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DriverMED_W_SMESHDS_Mesh.cpp
1011 lines (909 loc) · 37.6 KB
/
DriverMED_W_SMESHDS_Mesh.cpp
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// Copyright (C) 2007-2016 CEA/DEN, EDF R&D, OPEN CASCADE
//
// Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN,
// CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS
//
// This library is free software; you can redistribute it and/or
// modify it under the terms of the GNU Lesser General Public
// License as published by the Free Software Foundation; either
// version 2.1 of the License, or (at your option) any later version.
//
// 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 DriverMED : driver to read and write 'med' files
// File : DriverMED_W_SMESHDS_Mesh.cxx
// Module : SMESH
//
#include "DriverMED_W_SMESHDS_Mesh.h"
#include "DriverMED_Family.h"
#include "MED_Factory.hxx"
#include "MED_Utilities.hxx"
#include "SMDS_IteratorOnIterators.hxx"
#include "SMDS_MeshElement.hxx"
#include "SMDS_MeshNode.hxx"
#include "SMDS_PolyhedralVolumeOfNodes.hxx"
#include "SMDS_SetIterator.hxx"
#include "SMESHDS_Mesh.hxx"
#include <BRep_Tool.hxx>
#include <TopExp_Explorer.hxx>
#include <TopoDS.hxx>
#include <utilities.h>
#define _EDF_NODE_IDS_
//#define _ELEMENTS_BY_DIM_
using namespace std;
using namespace MED;
DriverMED_W_SMESHDS_Mesh::DriverMED_W_SMESHDS_Mesh():
myMedVersion(MED::eV2_2),
myAllSubMeshes (false),
myDoGroupOfNodes (false),
myDoGroupOfEdges (false),
myDoGroupOfFaces (false),
myDoGroupOfVolumes (false),
myDoGroupOf0DElems(false),
myDoGroupOfBalls(false),
myAutoDimension(true),
myAddODOnVertices(false)
{}
void DriverMED_W_SMESHDS_Mesh::SetFile(const std::string& theFileName,
MED::EVersion theId)
{
Driver_SMESHDS_Mesh::SetFile(theFileName);
myMedVersion = theId;
}
void DriverMED_W_SMESHDS_Mesh::SetFile(const std::string& theFileName)
{
Driver_SMESHDS_Mesh::SetFile(theFileName);
}
string DriverMED_W_SMESHDS_Mesh::GetVersionString(const MED::EVersion theVersion, int theNbDigits)
{
TInt majeur, mineur, release;
majeur = mineur = release = 0;
// if ( theVersion == eV2_1 )
// MED::GetVersionRelease<eV2_1>(majeur, mineur, release);
// else
// MED::GetVersionRelease<eV2_2>(majeur, mineur, release);
majeur = 3;
mineur = 2;
release = 1;
ostringstream name;
if ( theNbDigits > 0 )
name << majeur;
if ( theNbDigits > 1 )
name << "." << mineur;
if ( theNbDigits > 2 )
name << "." << release;
return name.str();
}
void DriverMED_W_SMESHDS_Mesh::AddGroup(SMESHDS_GroupBase* theGroup)
{
myGroups.push_back(theGroup);
}
void DriverMED_W_SMESHDS_Mesh::AddAllSubMeshes()
{
myAllSubMeshes = true;
}
void DriverMED_W_SMESHDS_Mesh::AddSubMesh(SMESHDS_SubMesh* theSubMesh, int theID)
{
mySubMeshes.push_back( theSubMesh );
}
void DriverMED_W_SMESHDS_Mesh::AddGroupOfNodes()
{
myDoGroupOfNodes = true;
}
void DriverMED_W_SMESHDS_Mesh::AddGroupOfEdges()
{
myDoGroupOfEdges = true;
}
void DriverMED_W_SMESHDS_Mesh::AddGroupOfFaces()
{
myDoGroupOfFaces = true;
}
void DriverMED_W_SMESHDS_Mesh::AddGroupOfVolumes()
{
myDoGroupOfVolumes = true;
}
namespace
{
typedef double (SMDS_MeshNode::* TGetCoord)() const;
typedef const char* TName;
typedef const char* TUnit;
// name length in a mesh must be equal to 16 :
// 1234567890123456
TName M = "m ";
TName X = "x ";
TName Y = "y ";
TName Z = "z ";
TUnit aUnit[3] = {M,M,M};
// 3 dim
TGetCoord aXYZGetCoord[3] = {
&SMDS_MeshNode::X,
&SMDS_MeshNode::Y,
&SMDS_MeshNode::Z
};
TName aXYZName[3] = {X,Y,Z};
// 2 dim
