// 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
+// See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
//
//
//
#include "SMESH_Gen.hxx"
#include "SMESH_Hypothesis.hxx"
#include "SMESH_Group.hxx"
+#include "SMESH_HypoFilter.hxx"
#include "SMESHDS_Group.hxx"
#include "SMESHDS_Script.hxx"
#include "SMESHDS_GroupOnGeom.hxx"
#include <TopTools_ListOfShape.hxx>
#include <TopTools_Array1OfShape.hxx>
#include <TopTools_ListIteratorOfListOfShape.hxx>
+#include <TopTools_MapOfShape.hxx>
#include <memory>
#include "Utils_ExceptHandlers.hxx"
+// maximum stored group name length in MED file
+#define MAX_MED_GROUP_NAME_LENGTH 80
+
#ifdef _DEBUG_
static int MYDEBUG = 0;
#else
*/
//=============================================================================
-SMESH_Mesh::SMESH_Mesh(int localId, int studyId, SMESH_Gen * gen, SMESHDS_Document * myDocument)
-: _groupId( 0 )
+SMESH_Mesh::SMESH_Mesh(int theLocalId,
+ int theStudyId,
+ SMESH_Gen* theGen,
+ bool theIsEmbeddedMode,
+ SMESHDS_Document* theDocument):
+ _groupId( 0 )
{
INFOS("SMESH_Mesh::SMESH_Mesh(int localId)");
- _id = localId;
- _studyId = studyId;
- _gen = gen;
- _myDocument = myDocument;
- _idDoc = _myDocument->NewMesh();
- _myMeshDS = _myDocument->GetMesh(_idDoc);
- _isShapeToMesh = false;
+ _id = theLocalId;
+ _studyId = theStudyId;
+ _gen = theGen;
+ _myDocument = theDocument;
+ _idDoc = theDocument->NewMesh(theIsEmbeddedMode);
+ _myMeshDS = theDocument->GetMesh(_idDoc);
+ _isShapeToMesh = false;
}
//=============================================================================
else
i_gr++;
}
- _mapAncestors.Clear();
_mapPropagationChains.Clear();
}
else
}
_isShapeToMesh = true;
_myMeshDS->ShapeToMesh(aShape);
+
+ // fill _mapAncestors
+ _mapAncestors.Clear();
+ int desType, ancType;
+ for ( desType = TopAbs_VERTEX; desType > TopAbs_COMPOUND; desType-- )
+ for ( ancType = desType - 1; ancType >= TopAbs_COMPOUND; ancType-- )
+ TopExp::MapShapesAndAncestors ( aShape,
+ (TopAbs_ShapeEnum) desType,
+ (TopAbs_ShapeEnum) ancType,
+ _mapAncestors );
+
// NRI : 24/02/03
//EAP: 1/9/04 TopExp::MapShapes(aShape, _subShapes); USE the same map of _myMeshDS
}
myReader.SetMeshId(-1);
myReader.Perform();
if(MYDEBUG){
- MESSAGE("MEDToMesh - _myMeshDS->NbNodes() = "<<_myMeshDS->NbNodes());
- MESSAGE("MEDToMesh - _myMeshDS->NbEdges() = "<<_myMeshDS->NbEdges());
- MESSAGE("MEDToMesh - _myMeshDS->NbFaces() = "<<_myMeshDS->NbFaces());
- MESSAGE("MEDToMesh - _myMeshDS->NbVolumes() = "<<_myMeshDS->NbVolumes());
+ MESSAGE("UNVToMesh - _myMeshDS->NbNodes() = "<<_myMeshDS->NbNodes());
+ MESSAGE("UNVToMesh - _myMeshDS->NbEdges() = "<<_myMeshDS->NbEdges());
+ MESSAGE("UNVToMesh - _myMeshDS->NbFaces() = "<<_myMeshDS->NbFaces());
+ MESSAGE("UNVToMesh - _myMeshDS->NbVolumes() = "<<_myMeshDS->NbVolumes());
+ }
+ SMDS_MeshGroup* aGroup = (SMDS_MeshGroup*) myReader.GetGroup();
+ if (aGroup != 0) {
+ TGroupNamesMap aGroupNames = myReader.GetGroupNamesMap();
+ //const TGroupIdMap& aGroupId = myReader.GetGroupIdMap();
+ aGroup->InitSubGroupsIterator();
+ while (aGroup->MoreSubGroups()) {
+ SMDS_MeshGroup* aSubGroup = (SMDS_MeshGroup*) aGroup->NextSubGroup();
+ std::string aName = aGroupNames[aSubGroup];
+ int aId;
+
+ SMESH_Group* aSMESHGroup = AddGroup( aSubGroup->GetType(), aName.c_str(), aId );
+ if ( aSMESHGroup ) {
+ if(MYDEBUG) MESSAGE("UNVToMesh - group added: "<<aName);
+ SMESHDS_Group* aGroupDS = dynamic_cast<SMESHDS_Group*>( aSMESHGroup->GetGroupDS() );
+ if ( aGroupDS ) {
+ aGroupDS->SetStoreName(aName.c_str());
+ aSubGroup->InitIterator();
+ const SMDS_MeshElement* aElement = 0;
+ while (aSubGroup->More()) {
+ aElement = aSubGroup->Next();
+ if (aElement) {
+ aGroupDS->SMDSGroup().Add(aElement);
+ }
+ }
+ if (aElement)
+ aGroupDS->SetType(aElement->GetType());
+ }
+ }
+ }
}
return 1;
}
}
// Reading groups (sub-meshes are out of scope of MED import functionality)
- list<string> aGroupNames = myReader.GetGroupNames();
+ list<TNameAndType> aGroupNames = myReader.GetGroupNamesAndTypes();
if(MYDEBUG) MESSAGE("MEDToMesh - Nb groups = "<<aGroupNames.size());
int anId;
- for ( list<string>::iterator it = aGroupNames.begin(); it != aGroupNames.end(); it++ ) {
- SMESH_Group* aGroup = AddGroup( SMDSAbs_All, it->c_str(), anId );
+ list<TNameAndType>::iterator name_type = aGroupNames.begin();
