1 // Copyright (C) 2007-2013 CEA/DEN, EDF R&D
3 // This library is free software; you can redistribute it and/or
4 // modify it under the terms of the GNU Lesser General Public
5 // License as published by the Free Software Foundation; either
6 // version 2.1 of the License.
8 // This library is distributed in the hope that it will be useful,
9 // but WITHOUT ANY WARRANTY; without even the implied warranty of
10 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
11 // Lesser General Public License for more details.
13 // You should have received a copy of the GNU Lesser General Public
14 // License along with this library; if not, write to the Free Software
15 // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
17 // See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
19 // Author : Anthony Geay (CEA/DEN)
21 #include "MEDFileField.hxx"
22 #include "MEDFileMesh.hxx"
23 #include "MEDLoaderBase.hxx"
24 #include "MEDFileUtilities.hxx"
25 #include "MEDFileFieldOverView.hxx"
27 #include "MEDCouplingFieldDouble.hxx"
28 #include "MEDCouplingFieldDiscretization.hxx"
30 #include "InterpKernelAutoPtr.hxx"
31 #include "CellModel.hxx"
36 extern med_geometry_type typmai[MED_N_CELL_FIXED_GEO];
37 extern INTERP_KERNEL::NormalizedCellType typmai2[MED_N_CELL_FIXED_GEO];
38 extern med_geometry_type typmainoeud[1];
39 extern med_geometry_type typmai3[34];
41 using namespace ParaMEDMEM;
43 const char MEDFileField1TSWithoutSDA::TYPE_STR[]="FLOAT64";
44 const char MEDFileIntField1TSWithoutSDA::TYPE_STR[]="INT32";
46 MEDFileFieldLoc *MEDFileFieldLoc::New(med_idt fid, const std::string& locName)
48 return new MEDFileFieldLoc(fid,locName);
51 MEDFileFieldLoc *MEDFileFieldLoc::New(med_idt fid, int id)
53 return new MEDFileFieldLoc(fid,id);
56 MEDFileFieldLoc *MEDFileFieldLoc::New(const std::string& locName, INTERP_KERNEL::NormalizedCellType geoType, const std::vector<double>& refCoo, const std::vector<double>& gsCoo, const std::vector<double>& w)
58 return new MEDFileFieldLoc(locName,geoType,refCoo,gsCoo,w);
61 MEDFileFieldLoc::MEDFileFieldLoc(med_idt fid, const std::string& locName):_name(locName)
63 med_geometry_type geotype;
64 med_geometry_type sectiongeotype;
66 INTERP_KERNEL::AutoPtr<char> geointerpname=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
67 INTERP_KERNEL::AutoPtr<char> sectionmeshname=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
68 MEDlocalizationInfoByName(fid,locName.c_str(),&geotype,&_dim,&_nb_gauss_pt,geointerpname,sectionmeshname,&nsectionmeshcell,§iongeotype);
69 _geo_type=(INTERP_KERNEL::NormalizedCellType)(std::distance(typmai3,std::find(typmai3,typmai3+34,geotype)));
70 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
71 _nb_node_per_cell=cm.getNumberOfNodes();
72 _ref_coo.resize(_dim*_nb_node_per_cell);
73 _gs_coo.resize(_dim*_nb_gauss_pt);
74 _w.resize(_nb_gauss_pt);
75 MEDlocalizationRd(fid,locName.c_str(),MED_FULL_INTERLACE,&_ref_coo[0],&_gs_coo[0],&_w[0]);
78 MEDFileFieldLoc::MEDFileFieldLoc(med_idt fid, int id)
80 med_geometry_type geotype;
81 med_geometry_type sectiongeotype;
83 INTERP_KERNEL::AutoPtr<char> locName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
84 INTERP_KERNEL::AutoPtr<char> geointerpname=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
85 INTERP_KERNEL::AutoPtr<char> sectionmeshname=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
86 MEDlocalizationInfo(fid,id+1,locName,&geotype,&_dim,&_nb_gauss_pt,geointerpname,sectionmeshname,&nsectionmeshcell,§iongeotype);
88 _geo_type=(INTERP_KERNEL::NormalizedCellType)(std::distance(typmai3,std::find(typmai3,typmai3+34,geotype)));
89 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
90 _nb_node_per_cell=cm.getNumberOfNodes();
91 _ref_coo.resize(_dim*_nb_node_per_cell);
92 _gs_coo.resize(_dim*_nb_gauss_pt);
93 _w.resize(_nb_gauss_pt);
94 MEDlocalizationRd(fid,locName,MED_FULL_INTERLACE,&_ref_coo[0],&_gs_coo[0],&_w[0]);
97 MEDFileFieldLoc::MEDFileFieldLoc(const std::string& locName, INTERP_KERNEL::NormalizedCellType geoType,
98 const std::vector<double>& refCoo, const std::vector<double>& gsCoo, const std::vector<double>& w):_name(locName),_geo_type(geoType),_ref_coo(refCoo),_gs_coo(gsCoo),
101 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
102 _dim=cm.getDimension();
103 _nb_node_per_cell=cm.getNumberOfNodes();
104 _nb_gauss_pt=_w.size();
107 MEDFileFieldLoc *MEDFileFieldLoc::deepCpy() const
109 return new MEDFileFieldLoc(*this);
112 std::size_t MEDFileFieldLoc::getHeapMemorySizeWithoutChildren() const
114 return (_ref_coo.capacity()+_gs_coo.capacity()+_w.capacity())*sizeof(double)+_name.capacity();
117 std::vector<const BigMemoryObject *> MEDFileFieldLoc::getDirectChildren() const
119 return std::vector<const BigMemoryObject *>();
122 void MEDFileFieldLoc::simpleRepr(std::ostream& oss) const
124 static const char OFF7[]="\n ";
125 oss << "\"" << _name << "\"" << OFF7;
126 oss << "GeoType=" << INTERP_KERNEL::CellModel::GetCellModel(_geo_type).getRepr() << OFF7;
127 oss << "Dimension=" << _dim << OFF7;
128 oss << "Number of Gauss points=" << _nb_gauss_pt << OFF7;
129 oss << "Number of nodes per cell=" << _nb_node_per_cell << OFF7;
130 oss << "RefCoords="; std::copy(_ref_coo.begin(),_ref_coo.end(),std::ostream_iterator<double>(oss," ")); oss << OFF7;
131 oss << "Weights="; std::copy(_w.begin(),_w.end(),std::ostream_iterator<double>(oss," ")); oss << OFF7;
132 oss << "GaussPtsCoords="; std::copy(_gs_coo.begin(),_gs_coo.end(),std::ostream_iterator<double>(oss," ")); oss << std::endl;
135 void MEDFileFieldLoc::setName(const std::string& name)
140 bool MEDFileFieldLoc::isEqual(const MEDFileFieldLoc& other, double eps) const
142 if(_name!=other._name)
146 if(_nb_gauss_pt!=other._nb_gauss_pt)
148 if(_nb_node_per_cell!=other._nb_node_per_cell)
150 if(_geo_type!=other._geo_type)
152 if(!MEDCouplingGaussLocalization::AreAlmostEqual(_ref_coo,other._ref_coo,eps))
154 if(!MEDCouplingGaussLocalization::AreAlmostEqual(_gs_coo,other._gs_coo,eps))
156 if(!MEDCouplingGaussLocalization::AreAlmostEqual(_w,other._w,eps))
162 void MEDFileFieldLoc::writeLL(med_idt fid) const
164 MEDlocalizationWr(fid,_name.c_str(),typmai3[(int)_geo_type],_dim,&_ref_coo[0],MED_FULL_INTERLACE,_nb_gauss_pt,&_gs_coo[0],&_w[0],MED_NO_INTERPOLATION,MED_NO_MESH_SUPPORT);
167 std::string MEDFileFieldLoc::repr() const
169 std::ostringstream oss; oss.precision(15);
170 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
171 oss << "Localization \"" << _name << "\" :\n" << " - Geometric Type : " << cm.getRepr();
172 oss << "\n - Dimension : " << _dim << "\n - Number of gauss points : ";
173 oss << _nb_gauss_pt << "\n - Number of nodes in cell : " << _nb_node_per_cell;
174 oss << "\n - Ref coords are : ";
175 int sz=_ref_coo.size();
178 int nbOfTuples=sz/_dim;
179 for(int i=0;i<nbOfTuples;i++)
182 for(int j=0;j<_dim;j++)
183 { oss << _ref_coo[i*_dim+j]; if(j!=_dim-1) oss << ", "; }
188 std::copy(_ref_coo.begin(),_ref_coo.end(),std::ostream_iterator<double>(oss," "));
189 oss << "\n - Gauss coords in reference element : ";
193 int nbOfTuples=sz/_dim;
194 for(int i=0;i<nbOfTuples;i++)
197 for(int j=0;j<_dim;j++)
198 { oss << _gs_coo[i*_dim+j]; if(j!=_dim-1) oss << ", "; }
203 std::copy(_gs_coo.begin(),_gs_coo.end(),std::ostream_iterator<double>(oss," "));
204 oss << "\n - Weights of Gauss coords are : "; std::copy(_w.begin(),_w.end(),std::ostream_iterator<double>(oss," "));
208 void MEDFileFieldPerMeshPerTypePerDisc::assignFieldNoProfile(int& start, int offset, int nbOfCells, const MEDCouplingFieldDouble *field, const DataArray *arrr, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
210 _type=field->getTypeOfField();
216 getOrCreateAndGetArray()->setContigPartOfSelectedValues2(_start,arrr,offset,offset+nbOfCells,1);
217 _end=_start+nbOfCells;
223 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr=field->getDiscretization()->getOffsetArr(field->getMesh());
224 const int *arrPtr=arr->getConstPointer();
225 getOrCreateAndGetArray()->setContigPartOfSelectedValues2(_start,arrr,arrPtr[offset],arrPtr[offset+nbOfCells],1);
226 _end=_start+(arrPtr[offset+nbOfCells]-arrPtr[offset]);
232 const MEDCouplingFieldDiscretization *disc=field->getDiscretization();
233 const MEDCouplingGaussLocalization& gsLoc=field->getGaussLocalization(_loc_id);
234 const MEDCouplingFieldDiscretizationGauss *disc2=dynamic_cast<const MEDCouplingFieldDiscretizationGauss *>(disc);
236 throw INTERP_KERNEL::Exception("assignFieldNoProfile : invalid call to this method ! Internal Error !");
237 const DataArrayInt *dai=disc2->getArrayOfDiscIds();
238 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> dai2=disc2->getOffsetArr(field->getMesh());
239 const int *dai2Ptr=dai2->getConstPointer();
240 int nbi=gsLoc.getWeights().size();
241 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da2=dai->selectByTupleId2(offset,offset+nbOfCells,1);
242 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da3=da2->getIdsEqual(_loc_id);
243 const int *da3Ptr=da3->getConstPointer();
244 if(da3->getNumberOfTuples()!=nbOfCells)
245 {//profile : for gauss even in NoProfile !!!
246 std::ostringstream oss; oss << "Pfl_" << nasc.getName() << "_" << INTERP_KERNEL::CellModel::GetCellModel(getGeoType()).getRepr() << "_" << _loc_id;
248 da3->setName(_profile.c_str());
249 glob.appendProfile(da3);
251 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da4=DataArrayInt::New();
252 _nval=da3->getNbOfElems();
253 da4->alloc(_nval*nbi,1);
254 int *da4Ptr=da4->getPointer();
255 for(int i=0;i<_nval;i++)
257 int ref=dai2Ptr[offset+da3Ptr[i]];
258 for(int j=0;j<nbi;j++)
261 std::ostringstream oss2; oss2 << "Loc_" << nasc.getName() << "_" << INTERP_KERNEL::CellModel::GetCellModel(getGeoType()).getRepr() << "_" << _loc_id;
262 _localization=oss2.str();
263 getOrCreateAndGetArray()->setContigPartOfSelectedValues(_start,arrr,da4);
264 _end=_start+_nval*nbi;
265 glob.appendLoc(_localization.c_str(),getGeoType(),gsLoc.getRefCoords(),gsLoc.getGaussCoords(),gsLoc.getWeights());
269 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::assignFieldNoProfile : not implemented yet for such discretization type of field !");
275 * Leaf method of field with profile assignement. This method is the most general one. No optimization is done here.
276 * \param [in] pflName input containing name of profile if any. 0 if no profile (except for GAUSS_PT where a no profile can hide a profile when splitted by loc_id).
277 * \param [in] multiTypePfl is the end user profile specified in high level API
278 * \param [in] idsInPfl is the selection into the \a multiTypePfl whole profile that corresponds to the current geometric type.
279 * \param [in] locIds is the profile needed to be created for MED file format. It can be null if all cells of current geometric type are fetched in \a multiTypePfl.
280 * \b WARNING if not null the MED file profile can be subdivided again in case of Gauss points.
281 * \param [in] mesh is the mesh coming from the MEDFileMesh instance in correspondance with the MEDFileField. The mesh inside the \a field is simply ignored.
283 void MEDFileFieldPerMeshPerTypePerDisc::assignFieldProfile(int& start, const DataArrayInt *multiTypePfl, const DataArrayInt *idsInPfl, DataArrayInt *locIds, int nbOfEltsInWholeMesh, const MEDCouplingFieldDouble *field, const DataArray *arrr, const MEDCouplingMesh *mesh, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
286 _type=field->getTypeOfField();
287 std::string pflName(multiTypePfl->getName());
288 std::ostringstream oss; oss << pflName;
289 if(_type!=ON_NODES) { const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(getGeoType()); oss << "_" << cm.getRepr(); } else { oss << "_NODE"; }
293 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::assignFieldProfile : existing profile with empty name !");
294 if(_type!=ON_GAUSS_PT)
296 locIds->setName(oss.str().c_str());
297 glob.appendProfile(locIds);
306 _nval=idsInPfl->getNumberOfTuples();
307 getOrCreateAndGetArray()->setContigPartOfSelectedValues2(_start,arrr,0,arrr->getNumberOfTuples(),1);
313 _nval=idsInPfl->getNumberOfTuples();
314 getOrCreateAndGetArray()->setContigPartOfSelectedValues(_start,arrr,idsInPfl);
320 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr=field->getDiscretization()->getOffsetArr(mesh);
321 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr2=arr->deltaShiftIndex();
322 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr3=arr2->selectByTupleId(multiTypePfl->begin(),multiTypePfl->end());
323 arr3->computeOffsets2();
324 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> tmp=idsInPfl->buildExplicitArrByRanges(arr3);
325 int trueNval=tmp->getNumberOfTuples();
326 _nval=idsInPfl->getNumberOfTuples();
327 getOrCreateAndGetArray()->setContigPartOfSelectedValues(_start,arrr,tmp);
328 _end=_start+trueNval;
333 const MEDCouplingFieldDiscretizationGauss *disc2=dynamic_cast<const MEDCouplingFieldDiscretizationGauss *>(field->getDiscretization());
335 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : invalid call to this method ! Internal Error !");
336 const DataArrayInt *da1=disc2->getArrayOfDiscIds();
337 const MEDCouplingGaussLocalization& gsLoc=field->getGaussLocalization(_loc_id);
338 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da2=da1->selectByTupleId(idsInPfl->begin(),idsInPfl->end());
339 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da3=da2->getIdsEqual(_loc_id);
340 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da4=idsInPfl->selectByTupleId(da3->begin(),da3->end());
342 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> mesh2=mesh->buildPart(multiTypePfl->begin(),multiTypePfl->end());
343 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr=disc2->getOffsetArr(mesh2);
345 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> tmp=DataArrayInt::New();
347 for(const int *pt=da4->begin();pt!=da4->end();pt++)
348 trueNval+=arr->getIJ(*pt+1,0)-arr->getIJ(*pt,0);
349 tmp->alloc(trueNval,1);
350 int *tmpPtr=tmp->getPointer();
351 for(const int *pt=da4->begin();pt!=da4->end();pt++)
352 for(int j=arr->getIJ(*pt,0);j<arr->getIJ(*pt+1,0);j++)
355 _nval=da4->getNumberOfTuples();
356 getOrCreateAndGetArray()->setContigPartOfSelectedValues(_start,arrr,tmp);
357 _end=_start+trueNval;
358 oss << "_loc_" << _loc_id;
361 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da5=locIds->selectByTupleId(da3->begin(),da3->end());
362 da5->setName(oss.str().c_str());
363 glob.appendProfile(da5);
368 if(da3->getNumberOfTuples()!=nbOfEltsInWholeMesh || !da3->isIdentity())
370 da3->setName(oss.str().c_str());
371 glob.appendProfile(da3);
375 std::ostringstream oss2; oss2 << "Loc_" << nasc.getName() << "_" << INTERP_KERNEL::CellModel::GetCellModel(getGeoType()).getRepr() << "_" << _loc_id;
376 _localization=oss2.str();
377 glob.appendLoc(_localization.c_str(),getGeoType(),gsLoc.getRefCoords(),gsLoc.getGaussCoords(),gsLoc.getWeights());
381 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::assignFieldProfile : not implemented yet for such discretization type of field !");
386 void MEDFileFieldPerMeshPerTypePerDisc::assignNodeFieldNoProfile(int& start, const MEDCouplingFieldDouble *field, const DataArray *arrr, MEDFileFieldGlobsReal& glob)
389 _nval=arrr->getNumberOfTuples();
390 getOrCreateAndGetArray()->setContigPartOfSelectedValues2(_start,arrr,0,_nval,1);
395 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerTypePerDisc::NewOnRead(MEDFileFieldPerMeshPerType *fath, TypeOfField type, int profileIt)
397 return new MEDFileFieldPerMeshPerTypePerDisc(fath,type,profileIt);
400 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerTypePerDisc::New(MEDFileFieldPerMeshPerType *fath, TypeOfField type, int locId)
402 return new MEDFileFieldPerMeshPerTypePerDisc(fath,type,locId,std::string());
405 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerTypePerDisc::New(const MEDFileFieldPerMeshPerTypePerDisc& other)
407 return new MEDFileFieldPerMeshPerTypePerDisc(other);
410 std::size_t MEDFileFieldPerMeshPerTypePerDisc::getHeapMemorySizeWithoutChildren() const
412 return _profile.capacity()+_localization.capacity()+5*sizeof(int);
415 std::vector<const BigMemoryObject *> MEDFileFieldPerMeshPerTypePerDisc::getDirectChildren() const
417 return std::vector<const BigMemoryObject *>();
420 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerTypePerDisc::deepCpy(MEDFileFieldPerMeshPerType *father) const
422 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> ret=new MEDFileFieldPerMeshPerTypePerDisc(*this);
427 MEDFileFieldPerMeshPerTypePerDisc::MEDFileFieldPerMeshPerTypePerDisc(MEDFileFieldPerMeshPerType *fath, TypeOfField atype, int profileIt)
428 try:_type(atype),_father(fath),_profile_it(profileIt)
431 catch(INTERP_KERNEL::Exception& e)
436 MEDFileFieldPerMeshPerTypePerDisc::MEDFileFieldPerMeshPerTypePerDisc(MEDFileFieldPerMeshPerType *fath, TypeOfField type, int locId, const std::string& dummy):_type(type),_father(fath),_loc_id(locId)
440 MEDFileFieldPerMeshPerTypePerDisc::MEDFileFieldPerMeshPerTypePerDisc(const MEDFileFieldPerMeshPerTypePerDisc& other):RefCountObject(other),_type(other._type),_father(0),_start(other._start),_end(other._end),_nval(other._nval),_profile(other._profile),_localization(other._localization),_loc_id(other._loc_id),_tmp_work1(other._tmp_work1)
444 MEDFileFieldPerMeshPerTypePerDisc::MEDFileFieldPerMeshPerTypePerDisc():_type(ON_CELLS),_father(0),_start(-std::numeric_limits<int>::max()),_end(-std::numeric_limits<int>::max()),
445 _nval(-std::numeric_limits<int>::max()),_loc_id(-std::numeric_limits<int>::max())
449 const MEDFileFieldPerMeshPerType *MEDFileFieldPerMeshPerTypePerDisc::getFather() const
454 void MEDFileFieldPerMeshPerTypePerDisc::loadOnlyStructureOfDataRecursively(med_idt fid, int& start, const MEDFileFieldNameScope& nasc)
456 INTERP_KERNEL::AutoPtr<char> locname=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
457 INTERP_KERNEL::AutoPtr<char> pflname=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
458 std::string fieldName=nasc.getName();
459 std::string meshName=getMeshName();
460 int iteration=getIteration();
461 int order=getOrder();
462 TypeOfField type=getType();
463 INTERP_KERNEL::NormalizedCellType geoType=getGeoType();
465 med_geometry_type mgeoti;
466 med_entity_type menti=MEDFileFieldPerMeshPerType::ConvertIntoMEDFileType(type,geoType,mgeoti);
467 _nval=MEDfieldnValueWithProfile(fid,fieldName.c_str(),iteration,order,menti,mgeoti,_profile_it,MED_COMPACT_PFLMODE,
468 pflname,&profilesize,locname,&nbi);
469 _profile=MEDLoaderBase::buildStringFromFortran(pflname,MED_NAME_SIZE);
470 _localization=MEDLoaderBase::buildStringFromFortran(locname,MED_NAME_SIZE);
472 _end=start+_nval*nbi;
474 if(type==ON_CELLS && !_localization.empty())
476 if(_localization!="MED_GAUSS_ELNO")//For compatibily with MED2.3
477 setType(ON_GAUSS_PT);
480 setType(ON_GAUSS_NE);
481 _localization.clear();
486 void MEDFileFieldPerMeshPerTypePerDisc::loadBigArray(med_idt fid, const MEDFileFieldNameScope& nasc)
488 std::string fieldName=nasc.getName();
489 std::string meshName=getMeshName();
490 int iteration=getIteration();
491 int order=getOrder();
492 TypeOfField type=getType();
493 INTERP_KERNEL::NormalizedCellType geoType=getGeoType();
494 med_geometry_type mgeoti;
495 med_entity_type menti=MEDFileFieldPerMeshPerType::ConvertIntoMEDFileType(type,geoType,mgeoti);
497 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::loadBigArray : internal error in range !");
500 DataArray *arr=getOrCreateAndGetArray();//arr is not null due to the spec of getOrCreateAndGetArray
501 if(_start<0 || _start>=arr->getNumberOfTuples())
503 std::ostringstream oss; oss << "MEDFileFieldPerMeshPerTypePerDisc::loadBigArray : Invalid start ("<< _start << ") regarding admissible range of allocated array [0," << arr->getNumberOfTuples() << ") !";
504 throw INTERP_KERNEL::Exception(oss.str().c_str());
506 if(_end<0 || _end>arr->getNumberOfTuples())
508 std::ostringstream oss; oss << "MEDFileFieldPerMeshPerTypePerDisc::loadBigArray : Invalid start ("<< _start << ") regarding admissible range of allocated array [0," << arr->getNumberOfTuples() << "] !";
509 throw INTERP_KERNEL::Exception(oss.str().c_str());
512 INTERP_KERNEL::AutoPtr<char> locname=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
513 med_int nbValsInFile=MEDfieldnValueWithProfileByName(fid,fieldName.c_str(),iteration,order,menti,mgeoti,_profile.c_str(),MED_COMPACT_PFLMODE,&tmp1,locname,&nbi);
514 int nbOfCompo=arr->getNumberOfComponents();
515 if(_end-_start!=nbValsInFile*nbi)
517 std::ostringstream oss; oss << "MEDFileFieldPerMeshPerTypePerDisc::loadBigArray : The number of tuples to read is " << nbValsInFile << "*" << nbi << " (nb integration points) ! But in data structure it values " << _end-_start << " is expected !";
518 throw INTERP_KERNEL::Exception(oss.str().c_str());
520 DataArrayDouble *arrD=dynamic_cast<DataArrayDouble *>(arr);
523 double *startFeeding=arrD->getPointer()+_start*nbOfCompo;
524 MEDfieldValueWithProfileRd(fid,fieldName.c_str(),iteration,order,menti,mgeoti,MED_COMPACT_PFLMODE,
525 _profile.c_str(),MED_FULL_INTERLACE,MED_ALL_CONSTITUENT,reinterpret_cast<unsigned char*>(startFeeding));
528 DataArrayInt *arrI=dynamic_cast<DataArrayInt *>(arr);
531 int *startFeeding=arrI->getPointer()+_start*nbOfCompo;
532 MEDfieldValueWithProfileRd(fid,fieldName.c_str(),iteration,order,menti,mgeoti,MED_COMPACT_PFLMODE,
533 _profile.c_str(),MED_FULL_INTERLACE,MED_ALL_CONSTITUENT,reinterpret_cast<unsigned char*>(startFeeding));
536 throw INTERP_KERNEL::Exception("Error on array reading ! Unrecognized type of field ! Should be in FLOAT64 or INT32 !");
540 * Set a \c this->_start **and** \c this->_end keeping the same delta between the two.
542 void MEDFileFieldPerMeshPerTypePerDisc::setNewStart(int newValueOfStart)
544 int delta=_end-_start;
545 _start=newValueOfStart;
549 int MEDFileFieldPerMeshPerTypePerDisc::getIteration() const
551 return _father->getIteration();
554 int MEDFileFieldPerMeshPerTypePerDisc::getOrder() const
556 return _father->getOrder();
559 double MEDFileFieldPerMeshPerTypePerDisc::getTime() const
561 return _father->getTime();
564 std::string MEDFileFieldPerMeshPerTypePerDisc::getMeshName() const
566 return _father->getMeshName();
569 void MEDFileFieldPerMeshPerTypePerDisc::simpleRepr(int bkOffset, std::ostream& oss, int id) const
571 const char startLine[]=" ## ";
572 std::string startLine2(bkOffset,' ');
573 startLine2+=startLine;
574 MEDCouplingFieldDiscretization *tmp=MEDCouplingFieldDiscretization::New(_type);
575 oss << startLine2 << "Localization #" << id << "." << std::endl;
576 oss << startLine2 << " Type=" << tmp->getRepr() << "." << std::endl;
578 oss << startLine2 << " This type discretization lies on profile : \"" << _profile << "\" and on the following localization : \"" << _localization << "\"." << std::endl;
579 oss << startLine2 << " This type discretization has " << _end-_start << " tuples (start=" << _start << ", end=" << _end << ")." << std::endl;
580 oss << startLine2 << " This type discretization has " << (_end-_start)/_nval << " integration points." << std::endl;
583 TypeOfField MEDFileFieldPerMeshPerTypePerDisc::getType() const
588 void MEDFileFieldPerMeshPerTypePerDisc::fillTypesOfFieldAvailable(std::set<TypeOfField>& types) const
593 void MEDFileFieldPerMeshPerTypePerDisc::setType(TypeOfField newType)
598 INTERP_KERNEL::NormalizedCellType MEDFileFieldPerMeshPerTypePerDisc::getGeoType() const
600 return _father->getGeoType();
603 int MEDFileFieldPerMeshPerTypePerDisc::getNumberOfComponents() const
605 return _father->getNumberOfComponents();
608 int MEDFileFieldPerMeshPerTypePerDisc::getNumberOfTuples() const
613 DataArray *MEDFileFieldPerMeshPerTypePerDisc::getOrCreateAndGetArray()
615 return _father->getOrCreateAndGetArray();
618 const DataArray *MEDFileFieldPerMeshPerTypePerDisc::getOrCreateAndGetArray() const
620 const MEDFileFieldPerMeshPerType *fath=_father;
621 return fath->getOrCreateAndGetArray();
624 const std::vector<std::string>& MEDFileFieldPerMeshPerTypePerDisc::getInfo() const
626 return _father->getInfo();
629 std::string MEDFileFieldPerMeshPerTypePerDisc::getProfile() const
634 void MEDFileFieldPerMeshPerTypePerDisc::setProfile(const std::string& newPflName)
639 std::string MEDFileFieldPerMeshPerTypePerDisc::getLocalization() const
641 return _localization;
644 void MEDFileFieldPerMeshPerTypePerDisc::setLocalization(const std::string& newLocName)
646 _localization=newLocName;
649 void MEDFileFieldPerMeshPerTypePerDisc::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
651 for(std::vector< std::pair<std::vector<std::string>, std::string > >::const_iterator it2=mapOfModif.begin();it2!=mapOfModif.end();it2++)
653 if(std::find((*it2).first.begin(),(*it2).first.end(),_profile)!=(*it2).first.end())
655 _profile=(*it2).second;
661 void MEDFileFieldPerMeshPerTypePerDisc::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
663 for(std::vector< std::pair<std::vector<std::string>, std::string > >::const_iterator it2=mapOfModif.begin();it2!=mapOfModif.end();it2++)
665 if(std::find((*it2).first.begin(),(*it2).first.end(),_localization)!=(*it2).first.end())
667 _localization=(*it2).second;
673 void MEDFileFieldPerMeshPerTypePerDisc::getFieldAtLevel(TypeOfField type, const MEDFileFieldGlobsReal *glob, std::vector< std::pair<int,int> >& dads, std::vector<const DataArrayInt *>& pfls, std::vector<int>& locs, std::vector<INTERP_KERNEL::NormalizedCellType>& geoTypes) const
677 dads.push_back(std::pair<int,int>(_start,_end));
678 geoTypes.push_back(getGeoType());
683 pfls.push_back(glob->getProfile(_profile.c_str()));
685 if(_localization.empty())
689 locs.push_back(glob->getLocalizationId(_localization.c_str()));
693 void MEDFileFieldPerMeshPerTypePerDisc::fillValues(int discId, int& startEntryId, std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
695 entries[startEntryId]=std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int> ,std::pair<int,int> >(std::pair<INTERP_KERNEL::NormalizedCellType,int>(getGeoType(),discId),std::pair<int,int>(_start,_end));
699 void MEDFileFieldPerMeshPerTypePerDisc::writeLL(med_idt fid, const MEDFileFieldNameScope& nasc) const
701 TypeOfField type=getType();
702 INTERP_KERNEL::NormalizedCellType geoType=getGeoType();
703 med_geometry_type mgeoti;
704 med_entity_type menti=MEDFileFieldPerMeshPerType::ConvertIntoMEDFileType(type,geoType,mgeoti);
705 const DataArray *arr=getOrCreateAndGetArray();
707 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::writeLL : no array set !");
708 const DataArrayDouble *arrD=dynamic_cast<const DataArrayDouble *>(arr);
709 const DataArrayInt *arrI=dynamic_cast<const DataArrayInt *>(arr);
710 const unsigned char *locToWrite=0;
712 locToWrite=reinterpret_cast<const unsigned char *>(arrD->getConstPointer()+_start*arr->getNumberOfComponents());
714 locToWrite=reinterpret_cast<const unsigned char *>(arrI->getConstPointer()+_start*arr->getNumberOfComponents());
716 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::writeLL : not recognized type of values ! Supported are FLOAT64 and INT32 !");
717 MEDfieldValueWithProfileWr(fid,nasc.getName().c_str(),getIteration(),getOrder(),getTime(),menti,mgeoti,
718 MED_COMPACT_PFLMODE,_profile.c_str(),_localization.c_str(),MED_FULL_INTERLACE,MED_ALL_CONSTITUENT,_nval,
722 void MEDFileFieldPerMeshPerTypePerDisc::getCoarseData(TypeOfField& type, std::pair<int,int>& dad, std::string& pfl, std::string& loc) const
727 dad.first=_start; dad.second=_end;
731 * \param [in] codeOfMesh is of format returned by MEDCouplingUMesh::getDistributionOfTypes. And for each *i* oldCode[3*i+2] gives the position (MEDFileUMesh::PutInThirdComponentOfCodeOffset).
732 * This code corresponds to the distribution of types in the corresponding mesh.
733 * \param [out] ptToFill memory zone where the output will be stored.
734 * \return the size of data pushed into output param \a ptToFill
736 int MEDFileFieldPerMeshPerTypePerDisc::fillEltIdsFromCode(int offset, const std::vector<int>& codeOfMesh, const MEDFileFieldGlobsReal& glob, int *ptToFill) const
739 std::ostringstream oss;
740 std::size_t nbOfType=codeOfMesh.size()/3;
742 for(std::size_t i=0;i<nbOfType && found==-1;i++)
743 if(getGeoType()==(INTERP_KERNEL::NormalizedCellType)codeOfMesh[3*i])
747 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(getGeoType());
748 oss << "MEDFileFieldPerMeshPerTypePerDisc::fillEltIdsFromCode : not found geometric type " << cm.getRepr() << " in the referenced mesh of field !";
749 throw INTERP_KERNEL::Exception(oss.str().c_str());
754 if(_nval!=codeOfMesh[3*found+1])
756 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(getGeoType());
757 oss << "MEDFileFieldPerMeshPerTypePerDisc::fillEltIdsFromCode : for geometric type " << cm.getRepr() << " number of elt ids in mesh is equal to " << _nval;
758 oss << " whereas mesh has " << codeOfMesh[3*found+1] << " for this geometric type !";
759 throw INTERP_KERNEL::Exception(oss.str().c_str());
761 for(int ii=codeOfMesh[3*found+2];ii<codeOfMesh[3*found+2]+_nval;ii++)
766 const DataArrayInt *pfl=glob.getProfile(_profile.c_str());
767 if(pfl->getNumberOfTuples()!=_nval)
769 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(getGeoType());
770 oss << "MEDFileFieldPerMeshPerTypePerDisc::fillEltIdsFromCode : for geometric type " << cm.getRepr() << ", field is defined on profile \"" << _profile << "\" and size of profile is ";
772 oss << pfl->getNumberOfTuples() << " whereas the number of ids is set to " << _nval << " for this geometric type !";
773 throw INTERP_KERNEL::Exception(oss.str().c_str());
775 int offset2=codeOfMesh[3*found+2];
776 for(const int *pflId=pfl->begin();pflId!=pfl->end();pflId++)
778 if(*pflId<codeOfMesh[3*found+1])
779 *work++=offset2+*pflId;
785 int MEDFileFieldPerMeshPerTypePerDisc::fillTupleIds(int *ptToFill) const
787 for(int i=_start;i<_end;i++)
792 int MEDFileFieldPerMeshPerTypePerDisc::ConvertType(TypeOfField type, int locId)
803 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::ConvertType : not managed type of field !");
807 std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> > MEDFileFieldPerMeshPerTypePerDisc::SplitPerDiscretization(const std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>& entries)
810 std::map<std::pair<std::string,TypeOfField>,int> m;
811 std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> > ret;
812 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=entries.begin();it!=entries.end();it++)
813 if(m.find(std::pair<std::string,TypeOfField>((*it)->getLocalization(),(*it)->getType()))==m.end())
814 m[std::pair<std::string,TypeOfField>((*it)->getLocalization(),(*it)->getType())]=id++;
816 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=entries.begin();it!=entries.end();it++)
817 ret[m[std::pair<std::string,TypeOfField>((*it)->getLocalization(),(*it)->getType())]].push_back(*it);
822 * - \c this->_loc_id mutable attribute is used for elt id in mesh offsets.
824 * \param [in] offset the offset id used to take into account that \a result is not compulsary empty in input
825 * \param [in] entriesOnSameDisc some entries **on same localization** if not the result can be invalid. The _start and _end on them are relative to \a arr parameter.
826 * \param [in] explicitIdsInMesh ids in mesh of the considered chunk.
827 * \param [in] newCode one of the input parameter to explicit the new geo type dispatch (in classical format same than those asked by MEDFileFields::renumberEntitiesLyingOnMesh)
828 * \param [in,out] glob if necessary by the method, new profiles can be added to it
829 * \param [in,out] arr after the call of this method \a arr is renumbered to be compliant with added entries to \a result.
830 * \param [out] result All new entries will be appended on it.
831 * \return false if the configuration of renumbering leads to an unnecessary resplit of input \a entriesOnSameDisc. If not true is returned (the most general case !)
833 bool MEDFileFieldPerMeshPerTypePerDisc::RenumberChunks(int offset, const std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>& entriesOnSameDisc,
834 const DataArrayInt *explicitIdsInMesh,
835 const std::vector<int>& newCode,
836 MEDFileFieldGlobsReal& glob, DataArrayDouble *arr,
837 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >& result)
839 if(entriesOnSameDisc.empty())
841 TypeOfField type=entriesOnSameDisc[0]->getType();
842 int szEntities=0,szTuples=0;
843 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=entriesOnSameDisc.begin();it!=entriesOnSameDisc.end();it++)
844 { szEntities+=(*it)->_nval; szTuples+=(*it)->_end-(*it)->_start; }
845 int nbi=szTuples/szEntities;
846 if(szTuples%szEntities!=0)
847 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::RenumberChunks : internal error the splitting into same dicretization failed !");
848 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> renumTuples=DataArrayInt::New(); renumTuples->alloc(szTuples,1);
849 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ranges=MEDCouplingUMesh::ComputeRangesFromTypeDistribution(newCode);
850 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > newGeoTypesPerChunk(entriesOnSameDisc.size());
851 std::vector< const DataArrayInt * > newGeoTypesPerChunk2(entriesOnSameDisc.size());
852 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > newGeoTypesPerChunk_bis(entriesOnSameDisc.size());
853 std::vector< const DataArrayInt * > newGeoTypesPerChunk3(entriesOnSameDisc.size());
854 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> newGeoTypesPerChunk4=DataArrayInt::New(); newGeoTypesPerChunk4->alloc(szEntities,nbi);
856 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=entriesOnSameDisc.begin();it!=entriesOnSameDisc.end();it++,id++)
858 int startOfEltIdOfChunk=(*it)->_start;
859 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> newEltIds=explicitIdsInMesh->substr(startOfEltIdOfChunk,startOfEltIdOfChunk+(*it)->_nval);
860 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> rangeIdsForChunk=newEltIds->findRangeIdForEachTuple(ranges);
861 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> idsInRrangeForChunk=newEltIds->findIdInRangeForEachTuple(ranges);
863 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> tmp=rangeIdsForChunk->duplicateEachTupleNTimes(nbi); rangeIdsForChunk->rearrange(nbi);
864 newGeoTypesPerChunk4->setPartOfValues1(tmp,(*it)->_tmp_work1-offset,(*it)->_tmp_work1+(*it)->_nval*nbi-offset,1,0,nbi,1);
866 newGeoTypesPerChunk[id]=rangeIdsForChunk; newGeoTypesPerChunk2[id]=rangeIdsForChunk;
867 newGeoTypesPerChunk_bis[id]=idsInRrangeForChunk; newGeoTypesPerChunk3[id]=idsInRrangeForChunk;
869 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> newGeoTypesEltIdsAllGather=DataArrayInt::Aggregate(newGeoTypesPerChunk2); newGeoTypesPerChunk.clear(); newGeoTypesPerChunk2.clear();
870 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> newGeoTypesEltIdsAllGather2=DataArrayInt::Aggregate(newGeoTypesPerChunk3); newGeoTypesPerChunk_bis.clear(); newGeoTypesPerChunk3.clear();
871 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> diffVals=newGeoTypesEltIdsAllGather->getDifferentValues();
872 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> renumEltIds=newGeoTypesEltIdsAllGather->buildPermArrPerLevel();
874 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> renumTupleIds=newGeoTypesPerChunk4->buildPermArrPerLevel();
876 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arrPart=arr->substr(offset,offset+szTuples);
877 arrPart->renumberInPlace(renumTupleIds->begin());
878 arr->setPartOfValues1(arrPart,offset,offset+szTuples,1,0,arrPart->getNumberOfComponents(),1);
880 const int *idIt=diffVals->begin();
881 std::list<const MEDFileFieldPerMeshPerTypePerDisc *> li(entriesOnSameDisc.begin(),entriesOnSameDisc.end());
883 for(int i=0;i<diffVals->getNumberOfTuples();i++,idIt++)
885 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ids=newGeoTypesEltIdsAllGather->getIdsEqual(*idIt);
886 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> subIds=newGeoTypesEltIdsAllGather2->selectByTupleId(ids->begin(),ids->end());
887 int nbEntityElts=subIds->getNumberOfTuples();
889 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> eltToAdd=MEDFileFieldPerMeshPerTypePerDisc::
890 NewObjectOnSameDiscThanPool(type,(INTERP_KERNEL::NormalizedCellType)newCode[3*(*idIt)],subIds,!subIds->isIdentity() || nbEntityElts!=newCode[3*(*idIt)+1],nbi,
894 result.push_back(eltToAdd);
895 offset2+=nbEntityElts*nbi;
897 ret=ret || li.empty();
902 * \param [in] typeF type of field of new chunk
903 * \param [in] geoType the geometric type of the chunk
904 * \param [in] idsOfMeshElt the entity ids of mesh (cells or nodes) of the new chunk.
905 * \param [in] isPfl specifies if a profile is requested regarding size of \a idsOfMeshElt and the number of such entities regarding underlying mesh.
906 * \param [in] nbi number of integration points
907 * \param [in] offset The offset in the **global array of data**.
908 * \param [in,out] entriesOnSameDisc the pool **on the same discretization** inside which it will be attempted to find an existing entry corresponding exactly
909 * to the new chunk to create.
910 * \param [in,out] glob the global shared info that will be requested for existing profiles or to append a new profile if needed.
911 * \param [out] notInExisting If false the return newly allocated entry is not coming from \a entriesOnSameDisc. If true the output comes from copy of \a entriesOnSameDisc
912 * and corresponding entry erased from \a entriesOnSameDisc.