TGetCoord aXYGetCoord[2] = {
&SMDS_MeshNode::X,
&SMDS_MeshNode::Y
};
TName aXYName[2] = {X,Y};
TGetCoord aYZGetCoord[2] = {
&SMDS_MeshNode::Y,
&SMDS_MeshNode::Z
};
TName aYZName[2] = {Y,Z};
TGetCoord aXZGetCoord[2] = {
&SMDS_MeshNode::X,
&SMDS_MeshNode::Z
};
TName aXZName[2] = {X,Z};
// 1 dim
TGetCoord aXGetCoord[1] = {
&SMDS_MeshNode::X
};
TName aXName[1] = {X};
TGetCoord aYGetCoord[1] = {
&SMDS_MeshNode::Y
};
TName aYName[1] = {Y};
TGetCoord aZGetCoord[1] = {
&SMDS_MeshNode::Z
};
TName aZName[1] = {Z};
class TCoordHelper{
SMDS_NodeIteratorPtr myNodeIter;
const SMDS_MeshNode* myCurrentNode;
TGetCoord* myGetCoord;
TName* myName;
TUnit* myUnit;
public:
TCoordHelper(const SMDS_NodeIteratorPtr& theNodeIter,
TGetCoord* theGetCoord,
TName* theName,
TUnit* theUnit = aUnit):
myNodeIter(theNodeIter),
myGetCoord(theGetCoord),
myName(theName),
myUnit(theUnit)
{}
virtual ~TCoordHelper(){}
bool Next(){
return myNodeIter->more() &&
(myCurrentNode = myNodeIter->next());
}
const SMDS_MeshNode* GetNode(){
return myCurrentNode;
}
MED::TIntVector::value_type GetID(){
return myCurrentNode->GetID();
}
MED::TFloatVector::value_type GetCoord(TInt theCoodId){
return (myCurrentNode->*myGetCoord[theCoodId])();
}
MED::TStringVector::value_type GetName(TInt theDimId){
return myName[theDimId];
}
MED::TStringVector::value_type GetUnit(TInt theDimId){
return myUnit[theDimId];
}
};
typedef boost::shared_ptr<TCoordHelper> TCoordHelperPtr;
//-------------------------------------------------------
/*!
* \brief Structure describing element type
*/
//-------------------------------------------------------
struct TElemTypeData
{
EEntiteMaillage _entity;
EGeometrieElement _geomType;
TInt _nbElems;
SMDSAbs_ElementType _smdsType;
TElemTypeData (EEntiteMaillage entity, EGeometrieElement geom, TInt nb, SMDSAbs_ElementType type)
: _entity(entity), _geomType(geom), _nbElems( nb ), _smdsType( type ) {}
};
typedef NCollection_DataMap< Standard_Address, int > TElemFamilyMap;
//================================================================================
/*!
* \brief Fills element to famaly ID map for element type.
* Removes all families of anElemType
*/
//================================================================================
void fillElemFamilyMap( TElemFamilyMap & anElemFamMap,
list<DriverMED_FamilyPtr> & aFamilies,
const SMDSAbs_ElementType anElemType)
{
anElemFamMap.Clear();
list<DriverMED_FamilyPtr>::iterator aFamsIter = aFamilies.begin();
while ( aFamsIter != aFamilies.end() )
{
if ((*aFamsIter)->GetType() != anElemType) {
aFamsIter++;
}
else {
int aFamId = (*aFamsIter)->GetId();
const ElementsSet& anElems = (*aFamsIter)->GetElements();
ElementsSet::const_iterator anElemsIter = anElems.begin();
for (; anElemsIter != anElems.end(); anElemsIter++)
{
anElemFamMap.Bind( (Standard_Address)*anElemsIter, aFamId );
}
// remove a family from the list
aFamilies.erase( aFamsIter++ );
}
}
}
//================================================================================
/*!
* \brief For an element, return family ID found in the map or a default one
*/
//================================================================================
int getFamilyId( const TElemFamilyMap & anElemFamMap,
const SMDS_MeshElement* anElement,
const int aDefaultFamilyId)
{
if ( anElemFamMap.IsBound( (Standard_Address) anElement ))
return anElemFamMap( (Standard_Address) anElement );
return aDefaultFamilyId;
}
//================================================================================
/*!