+ for ( ; name_type != aGroupNames.end(); name_type++ ) {
+ SMESH_Group* aGroup = AddGroup( name_type->second, name_type->first.c_str(), anId );
if ( aGroup ) {
- if(MYDEBUG) MESSAGE("MEDToMesh - group added: "<<it->c_str());
+ if(MYDEBUG) MESSAGE("MEDToMesh - group added: "<<name_type->first.c_str());
SMESHDS_Group* aGroupDS = dynamic_cast<SMESHDS_Group*>( aGroup->GetGroupDS() );
if ( aGroupDS ) {
- aGroupDS->SetStoreName( it->c_str() );
+ aGroupDS->SetStoreName( name_type->first.c_str() );
myReader.GetGroup( aGroupDS );
}
}
int SMESH_Mesh::STLToMesh(const char* theFileName)
{
- if(MYDEBUG) MESSAGE("UNVToMesh - theFileName = "<<theFileName);
+ if(MYDEBUG) MESSAGE("STLToMesh - theFileName = "<<theFileName);
if(_isShapeToMesh)
throw SALOME_Exception(LOCALIZED("a shape to mesh has already been defined"));
_isShapeToMesh = true;
myReader.SetMeshId(-1);
myReader.Perform();
if(MYDEBUG){
- MESSAGE("MEDToMesh - _myMeshDS->NbNodes() = "<<_myMeshDS->NbNodes());
- MESSAGE("MEDToMesh - _myMeshDS->NbEdges() = "<<_myMeshDS->NbEdges());
- MESSAGE("MEDToMesh - _myMeshDS->NbFaces() = "<<_myMeshDS->NbFaces());
- MESSAGE("MEDToMesh - _myMeshDS->NbVolumes() = "<<_myMeshDS->NbVolumes());
+ MESSAGE("STLToMesh - _myMeshDS->NbNodes() = "<<_myMeshDS->NbNodes());
+ MESSAGE("STLToMesh - _myMeshDS->NbEdges() = "<<_myMeshDS->NbEdges());
+ MESSAGE("STLToMesh - _myMeshDS->NbFaces() = "<<_myMeshDS->NbFaces());
+ MESSAGE("STLToMesh - _myMeshDS->NbVolumes() = "<<_myMeshDS->NbVolumes());
}
return 1;
}
if(MYDEBUG) MESSAGE("SMESH_Mesh::AddHypothesis");
SMESH_subMesh *subMesh = GetSubMesh(aSubShape);
+ if ( !subMesh || !subMesh->GetId())
+ return SMESH_Hypothesis::HYP_BAD_SUBSHAPE;
+
SMESHDS_SubMesh *subMeshDS = subMesh->GetSubMeshDS();
- if ( subMeshDS && subMeshDS->IsComplexSubmesh() )
+ if ( subMeshDS && subMeshDS->IsComplexSubmesh() ) // group of sub-shapes and maybe of not sub-
{
+ MESSAGE("AddHypothesis() to complex submesh");
// return the worst but not fatal state of all group memebers
SMESH_Hypothesis::Hypothesis_Status aBestRet, aWorstNotFatal, ret;
aBestRet = SMESH_Hypothesis::HYP_BAD_DIM;
aWorstNotFatal = SMESH_Hypothesis::HYP_OK;
for ( TopoDS_Iterator itS ( aSubShape ); itS.More(); itS.Next())
{
+ if ( !GetMeshDS()->ShapeToIndex( itS.Value() ))
+ continue; // not sub-shape
ret = AddHypothesis( itS.Value(), anHypId );
if ( !SMESH_Hypothesis::IsStatusFatal( ret ) && ret > aWorstNotFatal )
aWorstNotFatal = ret;
aWorstNotFatal = SMESH_Hypothesis::HYP_OK;
for ( TopoDS_Iterator itS ( aSubShape ); itS.More(); itS.Next())
{
+ if ( !GetMeshDS()->ShapeToIndex( itS.Value() ))
+ continue; // not sub-shape
ret = RemoveHypothesis( itS.Value(), anHypId );
if ( !SMESH_Hypothesis::IsStatusFatal( ret ) && ret > aWorstNotFatal )
aWorstNotFatal = ret;
return _myMeshDS->GetHypothesis(aSubShape);
}
+//=======================================================================
+//function : GetHypothesis
+//purpose :
+//=======================================================================
+
+const SMESH_Hypothesis * SMESH_Mesh::GetHypothesis(const TopoDS_Shape & aSubShape,
+ const SMESH_HypoFilter& aFilter,
+ const bool andAncestors) const
+{
+ {
+ const list<const SMESHDS_Hypothesis*>& hypList = _myMeshDS->GetHypothesis(aSubShape);
+ list<const SMESHDS_Hypothesis*>::const_iterator hyp = hypList.begin();
+ for ( ; hyp != hypList.end(); hyp++ ) {
+ const SMESH_Hypothesis * h = static_cast<const SMESH_Hypothesis*>( *hyp );
+ if ( aFilter.IsOk( h, aSubShape))
+ return h;
+ }
+ }
+ if ( andAncestors )
+ {
+ TopTools_ListIteratorOfListOfShape it( GetAncestors( aSubShape ));
+ for (; it.More(); it.Next() )
+ {
+ const list<const SMESHDS_Hypothesis*>& hypList = _myMeshDS->GetHypothesis(it.Value());
+ list<const SMESHDS_Hypothesis*>::const_iterator hyp = hypList.begin();
+ for ( ; hyp != hypList.end(); hyp++ ) {
+ const SMESH_Hypothesis * h = static_cast<const SMESH_Hypothesis*>( *hyp );
+ if (aFilter.IsOk( h, it.Value() ))
+ return h;
+ }
+ }
+ }
+ return 0;
+}
+
+//=======================================================================
+//function : GetHypotheses
+//purpose :
+//=======================================================================
+
+//================================================================================
+/*!
