-// Copyright (C) 2007-2008 CEA/DEN, EDF R&D, OPEN CASCADE
+// Copyright (C) 2007-2010 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
//
// See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
//
+
// SMESH SMESH : implementaion of SMESH idl descriptions
// File : SMESH_subMesh.cxx
// Author : Paul RASCLE, EDF
#include "utilities.h"
#include "OpUtil.hxx"
+#include "Basics_Utils.hxx"
#include <BRep_Builder.hxx>
#include <BRep_Tool.hxx>
#include <Standard_OutOfMemory.hxx>
#include <Standard_ErrorHandler.hxx>
+#include <numeric>
+
using namespace std;
//=============================================================================
break; // the rest subMeshes are all of less dimension
SMESHDS_SubMesh * ds = sm->GetSubMeshDS();
bool computeOk = (sm->GetComputeState() == COMPUTE_OK ||
- (ds && ( ds->NbNodes() || ds->NbElements() )));
+ (ds && ( dimToCheck ? ds->NbElements() : ds->NbNodes() )));
if (!computeOk)
{
int type = ss.ShapeType();
case TopAbs_COMPOUND:
{
//MESSAGE("compound");
- for (TopExp_Explorer exp(_subShape, TopAbs_SOLID); exp.More();
- exp.Next())
+ for (TopExp_Explorer exp(_subShape, TopAbs_SOLID); exp.More();exp.Next())
{
InsertDependence(exp.Current());
}
- for (TopExp_Explorer exp(_subShape, TopAbs_SHELL, TopAbs_SOLID); exp.More();
- exp.Next())
+ for (TopExp_Explorer exp(_subShape, TopAbs_SHELL, TopAbs_SOLID); exp.More(); exp.Next())
{
+ if ( BRep_Tool::IsClosed(exp.Current() ))
InsertDependence(exp.Current()); //only shell not in solid
+ else
+ for (TopExp_Explorer expF(exp.Current(), TopAbs_FACE); expF.More();expF.Next())
+ InsertDependence(expF.Current()); // issue 0020959: HEXA_3D fails on shell
+
}
- for (TopExp_Explorer exp(_subShape, TopAbs_FACE, TopAbs_SHELL); exp.More();
- exp.Next())
+ for (TopExp_Explorer exp(_subShape, TopAbs_FACE, TopAbs_SHELL); exp.More();exp.Next())
{
InsertDependence(exp.Current());
}
- for (TopExp_Explorer exp(_subShape, TopAbs_EDGE, TopAbs_FACE); exp.More();
- exp.Next())
+ for (TopExp_Explorer exp(_subShape, TopAbs_EDGE, TopAbs_FACE); exp.More();exp.Next())
{
InsertDependence(exp.Current());
}
}
case TopAbs_COMPSOLID:
{
- //MESSAGE("compsolid");
- for (TopExp_Explorer exp(_subShape, TopAbs_SOLID); exp.More();
- exp.Next())
+ //MESSAGE("compsolid");
+ for (TopExp_Explorer exp(_subShape, TopAbs_SOLID); exp.More(); exp.Next())
{
InsertDependence(exp.Current());
}
case TopAbs_SHELL:
{
//MESSAGE("shell");
- for (TopExp_Explorer exp(_subShape, TopAbs_FACE); exp.More();
- exp.Next())
+ for (TopExp_Explorer exp(_subShape, TopAbs_FACE); exp.More(); exp.Next())
{
InsertDependence(exp.Current());
}
case TopAbs_WIRE:
{
//MESSAGE("wire");
- for (TopExp_Explorer exp(_subShape, TopAbs_EDGE); exp.More();
- exp.Next())
+ for (TopExp_Explorer exp(_subShape, TopAbs_EDGE); exp.More(); exp.Next())
{
InsertDependence(exp.Current());
}
{
//MESSAGE("solid");
if(_father->HasShapeToMesh()) {
- for (TopExp_Explorer exp(_subShape, TopAbs_FACE); exp.More();
- exp.Next())
+ for (TopExp_Explorer exp(_subShape, TopAbs_FACE); exp.More();exp.Next())
{
InsertDependence(exp.Current());
}
case TopAbs_FACE:
{
//MESSAGE("face");
- for (TopExp_Explorer exp(_subShape, TopAbs_EDGE); exp.More();
- exp.Next())
+ for (TopExp_Explorer exp(_subShape, TopAbs_EDGE); exp.More();exp.Next())
{
InsertDependence(exp.Current());
}
case TopAbs_EDGE:
{
//MESSAGE("edge");
- for (TopExp_Explorer exp(_subShape, TopAbs_VERTEX); exp.More();
- exp.Next())
+ for (TopExp_Explorer exp(_subShape, TopAbs_VERTEX); exp.More(); exp.Next())
{
- InsertDependence(exp.Current());
- }
+ InsertDependence(exp.Current());
+ }
break;
}
case TopAbs_VERTEX:
if ( ret == SMESH_Hypothesis::HYP_OK &&
!algo->NeedDescretBoundary() &&
!algo->SupportSubmeshes()) {
+ TopoDS_Shape algoAssignedTo, otherAssignedTo;
+ gen->GetAlgo( *_father, _subShape, &algoAssignedTo );
map<int, SMESH_subMesh*>::reverse_iterator i_sm = _mapDepend.rbegin();
for ( ; ( ret == SMESH_Hypothesis::HYP_OK && i_sm != _mapDepend.rend()) ; ++i_sm )
- if ( gen->GetAlgo( *_father, i_sm->second->_subShape ))
+ if ( gen->GetAlgo( *_father, i_sm->second->_subShape, &otherAssignedTo ) &&
+ SMESH_MesherHelper::IsSubShape( /*sub=*/otherAssignedTo, /*main=*/algoAssignedTo ))
ret = SMESH_Hypothesis::HYP_HIDING_ALGO;
}
}
algo->InitComputeError();
MemoryReserve aMemoryReserve;
SMDS_Mesh::CheckMemory();