* \brief Returns iterator on sub-meshes
*/
//================================================================================
SMESHDS_SubMeshIteratorPtr getIterator( std::vector<SMESHDS_SubMesh*>& mySubMeshes )
{
return SMESHDS_SubMeshIteratorPtr
( new SMDS_SetIterator
< const SMESHDS_SubMesh*, std::vector< SMESHDS_SubMesh* >::iterator >( mySubMeshes.begin(),
mySubMeshes.end() ));
}
}
Driver_Mesh::Status DriverMED_W_SMESHDS_Mesh::Perform()
{
Status aResult = DRS_OK;
if (myMesh->hasConstructionEdges() || myMesh->hasConstructionFaces()) {
INFOS("SMDS_MESH with hasConstructionEdges() or hasConstructionFaces() do not supports!!!");
return DRS_FAIL;
}
try {
MESSAGE("Perform - myFile : "<<myFile);
// Creating the MED mesh for corresponding SMDS structure
//-------------------------------------------------------
string aMeshName;
if (myMeshId != -1) {
ostringstream aMeshNameStr;
aMeshNameStr<<myMeshId;
aMeshName = aMeshNameStr.str();
} else {
aMeshName = myMeshName;
}
// Mesh dimension definition
TInt aSpaceDimension = 3;
TCoordHelperPtr aCoordHelperPtr;
{
bool anIsXDimension = false;
bool anIsYDimension = false;
bool anIsZDimension = false;
if ( myAutoDimension )
{
SMDS_NodeIteratorPtr aNodesIter = myMesh->nodesIterator();
double aBounds[6];
if(aNodesIter->more()){
const SMDS_MeshNode* aNode = aNodesIter->next();
aBounds[0] = aBounds[1] = aNode->X();
aBounds[2] = aBounds[3] = aNode->Y();
aBounds[4] = aBounds[5] = aNode->Z();
}
while(aNodesIter->more()){
const SMDS_MeshNode* aNode = aNodesIter->next();
aBounds[0] = min(aBounds[0],aNode->X());
aBounds[1] = max(aBounds[1],aNode->X());
aBounds[2] = min(aBounds[2],aNode->Y());
aBounds[3] = max(aBounds[3],aNode->Y());
aBounds[4] = min(aBounds[4],aNode->Z());
aBounds[5] = max(aBounds[5],aNode->Z());
}
double EPS = 1.0E-7;
TopoDS_Shape mainShape = myMesh->ShapeToMesh();
bool hasShapeToMesh = ( myMesh->SubMeshIndices().size() > 1 );
if ( !mainShape.IsNull() && hasShapeToMesh )
{
// define EPS by max tolerance of the mainShape (IPAL53097)
TopExp_Explorer subShape;
for ( subShape.Init( mainShape, TopAbs_FACE ); subShape.More(); subShape.Next() ) {
EPS = Max( EPS, BRep_Tool::Tolerance( TopoDS::Face( subShape.Current() )));
}
for ( subShape.Init( mainShape, TopAbs_EDGE ); subShape.More(); subShape.Next() ) {
EPS = Max( EPS, BRep_Tool::Tolerance( TopoDS::Edge( subShape.Current() )));
}
for ( subShape.Init( mainShape, TopAbs_VERTEX ); subShape.More(); subShape.Next() ) {
EPS = Max( EPS, BRep_Tool::Tolerance( TopoDS::Vertex( subShape.Current() )));
}
EPS *= 2.;
}
anIsXDimension = (aBounds[1] - aBounds[0]) + abs(aBounds[1]) + abs(aBounds[0]) > EPS;
anIsYDimension = (aBounds[3] - aBounds[2]) + abs(aBounds[3]) + abs(aBounds[2]) > EPS;
anIsZDimension = (aBounds[5] - aBounds[4]) + abs(aBounds[5]) + abs(aBounds[4]) > EPS;
aSpaceDimension = anIsXDimension + anIsYDimension + anIsZDimension;
if ( !aSpaceDimension )
aSpaceDimension = 3;
// PAL16857(SMESH not conform to the MED convention):
if ( aSpaceDimension == 2 && anIsZDimension ) // 2D only if mesh is in XOY plane
aSpaceDimension = 3;
// PAL18941(a saved study with a mesh belong Z is opened and the mesh is belong X)
if ( aSpaceDimension == 1 && !anIsXDimension ) {// 1D only if mesh is along OX
if ( anIsYDimension ) {
aSpaceDimension = 2;
anIsXDimension = true;
} else {
aSpaceDimension = 3;
}
}
}
SMDS_NodeIteratorPtr aNodesIter = myMesh->nodesIterator(/*idInceasingOrder=*/true);
switch ( aSpaceDimension ) {
case 3:
aCoordHelperPtr.reset(new TCoordHelper(aNodesIter,aXYZGetCoord,aXYZName));