+ * \brief Return hypothesis assigned to the shape
+ * \param aSubShape - the shape to check
+ * \param aFilter - the hypothesis filter
+ * \param aHypList - the list of the found hypotheses
+ * \param andAncestors - flag to check hypos assigned to ancestors of the shape
+ * \retval int - number of unique hypos in aHypList
+ */
+//================================================================================
+
+int SMESH_Mesh::GetHypotheses(const TopoDS_Shape & aSubShape,
+ const SMESH_HypoFilter& aFilter,
+ list <const SMESHDS_Hypothesis * >& aHypList,
+ const bool andAncestors) const
+{
+ set<string> hypTypes; // to exclude same type hypos from the result list
+ int nbHyps = 0;
+
+ // fill in hypTypes
+ list<const SMESHDS_Hypothesis*>::const_iterator hyp;
+ for ( hyp = aHypList.begin(); hyp != aHypList.end(); hyp++ )
+ if ( hypTypes.insert( (*hyp)->GetName() ).second )
+ nbHyps++;
+
+ // get hypos from aSubShape
+ {
+ const list<const SMESHDS_Hypothesis*>& hypList = _myMeshDS->GetHypothesis(aSubShape);
+ for ( hyp = hypList.begin(); hyp != hypList.end(); hyp++ )
+ if ( aFilter.IsOk (static_cast<const SMESH_Hypothesis*>( *hyp ), aSubShape) &&
+ hypTypes.insert( (*hyp)->GetName() ).second )
+ {
+ aHypList.push_back( *hyp );
+ nbHyps++;
+ }
+ }
+
+ // get hypos from ancestors of aSubShape
+ if ( andAncestors )
+ {
+ TopTools_MapOfShape map;
+ TopTools_ListIteratorOfListOfShape it( GetAncestors( aSubShape ));
+ for (; it.More(); it.Next() )
+ {
+ if ( !map.Add( it.Value() ))
+ continue;
+ const list<const SMESHDS_Hypothesis*>& hypList = _myMeshDS->GetHypothesis(it.Value());
+ for ( hyp = hypList.begin(); hyp != hypList.end(); hyp++ )
+ if (aFilter.IsOk( static_cast<const SMESH_Hypothesis*>( *hyp ), it.Value() ) &&
+ hypTypes.insert( (*hyp)->GetName() ).second ) {
+ aHypList.push_back( *hyp );
+ nbHyps++;
+ }
+ }
+ }
+ return nbHyps;
+}
+
//=============================================================================
/*!
*
//=============================================================================
SMESH_subMesh *SMESH_Mesh::GetSubMesh(const TopoDS_Shape & aSubShape)
-throw(SALOME_Exception)
+ throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
SMESH_subMesh *aSubMesh;
int index = _myMeshDS->ShapeToIndex(aSubShape);
-
+
// for submeshes on GEOM Group
if ( !index && aSubShape.ShapeType() == TopAbs_COMPOUND ) {
TopoDS_Iterator it( aSubShape );
if ( it.More() )
index = _myMeshDS->AddCompoundSubmesh( aSubShape, it.Value().ShapeType() );
}
+// if ( !index )
+// return NULL; // neither sub-shape nor a group
- if (_mapSubMesh.find(index) != _mapSubMesh.end())
- {
- aSubMesh = _mapSubMesh[index];
- }
+ map <int, SMESH_subMesh *>::iterator i_sm = _mapSubMesh.find(index);
+ if ( i_sm != _mapSubMesh.end())
+ {
+ aSubMesh = i_sm->second;
+ }
else
- {
- aSubMesh = new SMESH_subMesh(index, this, _myMeshDS, aSubShape);
- _mapSubMesh[index] = aSubMesh;
- }
+ {
+ aSubMesh = new SMESH_subMesh(index, this, _myMeshDS, aSubShape);
+ _mapSubMesh[index] = aSubMesh;
+ }
return aSubMesh;
}
//=============================================================================
SMESH_subMesh *SMESH_Mesh::GetSubMeshContaining(const TopoDS_Shape & aSubShape)
-throw(SALOME_Exception)
+ throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
- bool isFound = false;
SMESH_subMesh *aSubMesh = NULL;
int index = _myMeshDS->ShapeToIndex(aSubShape);
- if (_mapSubMesh.find(index) != _mapSubMesh.end())
- {
- aSubMesh = _mapSubMesh[index];
- isFound = true;
- }
- if (!isFound)
- aSubMesh = NULL;
+
+ map <int, SMESH_subMesh *>::iterator i_sm = _mapSubMesh.find(index);
+ if ( i_sm != _mapSubMesh.end())
+ aSubMesh = i_sm->second;
+
return aSubMesh;
}
+//=============================================================================
+/*!
+ * Get the SMESH_subMesh object implementation. Dont create it, return null
+ * if it does not exist.
+ */
+//=============================================================================
+
+SMESH_subMesh *SMESH_Mesh::GetSubMeshContaining(const int aShapeID)
+throw(SALOME_Exception)
+{
+ Unexpect aCatch(SalomeException);
+
+ map <int, SMESH_subMesh *>::iterator i_sm = _mapSubMesh.find(aShapeID);
+ if (i_sm == _mapSubMesh.end())
+ return NULL;
+ return i_sm->second;
+}
+
//=======================================================================
//function : IsUsedHypothesis
//purpose : Return True if anHyp is used to mesh aSubShape
//=======================================================================
bool SMESH_Mesh::IsUsedHypothesis(SMESHDS_Hypothesis * anHyp,
- const TopoDS_Shape & aSubShape)
+ const SMESH_subMesh* aSubMesh)
{
- // check if anHyp is applicable to aSubShape
- SMESH_subMesh * subMesh = GetSubMeshContaining( aSubShape );
- if (!subMesh ||
- !subMesh->IsApplicableHypotesis(static_cast<SMESH_Hypothesis*>(anHyp)))
+ SMESH_Hypothesis* hyp = static_cast<SMESH_Hypothesis*>(anHyp);
+
+ // check if anHyp can be used to mesh aSubMesh
+ if ( !aSubMesh || !aSubMesh->IsApplicableHypotesis( hyp ))
return false;
- SMESH_Algo *algo = _gen->GetAlgo(*this, aSubShape);
+ const TopoDS_Shape & aSubShape = const_cast<SMESH_subMesh*>( aSubMesh )->GetSubShape();
+
+ SMESH_Algo *algo = _gen->GetAlgo(*this, aSubShape );
// algorithm
if (anHyp->GetType() > SMESHDS_Hypothesis::PARAM_ALGO)
if (algo)
{
// look trough hypotheses used by algo
- const list <const SMESHDS_Hypothesis * >&usedHyps =
- algo->GetUsedHypothesis(*this, aSubShape);
- list <const SMESHDS_Hypothesis * >::const_iterator itl;
- for (itl = usedHyps.begin(); itl != usedHyps.end(); itl++)
- if (anHyp == (*itl))
- return true;
- }
- else
- {
- // look through all assigned hypotheses
- {
- const list <const SMESHDS_Hypothesis * >&usedHyps =
- _myMeshDS->GetHypothesis( aSubShape );
- list <const SMESHDS_Hypothesis * >::const_iterator itl;
- for (itl = usedHyps.begin(); itl != usedHyps.end(); itl++)
- if (anHyp == (*itl))
- return true;
- }
-
- // on ancestors
- TopTools_ListIteratorOfListOfShape it( GetAncestors( aSubShape ));
- for (; it.More(); it.Next())
- {
- const list <const SMESHDS_Hypothesis * >&usedHyps =
- _myMeshDS->GetHypothesis( aSubShape );
- list <const SMESHDS_Hypothesis * >::const_iterator itl;
- for (itl = usedHyps.begin(); itl != usedHyps.end(); itl++)
- if (anHyp == (*itl))
- return true;
+ SMESH_HypoFilter hypoKind;
+ if ( algo->InitCompatibleHypoFilter( hypoKind, !hyp->IsAuxiliary() )) {
+ list <const SMESHDS_Hypothesis * > usedHyps;
+ if ( GetHypotheses( aSubShape, hypoKind, usedHyps, true ))
+ return ( find( usedHyps.begin(), usedHyps.end(), anHyp ) != usedHyps.end() );
}
}
-
- return false;
-}
+ // look through all assigned hypotheses
+ //SMESH_HypoFilter filter( SMESH_HypoFilter::Is( hyp ));
+ return false; //GetHypothesis( aSubShape, filter, true );
+}
//=============================================================================
/*!