913 * \return a newly allocated chunk
915 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerTypePerDisc::NewObjectOnSameDiscThanPool(TypeOfField typeF, INTERP_KERNEL::NormalizedCellType geoType, DataArrayInt *idsOfMeshElt,
916 bool isPfl, int nbi, int offset,
917 std::list< const MEDFileFieldPerMeshPerTypePerDisc *>& entriesOnSameDisc,
918 MEDFileFieldGlobsReal& glob,
919 bool ¬InExisting) throw(INTERP_KERNEL::Exception)
921 int nbMeshEntities=idsOfMeshElt->getNumberOfTuples();
922 std::list< const MEDFileFieldPerMeshPerTypePerDisc *>::iterator it=entriesOnSameDisc.begin();
923 for(;it!=entriesOnSameDisc.end();it++)
925 if(((INTERP_KERNEL::NormalizedCellType)(*it)->_loc_id)==geoType && (*it)->_nval==nbMeshEntities)
929 if((*it)->_profile.empty())
932 if(!(*it)->_profile.empty())
934 const DataArrayInt *pfl=glob.getProfile((*it)->_profile.c_str());
935 if(pfl->isEqualWithoutConsideringStr(*idsOfMeshElt))
941 if(it==entriesOnSameDisc.end())
944 MEDFileFieldPerMeshPerTypePerDisc *ret=new MEDFileFieldPerMeshPerTypePerDisc;
946 ret->_loc_id=(int)geoType;
947 ret->_nval=nbMeshEntities;
949 ret->_end=ret->_start+ret->_nval*nbi;
952 idsOfMeshElt->setName(glob.createNewNameOfPfl().c_str());
953 glob.appendProfile(idsOfMeshElt);
954 ret->_profile=idsOfMeshElt->getName();
956 //tony treatment of localization
962 MEDFileFieldPerMeshPerTypePerDisc *ret=MEDFileFieldPerMeshPerTypePerDisc::New(*(*it));
963 ret->_loc_id=(int)geoType;
964 ret->setNewStart(offset);
965 entriesOnSameDisc.erase(it);
971 MEDFileFieldPerMeshPerType *MEDFileFieldPerMeshPerType::NewOnRead(med_idt fid, MEDFileFieldPerMesh *fath, TypeOfField type, INTERP_KERNEL::NormalizedCellType geoType, const MEDFileFieldNameScope& nasc)
973 return new MEDFileFieldPerMeshPerType(fid,fath,type,geoType,nasc);
976 MEDFileFieldPerMeshPerType *MEDFileFieldPerMeshPerType::New(MEDFileFieldPerMesh *fath, INTERP_KERNEL::NormalizedCellType geoType)
978 return new MEDFileFieldPerMeshPerType(fath,geoType);
981 std::size_t MEDFileFieldPerMeshPerType::getHeapMemorySizeWithoutChildren() const
983 return _field_pm_pt_pd.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc>);
986 std::vector<const BigMemoryObject *> MEDFileFieldPerMeshPerType::getDirectChildren() const
988 std::vector<const BigMemoryObject *> ret;
989 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
991 const MEDFileFieldPerMeshPerTypePerDisc *cur(*it);
998 MEDFileFieldPerMeshPerType *MEDFileFieldPerMeshPerType::deepCpy(MEDFileFieldPerMesh *father) const
1000 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerType> ret=new MEDFileFieldPerMeshPerType(*this);
1001 ret->_father=father;
1003 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++,i++)
1005 if((const MEDFileFieldPerMeshPerTypePerDisc *)*it)
1006 ret->_field_pm_pt_pd[i]=(*it)->deepCpy((MEDFileFieldPerMeshPerType *)ret);
1011 void MEDFileFieldPerMeshPerType::assignFieldNoProfile(int& start, int offset, int nbOfCells, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
1013 std::vector<int> pos=addNewEntryIfNecessary(field,offset,nbOfCells);
1014 for(std::vector<int>::const_iterator it=pos.begin();it!=pos.end();it++)
1015 _field_pm_pt_pd[*it]->assignFieldNoProfile(start,offset,nbOfCells,field,arr,glob,nasc);
1019 * This method is the most general one. No optimization is done here.
1020 * \param [in] multiTypePfl is the end user profile specified in high level API
1021 * \param [in] idsInPfl is the selection into the \a multiTypePfl whole profile that corresponds to the current geometric type.
1022 * \param [in] locIds is the profile needed to be created for MED file format. It can be null if all cells of current geometric type are fetched in \a multiTypePfl.
1023 * \b WARNING if not null the MED file profile can be subdivided again in case of Gauss points.
1024 * \param [in] nbOfEltsInWholeMesh nb of elts of type \a this->_geo_type in \b WHOLE mesh
1025 * \param [in] mesh is the mesh coming from the MEDFileMesh instance in correspondance with the MEDFileField. The mesh inside the \a field is simply ignored.
1027 void MEDFileFieldPerMeshPerType::assignFieldProfile(int& start, const DataArrayInt *multiTypePfl, const DataArrayInt *idsInPfl, DataArrayInt *locIds, int nbOfEltsInWholeMesh, const MEDCouplingFieldDouble *field, const DataArray *arr, const MEDCouplingMesh *mesh, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
1029 std::vector<int> pos=addNewEntryIfNecessary(field,idsInPfl);
1030 for(std::vector<int>::const_iterator it=pos.begin();it!=pos.end();it++)
1031 _field_pm_pt_pd[*it]->assignFieldProfile(start,multiTypePfl,idsInPfl,locIds,nbOfEltsInWholeMesh,field,arr,mesh,glob,nasc);
1034 void MEDFileFieldPerMeshPerType::assignNodeFieldNoProfile(int& start, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob)
1036 _field_pm_pt_pd.resize(1);
1037 _field_pm_pt_pd[0]=MEDFileFieldPerMeshPerTypePerDisc::New(this,ON_NODES,-3);
1038 _field_pm_pt_pd[0]->assignNodeFieldNoProfile(start,field,arr,glob);
1041 void MEDFileFieldPerMeshPerType::assignNodeFieldProfile(int& start, const DataArrayInt *pfl, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
1043 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> pfl2=pfl->deepCpy();
1044 if(!arr || !arr->isAllocated())
1045 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerType::assignNodeFieldProfile : input array is null, or not allocated !");
1046 _field_pm_pt_pd.resize(1);
1047 _field_pm_pt_pd[0]=MEDFileFieldPerMeshPerTypePerDisc::New(this,ON_NODES,-3);
1048 _field_pm_pt_pd[0]->assignFieldProfile(start,pfl,pfl2,pfl2,-1,field,arr,0,glob,nasc);//mesh is not requested so 0 is send.
1051 std::vector<int> MEDFileFieldPerMeshPerType::addNewEntryIfNecessary(const MEDCouplingFieldDouble *field, int offset, int nbOfCells)
1053 TypeOfField type=field->getTypeOfField();
1054 if(type!=ON_GAUSS_PT)
1056 int locIdToFind=MEDFileFieldPerMeshPerTypePerDisc::ConvertType(type,0);
1057 int sz=_field_pm_pt_pd.size();
1059 for(int j=0;j<sz && !found;j++)
1061 if(_field_pm_pt_pd[j]->getLocId()==locIdToFind)
1063 _field_pm_pt_pd[j]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1069 _field_pm_pt_pd.resize(sz+1);
1070 _field_pm_pt_pd[sz]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1072 std::vector<int> ret(1,(int)sz);
1077 std::vector<int> ret2=addNewEntryIfNecessaryGauss(field,offset,nbOfCells);
1078 int sz2=ret2.size();
1079 std::vector<int> ret3(sz2);
1081 for(int i=0;i<sz2;i++)
1083 int sz=_field_pm_pt_pd.size();
1084 int locIdToFind=ret2[i];
1086 for(int j=0;j<sz && !found;j++)
1088 if(_field_pm_pt_pd[j]->getLocId()==locIdToFind)
1090 _field_pm_pt_pd[j]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1097 _field_pm_pt_pd.resize(sz+1);
1098 _field_pm_pt_pd[sz]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1106 std::vector<int> MEDFileFieldPerMeshPerType::addNewEntryIfNecessaryGauss(const MEDCouplingFieldDouble *field, int offset, int nbOfCells)
1108 const MEDCouplingFieldDiscretization *disc=field->getDiscretization();
1109 const MEDCouplingFieldDiscretizationGauss *disc2=dynamic_cast<const MEDCouplingFieldDiscretizationGauss *>(disc);
1111 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : invalid call to this method ! Internal Error !");
1112 const DataArrayInt *da=disc2->getArrayOfDiscIds();
1114 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss (no profile) : no localization ids per cell array available ! The input Gauss node field is maybe invalid !");
1115 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da2=da->selectByTupleId2(offset,offset+nbOfCells,1);
1116 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> retTmp=da2->getDifferentValues();
1117 if(retTmp->presenceOfValue(-1))
1118 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : some cells have no dicretization description !");
1119 std::vector<int> ret(retTmp->begin(),retTmp->end());
1123 std::vector<int> MEDFileFieldPerMeshPerType::addNewEntryIfNecessary(const MEDCouplingFieldDouble *field, const DataArrayInt *subCells)
1125 TypeOfField type=field->getTypeOfField();
1126 if(type!=ON_GAUSS_PT)
1128 int locIdToFind=MEDFileFieldPerMeshPerTypePerDisc::ConvertType(type,0);
1129 int sz=_field_pm_pt_pd.size();
1131 for(int j=0;j<sz && !found;j++)
1133 if(_field_pm_pt_pd[j]->getLocId()==locIdToFind)
1135 _field_pm_pt_pd[j]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1141 _field_pm_pt_pd.resize(sz+1);
1142 _field_pm_pt_pd[sz]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1144 std::vector<int> ret(1,0);
1149 std::vector<int> ret2=addNewEntryIfNecessaryGauss(field,subCells);
1150 int sz2=ret2.size();
1151 std::vector<int> ret3(sz2);
1153 for(int i=0;i<sz2;i++)
1155 int sz=_field_pm_pt_pd.size();
1156 int locIdToFind=ret2[i];
1158 for(int j=0;j<sz && !found;j++)
1160 if(_field_pm_pt_pd[j]->getLocId()==locIdToFind)
1162 _field_pm_pt_pd[j]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1169 _field_pm_pt_pd.resize(sz+1);
1170 _field_pm_pt_pd[sz]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1178 std::vector<int> MEDFileFieldPerMeshPerType::addNewEntryIfNecessaryGauss(const MEDCouplingFieldDouble *field, const DataArrayInt *subCells)
1180 const MEDCouplingFieldDiscretization *disc=field->getDiscretization();
1181 const MEDCouplingFieldDiscretizationGauss *disc2=dynamic_cast<const MEDCouplingFieldDiscretizationGauss *>(disc);
1183 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : invalid call to this method ! Internal Error !");
1184 const DataArrayInt *da=disc2->getArrayOfDiscIds();
1186 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : no localization ids per cell array available ! The input Gauss node field is maybe invalid !");
1187 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da2=da->selectByTupleIdSafe(subCells->getConstPointer(),subCells->getConstPointer()+subCells->getNumberOfTuples());
1188 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> retTmp=da2->getDifferentValues();
1189 if(retTmp->presenceOfValue(-1))
1190 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : some cells have no dicretization description !");
1191 std::vector<int> ret(retTmp->begin(),retTmp->end());
1195 const MEDFileFieldPerMesh *MEDFileFieldPerMeshPerType::getFather() const
1200 void MEDFileFieldPerMeshPerType::getDimension(int& dim) const
1202 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1203 int curDim=(int)cm.getDimension();
1204 dim=std::max(dim,curDim);
1207 void MEDFileFieldPerMeshPerType::fillTypesOfFieldAvailable(std::set<TypeOfField>& types) const
1209 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1211 (*it)->fillTypesOfFieldAvailable(types);
1215 void MEDFileFieldPerMeshPerType::fillFieldSplitedByType(std::vector< std::pair<int,int> >& dads, std::vector<TypeOfField>& types, std::vector<std::string>& pfls, std::vector<std::string>& locs) const
1217 int sz=_field_pm_pt_pd.size();
1218 dads.resize(sz); types.resize(sz); pfls.resize(sz); locs.resize(sz);
1219 for(int i=0;i<sz;i++)
1221 _field_pm_pt_pd[i]->getCoarseData(types[i],dads[i],pfls[i],locs[i]);
1225 int MEDFileFieldPerMeshPerType::getIteration() const
1227 return _father->getIteration();
1230 int MEDFileFieldPerMeshPerType::getOrder() const
1232 return _father->getOrder();
1235 double MEDFileFieldPerMeshPerType::getTime() const
1237 return _father->getTime();
1240 std::string MEDFileFieldPerMeshPerType::getMeshName() const
1242 return _father->getMeshName();
1245 void MEDFileFieldPerMeshPerType::simpleRepr(int bkOffset, std::ostream& oss, int id) const
1247 const char startLine[]=" ## ";
1248 std::string startLine2(bkOffset,' ');
1249 std::string startLine3(startLine2);
1250 startLine3+=startLine;
1251 if(_geo_type!=INTERP_KERNEL::NORM_ERROR)
1253 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1254 oss << startLine3 << "Entry geometry type #" << id << " is lying on geometry types " << cm.getRepr() << "." << std::endl;
1257 oss << startLine3 << "Entry geometry type #" << id << " is lying on NODES." << std::endl;
1258 oss << startLine3 << "Entry is defined on " << _field_pm_pt_pd.size() << " localizations." << std::endl;
1260 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++,i++)
1262 const MEDFileFieldPerMeshPerTypePerDisc *cur=(*it);
1264 cur->simpleRepr(bkOffset,oss,i);
1267 oss << startLine2 << " ## " << "Localization #" << i << " is empty !" << std::endl;
1272 void MEDFileFieldPerMeshPerType::getSizes(int& globalSz, int& nbOfEntries) const
1274 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1276 globalSz+=(*it)->getNumberOfTuples();
1278 nbOfEntries+=(int)_field_pm_pt_pd.size();
1281 INTERP_KERNEL::NormalizedCellType MEDFileFieldPerMeshPerType::getGeoType() const
1287 int MEDFileFieldPerMeshPerType::getNumberOfComponents() const
1289 return _father->getNumberOfComponents();
1292 DataArray *MEDFileFieldPerMeshPerType::getOrCreateAndGetArray()
1294 return _father->getOrCreateAndGetArray();
1297 const DataArray *MEDFileFieldPerMeshPerType::getOrCreateAndGetArray() const
1299 const MEDFileFieldPerMesh *fath=_father;
1300 return fath->getOrCreateAndGetArray();
1303 const std::vector<std::string>& MEDFileFieldPerMeshPerType::getInfo() const
1305 return _father->getInfo();
1308 std::vector<std::string> MEDFileFieldPerMeshPerType::getPflsReallyUsed() const
1310 std::vector<std::string> ret;
1311 std::set<std::string> ret2;
1312 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1314 std::string tmp=(*it1)->getProfile();
1316 if(ret2.find(tmp)==ret2.end())
1325 std::vector<std::string> MEDFileFieldPerMeshPerType::getLocsReallyUsed() const
1327 std::vector<std::string> ret;
1328 std::set<std::string> ret2;
1329 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1331 std::string tmp=(*it1)->getLocalization();
1332 if(!tmp.empty() && tmp!=MED_GAUSS_ELNO)
1333 if(ret2.find(tmp)==ret2.end())
1342 std::vector<std::string> MEDFileFieldPerMeshPerType::getPflsReallyUsedMulti() const
1344 std::vector<std::string> ret;
1345 std::set<std::string> ret2;
1346 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1348 std::string tmp=(*it1)->getProfile();
1355 std::vector<std::string> MEDFileFieldPerMeshPerType::getLocsReallyUsedMulti() const
1357 std::vector<std::string> ret;
1358 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1360 std::string tmp=(*it1)->getLocalization();
1361 if(!tmp.empty() && tmp!=MED_GAUSS_ELNO)
1367 void MEDFileFieldPerMeshPerType::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
1369 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1370 (*it1)->changePflsRefsNamesGen(mapOfModif);
1373 void MEDFileFieldPerMeshPerType::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
1375 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1376 (*it1)->changeLocsRefsNamesGen(mapOfModif);
1379 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerType::getLeafGivenLocId(int locId)
1381 if(_field_pm_pt_pd.empty())
1383 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1384 std::ostringstream oss; oss << "MEDFileFieldPerMeshPerType::getLeafGivenLocId : no localizations for geotype \"" << cm.getRepr() << "\" !";
1385 throw INTERP_KERNEL::Exception(oss.str().c_str());
1387 if(locId>=0 && locId<(int)_field_pm_pt_pd.size())
1388 return _field_pm_pt_pd[locId];
1389 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1390 std::ostringstream oss2; oss2 << "MEDFileFieldPerMeshPerType::getLeafGivenLocId : no such locId available (" << locId;
1391 oss2 << ") for geometric type \"" << cm.getRepr() << "\" It should be in [0," << _field_pm_pt_pd.size() << ") !";
1392 throw INTERP_KERNEL::Exception(oss2.str().c_str());
1393 return static_cast<MEDFileFieldPerMeshPerTypePerDisc*>(0);
1396 const MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerType::getLeafGivenLocId(int locId) const
1398 if(_field_pm_pt_pd.empty())
1400 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1401 std::ostringstream oss; oss << "MEDFileFieldPerMeshPerType::getLeafGivenLocId : no localizations for geotype \"" << cm.getRepr() << "\" !";
1402 throw INTERP_KERNEL::Exception(oss.str().c_str());
1404 if(locId>=0 && locId<(int)_field_pm_pt_pd.size())
1405 return _field_pm_pt_pd[locId];
1406 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1407 std::ostringstream oss2; oss2 << "MEDFileFieldPerMeshPerType::getLeafGivenLocId : no such locId available (" << locId;
1408 oss2 << ") for geometric type \"" << cm.getRepr() << "\" It should be in [0," << _field_pm_pt_pd.size() << ") !";
1409 throw INTERP_KERNEL::Exception(oss2.str().c_str());
1410 return static_cast<const MEDFileFieldPerMeshPerTypePerDisc*>(0);
1413 void MEDFileFieldPerMeshPerType::getFieldAtLevel(int meshDim, TypeOfField type, const MEDFileFieldGlobsReal *glob, std::vector< std::pair<int,int> >& dads, std::vector<const DataArrayInt *>& pfls, std::vector<int>& locs, std::vector<INTERP_KERNEL::NormalizedCellType>& geoTypes) const
1415 if(_geo_type!=INTERP_KERNEL::NORM_ERROR)
1417 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1418 if(meshDim!=(int)cm.getDimension())
1421 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1422 (*it)->getFieldAtLevel(type,glob,dads,pfls,locs,geoTypes);
1425 void MEDFileFieldPerMeshPerType::fillValues(int& startEntryId, std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
1428 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++,i++)
1430 (*it)->fillValues(i,startEntryId,entries);
1434 void MEDFileFieldPerMeshPerType::setLeaves(const std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerTypePerDisc > >& leaves)
1436 _field_pm_pt_pd=leaves;
1437 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1438 (*it)->setFather(this);
1442 * \param [in,out] globalNum a global numbering counter for the renumbering.
1443 * \param [out] its - list of pair (start,stop) kept
1444 * \return bool - false if the type of field \a tof is not contained in \a this.
1446 bool MEDFileFieldPerMeshPerType::keepOnlySpatialDiscretization(TypeOfField tof, int &globalNum, std::vector< std::pair<int,int> >& its)
1449 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> > newPmPtPd;
1450 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1451 if((*it)->getType()==tof)
1453 newPmPtPd.push_back(*it);
1454 std::pair<int,int> bgEnd; bgEnd.first=(*it)->getStart(); bgEnd.second=(*it)->getEnd();
1455 (*it)->setNewStart(globalNum);
1456 globalNum=(*it)->getEnd();
1457 its.push_back(bgEnd);
1461 _field_pm_pt_pd=newPmPtPd;
1465 MEDFileFieldPerMeshPerType::MEDFileFieldPerMeshPerType(MEDFileFieldPerMesh *fath, INTERP_KERNEL::NormalizedCellType geoType):_father(fath),_geo_type(geoType)
1469 MEDFileFieldPerMeshPerType::MEDFileFieldPerMeshPerType(med_idt fid, MEDFileFieldPerMesh *fath, TypeOfField type, INTERP_KERNEL::NormalizedCellType geoType, const MEDFileFieldNameScope& nasc):_father(fath),_geo_type(geoType)
1471 INTERP_KERNEL::AutoPtr<char> pflName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
1472 INTERP_KERNEL::AutoPtr<char> locName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
1473 med_geometry_type mgeoti;
1474 med_entity_type menti;
1475 menti=ConvertIntoMEDFileType(type,geoType,mgeoti);
1476 int nbProfiles=MEDfieldnProfile(fid,nasc.getName().c_str(),getIteration(),getOrder(),menti,mgeoti,pflName,locName);
1477 _field_pm_pt_pd.resize(nbProfiles);
1478 for(int i=0;i<nbProfiles;i++)
1480 _field_pm_pt_pd[i]=MEDFileFieldPerMeshPerTypePerDisc::NewOnRead(this,type,i+1);
1484 int nbProfiles2=MEDfieldnProfile(fid,nasc.getName().c_str(),getIteration(),getOrder(),MED_NODE_ELEMENT,mgeoti,pflName,locName);
1485 for(int i=0;i<nbProfiles2;i++)
1486 _field_pm_pt_pd.push_back(MEDFileFieldPerMeshPerTypePerDisc::NewOnRead(this,ON_GAUSS_NE,i+1));
1490 void MEDFileFieldPerMeshPerType::loadOnlyStructureOfDataRecursively(med_idt fid, int &start, const MEDFileFieldNameScope& nasc)
1492 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1493 (*it)->loadOnlyStructureOfDataRecursively(fid,start,nasc);
1496 void MEDFileFieldPerMeshPerType::loadBigArraysRecursively(med_idt fid, const MEDFileFieldNameScope& nasc)
1498 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1499 (*it)->loadBigArray(fid,nasc);
1502 void MEDFileFieldPerMeshPerType::writeLL(med_idt fid, const MEDFileFieldNameScope& nasc) const
1504 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1506 (*it)->copyOptionsFrom(*this);
1507 (*it)->writeLL(fid,nasc);
1511 med_entity_type MEDFileFieldPerMeshPerType::ConvertIntoMEDFileType(TypeOfField ikType, INTERP_KERNEL::NormalizedCellType ikGeoType, med_geometry_type& medfGeoType)
1516 medfGeoType=typmai3[(int)ikGeoType];
1519 medfGeoType=MED_NONE;
1522 medfGeoType=typmai3[(int)ikGeoType];
1523 return MED_NODE_ELEMENT;
1525 medfGeoType=typmai3[(int)ikGeoType];
1528 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerType::ConvertIntoMEDFileType : unexpected entity type ! internal error");
1530 return MED_UNDEF_ENTITY_TYPE;
1533 MEDFileFieldPerMesh *MEDFileFieldPerMesh::NewOnRead(med_idt fid, MEDFileAnyTypeField1TSWithoutSDA *fath, int meshCsit, int meshIteration, int meshOrder, const MEDFileFieldNameScope& nasc)
1535 return new MEDFileFieldPerMesh(fid,fath,meshCsit,meshIteration,meshOrder,nasc);
1538 MEDFileFieldPerMesh *MEDFileFieldPerMesh::New(MEDFileAnyTypeField1TSWithoutSDA *fath, const MEDCouplingMesh *mesh)
1540 return new MEDFileFieldPerMesh(fath,mesh);
1543 std::size_t MEDFileFieldPerMesh::getHeapMemorySizeWithoutChildren() const
1545 return _mesh_name.capacity()+_field_pm_pt.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType >);
1548 std::vector<const BigMemoryObject *> MEDFileFieldPerMesh::getDirectChildren() const
1550 std::vector<const BigMemoryObject *> ret;
1551 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1553 const MEDFileFieldPerMeshPerType *cur(*it);
1560 MEDFileFieldPerMesh *MEDFileFieldPerMesh::deepCpy(MEDFileAnyTypeField1TSWithoutSDA *father) const
1562 MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > ret=new MEDFileFieldPerMesh(*this);
1563 ret->_father=father;
1565 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++,i++)
1567 if((const MEDFileFieldPerMeshPerType *)*it)
1568 ret->_field_pm_pt[i]=(*it)->deepCpy((MEDFileFieldPerMesh *)(ret));
1573 void MEDFileFieldPerMesh::simpleRepr(int bkOffset, std::ostream& oss, int id) const
1575 std::string startLine(bkOffset,' ');
1576 oss << startLine << "## Field part (" << id << ") lying on mesh \"" << _mesh_name << "\", Mesh iteration=" << _mesh_iteration << ". Mesh order=" << _mesh_order << "." << std::endl;
1577 oss << startLine << "## Field is defined on " << _field_pm_pt.size() << " types." << std::endl;
1579 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++,i++)
1581 const MEDFileFieldPerMeshPerType *cur=*it;
1583 cur->simpleRepr(bkOffset,oss,i);
1586 oss << startLine << " ## Entry geometry type #" << i << " is empty !" << std::endl;
1591 void MEDFileFieldPerMesh::copyTinyInfoFrom(const MEDCouplingMesh *mesh)
1593 _mesh_name=mesh->getName();
1594 mesh->getTime(_mesh_iteration,_mesh_order);
1597 void MEDFileFieldPerMesh::assignFieldNoProfileNoRenum(int& start, const std::vector<int>& code, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
1599 int nbOfTypes=code.size()/3;
1601 for(int i=0;i<nbOfTypes;i++)
1603 INTERP_KERNEL::NormalizedCellType type=(INTERP_KERNEL::NormalizedCellType)code[3*i];
1604 int nbOfCells=code[3*i+1];
1605 int pos=addNewEntryIfNecessary(type);
1606 _field_pm_pt[pos]->assignFieldNoProfile(start,offset,nbOfCells,field,arr,glob,nasc);
1612 * This method is the most general one. No optimization is done here.
1613 * \param [in] multiTypePfl is the end user profile specified in high level API
1614 * \param [in] code is the code of \a mesh[multiTypePfl] mesh. It is of size of number of different geometric types into \a mesh[multiTypePfl].
1615 * \param [in] code2 is the code of the \b WHOLE mesh on the same level. So all types in \a code are in \a code2.
1616 * \param [in] idsInPflPerType is the selection into the \a multiTypePfl whole profile that corresponds to the given geometric type. This vector is always 3 times smaller than \a code.
1617 * \param [in] idsPerType is a vector containing the profiles needed to be created for MED file format. \b WARNING these processed MED file profiles can be subdivided again in case of Gauss points.
1618 * \param [in] mesh is the mesh coming from the MEDFileMesh instance in correspondance with the MEDFileField. The mesh inside the \a field is simply ignored.
1620 void MEDFileFieldPerMesh::assignFieldProfile(int& start, const DataArrayInt *multiTypePfl, const std::vector<int>& code, const std::vector<int>& code2, const std::vector<DataArrayInt *>& idsInPflPerType, const std::vector<DataArrayInt *>& idsPerType, const MEDCouplingFieldDouble *field, const DataArray *arr, const MEDCouplingMesh *mesh, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
1622 int nbOfTypes=code.size()/3;
1623 for(int i=0;i<nbOfTypes;i++)
1625 INTERP_KERNEL::NormalizedCellType type=(INTERP_KERNEL::NormalizedCellType)code[3*i];
1626 int pos=addNewEntryIfNecessary(type);
1627 DataArrayInt *pfl=0;
1629 pfl=idsPerType[code[3*i+2]];
1630 int nbOfTupes2=code2.size()/3;
1632 for(;found<nbOfTupes2;found++)
1633 if(code[3*i]==code2[3*found])
1635 if(found==nbOfTupes2)
1636 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::assignFieldProfile : internal problem ! Should never happen ! Please report bug to anthony.geay@cea.fr !");
1637 _field_pm_pt[pos]->assignFieldProfile(start,multiTypePfl,idsInPflPerType[i],pfl,code2[3*found+1],field,arr,mesh,glob,nasc);
1641 void MEDFileFieldPerMesh::assignNodeFieldNoProfile(int& start, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob)
1643 int pos=addNewEntryIfNecessary(INTERP_KERNEL::NORM_ERROR);
1644 _field_pm_pt[pos]->assignNodeFieldNoProfile(start,field,arr,glob);
1647 void MEDFileFieldPerMesh::assignNodeFieldProfile(int& start, const DataArrayInt *pfl, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
1649 int pos=addNewEntryIfNecessary(INTERP_KERNEL::NORM_ERROR);
1650 _field_pm_pt[pos]->assignNodeFieldProfile(start,pfl,field,arr,glob,nasc);
1653 void MEDFileFieldPerMesh::loadOnlyStructureOfDataRecursively(med_idt fid, int& start, const MEDFileFieldNameScope& nasc)
1655 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1656 (*it)->loadOnlyStructureOfDataRecursively(fid,start,nasc);
1659 void MEDFileFieldPerMesh::loadBigArraysRecursively(med_idt fid, const MEDFileFieldNameScope& nasc)
1661 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1662 (*it)->loadBigArraysRecursively(fid,nasc);
1665 void MEDFileFieldPerMesh::writeLL(med_idt fid, const MEDFileFieldNameScope& nasc) const
1667 int nbOfTypes=_field_pm_pt.size();
1668 for(int i=0;i<nbOfTypes;i++)
1670 _field_pm_pt[i]->copyOptionsFrom(*this);
1671 _field_pm_pt[i]->writeLL(fid,nasc);
1675 void MEDFileFieldPerMesh::getDimension(int& dim) const
1677 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1678 (*it)->getDimension(dim);
1681 void MEDFileFieldPerMesh::fillTypesOfFieldAvailable(std::set<TypeOfField>& types) const
1683 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1684 (*it)->fillTypesOfFieldAvailable(types);
1687 std::vector< std::vector< std::pair<int,int> > > MEDFileFieldPerMesh::getFieldSplitedByType(std::vector<INTERP_KERNEL::NormalizedCellType>& types, std::vector< std::vector<TypeOfField> >& typesF, std::vector< std::vector<std::string> >& pfls, std::vector< std::vector<std::string> > & locs) const
1689 int sz=_field_pm_pt.size();
1690 std::vector< std::vector<std::pair<int,int> > > ret(sz);
1691 types.resize(sz); typesF.resize(sz); pfls.resize(sz); locs.resize(sz);
1692 for(int i=0;i<sz;i++)
1694 types[i]=_field_pm_pt[i]->getGeoType();
1695 _field_pm_pt[i]->fillFieldSplitedByType(ret[i],typesF[i],pfls[i],locs[i]);
1700 double MEDFileFieldPerMesh::getTime() const
1703 return _father->getTime(tmp1,tmp2);
1706 int MEDFileFieldPerMesh::getIteration() const
1708 return _father->getIteration();
1711 int MEDFileFieldPerMesh::getOrder() const
1713 return _father->getOrder();
1716 int MEDFileFieldPerMesh::getNumberOfComponents() const
1718 return _father->getNumberOfComponents();
1721 DataArray *MEDFileFieldPerMesh::getOrCreateAndGetArray()
1724 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getOrCreateAndGetArray : no father ! internal error !");
1725 return _father->getOrCreateAndGetArray();
1728 const DataArray *MEDFileFieldPerMesh::getOrCreateAndGetArray() const
1731 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getOrCreateAndGetArray : no father ! internal error !");
1732 return _father->getOrCreateAndGetArray();
1735 const std::vector<std::string>& MEDFileFieldPerMesh::getInfo() const
1737 return _father->getInfo();
1741 * type,geoTypes,dads,pfls,locs are input parameters. They should have the same size.
1742 * Before the call of this method 'geoTypes','dads','pfls','locs' must be reorganized so that types in geoTypes are contiguous and ordered following typmai2 array.
1743 * It returns 2 output vectors :
1744 * - 'code' of size 3*sz where sz is the number of different values into 'geoTypes'
1745 * - 'notNullPfls' contains sz2 values that are extracted from 'pfls' in which null profiles have been removed.
1746 * 'code' and 'notNullPfls' are in MEDCouplingUMesh::checkTypeConsistencyAndContig format.
1748 void MEDFileFieldPerMesh::SortArraysPerType(const MEDFileFieldGlobsReal *glob, TypeOfField type, const std::vector<INTERP_KERNEL::NormalizedCellType>& geoTypes, const std::vector< std::pair<int,int> >& dads, const std::vector<const DataArrayInt *>& pfls, const std::vector<int>& locs, std::vector<int>& code, std::vector<DataArrayInt *>& notNullPfls)
1750 int notNullPflsSz=0;
1751 int nbOfArrs=geoTypes.size();
1752 for(int i=0;i<nbOfArrs;i++)
1755 std::set<INTERP_KERNEL::NormalizedCellType> geoTypes3(geoTypes.begin(),geoTypes.end());
1756 int nbOfDiffGeoTypes=geoTypes3.size();
1757 code.resize(3*nbOfDiffGeoTypes);
1758 notNullPfls.resize(notNullPflsSz);
1761 for(int i=0;i<nbOfDiffGeoTypes;i++)
1764 INTERP_KERNEL::NormalizedCellType refType=geoTypes[j];
1765 std::vector<const DataArrayInt *> notNullTmp;
1767 notNullTmp.push_back(pfls[j]);
1769 for(;j<nbOfArrs;j++)
1770 if(geoTypes[j]==refType)
1773 notNullTmp.push_back(pfls[j]);
1777 std::vector< std::pair<int,int> > tmpDads(dads.begin()+startZone,dads.begin()+j);
1778 std::vector<const DataArrayInt *> tmpPfls(pfls.begin()+startZone,pfls.begin()+j);
1779 std::vector<int> tmpLocs(locs.begin()+startZone,locs.begin()+j);
1780 code[3*i]=(int)refType;
1781 std::vector<INTERP_KERNEL::NormalizedCellType> refType2(1,refType);
1782 code[3*i+1]=ComputeNbOfElems(glob,type,refType2,tmpDads,tmpLocs);
1783 if(notNullTmp.empty())
1787 notNullPfls[notNullPflsSz]=DataArrayInt::Aggregate(notNullTmp);
1788 code[3*i+2]=notNullPflsSz++;
1794 * 'dads' 'geoTypes' and 'locs' are input parameters that should have same size sz. sz should be >=1.
1796 int MEDFileFieldPerMesh::ComputeNbOfElems(const MEDFileFieldGlobsReal *glob, TypeOfField type, const std::vector<INTERP_KERNEL::NormalizedCellType>& geoTypes, const std::vector< std::pair<int,int> >& dads, const std::vector<int>& locs)
1800 for(int i=0;i<sz;i++)
1804 if(type!=ON_GAUSS_NE)
1805 ret+=dads[i].second-dads[i].first;
1808 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(geoTypes[i]);
1809 ret+=(dads[i].second-dads[i].first)/cm.getNumberOfNodes();
1814 int nbOfGaussPtPerCell=glob->getNbOfGaussPtPerCell(locs[i]);
1815 ret+=(dads[i].second-dads[i].first)/nbOfGaussPtPerCell;
1821 std::vector<std::string> MEDFileFieldPerMesh::getPflsReallyUsed() const
1823 std::vector<std::string> ret;
1824 std::set<std::string> ret2;
1825 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1827 std::vector<std::string> tmp=(*it)->getPflsReallyUsed();
1828 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
1829 if(ret2.find(*it2)==ret2.end())
1831 ret.push_back(*it2);
1838 std::vector<std::string> MEDFileFieldPerMesh::getPflsReallyUsedMulti() const
1840 std::vector<std::string> ret;
1841 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1843 std::vector<std::string> tmp=(*it)->getPflsReallyUsedMulti();
1844 ret.insert(ret.end(),tmp.begin(),tmp.end());
1849 std::vector<std::string> MEDFileFieldPerMesh::getLocsReallyUsed() const
1851 std::vector<std::string> ret;
1852 std::set<std::string> ret2;
1853 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1855 std::vector<std::string> tmp=(*it)->getLocsReallyUsed();
1856 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
1857 if(ret2.find(*it2)==ret2.end())
1859 ret.push_back(*it2);
1866 std::vector<std::string> MEDFileFieldPerMesh::getLocsReallyUsedMulti() const
1868 std::vector<std::string> ret;
1869 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1871 std::vector<std::string> tmp=(*it)->getLocsReallyUsedMulti();
1872 ret.insert(ret.end(),tmp.begin(),tmp.end());
1877 bool MEDFileFieldPerMesh::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
1879 for(std::vector< std::pair<std::string,std::string> >::const_iterator it=modifTab.begin();it!=modifTab.end();it++)
1881 if((*it).first==_mesh_name)
1883 _mesh_name=(*it).second;
1890 bool MEDFileFieldPerMesh::renumberEntitiesLyingOnMesh(const std::string& meshName, const std::vector<int>& oldCode, const std::vector<int>& newCode, const DataArrayInt *renumO2N,
1891 MEDFileFieldGlobsReal& glob)
1893 if(_mesh_name!=meshName)
1895 std::set<INTERP_KERNEL::NormalizedCellType> typesToKeep;
1896 for(std::size_t i=0;i<oldCode.size()/3;i++) typesToKeep.insert((INTERP_KERNEL::NormalizedCellType)oldCode[3*i]);
1897 std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > > entries;
1898 std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> entriesKept;
1899 std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> otherEntries;
1900 getUndergroundDataArrayExt(entries);
1901 DataArray *arr0=getOrCreateAndGetArray();//tony
1903 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::renumberEntitiesLyingOnMesh : DataArray storing values of field is null !");
1904 DataArrayDouble *arr=dynamic_cast<DataArrayDouble *>(arr0);//tony
1906 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::renumberEntitiesLyingOnMesh : DataArray storing values is double ! Not managed for the moment !");
1909 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::renumberEntitiesLyingOnMesh : DataArrayDouble storing values of field is null !");
1910 for(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >::const_iterator it=entries.begin();it!=entries.end();it++)
1912 if(typesToKeep.find((*it).first.first)!=typesToKeep.end())
1914 entriesKept.push_back(getLeafGivenTypeAndLocId((*it).first.first,(*it).first.second));
1915 sz+=(*it).second.second-(*it).second.first;
1918 otherEntries.push_back(getLeafGivenTypeAndLocId((*it).first.first,(*it).first.second));
1920 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> renumDefrag=DataArrayInt::New(); renumDefrag->alloc(arr->getNumberOfTuples(),1); renumDefrag->fillWithZero();
1921 ////////////////////
1922 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> explicitIdsOldInMesh=DataArrayInt::New(); explicitIdsOldInMesh->alloc(sz,1);//sz is a majorant of the real size. A realloc will be done after
1923 int *workI2=explicitIdsOldInMesh->getPointer();
1924 int sz1=0,sz2=0,sid=1;
1925 std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> > entriesKeptML=MEDFileFieldPerMeshPerTypePerDisc::SplitPerDiscretization(entriesKept);
1926 // std::vector<int> tupleIdOfStartOfNewChuncksV(entriesKeptML.size());
1927 for(std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> >::const_iterator itL1=entriesKeptML.begin();itL1!=entriesKeptML.end();itL1++,sid++)
1929 // tupleIdOfStartOfNewChuncksV[sid-1]=sz2;
1930 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> explicitIdsOldInArr=DataArrayInt::New(); explicitIdsOldInArr->alloc(sz,1);
1931 int *workI=explicitIdsOldInArr->getPointer();
1932 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator itL2=(*itL1).begin();itL2!=(*itL1).end();itL2++)
1934 int delta1=(*itL2)->fillTupleIds(workI); workI+=delta1; sz1+=delta1;
1935 (*itL2)->setLocId(sz2);
1936 (*itL2)->_tmp_work1=(*itL2)->getStart();
1937 int delta2=(*itL2)->fillEltIdsFromCode(sz2,oldCode,glob,workI2); workI2+=delta2; sz2+=delta2;
1939 renumDefrag->setPartOfValuesSimple3(sid,explicitIdsOldInArr->begin(),explicitIdsOldInArr->end(),0,1,1);
1941 explicitIdsOldInMesh->reAlloc(sz2);
1942 int tupleIdOfStartOfNewChuncks=arr->getNumberOfTuples()-sz2;
1943 ////////////////////
1944 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> permArrDefrag=renumDefrag->buildPermArrPerLevel(); renumDefrag=0;
1945 // perform redispatching of non concerned MEDFileFieldPerMeshPerTypePerDisc
1946 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> > otherEntriesNew;
1947 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=otherEntries.begin();it!=otherEntries.end();it++)
1949 otherEntriesNew.push_back(MEDFileFieldPerMeshPerTypePerDisc::New(*(*it)));
1950 otherEntriesNew.back()->setNewStart(permArrDefrag->getIJ((*it)->getStart(),0));
1951 otherEntriesNew.back()->setLocId((*it)->getGeoType());
1953 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> > entriesKeptNew;
1954 std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> entriesKeptNew2;
1955 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=entriesKept.begin();it!=entriesKept.end();it++)
1957 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> elt=MEDFileFieldPerMeshPerTypePerDisc::New(*(*it));
1958 int newStart=elt->getLocId();
1959 elt->setLocId((*it)->getGeoType());
1960 elt->setNewStart(newStart);
1961 elt->_tmp_work1=permArrDefrag->getIJ(elt->_tmp_work1,0);
1962 entriesKeptNew.push_back(elt);
1963 entriesKeptNew2.push_back(elt);
1965 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arr2=arr->renumber(permArrDefrag->getConstPointer());
1966 // perform redispatching of concerned MEDFileFieldPerMeshPerTypePerDisc -> values are in arr2
1967 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> explicitIdsNewInMesh=renumO2N->selectByTupleId(explicitIdsOldInMesh->begin(),explicitIdsOldInMesh->end());
1968 std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> > entriesKeptPerDisc=MEDFileFieldPerMeshPerTypePerDisc::SplitPerDiscretization(entriesKeptNew2);
1970 for(std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> >::const_iterator it4=entriesKeptPerDisc.begin();it4!=entriesKeptPerDisc.end();it4++)
1973 /*for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator itL2=(*it4).begin();itL2!=(*it4).end();itL2++)
1975 MEDFileFieldPerMeshPerTypePerDisc *curNC=const_cast<MEDFileFieldPerMeshPerTypePerDisc *>(*itL2);
1976 curNC->setNewStart(permArrDefrag->getIJ((*itL2)->getStart(),0)-tupleIdOfStartOfNewChuncks+tupleIdOfStartOfNewChuncksV[sid]);
1978 ret=MEDFileFieldPerMeshPerTypePerDisc::RenumberChunks(tupleIdOfStartOfNewChuncks,*it4,explicitIdsNewInMesh,newCode,
1979 glob,arr2,otherEntriesNew) || ret;
1983 // Assign new dispatching
1984 assignNewLeaves(otherEntriesNew);
1985 arr->cpyFrom(*arr2);
1990 * \param [in,out] globalNum a global numbering counter for the renumbering.