break;
case 2:
if(anIsXDimension && anIsYDimension)
aCoordHelperPtr.reset(new TCoordHelper(aNodesIter,aXYGetCoord,aXYName));
if(anIsYDimension && anIsZDimension)
aCoordHelperPtr.reset(new TCoordHelper(aNodesIter,aYZGetCoord,aYZName));
if(anIsXDimension && anIsZDimension)
aCoordHelperPtr.reset(new TCoordHelper(aNodesIter,aXZGetCoord,aXZName));
break;
case 1:
if(anIsXDimension)
aCoordHelperPtr.reset(new TCoordHelper(aNodesIter,aXGetCoord,aXName));
if(anIsYDimension)
aCoordHelperPtr.reset(new TCoordHelper(aNodesIter,aYGetCoord,aYName));
if(anIsZDimension)
aCoordHelperPtr.reset(new TCoordHelper(aNodesIter,aZGetCoord,aZName));
break;
}
}
TInt aMeshDimension = 0;
if ( myMesh->NbEdges() > 0 )
aMeshDimension = 1;
if ( myMesh->NbFaces() > 0 )
aMeshDimension = 2;
if ( myMesh->NbVolumes() > 0 )
aMeshDimension = 3;
MED::PWrapper myMed = CrWrapper(myFile,myMedVersion);
PMeshInfo aMeshInfo = myMed->CrMeshInfo(aMeshDimension,aSpaceDimension,aMeshName);
MESSAGE("Add - aMeshName : "<<aMeshName<<"; "<<aMeshInfo->GetName());
myMed->SetMeshInfo(aMeshInfo);
// Storing SMDS groups and sub-meshes as med families
//----------------------------------------------------
int myNodesDefaultFamilyId = 0;
int my0DElementsDefaultFamilyId = 0;
int myBallsDefaultFamilyId = 0;
int myEdgesDefaultFamilyId = 0;
int myFacesDefaultFamilyId = 0;
int myVolumesDefaultFamilyId = 0;
int nbNodes = myMesh->NbNodes();
int nb0DElements = myMesh->Nb0DElements();
int nbBalls = myMesh->NbBalls();
int nbEdges = myMesh->NbEdges();
int nbFaces = myMesh->NbFaces();
int nbVolumes = myMesh->NbVolumes();
if (myDoGroupOfNodes && nbNodes) myNodesDefaultFamilyId = REST_NODES_FAMILY;
if (myDoGroupOfEdges && nbEdges) myEdgesDefaultFamilyId = REST_EDGES_FAMILY;
if (myDoGroupOfFaces && nbFaces) myFacesDefaultFamilyId = REST_FACES_FAMILY;
if (myDoGroupOfVolumes && nbVolumes) myVolumesDefaultFamilyId = REST_VOLUMES_FAMILY;
if (myDoGroupOf0DElems && nb0DElements) my0DElementsDefaultFamilyId = REST_0DELEM_FAMILY;
if (myDoGroupOfBalls && nbBalls) myBallsDefaultFamilyId = REST_BALL_FAMILY;
MESSAGE("Perform - aFamilyInfo");
list<DriverMED_FamilyPtr> aFamilies;
if (myAllSubMeshes) {
aFamilies = DriverMED_Family::MakeFamilies
(myMesh->SubMeshes(), myGroups,
myDoGroupOfNodes && nbNodes,
myDoGroupOfEdges && nbEdges,
myDoGroupOfFaces && nbFaces,
myDoGroupOfVolumes && nbVolumes,
myDoGroupOf0DElems && nb0DElements,
myDoGroupOfBalls && nbBalls);
}
else {
aFamilies = DriverMED_Family::MakeFamilies
(getIterator( mySubMeshes ), myGroups,
myDoGroupOfNodes && nbNodes,
myDoGroupOfEdges && nbEdges,
myDoGroupOfFaces && nbFaces,
myDoGroupOfVolumes && nbVolumes,
myDoGroupOf0DElems && nb0DElements,
myDoGroupOfBalls && nbBalls);
}
list<DriverMED_FamilyPtr>::iterator aFamsIter;
for (aFamsIter = aFamilies.begin(); aFamsIter != aFamilies.end(); aFamsIter++)
{
PFamilyInfo aFamilyInfo = (*aFamsIter)->GetFamilyInfo(myMed,aMeshInfo);
myMed->SetFamilyInfo(aFamilyInfo);
}
// Storing SMDS nodes to the MED file for the MED mesh
//----------------------------------------------------
#ifdef _EDF_NODE_IDS_
typedef map<TInt,TInt> TNodeIdMap;
TNodeIdMap aNodeIdMap;
#endif
const EModeSwitch theMode = eFULL_INTERLACE;
const ERepere theSystem = eCART;
const EBooleen theIsElemNum = eVRAI;
const EBooleen theIsElemNames = eFAUX;
const EConnectivite theConnMode = eNOD;
TInt aNbNodes = myMesh->NbNodes();
PNodeInfo aNodeInfo = myMed->CrNodeInfo(aMeshInfo, aNbNodes,
theMode, theSystem, theIsElemNum, theIsElemNames);
// find family numbers for nodes
TElemFamilyMap anElemFamMap;