//=============================================================================
const list < SMESH_subMesh * >&
- SMESH_Mesh::GetSubMeshUsingHypothesis(SMESHDS_Hypothesis * anHyp)
-throw(SALOME_Exception)
+SMESH_Mesh::GetSubMeshUsingHypothesis(SMESHDS_Hypothesis * anHyp)
+ throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
- if(MYDEBUG) MESSAGE("SMESH_Mesh::GetSubMeshUsingHypothesis");
- map < int, SMESH_subMesh * >::iterator itsm;
- _subMeshesUsingHypothesisList.clear();
- for (itsm = _mapSubMesh.begin(); itsm != _mapSubMesh.end(); itsm++)
- {
- SMESH_subMesh *aSubMesh = (*itsm).second;
- if ( IsUsedHypothesis ( anHyp, aSubMesh->GetSubShape() ))
- _subMeshesUsingHypothesisList.push_back(aSubMesh);
- }
- return _subMeshesUsingHypothesisList;
+ if(MYDEBUG) MESSAGE("SMESH_Mesh::GetSubMeshUsingHypothesis");
+ map < int, SMESH_subMesh * >::iterator itsm;
+ _subMeshesUsingHypothesisList.clear();
+ for (itsm = _mapSubMesh.begin(); itsm != _mapSubMesh.end(); itsm++)
+ {
+ SMESH_subMesh *aSubMesh = (*itsm).second;
+ if ( IsUsedHypothesis ( anHyp, aSubMesh ))
+ _subMeshesUsingHypothesisList.push_back(aSubMesh);
+ }
+ return _subMeshesUsingHypothesisList;
+}
+
+//=======================================================================
+//function : NotifySubMeshesHypothesisModification
+//purpose : Say all submeshes using theChangedHyp that it has been modified
+//=======================================================================
+
+void SMESH_Mesh::NotifySubMeshesHypothesisModification(const SMESH_Hypothesis* theChangedHyp)
+{
+ Unexpect aCatch(SalomeException);
+
+ const SMESH_Hypothesis* hyp = static_cast<const SMESH_Hypothesis*>(theChangedHyp);
+
+ const SMESH_Algo *foundAlgo = 0;
+ SMESH_HypoFilter algoKind( SMESH_HypoFilter::IsAlgo() );
+ SMESH_HypoFilter compatibleHypoKind;
+ list <const SMESHDS_Hypothesis * > usedHyps;
+
+
+ map < int, SMESH_subMesh * >::iterator itsm;
+ for (itsm = _mapSubMesh.begin(); itsm != _mapSubMesh.end(); itsm++)
+ {
+ SMESH_subMesh *aSubMesh = (*itsm).second;
+ if ( aSubMesh->IsApplicableHypotesis( hyp ))
+ {
+ const TopoDS_Shape & aSubShape = aSubMesh->GetSubShape();
+
+ if ( !foundAlgo ) // init filter for algo search
+ algoKind.And( algoKind.IsApplicableTo( aSubShape ));
+
+ const SMESH_Algo *algo = static_cast<const SMESH_Algo*>
+ ( GetHypothesis( aSubShape, algoKind, true ));
+
+ if ( algo )
+ {
+ bool sameAlgo = ( algo == foundAlgo );
+ if ( !sameAlgo && foundAlgo )
+ sameAlgo = ( strcmp( algo->GetName(), foundAlgo->GetName() ) == 0);
+
+ if ( !sameAlgo ) { // init filter for used hypos search
+ if ( !algo->InitCompatibleHypoFilter( compatibleHypoKind, !hyp->IsAuxiliary() ))
+ continue; // algo does not use any hypothesis
+ foundAlgo = algo;
+ }
+
+ // check if hyp is used by algo
+ usedHyps.clear();
+ if ( GetHypotheses( aSubShape, compatibleHypoKind, usedHyps, true ) &&
+ find( usedHyps.begin(), usedHyps.end(), hyp ) != usedHyps.end() )
+ {
+ aSubMesh->ComputeStateEngine(SMESH_subMesh::MODIF_HYP);
+
+ if ( algo->GetDim() == 1 && IsPropagationHypothesis( aSubShape ))
+ CleanMeshOnPropagationChain( aSubShape );
+ }
+ }
+ }
+ }
}
//=============================================================================
-/*!
- *
+/*! Export* methods.
+ * To store mesh contents on disk in different formats.
*/
//=============================================================================
+bool SMESH_Mesh::HasDuplicatedGroupNamesMED()
+{
+ set<string> aGroupNames;
+ for ( map<int, SMESH_Group*>::iterator it = _mapGroup.begin(); it != _mapGroup.end(); it++ ) {
+ SMESH_Group* aGroup = it->second;
+ string aGroupName = aGroup->GetName();
+ aGroupName.resize(MAX_MED_GROUP_NAME_LENGTH);
+ if (!aGroupNames.insert(aGroupName).second)
+ return true;
+ }
+
+ return false;
+}
+
void SMESH_Mesh::ExportMED(const char *file,
const char* theMeshName,
bool theAutoGroups,
throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
+
DriverMED_W_SMESHDS_Mesh myWriter;
myWriter.SetFile ( file, MED::EVersion(theVersion) );
myWriter.SetMesh ( _myMeshDS );
myWriter.AddGroupOfVolumes();
}
+ // Pass groups to writer. Provide unique group names.