1991 * \param [out] its - list of pair (start,stop) kept
1993 void MEDFileFieldPerMesh::keepOnlySpatialDiscretization(TypeOfField tof, int &globalNum, std::vector< std::pair<int,int> >& its)
1995 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > > ret;
1996 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1998 std::vector< std::pair<int,int> > its2;
1999 if((*it)->keepOnlySpatialDiscretization(tof,globalNum,its2))
2002 its.insert(its.end(),its2.begin(),its2.end());
2008 void MEDFileFieldPerMesh::assignNewLeaves(const std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerTypePerDisc > >& leaves)
2010 std::map<INTERP_KERNEL::NormalizedCellType,std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerTypePerDisc> > > types;
2011 for( std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerTypePerDisc > >::const_iterator it=leaves.begin();it!=leaves.end();it++)
2012 types[(INTERP_KERNEL::NormalizedCellType)(*it)->getLocId()].push_back(*it);
2014 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > > fieldPmPt(types.size());
2015 std::map<INTERP_KERNEL::NormalizedCellType,std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerTypePerDisc> > >::const_iterator it1=types.begin();
2016 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it2=fieldPmPt.begin();
2017 for(;it1!=types.end();it1++,it2++)
2019 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerType> elt=MEDFileFieldPerMeshPerType::New(this,(INTERP_KERNEL::NormalizedCellType)((*it1).second[0]->getLocId()));
2020 elt->setLeaves((*it1).second);
2023 _field_pm_pt=fieldPmPt;
2026 void MEDFileFieldPerMesh::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
2028 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2029 (*it)->changePflsRefsNamesGen(mapOfModif);
2032 void MEDFileFieldPerMesh::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
2034 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2035 (*it)->changeLocsRefsNamesGen(mapOfModif);
2039 * \param [in] mesh is the whole mesh
2041 MEDCouplingFieldDouble *MEDFileFieldPerMesh::getFieldOnMeshAtLevel(TypeOfField type, const MEDFileFieldGlobsReal *glob, const MEDCouplingMesh *mesh, bool& isPfl, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
2043 if(_field_pm_pt.empty())
2044 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getFieldOnMeshAtLevel : no types field set !");
2046 std::vector< std::pair<int,int> > dads;
2047 std::vector<const DataArrayInt *> pfls;
2048 std::vector<DataArrayInt *> notNullPflsPerGeoType;
2049 std::vector<int> locs,code;
2050 std::vector<INTERP_KERNEL::NormalizedCellType> geoTypes;
2051 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2052 (*it)->getFieldAtLevel(mesh->getMeshDimension(),type,glob,dads,pfls,locs,geoTypes);
2054 SortArraysPerType(glob,type,geoTypes,dads,pfls,locs,code,notNullPflsPerGeoType);
2057 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getFieldOnMeshAtLevel : " << "The field \"" << nasc.getName() << "\" exists but not with such spatial discretization or such dimension specified !";
2058 throw INTERP_KERNEL::Exception(oss.str().c_str());
2061 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > notNullPflsPerGeoType2(notNullPflsPerGeoType.begin(),notNullPflsPerGeoType.end());
2062 std::vector< const DataArrayInt *> notNullPflsPerGeoType3(notNullPflsPerGeoType.begin(),notNullPflsPerGeoType.end());
2065 DataArrayInt *arr=mesh->checkTypeConsistencyAndContig(code,notNullPflsPerGeoType3);
2067 return finishField(type,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2070 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr2(arr);
2071 return finishField2(type,glob,dads,locs,geoTypes,mesh,arr,isPfl,arrOut,nasc);
2077 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getFieldOnMeshAtLevel : internal error #1 !");
2081 if(nb!=mesh->getNumberOfNodes())
2083 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getFieldOnMeshAtLevel : There is a problem there is " << nb << " nodes in field whereas there is " << mesh->getNumberOfNodes();
2084 oss << " nodes in mesh !";
2085 throw INTERP_KERNEL::Exception(oss.str().c_str());
2087 return finishField(type,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2090 return finishFieldNode2(glob,dads,locs,mesh,notNullPflsPerGeoType3[0],isPfl,arrOut,nasc);
2094 DataArray *MEDFileFieldPerMesh::getFieldOnMeshAtLevelWithPfl(TypeOfField type, const MEDCouplingMesh *mesh, DataArrayInt *&pfl, const MEDFileFieldGlobsReal *glob, const MEDFileFieldNameScope& nasc) const
2096 if(_field_pm_pt.empty())
2097 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getFieldOnMeshAtLevel : no types field set !");
2099 std::vector<std::pair<int,int> > dads;
2100 std::vector<const DataArrayInt *> pfls;
2101 std::vector<DataArrayInt *> notNullPflsPerGeoType;
2102 std::vector<int> locs,code;
2103 std::vector<INTERP_KERNEL::NormalizedCellType> geoTypes;
2104 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2105 (*it)->getFieldAtLevel(mesh->getMeshDimension(),type,glob,dads,pfls,locs,geoTypes);
2107 SortArraysPerType(glob,type,geoTypes,dads,pfls,locs,code,notNullPflsPerGeoType);
2110 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getFieldOnMeshAtLevelWithPfl : " << "The field \"" << nasc.getName() << "\" exists but not with such spatial discretization or such dimension specified !";
2111 throw INTERP_KERNEL::Exception(oss.str().c_str());
2113 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > notNullPflsPerGeoType2(notNullPflsPerGeoType.begin(),notNullPflsPerGeoType.end());
2114 std::vector< const DataArrayInt *> notNullPflsPerGeoType3(notNullPflsPerGeoType.begin(),notNullPflsPerGeoType.end());
2117 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr=mesh->checkTypeConsistencyAndContig(code,notNullPflsPerGeoType3);
2118 return finishField4(dads,arr,mesh->getNumberOfCells(),pfl);
2123 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getFieldOnMeshAtLevel : internal error #1 !");
2127 if(nb!=mesh->getNumberOfNodes())
2129 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getFieldOnMeshAtLevel : There is a problem there is " << nb << " nodes in field whereas there is " << mesh->getNumberOfNodes();
2130 oss << " nodes in mesh !";
2131 throw INTERP_KERNEL::Exception(oss.str().c_str());
2134 return finishField4(dads,code[2]==-1?0:notNullPflsPerGeoType3[0],mesh->getNumberOfNodes(),pfl);
2140 void MEDFileFieldPerMesh::getUndergroundDataArrayExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
2144 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2146 (*it)->getSizes(globalSz,nbOfEntries);
2148 entries.resize(nbOfEntries);
2150 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2152 (*it)->fillValues(nbOfEntries,entries);
2156 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMesh::getLeafGivenTypeAndLocId(INTERP_KERNEL::NormalizedCellType typ, int locId)
2158 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2160 if((*it)->getGeoType()==typ)
2161 return (*it)->getLeafGivenLocId(locId);
2163 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(typ);
2164 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getLeafGivenTypeAndLocId : no such geometric type \"" << cm.getRepr() << "\" in this !" << std::endl;
2165 oss << "Possiblities are : ";
2166 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2168 const INTERP_KERNEL::CellModel& cm2=INTERP_KERNEL::CellModel::GetCellModel((*it)->getGeoType());
2169 oss << "\"" << cm2.getRepr() << "\", ";
2171 throw INTERP_KERNEL::Exception(oss.str().c_str());
2174 const MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMesh::getLeafGivenTypeAndLocId(INTERP_KERNEL::NormalizedCellType typ, int locId) const
2176 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2178 if((*it)->getGeoType()==typ)
2179 return (*it)->getLeafGivenLocId(locId);
2181 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(typ);
2182 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getLeafGivenTypeAndLocId : no such geometric type \"" << cm.getRepr() << "\" in this !" << std::endl;
2183 oss << "Possiblities are : ";
2184 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2186 const INTERP_KERNEL::CellModel& cm2=INTERP_KERNEL::CellModel::GetCellModel((*it)->getGeoType());
2187 oss << "\"" << cm2.getRepr() << "\", ";
2189 throw INTERP_KERNEL::Exception(oss.str().c_str());
2192 int MEDFileFieldPerMesh::addNewEntryIfNecessary(INTERP_KERNEL::NormalizedCellType type)
2195 int pos=std::distance(typmai2,std::find(typmai2,typmai2+MED_N_CELL_FIXED_GEO,type));
2196 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it2=_field_pm_pt.begin();
2197 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++,i++)
2199 INTERP_KERNEL::NormalizedCellType curType=(*it)->getGeoType();
2204 int pos2=std::distance(typmai2,std::find(typmai2,typmai2+MED_N_CELL_FIXED_GEO,curType));
2209 int ret=std::distance(_field_pm_pt.begin(),it2);
2210 _field_pm_pt.insert(it2,MEDFileFieldPerMeshPerType::New(this,type));
2215 * 'dads' and 'locs' input parameters have the same number of elements
2216 * \param [in] mesh is \b NOT the global mesh, but the possibly reduced mesh. \a mesh parameter will be directly aggregated in the returned field
2218 MEDCouplingFieldDouble *MEDFileFieldPerMesh::finishField(TypeOfField type, const MEDFileFieldGlobsReal *glob,
2219 const std::vector< std::pair<int,int> >& dads, const std::vector<int>& locs,
2220 const MEDCouplingMesh *mesh, bool& isPfl, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const throw(INTERP_KERNEL::Exception)
2223 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=MEDCouplingFieldDouble::New(type,ONE_TIME);
2224 ret->setMesh(mesh); ret->setName(nasc.getName().c_str()); ret->setTime(getTime(),getIteration(),getOrder()); ret->setTimeUnit(nasc.getDtUnit().c_str());
2225 MEDCouplingAutoRefCountObjectPtr<DataArray> da=getOrCreateAndGetArray()->selectByTupleRanges(dads);
2226 const std::vector<std::string>& infos=getInfo();
2227 da->setInfoOnComponents(infos);
2229 if(type==ON_GAUSS_PT)
2232 int nbOfArrs=dads.size();
2233 for(int i=0;i<nbOfArrs;i++)
2235 std::vector<std::pair<int,int> > dads2(1,dads[i]); const std::vector<int> locs2(1,locs[i]);
2236 const std::vector<INTERP_KERNEL::NormalizedCellType> geoTypes2(1,INTERP_KERNEL::NORM_ERROR);
2237 int nbOfElems=ComputeNbOfElems(glob,type,geoTypes2,dads2,locs2);
2238 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> di=DataArrayInt::New();
2239 di->alloc(nbOfElems,1);
2241 const MEDFileFieldLoc& fl=glob->getLocalizationFromId(locs[i]);
2242 ret->setGaussLocalizationOnCells(di->getConstPointer(),di->getConstPointer()+nbOfElems,fl.getRefCoords(),fl.getGaussCoords(),fl.getGaussWeights());
2251 * This method is an extension of MEDFileFieldPerMesh::finishField method. It deals with profiles. This method should be called when type is different from ON_NODES.
2252 * 'dads', 'locs' and 'geoTypes' input parameters have the same number of elements.
2253 * No check of this is performed. 'da' array contains an array in old2New style to be applyied to mesh to obtain the right support.
2254 * The order of cells in the returned field is those imposed by the profile.
2255 * \param [in] mesh is the global mesh.
2257 MEDCouplingFieldDouble *MEDFileFieldPerMesh::finishField2(TypeOfField type, const MEDFileFieldGlobsReal *glob,
2258 const std::vector<std::pair<int,int> >& dads, const std::vector<int>& locs,
2259 const std::vector<INTERP_KERNEL::NormalizedCellType>& geoTypes,
2260 const MEDCouplingMesh *mesh, const DataArrayInt *da, bool& isPfl, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const throw(INTERP_KERNEL::Exception)
2262 if(da->isIdentity())
2264 int nbOfTuples=da->getNumberOfTuples();
2265 if(nbOfTuples==mesh->getNumberOfCells())
2266 return finishField(type,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2268 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> m2=mesh->buildPart(da->getConstPointer(),da->getConstPointer()+da->getNbOfElems());
2269 m2->setName(mesh->getName().c_str());
2270 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=finishField(type,glob,dads,locs,m2,isPfl,arrOut,nasc);
2276 * This method is the complement of MEDFileFieldPerMesh::finishField2 method except that this method works for node profiles.
2278 MEDCouplingFieldDouble *MEDFileFieldPerMesh::finishFieldNode2(const MEDFileFieldGlobsReal *glob,
2279 const std::vector<std::pair<int,int> >& dads, const std::vector<int>& locs,
2280 const MEDCouplingMesh *mesh, const DataArrayInt *da, bool& isPfl, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const throw(INTERP_KERNEL::Exception)
2282 if(da->isIdentity())
2284 int nbOfTuples=da->getNumberOfTuples();
2285 if(nbOfTuples==mesh->getNumberOfNodes())//No problem for NORM_ERROR because it is in context of node
2286 return finishField(ON_NODES,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2288 // Treatment of particular case where nodal field on pfl is requested with a meshDimRelToMax=1.
2289 const MEDCouplingUMesh *meshu=dynamic_cast<const MEDCouplingUMesh *>(mesh);
2292 if(meshu->getNodalConnectivity()==0)
2294 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=finishField(ON_CELLS,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2295 int nb=da->getNbOfElems();
2296 const int *ptr=da->getConstPointer();
2297 MEDCouplingUMesh *meshuc=const_cast<MEDCouplingUMesh *>(meshu);
2298 meshuc->allocateCells(nb);
2299 for(int i=0;i<nb;i++)
2300 meshuc->insertNextCell(INTERP_KERNEL::NORM_POINT1,1,ptr+i);
2301 meshuc->finishInsertingCells();
2302 ret->setMesh(meshuc);
2303 const MEDCouplingFieldDiscretization *disc=ret->getDiscretization();
2304 if(!disc) throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::finishFieldNode2 : internal error, no discretization on field !");
2305 disc->checkCoherencyBetween(meshuc,arrOut);
2310 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=finishField(ON_NODES,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2312 DataArrayInt *arr2=0;
2313 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> cellIds=mesh->getCellIdsFullyIncludedInNodeIds(da->getConstPointer(),da->getConstPointer()+da->getNbOfElems());
2314 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> mesh2=mesh->buildPartAndReduceNodes(cellIds->getConstPointer(),cellIds->getConstPointer()+cellIds->getNbOfElems(),arr2);
2315 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr3(arr2);
2316 int nnodes=mesh2->getNumberOfNodes();
2317 if(nnodes==(int)da->getNbOfElems())
2319 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da3=da->transformWithIndArrR(arr2->begin(),arr2->end());
2320 arrOut->renumberInPlace(da3->getConstPointer());
2321 mesh2->setName(mesh->getName().c_str());
2322 ret->setMesh(mesh2);
2327 std::ostringstream oss; oss << "MEDFileFieldPerMesh::finishFieldNode2 : The field on nodes lies on a node profile so that it is impossible to find a submesh having exactly the same nodes of that profile !!!";
2328 oss << "So it is impossible to return a well definied MEDCouplingFieldDouble instance on specified mesh on a specified meshDim !" << std::endl;
2329 oss << "To retrieve correctly such a field you have 3 possibilities :" << std::endl;
2330 oss << " - use an another meshDim compatible with the field on nodes (MED file does not have such information)" << std::endl;
2331 oss << " - use an another a meshDimRelToMax equal to 1 -> it will return a mesh with artificial cell POINT1 containing the profile !" << std::endl;
2332 oss << " - if definitely the node profile has no link with mesh connectivity use MEDFileField1TS::getFieldWithProfile or MEDFileFieldMultiTS::getFieldWithProfile methods instead !";
2333 throw INTERP_KERNEL::Exception(oss.str().c_str());
2339 * This method is the most light method of field retrieving.
2341 DataArray *MEDFileFieldPerMesh::finishField4(const std::vector<std::pair<int,int> >& dads, const DataArrayInt *pflIn, int nbOfElems, DataArrayInt *&pflOut) const
2345 pflOut=DataArrayInt::New();
2346 pflOut->alloc(nbOfElems,1);
2351 pflOut=const_cast<DataArrayInt*>(pflIn);
2354 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> safePfl(pflOut);
2355 MEDCouplingAutoRefCountObjectPtr<DataArray> da=getOrCreateAndGetArray()->selectByTupleRanges(dads);
2356 const std::vector<std::string>& infos=getInfo();
2357 int nbOfComp=infos.size();
2358 for(int i=0;i<nbOfComp;i++)
2359 da->setInfoOnComponent(i,infos[i].c_str());
2364 MEDFileFieldPerMesh::MEDFileFieldPerMesh(med_idt fid, MEDFileAnyTypeField1TSWithoutSDA *fath, int meshCsit, int meshIteration, int meshOrder, const MEDFileFieldNameScope& nasc):_mesh_iteration(meshIteration),_mesh_order(meshOrder),
2365 _mesh_csit(meshCsit),_father(fath)
2367 INTERP_KERNEL::AutoPtr<char> meshName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
2368 INTERP_KERNEL::AutoPtr<char> pflName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
2369 INTERP_KERNEL::AutoPtr<char> locName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
2370 for(int i=0;i<MED_N_CELL_FIXED_GEO;i++)
2372 int nbProfile =MEDfield23nProfile(fid,nasc.getName().c_str(),getIteration(),getOrder(),MED_CELL ,typmai[i],_mesh_csit,meshName,pflName,locName);
2373 std::string name0(MEDLoaderBase::buildStringFromFortran(meshName,MED_NAME_SIZE+1));
2374 int nbProfile2=MEDfield23nProfile(fid,nasc.getName().c_str(),getIteration(),getOrder(),MED_NODE_ELEMENT,typmai[i],_mesh_csit,meshName,pflName,locName);
2375 std::string name1(MEDLoaderBase::buildStringFromFortran(meshName,MED_NAME_SIZE+1));
2376 if(nbProfile>0 || nbProfile2>0)
2378 _field_pm_pt.push_back(MEDFileFieldPerMeshPerType::NewOnRead(fid,this,ON_CELLS,typmai2[i],nasc));
2385 int nbProfile=MEDfield23nProfile(fid,nasc.getName().c_str(),getIteration(),getOrder(),MED_NODE,MED_NONE,_mesh_csit,meshName,pflName,locName);
2388 _field_pm_pt.push_back(MEDFileFieldPerMeshPerType::NewOnRead(fid,this,ON_NODES,INTERP_KERNEL::NORM_ERROR,nasc));
2389 _mesh_name=MEDLoaderBase::buildStringFromFortran(meshName,MED_NAME_SIZE+1);
2393 MEDFileFieldPerMesh::MEDFileFieldPerMesh(MEDFileAnyTypeField1TSWithoutSDA *fath, const MEDCouplingMesh *mesh):_father(fath)
2395 copyTinyInfoFrom(mesh);
2398 void MEDFileFieldGlobs::loadProfileInFile(med_idt fid, int id, const std::string& pflName)
2400 if(id>=(int)_pfls.size())
2402 _pfls[id]=DataArrayInt::New();
2403 int lgth=MEDprofileSizeByName(fid,pflName.c_str());
2404 _pfls[id]->setName(pflName);
2405 _pfls[id]->alloc(lgth,1);
2406 MEDprofileRd(fid,pflName.c_str(),_pfls[id]->getPointer());
2407 _pfls[id]->applyLin(1,-1,0);//Converting into C format
2410 void MEDFileFieldGlobs::loadProfileInFile(med_idt fid, int i)
2412 INTERP_KERNEL::AutoPtr<char> pflName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
2414 MEDprofileInfo(fid,i+1,pflName,&sz);
2415 std::string pflCpp=MEDLoaderBase::buildStringFromFortran(pflName,MED_NAME_SIZE);
2416 if(i>=(int)_pfls.size())
2418 _pfls[i]=DataArrayInt::New();
2419 _pfls[i]->alloc(sz,1);
2420 _pfls[i]->setName(pflCpp.c_str());
2421 MEDprofileRd(fid,pflName,_pfls[i]->getPointer());
2422 _pfls[i]->applyLin(1,-1,0);//Converting into C format
2425 void MEDFileFieldGlobs::writeGlobals(med_idt fid, const MEDFileWritable& opt) const
2427 int nbOfPfls=_pfls.size();
2428 for(int i=0;i<nbOfPfls;i++)
2430 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> cpy=_pfls[i]->deepCpy();
2431 cpy->applyLin(1,1,0);
2432 INTERP_KERNEL::AutoPtr<char> pflName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
2433 MEDLoaderBase::safeStrCpy(_pfls[i]->getName().c_str(),MED_NAME_SIZE,pflName,opt.getTooLongStrPolicy());
2434 MEDprofileWr(fid,pflName,_pfls[i]->getNumberOfTuples(),cpy->getConstPointer());
2437 int nbOfLocs=_locs.size();
2438 for(int i=0;i<nbOfLocs;i++)
2439 _locs[i]->writeLL(fid);
2442 void MEDFileFieldGlobs::appendGlobs(const MEDFileFieldGlobs& other, double eps)
2444 std::vector<std::string> pfls=getPfls();
2445 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=other._pfls.begin();it!=other._pfls.end();it++)
2447 std::vector<std::string>::iterator it2=std::find(pfls.begin(),pfls.end(),(*it)->getName());
2450 _pfls.push_back(*it);
2454 int id=std::distance(pfls.begin(),it2);
2455 if(!(*it)->isEqual(*_pfls[id]))
2457 std::ostringstream oss; oss << "MEDFileFieldGlobs::appendGlobs : Profile \"" << (*it)->getName() << "\" already exists and is different from those expecting to be append !";
2458 throw INTERP_KERNEL::Exception(oss.str().c_str());
2462 std::vector<std::string> locs=getLocs();
2463 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=other._locs.begin();it!=other._locs.end();it++)
2465 std::vector<std::string>::iterator it2=std::find(locs.begin(),locs.end(),(*it)->getName());
2468 _locs.push_back(*it);
2472 int id=std::distance(locs.begin(),it2);
2473 if(!(*it)->isEqual(*_locs[id],eps))
2475 std::ostringstream oss; oss << "MEDFileFieldGlobs::appendGlobs : Localization \"" << (*it)->getName() << "\" already exists and is different from those expecting to be append !";
2476 throw INTERP_KERNEL::Exception(oss.str().c_str());
2482 void MEDFileFieldGlobs::checkGlobsPflsPartCoherency(const std::vector<std::string>& pflsUsed) const
2484 for(std::vector<std::string>::const_iterator it=pflsUsed.begin();it!=pflsUsed.end();it++)
2485 getProfile((*it).c_str());
2488 void MEDFileFieldGlobs::checkGlobsLocsPartCoherency(const std::vector<std::string>& locsUsed) const
2490 for(std::vector<std::string>::const_iterator it=locsUsed.begin();it!=locsUsed.end();it++)
2491 getLocalization((*it).c_str());
2494 void MEDFileFieldGlobs::loadGlobals(med_idt fid, const MEDFileFieldGlobsReal& real)
2496 std::vector<std::string> profiles=real.getPflsReallyUsed();
2497 int sz=profiles.size();
2499 for(int i=0;i<sz;i++)
2500 loadProfileInFile(fid,i,profiles[i].c_str());
2502 std::vector<std::string> locs=real.getLocsReallyUsed();
2505 for(int i=0;i<sz;i++)
2506 _locs[i]=MEDFileFieldLoc::New(fid,locs[i].c_str());
2509 void MEDFileFieldGlobs::loadAllGlobals(med_idt fid)
2511 int nProfil=MEDnProfile(fid);
2512 for(int i=0;i<nProfil;i++)
2513 loadProfileInFile(fid,i);
2514 int sz=MEDnLocalization(fid);
2516 for(int i=0;i<sz;i++)
2518 _locs[i]=MEDFileFieldLoc::New(fid,i);
2522 MEDFileFieldGlobs *MEDFileFieldGlobs::New(const std::string& fname)
2524 return new MEDFileFieldGlobs(fname);
2527 MEDFileFieldGlobs *MEDFileFieldGlobs::New()
2529 return new MEDFileFieldGlobs;
2532 std::size_t MEDFileFieldGlobs::getHeapMemorySizeWithoutChildren() const
2534 return _file_name.capacity()+_pfls.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr<DataArrayInt>)+_locs.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc>);
2537 std::vector<const BigMemoryObject *> MEDFileFieldGlobs::getDirectChildren() const
2539 std::vector<const BigMemoryObject *> ret;
2540 for(std::vector< MEDCouplingAutoRefCountObjectPtr< DataArrayInt > >::const_iterator it=_pfls.begin();it!=_pfls.end();it++)
2542 const DataArrayInt *cur(*it);
2546 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=_locs.begin();it!=_locs.end();it++)
2548 const MEDFileFieldLoc *cur(*it);
2555 MEDFileFieldGlobs *MEDFileFieldGlobs::deepCpy() const
2557 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldGlobs> ret=new MEDFileFieldGlobs(*this);
2559 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=_pfls.begin();it!=_pfls.end();it++,i++)
2561 if((const DataArrayInt *)*it)
2562 ret->_pfls[i]=(*it)->deepCpy();
2565 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=_locs.begin();it!=_locs.end();it++,i++)
2567 if((const MEDFileFieldLoc*)*it)
2568 ret->_locs[i]=(*it)->deepCpy();
2574 * \throw if a profile in \a pfls in not in \a this.
2575 * \throw if a localization in \a locs in not in \a this.
2576 * \sa MEDFileFieldGlobs::deepCpyPart
2578 MEDFileFieldGlobs *MEDFileFieldGlobs::shallowCpyPart(const std::vector<std::string>& pfls, const std::vector<std::string>& locs) const
2580 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldGlobs> ret=MEDFileFieldGlobs::New();
2581 for(std::vector<std::string>::const_iterator it1=pfls.begin();it1!=pfls.end();it1++)
2583 DataArrayInt *pfl=const_cast<DataArrayInt *>(getProfile((*it1).c_str()));
2585 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::shallowCpyPart : internal error ! pfl null !");
2587 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> pfl2(pfl);
2588 ret->_pfls.push_back(pfl2);
2590 for(std::vector<std::string>::const_iterator it2=locs.begin();it2!=locs.end();it2++)
2592 MEDFileFieldLoc *loc=const_cast<MEDFileFieldLoc *>(&getLocalization((*it2).c_str()));
2594 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::shallowCpyPart : internal error ! loc null !");
2596 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> loc2(loc);
2597 ret->_locs.push_back(loc2);
2599 ret->setFileName(getFileName());
2604 * \throw if a profile in \a pfls in not in \a this.
2605 * \throw if a localization in \a locs in not in \a this.
2606 * \sa MEDFileFieldGlobs::shallowCpyPart
2608 MEDFileFieldGlobs *MEDFileFieldGlobs::deepCpyPart(const std::vector<std::string>& pfls, const std::vector<std::string>& locs) const
2610 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldGlobs> ret=MEDFileFieldGlobs::New();
2611 for(std::vector<std::string>::const_iterator it1=pfls.begin();it1!=pfls.end();it1++)
2613 DataArrayInt *pfl=const_cast<DataArrayInt *>(getProfile((*it1).c_str()));
2615 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::deepCpyPart : internal error ! pfl null !");
2616 ret->_pfls.push_back(pfl->deepCpy());
2618 for(std::vector<std::string>::const_iterator it2=locs.begin();it2!=locs.end();it2++)
2620 MEDFileFieldLoc *loc=const_cast<MEDFileFieldLoc *>(&getLocalization((*it2).c_str()));
2622 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::deepCpyPart : internal error ! loc null !");
2623 ret->_locs.push_back(loc->deepCpy());
2625 ret->setFileName(getFileName());
2629 MEDFileFieldGlobs::MEDFileFieldGlobs(const std::string& fname):_file_name(fname)
2633 MEDFileFieldGlobs::MEDFileFieldGlobs()
2637 MEDFileFieldGlobs::~MEDFileFieldGlobs()
2641 void MEDFileFieldGlobs::simpleRepr(std::ostream& oss) const
2643 oss << "Profiles :\n";
2644 std::size_t n=_pfls.size();
2645 for(std::size_t i=0;i<n;i++)
2647 oss << " - #" << i << " ";
2648 const DataArrayInt *pfl=_pfls[i];
2650 oss << "\"" << pfl->getName() << "\"\n";
2655 oss << "Localizations :\n";
2656 for(std::size_t i=0;i<n;i++)
2658 oss << " - #" << i << " ";
2659 const MEDFileFieldLoc *loc=_locs[i];
2661 loc->simpleRepr(oss);
2667 void MEDFileFieldGlobs::setFileName(const std::string& fileName)
2669 _file_name=fileName;
2672 void MEDFileFieldGlobs::changePflsNamesInStruct(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
2674 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::iterator it=_pfls.begin();it!=_pfls.end();it++)
2676 DataArrayInt *elt(*it);
2679 std::string name(elt->getName());
2680 for(std::vector< std::pair<std::vector<std::string>, std::string > >::const_iterator it2=mapOfModif.begin();it2!=mapOfModif.end();it2++)
2682 if(std::find((*it2).first.begin(),(*it2).first.end(),name)!=(*it2).first.end())
2684 elt->setName((*it2).second.c_str());
2692 void MEDFileFieldGlobs::changeLocsNamesInStruct(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
2694 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::iterator it=_locs.begin();it!=_locs.end();it++)
2696 MEDFileFieldLoc *elt(*it);
2699 std::string name(elt->getName());
2700 for(std::vector< std::pair<std::vector<std::string>, std::string > >::const_iterator it2=mapOfModif.begin();it2!=mapOfModif.end();it2++)
2702 if(std::find((*it2).first.begin(),(*it2).first.end(),name)!=(*it2).first.end())
2704 elt->setName((*it2).second.c_str());
2712 int MEDFileFieldGlobs::getNbOfGaussPtPerCell(int locId) const
2714 if(locId<0 || locId>=(int)_locs.size())
2715 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::getNbOfGaussPtPerCell : Invalid localization id !");
2716 return _locs[locId]->getNbOfGaussPtPerCell();
2719 const MEDFileFieldLoc& MEDFileFieldGlobs::getLocalization(const std::string& locName) const
2721 return getLocalizationFromId(getLocalizationId(locName));
2724 const MEDFileFieldLoc& MEDFileFieldGlobs::getLocalizationFromId(int locId) const
2726 if(locId<0 || locId>=(int)_locs.size())
2727 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::getLocalizationFromId : Invalid localization id !");
2728 return *_locs[locId];
2731 namespace ParaMEDMEMImpl
2736 LocFinder(const std::string& loc):_loc(loc) { }
2737 bool operator() (const MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc>& loc) { return loc->isName(_loc); }
2739 const std::string &_loc;
2745 PflFinder(const std::string& pfl):_pfl(pfl) { }
2746 bool operator() (const MEDCouplingAutoRefCountObjectPtr<DataArrayInt>& pfl) { return _pfl==pfl->getName(); }
2748 const std::string& _pfl;
2752 int MEDFileFieldGlobs::getLocalizationId(const std::string& loc) const
2754 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=std::find_if(_locs.begin(),_locs.end(),ParaMEDMEMImpl::LocFinder(loc));
2757 std::ostringstream oss; oss << "MEDFileFieldGlobs::getLocalisationId : no such localisation name : \"" << loc << "\" Possible localizations are : ";
2758 for(it=_locs.begin();it!=_locs.end();it++)
2759 oss << "\"" << (*it)->getName() << "\", ";
2760 throw INTERP_KERNEL::Exception(oss.str().c_str());
2762 return std::distance(_locs.begin(),it);
2766 * The returned value is never null.
2768 const DataArrayInt *MEDFileFieldGlobs::getProfile(const std::string& pflName) const
2770 std::string pflNameCpp(pflName);
2771 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=std::find_if(_pfls.begin(),_pfls.end(),ParaMEDMEMImpl::PflFinder(pflNameCpp));
2774 std::ostringstream oss; oss << "MEDFileFieldGlobs::getProfile: no such profile name : \"" << pflNameCpp << "\" Possible profiles are : ";
2775 for(it=_pfls.begin();it!=_pfls.end();it++)
2776 oss << "\"" << (*it)->getName() << "\", ";
2777 throw INTERP_KERNEL::Exception(oss.str().c_str());
2782 const DataArrayInt *MEDFileFieldGlobs::getProfileFromId(int pflId) const
2784 if(pflId<0 || pflId>=(int)_pfls.size())
2785 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::getProfileFromId : Invalid profile id !");
2786 return _pfls[pflId];
2789 MEDFileFieldLoc& MEDFileFieldGlobs::getLocalizationFromId(int locId)
2791 if(locId<0 || locId>=(int)_locs.size())
2792 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::getLocalizationFromId : Invalid localization id !");
2793 return *_locs[locId];
2796 MEDFileFieldLoc& MEDFileFieldGlobs::getLocalization(const std::string& locName)
2798 return getLocalizationFromId(getLocalizationId(locName));
2802 * The returned value is never null.
2804 DataArrayInt *MEDFileFieldGlobs::getProfile(const std::string& pflName)
2806 std::string pflNameCpp(pflName);
2807 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::iterator it=std::find_if(_pfls.begin(),_pfls.end(),ParaMEDMEMImpl::PflFinder(pflNameCpp));
2810 std::ostringstream oss; oss << "MEDFileFieldGlobs::getProfile: no such profile name : \"" << pflNameCpp << "\" Possible profiles are : ";
2811 for(it=_pfls.begin();it!=_pfls.end();it++)
2812 oss << "\"" << (*it)->getName() << "\", ";
2813 throw INTERP_KERNEL::Exception(oss.str().c_str());
2818 DataArrayInt *MEDFileFieldGlobs::getProfileFromId(int pflId)
2820 if(pflId<0 || pflId>=(int)_pfls.size())
2821 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::getProfileFromId : Invalid profile id !");
2822 return _pfls[pflId];
2825 void MEDFileFieldGlobs::killProfileIds(const std::vector<int>& pflIds)
2827 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > newPfls;
2829 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=_pfls.begin();it!=_pfls.end();it++,i++)
2831 if(std::find(pflIds.begin(),pflIds.end(),i)==pflIds.end())
2832 newPfls.push_back(*it);
2837 void MEDFileFieldGlobs::killLocalizationIds(const std::vector<int>& locIds)
2839 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> > newLocs;
2841 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=_locs.begin();it!=_locs.end();it++,i++)
2843 if(std::find(locIds.begin(),locIds.end(),i)==locIds.end())
2844 newLocs.push_back(*it);
2849 std::vector<std::string> MEDFileFieldGlobs::getPfls() const
2851 int sz=_pfls.size();
2852 std::vector<std::string> ret(sz);
2853 for(int i=0;i<sz;i++)
2854 ret[i]=_pfls[i]->getName();
2858 std::vector<std::string> MEDFileFieldGlobs::getLocs() const
2860 int sz=_locs.size();
2861 std::vector<std::string> ret(sz);
2862 for(int i=0;i<sz;i++)
2863 ret[i]=_locs[i]->getName();
2867 bool MEDFileFieldGlobs::existsPfl(const std::string& pflName) const
2869 std::vector<std::string> v=getPfls();
2870 std::string s(pflName);
2871 return std::find(v.begin(),v.end(),s)!=v.end();
2874 bool MEDFileFieldGlobs::existsLoc(const std::string& locName) const
2876 std::vector<std::string> v=getLocs();
2877 std::string s(locName);
2878 return std::find(v.begin(),v.end(),s)!=v.end();
2881 std::vector< std::vector<int> > MEDFileFieldGlobs::whichAreEqualProfiles() const
2883 std::map<int,std::vector<int> > m;
2885 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=_pfls.begin();it!=_pfls.end();it++,i++)
2887 const DataArrayInt *tmp=(*it);
2890 m[tmp->getHashCode()].push_back(i);
2893 std::vector< std::vector<int> > ret;
2894 for(std::map<int,std::vector<int> >::const_iterator it2=m.begin();it2!=m.end();it2++)
2896 if((*it2).second.size()>1)
2898 std::vector<int> ret0;
2899 bool equalityOrNot=false;
2900 for(std::vector<int>::const_iterator it3=(*it2).second.begin();it3!=(*it2).second.end();it3++)
2902 std::vector<int>::const_iterator it4=it3; it4++;
2903 for(;it4!=(*it2).second.end();it4++)
2905 if(_pfls[*it3]->isEqualWithoutConsideringStr(*_pfls[*it4]))
2908 ret0.push_back(*it3);
2909 ret0.push_back(*it4);
2915 ret.push_back(ret0);
2921 std::vector< std::vector<int> > MEDFileFieldGlobs::whichAreEqualLocs(double eps) const
2923 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::whichAreEqualLocs : no implemented yet ! Sorry !");
2926 void MEDFileFieldGlobs::appendProfile(DataArrayInt *pfl)
2928 std::string name(pfl->getName());
2930 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::appendProfile : unsupported profiles with no name !");
2931 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=_pfls.begin();it!=_pfls.end();it++)
2932 if(name==(*it)->getName())
2934 if(!pfl->isEqual(*(*it)))
2936 std::ostringstream oss; oss << "MEDFileFieldGlobs::appendProfile : profile \"" << name << "\" already exists and is different from existing !";
2937 throw INTERP_KERNEL::Exception(oss.str().c_str());
2941 _pfls.push_back(pfl);
2944 void MEDFileFieldGlobs::appendLoc(const std::string& locName, INTERP_KERNEL::NormalizedCellType geoType, const std::vector<double>& refCoo, const std::vector<double>& gsCoo, const std::vector<double>& w)
2946 std::string name(locName);
2948 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::appendLoc : unsupported localizations with no name !");
2949 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> obj=MEDFileFieldLoc::New(locName,geoType,refCoo,gsCoo,w);
2950 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=_locs.begin();it!=_locs.end();it++)
2951 if((*it)->isName(locName))
2953 if(!(*it)->isEqual(*obj,1e-12))
2955 std::ostringstream oss; oss << "MEDFileFieldGlobs::appendLoc : localization \"" << name << "\" already exists and is different from existing !";
2956 throw INTERP_KERNEL::Exception(oss.str().c_str());
2959 _locs.push_back(obj);
2962 std::string MEDFileFieldGlobs::createNewNameOfPfl() const
2964 std::vector<std::string> names=getPfls();
2965 return CreateNewNameNotIn("NewPfl_",names);
2968 std::string MEDFileFieldGlobs::createNewNameOfLoc() const
2970 std::vector<std::string> names=getLocs();
2971 return CreateNewNameNotIn("NewLoc_",names);
2974 std::string MEDFileFieldGlobs::CreateNewNameNotIn(const std::string& prefix, const std::vector<std::string>& namesToAvoid)
2976 for(std::size_t sz=0;sz<100000;sz++)
2978 std::ostringstream tryName;
2979 tryName << prefix << sz;
2980 if(std::find(namesToAvoid.begin(),namesToAvoid.end(),tryName.str())==namesToAvoid.end())
2981 return tryName.str();
2983 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::CreateNewNameNotIn : impossible to create an additional profile limit of 100000 profiles reached !");
2987 * Creates a MEDFileFieldGlobsReal on a given file name. Nothing is read here.
2988 * \param [in] fname - the file name.
2990 MEDFileFieldGlobsReal::MEDFileFieldGlobsReal(const std::string& fname):_globals(MEDFileFieldGlobs::New(fname))
2995 * Creates an empty MEDFileFieldGlobsReal.
2997 MEDFileFieldGlobsReal::MEDFileFieldGlobsReal():_globals(MEDFileFieldGlobs::New())
3001 std::size_t MEDFileFieldGlobsReal::getHeapMemorySizeWithoutChildren() const
3006 std::vector<const BigMemoryObject *> MEDFileFieldGlobsReal::getDirectChildren() const
3008 std::vector<const BigMemoryObject *> ret;
3009 if((const MEDFileFieldGlobs *)_globals)
3010 ret.push_back((const MEDFileFieldGlobs *)_globals);
3015 * Returns a string describing profiles and Gauss points held in \a this.
3016 * \return std::string - the description string.
3018 void MEDFileFieldGlobsReal::simpleReprGlobs(std::ostream& oss) const
3020 const MEDFileFieldGlobs *glob=_globals;
3021 std::ostringstream oss2; oss2 << glob;
3022 std::string stars(oss2.str().length(),'*');
3023 oss << "Globals information on fields (at " << oss2.str() << "):" << "\n************************************" << stars << "\n\n";
3025 glob->simpleRepr(oss);
3027 oss << "NO GLOBAL INFORMATION !\n";
3030 void MEDFileFieldGlobsReal::resetContent()
3032 _globals=MEDFileFieldGlobs::New();
3035 MEDFileFieldGlobsReal::~MEDFileFieldGlobsReal()
3040 * Copies references to profiles and Gauss points from another MEDFileFieldGlobsReal.
3041 * \param [in] other - the other MEDFileFieldGlobsReal to copy data from.
3043 void MEDFileFieldGlobsReal::shallowCpyGlobs(const MEDFileFieldGlobsReal& other)
3045 _globals=other._globals;
3049 * Copies references to ** only used ** by \a this, profiles and Gauss points from another MEDFileFieldGlobsReal.
3050 * \param [in] other - the other MEDFileFieldGlobsReal to copy data from.
3052 void MEDFileFieldGlobsReal::shallowCpyOnlyUsedGlobs(const MEDFileFieldGlobsReal& other)
3054 const MEDFileFieldGlobs *otherg(other._globals);
3057 _globals=otherg->shallowCpyPart(getPflsReallyUsed(),getLocsReallyUsed());
3061 * Copies deeply to ** only used ** by \a this, profiles and Gauss points from another MEDFileFieldGlobsReal.
3062 * \param [in] other - the other MEDFileFieldGlobsReal to copy data from.
3064 void MEDFileFieldGlobsReal::deepCpyOnlyUsedGlobs(const MEDFileFieldGlobsReal& other)
3066 const MEDFileFieldGlobs *otherg(other._globals);
3069 _globals=otherg->deepCpyPart(getPflsReallyUsed(),getLocsReallyUsed());
3072 void MEDFileFieldGlobsReal::deepCpyGlobs(const MEDFileFieldGlobsReal& other)
3074 _globals=other._globals;
3075 if((const MEDFileFieldGlobs *)_globals)
3076 _globals=other._globals->deepCpy();
3080 * Adds profiles and Gauss points held by another MEDFileFieldGlobsReal to \a this one.
3081 * \param [in] other - the MEDFileFieldGlobsReal to copy data from.
3082 * \param [in] eps - a precision used to compare Gauss points with same name held by
3083 * \a this and \a other MEDFileFieldGlobsReal.
3084 * \throw If \a this and \a other hold profiles with equal names but different ids.
3085 * \throw If \a this and \a other hold different Gauss points with equal names.
3087 void MEDFileFieldGlobsReal::appendGlobs(const MEDFileFieldGlobsReal& other, double eps)
3089 const MEDFileFieldGlobs *thisGlobals(_globals),*otherGlobals(other._globals);
3090 if(thisGlobals==otherGlobals)
3094 _globals=other._globals;
3097 _globals->appendGlobs(*other._globals,eps);
3100 void MEDFileFieldGlobsReal::checkGlobsCoherency() const
3102 checkGlobsPflsPartCoherency();
3103 checkGlobsLocsPartCoherency();
3106 void MEDFileFieldGlobsReal::checkGlobsPflsPartCoherency() const
3108 contentNotNull()->checkGlobsPflsPartCoherency(getPflsReallyUsed());
3111 void MEDFileFieldGlobsReal::checkGlobsLocsPartCoherency() const
3113 contentNotNull()->checkGlobsLocsPartCoherency(getLocsReallyUsed());
3116 void MEDFileFieldGlobsReal::loadProfileInFile(med_idt fid, int id, const std::string& pflName)
3118 contentNotNull()->loadProfileInFile(fid,id,pflName);
3121 void MEDFileFieldGlobsReal::loadProfileInFile(med_idt fid, int id)
3123 contentNotNull()->loadProfileInFile(fid,id);
3126 void MEDFileFieldGlobsReal::loadGlobals(med_idt fid)
3128 contentNotNull()->loadGlobals(fid,*this);
3131 void MEDFileFieldGlobsReal::loadAllGlobals(med_idt fid)
3133 contentNotNull()->loadAllGlobals(fid);
3136 void MEDFileFieldGlobsReal::writeGlobals(med_idt fid, const MEDFileWritable& opt) const
3138 contentNotNull()->writeGlobals(fid,opt);
3142 * Returns names of all profiles. To get only used profiles call getPflsReallyUsed()
3143 * or getPflsReallyUsedMulti().