fillElemFamilyMap( anElemFamMap, aFamilies, SMDSAbs_Node );
for (TInt iNode = 0; aCoordHelperPtr->Next(); iNode++)
{
// coordinates
TCoordSlice aTCoordSlice = aNodeInfo->GetCoordSlice( iNode );
for(TInt iCoord = 0; iCoord < aSpaceDimension; iCoord++){
aTCoordSlice[iCoord] = aCoordHelperPtr->GetCoord(iCoord);
}
// node number
int aNodeID = aCoordHelperPtr->GetID();
aNodeInfo->SetElemNum( iNode, aNodeID );
#ifdef _EDF_NODE_IDS_
aNodeIdMap.insert( aNodeIdMap.end(), make_pair( aNodeID, iNode+1 ));
#endif
// family number
const SMDS_MeshNode* aNode = aCoordHelperPtr->GetNode();
int famNum = getFamilyId( anElemFamMap, aNode, myNodesDefaultFamilyId );
aNodeInfo->SetFamNum( iNode, famNum );
}
anElemFamMap.Clear();
// coordinate names and units
for (TInt iCoord = 0; iCoord < aSpaceDimension; iCoord++) {
aNodeInfo->SetCoordName( iCoord, aCoordHelperPtr->GetName(iCoord));
aNodeInfo->SetCoordUnit( iCoord, aCoordHelperPtr->GetUnit(iCoord));
}
//cout << " SetNodeInfo(aNodeInfo)" << endl;
MESSAGE("Perform - aNodeInfo->GetNbElem() = "<<aNbNodes);
myMed->SetNodeInfo(aNodeInfo);
aNodeInfo.reset(); // free memory used for arrays
// Storing SMDS elements to the MED file for the MED mesh
//-------------------------------------------------------
// Write one element type at once in order to minimize memory usage (PAL19276)
const SMDS_MeshInfo& nbElemInfo = myMesh->GetMeshInfo();
// poly elements are not supported by med-2.1
bool polyTypesSupported = ( myMed->CrPolygoneInfo(aMeshInfo,eMAILLE,ePOLYGONE,0,0).get() != 0 );
TInt nbPolygonNodes = 0, nbPolyhedronNodes = 0, nbPolyhedronFaces = 0;
// nodes on VERTEXes where 0D elements are absent
std::vector<const SMDS_MeshElement*> nodesOf0D;
std::vector< SMDS_ElemIteratorPtr > iterVec;
SMDS_ElemIteratorPtr iterVecIter;
if ( myAddODOnVertices && getNodesOfMissing0DOnVert( myMesh, nodesOf0D ))
{
iterVec.resize(2);
iterVec[0] = myMesh->elementsIterator( SMDSAbs_0DElement );
iterVec[1] = SMDS_ElemIteratorPtr
( new SMDS_ElementVectorIterator( nodesOf0D.begin(), nodesOf0D.end() ));
typedef SMDS_IteratorOnIterators
< const SMDS_MeshElement *, std::vector< SMDS_ElemIteratorPtr > > TItIterator;
iterVecIter = SMDS_ElemIteratorPtr( new TItIterator( iterVec ));
}
// collect info on all geom types
list< TElemTypeData > aTElemTypeDatas;
EEntiteMaillage anEntity = eMAILLE;
#ifdef _ELEMENTS_BY_DIM_
anEntity = eNOEUD_ELEMENT;
#endif
aTElemTypeDatas.push_back(TElemTypeData(anEntity,
ePOINT1,
nbElemInfo.Nb0DElements() + nodesOf0D.size(),
SMDSAbs_0DElement));
#ifdef _ELEMENTS_BY_DIM_
anEntity = eSTRUCT_ELEMENT;
#endif
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eBALL,
nbElemInfo.NbBalls(),
SMDSAbs_Ball));
#ifdef _ELEMENTS_BY_DIM_
anEntity = eARETE;
#endif
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eSEG2,
nbElemInfo.NbEdges( ORDER_LINEAR ),
SMDSAbs_Edge));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eSEG3,
nbElemInfo.NbEdges( ORDER_QUADRATIC ),
SMDSAbs_Edge));
#ifdef _ELEMENTS_BY_DIM_
anEntity = eFACE;
#endif
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eTRIA3,
nbElemInfo.NbTriangles( ORDER_LINEAR ),
SMDSAbs_Face));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eTRIA6,
nbElemInfo.NbTriangles( ORDER_QUADRATIC ) -
nbElemInfo.NbBiQuadTriangles(),
SMDSAbs_Face));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eTRIA7,
nbElemInfo.NbBiQuadTriangles(),
SMDSAbs_Face));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eQUAD4,
nbElemInfo.NbQuadrangles( ORDER_LINEAR ),
SMDSAbs_Face));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eQUAD8,
