_Status status; + if ( subAlgo->CheckHypothesis( aMesh, aSubShape, status )) + // mesh a lower smToCompute starting from vertices + Evaluate( aMesh, aSubShape, aResMap, /*anUpward=*/true, aShapesId ); + } + } } - else + // ---------------------------------------------------------- + // apply the algos that do not require Discreteized boundaries + // ---------------------------------------------------------- + for ( size_t i = 0; i < smVec.size(); ++i ) { - TopoDS_Vertex V1 = TopoDS::Vertex(subShape); - gp_Pnt P1 = BRep_Tool::Pnt(V1); - SMESHDS_Mesh * meshDS = aMesh.GetMeshDS(); - SMDS_MeshNode * node = meshDS->AddNode(P1.X(), P1.Y(), P1.Z()); - if ( node ) { // san - increase robustness - meshDS->SetNodeOnVertex(node, V1); - smToCompute->ComputeStateEngine(SMESH_subMesh::COMPUTE); - } + sm = smVec[i]; + sm->Evaluate(aResMap); + if ( aShapesId ) + aShapesId->insert( sm->GetId() ); } + + // ----------------------------------------------- + // mesh the rest sub-shapes starting from vertices + // ----------------------------------------------- + ret = Evaluate( aMesh, aShape, aResMap, /*anUpward=*/true, aShapesId ); } - MESSAGE( "VSR - SMESH_Gen::Compute() finished, OK = " << ret); + MESSAGE( "VSR - SMESH_Gen::Evaluate() finished, OK = " << ret); return ret; } @@ -255,7 +568,8 @@ static bool checkConformIgnoredAlgos(SMESH_Mesh& aMesh, const SMESH_Algo* aGlobIgnoAlgo, const SMESH_Algo* aLocIgnoAlgo, bool & checkConform, - map& aCheckedMap) + set& aCheckedMap, + list< SMESH_Gen::TAlgoStateError > & theErrors) { ASSERT( aSubMesh ); if ( aSubMesh->GetSubShape().ShapeType() == TopAbs_VERTEX) @@ -278,23 +592,29 @@ static bool checkConformIgnoredAlgos(SMESH_Mesh& aMesh, if ( aLocIgnoAlgo ) // algo is hidden by a local algo of upper dim { + theErrors.push_back( SMESH_Gen::TAlgoStateError() ); + theErrors.back().Set( SMESH_Hypothesis::HYP_HIDDEN_ALGO, algo, false ); INFOS( "Local <" << algo->GetName() << "> is hidden by local <" << aLocIgnoAlgo->GetName() << ">"); } else { - bool isGlobal = (aMesh.IsMainShape( aSubMesh->GetSubShape() )); - int dim = algo->GetDim(); + bool isGlobal = (aMesh.IsMainShape( aSubMesh->GetSubShape() )); + int dim = algo->GetDim(); int aMaxGlobIgnoDim = ( aGlobIgnoAlgo ? aGlobIgnoAlgo->GetDim() : -1 ); + bool isNeededDim = ( aGlobIgnoAlgo ? aGlobIgnoAlgo->NeedLowerHyps( dim ) : false ); - if ( dim < aMaxGlobIgnoDim ) + if (( dim < aMaxGlobIgnoDim && !isNeededDim ) && + ( isGlobal || !aGlobIgnoAlgo->SupportSubmeshes() )) { // algo is hidden by a global algo + theErrors.push_back( SMESH_Gen::TAlgoStateError() ); + theErrors.back().Set( SMESH_Hypothesis::HYP_HIDDEN_ALGO, algo, true ); INFOS( ( isGlobal ? "Global" : "Local" ) << " <" << algo->GetName() << "> is hidden by global <" << aGlobIgnoAlgo->GetName() << ">"); } - else if ( !algo->NeedDescretBoundary() && !isGlobal) + else if ( !algo->NeedDiscreteBoundary() && !isGlobal) { // local algo is not hidden and hides algos on sub-shapes if (checkConform && !aSubMesh->IsConform( algo )) @@ -304,22 +624,22 @@ static bool checkConformIgnoredAlgos(SMESH_Mesh& aMesh, INFOS( "ERROR: Local <" << algo->GetName() << "> would produce not conform mesh: " " hypotesis is missing"); + theErrors.push_back( SMESH_Gen::TAlgoStateError() ); + theErrors.back().Set( SMESH_Hypothesis::HYP_NOTCONFORM, algo, false ); } - // sub-algos will be hidden by a local - const