3144 * \return std::vector<std::string> - a sequence of names of all profiles.
3146 std::vector<std::string> MEDFileFieldGlobsReal::getPfls() const
3148 return contentNotNull()->getPfls();
3152 * Returns names of all localizations. To get only used localizations call getLocsReallyUsed()
3153 * or getLocsReallyUsedMulti().
3154 * \return std::vector<std::string> - a sequence of names of all localizations.
3156 std::vector<std::string> MEDFileFieldGlobsReal::getLocs() const
3158 return contentNotNull()->getLocs();
3162 * Checks if the profile with a given name exists.
3163 * \param [in] pflName - the profile name of interest.
3164 * \return bool - \c true if the profile named \a pflName exists.
3166 bool MEDFileFieldGlobsReal::existsPfl(const std::string& pflName) const
3168 return contentNotNull()->existsPfl(pflName);
3172 * Checks if the localization with a given name exists.
3173 * \param [in] locName - the localization name of interest.
3174 * \return bool - \c true if the localization named \a locName exists.
3176 bool MEDFileFieldGlobsReal::existsLoc(const std::string& locName) const
3178 return contentNotNull()->existsLoc(locName);
3181 std::string MEDFileFieldGlobsReal::createNewNameOfPfl() const
3183 return contentNotNull()->createNewNameOfPfl();
3186 std::string MEDFileFieldGlobsReal::createNewNameOfLoc() const
3188 return contentNotNull()->createNewNameOfLoc();
3192 * Sets the name of a MED file.
3193 * \param [inout] fileName - the file name.
3195 void MEDFileFieldGlobsReal::setFileName(const std::string& fileName)
3197 contentNotNull()->setFileName(fileName);
3201 * Finds equal profiles. Two profiles are considered equal if they contain the same ids
3202 * in the same order.
3203 * \return std::vector< std::vector<int> > - a sequence of groups of equal profiles.
3204 * Each item of this sequence is a vector containing ids of equal profiles.
3206 std::vector< std::vector<int> > MEDFileFieldGlobsReal::whichAreEqualProfiles() const
3208 return contentNotNull()->whichAreEqualProfiles();
3212 * Finds equal localizations.
3213 * \param [in] eps - a precision used to compare real values of the localizations.
3214 * \return std::vector< std::vector<int> > - a sequence of groups of equal localizations.
3215 * Each item of this sequence is a vector containing ids of equal localizations.
3217 std::vector< std::vector<int> > MEDFileFieldGlobsReal::whichAreEqualLocs(double eps) const
3219 return contentNotNull()->whichAreEqualLocs(eps);
3223 * Renames the profiles. References to profiles (a reference is a profile name) are not changed.
3224 * \param [in] mapOfModif - a sequence describing required renaming. Each element of
3225 * this sequence is a pair whose
3226 * - the first item is a vector of profile names to replace by the second item,
3227 * - the second item is a profile name to replace every profile name of the first item.
3229 void MEDFileFieldGlobsReal::changePflsNamesInStruct(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
3231 contentNotNull()->changePflsNamesInStruct(mapOfModif);
3235 * Renames the localizations. References to localizations (a reference is a localization name) are not changed.
3236 * \param [in] mapOfModif - a sequence describing required renaming. Each element of
3237 * this sequence is a pair whose
3238 * - the first item is a vector of localization names to replace by the second item,
3239 * - the second item is a localization name to replace every localization name of the first item.
3241 void MEDFileFieldGlobsReal::changeLocsNamesInStruct(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
3243 contentNotNull()->changeLocsNamesInStruct(mapOfModif);
3247 * Replaces references to some profiles (a reference is a profile name) by references
3248 * to other profiles and, contrary to changePflsRefsNamesGen(), renames the profiles
3249 * them-selves accordingly. <br>
3250 * This method is a generalization of changePflName().
3251 * \param [in] mapOfModif - a sequence describing required replacements. Each element of
3252 * this sequence is a pair whose
3253 * - the first item is a vector of profile names to replace by the second item,
3254 * - the second item is a profile name to replace every profile of the first item.
3255 * \sa changePflsRefsNamesGen()
3256 * \sa changePflName()
3258 void MEDFileFieldGlobsReal::changePflsNames(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
3260 changePflsRefsNamesGen(mapOfModif);
3261 changePflsNamesInStruct(mapOfModif);
3265 * Replaces references to some localizations (a reference is a localization name) by references
3266 * to other localizations and, contrary to changeLocsRefsNamesGen(), renames the localizations
3267 * them-selves accordingly. <br>
3268 * This method is a generalization of changeLocName().
3269 * \param [in] mapOfModif - a sequence describing required replacements. Each element of
3270 * this sequence is a pair whose
3271 * - the first item is a vector of localization names to replace by the second item,
3272 * - the second item is a localization name to replace every localization of the first item.
3273 * \sa changeLocsRefsNamesGen()
3274 * \sa changeLocName()
3276 void MEDFileFieldGlobsReal::changeLocsNames(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
3278 changeLocsRefsNamesGen(mapOfModif);
3279 changeLocsNamesInStruct(mapOfModif);
3283 * Renames the profile having a given name and updates references to this profile.
3284 * \param [in] oldName - the name of the profile to rename.
3285 * \param [in] newName - a new name of the profile.
3286 * \sa changePflsNames().
3288 void MEDFileFieldGlobsReal::changePflName(const std::string& oldName, const std::string& newName)
3290 std::vector< std::pair<std::vector<std::string>, std::string > > mapOfModif(1);
3291 std::pair<std::vector<std::string>, std::string > p(std::vector<std::string>(1,std::string(oldName)),std::string(newName));
3293 changePflsNames(mapOfModif);
3297 * Renames the localization having a given name and updates references to this localization.
3298 * \param [in] oldName - the name of the localization to rename.
3299 * \param [in] newName - a new name of the localization.
3300 * \sa changeLocsNames().
3302 void MEDFileFieldGlobsReal::changeLocName(const std::string& oldName, const std::string& newName)
3304 std::vector< std::pair<std::vector<std::string>, std::string > > mapOfModif(1);
3305 std::pair<std::vector<std::string>, std::string > p(std::vector<std::string>(1,std::string(oldName)),std::string(newName));
3307 changeLocsNames(mapOfModif);
3311 * Removes duplicated profiles. Returns a map used to update references to removed
3312 * profiles via changePflsRefsNamesGen().
3313 * Equal profiles are found using whichAreEqualProfiles().
3314 * \return std::vector< std::pair<std::vector<std::string>, std::string > > -
3315 * a sequence describing the performed replacements of profiles. Each element of
3316 * this sequence is a pair whose
3317 * - the first item is a vector of profile names replaced by the second item,
3318 * - the second item is a profile name replacing every profile of the first item.
3320 std::vector< std::pair<std::vector<std::string>, std::string > > MEDFileFieldGlobsReal::zipPflsNames()
3322 std::vector< std::vector<int> > pseudoRet=whichAreEqualProfiles();
3323 std::vector< std::pair<std::vector<std::string>, std::string > > ret(pseudoRet.size());
3325 for(std::vector< std::vector<int> >::const_iterator it=pseudoRet.begin();it!=pseudoRet.end();it++,i++)
3327 std::vector< std::string > tmp((*it).size());
3329 for(std::vector<int>::const_iterator it2=(*it).begin();it2!=(*it).end();it2++,j++)
3330 tmp[j]=std::string(getProfileFromId(*it2)->getName());
3331 std::pair<std::vector<std::string>, std::string > p(tmp,tmp.front());
3333 std::vector<int> tmp2((*it).begin()+1,(*it).end());
3334 killProfileIds(tmp2);
3336 changePflsRefsNamesGen(ret);
3341 * Removes duplicated localizations. Returns a map used to update references to removed
3342 * localizations via changeLocsRefsNamesGen().
3343 * Equal localizations are found using whichAreEqualLocs().
3344 * \param [in] eps - a precision used to compare real values of the localizations.
3345 * \return std::vector< std::pair<std::vector<std::string>, std::string > > -
3346 * a sequence describing the performed replacements of localizations. Each element of
3347 * this sequence is a pair whose
3348 * - the first item is a vector of localization names replaced by the second item,
3349 * - the second item is a localization name replacing every localization of the first item.
3351 std::vector< std::pair<std::vector<std::string>, std::string > > MEDFileFieldGlobsReal::zipLocsNames(double eps)
3353 std::vector< std::vector<int> > pseudoRet=whichAreEqualLocs(eps);
3354 std::vector< std::pair<std::vector<std::string>, std::string > > ret(pseudoRet.size());
3356 for(std::vector< std::vector<int> >::const_iterator it=pseudoRet.begin();it!=pseudoRet.end();it++,i++)
3358 std::vector< std::string > tmp((*it).size());
3360 for(std::vector<int>::const_iterator it2=(*it).begin();it2!=(*it).end();it2++,j++)
3361 tmp[j]=std::string(getLocalizationFromId(*it2).getName());
3362 std::pair<std::vector<std::string>, std::string > p(tmp,tmp.front());
3364 std::vector<int> tmp2((*it).begin()+1,(*it).end());
3365 killLocalizationIds(tmp2);
3367 changeLocsRefsNamesGen(ret);
3372 * Returns number of Gauss points per cell in a given localization.
3373 * \param [in] locId - an id of the localization of interest.
3374 * \return int - the number of the Gauss points per cell.
3376 int MEDFileFieldGlobsReal::getNbOfGaussPtPerCell(int locId) const
3378 return contentNotNull()->getNbOfGaussPtPerCell(locId);
3382 * Returns an id of a localization by its name.
3383 * \param [in] loc - the localization name of interest.
3384 * \return int - the id of the localization.
3385 * \throw If there is no a localization named \a loc.
3387 int MEDFileFieldGlobsReal::getLocalizationId(const std::string& loc) const
3389 return contentNotNull()->getLocalizationId(loc);
3393 * Returns the name of the MED file.
3394 * \return const std::string& - the MED file name.
3396 std::string MEDFileFieldGlobsReal::getFileName() const
3398 return contentNotNull()->getFileName();
3401 std::string MEDFileFieldGlobsReal::getFileName2() const
3403 return contentNotNull()->getFileName2();
3407 * Returns a localization object by its name.
3408 * \param [in] locName - the name of the localization of interest.
3409 * \return const MEDFileFieldLoc& - the localization object having the name \a locName.
3410 * \throw If there is no a localization named \a locName.
3412 const MEDFileFieldLoc& MEDFileFieldGlobsReal::getLocalization(const std::string& locName) const
3414 return contentNotNull()->getLocalization(locName);
3418 * Returns a localization object by its id.
3419 * \param [in] locId - the id of the localization of interest.
3420 * \return const MEDFileFieldLoc& - the localization object having the id \a locId.
3421 * \throw If there is no a localization with id \a locId.
3423 const MEDFileFieldLoc& MEDFileFieldGlobsReal::getLocalizationFromId(int locId) const
3425 return contentNotNull()->getLocalizationFromId(locId);
3429 * Returns a profile array by its name.
3430 * \param [in] pflName - the name of the profile of interest.
3431 * \return const DataArrayInt * - the profile array having the name \a pflName.
3432 * \throw If there is no a profile named \a pflName.
3434 const DataArrayInt *MEDFileFieldGlobsReal::getProfile(const std::string& pflName) const
3436 return contentNotNull()->getProfile(pflName);
3440 * Returns a profile array by its id.
3441 * \param [in] pflId - the id of the profile of interest.
3442 * \return const DataArrayInt * - the profile array having the id \a pflId.
3443 * \throw If there is no a profile with id \a pflId.
3445 const DataArrayInt *MEDFileFieldGlobsReal::getProfileFromId(int pflId) const
3447 return contentNotNull()->getProfileFromId(pflId);
3451 * Returns a localization object, apt for modification, by its id.
3452 * \param [in] locId - the id of the localization of interest.
3453 * \return MEDFileFieldLoc& - a non-const reference to the localization object
3454 * having the id \a locId.
3455 * \throw If there is no a localization with id \a locId.
3457 MEDFileFieldLoc& MEDFileFieldGlobsReal::getLocalizationFromId(int locId)
3459 return contentNotNull()->getLocalizationFromId(locId);
3463 * Returns a localization object, apt for modification, by its name.
3464 * \param [in] locName - the name of the localization of interest.
3465 * \return MEDFileFieldLoc& - a non-const reference to the localization object
3466 * having the name \a locName.
3467 * \throw If there is no a localization named \a locName.
3469 MEDFileFieldLoc& MEDFileFieldGlobsReal::getLocalization(const std::string& locName)
3471 return contentNotNull()->getLocalization(locName);
3475 * Returns a profile array, apt for modification, by its name.
3476 * \param [in] pflName - the name of the profile of interest.
3477 * \return DataArrayInt * - a non-const pointer to the profile array having the name \a pflName.
3478 * \throw If there is no a profile named \a pflName.
3480 DataArrayInt *MEDFileFieldGlobsReal::getProfile(const std::string& pflName)
3482 return contentNotNull()->getProfile(pflName);
3486 * Returns a profile array, apt for modification, by its id.
3487 * \param [in] pflId - the id of the profile of interest.
3488 * \return DataArrayInt * - a non-const pointer to the profile array having the id \a pflId.
3489 * \throw If there is no a profile with id \a pflId.
3491 DataArrayInt *MEDFileFieldGlobsReal::getProfileFromId(int pflId)
3493 return contentNotNull()->getProfileFromId(pflId);
3497 * Removes profiles given by their ids. No data is updated to track this removal.
3498 * \param [in] pflIds - a sequence of ids of the profiles to remove.
3500 void MEDFileFieldGlobsReal::killProfileIds(const std::vector<int>& pflIds)
3502 contentNotNull()->killProfileIds(pflIds);
3506 * Removes localizations given by their ids. No data is updated to track this removal.
3507 * \param [in] locIds - a sequence of ids of the localizations to remove.
3509 void MEDFileFieldGlobsReal::killLocalizationIds(const std::vector<int>& locIds)
3511 contentNotNull()->killLocalizationIds(locIds);
3515 * Stores a profile array.
3516 * \param [in] pfl - the profile array to store.
3517 * \throw If the name of \a pfl is empty.
3518 * \throw If a profile with the same name as that of \a pfl already exists but contains
3521 void MEDFileFieldGlobsReal::appendProfile(DataArrayInt *pfl)
3523 contentNotNull()->appendProfile(pfl);
3527 * Adds a new localization of Gauss points.
3528 * \param [in] locName - the name of the new localization.
3529 * \param [in] geoType - a geometrical type of the reference cell.
3530 * \param [in] refCoo - coordinates of points of the reference cell. Size of this vector
3531 * must be \c nbOfNodesPerCell * \c dimOfType.
3532 * \param [in] gsCoo - coordinates of Gauss points on the reference cell. Size of this vector
3533 * must be _wg_.size() * \c dimOfType.
3534 * \param [in] w - the weights of Gauss points.
3535 * \throw If \a locName is empty.
3536 * \throw If a localization with the name \a locName already exists but is
3537 * different form the new one.
3539 void MEDFileFieldGlobsReal::appendLoc(const std::string& locName, INTERP_KERNEL::NormalizedCellType geoType, const std::vector<double>& refCoo, const std::vector<double>& gsCoo, const std::vector<double>& w)
3541 contentNotNull()->appendLoc(locName,geoType,refCoo,gsCoo,w);
3544 MEDFileFieldGlobs *MEDFileFieldGlobsReal::contentNotNull()
3546 MEDFileFieldGlobs *g(_globals);
3548 throw INTERP_KERNEL::Exception("MEDFileFieldGlobsReal::contentNotNull : no content in not const !");
3552 const MEDFileFieldGlobs *MEDFileFieldGlobsReal::contentNotNull() const
3554 const MEDFileFieldGlobs *g(_globals);
3556 throw INTERP_KERNEL::Exception("MEDFileFieldGlobsReal::contentNotNull : no content in const !");
3560 //= MEDFileFieldNameScope
3562 MEDFileFieldNameScope::MEDFileFieldNameScope()
3566 MEDFileFieldNameScope::MEDFileFieldNameScope(const std::string& fieldName):_name(fieldName)
3571 * Returns the name of \a this field.
3572 * \return std::string - a string containing the field name.
3574 std::string MEDFileFieldNameScope::getName() const
3580 * Sets name of \a this field
3581 * \param [in] name - the new field name.
3583 void MEDFileFieldNameScope::setName(const std::string& fieldName)
3588 std::string MEDFileFieldNameScope::getDtUnit() const
3593 void MEDFileFieldNameScope::setDtUnit(const std::string& dtUnit)
3598 void MEDFileFieldNameScope::copyNameScope(const MEDFileFieldNameScope& other)
3601 _dt_unit=other._dt_unit;
3604 //= MEDFileAnyTypeField1TSWithoutSDA
3606 void MEDFileAnyTypeField1TSWithoutSDA::deepCpyLeavesFrom(const MEDFileAnyTypeField1TSWithoutSDA& other)
3608 _field_per_mesh.resize(other._field_per_mesh.size());
3610 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=other._field_per_mesh.begin();it!=other._field_per_mesh.end();it++,i++)
3612 if((const MEDFileFieldPerMesh *)*it)
3613 _field_per_mesh[i]=(*it)->deepCpy(this);
3618 * Prints a string describing \a this field into a stream. This string is outputted
3619 * by \c print Python command.
3620 * \param [in] bkOffset - number of white spaces printed at the beginning of each line.
3621 * \param [in,out] oss - the out stream.
3622 * \param [in] f1tsId - the field index within a MED file. If \a f1tsId < 0, the tiny
3623 * info id printed, else, not.
3625 void MEDFileAnyTypeField1TSWithoutSDA::simpleRepr(int bkOffset, std::ostream& oss, int f1tsId) const
3627 std::string startOfLine(bkOffset,' ');
3628 oss << startOfLine << "Field ";
3630 oss << "[Type=" << getTypeStr() << "] with name \"" << getName() << "\" ";
3631 oss << "on one time Step ";
3633 oss << "(" << f1tsId << ") ";
3634 oss << "on iteration=" << _iteration << " order=" << _order << "." << std::endl;
3635 oss << startOfLine << "Time attached is : " << _dt << " [" << _dt_unit << "]." << std::endl;
3636 const DataArray *arr=getUndergroundDataArray();
3639 const std::vector<std::string> &comps=arr->getInfoOnComponents();
3642 oss << startOfLine << "Field has " << comps.size() << " components with the following infos :" << std::endl;
3643 for(std::vector<std::string>::const_iterator it=comps.begin();it!=comps.end();it++)
3644 oss << startOfLine << " - \"" << (*it) << "\"" << std::endl;
3646 if(arr->isAllocated())
3648 oss << startOfLine << "Whole field contains " << arr->getNumberOfTuples() << " tuples." << std::endl;
3651 oss << startOfLine << "The array of the current field has not allocated yet !" << std::endl;
3655 oss << startOfLine << "Field infos are empty ! Not defined yet !" << std::endl;
3657 oss << startOfLine << "----------------------" << std::endl;
3658 if(!_field_per_mesh.empty())
3661 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it2=_field_per_mesh.begin();it2!=_field_per_mesh.end();it2++,i++)
3663 const MEDFileFieldPerMesh *cur=(*it2);
3665 cur->simpleRepr(bkOffset,oss,i);
3667 oss << startOfLine << "Field per mesh #" << i << " is not defined !" << std::endl;
3672 oss << startOfLine << "Field is not defined on any meshes !" << std::endl;
3674 oss << startOfLine << "----------------------" << std::endl;
3677 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > MEDFileAnyTypeField1TSWithoutSDA::splitComponents() const
3679 const DataArray *arr(getUndergroundDataArray());
3681 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::splitComponents : no array defined !");
3682 int nbOfCompo=arr->getNumberOfComponents();
3683 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > ret(nbOfCompo);
3684 for(int i=0;i<nbOfCompo;i++)
3687 std::vector<int> v(1,i);
3688 MEDCouplingAutoRefCountObjectPtr<DataArray> arr2=arr->keepSelectedComponents(v);
3689 ret[i]->setArray(arr2);
3694 MEDFileAnyTypeField1TSWithoutSDA::MEDFileAnyTypeField1TSWithoutSDA(const std::string& fieldName, int csit, int iteration, int order):MEDFileFieldNameScope(fieldName),_iteration(iteration),_order(order),_csit(csit),_nb_of_tuples_to_be_allocated(-2)
3698 MEDFileAnyTypeField1TSWithoutSDA::MEDFileAnyTypeField1TSWithoutSDA():_iteration(-1),_order(-1),_dt(0.),_csit(-1),_nb_of_tuples_to_be_allocated(-1)
3703 * Returns the maximal dimension of supporting elements. Returns -2 if \a this is
3704 * empty. Returns -1 if this in on nodes.
3705 * \return int - the dimension of \a this.
3707 int MEDFileAnyTypeField1TSWithoutSDA::getDimension() const
3710 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3711 (*it)->getDimension(ret);
3716 * Returns the mesh name.
3717 * \return std::string - a string holding the mesh name.
3718 * \throw If \c _field_per_mesh.empty()
3720 std::string MEDFileAnyTypeField1TSWithoutSDA::getMeshName() const
3722 if(_field_per_mesh.empty())
3723 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::getMeshName : No field set !");
3724 return _field_per_mesh[0]->getMeshName();
3727 void MEDFileAnyTypeField1TSWithoutSDA::setMeshName(const std::string& newMeshName)
3729 std::string oldName(getMeshName());
3730 std::vector< std::pair<std::string,std::string> > v(1);
3731 v[0].first=oldName; v[0].second=newMeshName;
3735 bool MEDFileAnyTypeField1TSWithoutSDA::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
3738 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3740 MEDFileFieldPerMesh *cur(*it);
3742 ret=cur->changeMeshNames(modifTab) || ret;
3748 * Returns the number of iteration of the state of underlying mesh.
3749 * \return int - the iteration number.
3750 * \throw If \c _field_per_mesh.empty()
3752 int MEDFileAnyTypeField1TSWithoutSDA::getMeshIteration() const
3754 if(_field_per_mesh.empty())
3755 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::getMeshIteration : No field set !");
3756 return _field_per_mesh[0]->getMeshIteration();
3760 * Returns the order number of iteration of the state of underlying mesh.
3761 * \return int - the order number.
3762 * \throw If \c _field_per_mesh.empty()
3764 int MEDFileAnyTypeField1TSWithoutSDA::getMeshOrder() const
3766 if(_field_per_mesh.empty())
3767 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::getMeshOrder : No field set !");
3768 return _field_per_mesh[0]->getMeshOrder();
3772 * Checks if \a this field is tagged by a given iteration number and a given
3773 * iteration order number.
3774 * \param [in] iteration - the iteration number of interest.
3775 * \param [in] order - the iteration order number of interest.
3776 * \return bool - \c true if \a this->getIteration() == \a iteration &&
3777 * \a this->getOrder() == \a order.
3779 bool MEDFileAnyTypeField1TSWithoutSDA::isDealingTS(int iteration, int order) const
3781 return iteration==_iteration && order==_order;
3785 * Returns number of iteration and order number of iteration when
3786 * \a this field has been calculated.
3787 * \return std::pair<int,int> - a pair of the iteration number and the iteration
3790 std::pair<int,int> MEDFileAnyTypeField1TSWithoutSDA::getDtIt() const
3792 std::pair<int,int> p;
3798 * Returns number of iteration and order number of iteration when
3799 * \a this field has been calculated.
3800 * \param [in,out] p - a pair returning the iteration number and the iteration
3803 void MEDFileAnyTypeField1TSWithoutSDA::fillIteration(std::pair<int,int>& p) const
3810 * Returns all types of spatial discretization of \a this field.
3811 * \param [in,out] types - a sequence of types of \a this field.
3813 void MEDFileAnyTypeField1TSWithoutSDA::fillTypesOfFieldAvailable(std::vector<TypeOfField>& types) const
3815 std::set<TypeOfField> types2;
3816 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3818 (*it)->fillTypesOfFieldAvailable(types2);
3820 std::back_insert_iterator< std::vector<TypeOfField> > bi(types);
3821 std::copy(types2.begin(),types2.end(),bi);
3825 * Returns all types of spatial discretization of \a this field.
3826 * \return std::vector<TypeOfField> - a sequence of types of spatial discretization
3829 std::vector<TypeOfField> MEDFileAnyTypeField1TSWithoutSDA::getTypesOfFieldAvailable() const
3831 std::vector<TypeOfField> ret;
3832 fillTypesOfFieldAvailable(ret);
3836 std::vector<std::string> MEDFileAnyTypeField1TSWithoutSDA::getPflsReallyUsed2() const
3838 std::vector<std::string> ret;
3839 std::set<std::string> ret2;
3840 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3842 std::vector<std::string> tmp=(*it)->getPflsReallyUsed();
3843 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
3844 if(ret2.find(*it2)==ret2.end())
3846 ret.push_back(*it2);
3853 std::vector<std::string> MEDFileAnyTypeField1TSWithoutSDA::getLocsReallyUsed2() const
3855 std::vector<std::string> ret;
3856 std::set<std::string> ret2;
3857 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3859 std::vector<std::string> tmp=(*it)->getLocsReallyUsed();
3860 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
3861 if(ret2.find(*it2)==ret2.end())
3863 ret.push_back(*it2);
3870 std::vector<std::string> MEDFileAnyTypeField1TSWithoutSDA::getPflsReallyUsedMulti2() const
3872 std::vector<std::string> ret;
3873 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3875 std::vector<std::string> tmp=(*it)->getPflsReallyUsedMulti();
3876 ret.insert(ret.end(),tmp.begin(),tmp.end());
3881 std::vector<std::string> MEDFileAnyTypeField1TSWithoutSDA::getLocsReallyUsedMulti2() const
3883 std::vector<std::string> ret;
3884 std::set<std::string> ret2;
3885 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3887 std::vector<std::string> tmp=(*it)->getLocsReallyUsedMulti();
3888 ret.insert(ret.end(),tmp.begin(),tmp.end());
3893 void MEDFileAnyTypeField1TSWithoutSDA::changePflsRefsNamesGen2(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
3895 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3896 (*it)->changePflsRefsNamesGen(mapOfModif);
3899 void MEDFileAnyTypeField1TSWithoutSDA::changeLocsRefsNamesGen2(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
3901 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3902 (*it)->changeLocsRefsNamesGen(mapOfModif);
3906 * Returns all attributes of parts of \a this field lying on a given mesh.
3907 * Each part differs from other ones by a type of supporting mesh entity. The _i_-th
3908 * item of every of returned sequences refers to the _i_-th part of \a this field.
3909 * Thus all sequences returned by this method are of the same length equal to number
3910 * of different types of supporting entities.<br>
3911 * A field part can include sub-parts with several different spatial discretizations,
3912 * \ref ParaMEDMEM::ON_CELLS "ON_CELLS" and \ref ParaMEDMEM::ON_GAUSS_PT "ON_GAUSS_PT"
3913 * for example. Hence, some of the returned sequences contains nested sequences, and an item
3914 * of a nested sequence corresponds to a type of spatial discretization.<br>
3915 * This method allows for iteration over MEDFile DataStructure without any overhead.
3916 * \param [in] mname - a name of a mesh of interest. It can be \c NULL, which is valid
3917 * for the case with only one underlying mesh. (Actually, the number of meshes is
3918 * not checked if \a mname == \c NULL).
3919 * \param [in,out] types - a sequence of types of underlying mesh entities. A type per
3920 * a field part is returned.
3921 * \param [in,out] typesF - a sequence of sequences of types of spatial discretizations.
3922 * This sequence is of the same length as \a types.
3923 * \param [in,out] pfls - a sequence returning a profile name per each type of spatial
3924 * discretization. A profile name can be empty.
3925 * Length of this and of nested sequences is the same as that of \a typesF.
3926 * \param [in,out] locs - a sequence returning a localization name per each type of spatial
3927 * discretization. A localization name can be empty.
3928 * Length of this and of nested sequences is the same as that of \a typesF.
3929 * \return std::vector< std::vector< std::pair<int,int> > > - a sequence holding a range
3930 * of ids of tuples within the data array, per each type of spatial
3931 * discretization within one mesh entity type.
3932 * Length of this and of nested sequences is the same as that of \a typesF.
3933 * \throw If no field is lying on \a mname.
3935 std::vector< std::vector< std::pair<int,int> > > MEDFileAnyTypeField1TSWithoutSDA::getFieldSplitedByType(const std::string& mname, std::vector<INTERP_KERNEL::NormalizedCellType>& types, std::vector< std::vector<TypeOfField> >& typesF, std::vector< std::vector<std::string> >& pfls, std::vector< std::vector<std::string> >& locs) const
3939 meshId=getMeshIdFromMeshName(mname);
3941 if(_field_per_mesh.empty())
3942 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getFieldSplitedByType : This is empty !");
3943 return _field_per_mesh[meshId]->getFieldSplitedByType(types,typesF,pfls,locs);
3947 * Returns dimensions of mesh elements \a this field lies on. The returned value is a
3948 * maximal absolute dimension and values returned via the out parameter \a levs are
3949 * dimensions relative to the maximal absolute dimension. <br>
3950 * This method is designed for MEDFileField1TS instances that have a discretization
3951 * \ref ParaMEDMEM::ON_CELLS "ON_CELLS",
3952 * \ref ParaMEDMEM::ON_GAUSS_PT "ON_GAUSS_PT",
3953 * \ref ParaMEDMEM::ON_GAUSS_NE "ON_GAUSS_NE".
3954 * Only these 3 discretizations will be taken into account here. If \a this is
3955 * \ref ParaMEDMEM::ON_NODES "ON_NODES", -1 is returned and \a levs are empty.<br>
3956 * This method is useful to make the link between the dimension of the underlying mesh
3957 * and the levels of \a this, because it is possible that the highest dimension of \a this
3958 * field is not equal to the dimension of the underlying mesh.
3960 * Let's consider the following case:
3961 * - mesh \a m1 has a meshDimension 3 and has non empty levels [0,-1,-2] with elements
3962 * TETRA4, HEXA8, TRI3 and SEG2.
3963 * - field \a f1 lies on \a m1 and is defined on 3D and 1D elements TETRA4 and SEG2.
3964 * - field \a f2 lies on \a m1 and is defined on 2D and 1D elements TRI3 and SEG2.
3966 * In this case \a f1->getNonEmptyLevels() returns (3,[0,-2]) and \a
3967 * f2->getNonEmptyLevels() returns (2,[0,-1]). <br>
3968 * The returned values can be used for example to retrieve a MEDCouplingFieldDouble lying
3969 * on elements of a certain relative level by calling getFieldAtLevel(). \a meshDimRelToMax
3970 * parameter of getFieldAtLevel() is computed basing on the returned values as this:
3971 * <em> meshDimRelToMax = absDim - meshDim + relativeLev </em>.
3973 * to retrieve the highest level of
3974 * \a f1: <em>f1->getFieldAtLevel( ON_CELLS, 3-3+0 ); // absDim - meshDim + relativeLev</em><br>
3975 * to retrieve the lowest level of \a f1: <em>f1->getFieldAtLevel( ON_CELLS, 3-3+(-2) );</em><br>
3976 * to retrieve the highest level of \a f2: <em>f2->getFieldAtLevel( ON_CELLS, 2-3+0 );</em><br>
3977 * to retrieve the lowest level of \a f2: <em>f2->getFieldAtLevel( ON_CELLS, 2-3+(-1) )</em>.
3978 * \param [in] mname - a name of a mesh of interest. It can be \c NULL, which is valid
3979 * for the case with only one underlying mesh. (Actually, the number of meshes is
3980 * not checked if \a mname == \c NULL).
3981 * \param [in,out] levs - a sequence returning the dimensions relative to the maximal
3982 * absolute one. They are in decreasing order. This sequence is cleared before
3984 * \return int - the maximal absolute dimension of elements \a this fields lies on.
3985 * \throw If no field is lying on \a mname.
3987 int MEDFileAnyTypeField1TSWithoutSDA::getNonEmptyLevels(const std::string& mname, std::vector<int>& levs) const
3990 int meshId=getMeshIdFromMeshName(mname);
3991 std::vector<INTERP_KERNEL::NormalizedCellType> types;
3992 std::vector< std::vector<TypeOfField> > typesF;
3993 std::vector< std::vector<std::string> > pfls, locs;
3994 _field_per_mesh[meshId]->getFieldSplitedByType(types,typesF,pfls,locs);
3996 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getNonEmptyLevels : 'this' is empty !");
3997 std::set<INTERP_KERNEL::NormalizedCellType> st(types.begin(),types.end());
3998 if(st.size()==1 && (*st.begin())==INTERP_KERNEL::NORM_ERROR)
4000 st.erase(INTERP_KERNEL::NORM_ERROR);
4002 for(std::set<INTERP_KERNEL::NormalizedCellType>::const_iterator it=st.begin();it!=st.end();it++)
4004 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(*it);
4005 ret1.insert((int)cm.getDimension());
4007 int ret=*std::max_element(ret1.begin(),ret1.end());
4008 std::copy(ret1.rbegin(),ret1.rend(),std::back_insert_iterator<std::vector<int> >(levs));
4009 std::transform(levs.begin(),levs.end(),levs.begin(),std::bind2nd(std::plus<int>(),-ret));
4014 * \param [in] mName specifies the underlying mesh name. This value can be pointer 0 for users that do not deal with fields on multi mesh.
4015 * \param [in] typ is for the geometric cell type (or INTERP_KERNEL::NORM_ERROR for node field) entry to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set.
4016 * \param [in] locId is the localization id to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set. It corresponds to the position of
4017 * \c pfls[std::distance(types.begin(),std::find(types.begin(),typ)] vector in MEDFileField1TSWithoutSDA::getFieldSplitedByType. For non gausspoints field users, the value is 0.
4019 MEDFileFieldPerMeshPerTypePerDisc *MEDFileAnyTypeField1TSWithoutSDA::getLeafGivenMeshAndTypeAndLocId(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId)
4021 int mid=getMeshIdFromMeshName(mName);
4022 return _field_per_mesh[mid]->getLeafGivenTypeAndLocId(typ,locId);
4026 * \param [in] mName specifies the underlying mesh name. This value can be pointer 0 for users that do not deal with fields on multi mesh.
4027 * \param [in] typ is for the geometric cell type (or INTERP_KERNEL::NORM_ERROR for node field) entry to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set.
4028 * \param [in] locId is the localization id to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set. It corresponds to the position of
4029 * \c pfls[std::distance(types.begin(),std::find(types.begin(),typ)] vector in MEDFileField1TSWithoutSDA::getFieldSplitedByType. For non gausspoints field users, the value is 0.
4031 const MEDFileFieldPerMeshPerTypePerDisc *MEDFileAnyTypeField1TSWithoutSDA::getLeafGivenMeshAndTypeAndLocId(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId) const
4033 int mid=getMeshIdFromMeshName(mName);
4034 return _field_per_mesh[mid]->getLeafGivenTypeAndLocId(typ,locId);
4038 * \param [in] mName specifies the underlying mesh name. This value can be pointer 0 for users that do not deal with fields on multi mesh.
4040 int MEDFileAnyTypeField1TSWithoutSDA::getMeshIdFromMeshName(const std::string& mName) const
4042 if(_field_per_mesh.empty())
4043 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getMeshIdFromMeshName : No field set !");
4046 std::string mName2(mName);
4048 std::vector<std::string> msg;
4049 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++,ret++)
4050 if(mName2==(*it)->getMeshName())
4053 msg.push_back((*it)->getMeshName());
4054 std::ostringstream oss; oss << "MEDFileField1TSWithoutSDA::getMeshIdFromMeshName : No such mesh \"" << mName2 << "\" as underlying mesh of field \"" << getName() << "\" !\n";
4055 oss << "Possible meshes are : ";
4056 for(std::vector<std::string>::const_iterator it2=msg.begin();it2!=msg.end();it2++)
4057 oss << "\"" << (*it2) << "\" ";
4058 throw INTERP_KERNEL::Exception(oss.str().c_str());
4061 int MEDFileAnyTypeField1TSWithoutSDA::addNewEntryIfNecessary(const MEDCouplingMesh *mesh)
4064 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::addNewEntryIfNecessary : input mesh is NULL !");
4065 std::string tmp(mesh->getName());
4067 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::addNewEntryIfNecessary : empty mesh name ! unsupported by MED file !");
4068 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();
4070 for(;it!=_field_per_mesh.end();it++,i++)
4072 if((*it)->getMeshName()==tmp)
4075 int sz=_field_per_mesh.size();
4076 _field_per_mesh.resize(sz+1);
4077 _field_per_mesh[sz]=MEDFileFieldPerMesh::New(this,mesh);
4081 bool MEDFileAnyTypeField1TSWithoutSDA::renumberEntitiesLyingOnMesh(const std::string& meshName, const std::vector<int>& oldCode, const std::vector<int>& newCode, const DataArrayInt *renumO2N,
4082 MEDFileFieldGlobsReal& glob)
4085 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4087 MEDFileFieldPerMesh *fpm(*it);
4089 ret=fpm->renumberEntitiesLyingOnMesh(meshName,oldCode,newCode,renumO2N,glob) || ret;
4094 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > MEDFileAnyTypeField1TSWithoutSDA::splitDiscretizations() const
4096 std::vector<INTERP_KERNEL::NormalizedCellType> types;
4097 std::vector< std::vector<TypeOfField> > typesF;
4098 std::vector< std::vector<std::string> > pfls,locs;
4099 std::vector< std::vector<std::pair<int,int> > > bgEnd=getFieldSplitedByType(getMeshName().c_str(),types,typesF,pfls,locs);
4100 std::set<TypeOfField> allEnt;
4101 for(std::vector< std::vector<TypeOfField> >::const_iterator it1=typesF.begin();it1!=typesF.end();it1++)
4102 for(std::vector<TypeOfField>::const_iterator it2=(*it1).begin();it2!=(*it1).end();it2++)
4103 allEnt.insert(*it2);
4104 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > ret(allEnt.size());
4105 std::set<TypeOfField>::const_iterator it3(allEnt.begin());
4106 for(std::size_t i=0;i<allEnt.size();i++,it3++)
4108 std::vector< std::pair<int,int> > its;
4109 ret[i]=shallowCpy();
4110 int newLgth=ret[i]->keepOnlySpatialDiscretization(*it3,its);
4111 ret[i]->updateData(newLgth,its);
4116 int MEDFileAnyTypeField1TSWithoutSDA::keepOnlySpatialDiscretization(TypeOfField tof, std::vector< std::pair<int,int> >& its)
4118 int globalCounter=0;
4119 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4120 (*it)->keepOnlySpatialDiscretization(tof,globalCounter,its);
4121 return globalCounter;
4124 void MEDFileAnyTypeField1TSWithoutSDA::updateData(int newLgth, const std::vector< std::pair<int,int> >& oldStartStops)
4126 if(_nb_of_tuples_to_be_allocated>=0)
4128 _nb_of_tuples_to_be_allocated=newLgth;
4129 const DataArray *oldArr(getUndergroundDataArray());
4132 MEDCouplingAutoRefCountObjectPtr<DataArray> newArr(createNewEmptyDataArrayInstance());
4133 newArr->setInfoAndChangeNbOfCompo(oldArr->getInfoOnComponents());
4135 _nb_of_tuples_to_be_allocated=newLgth;//force the _nb_of_tuples_to_be_allocated because setArray has been used specialy
4139 if(_nb_of_tuples_to_be_allocated==-1)
4141 if(_nb_of_tuples_to_be_allocated==-2 || _nb_of_tuples_to_be_allocated==-3)
4143 const DataArray *oldArr(getUndergroundDataArray());
4144 if(!oldArr || !oldArr->isAllocated())
4145 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::updateData : internal error 1 !");
4146 MEDCouplingAutoRefCountObjectPtr<DataArray> newArr(createNewEmptyDataArrayInstance());
4147 newArr->alloc(newLgth,getNumberOfComponents());
4149 newArr->copyStringInfoFrom(*oldArr);
4151 for(std::vector< std::pair<int,int> >::const_iterator it=oldStartStops.begin();it!=oldStartStops.end();it++)
4153 if((*it).second<(*it).first)
4154 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::updateData : the range in the leaves was invalid !");
4155 newArr->setContigPartOfSelectedValues2(pos,oldArr,(*it).first,(*it).second,1);
4156 pos+=(*it).second-(*it).first;
4161 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::updateData : internal error 2 !");
4164 void MEDFileAnyTypeField1TSWithoutSDA::writeLL(med_idt fid, const MEDFileWritable& opts, const MEDFileFieldNameScope& nasc) const
4166 if(_field_per_mesh.empty())
4167 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::writeLL : empty field !");
4168 if(_field_per_mesh.size()>1)
4169 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::writeLL : In MED3.0 mode in writting mode only ONE underlying mesh supported !");
4170 _field_per_mesh[0]->copyOptionsFrom(opts);
4171 _field_per_mesh[0]->writeLL(fid,nasc);
4175 * This methods returns true is the allocation has been needed leading to a modification of state in \a this->_nb_of_tuples_to_be_allocated.
4176 * If false is returned the memory allocation is not required.