nbElemInfo.NbQuadrangles( ORDER_QUADRATIC ) -
nbElemInfo.NbBiQuadQuadrangles(),
SMDSAbs_Face));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eQUAD9,
nbElemInfo.NbBiQuadQuadrangles(),
SMDSAbs_Face));
if ( polyTypesSupported ) {
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
ePOLYGONE,
nbElemInfo.NbPolygons( ORDER_LINEAR ),
SMDSAbs_Face));
// we need one more loop on poly elements to count nb of their nodes
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
ePOLYGONE,
nbElemInfo.NbPolygons( ORDER_LINEAR ),
SMDSAbs_Face));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
ePOLYGON2,
nbElemInfo.NbPolygons( ORDER_QUADRATIC ),
SMDSAbs_Face));
// we need one more loop on QUAD poly elements to count nb of their nodes
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
ePOLYGON2,
nbElemInfo.NbPolygons( ORDER_QUADRATIC ),
SMDSAbs_Face));
}
#ifdef _ELEMENTS_BY_DIM_
anEntity = eMAILLE;
#endif
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eTETRA4,
nbElemInfo.NbTetras( ORDER_LINEAR ),
SMDSAbs_Volume));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eTETRA10,
nbElemInfo.NbTetras( ORDER_QUADRATIC ),
SMDSAbs_Volume));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
ePYRA5,
nbElemInfo.NbPyramids( ORDER_LINEAR ),
SMDSAbs_Volume));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
ePYRA13,
nbElemInfo.NbPyramids( ORDER_QUADRATIC ),
SMDSAbs_Volume));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
ePENTA6,
nbElemInfo.NbPrisms( ORDER_LINEAR ),
SMDSAbs_Volume));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
ePENTA15,
nbElemInfo.NbPrisms( ORDER_QUADRATIC ),
SMDSAbs_Volume));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eHEXA8,
nbElemInfo.NbHexas( ORDER_LINEAR ),
SMDSAbs_Volume));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eHEXA20,
nbElemInfo.NbHexas( ORDER_QUADRATIC )-
nbElemInfo.NbTriQuadHexas(),
SMDSAbs_Volume));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eHEXA27,
nbElemInfo.NbTriQuadHexas(),
SMDSAbs_Volume));
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
eOCTA12,
nbElemInfo.NbHexPrisms(),
SMDSAbs_Volume));
if ( polyTypesSupported ) {
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
ePOLYEDRE,
nbElemInfo.NbPolyhedrons(),
SMDSAbs_Volume));
// we need one more loop on poly elements to count nb of their nodes
aTElemTypeDatas.push_back( TElemTypeData(anEntity,
ePOLYEDRE,
nbElemInfo.NbPolyhedrons(),
SMDSAbs_Volume));
}
vector< bool > isElemFamMapBuilt( SMDSAbs_NbElementTypes, false );
// loop on all geom types of elements
list< TElemTypeData >::iterator aElemTypeData = aTElemTypeDatas.begin();
for ( ; aElemTypeData != aTElemTypeDatas.end(); ++aElemTypeData )
{
if ( aElemTypeData->_nbElems == 0 )
continue;
int defaultFamilyId = 0;
switch ( aElemTypeData->_smdsType ) {
case SMDSAbs_0DElement: defaultFamilyId = my0DElementsDefaultFamilyId; break;
case SMDSAbs_Ball: defaultFamilyId = myBallsDefaultFamilyId; break;
case SMDSAbs_Edge: defaultFamilyId = myEdgesDefaultFamilyId; break;
case SMDSAbs_Face: defaultFamilyId = myFacesDefaultFamilyId; break;
case SMDSAbs_Volume: defaultFamilyId = myVolumesDefaultFamilyId; break;
default:
continue;
}
// iterator on elements of a current type
SMDS_ElemIteratorPtr elemIterator;
int iElem = 0;
// Treat POLYGONs
// ---------------
if ( aElemTypeData->_geomType == ePOLYGONE ||
aElemTypeData->_geomType == ePOLYGON2 )
{
if ( aElemTypeData->_geomType == ePOLYGONE )
elemIterator = myMesh->elementEntityIterator( SMDSEntity_Polygon );
else {
#ifndef VTK_NO_QUAD_POLY