map& smMap = aSubMesh->DependsOn(); - map::const_reverse_iterator revItSub; + // sub-algos will be hidden by a local if does not support sub-meshes + if ( algo->SupportSubmeshes() ) + algo = 0; + SMESH_subMeshIteratorPtr revItSub = + aSubMesh->getDependsOnIterator( /*includeSelf=*/false, /*complexShapeFirst=*/true); bool checkConform2 = false; - for ( revItSub = smMap.rbegin(); revItSub != smMap.rend(); revItSub++) + while ( revItSub->more() ) { - checkConformIgnoredAlgos (aMesh, (*revItSub).second, aGlobIgnoAlgo, - algo, checkConform2, aCheckedMap); - int key = (*revItSub).first; - SMESH_subMesh* sm = (*revItSub).second; - if ( aCheckedMap.find( key ) == aCheckedMap.end() ) - { - aCheckedMap[ key ] = sm; - } + SMESH_subMesh* sm = revItSub->next(); + checkConformIgnoredAlgos (aMesh, sm, aGlobIgnoAlgo, + algo, checkConform2, aCheckedMap, theErrors); + aCheckedMap.insert( sm ); } } } @@ -340,9 +660,18 @@ static bool checkMissing(SMESH_Gen* aGen, const int aTopAlgoDim, bool* globalChecked, const bool checkNoAlgo, - map& aCheckedMap) + set& aCheckedMap, + list< SMESH_Gen::TAlgoStateError > & theErrors) { - if ( aSubMesh->GetSubShape().ShapeType() == TopAbs_VERTEX) + switch ( aSubMesh->GetSubShape().ShapeType() ) + { + case TopAbs_EDGE: + case TopAbs_FACE: + case TopAbs_SOLID: break; // check this sub-mesh, it can be meshed + default: + return true; // not meshable sub-mesh + } + if ( aCheckedMap.count( aSubMesh )) return true; //MESSAGE("=====checkMissing"); @@ -359,30 +688,54 @@ static bool checkMissing(SMESH_Gen* aGen, int shapeDim = SMESH_Gen::GetShapeDim( aSubMesh->GetSubShape() ); if (aTopAlgoDim > shapeDim) { - INFOS( "ERROR: " << shapeDim << "D algorithm is missing" ); + MESSAGE( "ERROR: " << shapeDim << "D algorithm is missing" ); ret = false; + theErrors.push_back( SMESH_Gen::TAlgoStateError() ); + theErrors.back().Set( SMESH_Hypothesis::HYP_MISSING, shapeDim, true ); } } return ret; } case SMESH_subMesh::MISSING_HYP: { // notify if an algo missing hyp is attached to aSubMesh - algo = aGen->GetAlgo( aMesh, aSubMesh->GetSubShape() ); + algo = aSubMesh->GetAlgo(); ASSERT( algo ); - bool isGlobalAlgo = aGen->IsGlobalAlgo( algo, aMesh ); - if (!isGlobalAlgo || !globalChecked[ algo->GetDim() ]) + bool IsGlobalHypothesis = aGen->IsGlobalHypothesis( algo, aMesh ); + if (!IsGlobalHypothesis || !globalChecked[ algo->GetDim() ]) { - INFOS( "ERROR: " << (isGlobalAlgo ? "Global " : "Local ") - << "<" << algo->GetName() << "> misses some hypothesis"); - if (isGlobalAlgo) + TAlgoStateErrorName errName = SMESH_Hypothesis::HYP_MISSING; + SMESH_Hypothesis::Hypothesis_Status status; + algo->CheckHypothesis( aMesh, aSubMesh->GetSubShape(), status ); + if ( status == SMESH_Hypothesis::HYP_BAD_PARAMETER ) { + MESSAGE( "ERROR: hypothesis of " << (IsGlobalHypothesis ? "Global " : "Local ") + << "<" << algo->GetName() << "> has a bad parameter value"); + errName = status; + } else if ( status == SMESH_Hypothesis::HYP_BAD_GEOMETRY ) { + MESSAGE( "ERROR: " << (IsGlobalHypothesis ? "Global " : "Local ") + << "<" << algo->GetName() << "> assigned to mismatching geometry"); + errName = status; + } else { + MESSAGE( "ERROR: " << (IsGlobalHypothesis ? "Global " : "Local ") + << "<" << algo->GetName() << "> misses some hypothesis"); + } + if (IsGlobalHypothesis) globalChecked[ algo->GetDim() ] = true; + theErrors.push_back( SMESH_Gen::TAlgoStateError() ); + theErrors.back().Set( errName, algo, IsGlobalHypothesis ); } ret = false; break; } case SMESH_subMesh::HYP_OK: - algo = aGen->GetAlgo( aMesh, aSubMesh->GetSubShape() ); + algo = aSubMesh->GetAlgo(); ret = true; + if (!algo->NeedDiscreteBoundary()) + { + SMESH_subMeshIteratorPtr itsub = aSubMesh->getDependsOnIterator( /*includeSelf=*/false, + /*complexShapeFirst=*/false); + while ( itsub->more() ) + aCheckedMap.insert( itsub->next() ); + } break; default: ASSERT(0); } @@ -391,32 +744,30 @@ static bool checkMissing(SMESH_Gen* aGen, // re-start checking NO_ALGO state ASSERT (algo); bool isTopLocalAlgo = - ( aTopAlgoDim <= algo->GetDim() && !aGen->IsGlobalAlgo( algo, aMesh )); - if (!algo->NeedDescretBoundary() || isTopLocalAlgo) + ( aTopAlgoDim <= algo->GetDim() && !aGen->IsGlobalHypothesis( algo, aMesh )); + if (!algo->NeedDiscreteBoundary() || isTopLocalAlgo) { - bool checkNoAlgo2 = ( algo->NeedDescretBoundary() ); - const map& subMeshes = aSubMesh->DependsOn(); - map::const_iterator itsub; - for (itsub = subMeshes.begin(); itsub != subMeshes.end(); itsub++) + bool checkNoAlgo2 = ( algo->NeedDiscreteBoundary() ); + SMESH_subMeshIteratorPtr itsub = aSubMesh->getDependsOnIterator( /*includeSelf=*/false, + /*complexShapeFirst=*/true); + while ( itsub->more() ) { // sub-meshes should not be checked further more - int key = (*itsub).first; - SMESH_subMesh* sm = (*itsub).second; - if ( aCheckedMap.find( key ) == aCheckedMap.end() ) - aCheckedMap[ key ] = sm; + SMESH_subMesh* sm = itsub->next(); if (isTopLocalAlgo) { //check algo on sub-meshes int aTopAlgoDim2 = algo->GetDim(); if (!checkMissing (aGen, aMesh, sm, aTopAlgoDim2, - globalChecked, checkNoAlgo2, aCheckedMap)) + globalChecked, checkNoAlgo2, aCheckedMap, theErrors)) { ret = false; if (sm->GetAlgoState() == SMESH_subMesh::NO_ALGO ) checkNoAlgo2 = false; } } + aCheckedMap.insert( sm ); } } return ret; @@ -429,15 +780,30 @@ static bool checkMissing(SMESH_Gen* aGen, //======================================================================= bool SMESH_Gen::CheckAlgoState(SMESH_Mesh& aMesh, const TopoDS_Shape& aShape) +{ + list< TAlgoStateError > errors; + return GetAlgoState( aMesh, aShape, errors ); +} + +//======================================================================= +//function : GetAlgoState +//purpose : notify on bad state of attached algos, return false +// if Compute() would fail because of some algo bad state +// theErrors list contains problems description +//======================================================================= + +bool SMESH_Gen::GetAlgoState(SMESH_Mesh& theMesh, + const TopoDS_Shape& theShape, + list< TAlgoStateError > & theErrors) { //MESSAGE("SMESH_Gen::CheckAlgoState"); bool ret = true; bool hasAlgo = false; - SMESH_subMesh* sm = aMesh.GetSubMesh(aShape); - const SMESHDS_Mesh* meshDS = aMesh.GetMeshDS(); - TopoDS_Shape mainShape = meshDS->ShapeToMesh(); + SMESH_subMesh* sm = theMesh.GetSubMesh(theShape); + const SMESHDS_Mesh* meshDS = theMesh.GetMeshDS(); + TopoDS_Shape mainShape = meshDS->ShapeToMesh(); // ----------------- // get global algos @@ -464,57 +830,44 @@ bool SMESH_Gen::CheckAlgoState(SMESH_Mesh& aMesh, const TopoDS_Shape& aShape) // -------------------------------------------------------- // info on algos that will be ignored because of ones that - // don't NeedDescretBoundary() attached