+ Kernel_Utils::Localizer loc;
if ( !_father->HasShapeToMesh() ) // no shape
{
SMESH_MesherHelper helper( *_father );
else
ret = false;
}
- if (ret && !_alwaysComputed && shape == _subShape) { // check if anything was built
- ret = ( GetSubMeshDS() && ( GetSubMeshDS()->NbElements() || GetSubMeshDS()->NbNodes() ));
+ TopExp_Explorer subS(shape, _subShape.ShapeType());
+ if (ret) // check if anything was built
+ {
+ for (; ret && subS.More(); subS.Next())
+ ret = _father->GetSubMesh( subS.Current() )->IsMeshComputed();
}
bool isComputeErrorSet = !CheckComputeError( algo, shape );
if (!ret && !isComputeErrorSet)
{
// Set _computeError
- if ( !_computeError )
- _computeError = SMESH_ComputeError::New();
- if ( _computeError->IsOK() )
- _computeError->myName = COMPERR_ALGO_FAILED;
- _computeState = FAILED_TO_COMPUTE;
+ for (subS.ReInit(); subS.More(); subS.Next())
+ {
+ SMESH_subMesh* sm = _father->GetSubMesh( subS.Current() );
+ if ( !sm->IsMeshComputed() )
+ {
+ if ( !sm->_computeError )
+ sm->_computeError = SMESH_ComputeError::New();
+ if ( sm->_computeError->IsOK() )
+ sm->_computeError->myName = COMPERR_ALGO_FAILED;
+ sm->_computeState = FAILED_TO_COMPUTE;
+ sm->_computeError->myAlgo = algo;
+ }
+ }
}
if (ret)
{
ComputeSubMeshStateEngine( CHECK_COMPUTE_STATE );
break;
case CHECK_COMPUTE_STATE:
- if ( !IsMeshComputed() )
+ if ( !IsMeshComputed() ) {
if (_algoState == HYP_OK)
_computeState = READY_TO_COMPUTE;
else
_computeState = NOT_READY;
+ }
break;
default:
ASSERT(0);
switch (event)
{
case MODIF_ALGO_STATE:
+ if ( !IsEmpty() )
+ ComputeStateEngine( CLEAN );
algo = gen->GetAlgo((*_father), _subShape);
if (algo && !algo->NeedDescretBoundary())
CleanDependsOn(); // clean sub-meshes with event CLEAN
bool ret = true;
if (_subShape.ShapeType() == TopAbs_VERTEX) {
- std::vector<int> aVec(SMDSEntity_Last);
- for(int i= SMDSEntity_Node; i < SMDSEntity_Last; i++)
- aVec[i] = 0;
+ vector<int> aVec(SMDSEntity_Last,0);
aVec[SMDSEntity_Node] = 1;
- aResMap.insert(std::make_pair(this,aVec));
+ aResMap.insert(make_pair(this,aVec));
return ret;
}
SMESH_Hypothesis::Hypothesis_Status hyp_status;
algo = gen->GetAlgo((*_father), _subShape);
- if(algo) {
+ if(algo && !aResMap.count(this) )
+ {
ret = algo->CheckHypothesis((*_father), _subShape, hyp_status);
if (!ret) return false;
- TopoDS_Shape shape = _subShape;
-
+ if (_father->HasShapeToMesh() && algo->NeedDescretBoundary())
+ {
+ // check submeshes needed
+ bool subMeshEvaluated = true;
+ int dimToCheck = SMESH_Gen::GetShapeDim( _subShape ) - 1;
+ SMESH_subMeshIteratorPtr smIt = getDependsOnIterator(false,/*complexShapeFirst=*/true);
+ while ( smIt->more() && subMeshEvaluated )
+ {
+ SMESH_subMesh* sm = smIt->next();
+ int dim = SMESH_Gen::GetShapeDim( sm->GetSubShape() );
+ if (dim < dimToCheck) break; // the rest subMeshes are all of less dimension
+ const vector<int> & nbs = aResMap[ sm ];
+ subMeshEvaluated = (std::accumulate( nbs.begin(), nbs.end(), 0 ) > 0 );
+ }
+ if ( !subMeshEvaluated )
+ return false;
+ }
_computeError = SMESH_ComputeError::New(COMPERR_OK,"",algo);
+ ret = algo->Evaluate((*_father), _subShape, aResMap);
- ret = algo->Evaluate((*_father), shape, aResMap);
+ aResMap.insert( make_pair( this,vector<int>(0)));
}
return ret;
// Check my state
if ( !_computeError || _computeError->IsOK() )
{
- _computeState = COMPUTE_OK;
+ _computeState = IsMeshComputed() ? COMPUTE_OK : FAILED_TO_COMPUTE;
}
else
{
* \brief Notify stored event listeners on the occured event
* \param event - algo_event or compute_event itself
* \param eventType - algo_event or compute_event
- * \param subMesh - the submesh where the event occures
- * \param data - listener data stored in the subMesh
* \param hyp - hypothesis, if eventType is algo_event
*/
//================================================================================
{
map< EventListener*, EventListenerData* >::iterator l_d = myEventListeners.begin();
for ( ; l_d != myEventListeners.end(); ++l_d )
- l_d->first->ProcessEvent( event, eventType, this, l_d->second, hyp );
+ if ( (*l_d).first->myBusySM.insert( this ).second )
+ {
+ l_d->first->ProcessEvent( event, eventType, this, l_d->second, hyp );
+ l_d->first->myBusySM.erase( this );
+ }
}
//================================================================================