elemIterator = myMesh->elementEntityIterator( SMDSEntity_Quad_Polygon );
#else
throw SALOME_Exception("Quadratic polygon not supported with VTK <6.2");
#endif
}
if ( nbPolygonNodes == 0 ) {
// Count nb of nodes
while ( elemIterator->more() ) {
const SMDS_MeshElement* anElem = elemIterator->next();
nbPolygonNodes += anElem->NbNodes();
if ( ++iElem == aElemTypeData->_nbElems )
break;
}
}
else {
// Store in med file
PPolygoneInfo aPolygoneInfo = myMed->CrPolygoneInfo(aMeshInfo,
aElemTypeData->_entity,
aElemTypeData->_geomType,
aElemTypeData->_nbElems,
nbPolygonNodes,
theConnMode, theIsElemNum,
theIsElemNames);
TElemNum & index = *(aPolygoneInfo->myIndex.get());
index[0] = 1;
while ( elemIterator->more() )
{
const SMDS_MeshElement* anElem = elemIterator->next();
// index
TInt aNbNodes = anElem->NbNodes();
index[ iElem+1 ] = index[ iElem ] + aNbNodes;
// connectivity
TConnSlice aTConnSlice = aPolygoneInfo->GetConnSlice( iElem );
for(TInt iNode = 0; iNode < aNbNodes; iNode++) {
const SMDS_MeshElement* aNode = anElem->GetNode( iNode );
#ifdef _EDF_NODE_IDS_
aTConnSlice[ iNode ] = aNodeIdMap[aNode->GetID()];
#else
aTConnSlice[ iNode ] = aNode->GetID();
#endif
}
// element number
aPolygoneInfo->SetElemNum( iElem, anElem->GetID() );
// family number
int famNum = getFamilyId( anElemFamMap, anElem, defaultFamilyId );
aPolygoneInfo->SetFamNum( iElem, famNum );
if ( ++iElem == aPolygoneInfo->GetNbElem() )
break;
}
myMed->SetPolygoneInfo(aPolygoneInfo);
nbPolygonNodes = 0; // to treat next polygon type
}
}
// Treat POLYEDREs
// ----------------
else if (aElemTypeData->_geomType == ePOLYEDRE )
{
elemIterator = myMesh->elementGeomIterator( SMDSGeom_POLYHEDRA );
if ( nbPolyhedronNodes == 0 ) {
// Count nb of nodes
while ( elemIterator->more() ) {
const SMDS_MeshElement* anElem = elemIterator->next();
const SMDS_VtkVolume *aPolyedre = dynamic_cast<const SMDS_VtkVolume*>(anElem);
if ( !aPolyedre ) continue;
nbPolyhedronNodes += aPolyedre->NbNodes();
nbPolyhedronFaces += aPolyedre->NbFaces();
if ( ++iElem == aElemTypeData->_nbElems )
break;
}
}
else {
// Store in med file
PPolyedreInfo aPolyhInfo = myMed->CrPolyedreInfo(aMeshInfo,
aElemTypeData->_entity,
aElemTypeData->_geomType,
aElemTypeData->_nbElems,
nbPolyhedronFaces+1,
nbPolyhedronNodes,
theConnMode,
theIsElemNum,
theIsElemNames);
TElemNum & index = *(aPolyhInfo->myIndex.get());
TElemNum & faces = *(aPolyhInfo->myFaces.get());
TElemNum & conn = *(aPolyhInfo->myConn.get());
index[0] = 1;
faces[0] = 1;
TInt iFace = 0, iNode = 0;
while ( elemIterator->more() )
{
const SMDS_MeshElement* anElem = elemIterator->next();
const SMDS_VtkVolume *aPolyedre = dynamic_cast<const SMDS_VtkVolume*>(anElem);
if ( !aPolyedre ) continue;
// index
TInt aNbFaces = aPolyedre->NbFaces();
index[ iElem+1 ] = index[ iElem ] + aNbFaces;
// face index
for (TInt f = 1; f <= aNbFaces; ++f, ++iFace ) {
int aNbFaceNodes = aPolyedre->NbFaceNodes( f );
faces[ iFace+1 ] = faces[ iFace ] + aNbFaceNodes;
}
// connectivity
SMDS_ElemIteratorPtr nodeIt = anElem->nodesIterator();
while ( nodeIt->more() ) {
const SMDS_MeshElement* aNode = nodeIt->next();
#ifdef _EDF_NODE_IDS_
conn[ iNode ] = aNodeIdMap[aNode->GetID()];
#else
conn[ iNode ] = aNode->GetID();
#endif
++iNode;
}
// element number
aPolyhInfo->SetElemNum( iElem, anElem->GetID() );
// family number
int famNum = getFamilyId( anElemFamMap, anElem, defaultFamilyId );
aPolyhInfo->SetFamNum( iElem, famNum );
if ( ++iElem == aPolyhInfo->GetNbElem() )
break;
}
myMed->SetPolyedreInfo(aPolyhInfo);
}