4178 bool MEDFileAnyTypeField1TSWithoutSDA::allocIfNecessaryTheArrayToReceiveDataFromFile()
4180 if(_nb_of_tuples_to_be_allocated>=0)
4182 getOrCreateAndGetArray()->alloc(_nb_of_tuples_to_be_allocated,getNumberOfComponents());
4183 _nb_of_tuples_to_be_allocated=-2;
4186 if(_nb_of_tuples_to_be_allocated==-2 || _nb_of_tuples_to_be_allocated==-3)
4188 if(_nb_of_tuples_to_be_allocated==-1)
4189 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::allocIfNecessaryTheArrayToReceiveDataFromFile : trying to read from a file an empty instance ! Need to prepare the structure before !");
4190 if(_nb_of_tuples_to_be_allocated<-3)
4191 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::allocIfNecessaryTheArrayToReceiveDataFromFile : internal error !");
4192 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::allocIfNecessaryTheArrayToReceiveDataFromFile : internal error !");
4195 void MEDFileAnyTypeField1TSWithoutSDA::loadOnlyStructureOfDataRecursively(med_idt fid, const MEDFileFieldNameScope& nasc)
4197 med_int numdt,numit;
4201 med_int meshnumdt,meshnumit;
4202 INTERP_KERNEL::AutoPtr<char> meshName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
4203 MEDfieldComputingStepInfo(fid,nasc.getName().c_str(),_csit,&numdt,&numit,&_dt);
4204 MEDfield23ComputingStepMeshInfo(fid,nasc.getName().c_str(),_csit,&numdt,&numit,&dt,&nmesh,meshName,&localMesh,&meshnumdt,&meshnumit);
4205 if(_iteration!=numdt || _order!=numit)
4206 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::loadBigArraysRecursively : unexpected exception internal error !");
4207 _field_per_mesh.resize(nmesh);
4208 for(int i=0;i<nmesh;i++)
4209 _field_per_mesh[i]=MEDFileFieldPerMesh::NewOnRead(fid,this,i+1,meshnumdt,meshnumit,nasc);//tony
4210 _nb_of_tuples_to_be_allocated=0;
4211 for(int i=0;i<nmesh;i++)
4212 _field_per_mesh[i]->loadOnlyStructureOfDataRecursively(fid,_nb_of_tuples_to_be_allocated,nasc);
4215 void MEDFileAnyTypeField1TSWithoutSDA::loadBigArraysRecursively(med_idt fid, const MEDFileFieldNameScope& nasc)
4217 allocIfNecessaryTheArrayToReceiveDataFromFile();
4218 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4219 (*it)->loadBigArraysRecursively(fid,nasc);
4222 void MEDFileAnyTypeField1TSWithoutSDA::loadBigArraysRecursivelyIfNecessary(med_idt fid, const MEDFileFieldNameScope& nasc)
4224 if(allocIfNecessaryTheArrayToReceiveDataFromFile())
4225 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4226 (*it)->loadBigArraysRecursively(fid,nasc);
4229 void MEDFileAnyTypeField1TSWithoutSDA::loadStructureAndBigArraysRecursively(med_idt fid, const MEDFileFieldNameScope& nasc)
4231 loadOnlyStructureOfDataRecursively(fid,nasc);
4232 loadBigArraysRecursively(fid,nasc);
4235 void MEDFileAnyTypeField1TSWithoutSDA::unloadArrays()
4237 DataArray *thisArr(getUndergroundDataArray());
4238 if(thisArr && thisArr->isAllocated())
4240 _nb_of_tuples_to_be_allocated=thisArr->getNumberOfTuples();
4241 thisArr->desallocate();
4245 std::size_t MEDFileAnyTypeField1TSWithoutSDA::getHeapMemorySizeWithoutChildren() const
4247 return _dt_unit.capacity()+_field_per_mesh.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh >);
4250 std::vector<const BigMemoryObject *> MEDFileAnyTypeField1TSWithoutSDA::getDirectChildren() const
4252 std::vector<const BigMemoryObject *> ret;
4253 if(getUndergroundDataArray())
4254 ret.push_back(getUndergroundDataArray());
4255 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4257 const MEDFileFieldPerMesh *cur(*it);
4265 * Adds a MEDCouplingFieldDouble to \a this. The underlying mesh of the given field is
4266 * checked if its elements are sorted suitable for writing to MED file ("STB" stands for
4267 * "Sort By Type"), if not, an exception is thrown.
4268 * \param [in] field - the field to add to \a this. The array of field \a field is ignored
4269 * \param [in] arr - the array of values.
4270 * \param [in,out] glob - the global data where profiles and localization present in
4271 * \a field, if any, are added.
4272 * \throw If the name of \a field is empty.
4273 * \throw If the data array of \a field is not set.
4274 * \throw If \a this->_arr is already allocated but has different number of components
4276 * \throw If the underlying mesh of \a field has no name.
4277 * \throw If elements in the mesh are not in the order suitable for writing to the MED file.
4279 void MEDFileAnyTypeField1TSWithoutSDA::setFieldNoProfileSBT(const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
4281 const MEDCouplingMesh *mesh=field->getMesh();
4283 TypeOfField type=field->getTypeOfField();
4284 std::vector<DataArrayInt *> dummy;
4285 int start=copyTinyInfoFrom(field,arr);
4286 int pos=addNewEntryIfNecessary(mesh);
4289 std::vector<int> code=MEDFileField1TSWithoutSDA::CheckSBTMesh(mesh);
4290 _field_per_mesh[pos]->assignFieldNoProfileNoRenum(start,code,field,arr,glob,nasc);
4293 _field_per_mesh[pos]->assignNodeFieldNoProfile(start,field,arr,glob);
4297 * Adds a MEDCouplingFieldDouble to \a this. Specified entities of a given dimension
4298 * of a given mesh are used as the support of the given field (a real support is not used).
4299 * Elements of the given mesh must be sorted suitable for writing to MED file.
4300 * Order of underlying mesh entities of the given field specified by \a profile parameter
4301 * is not prescribed; this method permutes field values to have them sorted by element
4302 * type as required for writing to MED file. A new profile is added only if no equal
4303 * profile is missing.
4304 * \param [in] field - the field to add to \a this. The field double values are ignored.
4305 * \param [in] arrOfVals - the values of the field \a field used.
4306 * \param [in] mesh - the supporting mesh of \a field.
4307 * \param [in] meshDimRelToMax - a relative dimension of mesh entities \a field lies on.
4308 * \param [in] profile - ids of mesh entities on which corresponding field values lie.
4309 * \param [in,out] glob - the global data where profiles and localization present in
4310 * \a field, if any, are added.
4311 * \throw If either \a field or \a mesh or \a profile has an empty name.
4312 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
4313 * \throw If the data array of \a field is not set.
4314 * \throw If \a this->_arr is already allocated but has different number of components
4316 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
4317 * \sa setFieldNoProfileSBT()
4319 void MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile(const MEDCouplingFieldDouble *field, const DataArray *arrOfVals, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
4322 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile : input field is null !");
4323 if(!arrOfVals || !arrOfVals->isAllocated())
4324 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile : input array is null or not allocated !");
4325 TypeOfField type=field->getTypeOfField();
4326 std::vector<DataArrayInt *> idsInPflPerType;
4327 std::vector<DataArrayInt *> idsPerType;
4328 std::vector<int> code,code2;
4329 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> m=mesh->getGenMeshAtLevel(meshDimRelToMax);
4332 m->splitProfilePerType(profile,code,idsInPflPerType,idsPerType);
4333 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > idsInPflPerType2(idsInPflPerType.size()); std::copy(idsInPflPerType.begin(),idsInPflPerType.end(),idsInPflPerType2.begin());
4334 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > idsPerType2(idsPerType.size()); std::copy(idsPerType.begin(),idsPerType.end(),idsPerType2.begin());
4335 std::vector<const DataArrayInt *> idsPerType3(idsPerType.size()); std::copy(idsPerType.begin(),idsPerType.end(),idsPerType3.begin());
4337 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> field2=field->clone(false);
4338 int nbOfTuplesExp=field2->getNumberOfTuplesExpectedRegardingCode(code,idsPerType3);
4339 if(nbOfTuplesExp!=arrOfVals->getNumberOfTuples())
4341 std::ostringstream oss; oss << "MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile : The array is expected to have " << nbOfTuplesExp << " tuples ! It has " << arrOfVals->getNumberOfTuples() << " !";
4342 throw INTERP_KERNEL::Exception(oss.str().c_str());
4345 int start=copyTinyInfoFrom(field,arrOfVals);
4346 code2=m->getDistributionOfTypes();
4348 int pos=addNewEntryIfNecessary(m);
4349 _field_per_mesh[pos]->assignFieldProfile(start,profile,code,code2,idsInPflPerType,idsPerType,field,arrOfVals,m,glob,nasc);
4353 if(!profile || !profile->isAllocated() || profile->getNumberOfComponents()!=1)
4354 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile : input profile is null, not allocated or with number of components != 1 !");
4355 std::vector<int> v(3); v[0]=-1; v[1]=profile->getNumberOfTuples(); v[2]=0;
4356 std::vector<const DataArrayInt *> idsPerType3(1); idsPerType3[0]=profile;
4357 int nbOfTuplesExp=field->getNumberOfTuplesExpectedRegardingCode(v,idsPerType3);
4358 if(nbOfTuplesExp!=arrOfVals->getNumberOfTuples())
4360 std::ostringstream oss; oss << "MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile : For node field, the array is expected to have " << nbOfTuplesExp << " tuples ! It has " << arrOfVals->getNumberOfTuples() << " !";
4361 throw INTERP_KERNEL::Exception(oss.str().c_str());
4363 int start=copyTinyInfoFrom(field,arrOfVals);
4364 int pos=addNewEntryIfNecessary(m);
4365 _field_per_mesh[pos]->assignNodeFieldProfile(start,profile,field,arrOfVals,glob,nasc);
4370 * \param [in] newNbOfTuples - The new nb of tuples to be allocated.
4372 void MEDFileAnyTypeField1TSWithoutSDA::allocNotFromFile(int newNbOfTuples)
4374 if(_nb_of_tuples_to_be_allocated>=0)
4375 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::allocNotFromFile : the object is expected to be appended to a data coming from a file but not loaded ! Load before appending data !");
4376 DataArray *arr(getOrCreateAndGetArray());
4377 arr->alloc(newNbOfTuples,arr->getNumberOfComponents());
4378 _nb_of_tuples_to_be_allocated=-3;
4382 * Copies tiny info and allocates \a this->_arr instance of DataArrayDouble to
4383 * append data of a given MEDCouplingFieldDouble. So that the size of \a this->_arr becomes
4384 * larger by the size of \a field. Returns an id of the first not filled
4385 * tuple of \a this->_arr.
4386 * \param [in] field - the field to copy the info on components and the name from.
4387 * \return int - the id of first not initialized tuple of \a this->_arr.
4388 * \throw If the name of \a field is empty.
4389 * \throw If the data array of \a field is not set.
4390 * \throw If \a this->_arr is already allocated but has different number of components
4393 int MEDFileAnyTypeField1TSWithoutSDA::copyTinyInfoFrom(const MEDCouplingFieldDouble *field, const DataArray *arr)
4396 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::copyTinyInfoFrom : input field is NULL !");
4397 std::string name(field->getName());
4398 setName(name.c_str());
4399 setDtUnit(field->getTimeUnit());
4401 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::copyTinyInfoFrom : unsupported fields with no name in MED file !");
4403 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::copyTinyInfoFrom : no array set !");
4404 if(!arr->isAllocated())
4405 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::copyTinyInfoFrom : array is not allocated !");
4406 _dt=field->getTime(_iteration,_order);
4407 getOrCreateAndGetArray()->setInfoAndChangeNbOfCompo(arr->getInfoOnComponents());
4408 if(!getOrCreateAndGetArray()->isAllocated())
4410 allocNotFromFile(arr->getNumberOfTuples());
4415 int oldNbOfTuples=getOrCreateAndGetArray()->getNumberOfTuples();
4416 int newNbOfTuples=oldNbOfTuples+arr->getNumberOfTuples();
4417 getOrCreateAndGetArray()->reAlloc(newNbOfTuples);
4418 _nb_of_tuples_to_be_allocated=-3;
4419 return oldNbOfTuples;
4424 * Returns number of components in \a this field
4425 * \return int - the number of components.
4427 int MEDFileAnyTypeField1TSWithoutSDA::getNumberOfComponents() const
4429 return getOrCreateAndGetArray()->getNumberOfComponents();
4433 * Change info on components in \a this.
4434 * \throw If size of \a infos is not equal to the number of components already in \a this.
4436 void MEDFileAnyTypeField1TSWithoutSDA::setInfo(const std::vector<std::string>& infos)
4438 DataArray *arr=getOrCreateAndGetArray();
4439 arr->setInfoOnComponents(infos);//will throw an exception if number of components mimatches
4443 * Returns info on components of \a this field.
4444 * \return const std::vector<std::string>& - a sequence of strings each being an
4445 * information on _i_-th component.
4447 const std::vector<std::string>& MEDFileAnyTypeField1TSWithoutSDA::getInfo() const
4449 const DataArray *arr=getOrCreateAndGetArray();
4450 return arr->getInfoOnComponents();
4454 * Returns a mutable info on components of \a this field.
4455 * \return std::vector<std::string>& - a sequence of strings each being an
4456 * information on _i_-th component.
4458 std::vector<std::string>& MEDFileAnyTypeField1TSWithoutSDA::getInfo()
4460 DataArray *arr=getOrCreateAndGetArray();
4461 return arr->getInfoOnComponents();
4465 * Returns a new MEDCouplingFieldDouble of given type lying on a given support.
4466 * \param [in] type - a spatial discretization of the new field.
4467 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
4468 * \param [in] mName - a name of the supporting mesh.
4469 * \param [in] renumPol - specifies how to permute values of the result field according to
4470 * the optional numbers of cells and nodes, if any. The valid values are
4471 * - 0 - do not permute.
4472 * - 1 - permute cells.
4473 * - 2 - permute nodes.
4474 * - 3 - permute cells and nodes.
4476 * \param [in] glob - the global data storing profiles and localization.
4477 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
4478 * caller is to delete this field using decrRef() as it is no more needed.
4479 * \throw If the MED file is not readable.
4480 * \throw If there is no mesh named \a mName in the MED file.
4481 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
4482 * \throw If no field of \a this is lying on the mesh \a mName.
4483 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
4485 MEDCouplingFieldDouble *MEDFileAnyTypeField1TSWithoutSDA::getFieldAtLevel(TypeOfField type, int meshDimRelToMax, const std::string& mName, int renumPol, const MEDFileFieldGlobsReal *glob, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
4487 MEDCouplingAutoRefCountObjectPtr<MEDFileMesh> mm;
4489 mm=MEDFileMesh::New(glob->getFileName(),getMeshName().c_str(),getMeshIteration(),getMeshOrder());
4491 mm=MEDFileMesh::New(glob->getFileName(),mName,getMeshIteration(),getMeshOrder());
4492 return MEDFileAnyTypeField1TSWithoutSDA::getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,glob,mm,arrOut,nasc);
4496 * Returns a new MEDCouplingFieldDouble of given type lying on a given support.
4497 * \param [in] type - a spatial discretization of the new field.
4498 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
4499 * \param [in] renumPol - specifies how to permute values of the result field according to
4500 * the optional numbers of cells and nodes, if any. The valid values are
4501 * - 0 - do not permute.
4502 * - 1 - permute cells.
4503 * - 2 - permute nodes.
4504 * - 3 - permute cells and nodes.
4506 * \param [in] glob - the global data storing profiles and localization.
4507 * \param [in] mesh - the supporting mesh.
4508 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
4509 * caller is to delete this field using decrRef() as it is no more needed.
4510 * \throw If the MED file is not readable.
4511 * \throw If no field of \a this is lying on \a mesh.
4512 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
4513 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
4515 MEDCouplingFieldDouble *MEDFileAnyTypeField1TSWithoutSDA::getFieldOnMeshAtLevel(TypeOfField type, int meshDimRelToMax, int renumPol, const MEDFileFieldGlobsReal *glob, const MEDFileMesh *mesh, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
4517 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> m=mesh->getGenMeshAtLevel(meshDimRelToMax,false);
4518 const DataArrayInt *d=mesh->getNumberFieldAtLevel(meshDimRelToMax);
4519 const DataArrayInt *e=mesh->getNumberFieldAtLevel(1);
4520 if(meshDimRelToMax==1)
4521 (static_cast<MEDCouplingUMesh *>((MEDCouplingMesh *)m))->setMeshDimension(0);
4522 return MEDFileAnyTypeField1TSWithoutSDA::getFieldOnMeshAtLevel(type,renumPol,glob,m,d,e,arrOut,nasc);
4526 * Returns a new MEDCouplingFieldDouble of a given type lying on the top level cells of a
4528 * \param [in] type - a spatial discretization of the new field.
4529 * \param [in] mName - a name of the supporting mesh.
4530 * \param [in] renumPol - specifies how to permute values of the result field according to
4531 * the optional numbers of cells and nodes, if any. The valid values are
4532 * - 0 - do not permute.
4533 * - 1 - permute cells.
4534 * - 2 - permute nodes.
4535 * - 3 - permute cells and nodes.
4537 * \param [in] glob - the global data storing profiles and localization.
4538 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
4539 * caller is to delete this field using decrRef() as it is no more needed.
4540 * \throw If the MED file is not readable.
4541 * \throw If there is no mesh named \a mName in the MED file.
4542 * \throw If there are no mesh entities in the mesh.
4543 * \throw If no field values of the given \a type are available.
4545 MEDCouplingFieldDouble *MEDFileAnyTypeField1TSWithoutSDA::getFieldAtTopLevel(TypeOfField type, const std::string& mName, int renumPol, const MEDFileFieldGlobsReal *glob, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
4547 MEDCouplingAutoRefCountObjectPtr<MEDFileMesh> mm;
4549 mm=MEDFileMesh::New(glob->getFileName(),getMeshName().c_str(),getMeshIteration(),getMeshOrder());
4551 mm=MEDFileMesh::New(glob->getFileName(),mName,getMeshIteration(),getMeshOrder());
4552 int absDim=getDimension();
4553 int meshDimRelToMax=absDim-mm->getMeshDimension();
4554 return MEDFileAnyTypeField1TSWithoutSDA::getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,glob,mm,arrOut,nasc);
4558 * Returns a new MEDCouplingFieldDouble of given type lying on a given support.
4559 * \param [in] type - a spatial discretization of the new field.
4560 * \param [in] renumPol - specifies how to permute values of the result field according to
4561 * the optional numbers of cells and nodes, if any. The valid values are
4562 * - 0 - do not permute.
4563 * - 1 - permute cells.
4564 * - 2 - permute nodes.
4565 * - 3 - permute cells and nodes.
4567 * \param [in] glob - the global data storing profiles and localization.
4568 * \param [in] mesh - the supporting mesh.
4569 * \param [in] cellRenum - the cell numbers array used for permutation of the result
4570 * field according to \a renumPol.
4571 * \param [in] nodeRenum - the node numbers array used for permutation of the result
4572 * field according to \a renumPol.
4573 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
4574 * caller is to delete this field using decrRef() as it is no more needed.
4575 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
4576 * \throw If no field of \a this is lying on \a mesh.
4577 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
4579 MEDCouplingFieldDouble *MEDFileAnyTypeField1TSWithoutSDA::getFieldOnMeshAtLevel(TypeOfField type, int renumPol, const MEDFileFieldGlobsReal *glob, const MEDCouplingMesh *mesh, const DataArrayInt *cellRenum, const DataArrayInt *nodeRenum, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
4581 static const char msg1[]="MEDFileField1TSWithoutSDA::getFieldOnMeshAtLevel : request for a renumbered field following mesh numbering whereas it is a profile field !";
4582 int meshId=getMeshIdFromMeshName(mesh->getName());
4584 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=_field_per_mesh[meshId]->getFieldOnMeshAtLevel(type,glob,mesh,isPfl,arrOut,nasc);
4589 //no need to test _field_per_mesh.empty() because geMeshName has already done it
4596 throw INTERP_KERNEL::Exception(msg1);
4597 //no need to test _field_per_mesh.empty() because geMeshName has already done it
4600 if((int)cellRenum->getNbOfElems()!=mesh->getNumberOfCells())
4602 std::ostringstream oss; oss << "MEDFileField1TSWithoutSDA::getFieldOnMeshAtLevel : Request of simple renumbering but it seems that underlying mesh \"" << mesh->getName() << "\" of requested field ";
4603 oss << "\"" << getName() << "\" has partial renumbering (some geotype has no renumber) !";
4604 throw INTERP_KERNEL::Exception(oss.str().c_str());
4606 MEDCouplingFieldDiscretization *disc=ret->getDiscretization();
4607 if(!disc) throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::getFieldOnMeshAtLevel : internal error, no discretization on field !");
4608 std::vector<DataArray *> arrOut2(1,arrOut);
4609 // 2 following lines replace ret->renumberCells(cellRenum->getConstPointer()) if not DataArrayDouble
4610 disc->renumberArraysForCell(ret->getMesh(),arrOut2,cellRenum->getConstPointer(),true);
4611 (const_cast<MEDCouplingMesh*>(ret->getMesh()))->renumberCells(cellRenum->getConstPointer(),true);
4618 //no need to test _field_per_mesh.empty() because geMeshName has already done it
4620 throw INTERP_KERNEL::Exception(msg1);
4623 if((int)nodeRenum->getNbOfElems()!=mesh->getNumberOfNodes())
4625 std::ostringstream oss; oss << "MEDFileField1TSWithoutSDA::getFieldOnMeshAtLevel : Request of simple renumbering but it seems that underlying mesh \"" << mesh->getName() << "\" of requested field ";
4626 oss << "\"" << nasc.getName() << "\" not defined on all nodes !";
4627 throw INTERP_KERNEL::Exception(oss.str().c_str());
4629 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> nodeRenumSafe=nodeRenum->checkAndPreparePermutation();
4630 if(!dynamic_cast<DataArrayDouble *>((DataArray *)arrOut))
4631 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getFieldOnMeshAtLevel : node renumbering not implemented for not double DataArrays !");
4632 ret->renumberNodes(nodeRenumSafe->getConstPointer());
4637 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getFieldOnMeshAtLevel : unsupported renum policy ! Dealing with policy 0 1 2 and 3 !");
4642 * Returns values and a profile of the field of a given type lying on a given support.
4643 * \param [in] type - a spatial discretization of the field.
4644 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
4645 * \param [in] mesh - the supporting mesh.
4646 * \param [out] pfl - a new instance of DataArrayInt holding ids of mesh entities the
4647 * field of interest lies on. If the field lies on all entities of the given
4648 * dimension, all ids in \a pfl are zero. The caller is to delete this array
4649 * using decrRef() as it is no more needed.
4650 * \param [in] glob - the global data storing profiles and localization.
4651 * \return DataArrayDouble * - a new instance of DataArrayDouble holding values of the
4652 * field. The caller is to delete this array using decrRef() as it is no more needed.
4653 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
4654 * \throw If no field of \a this is lying on \a mesh.
4655 * \throw If no field values of the given \a type are available.
4657 DataArray *MEDFileAnyTypeField1TSWithoutSDA::getFieldWithProfile(TypeOfField type, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt *&pfl, const MEDFileFieldGlobsReal *glob, const MEDFileFieldNameScope& nasc) const
4659 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> m=mesh->getGenMeshAtLevel(meshDimRelToMax);
4660 int meshId=getMeshIdFromMeshName(mesh->getName().c_str());
4661 MEDCouplingAutoRefCountObjectPtr<DataArray> ret=_field_per_mesh[meshId]->getFieldOnMeshAtLevelWithPfl(type,m,pfl,glob,nasc);
4662 ret->setName(nasc.getName().c_str());
4666 //= MEDFileField1TSWithoutSDA
4669 * Throws if a given value is not a valid (non-extended) relative dimension.
4670 * \param [in] meshDimRelToMax - the relative dimension value.
4671 * \throw If \a meshDimRelToMax > 0.
4673 void MEDFileField1TSWithoutSDA::CheckMeshDimRel(int meshDimRelToMax)
4675 if(meshDimRelToMax>0)
4676 throw INTERP_KERNEL::Exception("CheckMeshDimRel : This is a meshDimRel not a meshDimRelExt ! So value should be <=0 !");
4680 * Checks if elements of a given mesh are in the order suitable for writing
4681 * to the MED file. If this is not so, an exception is thrown. In a case of success, returns a
4682 * vector describing types of elements and their number.
4683 * \param [in] mesh - the mesh to check.
4684 * \return std::vector<int> - a vector holding for each element type (1) item of
4685 * INTERP_KERNEL::NormalizedCellType, (2) number of elements, (3) -1.
4686 * These values are in full-interlace mode.
4687 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
4689 std::vector<int> MEDFileField1TSWithoutSDA::CheckSBTMesh(const MEDCouplingMesh *mesh)
4692 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::CheckSBTMesh : input mesh is NULL !");
4693 std::set<INTERP_KERNEL::NormalizedCellType> geoTypes=mesh->getAllGeoTypes();
4694 int nbOfTypes=geoTypes.size();
4695 std::vector<int> code(3*nbOfTypes);
4696 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr1=DataArrayInt::New();
4697 arr1->alloc(nbOfTypes,1);
4698 int *arrPtr=arr1->getPointer();
4699 std::set<INTERP_KERNEL::NormalizedCellType>::const_iterator it=geoTypes.begin();
4700 for(int i=0;i<nbOfTypes;i++,it++)
4701 arrPtr[i]=std::distance(typmai2,std::find(typmai2,typmai2+MED_N_CELL_FIXED_GEO,*it));
4702 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr2=arr1->checkAndPreparePermutation();
4703 const int *arrPtr2=arr2->getConstPointer();
4705 for(it=geoTypes.begin();it!=geoTypes.end();it++,i++)
4708 int nbCells=mesh->getNumberOfCellsWithType(*it);
4709 code[3*pos]=(int)(*it);
4710 code[3*pos+1]=nbCells;
4711 code[3*pos+2]=-1;//no profiles
4713 std::vector<const DataArrayInt *> idsPerType;//no profiles
4714 DataArrayInt *da=mesh->checkTypeConsistencyAndContig(code,idsPerType);
4718 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::CheckSBTMesh : underlying mesh is not sorted by type as MED file expects !");
4723 MEDFileField1TSWithoutSDA *MEDFileField1TSWithoutSDA::New(const std::string& fieldName, int csit, int iteration, int order, const std::vector<std::string>& infos)
4725 return new MEDFileField1TSWithoutSDA(fieldName,csit,iteration,order,infos);
4729 * Returns all attributes and values of parts of \a this field lying on a given mesh.
4730 * Each part differs from other ones by a type of supporting mesh entity. The _i_-th
4731 * item of every of returned sequences refers to the _i_-th part of \a this field.
4732 * Thus all sequences returned by this method are of the same length equal to number
4733 * of different types of supporting entities.<br>
4734 * A field part can include sub-parts with several different spatial discretizations,
4735 * \ref ParaMEDMEM::ON_CELLS "ON_CELLS" and \ref ParaMEDMEM::ON_GAUSS_PT "ON_GAUSS_PT"
4736 * for example. Hence, some of the returned sequences contains nested sequences, and an item
4737 * of a nested sequence corresponds to a type of spatial discretization.<br>
4738 * This method allows for iteration over MEDFile DataStructure with a reduced overhead.
4739 * The overhead is due to selecting values into new instances of DataArrayDouble.
4740 * \param [in] mname - a name of a mesh of interest. It can be \c NULL, which is valid
4741 * for the case with only one underlying mesh. (Actually, the number of meshes is
4742 * not checked if \a mname == \c NULL).
4743 * \param [in,out] types - a sequence of types of underlying mesh entities. A type per
4744 * a field part is returned.
4745 * \param [in,out] typesF - a sequence of sequences of types of spatial discretizations.
4746 * A field part can include sub-parts with several different spatial discretizations,
4747 * \ref ParaMEDMEM::ON_CELLS "ON_CELLS" and
4748 * \ref ParaMEDMEM::ON_GAUSS_PT "ON_GAUSS_PT" for example.
4749 * This sequence is of the same length as \a types.
4750 * \param [in,out] pfls - a sequence returning a profile name per each type of spatial
4751 * discretization. A profile name can be empty.
4752 * Length of this and of nested sequences is the same as that of \a typesF.
4753 * \param [in,out] locs - a sequence returning a localization name per each type of spatial
4754 * discretization. A localization name can be empty.
4755 * Length of this and of nested sequences is the same as that of \a typesF.
4756 * \return std::vector< std::vector<DataArrayDouble *> > - a sequence holding arrays of values
4757 * per each type of spatial discretization within one mesh entity type.
4758 * The caller is to delete each DataArrayDouble using decrRef() as it is no more needed.
4759 * Length of this and of nested sequences is the same as that of \a typesF.
4760 * \throw If no field is lying on \a mname.
4762 std::vector< std::vector<DataArrayDouble *> > MEDFileField1TSWithoutSDA::getFieldSplitedByType2(const std::string& mname, std::vector<INTERP_KERNEL::NormalizedCellType>& types, std::vector< std::vector<TypeOfField> >& typesF, std::vector< std::vector<std::string> >& pfls, std::vector< std::vector<std::string> >& locs) const
4766 meshId=getMeshIdFromMeshName(mname);
4768 if(_field_per_mesh.empty())
4769 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getFieldSplitedByType : This is empty !");
4770 std::vector< std::vector< std::pair<int,int> > > ret0=_field_per_mesh[meshId]->getFieldSplitedByType(types,typesF,pfls,locs);
4771 int nbOfRet=ret0.size();
4772 std::vector< std::vector<DataArrayDouble *> > ret(nbOfRet);
4773 for(int i=0;i<nbOfRet;i++)
4775 const std::vector< std::pair<int,int> >& p=ret0[i];
4776 int nbOfRet1=p.size();
4777 ret[i].resize(nbOfRet1);
4778 for(int j=0;j<nbOfRet1;j++)
4780 DataArrayDouble *tmp=_arr->selectByTupleId2(p[j].first,p[j].second,1);
4788 * Returns a pointer to the underground DataArrayDouble instance. So the
4789 * caller should not decrRef() it. This method allows for a direct access to the field
4790 * values. This method is quite unusable if there is more than a nodal field or a cell
4791 * field on single geometric cell type.
4792 * \return DataArrayDouble * - the pointer to the field values array.
4794 DataArrayDouble *MEDFileField1TSWithoutSDA::getUndergroundDataArrayDouble() const
4796 const DataArrayDouble *ret=_arr;
4798 return const_cast<DataArrayDouble *>(ret);
4803 const char *MEDFileField1TSWithoutSDA::getTypeStr() const
4808 MEDFileIntField1TSWithoutSDA *MEDFileField1TSWithoutSDA::convertToInt() const
4810 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TSWithoutSDA> ret(new MEDFileIntField1TSWithoutSDA);
4811 ret->MEDFileAnyTypeField1TSWithoutSDA::operator =(*this);
4812 ret->deepCpyLeavesFrom(*this);
4813 const DataArrayDouble *arr(_arr);
4816 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr2(arr->convertToIntArr());
4817 ret->setArray(arr2);
4823 * Returns a pointer to the underground DataArrayDouble instance. So the
4824 * caller should not decrRef() it. This method allows for a direct access to the field
4825 * values. This method is quite unusable if there is more than a nodal field or a cell
4826 * field on single geometric cell type.
4827 * \return DataArrayDouble * - the pointer to the field values array.
4829 DataArray *MEDFileField1TSWithoutSDA::getUndergroundDataArray() const
4831 return getUndergroundDataArrayDouble();
4835 * Returns a pointer to the underground DataArrayDouble instance and a
4836 * sequence describing parameters of a support of each part of \a this field. The
4837 * caller should not decrRef() the returned DataArrayDouble. This method allows for a
4838 * direct access to the field values. This method is intended for the field lying on one
4840 * \param [in,out] entries - the sequence describing parameters of a support of each
4841 * part of \a this field. Each item of this sequence consists of two parts. The
4842 * first part describes a type of mesh entity and an id of discretization of a
4843 * current field part. The second part describes a range of values [begin,end)
4844 * within the returned array relating to the current field part.
4845 * \return DataArrayDouble * - the pointer to the field values array.
4846 * \throw If the number of underlying meshes is not equal to 1.
4847 * \throw If no field values are available.
4848 * \sa getUndergroundDataArray()
4850 DataArrayDouble *MEDFileField1TSWithoutSDA::getUndergroundDataArrayDoubleExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
4852 if(_field_per_mesh.size()!=1)
4853 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt : field lies on several meshes, this method has no sense !");
4854 if(_field_per_mesh[0]==0)
4855 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt : no field specified !");
4856 _field_per_mesh[0]->getUndergroundDataArrayExt(entries);
4857 return getUndergroundDataArrayDouble();
4861 * Returns a pointer to the underground DataArrayDouble instance and a
4862 * sequence describing parameters of a support of each part of \a this field. The
4863 * caller should not decrRef() the returned DataArrayDouble. This method allows for a
4864 * direct access to the field values. This method is intended for the field lying on one
4866 * \param [in,out] entries - the sequence describing parameters of a support of each
4867 * part of \a this field. Each item of this sequence consists of two parts. The
4868 * first part describes a type of mesh entity and an id of discretization of a
4869 * current field part. The second part describes a range of values [begin,end)
4870 * within the returned array relating to the current field part.
4871 * \return DataArrayDouble * - the pointer to the field values array.
4872 * \throw If the number of underlying meshes is not equal to 1.
4873 * \throw If no field values are available.
4874 * \sa getUndergroundDataArray()
4876 DataArray *MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
4878 return getUndergroundDataArrayDoubleExt(entries);
4881 MEDFileField1TSWithoutSDA::MEDFileField1TSWithoutSDA(const std::string& fieldName, int csit, int iteration, int order,
4882 const std::vector<std::string>& infos):MEDFileAnyTypeField1TSWithoutSDA(fieldName,csit,iteration,order)
4884 DataArrayDouble *arr=getOrCreateAndGetArrayDouble();
4885 arr->setInfoAndChangeNbOfCompo(infos);
4888 MEDFileField1TSWithoutSDA::MEDFileField1TSWithoutSDA():MEDFileAnyTypeField1TSWithoutSDA()
4892 MEDFileAnyTypeField1TSWithoutSDA *MEDFileField1TSWithoutSDA::shallowCpy() const
4894 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TSWithoutSDA> ret(new MEDFileField1TSWithoutSDA(*this));
4895 ret->deepCpyLeavesFrom(*this);
4899 MEDFileAnyTypeField1TSWithoutSDA *MEDFileField1TSWithoutSDA::deepCpy() const
4901 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TSWithoutSDA> ret=static_cast<MEDFileField1TSWithoutSDA *>(shallowCpy());
4902 if((const DataArrayDouble *)_arr)
4903 ret->_arr=_arr->deepCpy();
4907 void MEDFileField1TSWithoutSDA::setArray(DataArray *arr)
4911 _nb_of_tuples_to_be_allocated=-1;
4915 DataArrayDouble *arrC=dynamic_cast<DataArrayDouble *>(arr);
4917 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::setArray : the input not null array is not of type DataArrayDouble !");
4919 _nb_of_tuples_to_be_allocated=-3;
4924 DataArray *MEDFileField1TSWithoutSDA::createNewEmptyDataArrayInstance() const
4926 return DataArrayDouble::New();
4929 DataArrayDouble *MEDFileField1TSWithoutSDA::getOrCreateAndGetArrayDouble()
4931 DataArrayDouble *ret=_arr;
4934 _arr=DataArrayDouble::New();
4938 DataArray *MEDFileField1TSWithoutSDA::getOrCreateAndGetArray()
4940 return getOrCreateAndGetArrayDouble();
4943 const DataArrayDouble *MEDFileField1TSWithoutSDA::getOrCreateAndGetArrayDouble() const
4945 const DataArrayDouble *ret=_arr;
4948 DataArrayDouble *ret2=DataArrayDouble::New();
4949 const_cast<MEDFileField1TSWithoutSDA *>(this)->_arr=DataArrayDouble::New();
4953 const DataArray *MEDFileField1TSWithoutSDA::getOrCreateAndGetArray() const
4955 return getOrCreateAndGetArrayDouble();
4958 //= MEDFileIntField1TSWithoutSDA
4960 MEDFileIntField1TSWithoutSDA *MEDFileIntField1TSWithoutSDA::New(const std::string& fieldName, int csit, int iteration, int order,
4961 const std::vector<std::string>& infos)
4963 return new MEDFileIntField1TSWithoutSDA(fieldName,csit,iteration,order,infos);
4966 MEDFileIntField1TSWithoutSDA::MEDFileIntField1TSWithoutSDA():MEDFileAnyTypeField1TSWithoutSDA()
4970 MEDFileIntField1TSWithoutSDA::MEDFileIntField1TSWithoutSDA(const std::string& fieldName, int csit, int iteration, int order,
4971 const std::vector<std::string>& infos):MEDFileAnyTypeField1TSWithoutSDA(fieldName,csit,iteration,order)
4973 DataArrayInt *arr=getOrCreateAndGetArrayInt();
4974 arr->setInfoAndChangeNbOfCompo(infos);
4977 const char *MEDFileIntField1TSWithoutSDA::getTypeStr() const
4982 MEDFileField1TSWithoutSDA *MEDFileIntField1TSWithoutSDA::convertToDouble() const
4984 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TSWithoutSDA> ret(new MEDFileField1TSWithoutSDA);
4985 ret->MEDFileAnyTypeField1TSWithoutSDA::operator =(*this);
4986 ret->deepCpyLeavesFrom(*this);
4987 const DataArrayInt *arr(_arr);
4990 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arr2(arr->convertToDblArr());
4991 ret->setArray(arr2);
4997 * Returns a pointer to the underground DataArrayInt instance. So the
4998 * caller should not decrRef() it. This method allows for a direct access to the field
4999 * values. This method is quite unusable if there is more than a nodal field or a cell
5000 * field on single geometric cell type.
5001 * \return DataArrayInt * - the pointer to the field values array.
5003 DataArray *MEDFileIntField1TSWithoutSDA::getUndergroundDataArray() const
5005 return getUndergroundDataArrayInt();
5009 * Returns a pointer to the underground DataArrayInt instance. So the
5010 * caller should not decrRef() it. This method allows for a direct access to the field
5011 * values. This method is quite unusable if there is more than a nodal field or a cell
5012 * field on single geometric cell type.
5013 * \return DataArrayInt * - the pointer to the field values array.
5015 DataArrayInt *MEDFileIntField1TSWithoutSDA::getUndergroundDataArrayInt() const
5017 const DataArrayInt *ret=_arr;
5019 return const_cast<DataArrayInt *>(ret);
5025 * Returns a pointer to the underground DataArrayInt instance and a
5026 * sequence describing parameters of a support of each part of \a this field. The
5027 * caller should not decrRef() the returned DataArrayInt. This method allows for a
5028 * direct access to the field values. This method is intended for the field lying on one
5030 * \param [in,out] entries - the sequence describing parameters of a support of each
5031 * part of \a this field. Each item of this sequence consists of two parts. The
5032 * first part describes a type of mesh entity and an id of discretization of a
5033 * current field part. The second part describes a range of values [begin,end)
5034 * within the returned array relating to the current field part.
5035 * \return DataArrayInt * - the pointer to the field values array.
5036 * \throw If the number of underlying meshes is not equal to 1.
5037 * \throw If no field values are available.
5038 * \sa getUndergroundDataArray()
5040 DataArray *MEDFileIntField1TSWithoutSDA::getUndergroundDataArrayExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
5042 return getUndergroundDataArrayIntExt(entries);
5046 * Returns a pointer to the underground DataArrayInt instance and a
5047 * sequence describing parameters of a support of each part of \a this field. The
5048 * caller should not decrRef() the returned DataArrayInt. This method allows for a
5049 * direct access to the field values. This method is intended for the field lying on one
5051 * \param [in,out] entries - the sequence describing parameters of a support of each
5052 * part of \a this field. Each item of this sequence consists of two parts. The
5053 * first part describes a type of mesh entity and an id of discretization of a
5054 * current field part. The second part describes a range of values [begin,end)
5055 * within the returned array relating to the current field part.
5056 * \return DataArrayInt * - the pointer to the field values array.
5057 * \throw If the number of underlying meshes is not equal to 1.
5058 * \throw If no field values are available.