+ set<string> aGroupNames;
+ char aString [256];
+ int maxNbIter = 10000; // to guarantee cycle finish
for ( map<int, SMESH_Group*>::iterator it = _mapGroup.begin(); it != _mapGroup.end(); it++ ) {
SMESH_Group* aGroup = it->second;
SMESHDS_GroupBase* aGroupDS = aGroup->GetGroupDS();
if ( aGroupDS ) {
- aGroupDS->SetStoreName( aGroup->GetName() );
+ string aGroupName0 = aGroup->GetName();
+ aGroupName0.resize(MAX_MED_GROUP_NAME_LENGTH);
+ string aGroupName = aGroupName0;
+ for (int i = 1; !aGroupNames.insert(aGroupName).second && i < maxNbIter; i++) {
+ sprintf(&aString[0], "GR_%d_%s", i, aGroupName0.c_str());
+ aGroupName = aString;
+ aGroupName.resize(MAX_MED_GROUP_NAME_LENGTH);
+ }
+ aGroupDS->SetStoreName( aGroupName.c_str() );
myWriter.AddGroup( aGroupDS );
}
}
+ // Perform export
myWriter.Perform();
}
myWriter.SetFile(string(file));
myWriter.SetMesh(_myMeshDS);
myWriter.SetMeshId(_idDoc);
+ // myWriter.SetGroups(_mapGroup);
+
+ for ( map<int, SMESH_Group*>::iterator it = _mapGroup.begin(); it != _mapGroup.end(); it++ ) {
+ SMESH_Group* aGroup = it->second;
+ SMESHDS_GroupBase* aGroupDS = aGroup->GetGroupDS();
+ if ( aGroupDS ) {
+ string aGroupName = aGroup->GetName();
+ aGroupDS->SetStoreName( aGroupName.c_str() );
+ myWriter.AddGroup( aGroupDS );
+ }
+ }
myWriter.Perform();
}
*
*/
//=============================================================================
-int SMESH_Mesh::NbEdges() throw(SALOME_Exception)
+int SMESH_Mesh::NbEdges(ElementOrder order) throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
- return _myMeshDS->NbEdges();
+ if (order == ORDER_ANY)
+ return _myMeshDS->NbEdges();
+
+ int Nb = 0;
+ SMDS_EdgeIteratorPtr it = _myMeshDS->edgesIterator();
+ while (it->more()) {
+ const SMDS_MeshEdge* cur = it->next();
+ if ( order == ORDER_LINEAR && !cur->IsQuadratic() ||
+ order == ORDER_QUADRATIC && cur->IsQuadratic() )
+ Nb++;
+ }
+ return Nb;
}
//=============================================================================
*
*/
//=============================================================================
-int SMESH_Mesh::NbFaces() throw(SALOME_Exception)
+int SMESH_Mesh::NbFaces(ElementOrder order) throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
- return _myMeshDS->NbFaces();
+ if (order == ORDER_ANY)
+ return _myMeshDS->NbFaces();
+
+ int Nb = 0;
+ SMDS_FaceIteratorPtr it = _myMeshDS->facesIterator();
+ while (it->more()) {
+ const SMDS_MeshFace* cur = it->next();
+ if ( order == ORDER_LINEAR && !cur->IsQuadratic() ||
+ order == ORDER_QUADRATIC && cur->IsQuadratic() )
+ Nb++;
+ }
+ return Nb;
}
///////////////////////////////////////////////////////////////////////////////
/// Return the number of 3 nodes faces in the mesh. This method run in O(n)
///////////////////////////////////////////////////////////////////////////////
-int SMESH_Mesh::NbTriangles() throw(SALOME_Exception)
+int SMESH_Mesh::NbTriangles(ElementOrder order) throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
int Nb = 0;
SMDS_FaceIteratorPtr itFaces=_myMeshDS->facesIterator();
- while(itFaces->more()) if(itFaces->next()->NbNodes()==3) Nb++;
+ while (itFaces->more()) {
+ const SMDS_MeshFace* curFace = itFaces->next();
+ int nbnod = curFace->NbNodes();
+ if ( !curFace->IsPoly() &&
+ ( order == ORDER_ANY && (nbnod==3 || nbnod==6) ||
+ order == ORDER_LINEAR && nbnod==3 ||
+ order == ORDER_QUADRATIC && nbnod==6 ) )
+ Nb++;
+ }
return Nb;
}
///////////////////////////////////////////////////////////////////////////////
/// Return the number of 4 nodes faces in the mesh. This method run in O(n)
///////////////////////////////////////////////////////////////////////////////
-int SMESH_Mesh::NbQuadrangles() throw(SALOME_Exception)
+int SMESH_Mesh::NbQuadrangles(ElementOrder order) throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
int Nb = 0;
SMDS_FaceIteratorPtr itFaces=_myMeshDS->facesIterator();
- while(itFaces->more()) if(itFaces->next()->NbNodes()==4) Nb++;
+ while (itFaces->more()) {
+ const SMDS_MeshFace* curFace = itFaces->next();
+ int nbnod = curFace->NbNodes();
+ if ( !curFace->IsPoly() &&
+ ( order == ORDER_ANY && (nbnod==4 || nbnod==8) ||
+ order == ORDER_LINEAR && nbnod==4 ||
+ order == ORDER_QUADRATIC && nbnod==8 ) )
+ Nb++;
+ }
+ return Nb;
+}
+
+///////////////////////////////////////////////////////////////////////////////
+/// Return the number of polygonal faces in the mesh. This method run in O(n)
+///////////////////////////////////////////////////////////////////////////////