to super-shapes, + // don't NeedDiscreteBoundary() attached to super-shapes, // check that a conform mesh will be produced // -------------------------------------------------------- - // find a global algo possibly hidding sub-algos + // find a global algo possibly hiding sub-algos int dim; const SMESH_Algo* aGlobIgnoAlgo = 0; for (dim = 3; dim > 0; dim--) { if (aGlobAlgoArr[ dim ] && - !aGlobAlgoArr[ dim ]->NeedDescretBoundary()) + !aGlobAlgoArr[ dim ]->NeedDiscreteBoundary() /*&& + !aGlobAlgoArr[ dim ]->SupportSubmeshes()*/ ) { aGlobIgnoAlgo = aGlobAlgoArr[ dim ]; break; } } - const map& smMap = sm->DependsOn(); - map::const_reverse_iterator revItSub = smMap.rbegin(); - map aCheckedMap; - bool checkConform = ( !aMesh.IsNotConformAllowed() ); - int aKey = 1; - SMESH_subMesh* smToCheck = sm; + set aCheckedSubs; + bool checkConform = ( !theMesh.IsNotConformAllowed() ); - // loop on aShape and its sub-shapes - while ( smToCheck ) + // loop on theShape and its sub-shapes + SMESH_subMeshIteratorPtr revItSub = sm->getDependsOnIterator( /*includeSelf=*/true, + /*complexShapeFirst=*/true); + while ( revItSub->more() ) { + SMESH_subMesh* smToCheck = revItSub->next(); if ( smToCheck->GetSubShape().ShapeType() == TopAbs_VERTEX) break; - if ( aCheckedMap.find( aKey ) == aCheckedMap.end() ) - if (!checkConformIgnoredAlgos (aMesh, smToCheck, aGlobIgnoAlgo, - 0, checkConform, aCheckedMap)) + if ( aCheckedSubs.insert( smToCheck ).second ) // not yet checked + if (!checkConformIgnoredAlgos (theMesh, smToCheck, aGlobIgnoAlgo, + 0, checkConform, aCheckedSubs, theErrors)) ret = false; if ( smToCheck->GetAlgoState() != SMESH_subMesh::NO_ALGO ) hasAlgo = true; - - // next subMesh - if (revItSub != smMap.rend()) - { - aKey = (*revItSub).first; - smToCheck = (*revItSub).second; - revItSub++; - } - else - { - smToCheck = 0; - } - } // ---------------------------------------------------------------- @@ -534,312 +887,265 @@ bool SMESH_Gen::CheckAlgoState(SMESH_Mesh& aMesh, const TopoDS_Shape& aShape) break; } } - aCheckedMap.clear(); - smToCheck = sm; - revItSub = smMap.rbegin(); - bool checkNoAlgo = (bool) aTopAlgoDim; + bool checkNoAlgo = theMesh.HasShapeToMesh() ? bool( aTopAlgoDim ) : false; bool globalChecked[] = { false, false, false, false }; - // loop on aShape and its sub-shapes - while ( smToCheck ) + // loop on theShape and its sub-shapes + aCheckedSubs.clear(); + revItSub = sm->getDependsOnIterator( /*includeSelf=*/true, /*complexShapeFirst=*/true); + while ( revItSub->more() ) { + SMESH_subMesh* smToCheck = revItSub->next(); if ( smToCheck->GetSubShape().ShapeType() == TopAbs_VERTEX) break; - if ( aCheckedMap.find( aKey ) == aCheckedMap.end() ) - if (!checkMissing (this, aMesh, smToCheck, aTopAlgoDim, - globalChecked, checkNoAlgo, aCheckedMap)) - { - ret = false; - if (smToCheck->GetAlgoState() == SMESH_subMesh::NO_ALGO ) - checkNoAlgo = false; - } - - // next subMesh - if (revItSub != smMap.rend()) + if (!checkMissing (this, theMesh, smToCheck, aTopAlgoDim, + globalChecked, checkNoAlgo, aCheckedSubs, theErrors)) { - aKey = (*revItSub).first; - smToCheck = (*revItSub).second; - revItSub++; + ret = false; + if (smToCheck->GetAlgoState() == SMESH_subMesh::NO_ALGO ) + checkNoAlgo = false; } - else - smToCheck = 0; } - if ( !hasAlgo ) - INFOS( "None algorithm attached" ); + if ( !hasAlgo ) { + ret = false; + theErrors.push_back( TAlgoStateError() ); + theErrors.back().Set( SMESH_Hypothesis::HYP_MISSING, 1, true ); + } - return ( ret && hasAlgo ); + return ret; } //======================================================================= -//function : IsGlobalAlgo +//function : IsGlobalHypothesis //purpose : check if theAlgo is attached to the main shape //======================================================================= -bool SMESH_Gen::IsGlobalAlgo(const SMESH_Algo* theAlgo, SMESH_Mesh& aMesh) +bool SMESH_Gen::IsGlobalHypothesis(const SMESH_Hypothesis* theHyp, SMESH_Mesh& aMesh) { - const SMESHDS_Mesh* meshDS = aMesh.GetMeshDS(); - TopoDS_Shape mainShape = meshDS->ShapeToMesh(); - const list& listHyp = meshDS->GetHypothesis( mainShape ); - list::const_iterator it=listHyp.begin(); - for ( ; it != listHyp.end(); it++) - if ( *it == theAlgo ) - return true; - - return false; + SMESH_HypoFilter filter( SMESH_HypoFilter::Is( theHyp )); + return aMesh.GetHypothesis( aMesh.GetMeshDS()->ShapeToMesh(), filter, false ); } - -//======================================================================= -//function : getAlgoId -//purpose : return algo ID or -1 if not found -//======================================================================= - -static int getAlgo(const list& theHypList, - const int theAlgoDim, - const int theAlgoShapeType) -{ - list::const_iterator it = theHypList.begin(); - - int nb_algo = 0; - int algo_id = -1; - - while (it!=theHypList.end()) - { - const SMESH_Hypothesis *anHyp = static_cast< const SMESH_Hypothesis *>( *it ); - if (anHyp->GetType() > SMESHDS_Hypothesis::PARAM_ALGO && - anHyp->GetDim() == theAlgoDim && - ((anHyp->GetShapeType()) & (1 << theAlgoShapeType))) - { - nb_algo++; - algo_id = anHyp->GetID(); - break; - } - - //if (nb_algo > 1) return -1; // more than one algo - it++; - } - - return algo_id; -} - -//============================================================================= +//================================================================================ /*! - * + * \brief Return paths to xml files of plugins */ -//============================================================================= +//================================================================================ -SMESH_Algo *SMESH_Gen::GetAlgo(SMESH_Mesh & aMesh, const TopoDS_Shape & aShape) +std::vector< std::string > SMESH_Gen::GetPluginXMLPaths() { -// MESSAGE("SMESH_Gen::GetAlgo"); - - const SMESHDS_Mesh * meshDS = aMesh.GetMeshDS(); - int dim = GetShapeDim( aShape ); - int shape_type = aShape.ShapeType(); - int algo_id = -1; - - algo_id = getAlgo( meshDS->GetHypothesis( aShape ), dim, shape_type ); - - if (algo_id < 0) + // Get paths to xml files of plugins + vector< string > xmlPaths; + string sep; + if ( const char* meshersList = getenv("SMESH_MeshersList") ) { - // try ansestors - TopTools_ListIteratorOfListOfShape ancIt( aMesh.GetAncestors( aShape )); - for (; ancIt.More(); ancIt.Next()) + string meshers = meshersList, plugin; + string::size_type from = 0, pos; + while ( from < meshers.size() ) { - const TopoDS_Shape& ancestor = ancIt.Value(); - algo_id = getAlgo( meshDS->GetHypothesis( ancestor ), dim, shape_type ); - if ( algo_id >= 0 ) - break; + // cut off plugin name + pos = meshers.find( ':', from ); + if ( pos != string::npos ) + plugin = meshers.substr( from, pos-from ); + else + plugin = meshers.substr( from ), pos = meshers.size(); + from = pos + 1; + + // get PLUGIN_ROOT_DIR path + string rootDirVar, pluginSubDir = plugin; + if ( plugin == "StdMeshers" ) + rootDirVar = "SMESH", pluginSubDir = "smesh"; + else + for ( pos = 0; pos < plugin.size(); ++pos ) + rootDirVar += toupper( plugin[pos] ); + rootDirVar += "_ROOT_DIR"; + + const char* rootDir = getenv( rootDirVar.c_str() ); + if ( !rootDir || strlen(rootDir) == 0 ) + { + rootDirVar = plugin + "_ROOT_DIR"; // HexoticPLUGIN_ROOT_DIR + rootDir = getenv( rootDirVar.c_str() ); + if ( !rootDir || strlen(rootDir) == 0 ) continue; + } + + // get a separator from rootDir + for ( pos = strlen( rootDir )-1; pos >= 0 && sep.empty(); --pos ) + if ( rootDir[pos] == '/' || rootDir[pos] == '\\' ) + { + sep = rootDir[pos]; + break; + } +#ifdef WIN32 + if (sep.empty() ) sep = "\\"; +#else + if (sep.empty() ) sep = "/"; +#endif + + // get a path to resource file + string xmlPath = rootDir; + if ( xmlPath[ xmlPath.size()-1 ] != sep[0] ) + xmlPath += sep; + xmlPath += "share" + sep + "salome" + sep + "resources" + sep; + for ( pos = 0; pos < pluginSubDir.size(); ++pos ) + xmlPath += tolower( pluginSubDir[pos] ); + xmlPath += sep + plugin + ".xml"; + bool fileOK; +#ifdef WIN32 + fileOK = (GetFileAttributes(xmlPath.c_str()) != INVALID_FILE_ATTRIBUTES); +#else + fileOK = (access(xmlPath.c_str(), F_OK) == 0); +#endif + if ( fileOK ) + xmlPaths.push_back( xmlPath ); } - if (algo_id < 0) return NULL; } - ASSERT(_mapAlgo.find(algo_id) != _mapAlgo.end()); - - return _mapAlgo[algo_id]; - -// const SMESHDS_Hypothesis *theHyp = NULL; -// SMESH_Algo *algo = NULL; -// const SMESHDS_Mesh * meshDS = aMesh.GetMeshDS(); -// int hypType; -// int hypId; -// int algoDim; - -// // try shape first, then main shape - -// TopoDS_Shape mainShape = meshDS->ShapeToMesh(); -// const TopoDS_Shape *shapeToTry[2] = { &aShape, &mainShape }; - -// for (int iShape = 0; iShape < 2; iShape++) -// { -// TopoDS_Shape tryShape = (*shapeToTry[iShape]); - -// const list& listHyp = -// meshDS->GetHypothesis(tryShape); -// list::const_iterator it=listHyp.begin(); - -// int nb_algo = 0; -// int shapeDim = GetShapeDim(aShape); -// int typeOfShape = aShape.ShapeType(); - -// while (it!=listHyp.end()) -// { -// const SMESHDS_Hypothesis *anHyp = *it; -// hypType = anHyp->GetType(); -// //SCRUTE(hypType); -// if (hypType > SMESHDS_Hypothesis::PARAM_ALGO) -// { -// switch (hypType) -// { -// case SMESHDS_Hypothesis::ALGO_1D: -// algoDim = 1; -// break; -// case SMESHDS_Hypothesis::ALGO_2D: -// algoDim = 2; -// break; -// case SMESHDS_Hypothesis::ALGO_3D: -// algoDim = 3; -// break; -// default: -// algoDim = 0; -// break; -// } -// //SCRUTE(algoDim); -// //SCRUTE(shapeDim); -// //SCRUTE(typeOfShape); -// if (shapeDim == algoDim) // count only algos of shape dim. -// { // discard algos for subshapes -// hypId = anHyp->GetID(); // (of lower dim.) -// ASSERT(_mapAlgo.find(hypId) != _mapAlgo.end()); -// SMESH_Algo *anAlgo = _mapAlgo[hypId]; -// //SCRUTE(anAlgo->GetShapeType()); -// //if (anAlgo->GetShapeType() == typeOfShape) -// if ((anAlgo->GetShapeType()) & (1 << typeOfShape)) -// { // only specific TopoDS_Shape -// nb_algo++; -// theHyp = anHyp; -// } -// } -// } -// if (nb_algo > 1) return NULL; // more than one algo -// it++; -// } -// if (nb_algo == 1) // one algo found : OK -// break; // do not try a parent shape -// } - -// if (!theHyp) -// return NULL; // no algo found - -// hypType = theHyp->GetType(); -// hypId = theHyp->GetID(); - -// ASSERT(_mapAlgo.find(hypId) != _mapAlgo.end()); -// algo = _mapAlgo[hypId]; -// //MESSAGE("Algo found " << algo->GetName() << " Id " << hypId); -// return algo; + return xmlPaths; } //============================================================================= /*! - * + * Finds algo to mesh a shape. Optionally returns a shape the found algo is bound to */ //============================================================================= -StudyContextStruct *SMESH_Gen::GetStudyContext(int studyId) +SMESH_Algo *SMESH_Gen::GetAlgo(SMESH_Mesh & aMesh, + const TopoDS_Shape & aShape, + TopoDS_Shape* assignedTo) { - // Get studyContext, create it if it does'nt exist, with a SMESHDS_Document - - if (_mapStudyContext.find(studyId) == _mapStudyContext.end()) - { - _mapStudyContext[studyId] = new StudyContextStruct; - _mapStudyContext[studyId]->myDocument = new SMESHDS_Document(studyId); - } - StudyContextStruct *myStudyContext = _mapStudyContext[studyId]; -// ASSERT(_mapStudyContext.find(studyId) != _mapStudyContext.end()); - return myStudyContext; + return GetAlgo( aMesh.GetSubMesh( aShape ), assignedTo ); } //============================================================================= /*! - * + * Finds algo to mesh a sub-mesh. Optionally returns a shape the found algo is bound to */ //============================================================================= -void SMESH_Gen::Save(int studyId, const char *aUrlOfFile) +SMESH_Algo *SMESH_Gen::GetAlgo(SMESH_subMesh * aSubMesh, + TopoDS_Shape* assignedTo) { -} + if ( !aSubMesh ) return 0; -//============================================================================= -/*! - * - */ -//============================================================================= + const TopoDS_Shape & aShape = aSubMesh->GetSubShape(); + SMESH_Mesh& aMesh = *aSubMesh->GetFather(); -void SMESH_Gen::Load(int studyId, const char *aUrlOfFile) -{ + SMESH_HypoFilter filter( SMESH_HypoFilter::IsAlgo() ); + filter.And( filter.IsApplicableTo( aShape )); + + typedef SMESH_Algo::Features AlgoData; + + TopoDS_Shape assignedToShape; + SMESH_Algo* algo = + (SMESH_Algo*) aMesh.GetHypothesis( aSubMesh, filter, true, &assignedToShape ); + + if ( algo && + aShape.ShapeType() == TopAbs_FACE && + !aShape.IsSame( assignedToShape ) && + SMESH_MesherHelper::NbAncestors( aShape, aMesh, TopAbs_SOLID ) > 1 ) + { + // Issue 0021559. If there is another 2D algo with different types of output + // elements that can be used to mesh aShape, and 3D algos on adjacent SOLIDs + // have different types of input elements, we choose a most appropriate 2D algo. + + // try to find a concurrent 2D algo + filter.AndNot( filter.Is( algo )); + TopoDS_Shape assignedToShape2; + SMESH_Algo* algo2 = + (SMESH_Algo*) aMesh.GetHypothesis( aSubMesh, filter, true, &assignedToShape2 ); + if ( algo2 && // algo found + !assignedToShape2.IsSame( aMesh.GetShapeToMesh() ) && // algo is local + ( SMESH_MesherHelper::GetGroupType( assignedToShape2 ) == // algo of the same level + SMESH_MesherHelper::GetGroupType( assignedToShape )) && + aMesh.IsOrderOK( aMesh.GetSubMesh( assignedToShape2 ), // no forced order + aMesh.GetSubMesh( assignedToShape ))) + { + // get algos on the adjacent SOLIDs + filter.Init( filter.IsAlgo() ).And( filter.HasDim( 