5059 * \sa getUndergroundDataArray()
5061 DataArrayInt *MEDFileIntField1TSWithoutSDA::getUndergroundDataArrayIntExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
5063 if(_field_per_mesh.size()!=1)
5064 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt : field lies on several meshes, this method has no sense !");
5065 if(_field_per_mesh[0]==0)
5066 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt : no field specified !");
5067 _field_per_mesh[0]->getUndergroundDataArrayExt(entries);
5068 return getUndergroundDataArrayInt();
5071 MEDFileAnyTypeField1TSWithoutSDA *MEDFileIntField1TSWithoutSDA::shallowCpy() const
5073 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TSWithoutSDA> ret(new MEDFileIntField1TSWithoutSDA(*this));
5074 ret->deepCpyLeavesFrom(*this);
5078 MEDFileAnyTypeField1TSWithoutSDA *MEDFileIntField1TSWithoutSDA::deepCpy() const
5080 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TSWithoutSDA> ret=static_cast<MEDFileIntField1TSWithoutSDA *>(shallowCpy());
5081 if((const DataArrayInt *)_arr)
5082 ret->_arr=_arr->deepCpy();
5086 void MEDFileIntField1TSWithoutSDA::setArray(DataArray *arr)
5090 _nb_of_tuples_to_be_allocated=-1;
5094 DataArrayInt *arrC=dynamic_cast<DataArrayInt *>(arr);
5096 throw INTERP_KERNEL::Exception("MEDFileIntField1TSWithoutSDA::setArray : the input not null array is not of type DataArrayInt !");
5098 _nb_of_tuples_to_be_allocated=-3;
5103 DataArray *MEDFileIntField1TSWithoutSDA::createNewEmptyDataArrayInstance() const
5105 return DataArrayInt::New();
5108 DataArrayInt *MEDFileIntField1TSWithoutSDA::getOrCreateAndGetArrayInt()
5110 DataArrayInt *ret=_arr;
5113 _arr=DataArrayInt::New();
5117 DataArray *MEDFileIntField1TSWithoutSDA::getOrCreateAndGetArray()
5119 return getOrCreateAndGetArrayInt();
5122 const DataArrayInt *MEDFileIntField1TSWithoutSDA::getOrCreateAndGetArrayInt() const
5124 const DataArrayInt *ret=_arr;
5127 DataArrayInt *ret2=DataArrayInt::New();
5128 const_cast<MEDFileIntField1TSWithoutSDA *>(this)->_arr=DataArrayInt::New();
5132 const DataArray *MEDFileIntField1TSWithoutSDA::getOrCreateAndGetArray() const
5134 return getOrCreateAndGetArrayInt();
5137 MEDFileAnyTypeField1TS::MEDFileAnyTypeField1TS()
5141 //= MEDFileAnyTypeField1TS
5143 MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeField1TS::BuildContentFrom(med_idt fid, const std::string& fileName, bool loadAll)
5145 med_field_type typcha;
5147 std::vector<std::string> infos;
5148 std::string dtunit,fieldName;
5149 LocateField2(fid,fileName,0,true,fieldName,typcha,infos,dtunit);
5150 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> ret;
5155 ret=MEDFileField1TSWithoutSDA::New(fieldName.c_str(),-1,-1/*iteration*/,-1/*order*/,std::vector<std::string>());
5160 ret=MEDFileIntField1TSWithoutSDA::New(fieldName.c_str(),-1,-1/*iteration*/,-1/*order*/,std::vector<std::string>());
5165 std::ostringstream oss; oss << "MEDFileAnyTypeField1TS::BuildContentFrom(fileName) : file \'" << fileName << "\' contains field with name \'" << fieldName << "\' but the type of the first field is not in [MED_FLOAT64, MED_INT32] !";
5166 throw INTERP_KERNEL::Exception(oss.str().c_str());
5169 ret->setDtUnit(dtunit.c_str());
5170 ret->getOrCreateAndGetArray()->setInfoAndChangeNbOfCompo(infos);
5172 med_int numdt,numit;
5174 MEDfieldComputingStepInfo(fid,fieldName.c_str(),1,&numdt,&numit,&dt);
5175 ret->setTime(numdt,numit,dt);
5178 ret->loadStructureAndBigArraysRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret));
5180 ret->loadOnlyStructureOfDataRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret));
5184 MEDFileAnyTypeField1TS::MEDFileAnyTypeField1TS(const std::string& fileName, bool loadAll)
5185 try:MEDFileFieldGlobsReal(fileName)
5187 MEDFileUtilities::CheckFileForRead(fileName);
5188 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5189 _content=BuildContentFrom(fid,fileName,loadAll);
5192 catch(INTERP_KERNEL::Exception& e)
5197 MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeField1TS::BuildContentFrom(med_idt fid, const std::string& fileName, const std::string& fieldName, bool loadAll)
5199 med_field_type typcha;
5200 std::vector<std::string> infos;
5203 int nbSteps=LocateField(fid,fileName,fieldName,iii,typcha,infos,dtunit);
5204 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> ret;
5209 ret=MEDFileField1TSWithoutSDA::New(fieldName,-1,-1/*iteration*/,-1/*order*/,std::vector<std::string>());
5214 ret=MEDFileIntField1TSWithoutSDA::New(fieldName,-1,-1/*iteration*/,-1/*order*/,std::vector<std::string>());
5219 std::ostringstream oss; oss << "MEDFileAnyTypeField1TS::BuildContentFrom(fileName,fieldName) : file \'" << fileName << "\' contains field with name \'" << fieldName << "\' but the type of field is not in [MED_FLOAT64, MED_INT32] !";
5220 throw INTERP_KERNEL::Exception(oss.str().c_str());
5223 ret->setDtUnit(dtunit.c_str());
5224 ret->getOrCreateAndGetArray()->setInfoAndChangeNbOfCompo(infos);
5228 std::ostringstream oss; oss << "MEDFileField1TS(fileName,fieldName) : file \'" << fileName << "\' contains field with name \'" << fieldName << "\' but there is no time steps on it !";
5229 throw INTERP_KERNEL::Exception(oss.str().c_str());
5232 med_int numdt,numit;
5234 MEDfieldComputingStepInfo(fid,fieldName.c_str(),1,&numdt,&numit,&dt);
5235 ret->setTime(numdt,numit,dt);
5238 ret->loadStructureAndBigArraysRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret));
5240 ret->loadOnlyStructureOfDataRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret));
5244 MEDFileAnyTypeField1TS::MEDFileAnyTypeField1TS(const std::string& fileName, const std::string& fieldName, bool loadAll)
5245 try:MEDFileFieldGlobsReal(fileName)
5247 MEDFileUtilities::CheckFileForRead(fileName);
5248 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5249 _content=BuildContentFrom(fid,fileName,fieldName,loadAll);
5252 catch(INTERP_KERNEL::Exception& e)
5257 MEDFileAnyTypeField1TS *MEDFileAnyTypeField1TS::BuildNewInstanceFromContent(MEDFileAnyTypeField1TSWithoutSDA *c, const std::string& fileName)
5260 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS::BuildNewInstanceFromContent : empty content in input : unable to build a new instance !");
5261 if(dynamic_cast<const MEDFileField1TSWithoutSDA *>(c))
5263 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret=MEDFileField1TS::New();
5264 ret->setFileName(fileName);
5265 ret->_content=c; c->incrRef();
5268 if(dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(c))
5270 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret=MEDFileIntField1TS::New();
5271 ret->setFileName(fileName);
5272 ret->_content=c; c->incrRef();
5275 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS::BuildNewInstanceFromContent : internal error ! a content of type different from FLOAT64 and INT32 has been built but not intercepted !");
5278 MEDFileAnyTypeField1TS *MEDFileAnyTypeField1TS::New(const std::string& fileName, bool loadAll)
5280 MEDFileUtilities::CheckFileForRead(fileName);
5281 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5282 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> c=BuildContentFrom(fid,fileName,loadAll);
5283 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> ret=BuildNewInstanceFromContent(c,fileName);
5284 ret->loadGlobals(fid);
5288 MEDFileAnyTypeField1TS *MEDFileAnyTypeField1TS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
5290 MEDFileUtilities::CheckFileForRead(fileName);
5291 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5292 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> c=BuildContentFrom(fid,fileName,fieldName,loadAll);
5293 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> ret=BuildNewInstanceFromContent(c,fileName);
5294 ret->loadGlobals(fid);
5298 MEDFileAnyTypeField1TS *MEDFileAnyTypeField1TS::New(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll)
5300 MEDFileUtilities::CheckFileForRead(fileName);
5301 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5302 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> c=BuildContentFrom(fid,fileName,fieldName,iteration,order,loadAll);
5303 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> ret=BuildNewInstanceFromContent(c,fileName);
5304 ret->loadGlobals(fid);
5308 MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeField1TS::BuildContentFrom(med_idt fid, const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll)
5310 med_field_type typcha;
5311 std::vector<std::string> infos;
5314 int nbOfStep2=LocateField(fid,fileName,fieldName,iii,typcha,infos,dtunit);
5315 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> ret;
5320 ret=MEDFileField1TSWithoutSDA::New(fieldName,-1,iteration,order,std::vector<std::string>());
5325 ret=MEDFileIntField1TSWithoutSDA::New(fieldName,-1,iteration,order,std::vector<std::string>());
5330 std::ostringstream oss; oss << "MEDFileAnyTypeField1TS::BuildContentFrom(fileName,fieldName,iteration,order) : file \'" << fileName << "\' contains field with name \'" << fieldName << "\' but the type of field is not in [MED_FLOAT64, MED_INT32] !";
5331 throw INTERP_KERNEL::Exception(oss.str().c_str());
5334 ret->setDtUnit(dtunit.c_str());
5335 ret->getOrCreateAndGetArray()->setInfoAndChangeNbOfCompo(infos);
5338 std::vector< std::pair<int,int> > dtits(nbOfStep2);
5339 for(int i=0;i<nbOfStep2 && !found;i++)
5341 med_int numdt,numit;
5343 MEDfieldComputingStepInfo(fid,fieldName.c_str(),i+1,&numdt,&numit,&dt);
5344 if(numdt==iteration && numit==order)
5350 dtits[i]=std::pair<int,int>(numdt,numit);
5354 std::ostringstream oss; oss << "No such iteration (" << iteration << "," << order << ") in existing field '" << fieldName << "' in file '" << fileName << "' ! Available iterations are : ";
5355 for(std::vector< std::pair<int,int> >::const_iterator iter=dtits.begin();iter!=dtits.end();iter++)
5356 oss << "(" << (*iter).first << "," << (*iter).second << "), ";
5357 throw INTERP_KERNEL::Exception(oss.str().c_str());
5360 ret->loadStructureAndBigArraysRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret));
5362 ret->loadOnlyStructureOfDataRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret));
5366 MEDFileAnyTypeField1TS::MEDFileAnyTypeField1TS(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll)
5367 try:MEDFileFieldGlobsReal(fileName)
5369 MEDFileUtilities::CheckFileForRead(fileName);
5370 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5371 _content=BuildContentFrom(fid,fileName.c_str(),fieldName.c_str(),iteration,order,loadAll);
5374 catch(INTERP_KERNEL::Exception& e)
5380 * This constructor is a shallow copy constructor. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
5381 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
5383 * \warning this is a shallow copy constructor
5385 MEDFileAnyTypeField1TS::MEDFileAnyTypeField1TS(const MEDFileAnyTypeField1TSWithoutSDA& other, bool shallowCopyOfContent)
5387 if(!shallowCopyOfContent)
5389 const MEDFileAnyTypeField1TSWithoutSDA *otherPtr(&other);
5390 otherPtr->incrRef();
5391 _content=const_cast<MEDFileAnyTypeField1TSWithoutSDA *>(otherPtr);
5395 _content=other.shallowCpy();
5399 int MEDFileAnyTypeField1TS::LocateField2(med_idt fid, const std::string& fileName, int fieldIdCFormat, bool checkFieldId, std::string& fieldName, med_field_type& typcha, std::vector<std::string>& infos, std::string& dtunitOut)
5403 int nbFields=MEDnField(fid);
5404 if(fieldIdCFormat>=nbFields)
5406 std::ostringstream oss; oss << "MEDFileAnyTypeField1TS::LocateField2(fileName) : in file \'" << fileName << "\' number of fields is " << nbFields << " ! Trying to request for id " << fieldIdCFormat << " !";
5407 throw INTERP_KERNEL::Exception(oss.str().c_str());
5410 int ncomp=MEDfieldnComponent(fid,fieldIdCFormat+1);
5411 INTERP_KERNEL::AutoPtr<char> comp=MEDLoaderBase::buildEmptyString(ncomp*MED_SNAME_SIZE);
5412 INTERP_KERNEL::AutoPtr<char> unit=MEDLoaderBase::buildEmptyString(ncomp*MED_SNAME_SIZE);
5413 INTERP_KERNEL::AutoPtr<char> dtunit=MEDLoaderBase::buildEmptyString(MED_LNAME_SIZE);
5414 INTERP_KERNEL::AutoPtr<char> nomcha=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
5415 INTERP_KERNEL::AutoPtr<char> nomMaa=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
5418 MEDfieldInfo(fid,fieldIdCFormat+1,nomcha,nomMaa,&localMesh,&typcha,comp,unit,dtunit,&nbOfStep);
5419 fieldName=MEDLoaderBase::buildStringFromFortran(nomcha,MED_NAME_SIZE);
5420 dtunitOut=MEDLoaderBase::buildStringFromFortran(dtunit,MED_LNAME_SIZE);
5421 infos.clear(); infos.resize(ncomp);
5422 for(int j=0;j<ncomp;j++)
5423 infos[j]=MEDLoaderBase::buildUnionUnit((char *)comp+j*MED_SNAME_SIZE,MED_SNAME_SIZE,(char *)unit+j*MED_SNAME_SIZE,MED_SNAME_SIZE);
5428 * This method throws an INTERP_KERNEL::Exception if \a fieldName field is not in file pointed by \a fid and with name \a fileName.
5431 * \return in case of success the number of time steps available for the field with name \a fieldName.
5433 int MEDFileAnyTypeField1TS::LocateField(med_idt fid, const std::string& fileName, const std::string& fieldName, int& posCFormat, med_field_type& typcha, std::vector<std::string>& infos, std::string& dtunitOut)
5435 int nbFields=MEDnField(fid);
5437 std::vector<std::string> fns(nbFields);
5439 for(int i=0;i<nbFields && !found;i++)
5442 nbOfStep2=LocateField2(fid,fileName,i,false,tmp,typcha,infos,dtunitOut);
5444 found=(tmp==fieldName);
5450 std::ostringstream oss; oss << "No such field '" << fieldName << "' in file '" << fileName << "' ! Available fields are : ";
5451 for(std::vector<std::string>::const_iterator it=fns.begin();it!=fns.end();it++)
5452 oss << "\"" << *it << "\" ";
5453 throw INTERP_KERNEL::Exception(oss.str().c_str());
5459 * This method as MEDFileField1TSW::setLocNameOnLeaf, is dedicated for advanced user that a want a very fine control on their data structure
5460 * without overhead. This method can be called only regarding information returned by MEDFileField1TSWithoutSDA::getFieldSplitedByType or MEDFileField1TSWithoutSDA::getFieldSplitedByType2.
5461 * This method changes the attribute (here it's profile name) of the leaf datastructure (MEDFileFieldPerMeshPerTypePerDisc instance).
5462 * It is the responsability of the caller to invoke MEDFileFieldGlobs::appendProfile or MEDFileFieldGlobs::getProfile
5463 * to keep a valid instance.
5464 * If \b this do not have any leaf that correspond to the request of the input parameter (\b mName, \b typ, \b locId) an INTERP_KERNEL::Exception will be thrown.
5465 * If \b newPflName profile name does not already exist the profile with old name will be renamed with name \b newPflName.
5466 * If \b newPflName already exists and that \b forceRenameOnGlob is false (the default) an INTERP_KERNEL::Exception will be thrown to avoid big confusion. In this case the called should rename before the profile name with name \b newPflName.
5468 * \param [in] mName specifies the underlying mesh name. This value can be pointer 0 for users that do not deal with fields on multi mesh.
5469 * \param [in] typ is for the geometric cell type (or INTERP_KERNEL::NORM_ERROR for node field) entry to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set.
5470 * \param [in] locId is the localization id to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set. It corresponds to the position of
5471 * \c pfls[std::distance(types.begin(),std::find(types.begin(),typ)] vector in MEDFileField1TSWithoutSDA::getFieldSplitedByType. For non gausspoints field users, the value is 0.
5472 * \param [in] newLocName is the new localization name.
5473 * \param [in] forceRenameOnGlob specifies the behaviour in case of profile \b newPflName already exists. If true, the renaming is done without check. It can lead to major bug.
5474 * If false, an exception will be thrown to force user to change previously the name of the profile with name \b newPflName
5476 void MEDFileAnyTypeField1TS::setProfileNameOnLeaf(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId, const std::string& newPflName, bool forceRenameOnGlob)
5478 MEDFileFieldPerMeshPerTypePerDisc *disc=getLeafGivenMeshAndTypeAndLocId(mName,typ,locId);
5479 std::string oldPflName=disc->getProfile();
5480 std::vector<std::string> vv=getPflsReallyUsedMulti();
5481 int nbOfOcc=std::count(vv.begin(),vv.end(),oldPflName);
5482 if(forceRenameOnGlob || (!existsPfl(newPflName) && nbOfOcc==1))
5484 disc->setProfile(newPflName);
5485 DataArrayInt *pfl=getProfile(oldPflName.c_str());
5486 pfl->setName(newPflName);
5490 std::ostringstream oss; oss << "MEDFileField1TS::setProfileNameOnLeaf : Profile \"" << newPflName << "\" already exists or referenced more than one !";
5491 throw INTERP_KERNEL::Exception(oss.str().c_str());
5496 * This method as MEDFileField1TSW::setProfileNameOnLeaf, is dedicated for advanced user that a want a very fine control on their data structure
5497 * without overhead. This method can be called only regarding information returned by MEDFileField1TSWithoutSDA::getFieldSplitedByType or MEDFileField1TSWithoutSDA::getFieldSplitedByType2.
5498 * This method changes the attribute (here it's localization name) of the leaf datastructure (MEDFileFieldPerMeshPerTypePerDisc instance).
5499 * It is the responsability of the caller to invoke MEDFileFieldGlobs::appendProfile or MEDFileFieldGlobs::getProfile
5500 * to keep a valid instance.
5501 * If \b this do not have any leaf that correspond to the request of the input parameter (\b mName, \b typ, \b locId) an INTERP_KERNEL::Exception will be thrown.
5502 * This method is an extension of MEDFileField1TSWithoutSDA::setProfileNameOnLeafExt method because it performs a modification of global info.
5503 * If \b newLocName profile name does not already exist the localization with old name will be renamed with name \b newLocName.
5504 * If \b newLocName already exists an INTERP_KERNEL::Exception will be thrown to avoid big confusion. In this case the called should rename before the profile name with name \b newLocName.
5506 * \param [in] mName specifies the underlying mesh name. This value can be pointer 0 for users that do not deal with fields on multi mesh.
5507 * \param [in] typ is for the geometric cell type (or INTERP_KERNEL::NORM_ERROR for node field) entry to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set.
5508 * \param [in] locId is the localization id to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set. It corresponds to the position of
5509 * \c pfls[std::distance(types.begin(),std::find(types.begin(),typ)] vector in MEDFileField1TSWithoutSDA::getFieldSplitedByType. For non gausspoints field users, the value is 0.
5510 * \param [in] newLocName is the new localization name.
5511 * \param [in] forceRenameOnGlob specifies the behaviour in case of profile \b newLocName already exists. If true, the renaming is done without check. It can lead to major bug.
5512 * If false, an exception will be thrown to force user to change previously the name of the profile with name \b newLocName
5514 void MEDFileAnyTypeField1TS::setLocNameOnLeaf(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId, const std::string& newLocName, bool forceRenameOnGlob)
5516 MEDFileFieldPerMeshPerTypePerDisc *disc=getLeafGivenMeshAndTypeAndLocId(mName,typ,locId);
5517 std::string oldLocName=disc->getLocalization();
5518 std::vector<std::string> vv=getLocsReallyUsedMulti();
5519 int nbOfOcc=std::count(vv.begin(),vv.end(),oldLocName);
5520 if(forceRenameOnGlob || (!existsLoc(newLocName) && nbOfOcc==1))
5522 disc->setLocalization(newLocName);
5523 MEDFileFieldLoc& loc=getLocalization(oldLocName.c_str());
5524 loc.setName(newLocName);
5528 std::ostringstream oss; oss << "MEDFileField1TS::setLocNameOnLeaf : Localization \"" << newLocName << "\" already exists or referenced more than one !";
5529 throw INTERP_KERNEL::Exception(oss.str().c_str());
5533 MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeField1TS::contentNotNullBase()
5535 MEDFileAnyTypeField1TSWithoutSDA *ret=_content;
5537 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS : content is expected to be not null !");
5541 const MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeField1TS::contentNotNullBase() const
5543 const MEDFileAnyTypeField1TSWithoutSDA *ret=_content;
5545 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS : const content is expected to be not null !");
5550 * Writes \a this field into a MED file specified by its name.
5551 * \param [in] fileName - the MED file name.
5552 * \param [in] mode - the writing mode. For more on \a mode, see \ref AdvMEDLoaderBasics.
5553 * - 2 - erase; an existing file is removed.
5554 * - 1 - append; same data should not be present in an existing file.
5555 * - 0 - overwrite; same data present in an existing file is overwritten.
5556 * \throw If the field name is not set.
5557 * \throw If no field data is set.
5558 * \throw If \a mode == 1 and the same data is present in an existing file.
5560 void MEDFileAnyTypeField1TS::write(const std::string& fileName, int mode) const
5562 med_access_mode medmod=MEDFileUtilities::TraduceWriteMode(mode);
5563 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),medmod);
5568 * This method alloc the arrays and load potentially huge arrays contained in this field.
5569 * This method should be called when a MEDFileAnyTypeField1TS::New constructor has been with false as the last parameter.
5570 * This method can be also called to refresh or reinit values from a file.
5572 * \throw If the fileName is not set or points to a non readable MED file.
5573 * \sa MEDFileAnyTypeField1TS::loadArraysIfNecessary
5575 void MEDFileAnyTypeField1TS::loadArrays()
5577 if(getFileName().empty())
5578 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS::loadArrays : the structure does not come from a file !");
5579 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
5580 contentNotNullBase()->loadBigArraysRecursively(fid,*contentNotNullBase());
5584 * This method behaves as MEDFileAnyTypeField1TS::loadArrays does, the first call, if \a this was built using a file without loading big arrays.
5585 * But once data loaded once, this method does nothing. Contrary to MEDFileAnyTypeField1TS::loadArrays and MEDFileAnyTypeField1TS::unloadArrays
5586 * this method does not throw if \a this does not come from file read.
5588 * \sa MEDFileAnyTypeField1TS::loadArrays, MEDFileAnyTypeField1TS::unloadArrays
5590 void MEDFileAnyTypeField1TS::loadArraysIfNecessary()
5592 if(!getFileName().empty())
5594 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
5595 contentNotNullBase()->loadBigArraysRecursivelyIfNecessary(fid,*contentNotNullBase());
5600 * This method releases potentially big data arrays and so returns to the same heap memory than status loaded with 'loadAll' parameter set to false.
5601 * This method does not release arrays set outside the context of a MED file.
5603 * \sa MEDFileAnyTypeField1TS::loadArrays, MEDFileAnyTypeField1TS::loadArraysIfNecessary
5605 void MEDFileAnyTypeField1TS::unloadArrays()
5607 contentNotNullBase()->unloadArrays();
5610 void MEDFileAnyTypeField1TS::writeLL(med_idt fid) const
5612 int nbComp=getNumberOfComponents();
5613 INTERP_KERNEL::AutoPtr<char> comp=MEDLoaderBase::buildEmptyString(nbComp*MED_SNAME_SIZE);
5614 INTERP_KERNEL::AutoPtr<char> unit=MEDLoaderBase::buildEmptyString(nbComp*MED_SNAME_SIZE);
5615 for(int i=0;i<nbComp;i++)
5617 std::string info=getInfo()[i];
5619 MEDLoaderBase::splitIntoNameAndUnit(info,c,u);
5620 MEDLoaderBase::safeStrCpy2(c.c_str(),MED_SNAME_SIZE,comp+i*MED_SNAME_SIZE,_too_long_str);
5621 MEDLoaderBase::safeStrCpy2(u.c_str(),MED_SNAME_SIZE,unit+i*MED_SNAME_SIZE,_too_long_str);
5623 if(getName().empty())
5624 throw INTERP_KERNEL::Exception("MEDFileField1TS::write : MED file does not accept field with empty name !");
5625 MEDfieldCr(fid,getName().c_str(),getMEDFileFieldType(),nbComp,comp,unit,getDtUnit().c_str(),getMeshName().c_str());
5626 writeGlobals(fid,*this);
5627 contentNotNullBase()->writeLL(fid,*this,*contentNotNullBase());
5630 std::size_t MEDFileAnyTypeField1TS::getHeapMemorySizeWithoutChildren() const
5632 return MEDFileFieldGlobsReal::getHeapMemorySizeWithoutChildren();
5635 std::vector<const BigMemoryObject *> MEDFileAnyTypeField1TS::getDirectChildren() const
5637 std::vector<const BigMemoryObject *> ret(MEDFileFieldGlobsReal::getDirectChildren());
5638 if((const MEDFileAnyTypeField1TSWithoutSDA *)_content)
5639 ret.push_back((const MEDFileAnyTypeField1TSWithoutSDA *)_content);
5644 * Returns a string describing \a this field. This string is outputted
5645 * by \c print Python command.
5647 std::string MEDFileAnyTypeField1TS::simpleRepr() const
5649 std::ostringstream oss;
5650 contentNotNullBase()->simpleRepr(0,oss,-1);
5651 simpleReprGlobs(oss);
5656 * This method returns all profiles whose name is non empty used.
5657 * \b WARNING If profile is used several times it will be reported \b only \b once.
5658 * To get non empty name profiles as time as they appear in \b this call MEDFileField1TS::getPflsReallyUsedMulti instead.
5660 std::vector<std::string> MEDFileAnyTypeField1TS::getPflsReallyUsed() const
5662 return contentNotNullBase()->getPflsReallyUsed2();
5666 * This method returns all localizations whose name is non empty used.
5667 * \b WARNING If localization is used several times it will be reported \b only \b once.
5669 std::vector<std::string> MEDFileAnyTypeField1TS::getLocsReallyUsed() const
5671 return contentNotNullBase()->getLocsReallyUsed2();
5675 * This method returns all profiles whose name is non empty used.
5676 * \b WARNING contrary to MEDFileField1TS::getPflsReallyUsed, if profile is used several times it will be reported as time as it appears.
5678 std::vector<std::string> MEDFileAnyTypeField1TS::getPflsReallyUsedMulti() const
5680 return contentNotNullBase()->getPflsReallyUsedMulti2();
5684 * This method returns all localizations whose name is non empty used.
5685 * \b WARNING contrary to MEDFileField1TS::getLocsReallyUsed if localization is used several times it will be reported as time as it appears.
5687 std::vector<std::string> MEDFileAnyTypeField1TS::getLocsReallyUsedMulti() const
5689 return contentNotNullBase()->getLocsReallyUsedMulti2();
5692 void MEDFileAnyTypeField1TS::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
5694 contentNotNullBase()->changePflsRefsNamesGen2(mapOfModif);
5697 void MEDFileAnyTypeField1TS::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
5699 contentNotNullBase()->changeLocsRefsNamesGen2(mapOfModif);
5702 int MEDFileAnyTypeField1TS::getDimension() const
5704 return contentNotNullBase()->getDimension();
5707 int MEDFileAnyTypeField1TS::getIteration() const
5709 return contentNotNullBase()->getIteration();
5712 int MEDFileAnyTypeField1TS::getOrder() const
5714 return contentNotNullBase()->getOrder();
5717 double MEDFileAnyTypeField1TS::getTime(int& iteration, int& order) const
5719 return contentNotNullBase()->getTime(iteration,order);
5722 void MEDFileAnyTypeField1TS::setTime(int iteration, int order, double val)
5724 contentNotNullBase()->setTime(iteration,order,val);
5727 std::string MEDFileAnyTypeField1TS::getName() const
5729 return contentNotNullBase()->getName();
5732 void MEDFileAnyTypeField1TS::setName(const std::string& name)
5734 contentNotNullBase()->setName(name);
5737 void MEDFileAnyTypeField1TS::simpleRepr(int bkOffset, std::ostream& oss, int f1tsId) const
5739 contentNotNullBase()->simpleRepr(bkOffset,oss,f1tsId);
5742 std::string MEDFileAnyTypeField1TS::getDtUnit() const
5744 return contentNotNullBase()->getDtUnit();
5747 void MEDFileAnyTypeField1TS::setDtUnit(const std::string& dtUnit)
5749 contentNotNullBase()->setDtUnit(dtUnit);
5752 std::string MEDFileAnyTypeField1TS::getMeshName() const
5754 return contentNotNullBase()->getMeshName();
5757 void MEDFileAnyTypeField1TS::setMeshName(const std::string& newMeshName)
5759 contentNotNullBase()->setMeshName(newMeshName);
5762 bool MEDFileAnyTypeField1TS::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
5764 return contentNotNullBase()->changeMeshNames(modifTab);
5767 int MEDFileAnyTypeField1TS::getMeshIteration() const
5769 return contentNotNullBase()->getMeshIteration();
5772 int MEDFileAnyTypeField1TS::getMeshOrder() const
5774 return contentNotNullBase()->getMeshOrder();
5777 int MEDFileAnyTypeField1TS::getNumberOfComponents() const
5779 return contentNotNullBase()->getNumberOfComponents();
5782 bool MEDFileAnyTypeField1TS::isDealingTS(int iteration, int order) const
5784 return contentNotNullBase()->isDealingTS(iteration,order);
5787 std::pair<int,int> MEDFileAnyTypeField1TS::getDtIt() const
5789 return contentNotNullBase()->getDtIt();
5792 void MEDFileAnyTypeField1TS::fillIteration(std::pair<int,int>& p) const
5794 contentNotNullBase()->fillIteration(p);
5797 void MEDFileAnyTypeField1TS::fillTypesOfFieldAvailable(std::vector<TypeOfField>& types) const
5799 contentNotNullBase()->fillTypesOfFieldAvailable(types);
5802 void MEDFileAnyTypeField1TS::setInfo(const std::vector<std::string>& infos)
5804 contentNotNullBase()->setInfo(infos);
5807 const std::vector<std::string>& MEDFileAnyTypeField1TS::getInfo() const
5809 return contentNotNullBase()->getInfo();
5811 std::vector<std::string>& MEDFileAnyTypeField1TS::getInfo()
5813 return contentNotNullBase()->getInfo();
5816 MEDFileFieldPerMeshPerTypePerDisc *MEDFileAnyTypeField1TS::getLeafGivenMeshAndTypeAndLocId(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId)
5818 return contentNotNullBase()->getLeafGivenMeshAndTypeAndLocId(mName,typ,locId);
5821 const MEDFileFieldPerMeshPerTypePerDisc *MEDFileAnyTypeField1TS::getLeafGivenMeshAndTypeAndLocId(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId) const
5823 return contentNotNullBase()->getLeafGivenMeshAndTypeAndLocId(mName,typ,locId);
5826 int MEDFileAnyTypeField1TS::getNonEmptyLevels(const std::string& mname, std::vector<int>& levs) const
5828 return contentNotNullBase()->getNonEmptyLevels(mname,levs);
5831 std::vector<TypeOfField> MEDFileAnyTypeField1TS::getTypesOfFieldAvailable() const
5833 return contentNotNullBase()->getTypesOfFieldAvailable();
5836 std::vector< std::vector<std::pair<int,int> > > MEDFileAnyTypeField1TS::getFieldSplitedByType(const std::string& mname, std::vector<INTERP_KERNEL::NormalizedCellType>& types, std::vector< std::vector<TypeOfField> >& typesF,
5837 std::vector< std::vector<std::string> >& pfls, std::vector< std::vector<std::string> >& locs) const throw(INTERP_KERNEL::Exception)
5839 return contentNotNullBase()->getFieldSplitedByType(mname,types,typesF,pfls,locs);
5843 * This method returns as MEDFileAnyTypeField1TS new instances as number of components in \a this.
5844 * The returned instances are deep copy of \a this except that for globals that are share with those contained in \a this.
5845 * ** WARNING ** do no forget to rename the ouput instances to avoid to write n-times in the same MED file field !
5847 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TS > > MEDFileAnyTypeField1TS::splitComponents() const
5849 const MEDFileAnyTypeField1TSWithoutSDA *content(_content);
5851 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS::splitComponents : no content in this ! Unable to split components !");
5852 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > contentsSplit=content->splitComponents();
5853 std::size_t sz(contentsSplit.size());
5854 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TS > > ret(sz);
5855 for(std::size_t i=0;i<sz;i++)
5857 ret[i]=shallowCpy();
5858 ret[i]->_content=contentsSplit[i];
5864 * This method returns as MEDFileAnyTypeField1TS new instances as number of spatial discretizations in \a this.
5865 * The returned instances are deep copy of \a this except that for globals that are share with those contained in \a this.
5867 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TS > > MEDFileAnyTypeField1TS::splitDiscretizations() const
5869 const MEDFileAnyTypeField1TSWithoutSDA *content(_content);
5871 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS::splitDiscretizations : no content in this ! Unable to split discretization !");
5872 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > contentsSplit=content->splitDiscretizations();
5873 std::size_t sz(contentsSplit.size());
5874 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TS > > ret(sz);
5875 for(std::size_t i=0;i<sz;i++)
5877 ret[i]=shallowCpy();
5878 ret[i]->_content=contentsSplit[i];
5883 MEDFileAnyTypeField1TS *MEDFileAnyTypeField1TS::deepCpy() const
5885 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> ret=shallowCpy();
5886 if((const MEDFileAnyTypeField1TSWithoutSDA *)_content)
5887 ret->_content=_content->deepCpy();
5888 ret->deepCpyGlobs(*this);
5892 int MEDFileAnyTypeField1TS::copyTinyInfoFrom(const MEDCouplingFieldDouble *field, const DataArray *arr)
5894 return contentNotNullBase()->copyTinyInfoFrom(field,arr);
5900 * Returns a new instance of MEDFileField1TS holding data of the first time step of
5901 * the first field that has been read from a specified MED file.
5902 * \param [in] fileName - the name of the MED file to read.
5903 * \return MEDFileField1TS * - a new instance of MEDFileFieldMultiTS. The caller
5904 * is to delete this field using decrRef() as it is no more needed.
5905 * \throw If reading the file fails.
5907 MEDFileField1TS *MEDFileField1TS::New(const std::string& fileName, bool loadAll)
5909 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret=new MEDFileField1TS(fileName,loadAll);
5910 ret->contentNotNull();
5915 * Returns a new instance of MEDFileField1TS holding data of the first time step of
5916 * a given field that has been read from a specified MED file.
5917 * \param [in] fileName - the name of the MED file to read.
5918 * \param [in] fieldName - the name of the field to read.
5919 * \return MEDFileField1TS * - a new instance of MEDFileFieldMultiTS. The caller
5920 * is to delete this field using decrRef() as it is no more needed.
5921 * \throw If reading the file fails.
5922 * \throw If there is no field named \a fieldName in the file.
5924 MEDFileField1TS *MEDFileField1TS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
5926 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret=new MEDFileField1TS(fileName,fieldName,loadAll);
5927 ret->contentNotNull();
5932 * Returns a new instance of MEDFileField1TS holding data of a given time step of
5933 * a given field that has been read from a specified MED file.
5934 * \param [in] fileName - the name of the MED file to read.
5935 * \param [in] fieldName - the name of the field to read.
5936 * \param [in] iteration - the iteration number of a required time step.
5937 * \param [in] order - the iteration order number of required time step.
5938 * \return MEDFileField1TS * - a new instance of MEDFileFieldMultiTS. The caller
5939 * is to delete this field using decrRef() as it is no more needed.
5940 * \throw If reading the file fails.
5941 * \throw If there is no field named \a fieldName in the file.
5942 * \throw If the required time step is missing from the file.
5944 MEDFileField1TS *MEDFileField1TS::New(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll)
5946 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret=new MEDFileField1TS(fileName,fieldName,iteration,order,loadAll);
5947 ret->contentNotNull();
5952 * Returns a new instance of MEDFileField1TS. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
5953 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
5955 * Returns a new instance of MEDFileField1TS holding either a shallow copy
5956 * of a given MEDFileField1TSWithoutSDA ( \a other ) or \a other itself.
5957 * \warning this is a shallow copy constructor
5958 * \param [in] other - a MEDFileField1TSWithoutSDA to copy.
5959 * \param [in] shallowCopyOfContent - if \c true, a shallow copy of \a other is created.
5960 * \return MEDFileField1TS * - a new instance of MEDFileField1TS. The caller
5961 * is to delete this field using decrRef() as it is no more needed.
5963 MEDFileField1TS *MEDFileField1TS::New(const MEDFileField1TSWithoutSDA& other, bool shallowCopyOfContent)
5965 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret=new MEDFileField1TS(other,shallowCopyOfContent);
5966 ret->contentNotNull();
5971 * Returns a new empty instance of MEDFileField1TS.
5972 * \return MEDFileField1TS * - a new instance of MEDFileField1TS. The caller
5973 * is to delete this field using decrRef() as it is no more needed.
5975 MEDFileField1TS *MEDFileField1TS::New()
5977 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret=new MEDFileField1TS;
5978 ret->contentNotNull();
5983 * This method performs a copy with datatype modification ( float64->int32 ) of \a this. The globals information are copied
5984 * following the given input policy.
5986 * \param [in] isDeepCpyGlobs - a boolean that indicates the behaviour concerning globals (profiles and localizations)
5987 * By default (true) the globals are deeply copied.
5988 * \return MEDFileIntField1TS * - a new object that is the result of the conversion of \a this to int32 field.
5990 MEDFileIntField1TS *MEDFileField1TS::convertToInt(bool isDeepCpyGlobs) const
5992 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret;
5993 const MEDFileAnyTypeField1TSWithoutSDA *content(_content);
5996 const MEDFileField1TSWithoutSDA *contc=dynamic_cast<const MEDFileField1TSWithoutSDA *>(content);
5998 throw INTERP_KERNEL::Exception("MEDFileField1TS::convertToInt : the content inside this is not FLOAT64 ! This is incoherent !");
5999 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TSWithoutSDA> newc(contc->convertToInt());
6000 ret=static_cast<MEDFileIntField1TS *>(MEDFileAnyTypeField1TS::BuildNewInstanceFromContent((MEDFileIntField1TSWithoutSDA *)newc,getFileName()));
6003 ret=MEDFileIntField1TS::New();
6005 ret->deepCpyGlobs(*this);
6007 ret->shallowCpyGlobs(*this);
6011 const MEDFileField1TSWithoutSDA *MEDFileField1TS::contentNotNull() const
6013 const MEDFileAnyTypeField1TSWithoutSDA *pt(_content);
6015 throw INTERP_KERNEL::Exception("MEDFileField1TS::contentNotNull : the content pointer is null !");
6016 const MEDFileField1TSWithoutSDA *ret=dynamic_cast<const MEDFileField1TSWithoutSDA *>(pt);
6018 throw INTERP_KERNEL::Exception("MEDFileField1TS::contentNotNull : the content pointer is not null but it is not of type double ! Reason is maybe that the read field has not the type FLOAT64 !");
6022 MEDFileField1TSWithoutSDA *MEDFileField1TS::contentNotNull()
6024 MEDFileAnyTypeField1TSWithoutSDA *pt(_content);
6026 throw INTERP_KERNEL::Exception("MEDFileField1TS::contentNotNull : the non const content pointer is null !");
6027 MEDFileField1TSWithoutSDA *ret=dynamic_cast<MEDFileField1TSWithoutSDA *>(pt);
6029 throw INTERP_KERNEL::Exception("MEDFileField1TS::contentNotNull : the non const content pointer is not null but it is not of type double ! Reason is maybe that the read field has not the type FLOAT64 !");
6033 void MEDFileField1TS::SetDataArrayDoubleInField(MEDCouplingFieldDouble *f, MEDCouplingAutoRefCountObjectPtr<DataArray>& arr)
6036 throw INTERP_KERNEL::Exception("MEDFileField1TS::SetDataArrayDoubleInField : input field is NULL !");
6037 if(!((DataArray*)arr))
6038 throw INTERP_KERNEL::Exception("MEDFileField1TS::SetDataArrayDoubleInField : no array !");
6039 DataArrayDouble *arrOutC=dynamic_cast<DataArrayDouble *>((DataArray*)arr);
6041 throw INTERP_KERNEL::Exception("MEDFileField1TS::SetDataArrayDoubleInField : mismatch between dataArrays type and MEDFileField1TS ! Expected double !");
6042 f->setArray(arrOutC);
6045 DataArrayDouble *MEDFileField1TS::ReturnSafelyDataArrayDouble(MEDCouplingAutoRefCountObjectPtr<DataArray>& arr)
6047 if(!((DataArray*)arr))
6048 throw INTERP_KERNEL::Exception("MEDFileField1TS::ReturnSafelyDataArrayDouble : no array !");
6049 DataArrayDouble *arrOutC=dynamic_cast<DataArrayDouble *>((DataArray*)arr);
6051 throw INTERP_KERNEL::Exception("MEDFileField1TS::ReturnSafelyDataArrayDouble : mismatch between dataArrays type and MEDFileField1TS ! Expected double !");
6056 MEDFileField1TS::MEDFileField1TS(const std::string& fileName, bool loadAll)
6057 try:MEDFileAnyTypeField1TS(fileName,loadAll)
6060 catch(INTERP_KERNEL::Exception& e)
6063 MEDFileField1TS::MEDFileField1TS(const std::string& fileName, const std::string& fieldName, bool loadAll)
6064 try:MEDFileAnyTypeField1TS(fileName,fieldName,loadAll)
6067 catch(INTERP_KERNEL::Exception& e)
6070 MEDFileField1TS::MEDFileField1TS(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll)
6071 try:MEDFileAnyTypeField1TS(fileName,fieldName,iteration,order,loadAll)
6074 catch(INTERP_KERNEL::Exception& e)
6078 * This constructor is a shallow copy constructor. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
6079 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
6081 * \warning this is a shallow copy constructor
6083 MEDFileField1TS::MEDFileField1TS(const MEDFileField1TSWithoutSDA& other, bool shallowCopyOfContent)
6084 try:MEDFileAnyTypeField1TS(other,shallowCopyOfContent)
6087 catch(INTERP_KERNEL::Exception& e)
6090 MEDFileField1TS::MEDFileField1TS()
6092 _content=new MEDFileField1TSWithoutSDA;
6096 * Returns a new MEDCouplingFieldDouble of a given type lying on
6097 * mesh entities of a given dimension of the first mesh in MED file. If \a this field
6098 * has not been constructed via file reading, an exception is thrown.
6099 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6100 * \param [in] type - a spatial discretization of interest.
6101 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6102 * \param [in] renumPol - specifies how to permute values of the result field according to
6103 * the optional numbers of cells and nodes, if any. The valid values are
6104 * - 0 - do not permute.
6105 * - 1 - permute cells.
6106 * - 2 - permute nodes.
6107 * - 3 - permute cells and nodes.
6109 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6110 * caller is to delete this field using decrRef() as it is no more needed.
6111 * \throw If \a this field has not been constructed via file reading.
6112 * \throw If the MED file is not readable.
6113 * \throw If there is no mesh in the MED file.
6114 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
6115 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6116 * \sa getFieldOnMeshAtLevel()
6118 MEDCouplingFieldDouble *MEDFileField1TS::getFieldAtLevel(TypeOfField type, int meshDimRelToMax, int renumPol) const
6120 if(getFileName2().empty())
6121 throw INTERP_KERNEL::Exception("MEDFileField1TS::getFieldAtLevel : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtLevel method instead !");
6122 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
6123 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtLevel(type,meshDimRelToMax,std::string(),renumPol,this,arrOut,*contentNotNull());
6124 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
6129 * Returns a new MEDCouplingFieldDouble of a given type lying on
6130 * the top level cells of the first mesh in MED file. If \a this field
6131 * has not been constructed via file reading, an exception is thrown.
6132 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6133 * \param [in] type - a spatial discretization of interest.
6134 * \param [in] renumPol - specifies how to permute values of the result field according to
6135 * the optional numbers of cells and nodes, if any. The valid values are
6136 * - 0 - do not permute.
6137 * - 1 - permute cells.
6138 * - 2 - permute nodes.
6139 * - 3 - permute cells and nodes.
6141 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6142 * caller is to delete this field using decrRef() as it is no more needed.
6143 * \throw If \a this field has not been constructed via file reading.
6144 * \throw If the MED file is not readable.
6145 * \throw If there is no mesh in the MED file.
6146 * \throw If no field values of the given \a type.
6147 * \throw If no field values lying on the top level support.
6148 * \sa getFieldAtLevel()
6150 MEDCouplingFieldDouble *MEDFileField1TS::getFieldAtTopLevel(TypeOfField type, int renumPol) const
6152 if(getFileName2().empty())
6153 throw INTERP_KERNEL::Exception("MEDFileField1TS::getFieldAtTopLevel : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtTopLevel method instead !");
6154 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
6155 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtTopLevel(type,std::string(),renumPol,this,arrOut,*contentNotNull());
6156 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
6161 * Returns a new MEDCouplingFieldDouble of given type lying on a given mesh.
6162 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6163 * \param [in] type - a spatial discretization of the new field.
6164 * \param [in] mesh - the supporting mesh.
6165 * \param [in] renumPol - specifies how to permute values of the result field according to
6166 * the optional numbers of cells and nodes, if any. The valid values are
6167 * - 0 - do not permute.
6168 * - 1 - permute cells.
6169 * - 2 - permute nodes.
6170 * - 3 - permute cells and nodes.
6172 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6173 * caller is to delete this field using decrRef() as it is no more needed.
6174 * \throw If no field of \a this is lying on \a mesh.
6175 * \throw If the mesh is empty.
6176 * \throw If no field values of the given \a type are available.