+int SMESH_Mesh::NbPolygons() throw(SALOME_Exception)
+{
+ Unexpect aCatch(SalomeException);
+ int Nb = 0;
+ SMDS_FaceIteratorPtr itFaces = _myMeshDS->facesIterator();
+ while (itFaces->more())
+ if (itFaces->next()->IsPoly()) Nb++;
return Nb;
}
*
*/
//=============================================================================
-int SMESH_Mesh::NbVolumes() throw(SALOME_Exception)
+int SMESH_Mesh::NbVolumes(ElementOrder order) throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
- return _myMeshDS->NbVolumes();
+ if (order == ORDER_ANY)
+ return _myMeshDS->NbVolumes();
+
+ int Nb = 0;
+ SMDS_VolumeIteratorPtr it = _myMeshDS->volumesIterator();
+ while (it->more()) {
+ const SMDS_MeshVolume* cur = it->next();
+ if ( order == ORDER_LINEAR && !cur->IsQuadratic() ||
+ order == ORDER_QUADRATIC && cur->IsQuadratic() )
+ Nb++;
+ }
+ return Nb;
}
-int SMESH_Mesh::NbTetras() throw(SALOME_Exception)
+int SMESH_Mesh::NbTetras(ElementOrder order) throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
int Nb = 0;
SMDS_VolumeIteratorPtr itVolumes=_myMeshDS->volumesIterator();
- while(itVolumes->more()) if(itVolumes->next()->NbNodes()==4) Nb++;
+ while (itVolumes->more()) {
+ const SMDS_MeshVolume* curVolume = itVolumes->next();
+ int nbnod = curVolume->NbNodes();
+ if ( !curVolume->IsPoly() &&
+ ( order == ORDER_ANY && (nbnod==4 || nbnod==10) ||
+ order == ORDER_LINEAR && nbnod==4 ||
+ order == ORDER_QUADRATIC && nbnod==10 ) )
+ Nb++;
+ }
return Nb;
}
-int SMESH_Mesh::NbHexas() throw(SALOME_Exception)
+int SMESH_Mesh::NbHexas(ElementOrder order) throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
int Nb = 0;
SMDS_VolumeIteratorPtr itVolumes=_myMeshDS->volumesIterator();
- while(itVolumes->more()) if(itVolumes->next()->NbNodes()==8) Nb++;
+ while (itVolumes->more()) {
+ const SMDS_MeshVolume* curVolume = itVolumes->next();
+ int nbnod = curVolume->NbNodes();
+ if ( !curVolume->IsPoly() &&
+ ( order == ORDER_ANY && (nbnod==8 || nbnod==20) ||
+ order == ORDER_LINEAR && nbnod==8 ||
+ order == ORDER_QUADRATIC && nbnod==20 ) )
+ Nb++;
+ }
return Nb;
}
-int SMESH_Mesh::NbPyramids() throw(SALOME_Exception)
+int SMESH_Mesh::NbPyramids(ElementOrder order) throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
int Nb = 0;
SMDS_VolumeIteratorPtr itVolumes=_myMeshDS->volumesIterator();
- while(itVolumes->more()) if(itVolumes->next()->NbNodes()==5) Nb++;
+ while (itVolumes->more()) {
+ const SMDS_MeshVolume* curVolume = itVolumes->next();
+ int nbnod = curVolume->NbNodes();
+ if ( !curVolume->IsPoly() &&
+ ( order == ORDER_ANY && (nbnod==5 || nbnod==13) ||
+ order == ORDER_LINEAR && nbnod==5 ||
+ order == ORDER_QUADRATIC && nbnod==13 ) )
+ Nb++;
+ }
return Nb;
}
-int SMESH_Mesh::NbPrisms() throw(SALOME_Exception)
+int SMESH_Mesh::NbPrisms(ElementOrder order) throw(SALOME_Exception)
{
Unexpect aCatch(SalomeException);
int Nb = 0;
SMDS_VolumeIteratorPtr itVolumes=_myMeshDS->volumesIterator();
- while(itVolumes->more()) if(itVolumes->next()->NbNodes()==6) Nb++;
+ while (itVolumes->more()) {
+ const SMDS_MeshVolume* curVolume = itVolumes->next();
+ int nbnod = curVolume->NbNodes();
+ if ( !curVolume->IsPoly() &&
+ ( order == ORDER_ANY && (nbnod==6 || nbnod==15) ||
+ order == ORDER_LINEAR && nbnod==6 ||
+ order == ORDER_QUADRATIC && nbnod==15 ) )
+ Nb++;
+ }
+ return Nb;
+}
+
+int SMESH_Mesh::NbPolyhedrons() throw(SALOME_Exception)
+{
+ Unexpect aCatch(SalomeException);
+ int Nb = 0;
+ SMDS_VolumeIteratorPtr itVolumes = _myMeshDS->volumesIterator();
+ while (itVolumes->more())
+ if (itVolumes->next()->IsPoly()) Nb++;
return Nb;
}
{
if(MYDEBUG) MESSAGE("SMESH_Mesh::IsNotConformAllowed");
- const list<const SMESHDS_Hypothesis*>& listHyp =
- _myMeshDS->GetHypothesis( _myMeshDS->ShapeToMesh() );
- list<const SMESHDS_Hypothesis*>::const_iterator it=listHyp.begin();
- while (it!=listHyp.end())
- {
- const SMESHDS_Hypothesis *aHyp = *it;
- string hypName = aHyp->GetName();
- if ( hypName == "NotConformAllowed" )
- return true;
- it++;
- }
- return false;
+ SMESH_HypoFilter filter( SMESH_HypoFilter::HasName( "NotConformAllowed" ));
+ return GetHypothesis( _myMeshDS->ShapeToMesh(), filter, false );
}
//=======================================================================
if (_mapGroup.find(theGroupID) == _mapGroup.end())
return;
GetMeshDS()->RemoveGroup( _mapGroup[theGroupID]->GetGroupDS() );
- _mapGroup.erase (theGroupID);
delete _mapGroup[theGroupID];
+ _mapGroup.erase (theGroupID);
}
//=============================================================================
/*!