3 )); + vector< SMESH_Algo* > algos3D; + PShapeIteratorPtr solidIt = SMESH_MesherHelper::GetAncestors( aShape, aMesh, + TopAbs_SOLID ); + while ( const TopoDS_Shape* solid = solidIt->next() ) + if ( SMESH_Algo* algo3D = (SMESH_Algo*) aMesh.GetHypothesis( *solid, filter, true )) + { + algos3D.push_back( algo3D ); + filter.AndNot( filter.HasName( algo3D->GetName() )); + } + // check compatibility of algos + if ( algos3D.size() > 1 ) + { + const AlgoData& algoData = algo->SMESH_Algo::GetFeatures(); + const AlgoData& algoData2 = algo2->SMESH_Algo::GetFeatures(); + const AlgoData& algoData3d0 = algos3D[0]->SMESH_Algo::GetFeatures(); + const AlgoData& algoData3d1 = algos3D[1]->SMESH_Algo::GetFeatures(); + if (( algoData2.IsCompatible( algoData3d0 ) && + algoData2.IsCompatible( algoData3d1 )) + && + !(algoData.IsCompatible( algoData3d0 ) && + algoData.IsCompatible( algoData3d1 ))) + algo = algo2; + } + } + } + + if ( assignedTo && algo ) + * assignedTo = assignedToShape; + + return algo; } //============================================================================= /*! - * + * Returns StudyContextStruct for a study */ //============================================================================= -void SMESH_Gen::Close(int studyId) +StudyContextStruct *SMESH_Gen::GetStudyContext(int studyId) { + // Get studyContext, create it if it does'nt exist, with a SMESHDS_Document + + if (_mapStudyContext.find(studyId) == _mapStudyContext.end()) + { + _mapStudyContext[studyId] = new StudyContextStruct; + _mapStudyContext[studyId]->myDocument = new SMESHDS_Document(studyId); + } + StudyContextStruct *myStudyContext = _mapStudyContext[studyId]; + return myStudyContext; } -//============================================================================= +//================================================================================ /*! - * + * \brief Return shape dimension by TopAbs_ShapeEnum */ -//============================================================================= +//================================================================================ int SMESH_Gen::GetShapeDim(const TopAbs_ShapeEnum & aShapeType) { - int shapeDim = -1; // Shape dimension: 0D, 1D, 2D, 3D - int type = aShapeType;//.ShapeType(); - switch (type) - { - case TopAbs_COMPOUND: - case TopAbs_COMPSOLID: - case TopAbs_SOLID: - case TopAbs_SHELL: - { - shapeDim = 3; - break; - } - // case TopAbs_SHELL: - case TopAbs_FACE: - { - shapeDim = 2; - break; - } - case TopAbs_WIRE: - case TopAbs_EDGE: - { - shapeDim = 1; - break; - } - case TopAbs_VERTEX: - { - shapeDim = 0; - break; - } - } - return shapeDim; + static vector dim; + if ( dim.empty() ) + { + dim.resize( TopAbs_SHAPE, -1 ); + dim[ TopAbs_COMPOUND ] = MeshDim_3D; + dim[ TopAbs_COMPSOLID ] = MeshDim_3D; + dim[ TopAbs_SOLID ] = MeshDim_3D; + dim[ TopAbs_SHELL ] = MeshDim_2D; + dim[ TopAbs_FACE ] = MeshDim_2D; + dim[ TopAbs_WIRE ] = MeshDim_1D; + dim[ TopAbs_EDGE ] = MeshDim_1D; + dim[ TopAbs_VERTEX ] = MeshDim_0D; + } + return dim[ aShapeType ]; } //============================================================================= /*! - * + * Genarate a new id unique withing this Gen */ //============================================================================= int SMESH_Gen::GetANewId() { - //MESSAGE("SMESH_Gen::GetANewId"); - return _hypId++; + return _hypId++; }