6177 * \sa getFieldAtLevel()
6178 * \sa getFieldOnMeshAtLevel()
6180 MEDCouplingFieldDouble *MEDFileField1TS::getFieldOnMeshAtLevel(TypeOfField type, const MEDCouplingMesh *mesh, int renumPol) const
6182 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
6183 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldOnMeshAtLevel(type,renumPol,this,mesh,0,0,arrOut,*contentNotNull());
6184 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
6189 * Returns a new MEDCouplingFieldDouble of a given type lying on a given support.
6190 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6191 * \param [in] type - a spatial discretization of interest.
6192 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6193 * \param [in] mesh - the supporting mesh.
6194 * \param [in] renumPol - specifies how to permute values of the result field according to
6195 * the optional numbers of cells and nodes, if any. The valid values are
6196 * - 0 - do not permute.
6197 * - 1 - permute cells.
6198 * - 2 - permute nodes.
6199 * - 3 - permute cells and nodes.
6201 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6202 * caller is to delete this field using decrRef() as it is no more needed.
6203 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
6204 * \throw If no field of \a this is lying on \a mesh.
6205 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6206 * \sa getFieldAtLevel()
6207 * \sa getFieldOnMeshAtLevel()
6209 MEDCouplingFieldDouble *MEDFileField1TS::getFieldOnMeshAtLevel(TypeOfField type, int meshDimRelToMax, const MEDFileMesh *mesh, int renumPol) const
6211 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
6212 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,this,mesh,arrOut,*contentNotNull());
6213 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
6218 * Returns a new MEDCouplingFieldDouble of a given type lying on a given support.
6219 * This method is called "Old" because in MED3 norm a field has only one meshName
6220 * attached, so this method is for readers of MED2 files. If \a this field
6221 * has not been constructed via file reading, an exception is thrown.
6222 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6223 * \param [in] type - a spatial discretization of interest.
6224 * \param [in] mName - a name of the supporting mesh.
6225 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6226 * \param [in] renumPol - specifies how to permute values of the result field according to
6227 * the optional numbers of cells and nodes, if any. The valid values are
6228 * - 0 - do not permute.
6229 * - 1 - permute cells.
6230 * - 2 - permute nodes.
6231 * - 3 - permute cells and nodes.
6233 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6234 * caller is to delete this field using decrRef() as it is no more needed.
6235 * \throw If the MED file is not readable.
6236 * \throw If there is no mesh named \a mName in the MED file.
6237 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
6238 * \throw If \a this field has not been constructed via file reading.
6239 * \throw If no field of \a this is lying on the mesh named \a mName.
6240 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6241 * \sa getFieldAtLevel()
6243 MEDCouplingFieldDouble *MEDFileField1TS::getFieldAtLevelOld(TypeOfField type, const std::string& mname, int meshDimRelToMax, int renumPol) const
6245 if(getFileName2().empty())
6246 throw INTERP_KERNEL::Exception("MEDFileField1TS::getFieldAtLevelOld : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtLevel method instead !");
6247 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
6248 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtLevel(type,meshDimRelToMax,mname,renumPol,this,arrOut,*contentNotNull());
6249 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
6254 * Returns values and a profile of the field of a given type lying on a given support.
6255 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6256 * \param [in] type - a spatial discretization of the field.
6257 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6258 * \param [in] mesh - the supporting mesh.
6259 * \param [out] pfl - a new instance of DataArrayInt holding ids of mesh entities the
6260 * field of interest lies on. If the field lies on all entities of the given
6261 * dimension, all ids in \a pfl are zero. The caller is to delete this array
6262 * using decrRef() as it is no more needed.
6263 * \return DataArrayDouble * - a new instance of DataArrayDouble holding values of the
6264 * field. The caller is to delete this array using decrRef() as it is no more needed.
6265 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
6266 * \throw If no field of \a this is lying on \a mesh.
6267 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6269 DataArrayDouble *MEDFileField1TS::getFieldWithProfile(TypeOfField type, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt *&pfl) const
6271 MEDCouplingAutoRefCountObjectPtr<DataArray> ret=contentNotNull()->getFieldWithProfile(type,meshDimRelToMax,mesh,pfl,this,*contentNotNull());
6272 return MEDFileField1TS::ReturnSafelyDataArrayDouble(ret);
6276 * Adds a MEDCouplingFieldDouble to \a this. The underlying mesh of the given field is
6277 * checked if its elements are sorted suitable for writing to MED file ("STB" stands for
6278 * "Sort By Type"), if not, an exception is thrown.
6279 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6280 * \param [in] field - the field to add to \a this.
6281 * \throw If the name of \a field is empty.
6282 * \throw If the data array of \a field is not set.
6283 * \throw If the data array is already allocated but has different number of components
6285 * \throw If the underlying mesh of \a field has no name.
6286 * \throw If elements in the mesh are not in the order suitable for writing to the MED file.
6288 void MEDFileField1TS::setFieldNoProfileSBT(const MEDCouplingFieldDouble *field)
6291 contentNotNull()->setFieldNoProfileSBT(field,field->getArray(),*this,*contentNotNull());
6295 * Adds a MEDCouplingFieldDouble to \a this. As described in \ref MEDLoaderMainC a field in MED file sense
6296 * can be an aggregation of several MEDCouplingFieldDouble instances.
6297 * The mesh support of input parameter \a field is ignored here, it can be NULL.
6298 * The support of field \a field is expected to be those computed with the input parameter \a mesh, \a meshDimRelToMax,
6301 * This method will check that the field based on the computed support is coherent. If not an exception will be thrown.
6302 * A new profile is added only if no equal profile is missing.
6303 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6304 * \param [in] field - the field to add to \a this. The mesh support of field is ignored.
6305 * \param [in] mesh - the supporting mesh of \a field.
6306 * \param [in] meshDimRelToMax - a relative dimension of mesh entities \a field lies on (useless if field spatial discretization is ON_NODES).
6307 * \param [in] profile - ids of mesh entities on which corresponding field values lie.
6308 * \throw If either \a field or \a mesh or \a profile has an empty name.
6309 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
6310 * \throw If the data array of \a field is not set.
6311 * \throw If the data array of \a this is already allocated but has different number of
6312 * components than \a field.
6313 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
6314 * \sa setFieldNoProfileSBT()
6316 void MEDFileField1TS::setFieldProfile(const MEDCouplingFieldDouble *field, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile)
6319 contentNotNull()->setFieldProfile(field,field->getArray(),mesh,meshDimRelToMax,profile,*this,*contentNotNull());
6322 MEDFileAnyTypeField1TS *MEDFileField1TS::shallowCpy() const
6324 return new MEDFileField1TS(*this);
6327 DataArrayDouble *MEDFileField1TS::getUndergroundDataArray() const
6329 return contentNotNull()->getUndergroundDataArrayDouble();
6332 DataArrayDouble *MEDFileField1TS::getUndergroundDataArrayExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
6334 return contentNotNull()->getUndergroundDataArrayDoubleExt(entries);
6337 std::vector< std::vector<DataArrayDouble *> > MEDFileField1TS::getFieldSplitedByType2(const std::string& mname, std::vector<INTERP_KERNEL::NormalizedCellType>& types, std::vector< std::vector<TypeOfField> >& typesF,
6338 std::vector< std::vector<std::string> >& pfls, std::vector< std::vector<std::string> >& locs) const throw(INTERP_KERNEL::Exception)
6340 return contentNotNull()->getFieldSplitedByType2(mname,types,typesF,pfls,locs);
6343 //= MEDFileIntField1TS
6345 MEDFileIntField1TS *MEDFileIntField1TS::New()
6347 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret=new MEDFileIntField1TS;
6348 ret->contentNotNull();
6352 MEDFileIntField1TS *MEDFileIntField1TS::New(const std::string& fileName, bool loadAll)
6354 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret=new MEDFileIntField1TS(fileName,loadAll);
6355 ret->contentNotNull();
6359 MEDFileIntField1TS *MEDFileIntField1TS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
6361 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret=new MEDFileIntField1TS(fileName,fieldName,loadAll);
6362 ret->contentNotNull();
6366 MEDFileIntField1TS *MEDFileIntField1TS::New(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll)
6368 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret=new MEDFileIntField1TS(fileName,fieldName,iteration,order,loadAll);
6369 ret->contentNotNull();
6373 MEDFileIntField1TS *MEDFileIntField1TS::New(const MEDFileIntField1TSWithoutSDA& other, bool shallowCopyOfContent)
6375 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret=new MEDFileIntField1TS(other,shallowCopyOfContent);
6376 ret->contentNotNull();
6380 MEDFileIntField1TS::MEDFileIntField1TS()
6382 _content=new MEDFileIntField1TSWithoutSDA;
6385 MEDFileIntField1TS::MEDFileIntField1TS(const std::string& fileName, bool loadAll)
6386 try:MEDFileAnyTypeField1TS(fileName,loadAll)
6389 catch(INTERP_KERNEL::Exception& e)
6392 MEDFileIntField1TS::MEDFileIntField1TS(const std::string& fileName, const std::string& fieldName, bool loadAll)
6393 try:MEDFileAnyTypeField1TS(fileName,fieldName,loadAll)
6396 catch(INTERP_KERNEL::Exception& e)
6399 MEDFileIntField1TS::MEDFileIntField1TS(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll)
6400 try:MEDFileAnyTypeField1TS(fileName,fieldName,iteration,order,loadAll)
6403 catch(INTERP_KERNEL::Exception& e)
6407 * This constructor is a shallow copy constructor. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
6408 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
6410 * \warning this is a shallow copy constructor
6412 MEDFileIntField1TS::MEDFileIntField1TS(const MEDFileIntField1TSWithoutSDA& other, bool shallowCopyOfContent):MEDFileAnyTypeField1TS(other,shallowCopyOfContent)
6416 MEDFileAnyTypeField1TS *MEDFileIntField1TS::shallowCpy() const
6418 return new MEDFileIntField1TS(*this);
6422 * This method performs a copy with datatype modification ( int32->float64 ) of \a this. The globals information are copied
6423 * following the given input policy.
6425 * \param [in] isDeepCpyGlobs - a boolean that indicates the behaviour concerning globals (profiles and localizations)
6426 * By default (true) the globals are deeply copied.
6427 * \return MEDFileField1TS * - a new object that is the result of the conversion of \a this to float64 field.
6429 MEDFileField1TS *MEDFileIntField1TS::convertToDouble(bool isDeepCpyGlobs) const
6431 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret;
6432 const MEDFileAnyTypeField1TSWithoutSDA *content(_content);
6435 const MEDFileIntField1TSWithoutSDA *contc=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(content);
6437 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::convertToInt : the content inside this is not INT32 ! This is incoherent !");
6438 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TSWithoutSDA> newc(contc->convertToDouble());
6439 ret=static_cast<MEDFileField1TS *>(MEDFileAnyTypeField1TS::BuildNewInstanceFromContent((MEDFileField1TSWithoutSDA *)newc,getFileName()));
6442 ret=MEDFileField1TS::New();
6444 ret->deepCpyGlobs(*this);
6446 ret->shallowCpyGlobs(*this);
6451 * Adds a MEDCouplingFieldDouble to \a this. The underlying mesh of the given field is
6452 * checked if its elements are sorted suitable for writing to MED file ("STB" stands for
6453 * "Sort By Type"), if not, an exception is thrown.
6454 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6455 * \param [in] field - the field to add to \a this. The field double values are ignored.
6456 * \param [in] arrOfVals - the values of the field \a field used.
6457 * \throw If the name of \a field is empty.
6458 * \throw If the data array of \a field is not set.
6459 * \throw If the data array is already allocated but has different number of components
6461 * \throw If the underlying mesh of \a field has no name.
6462 * \throw If elements in the mesh are not in the order suitable for writing to the MED file.
6464 void MEDFileIntField1TS::setFieldNoProfileSBT(const MEDCouplingFieldDouble *field, const DataArrayInt *arrOfVals)
6467 contentNotNull()->setFieldNoProfileSBT(field,arrOfVals,*this,*contentNotNull());
6471 * Adds a MEDCouplingFieldDouble to \a this. As described in \ref MEDLoaderMainC a field in MED file sense
6472 * can be an aggregation of several MEDCouplingFieldDouble instances.
6473 * The mesh support of input parameter \a field is ignored here, it can be NULL.
6474 * The support of field \a field is expected to be those computed with the input parameter \a mesh, \a meshDimRelToMax,
6477 * This method will check that the field based on the computed support is coherent. If not an exception will be thrown.
6478 * A new profile is added only if no equal profile is missing.
6479 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6480 * \param [in] field - the field to add to \a this. The field double values and mesh support are ignored.
6481 * \param [in] arrOfVals - the values of the field \a field used.
6482 * \param [in] mesh - the supporting mesh of \a field.
6483 * \param [in] meshDimRelToMax - a relative dimension of mesh entities \a field lies on (useless if field spatial discretization is ON_NODES).
6484 * \param [in] profile - ids of mesh entities on which corresponding field values lie.
6485 * \throw If either \a field or \a mesh or \a profile has an empty name.
6486 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
6487 * \throw If the data array of \a field is not set.
6488 * \throw If the data array of \a this is already allocated but has different number of
6489 * components than \a field.
6490 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
6491 * \sa setFieldNoProfileSBT()
6493 void MEDFileIntField1TS::setFieldProfile(const MEDCouplingFieldDouble *field, const DataArrayInt *arrOfVals, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile)
6496 contentNotNull()->setFieldProfile(field,arrOfVals,mesh,meshDimRelToMax,profile,*this,*contentNotNull());
6499 const MEDFileIntField1TSWithoutSDA *MEDFileIntField1TS::contentNotNull() const
6501 const MEDFileAnyTypeField1TSWithoutSDA *pt(_content);
6503 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::contentNotNull : the content pointer is null !");
6504 const MEDFileIntField1TSWithoutSDA *ret=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(pt);
6506 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::contentNotNull : the content pointer is not null but it is not of type int32 ! Reason is maybe that the read field has not the type INT32 !");
6510 MEDCouplingFieldDouble *MEDFileIntField1TS::getFieldAtLevel(TypeOfField type, int meshDimRelToMax, DataArrayInt* &arrOut, int renumPol) const
6512 if(getFileName2().empty())
6513 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::getFieldAtLevel : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtLevel method instead !");
6514 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut2;
6515 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtLevel(type,meshDimRelToMax,std::string(),renumPol,this,arrOut2,*contentNotNull());
6516 DataArrayInt *arrOutC=dynamic_cast<DataArrayInt *>((DataArray *)arrOut2);
6518 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::getFieldAtLevelOld : mismatch between dataArrays type and MEDFileIntField1TS ! Expected int32 !");
6523 DataArrayInt *MEDFileIntField1TS::ReturnSafelyDataArrayInt(MEDCouplingAutoRefCountObjectPtr<DataArray>& arr)
6525 if(!((DataArray *)arr))
6526 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::ReturnSafelyDataArrayInt : input DataArray is NULL !");
6527 DataArrayInt *arrC=dynamic_cast<DataArrayInt *>((DataArray *)arr);
6529 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::ReturnSafelyDataArrayInt : input DataArray is not of type INT32 !");
6535 * Returns a new MEDCouplingFieldDouble of a given type lying on
6536 * the top level cells of the first mesh in MED file. If \a this field
6537 * has not been constructed via file reading, an exception is thrown.
6538 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6539 * \param [in] type - a spatial discretization of interest.
6540 * \param [out] arrOut - the DataArrayInt containing values of field.
6541 * \param [in] renumPol - specifies how to permute values of the result field according to
6542 * the optional numbers of cells and nodes, if any. The valid values are
6543 * - 0 - do not permute.
6544 * - 1 - permute cells.
6545 * - 2 - permute nodes.
6546 * - 3 - permute cells and nodes.
6548 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6549 * caller is to delete this field using decrRef() as it is no more needed.
6550 * \throw If \a this field has not been constructed via file reading.
6551 * \throw If the MED file is not readable.
6552 * \throw If there is no mesh in the MED file.
6553 * \throw If no field values of the given \a type.
6554 * \throw If no field values lying on the top level support.
6555 * \sa getFieldAtLevel()
6557 MEDCouplingFieldDouble *MEDFileIntField1TS::getFieldAtTopLevel(TypeOfField type, DataArrayInt* &arrOut, int renumPol) const
6559 if(getFileName2().empty())
6560 throw INTERP_KERNEL::Exception("MEDFileField1TS::getFieldAtTopLevel : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtTopLevel method instead !");
6561 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
6562 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtTopLevel(type,std::string(),renumPol,this,arr,*contentNotNull());
6563 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
6568 * Returns a new MEDCouplingFieldDouble of given type lying on a given mesh.
6569 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6570 * \param [in] type - a spatial discretization of the new field.
6571 * \param [in] mesh - the supporting mesh.
6572 * \param [out] arrOut - the DataArrayInt containing values of field.
6573 * \param [in] renumPol - specifies how to permute values of the result field according to
6574 * the optional numbers of cells and nodes, if any. The valid values are
6575 * - 0 - do not permute.
6576 * - 1 - permute cells.
6577 * - 2 - permute nodes.
6578 * - 3 - permute cells and nodes.
6580 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6581 * caller is to delete this field using decrRef() as it is no more needed.
6582 * \throw If no field of \a this is lying on \a mesh.
6583 * \throw If the mesh is empty.
6584 * \throw If no field values of the given \a type are available.
6585 * \sa getFieldAtLevel()
6586 * \sa getFieldOnMeshAtLevel()
6588 MEDCouplingFieldDouble *MEDFileIntField1TS::getFieldOnMeshAtLevel(TypeOfField type, const MEDCouplingMesh *mesh, DataArrayInt* &arrOut, int renumPol) const
6590 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
6591 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldOnMeshAtLevel(type,renumPol,this,mesh,0,0,arr,*contentNotNull());
6592 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
6597 * Returns a new MEDCouplingFieldDouble of a given type lying on a given support.
6598 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6599 * \param [in] type - a spatial discretization of interest.
6600 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6601 * \param [out] arrOut - the DataArrayInt containing values of field.
6602 * \param [in] mesh - the supporting mesh.
6603 * \param [in] renumPol - specifies how to permute values of the result field according to
6604 * the optional numbers of cells and nodes, if any. The valid values are
6605 * - 0 - do not permute.
6606 * - 1 - permute cells.
6607 * - 2 - permute nodes.
6608 * - 3 - permute cells and nodes.
6610 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6611 * caller is to delete this field using decrRef() as it is no more needed.
6612 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
6613 * \throw If no field of \a this is lying on \a mesh.
6614 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6615 * \sa getFieldAtLevel()
6616 * \sa getFieldOnMeshAtLevel()
6618 MEDCouplingFieldDouble *MEDFileIntField1TS::getFieldOnMeshAtLevel(TypeOfField type, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt* &arrOut, int renumPol) const
6620 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
6621 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,this,mesh,arr,*contentNotNull());
6622 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
6627 * Returns a new MEDCouplingFieldDouble of a given type lying on a given support.
6628 * This method is called "Old" because in MED3 norm a field has only one meshName
6629 * attached, so this method is for readers of MED2 files. If \a this field
6630 * has not been constructed via file reading, an exception is thrown.
6631 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6632 * \param [in] type - a spatial discretization of interest.
6633 * \param [in] mName - a name of the supporting mesh.
6634 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6635 * \param [out] arrOut - the DataArrayInt containing values of field.
6636 * \param [in] renumPol - specifies how to permute values of the result field according to
6637 * the optional numbers of cells and nodes, if any. The valid values are
6638 * - 0 - do not permute.
6639 * - 1 - permute cells.
6640 * - 2 - permute nodes.
6641 * - 3 - permute cells and nodes.
6643 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6644 * caller is to delete this field using decrRef() as it is no more needed.
6645 * \throw If the MED file is not readable.
6646 * \throw If there is no mesh named \a mName in the MED file.
6647 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
6648 * \throw If \a this field has not been constructed via file reading.
6649 * \throw If no field of \a this is lying on the mesh named \a mName.
6650 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6651 * \sa getFieldAtLevel()
6653 MEDCouplingFieldDouble *MEDFileIntField1TS::getFieldAtLevelOld(TypeOfField type, const std::string& mname, int meshDimRelToMax, DataArrayInt* &arrOut, int renumPol) const
6655 if(getFileName2().empty())
6656 throw INTERP_KERNEL::Exception("MEDFileField1TS::getFieldAtLevelOld : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtLevel method instead !");
6657 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
6658 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtLevel(type,meshDimRelToMax,mname,renumPol,this,arr,*contentNotNull());
6659 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
6664 * Returns values and a profile of the field of a given type lying on a given support.
6665 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6666 * \param [in] type - a spatial discretization of the field.
6667 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6668 * \param [in] mesh - the supporting mesh.
6669 * \param [out] pfl - a new instance of DataArrayInt holding ids of mesh entities the
6670 * field of interest lies on. If the field lies on all entities of the given
6671 * dimension, all ids in \a pfl are zero. The caller is to delete this array
6672 * using decrRef() as it is no more needed.
6673 * \return DataArrayInt * - a new instance of DataArrayInt holding values of the
6674 * field. The caller is to delete this array using decrRef() as it is no more needed.
6675 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
6676 * \throw If no field of \a this is lying on \a mesh.
6677 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6679 DataArrayInt *MEDFileIntField1TS::getFieldWithProfile(TypeOfField type, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt *&pfl) const
6681 MEDCouplingAutoRefCountObjectPtr<DataArray> arr=contentNotNull()->getFieldWithProfile(type,meshDimRelToMax,mesh,pfl,this,*contentNotNull());
6682 return MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
6685 MEDFileIntField1TSWithoutSDA *MEDFileIntField1TS::contentNotNull()
6687 MEDFileAnyTypeField1TSWithoutSDA *pt(_content);
6689 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::contentNotNull : the non const content pointer is null !");
6690 MEDFileIntField1TSWithoutSDA *ret=dynamic_cast<MEDFileIntField1TSWithoutSDA *>(pt);
6692 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::contentNotNull : the non const content pointer is not null but it is not of type int32 ! Reason is maybe that the read field has not the type INT32 !");
6696 DataArrayInt *MEDFileIntField1TS::getUndergroundDataArray() const
6698 return contentNotNull()->getUndergroundDataArrayInt();
6701 //= MEDFileAnyTypeFieldMultiTSWithoutSDA
6703 MEDFileAnyTypeFieldMultiTSWithoutSDA::MEDFileAnyTypeFieldMultiTSWithoutSDA()
6707 MEDFileAnyTypeFieldMultiTSWithoutSDA::MEDFileAnyTypeFieldMultiTSWithoutSDA(const std::string& fieldName):MEDFileFieldNameScope(fieldName)
6712 * \param [in] fieldId field id in C mode
6714 MEDFileAnyTypeFieldMultiTSWithoutSDA::MEDFileAnyTypeFieldMultiTSWithoutSDA(med_idt fid, int fieldId, bool loadAll)
6716 med_field_type typcha;
6717 std::string dtunitOut;
6718 int nbOfStep=MEDFileAnyTypeField1TS::LocateField2(fid,"",fieldId,false,_name,typcha,_infos,dtunitOut);
6719 setDtUnit(dtunitOut.c_str());
6720 loadStructureOrStructureAndBigArraysRecursively(fid,nbOfStep,typcha,loadAll);
6723 MEDFileAnyTypeFieldMultiTSWithoutSDA::MEDFileAnyTypeFieldMultiTSWithoutSDA(med_idt fid, const std::string& fieldName, med_field_type fieldTyp, const std::vector<std::string>& infos, int nbOfStep, const std::string& dtunit, bool loadAll)
6724 try:MEDFileFieldNameScope(fieldName),_infos(infos)
6726 setDtUnit(dtunit.c_str());
6727 loadStructureOrStructureAndBigArraysRecursively(fid,nbOfStep,fieldTyp,loadAll);
6729 catch(INTERP_KERNEL::Exception& e)
6734 std::size_t MEDFileAnyTypeFieldMultiTSWithoutSDA::getHeapMemorySizeWithoutChildren() const
6736 std::size_t ret(_name.capacity()+_infos.capacity()*sizeof(std::string)+_time_steps.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr<MEDFileField1TSWithoutSDA>));
6737 for(std::vector<std::string>::const_iterator it=_infos.begin();it!=_infos.end();it++)
6738 ret+=(*it).capacity();
6742 std::vector<const BigMemoryObject *> MEDFileAnyTypeFieldMultiTSWithoutSDA::getDirectChildren() const
6744 std::vector<const BigMemoryObject *> ret;
6745 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
6747 const MEDFileAnyTypeField1TSWithoutSDA *cur(*it);
6755 * If one of the id in [ \a startIds , \a endIds ) points to a null element, there is not throw. Simply, this empty element is added as if it were not
6758 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::buildFromTimeStepIds(const int *startIds, const int *endIds) const
6760 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> ret=createNew();
6761 ret->setInfo(_infos);
6762 int sz=(int)_time_steps.size();
6763 for(const int *id=startIds;id!=endIds;id++)
6765 if(*id>=0 && *id<sz)
6767 const MEDFileAnyTypeField1TSWithoutSDA *tse=_time_steps[*id];
6768 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> tse2;
6772 tse2=(const_cast<MEDFileAnyTypeField1TSWithoutSDA *>(tse));
6774 ret->pushBackTimeStep(tse2);
6778 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::buildFromTimeStepIds : At pos #" << std::distance(startIds,id) << " value is " << *id;
6779 oss << " ! Should be in [0," << sz << ") !";
6780 throw INTERP_KERNEL::Exception(oss.str().c_str());
6783 if(ret->getNumberOfTS()>0)
6784 ret->synchronizeNameScope();
6785 ret->copyNameScope(*this);
6790 * If one of the id in the input range points to a null element, there is not throw. Simply, this empty element is added as if it were not
6793 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::buildFromTimeStepIds2(int bg, int end, int step) const
6795 static const char msg[]="MEDFileAnyTypeFieldMultiTSWithoutSDA::buildFromTimeStepIds2";
6796 int nbOfEntriesToKeep=DataArrayInt::GetNumberOfItemGivenBESRelative(bg,end,step,msg);
6797 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> ret=createNew();
6798 ret->setInfo(_infos);
6799 int sz=(int)_time_steps.size();
6801 for(int i=0;i<nbOfEntriesToKeep;i++,j+=step)
6805 const MEDFileAnyTypeField1TSWithoutSDA *tse=_time_steps[j];
6806 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> tse2;
6810 tse2=(const_cast<MEDFileAnyTypeField1TSWithoutSDA *>(tse));
6812 ret->pushBackTimeStep(tse2);
6816 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::buildFromTimeStepIds : At pos #" << i << " value is " << j;
6817 oss << " ! Should be in [0," << sz << ") !";
6818 throw INTERP_KERNEL::Exception(oss.str().c_str());
6821 if(ret->getNumberOfTS()>0)
6822 ret->synchronizeNameScope();
6823 ret->copyNameScope(*this);
6827 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::partOfThisLyingOnSpecifiedTimeSteps(const std::vector< std::pair<int,int> >& timeSteps) const
6830 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ids=DataArrayInt::New(); ids->alloc(0,1);
6831 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,id++)
6833 const MEDFileAnyTypeField1TSWithoutSDA *cur(*it);
6836 std::pair<int,int> p(cur->getIteration(),cur->getOrder());
6837 if(std::find(timeSteps.begin(),timeSteps.end(),p)!=timeSteps.end())
6838 ids->pushBackSilent(id);
6840 return buildFromTimeStepIds(ids->begin(),ids->end());
6843 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::partOfThisNotLyingOnSpecifiedTimeSteps(const std::vector< std::pair<int,int> >& timeSteps) const
6846 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ids=DataArrayInt::New(); ids->alloc(0,1);
6847 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,id++)
6849 const MEDFileAnyTypeField1TSWithoutSDA *cur(*it);
6852 std::pair<int,int> p(cur->getIteration(),cur->getOrder());
6853 if(std::find(timeSteps.begin(),timeSteps.end(),p)==timeSteps.end())
6854 ids->pushBackSilent(id);
6856 return buildFromTimeStepIds(ids->begin(),ids->end());
6859 const std::vector<std::string>& MEDFileAnyTypeFieldMultiTSWithoutSDA::getInfo() const
6864 void MEDFileAnyTypeFieldMultiTSWithoutSDA::setInfo(const std::vector<std::string>& info)
6869 int MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepPos(int iteration, int order) const
6872 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,ret++)
6874 const MEDFileAnyTypeField1TSWithoutSDA *pt(*it);
6875 if(pt->isDealingTS(iteration,order))
6878 std::ostringstream oss; oss << "MEDFileFieldMultiTS::getTimeStepPos : Muli timestep field on time (" << iteration << "," << order << ") does not exist ! Available (iteration,order) are :\n";
6879 std::vector< std::pair<int,int> > vp=getIterations();
6880 for(std::vector< std::pair<int,int> >::const_iterator it2=vp.begin();it2!=vp.end();it2++)
6881 oss << "(" << (*it2).first << "," << (*it2).second << ") ";
6882 throw INTERP_KERNEL::Exception(oss.str().c_str());
6885 const MEDFileAnyTypeField1TSWithoutSDA& MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepEntry(int iteration, int order) const
6887 return *_time_steps[getTimeStepPos(iteration,order)];
6890 MEDFileAnyTypeField1TSWithoutSDA& MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepEntry(int iteration, int order)
6892 return *_time_steps[getTimeStepPos(iteration,order)];
6895 std::string MEDFileAnyTypeFieldMultiTSWithoutSDA::getMeshName() const
6897 if(_time_steps.empty())
6898 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::getMeshName : not time steps !");
6899 return _time_steps[0]->getMeshName();
6902 void MEDFileAnyTypeFieldMultiTSWithoutSDA::setMeshName(const std::string& newMeshName)
6904 std::string oldName(getMeshName());
6905 std::vector< std::pair<std::string,std::string> > v(1);
6906 v[0].first=oldName; v[0].second=newMeshName;
6910 bool MEDFileAnyTypeFieldMultiTSWithoutSDA::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
6913 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
6915 MEDFileAnyTypeField1TSWithoutSDA *cur(*it);
6917 ret=cur->changeMeshNames(modifTab) || ret;
6923 * See doc at MEDFileField1TSWithoutSDA::getUndergroundDataArray
6925 DataArray *MEDFileAnyTypeFieldMultiTSWithoutSDA::getUndergroundDataArray(int iteration, int order) const
6927 return getTimeStepEntry(iteration,order).getUndergroundDataArray();
6931 * See doc at MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt
6933 DataArray *MEDFileAnyTypeFieldMultiTSWithoutSDA::getUndergroundDataArrayExt(int iteration, int order, std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
6935 return getTimeStepEntry(iteration,order).getUndergroundDataArrayExt(entries);
6938 bool MEDFileAnyTypeFieldMultiTSWithoutSDA::renumberEntitiesLyingOnMesh(const std::string& meshName, const std::vector<int>& oldCode, const std::vector<int>& newCode, const DataArrayInt *renumO2N,
6939 MEDFileFieldGlobsReal& glob)
6942 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
6944 MEDFileAnyTypeField1TSWithoutSDA *f1ts(*it);
6946 ret=f1ts->renumberEntitiesLyingOnMesh(meshName,oldCode,newCode,renumO2N,glob) || ret;
6951 void MEDFileAnyTypeFieldMultiTSWithoutSDA::simpleRepr(int bkOffset, std::ostream& oss, int fmtsId) const
6953 std::string startLine(bkOffset,' ');
6954 oss << startLine << "Field multi time steps [Type=" << getTypeStr() << "]";
6956 oss << " (" << fmtsId << ")";
6957 oss << " has the following name: \"" << _name << "\"." << std::endl;
6958 oss << startLine << "Field multi time steps has " << _infos.size() << " components with the following infos :" << std::endl;
6959 for(std::vector<std::string>::const_iterator it=_infos.begin();it!=_infos.end();it++)
6961 oss << startLine << " - \"" << *it << "\"" << std::endl;
6964 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,i++)
6966 std::string chapter(17,'0'+i);
6967 oss << startLine << chapter << std::endl;
6968 const MEDFileAnyTypeField1TSWithoutSDA *cur=(*it);
6970 cur->simpleRepr(bkOffset+2,oss,i);
6972 oss << startLine << " Field on one time step #" << i << " is not defined !" << std::endl;
6973 oss << startLine << chapter << std::endl;
6977 std::vector< std::pair<int,int> > MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeSteps(std::vector<double>& ret1) const
6979 std::size_t sz=_time_steps.size();
6980 std::vector< std::pair<int,int> > ret(sz);
6982 for(std::size_t i=0;i<sz;i++)
6984 const MEDFileAnyTypeField1TSWithoutSDA *f1ts=_time_steps[i];
6987 ret1[i]=f1ts->getTime(ret[i].first,ret[i].second);
6991 std::ostringstream oss; oss << "MEDFileFieldMultiTSWithoutSDA::getTimeSteps : At rank #" << i << " time step is not defined. Invoke eraseEmptyTS method !";
6992 throw INTERP_KERNEL::Exception(oss.str().c_str());
6998 void MEDFileAnyTypeFieldMultiTSWithoutSDA::pushBackTimeStep(MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA>& tse)
7000 MEDFileAnyTypeField1TSWithoutSDA *tse2(tse);
7002 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::pushBackTimeStep : input content object is null !");
7003 checkCoherencyOfType(tse2);
7004 if(_time_steps.empty())
7006 setName(tse2->getName().c_str());
7007 setInfo(tse2->getInfo());
7009 checkThatComponentsMatch(tse2->getInfo());
7010 _time_steps.push_back(tse);
7013 void MEDFileAnyTypeFieldMultiTSWithoutSDA::synchronizeNameScope()
7015 std::size_t nbOfCompo=_infos.size();
7016 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7018 MEDFileAnyTypeField1TSWithoutSDA *cur=(*it);
7021 if((cur->getInfo()).size()!=nbOfCompo)
7023 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::synchronizeNameScope : Mismatch in the number of components of parts ! Should be " << nbOfCompo;
7024 oss << " ! but the field at iteration=" << cur->getIteration() << " order=" << cur->getOrder() << " has " << (cur->getInfo()).size() << " components !";
7025 throw INTERP_KERNEL::Exception(oss.str().c_str());
7027 cur->copyNameScope(*this);
7032 void MEDFileAnyTypeFieldMultiTSWithoutSDA::loadStructureOrStructureAndBigArraysRecursively(med_idt fid, int nbPdt, med_field_type fieldTyp, bool loadAll)
7034 _time_steps.resize(nbPdt);
7035 for(int i=0;i<nbPdt;i++)
7037 std::vector< std::pair<int,int> > ts;
7038 med_int numdt=0,numo=0;
7039 med_int meshIt=0,meshOrder=0;
7041 MEDfieldComputingStepMeshInfo(fid,_name.c_str(),i+1,&numdt,&numo,&dt,&meshIt,&meshOrder);
7046 _time_steps[i]=MEDFileField1TSWithoutSDA::New(_name.c_str(),i+1,numdt,numo,_infos);
7051 _time_steps[i]=MEDFileIntField1TSWithoutSDA::New(_name.c_str(),i+1,numdt,numo,_infos);
7055 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::loadStructureOrStructureAndBigArraysRecursively : managed field type are : FLOAT64, INT32 !");
7058 _time_steps[i]->loadStructureAndBigArraysRecursively(fid,*this);
7060 _time_steps[i]->loadOnlyStructureOfDataRecursively(fid,*this);
7064 void MEDFileAnyTypeFieldMultiTSWithoutSDA::writeLL(med_idt fid, const MEDFileWritable& opts) const
7066 if(_time_steps.empty())
7067 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::writeLL : no time steps set !");
7068 checkThatNbOfCompoOfTSMatchThis();
7069 std::vector<std::string> infos(getInfo());
7070 int nbComp=infos.size();
7071 INTERP_KERNEL::AutoPtr<char> comp=MEDLoaderBase::buildEmptyString(nbComp*MED_SNAME_SIZE);
7072 INTERP_KERNEL::AutoPtr<char> unit=MEDLoaderBase::buildEmptyString(nbComp*MED_SNAME_SIZE);
7073 for(int i=0;i<nbComp;i++)
7075 std::string info=infos[i];
7077 MEDLoaderBase::splitIntoNameAndUnit(info,c,u);
7078 MEDLoaderBase::safeStrCpy2(c.c_str(),MED_SNAME_SIZE,comp+i*MED_SNAME_SIZE,opts.getTooLongStrPolicy());
7079 MEDLoaderBase::safeStrCpy2(u.c_str(),MED_SNAME_SIZE,unit+i*MED_SNAME_SIZE,opts.getTooLongStrPolicy());
7082 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::write : MED file does not accept field with empty name !");
7083 MEDfieldCr(fid,_name.c_str(),getMEDFileFieldType(),nbComp,comp,unit,getDtUnit().c_str(),getMeshName().c_str());
7084 int nbOfTS=_time_steps.size();
7085 for(int i=0;i<nbOfTS;i++)
7086 _time_steps[i]->writeLL(fid,opts,*this);
7089 void MEDFileAnyTypeFieldMultiTSWithoutSDA::loadBigArraysRecursively(med_idt fid, const MEDFileFieldNameScope& nasc)
7091 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7093 MEDFileAnyTypeField1TSWithoutSDA *elt(*it);
7095 elt->loadBigArraysRecursively(fid,nasc);
7099 void MEDFileAnyTypeFieldMultiTSWithoutSDA::loadBigArraysRecursivelyIfNecessary(med_idt fid, const MEDFileFieldNameScope& nasc)
7101 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7103 MEDFileAnyTypeField1TSWithoutSDA *elt(*it);
7105 elt->loadBigArraysRecursivelyIfNecessary(fid,nasc);
7109 void MEDFileAnyTypeFieldMultiTSWithoutSDA::unloadArrays()
7111 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7113 MEDFileAnyTypeField1TSWithoutSDA *elt(*it);
7115 elt->unloadArrays();
7119 int MEDFileAnyTypeFieldMultiTSWithoutSDA::getNumberOfTS() const
7121 return _time_steps.size();
7124 void MEDFileAnyTypeFieldMultiTSWithoutSDA::eraseEmptyTS()
7126 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > newTS;
7127 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7129 const MEDFileAnyTypeField1TSWithoutSDA *tmp=(*it);
7131 newTS.push_back(*it);
7136 void MEDFileAnyTypeFieldMultiTSWithoutSDA::eraseTimeStepIds(const int *startIds, const int *endIds)
7138 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > newTS;
7139 int maxId=(int)_time_steps.size();
7141 std::set<int> idsToDel;
7142 for(const int *id=startIds;id!=endIds;id++,ii++)
7144 if(*id>=0 && *id<maxId)
7146 idsToDel.insert(*id);
7150 std::ostringstream oss; oss << "MEDFileFieldMultiTSWithoutSDA::eraseTimeStepIds : At pos #" << ii << " request for id=" << *id << " not in [0," << maxId << ") !";
7151 throw INTERP_KERNEL::Exception(oss.str().c_str());
7154 for(int iii=0;iii<maxId;iii++)
7155 if(idsToDel.find(iii)==idsToDel.end())
7156 newTS.push_back(_time_steps[iii]);
7160 void MEDFileAnyTypeFieldMultiTSWithoutSDA::eraseTimeStepIds2(int bg, int end, int step)
7162 static const char msg[]="MEDFileAnyTypeFieldMultiTSWithoutSDA::eraseTimeStepIds2";
7163 int nbOfEntriesToKill=DataArrayInt::GetNumberOfItemGivenBESRelative(bg,end,step,msg);
7164 if(nbOfEntriesToKill==0)
7166 std::size_t sz=_time_steps.size();
7167 std::vector<bool> b(sz,true);
7169 for(int i=0;i<nbOfEntriesToKill;i++,j+=step)
7171 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > newTS;
7172 for(std::size_t i=0;i<sz;i++)
7174 newTS.push_back(_time_steps[i]);
7178 int MEDFileAnyTypeFieldMultiTSWithoutSDA::getPosOfTimeStep(int iteration, int order) const
7181 std::ostringstream oss; oss << "MEDFileFieldMultiTSWithoutSDA::getPosOfTimeStep : No such time step (" << iteration << "," << order << ") !\nPossibilities are : ";
7182 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,ret++)
7184 const MEDFileAnyTypeField1TSWithoutSDA *tmp(*it);
7188 tmp->getTime(it2,ord);
7189 if(it2==iteration && order==ord)
7192 oss << "(" << it2 << "," << ord << "), ";
7195 throw INTERP_KERNEL::Exception(oss.str().c_str());
7198 int MEDFileAnyTypeFieldMultiTSWithoutSDA::getPosGivenTime(double time, double eps) const
7201 std::ostringstream oss; oss << "MEDFileFieldMultiTSWithoutSDA::getPosGivenTime : No such time step " << time << "! \nPossibilities are : ";
7203 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,ret++)
7205 const MEDFileAnyTypeField1TSWithoutSDA *tmp(*it);
7209 double ti=tmp->getTime(it2,ord);
7210 if(fabs(time-ti)<eps)
7216 throw INTERP_KERNEL::Exception(oss.str().c_str());
7219 std::vector< std::pair<int,int> > MEDFileAnyTypeFieldMultiTSWithoutSDA::getIterations() const
7221 int lgth=_time_steps.size();
7222 std::vector< std::pair<int,int> > ret(lgth);
7223 for(int i=0;i<lgth;i++)
7224 _time_steps[i]->fillIteration(ret[i]);
7229 * This method has 3 inputs 'iteration' 'order' 'mname'. 'mname' can be null if the user is the general case where there is only one meshName lying on 'this'
7230 * This method returns two things.
7231 * - The absolute dimension of 'this' in first parameter.
7232 * - The available ext levels relative to the absolute dimension returned in first parameter. These relative levels are relative
7233 * to the first output parameter. The values in 'levs' will be returned in decreasing order.
7235 * This method is designed for MEDFileFieldMultiTS instances that have a discritization ON_CELLS, ON_GAUSS_NE and ON_GAUSS.
7236 * Only these 3 discretizations will be taken into account here.
7238 * If 'this' is empty this method will throw an INTERP_KERNEL::Exception.
7239 * If there is \b only node fields defined in 'this' -1 is returned and 'levs' output parameter will be empty. In this
7240 * case the caller has to know the underlying mesh it refers to. By defaut it is the level 0 of the corresponding mesh.
7242 * This method is usefull to make the link between meshDimension of the underlying mesh in 'this' and the levels on 'this'.
7243 * It is possible (even if it is not common) that the highest level in 'this' were not equal to the meshDimension of the underlying mesh in 'this'.