* IsLocal1DHypothesis
- * Check, if there is 1D hypothesis assigned directly on <theEdge>
+ * Returns a local 1D hypothesis used for theEdge
*/
//=============================================================================
-bool SMESH_Mesh::IsLocal1DHypothesis (const TopoDS_Shape& theEdge)
+const SMESH_Hypothesis* SMESH_Mesh::IsLocal1DHypothesis (const TopoDS_Shape& theEdge)
{
- const SMESHDS_Mesh* meshDS = GetMeshDS();
- const list<const SMESHDS_Hypothesis*>& listHyp = meshDS->GetHypothesis(theEdge);
- list<const SMESHDS_Hypothesis*>::const_iterator it = listHyp.begin();
-
- for (; it != listHyp.end(); it++) {
- const SMESH_Hypothesis * aHyp = static_cast<const SMESH_Hypothesis*>(*it);
- if (aHyp->GetType() == SMESHDS_Hypothesis::PARAM_ALGO &&
- aHyp->GetDim() == 1) { // 1D Hypothesis found
- return true;
- }
- }
- return false;
+ SMESH_HypoFilter hypo ( SMESH_HypoFilter::HasDim( 1 ));
+ hypo.AndNot( hypo.IsAlgo() ).AndNot( hypo.IsAssignedTo( GetMeshDS()->ShapeToMesh() ));
+
+ return GetHypothesis( theEdge, hypo, true );
}
//=============================================================================
{
int nbChains = _mapPropagationChains.Extent();
for (int i = 1; i <= nbChains; i++) {
- const TopTools_IndexedMapOfShape& aChain = _mapPropagationChains.FindFromIndex(i);
+ //const TopTools_IndexedMapOfShape& aChain = _mapPropagationChains.FindFromIndex(i);
+ const SMESH_IndexedMapOfShape& aChain = _mapPropagationChains.FindFromIndex(i);
if (aChain.Contains(theEdge)) {
theMainEdge = _mapPropagationChains.FindKey(i);
return true;
if ( !theMainEdge.IsNull() && !theEdge.IsNull() &&
_mapPropagationChains.Contains( theMainEdge ))
{
- const TopTools_IndexedMapOfShape& aChain =
+ const SMESH_IndexedMapOfShape& aChain =
_mapPropagationChains.FindFromKey( theMainEdge );
int index = aChain.FindIndex( theEdge );
if ( index )
//=============================================================================
void SMESH_Mesh::CleanMeshOnPropagationChain (const TopoDS_Shape& theMainEdge)
{
- const TopTools_IndexedMapOfShape& aChain = _mapPropagationChains.FindFromKey(theMainEdge);
+ const SMESH_IndexedMapOfShape& aChain = _mapPropagationChains.FindFromKey(theMainEdge);
int i, nbEdges = aChain.Extent();
for (i = 1; i <= nbEdges; i++) {
TopoDS_Shape anEdge = aChain.FindKey(i);
SMESH_subMesh *subMesh = GetSubMesh(anEdge);
SMESHDS_SubMesh *subMeshDS = subMesh->GetSubMeshDS();
if (subMeshDS && subMeshDS->NbElements() > 0) {
- subMesh->ComputeStateEngine(SMESH_subMesh::CLEANDEP);
+ subMesh->ComputeStateEngine(SMESH_subMesh::CLEAN);
}
}
}
// Remove the chain from the map
int i = _mapPropagationChains.FindIndex(theMainEdge);
- TopoDS_Vertex anEmptyShape;
- BRep_Builder BB;
- BB.MakeVertex(anEmptyShape, gp_Pnt(0,0,0), 0.1);
- TopTools_IndexedMapOfShape anEmptyMap;
- _mapPropagationChains.Substitute(i, anEmptyShape, anEmptyMap);
+ if ( i == _mapPropagationChains.Extent() )
+ _mapPropagationChains.RemoveLast();
+ else {
+ TopoDS_Vertex anEmptyShape;
+ BRep_Builder BB;
+ BB.MakeVertex(anEmptyShape, gp_Pnt(0,0,0), 0.1);
+ SMESH_IndexedMapOfShape anEmptyMap;
+ _mapPropagationChains.Substitute(i, anEmptyShape, anEmptyMap);
+ }
return true;
}
// Add new chain, if there is no
if (!_mapPropagationChains.Contains(theMainEdge)) {
- TopTools_IndexedMapOfShape aNewChain;
+ SMESH_IndexedMapOfShape aNewChain;
_mapPropagationChains.Add(theMainEdge, aNewChain);
}
// Check presence of 1D hypothesis to be propagated
- if (!IsLocal1DHypothesis(theMainEdge)) {
+ const SMESH_Hypothesis* aMainHyp = IsLocal1DHypothesis(theMainEdge);
+ if (!aMainHyp) {
MESSAGE("Warning: There is no 1D hypothesis to propagate. Please, assign.");
return true;
}
// Edges, on which the 1D hypothesis will be propagated from <theMainEdge>
- TopTools_IndexedMapOfShape& aChain = _mapPropagationChains.ChangeFromKey(theMainEdge);
+ SMESH_IndexedMapOfShape& aChain = _mapPropagationChains.ChangeFromKey(theMainEdge);
if (aChain.Extent() > 0) {
CleanMeshOnPropagationChain(theMainEdge);
aChain.Clear();
if (opp > 4) opp -= 4;
anOppE = anEdges(opp);
- if (!aChain.Contains(anOppE)) {
- if (!IsLocal1DHypothesis(anOppE)) {
- TopoDS_Shape aMainEdgeForOppEdge;
- if (IsPropagatedHypothesis(anOppE, aMainEdgeForOppEdge)) {
- // Collision!
- MESSAGE("Error: Collision between propagated hypotheses");
- CleanMeshOnPropagationChain(theMainEdge);
- aChain.Clear();
- return false;
- } else {
+ // add anOppE to aChain if ...
+ if (!aChain.Contains(anOppE)) { // ... anOppE is not in aChain
+ if (!IsLocal1DHypothesis(anOppE)) { // ... no other 1d hyp on anOppE
+ TopoDS_Shape aMainEdgeForOppEdge; // ... no other hyp is propagated to anOppE
+ if (!IsPropagatedHypothesis(anOppE, aMainEdgeForOppEdge))
+ {
// Add found edge to the chain oriented so that to
- // have it in aChain co-directed with theMainEdge
+ // have it co-directed with a forward MainEdge
TopAbs_Orientation ori = anE.Orientation();
if ( anEdges(opp).Orientation() == anEdges(found).Orientation() )
ori = TopAbs::Reverse( ori );
aChain.Add(anOppE);
listCurEdges.Append(anOppE);
}
+ else {
+ // Collision!
+ MESSAGE("Error: Collision between propagated hypotheses");
+ CleanMeshOnPropagationChain(theMainEdge);
+ aChain.Clear();
+ return ( aMainHyp == IsLocal1DHypothesis(aMainEdgeForOppEdge) );
+ }
}
}
} // if (nb == 5 && found > 0)
// that lower dimention shapes come first.