} // if (aElemTypeData->_geomType == ePOLYEDRE )
// Treat BALLs
// ----------------
else if (aElemTypeData->_geomType == eBALL )
{
// allocate data arrays
PBallInfo aBallInfo = myMed->CrBallInfo( aMeshInfo, aElemTypeData->_nbElems );
// build map of family numbers for this type
if ( !isElemFamMapBuilt[ aElemTypeData->_smdsType ])
{
fillElemFamilyMap( anElemFamMap, aFamilies, aElemTypeData->_smdsType );
isElemFamMapBuilt[ aElemTypeData->_smdsType ] = true;
}
elemIterator = myMesh->elementsIterator( SMDSAbs_Ball );
while ( elemIterator->more() )
{
const SMDS_MeshElement* anElem = elemIterator->next();
// connectivity
const SMDS_MeshElement* aNode = anElem->GetNode( 0 );
#ifdef _EDF_NODE_IDS_
(*aBallInfo->myConn)[ iElem ] = aNodeIdMap[aNode->GetID()];
#else
(*aBallInfo->myConn)[ iElem ] = aNode->GetID();
#endif
// element number
aBallInfo->SetElemNum( iElem, anElem->GetID() );
// diameter
aBallInfo->myDiameters[ iElem ] =
static_cast<const SMDS_BallElement*>( anElem )->GetDiameter();
// family number
int famNum = getFamilyId( anElemFamMap, anElem, defaultFamilyId );
aBallInfo->SetFamNum( iElem, famNum );
++iElem;
}
// store data in a file
myMed->SetBallInfo(aBallInfo);
}
else
{
// Treat standard types
// ---------------------
// allocate data arrays
PCellInfo aCellInfo = myMed->CrCellInfo( aMeshInfo,
aElemTypeData->_entity,
aElemTypeData->_geomType,
aElemTypeData->_nbElems,
theConnMode,
theIsElemNum,
theIsElemNames);
// build map of family numbers for this type
if ( !isElemFamMapBuilt[ aElemTypeData->_smdsType ])
{
//cout << " fillElemFamilyMap()" << endl;
fillElemFamilyMap( anElemFamMap, aFamilies, aElemTypeData->_smdsType );
isElemFamMapBuilt[ aElemTypeData->_smdsType ] = true;
}
TInt aNbNodes = MED::GetNbNodes(aElemTypeData->_geomType);
elemIterator = myMesh->elementsIterator( aElemTypeData->_smdsType );
if ( aElemTypeData->_smdsType == SMDSAbs_0DElement && ! nodesOf0D.empty() )
elemIterator = iterVecIter;
while ( elemIterator->more() )
{
const SMDS_MeshElement* anElem = elemIterator->next();
if ( anElem->NbNodes() != aNbNodes || anElem->IsPoly() )
continue; // other geometry
// connectivity
TConnSlice aTConnSlice = aCellInfo->GetConnSlice( iElem );
for (TInt iNode = 0; iNode < aNbNodes; iNode++) {
const SMDS_MeshElement* aNode = anElem->GetNode( iNode );
#ifdef _EDF_NODE_IDS_
aTConnSlice[ iNode ] = aNodeIdMap[aNode->GetID()];
#else
aTConnSlice[ iNode ] = aNode->GetID();
#endif
}
// element number
aCellInfo->SetElemNum( iElem, anElem->GetID() );
// family number
int famNum = getFamilyId( anElemFamMap, anElem, defaultFamilyId );
aCellInfo->SetFamNum( iElem, famNum );
if ( ++iElem == aCellInfo->GetNbElem() )
break;
}
// store data in a file
myMed->SetCellInfo(aCellInfo);
}
} // loop on geom types
}
catch(const std::exception& exc) {
INFOS("The following exception was caught:\n\t"<<exc.what());
throw;
}
catch(...) {
INFOS("Unknown exception was caught !!!");
throw;
}
myMeshId = -1;
myGroups.clear();
mySubMeshes.clear();
return aResult;
}
//================================================================================
/*!
* \brief Returns nodes on VERTEXes where 0D elements are absent
*/
//================================================================================
bool DriverMED_W_SMESHDS_Mesh::
getNodesOfMissing0DOnVert(SMESHDS_Mesh* meshDS,
std::vector<const SMDS_MeshElement*>& nodes)
{
nodes.clear();
for ( int i = 1; i <= meshDS->MaxShapeIndex(); ++i )
{
if ( meshDS->IndexToShape( i ).ShapeType() != TopAbs_VERTEX )
continue;
if ( SMESHDS_SubMesh* sm = meshDS->MeshElements(i) ) {