//=======================================================================
-const TopTools_ListOfShape& SMESH_Mesh::GetAncestors(const TopoDS_Shape& theS)
+const TopTools_ListOfShape& SMESH_Mesh::GetAncestors(const TopoDS_Shape& theS) const
{
- if ( _mapAncestors.IsEmpty() )
- {
- // fill _mapAncestors
- int desType, ancType;
- for ( desType = TopAbs_EDGE; desType > TopAbs_COMPOUND; desType-- )
- for ( ancType = desType - 1; ancType >= TopAbs_COMPOUND; ancType-- )
- TopExp::MapShapesAndAncestors (_myMeshDS->ShapeToMesh(),
- (TopAbs_ShapeEnum) desType,
- (TopAbs_ShapeEnum) ancType,
- _mapAncestors );
- }
-
if ( _mapAncestors.Contains( theS ) )
return _mapAncestors.FindFromKey( theS );
//=======================================================================
ostream& SMESH_Mesh::Dump(ostream& save)
{
- save << "========================== Dump contents of mesh ==========================" << endl;
- save << "1) Total number of nodes: " << NbNodes() << endl;
- save << "2) Total number of edges: " << NbEdges() << endl;
- save << "3) Total number of faces: " << NbFaces() << endl;
- if ( NbFaces() > 0 ) {
- int nb3 = NbTriangles();
- int nb4 = NbQuadrangles();
- save << "3.1.) Number of triangles: " << nb3 << endl;
- save << "3.2.) Number of quadrangles: " << nb4 << endl;
- if ( nb3 + nb4 != NbFaces() ) {
- map<int,int> myFaceMap;
- SMDS_FaceIteratorPtr itFaces=_myMeshDS->facesIterator();
- while( itFaces->more( ) ) {
- int nbNodes = itFaces->next()->NbNodes();
- if ( myFaceMap.find( nbNodes ) == myFaceMap.end() )
- myFaceMap[ nbNodes ] = 0;
- myFaceMap[ nbNodes ] = myFaceMap[ nbNodes ] + 1;
+ int clause = 0;
+ save << "========================== Dump contents of mesh ==========================" << endl << endl;
+ save << ++clause << ") Total number of nodes: " << NbNodes() << endl << endl;
+ for ( int isQuadratic = 0; isQuadratic < 2; ++isQuadratic )
+ {
+ string orderStr = isQuadratic ? "quadratic" : "linear";
+ ElementOrder order = isQuadratic ? ORDER_QUADRATIC : ORDER_LINEAR;
+
+ save << ++clause << ") Total number of " << orderStr << " edges: " << NbEdges(order) << endl;
+ save << ++clause << ") Total number of " << orderStr << " faces: " << NbFaces(order) << endl;
+ if ( NbFaces(order) > 0 ) {
+ int nb3 = NbTriangles(order);
+ int nb4 = NbQuadrangles(order);
+ save << clause << ".1.) Number of " << orderStr << " triangles: " << nb3 << endl;
+ save << clause << ".2.) Number of " << orderStr << " quadrangles: " << nb4 << endl;
+ if ( nb3 + nb4 != NbFaces(order) ) {
+ map<int,int> myFaceMap;
+ SMDS_FaceIteratorPtr itFaces=_myMeshDS->facesIterator();
+ while( itFaces->more( ) ) {
+ int nbNodes = itFaces->next()->NbNodes();
+ if ( myFaceMap.find( nbNodes ) == myFaceMap.end() )
+ myFaceMap[ nbNodes ] = 0;
+ myFaceMap[ nbNodes ] = myFaceMap[ nbNodes ] + 1;
+ }
+ save << clause << ".3.) Faces in detail: " << endl;
+ map <int,int>::iterator itF;
+ for (itF = myFaceMap.begin(); itF != myFaceMap.end(); itF++)
+ save << "--> nb nodes: " << itF->first << " - nb elemens: " << itF->second << endl;
}
- save << "3.3.) Faces in detail: " << endl;
- map <int,int>::iterator itF;
- for (itF = myFaceMap.begin(); itF != myFaceMap.end(); itF++)
- save << "--> nb nodes: " << itF->first << " - nb elemens: " << itF->second << endl;
}
- }
- save << "4) Total number of volumes: " << NbVolumes() << endl;
- if ( NbVolumes() > 0 ) {
- int nb8 = NbHexas();
- int nb4 = NbTetras();
- int nb5 = NbPyramids();
- int nb6 = NbPrisms();
- save << "4.1.) Number of hexahedrons: " << nb8 << endl;
- save << "4.2.) Number of tetrahedrons: " << nb4 << endl;
- save << "4.3.) Number of prisms: " << nb6 << endl;
- save << "4.4.) Number of pyramides: " << nb5 << endl;
- if ( nb8 + nb4 + nb5 + nb6 != NbVolumes() ) {
- map<int,int> myVolumesMap;
- SMDS_VolumeIteratorPtr itVolumes=_myMeshDS->volumesIterator();
- while( itVolumes->more( ) ) {
- int nbNodes = itVolumes->next()->NbNodes();
- if ( myVolumesMap.find( nbNodes ) == myVolumesMap.end() )
- myVolumesMap[ nbNodes ] = 0;
- myVolumesMap[ nbNodes ] = myVolumesMap[ nbNodes ] + 1;
+ save << ++clause << ") Total number of " << orderStr << " volumes: " << NbVolumes(order) << endl;
+ if ( NbVolumes(order) > 0 ) {
+ int nb8 = NbHexas(order);
+ int nb4 = NbTetras(order);
+ int nb5 = NbPyramids(order);
+ int nb6 = NbPrisms(order);
+ save << clause << ".1.) Number of " << orderStr << " hexahedrons: " << nb8 << endl;
+ save << clause << ".2.) Number of " << orderStr << " tetrahedrons: " << nb4 << endl;
+ save << clause << ".3.) Number of " << orderStr << " prisms: " << nb6 << endl;
+ save << clause << ".4.) Number of " << orderStr << " pyramides: " << nb5 << endl;
+ if ( nb8 + nb4 + nb5 + nb6 != NbVolumes(order) ) {
+ map<int,int> myVolumesMap;
+ SMDS_VolumeIteratorPtr itVolumes=_myMeshDS->volumesIterator();
+ while( itVolumes->more( ) ) {
+ int nbNodes = itVolumes->next()->NbNodes();
+ if ( myVolumesMap.find( nbNodes ) == myVolumesMap.end() )
+ myVolumesMap[ nbNodes ] = 0;
+ myVolumesMap[ nbNodes ] = myVolumesMap[ nbNodes ] + 1;
+ }
+ save << clause << ".5.) Volumes in detail: " << endl;
+ map <int,int>::iterator itV;
+ for (itV = myVolumesMap.begin(); itV != myVolumesMap.end(); itV++)
+ save << "--> nb nodes: " << itV->first << " - nb elemens: " << itV->second << endl;
}
- save << "4.5.) Volumes in detail: " << endl;
- map <int,int>::iterator itV;
- for (itV = myVolumesMap.begin(); itV != myVolumesMap.end(); itV++)
- save << "--> nb nodes: " << itV->first << " - nb elemens: " << itV->second << endl;
}
+ save << endl;
}
save << "===========================================================================" << endl;
return save;
}
+
+//=======================================================================
+//function : GetElementType
+//purpose : Returns type of mesh element with certain id
+//=======================================================================
+SMDSAbs_ElementType SMESH_Mesh::GetElementType( const int id, const bool iselem )
+{
+ return _myMeshDS->GetElementType( id, iselem );
+}