7245 * Let's consider the typical following case :
7246 * - a mesh 'm1' has a meshDimension 3 and has the following non empty levels
7247 * [0,-1,-2] for example 'm1' lies on TETRA4, HEXA8 TRI3 and SEG2
7248 * - 'f1' lies on 'm1' and is defined on 3D and 1D cells for example
7250 * - 'f2' lies on 'm1' too and is defined on 2D and 1D cells for example TRI3 and SEG2
7252 * In this case f1->getNonEmptyLevelsExt will return (3,[0,-2]) and f2->getNonEmptyLevelsExt will return (2,[0,-1])
7254 * To retrieve the highest level of f1 it should be done, f1->getFieldAtLevel(ON_CELLS,3-3+0);//absDim-meshDim+relativeLev
7255 * To retrieve the lowest level of f1 it should be done, f1->getFieldAtLevel(ON_CELLS,3-3+(-2));//absDim-meshDim+relativeLev
7256 * To retrieve the highest level of f2 it should be done, f1->getFieldAtLevel(ON_CELLS,2-3+0);//absDim-meshDim+relativeLev
7257 * To retrieve the lowest level of f2 it should be done, f1->getFieldAtLevel(ON_CELLS,2-3+(-1));//absDim-meshDim+relativeLev
7259 int MEDFileAnyTypeFieldMultiTSWithoutSDA::getNonEmptyLevels(int iteration, int order, const std::string& mname, std::vector<int>& levs) const
7261 return getTimeStepEntry(iteration,order).getNonEmptyLevels(mname,levs);
7264 const MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2(int pos) const
7266 if(pos<0 || pos>=(int)_time_steps.size())
7268 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2 : request for pos #" << pos << " whereas should be in [0," << _time_steps.size() << ") !";
7269 throw INTERP_KERNEL::Exception(oss.str().c_str());
7271 const MEDFileAnyTypeField1TSWithoutSDA *item=_time_steps[pos];
7274 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2 : request for pos #" << pos << ", this pos id exists but the underlying Field1TS is null !";
7275 oss << "\nTry to use following method eraseEmptyTS !";
7276 throw INTERP_KERNEL::Exception(oss.str().c_str());
7281 MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2(int pos)
7283 if(pos<0 || pos>=(int)_time_steps.size())
7285 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2 : request for pos #" << pos << " whereas should be in [0," << _time_steps.size() << ") !";
7286 throw INTERP_KERNEL::Exception(oss.str().c_str());
7288 MEDFileAnyTypeField1TSWithoutSDA *item=_time_steps[pos];
7291 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2 : request for pos #" << pos << ", this pos id exists but the underlying Field1TS is null !";
7292 oss << "\nTry to use following method eraseEmptyTS !";
7293 throw INTERP_KERNEL::Exception(oss.str().c_str());
7298 std::vector<std::string> MEDFileAnyTypeFieldMultiTSWithoutSDA::getPflsReallyUsed2() const
7300 std::vector<std::string> ret;
7301 std::set<std::string> ret2;
7302 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7304 std::vector<std::string> tmp=(*it)->getPflsReallyUsed2();
7305 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
7306 if(ret2.find(*it2)==ret2.end())
7308 ret.push_back(*it2);
7315 std::vector<std::string> MEDFileAnyTypeFieldMultiTSWithoutSDA::getLocsReallyUsed2() const
7317 std::vector<std::string> ret;
7318 std::set<std::string> ret2;
7319 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7321 std::vector<std::string> tmp=(*it)->getLocsReallyUsed2();
7322 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
7323 if(ret2.find(*it2)==ret2.end())
7325 ret.push_back(*it2);
7332 std::vector<std::string> MEDFileAnyTypeFieldMultiTSWithoutSDA::getPflsReallyUsedMulti2() const
7334 std::vector<std::string> ret;
7335 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7337 std::vector<std::string> tmp=(*it)->getPflsReallyUsedMulti2();
7338 ret.insert(ret.end(),tmp.begin(),tmp.end());
7343 std::vector<std::string> MEDFileAnyTypeFieldMultiTSWithoutSDA::getLocsReallyUsedMulti2() const
7345 std::vector<std::string> ret;
7346 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7348 std::vector<std::string> tmp=(*it)->getLocsReallyUsedMulti2();
7349 ret.insert(ret.end(),tmp.begin(),tmp.end());
7354 void MEDFileAnyTypeFieldMultiTSWithoutSDA::changePflsRefsNamesGen2(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
7356 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7357 (*it)->changePflsRefsNamesGen2(mapOfModif);
7360 void MEDFileAnyTypeFieldMultiTSWithoutSDA::changeLocsRefsNamesGen2(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
7362 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7363 (*it)->changeLocsRefsNamesGen2(mapOfModif);
7366 std::vector< std::vector<TypeOfField> > MEDFileAnyTypeFieldMultiTSWithoutSDA::getTypesOfFieldAvailable() const
7368 int lgth=_time_steps.size();
7369 std::vector< std::vector<TypeOfField> > ret(lgth);
7370 for(int i=0;i<lgth;i++)
7371 _time_steps[i]->fillTypesOfFieldAvailable(ret[i]);
7376 * entry point for users that want to iterate into MEDFile DataStructure without any overhead.
7378 std::vector< std::vector< std::pair<int,int> > > MEDFileAnyTypeFieldMultiTSWithoutSDA::getFieldSplitedByType(int iteration, int order, const std::string& mname, std::vector<INTERP_KERNEL::NormalizedCellType>& types, std::vector< std::vector<TypeOfField> >& typesF, std::vector< std::vector<std::string> >& pfls, std::vector< std::vector<std::string> >& locs) const
7380 return getTimeStepEntry(iteration,order).getFieldSplitedByType(mname,types,typesF,pfls,locs);
7383 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::deepCpy() const
7385 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> ret=shallowCpy();
7387 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,i++)
7389 if((const MEDFileAnyTypeField1TSWithoutSDA *)*it)
7390 ret->_time_steps[i]=(*it)->deepCpy();
7395 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > MEDFileAnyTypeFieldMultiTSWithoutSDA::splitComponents() const
7397 std::size_t sz(_infos.size()),sz2(_time_steps.size());
7398 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > ret(sz);
7399 std::vector< std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > > ts(sz2);
7400 for(std::size_t i=0;i<sz;i++)
7402 ret[i]=shallowCpy();
7403 ret[i]->_infos.resize(1); ret[i]->_infos[0]=_infos[i];
7405 for(std::size_t i=0;i<sz2;i++)
7407 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > ret1=_time_steps[i]->splitComponents();
7410 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::splitComponents : At rank #" << i << " number of components is " << ret1.size() << " whereas it should be for all time steps " << sz << " !";
7411 throw INTERP_KERNEL::Exception(oss.str().c_str());
7415 for(std::size_t i=0;i<sz;i++)
7416 for(std::size_t j=0;j<sz2;j++)
7417 ret[i]->_time_steps[j]=ts[j][i];
7422 * This method splits into discretization each time steps in \a this.
7423 * ** WARNING ** the returned instances are not compulsary defined on the same time steps series !
7425 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > MEDFileAnyTypeFieldMultiTSWithoutSDA::splitDiscretizations() const
7427 std::size_t sz(_time_steps.size());
7428 std::vector< std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > > items(sz);
7429 for(std::size_t i=0;i<sz;i++)
7431 const MEDFileAnyTypeField1TSWithoutSDA *timeStep(_time_steps[i]);
7434 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::splitDiscretizations : time step #" << i << " is null !";
7435 throw INTERP_KERNEL::Exception(oss.str().c_str());
7437 items[i]=timeStep->splitDiscretizations();
7440 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > ret;
7441 std::vector< std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > > ret2;
7442 std::vector< TypeOfField > types;
7443 for(std::vector< std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > >::const_iterator it0=items.begin();it0!=items.end();it0++)
7444 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it1=(*it0).begin();it1!=(*it0).end();it1++)
7446 std::vector<TypeOfField> ts=(*it1)->getTypesOfFieldAvailable();
7448 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::splitDiscretizations : it appears that the splitting of MEDFileAnyTypeField1TSWithoutSDA::splitDiscretizations has returned invalid result !");
7449 std::vector< TypeOfField >::iterator it2=std::find(types.begin(),types.end(),ts[0]);
7450 if(it2==types.end())
7451 types.push_back(ts[0]);
7453 ret.resize(types.size()); ret2.resize(types.size());
7454 for(std::vector< std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > >::const_iterator it0=items.begin();it0!=items.end();it0++)
7455 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it1=(*it0).begin();it1!=(*it0).end();it1++)
7457 TypeOfField typ=(*it1)->getTypesOfFieldAvailable()[0];
7458 std::size_t pos=std::distance(types.begin(),std::find(types.begin(),types.end(),typ));
7459 ret2[pos].push_back(*it1);
7461 for(std::size_t i=0;i<types.size();i++)
7463 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> elt=createNew();
7464 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it1=ret2[i].begin();it1!=ret2[i].end();it1++)
7465 elt->pushBackTimeStep(*it1);//also updates infos in elt
7467 elt->MEDFileFieldNameScope::operator=(*this);
7472 void MEDFileAnyTypeFieldMultiTSWithoutSDA::copyTinyInfoFrom(const MEDCouplingFieldDouble *field, const DataArray *arr)
7474 _name=field->getName();
7476 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::copyTinyInfoFrom : unsupported fields with no name in MED file !");
7478 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::copyTinyInfoFrom : no array set !");
7479 _infos=arr->getInfoOnComponents();
7482 void MEDFileAnyTypeFieldMultiTSWithoutSDA::checkCoherencyOfTinyInfo(const MEDCouplingFieldDouble *field, const DataArray *arr) const
7484 static const char MSG[]="MEDFileFieldMultiTSWithoutSDA::checkCoherencyOfTinyInfo : invalid ";
7485 if(_name!=field->getName())
7487 std::ostringstream oss; oss << MSG << "name ! should be \"" << _name;
7488 oss << "\" and it is set in input field to \"" << field->getName() << "\" !";
7489 throw INTERP_KERNEL::Exception(oss.str().c_str());
7492 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::checkCoherencyOfTinyInfo : no array set !");
7493 checkThatComponentsMatch(arr->getInfoOnComponents());
7496 void MEDFileAnyTypeFieldMultiTSWithoutSDA::checkThatComponentsMatch(const std::vector<std::string>& compos) const
7498 static const char MSG[]="MEDFileFieldMultiTSWithoutSDA::checkThatComponentsMatch : ";
7499 if(getInfo().size()!=compos.size())
7501 std::ostringstream oss; oss << MSG << "mismatch of number of components between this (" << getInfo().size() << ") and ";
7502 oss << " number of components of element to append (" << compos.size() << ") !";
7503 throw INTERP_KERNEL::Exception(oss.str().c_str());
7507 std::ostringstream oss; oss << MSG << "components have same size but are different ! should be \"";
7508 std::copy(_infos.begin(),_infos.end(),std::ostream_iterator<std::string>(oss,", "));
7509 oss << " But compo in input fields are : ";
7510 std::copy(compos.begin(),compos.end(),std::ostream_iterator<std::string>(oss,", "));
7512 throw INTERP_KERNEL::Exception(oss.str().c_str());
7516 void MEDFileAnyTypeFieldMultiTSWithoutSDA::checkThatNbOfCompoOfTSMatchThis() const
7518 std::size_t sz=_infos.size();
7520 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,j++)
7522 const MEDFileAnyTypeField1TSWithoutSDA *elt(*it);
7524 if(elt->getInfo().size()!=sz)
7526 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::checkThatNbOfCompoOfTSMatchThis : At pos #" << j << " the number of components is equal to ";
7527 oss << elt->getInfo().size() << " whereas it is expected to be equal to " << sz << " !";
7528 throw INTERP_KERNEL::Exception(oss.str().c_str());
7533 void MEDFileAnyTypeFieldMultiTSWithoutSDA::appendFieldNoProfileSBT(const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob)
7536 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::appendFieldNoProfileSBT : input field is NULL !");
7537 if(!_time_steps.empty())
7538 checkCoherencyOfTinyInfo(field,arr);
7539 MEDFileAnyTypeField1TSWithoutSDA *objC=createNew1TSWithoutSDAEmptyInstance();
7540 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> obj(objC);
7541 objC->setFieldNoProfileSBT(field,arr,glob,*this);
7542 copyTinyInfoFrom(field,arr);
7543 _time_steps.push_back(obj);
7546 void MEDFileAnyTypeFieldMultiTSWithoutSDA::appendFieldProfile(const MEDCouplingFieldDouble *field, const DataArray *arr, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile, MEDFileFieldGlobsReal& glob)
7549 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTSWithoutSDA::appendFieldNoProfileSBT : input field is NULL !");
7550 if(!_time_steps.empty())
7551 checkCoherencyOfTinyInfo(field,arr);
7552 MEDFileField1TSWithoutSDA *objC=new MEDFileField1TSWithoutSDA;
7553 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> obj(objC);
7554 objC->setFieldProfile(field,arr,mesh,meshDimRelToMax,profile,glob,*this);
7555 copyTinyInfoFrom(field,arr);
7556 _time_steps.push_back(obj);
7559 void MEDFileAnyTypeFieldMultiTSWithoutSDA::setIteration(int i, MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> ts)
7561 int sz=(int)_time_steps.size();
7564 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::setIteration : trying to set element at place #" << i << " should be in [0," << sz << ") !";
7565 throw INTERP_KERNEL::Exception(oss.str().c_str());
7567 const MEDFileAnyTypeField1TSWithoutSDA *tsPtr(ts);
7570 if(tsPtr->getNumberOfComponents()!=(int)_infos.size())
7572 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::setIteration : trying to set element with " << tsPtr->getNumberOfComponents() << " components ! Should be " << _infos.size() << " !";
7573 throw INTERP_KERNEL::Exception(oss.str().c_str());
7579 //= MEDFileFieldMultiTSWithoutSDA
7581 MEDFileFieldMultiTSWithoutSDA *MEDFileFieldMultiTSWithoutSDA::New(med_idt fid, const std::string& fieldName, med_field_type fieldTyp, const std::vector<std::string>& infos, int nbOfStep, const std::string& dtunit, bool loadAll)
7583 return new MEDFileFieldMultiTSWithoutSDA(fid,fieldName,fieldTyp,infos,nbOfStep,dtunit,loadAll);
7586 MEDFileFieldMultiTSWithoutSDA::MEDFileFieldMultiTSWithoutSDA()
7590 MEDFileFieldMultiTSWithoutSDA::MEDFileFieldMultiTSWithoutSDA(const std::string& fieldName):MEDFileAnyTypeFieldMultiTSWithoutSDA(fieldName)
7595 * \param [in] fieldId field id in C mode
7597 MEDFileFieldMultiTSWithoutSDA::MEDFileFieldMultiTSWithoutSDA(med_idt fid, int fieldId, bool loadAll)
7598 try:MEDFileAnyTypeFieldMultiTSWithoutSDA(fid,fieldId,loadAll)
7601 catch(INTERP_KERNEL::Exception& e)
7604 MEDFileFieldMultiTSWithoutSDA::MEDFileFieldMultiTSWithoutSDA(med_idt fid, const std::string& fieldName, med_field_type fieldTyp, const std::vector<std::string>& infos, int nbOfStep, const std::string& dtunit, bool loadAll)
7605 try:MEDFileAnyTypeFieldMultiTSWithoutSDA(fid,fieldName,fieldTyp,infos,nbOfStep,dtunit,loadAll)
7608 catch(INTERP_KERNEL::Exception& e)
7611 MEDFileAnyTypeField1TSWithoutSDA *MEDFileFieldMultiTSWithoutSDA::createNew1TSWithoutSDAEmptyInstance() const
7613 return new MEDFileField1TSWithoutSDA;
7616 void MEDFileFieldMultiTSWithoutSDA::checkCoherencyOfType(const MEDFileAnyTypeField1TSWithoutSDA *f1ts) const
7619 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::checkCoherencyOfType : input field1TS is NULL ! Impossible to check !");
7620 const MEDFileField1TSWithoutSDA *f1tsC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(f1ts);
7622 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::checkCoherencyOfType : the input field1TS is not a FLOAT64 type !");
7625 const char *MEDFileFieldMultiTSWithoutSDA::getTypeStr() const
7627 return MEDFileField1TSWithoutSDA::TYPE_STR;
7630 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileFieldMultiTSWithoutSDA::shallowCpy() const
7632 return new MEDFileFieldMultiTSWithoutSDA(*this);
7635 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileFieldMultiTSWithoutSDA::createNew() const
7637 return new MEDFileFieldMultiTSWithoutSDA;
7641 * entry point for users that want to iterate into MEDFile DataStructure with a reduced overhead because output arrays are extracted (created) specially
7642 * for the call of this method. That's why the DataArrayDouble instance in returned vector of vector should be dealed by the caller.
7644 std::vector< std::vector<DataArrayDouble *> > MEDFileFieldMultiTSWithoutSDA::getFieldSplitedByType2(int iteration, int order, const std::string& mname, std::vector<INTERP_KERNEL::NormalizedCellType>& types, std::vector< std::vector<TypeOfField> >& typesF, std::vector< std::vector<std::string> >& pfls, std::vector< std::vector<std::string> >& locs) const
7646 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=getTimeStepEntry(iteration,order);
7647 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
7649 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::getFieldSplitedByType2 : mismatch of type of field expecting FLOAT64 !");
7650 return myF1TSC->getFieldSplitedByType2(mname,types,typesF,pfls,locs);
7653 MEDFileIntFieldMultiTSWithoutSDA *MEDFileFieldMultiTSWithoutSDA::convertToInt() const
7655 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTSWithoutSDA> ret(new MEDFileIntFieldMultiTSWithoutSDA);
7656 ret->MEDFileAnyTypeFieldMultiTSWithoutSDA::operator =(*this);
7658 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,i++)
7660 const MEDFileAnyTypeField1TSWithoutSDA *eltToConv(*it);
7663 const MEDFileField1TSWithoutSDA *eltToConvC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(eltToConv);
7665 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::convertToInt : presence of an invalid 1TS type ! Should be of type FLOAT64 !");
7666 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> elt=eltToConvC->convertToInt();
7667 ret->setIteration(i,elt);
7673 //= MEDFileAnyTypeFieldMultiTS
7675 MEDFileAnyTypeFieldMultiTS::MEDFileAnyTypeFieldMultiTS()
7679 MEDFileAnyTypeFieldMultiTS::MEDFileAnyTypeFieldMultiTS(const std::string& fileName, bool loadAll)
7680 try:MEDFileFieldGlobsReal(fileName)
7682 MEDFileUtilities::CheckFileForRead(fileName);
7683 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
7684 _content=BuildContentFrom(fid,fileName,loadAll);
7687 catch(INTERP_KERNEL::Exception& e)
7692 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTS::BuildContentFrom(med_idt fid, const std::string& fileName, const std::string& fieldName, bool loadAll)
7694 med_field_type typcha;
7695 std::vector<std::string> infos;
7698 MEDFileAnyTypeField1TS::LocateField(fid,fileName,fieldName,i,typcha,infos,dtunit);
7699 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> ret;
7704 ret=new MEDFileFieldMultiTSWithoutSDA(fid,i,loadAll);
7709 ret=new MEDFileIntFieldMultiTSWithoutSDA(fid,i,loadAll);
7714 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTS::BuildContentFrom(fileName,fieldName) : file \'" << fileName << "\' contains field with name \'" << fieldName << "\' but the type of field is not in [MED_FLOAT64, MED_INT32] !";
7715 throw INTERP_KERNEL::Exception(oss.str().c_str());
7718 ret->setDtUnit(dtunit.c_str());
7722 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTS::BuildContentFrom(med_idt fid, const std::string& fileName, bool loadAll)
7724 med_field_type typcha;
7726 std::vector<std::string> infos;
7727 std::string dtunit,fieldName;
7728 MEDFileAnyTypeField1TS::LocateField2(fid,fileName,0,true,fieldName,typcha,infos,dtunit);
7729 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> ret;
7734 ret=new MEDFileFieldMultiTSWithoutSDA(fid,0,loadAll);
7739 ret=new MEDFileIntFieldMultiTSWithoutSDA(fid,0,loadAll);
7744 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTS::BuildContentFrom(fileName) : file \'" << fileName << "\' contains field with name \'" << fieldName << "\' but the type of the first field is not in [MED_FLOAT64, MED_INT32] !";
7745 throw INTERP_KERNEL::Exception(oss.str().c_str());
7748 ret->setDtUnit(dtunit.c_str());
7752 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::BuildNewInstanceFromContent(MEDFileAnyTypeFieldMultiTSWithoutSDA *c, const std::string& fileName)
7755 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::BuildNewInstanceFromContent : empty content in input : unable to build a new instance !");
7756 if(dynamic_cast<const MEDFileFieldMultiTSWithoutSDA *>(c))
7758 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTS> ret=MEDFileFieldMultiTS::New();
7759 ret->setFileName(fileName);
7760 ret->_content=c; c->incrRef();
7763 if(dynamic_cast<const MEDFileIntFieldMultiTSWithoutSDA *>(c))
7765 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTS> ret=MEDFileIntFieldMultiTS::New();
7766 ret->setFileName(fileName);
7767 ret->_content=c; c->incrRef();
7770 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::BuildNewInstanceFromContent : internal error ! a content of type different from FLOAT64 and INT32 has been built but not intercepted !");
7773 MEDFileAnyTypeFieldMultiTS::MEDFileAnyTypeFieldMultiTS(const std::string& fileName, const std::string& fieldName, bool loadAll)
7774 try:MEDFileFieldGlobsReal(fileName)
7776 MEDFileUtilities::CheckFileForRead(fileName);
7777 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
7778 _content=BuildContentFrom(fid,fileName,fieldName,loadAll);
7781 catch(INTERP_KERNEL::Exception& e)
7786 //= MEDFileIntFieldMultiTSWithoutSDA
7788 MEDFileIntFieldMultiTSWithoutSDA *MEDFileIntFieldMultiTSWithoutSDA::New(med_idt fid, const std::string& fieldName, med_field_type fieldTyp, const std::vector<std::string>& infos, int nbOfStep, const std::string& dtunit, bool loadAll)
7790 return new MEDFileIntFieldMultiTSWithoutSDA(fid,fieldName,fieldTyp,infos,nbOfStep,dtunit,loadAll);
7793 MEDFileIntFieldMultiTSWithoutSDA::MEDFileIntFieldMultiTSWithoutSDA()
7797 MEDFileIntFieldMultiTSWithoutSDA::MEDFileIntFieldMultiTSWithoutSDA(const std::string& fieldName):MEDFileAnyTypeFieldMultiTSWithoutSDA(fieldName)
7801 MEDFileIntFieldMultiTSWithoutSDA::MEDFileIntFieldMultiTSWithoutSDA(med_idt fid, const std::string& fieldName, med_field_type fieldTyp, const std::vector<std::string>& infos, int nbOfStep, const std::string& dtunit, bool loadAll)
7802 try:MEDFileAnyTypeFieldMultiTSWithoutSDA(fid,fieldName,fieldTyp,infos,nbOfStep,dtunit,loadAll)
7805 catch(INTERP_KERNEL::Exception& e)
7809 * \param [in] fieldId field id in C mode
7811 MEDFileIntFieldMultiTSWithoutSDA::MEDFileIntFieldMultiTSWithoutSDA(med_idt fid, int fieldId, bool loadAll)
7812 try:MEDFileAnyTypeFieldMultiTSWithoutSDA(fid,fieldId,loadAll)
7815 catch(INTERP_KERNEL::Exception& e)
7818 MEDFileAnyTypeField1TSWithoutSDA *MEDFileIntFieldMultiTSWithoutSDA::createNew1TSWithoutSDAEmptyInstance() const
7820 return new MEDFileIntField1TSWithoutSDA;
7823 void MEDFileIntFieldMultiTSWithoutSDA::checkCoherencyOfType(const MEDFileAnyTypeField1TSWithoutSDA *f1ts) const
7826 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTSWithoutSDA::checkCoherencyOfType : input field1TS is NULL ! Impossible to check !");
7827 const MEDFileIntField1TSWithoutSDA *f1tsC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(f1ts);
7829 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTSWithoutSDA::checkCoherencyOfType : the input field1TS is not a INT32 type !");
7832 const char *MEDFileIntFieldMultiTSWithoutSDA::getTypeStr() const
7834 return MEDFileIntField1TSWithoutSDA::TYPE_STR;
7837 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileIntFieldMultiTSWithoutSDA::shallowCpy() const
7839 return new MEDFileIntFieldMultiTSWithoutSDA(*this);
7842 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileIntFieldMultiTSWithoutSDA::createNew() const
7844 return new MEDFileIntFieldMultiTSWithoutSDA;
7847 MEDFileFieldMultiTSWithoutSDA *MEDFileIntFieldMultiTSWithoutSDA::convertToDouble() const
7849 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTSWithoutSDA> ret(new MEDFileFieldMultiTSWithoutSDA);
7850 ret->MEDFileAnyTypeFieldMultiTSWithoutSDA::operator =(*this);
7852 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,i++)
7854 const MEDFileAnyTypeField1TSWithoutSDA *eltToConv(*it);
7857 const MEDFileIntField1TSWithoutSDA *eltToConvC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(eltToConv);
7859 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTSWithoutSDA::convertToInt : presence of an invalid 1TS type ! Should be of type INT32 !");
7860 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> elt=eltToConvC->convertToDouble();
7861 ret->setIteration(i,elt);
7867 //= MEDFileAnyTypeFieldMultiTS
7870 * Returns a new instance of MEDFileFieldMultiTS or MEDFileIntFieldMultiTS holding data of the first field
7871 * that has been read from a specified MED file.
7872 * \param [in] fileName - the name of the MED file to read.
7873 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS or MEDFileIntFieldMultiTS. The caller
7874 * is to delete this field using decrRef() as it is no more needed.
7875 * \throw If reading the file fails.
7877 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::New(const std::string& fileName, bool loadAll)
7879 MEDFileUtilities::CheckFileForRead(fileName);
7880 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
7881 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> c=BuildContentFrom(fid,fileName,loadAll);
7882 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret=BuildNewInstanceFromContent(c,fileName);
7883 ret->loadGlobals(fid);
7888 * Returns a new instance of MEDFileFieldMultiTS or MEDFileIntFieldMultiTS holding data of a given field
7889 * that has been read from a specified MED file.
7890 * \param [in] fileName - the name of the MED file to read.
7891 * \param [in] fieldName - the name of the field to read.
7892 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS or MEDFileIntFieldMultiTS. The caller
7893 * is to delete this field using decrRef() as it is no more needed.
7894 * \throw If reading the file fails.
7895 * \throw If there is no field named \a fieldName in the file.
7897 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
7899 MEDFileUtilities::CheckFileForRead(fileName);
7900 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
7901 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> c=BuildContentFrom(fid,fileName,fieldName,loadAll);
7902 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret=BuildNewInstanceFromContent(c,fileName);
7903 ret->loadGlobals(fid);
7908 * This constructor is a shallow copy constructor. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
7909 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
7911 * \warning this is a shallow copy constructor
7913 MEDFileAnyTypeFieldMultiTS::MEDFileAnyTypeFieldMultiTS(const MEDFileAnyTypeFieldMultiTSWithoutSDA& other, bool shallowCopyOfContent)
7915 if(!shallowCopyOfContent)
7917 const MEDFileAnyTypeFieldMultiTSWithoutSDA *otherPtr(&other);
7918 otherPtr->incrRef();
7919 _content=const_cast<MEDFileAnyTypeFieldMultiTSWithoutSDA *>(otherPtr);
7923 _content=other.shallowCpy();
7927 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTS::contentNotNullBase()
7929 MEDFileAnyTypeFieldMultiTSWithoutSDA *ret=_content;
7931 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS : content is expected to be not null !");
7935 const MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTS::contentNotNullBase() const
7937 const MEDFileAnyTypeFieldMultiTSWithoutSDA *ret=_content;
7939 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS : const content is expected to be not null !");
7943 std::vector<std::string> MEDFileAnyTypeFieldMultiTS::getPflsReallyUsed() const
7945 return contentNotNullBase()->getPflsReallyUsed2();
7948 std::vector<std::string> MEDFileAnyTypeFieldMultiTS::getLocsReallyUsed() const
7950 return contentNotNullBase()->getLocsReallyUsed2();
7953 std::vector<std::string> MEDFileAnyTypeFieldMultiTS::getPflsReallyUsedMulti() const
7955 return contentNotNullBase()->getPflsReallyUsedMulti2();
7958 std::vector<std::string> MEDFileAnyTypeFieldMultiTS::getLocsReallyUsedMulti() const
7960 return contentNotNullBase()->getLocsReallyUsedMulti2();
7963 void MEDFileAnyTypeFieldMultiTS::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
7965 contentNotNullBase()->changePflsRefsNamesGen2(mapOfModif);
7968 void MEDFileAnyTypeFieldMultiTS::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
7970 contentNotNullBase()->changeLocsRefsNamesGen2(mapOfModif);
7973 int MEDFileAnyTypeFieldMultiTS::getNumberOfTS() const
7975 return contentNotNullBase()->getNumberOfTS();
7978 void MEDFileAnyTypeFieldMultiTS::eraseEmptyTS()
7980 contentNotNullBase()->eraseEmptyTS();
7983 void MEDFileAnyTypeFieldMultiTS::eraseTimeStepIds(const int *startIds, const int *endIds)
7985 contentNotNullBase()->eraseTimeStepIds(startIds,endIds);
7988 void MEDFileAnyTypeFieldMultiTS::eraseTimeStepIds2(int bg, int end, int step)
7990 contentNotNullBase()->eraseTimeStepIds2(bg,end,step);
7993 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::buildSubPart(const int *startIds, const int *endIds) const
7995 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> c=contentNotNullBase()->buildFromTimeStepIds(startIds,endIds);
7996 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret=shallowCpy();
8001 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::buildSubPartSlice(int bg, int end, int step) const
8003 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> c=contentNotNullBase()->buildFromTimeStepIds2(bg,end,step);
8004 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret=shallowCpy();
8009 std::vector< std::pair<int,int> > MEDFileAnyTypeFieldMultiTS::getIterations() const
8011 return contentNotNullBase()->getIterations();
8014 void MEDFileAnyTypeFieldMultiTS::pushBackTimeSteps(const std::vector<MEDFileAnyTypeField1TS *>& f1ts)
8016 for(std::vector<MEDFileAnyTypeField1TS *>::const_iterator it=f1ts.begin();it!=f1ts.end();it++)
8017 pushBackTimeStep(*it);
8020 void MEDFileAnyTypeFieldMultiTS::pushBackTimeStep(MEDFileAnyTypeField1TS *f1ts)
8023 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::pushBackTimeStep : input pointer is NULL !");
8024 checkCoherencyOfType(f1ts);
8026 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> f1tsSafe(f1ts);
8027 MEDFileAnyTypeField1TSWithoutSDA *c=f1ts->contentNotNullBase();
8029 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> cSafe(c);
8030 if(!((MEDFileAnyTypeFieldMultiTSWithoutSDA *)_content))
8031 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::pushBackTimeStep : no content in this !");
8032 _content->pushBackTimeStep(cSafe);
8033 appendGlobs(*f1ts,1e-12);
8036 void MEDFileAnyTypeFieldMultiTS::synchronizeNameScope()
8038 contentNotNullBase()->synchronizeNameScope();
8041 int MEDFileAnyTypeFieldMultiTS::getPosOfTimeStep(int iteration, int order) const
8043 return contentNotNullBase()->getPosOfTimeStep(iteration,order);
8046 int MEDFileAnyTypeFieldMultiTS::getPosGivenTime(double time, double eps) const
8048 return contentNotNullBase()->getPosGivenTime(time,eps);
8051 int MEDFileAnyTypeFieldMultiTS::getNonEmptyLevels(int iteration, int order, const std::string& mname, std::vector<int>& levs) const
8053 return contentNotNullBase()->getNonEmptyLevels(iteration,order,mname,levs);
8056 std::vector< std::vector<TypeOfField> > MEDFileAnyTypeFieldMultiTS::getTypesOfFieldAvailable() const
8058 return contentNotNullBase()->getTypesOfFieldAvailable();
8061 std::vector< std::vector< std::pair<int,int> > > MEDFileAnyTypeFieldMultiTS::getFieldSplitedByType(int iteration, int order, const std::string& mname, std::vector<INTERP_KERNEL::NormalizedCellType>& types, std::vector< std::vector<TypeOfField> >& typesF, std::vector< std::vector<std::string> >& pfls, std::vector< std::vector<std::string> >& locs) const
8063 return contentNotNullBase()->getFieldSplitedByType(iteration,order,mname,types,typesF,pfls,locs);
8066 std::string MEDFileAnyTypeFieldMultiTS::getName() const
8068 return contentNotNullBase()->getName();
8071 void MEDFileAnyTypeFieldMultiTS::setName(const std::string& name)
8073 contentNotNullBase()->setName(name);
8076 std::string MEDFileAnyTypeFieldMultiTS::getDtUnit() const
8078 return contentNotNullBase()->getDtUnit();
8081 void MEDFileAnyTypeFieldMultiTS::setDtUnit(const std::string& dtUnit)
8083 contentNotNullBase()->setDtUnit(dtUnit);
8086 void MEDFileAnyTypeFieldMultiTS::simpleRepr(int bkOffset, std::ostream& oss, int fmtsId) const
8088 contentNotNullBase()->simpleRepr(bkOffset,oss,fmtsId);
8091 std::vector< std::pair<int,int> > MEDFileAnyTypeFieldMultiTS::getTimeSteps(std::vector<double>& ret1) const
8093 return contentNotNullBase()->getTimeSteps(ret1);
8096 std::string MEDFileAnyTypeFieldMultiTS::getMeshName() const
8098 return contentNotNullBase()->getMeshName();
8101 void MEDFileAnyTypeFieldMultiTS::setMeshName(const std::string& newMeshName)
8103 contentNotNullBase()->setMeshName(newMeshName);
8106 bool MEDFileAnyTypeFieldMultiTS::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
8108 return contentNotNullBase()->changeMeshNames(modifTab);
8111 const std::vector<std::string>& MEDFileAnyTypeFieldMultiTS::getInfo() const
8113 return contentNotNullBase()->getInfo();
8116 void MEDFileAnyTypeFieldMultiTS::setInfo(const std::vector<std::string>& info)
8118 return contentNotNullBase()->setInfo(info);
8121 int MEDFileAnyTypeFieldMultiTS::getNumberOfComponents() const
8123 const std::vector<std::string> ret=getInfo();
8124 return (int)ret.size();
8127 void MEDFileAnyTypeFieldMultiTS::writeLL(med_idt fid) const
8129 writeGlobals(fid,*this);
8130 contentNotNullBase()->writeLL(fid,*this);
8134 * Writes \a this field into a MED file specified by its name.
8135 * \param [in] fileName - the MED file name.
8136 * \param [in] mode - the writing mode. For more on \a mode, see \ref AdvMEDLoaderBasics.
8137 * - 2 - erase; an existing file is removed.
8138 * - 1 - append; same data should not be present in an existing file.
8139 * - 0 - overwrite; same data present in an existing file is overwritten.
8140 * \throw If the field name is not set.
8141 * \throw If no field data is set.
8142 * \throw If \a mode == 1 and the same data is present in an existing file.
8144 void MEDFileAnyTypeFieldMultiTS::write(const std::string& fileName, int mode) const
8146 med_access_mode medmod=MEDFileUtilities::TraduceWriteMode(mode);
8147 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),medmod);
8152 * This method alloc the arrays and load potentially huge arrays contained in this field.
8153 * This method should be called when a MEDFileAnyTypeFieldMultiTS::New constructor has been with false as the last parameter.
8154 * This method can be also called to refresh or reinit values from a file.
8156 * \throw If the fileName is not set or points to a non readable MED file.
8158 void MEDFileAnyTypeFieldMultiTS::loadArrays()
8160 if(getFileName().empty())
8161 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::loadArrays : the structure does not come from a file !");
8162 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
8163 contentNotNullBase()->loadBigArraysRecursively(fid,*contentNotNullBase());
8167 * This method behaves as MEDFileAnyTypeFieldMultiTS::loadArrays does, the first call, if \a this was built using a file without loading big arrays.
8168 * But once data loaded once, this method does nothing.
8170 * \throw If the fileName is not set or points to a non readable MED file.
8171 * \sa MEDFileAnyTypeFieldMultiTS::loadArrays, MEDFileAnyTypeFieldMultiTS::unloadArrays
8173 void MEDFileAnyTypeFieldMultiTS::loadArraysIfNecessary()
8175 if(!getFileName().empty())
8177 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
8178 contentNotNullBase()->loadBigArraysRecursivelyIfNecessary(fid,*contentNotNullBase());
8183 * This method releases potentially big data arrays and so returns to the same heap memory than status loaded with 'loadAll' parameter set to false.
8184 * This method does not release arrays set outside the context of a MED file.
8186 * \sa MEDFileAnyTypeFieldMultiTS::loadArrays, MEDFileAnyTypeFieldMultiTS::loadArraysIfNecessary
8188 void MEDFileAnyTypeFieldMultiTS::unloadArrays()
8190 contentNotNullBase()->unloadArrays();
8193 std::string MEDFileAnyTypeFieldMultiTS::simpleRepr() const
8195 std::ostringstream oss;
8196 contentNotNullBase()->simpleRepr(0,oss,-1);
8197 simpleReprGlobs(oss);
8201 std::size_t MEDFileAnyTypeFieldMultiTS::getHeapMemorySizeWithoutChildren() const
8203 return MEDFileFieldGlobsReal::getHeapMemorySizeWithoutChildren();
8206 std::vector<const BigMemoryObject *> MEDFileAnyTypeFieldMultiTS::getDirectChildren() const
8208 std::vector<const BigMemoryObject *> ret(MEDFileFieldGlobsReal::getDirectChildren());
8209 if((const MEDFileAnyTypeFieldMultiTSWithoutSDA *)_content)
8210 ret.push_back((const MEDFileAnyTypeFieldMultiTSWithoutSDA *)_content);
8215 * This method returns as MEDFileAnyTypeFieldMultiTS new instances as number of components in \a this.
8216 * The returned instances are deep copy of \a this except that for globals that are share with those contained in \a this.
8217 * ** WARNING ** do no forget to rename the ouput instances to avoid to write n-times in the same MED file field !
8219 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTS > > MEDFileAnyTypeFieldMultiTS::splitComponents() const
8221 const MEDFileAnyTypeFieldMultiTSWithoutSDA *content(_content);
8223 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::splitComponents : no content in this ! Unable to split components !");
8224 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > contentsSplit=content->splitComponents();
8225 std::size_t sz(contentsSplit.size());
8226 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTS > > ret(sz);
8227 for(std::size_t i=0;i<sz;i++)
8229 ret[i]=shallowCpy();
8230 ret[i]->_content=contentsSplit[i];
8236 * This method returns as MEDFileAnyTypeFieldMultiTS new instances as number of discretizations over time steps in \a this.
8237 * The returned instances are deep copy of \a this except that for globals that are share with those contained in \a this.
8239 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTS > > MEDFileAnyTypeFieldMultiTS::splitDiscretizations() const
8241 const MEDFileAnyTypeFieldMultiTSWithoutSDA *content(_content);
8243 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::splitDiscretizations : no content in this ! Unable to split discretizations !");
8244 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > contentsSplit=content->splitDiscretizations();
8245 std::size_t sz(contentsSplit.size());
8246 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTS > > ret(sz);
8247 for(std::size_t i=0;i<sz;i++)
8249 ret[i]=shallowCpy();
8250 ret[i]->_content=contentsSplit[i];
8255 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::deepCpy() const
8257 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret=shallowCpy();
8258 if((const MEDFileAnyTypeFieldMultiTSWithoutSDA *)_content)
8259 ret->_content=_content->deepCpy();
8260 ret->deepCpyGlobs(*this);
8264 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> MEDFileAnyTypeFieldMultiTS::getContent()
8270 * Returns a new MEDFileField1TS or MEDFileIntField1TS holding data of a given time step of \a this field.
8271 * \param [in] iteration - the iteration number of a required time step.
8272 * \param [in] order - the iteration order number of required time step.
8273 * \return MEDFileField1TS * or MEDFileIntField1TS *- a new instance of MEDFileField1TS or MEDFileIntField1TS. The caller is to
8274 * delete this field using decrRef() as it is no more needed.
8275 * \throw If there is no required time step in \a this field.
8277 MEDFileAnyTypeField1TS *MEDFileAnyTypeFieldMultiTS::getTimeStep(int iteration, int order) const
8279 int pos=getPosOfTimeStep(iteration,order);
8280 return getTimeStepAtPos(pos);
8284 * Returns a new MEDFileField1TS or MEDFileIntField1TS holding data of a given time step of \a this field.
8285 * \param [in] time - the time of the time step of interest.
8286 * \param [in] eps - a precision used to compare time values.
8287 * \return MEDFileField1TS * - a new instance of MEDFileField1TS. The caller is to
8288 * delete this field using decrRef() as it is no more needed.
8289 * \throw If there is no required time step in \a this field.
8291 MEDFileAnyTypeField1TS *MEDFileAnyTypeFieldMultiTS::getTimeStepGivenTime(double time, double eps) const
8293 int pos=getPosGivenTime(time,eps);
8294 return getTimeStepAtPos(pos);
8298 * This method groups not null items in \a vectFMTS per time step series. Two time series are considered equal if the list of their pair of integers iteration,order are equal.
8299 * The float64 value of time attached to the pair of integers are not considered here.
8300 * WARNING the returned pointers are not incremented. The caller is \b not responsible to deallocate them ! This method only reorganizes entries in \a vectFMTS.
8302 * \param [in] vectFMTS - vector of not null fields defined on a same global data pointer.
8303 * \throw If there is a null pointer in \a vectFMTS.
8305 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > MEDFileAnyTypeFieldMultiTS::SplitIntoCommonTimeSeries(const std::vector<MEDFileAnyTypeFieldMultiTS *>& vectFMTS)
8307 static const char msg[]="MEDFileAnyTypeFieldMultiTS::SplitIntoCommonTimeSeries : presence of null instance in input vector !";
8308 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > ret;
8309 std::list<MEDFileAnyTypeFieldMultiTS *> lstFMTS(vectFMTS.begin(),vectFMTS.end());
8310 while(!lstFMTS.empty())
8312 std::list<MEDFileAnyTypeFieldMultiTS *>::iterator it(lstFMTS.begin());
8313 MEDFileAnyTypeFieldMultiTS *curIt(*it);
8315 throw INTERP_KERNEL::Exception(msg);
8316 std::vector< std::pair<int,int> > refIts=curIt->getIterations();
8317 std::vector<MEDFileAnyTypeFieldMultiTS *> elt;
8318 elt.push_back(curIt); it=lstFMTS.erase(it);
8319 while(it!=lstFMTS.end())
8323 throw INTERP_KERNEL::Exception(msg);
8324 std::vector< std::pair<int,int> > curIts=curIt->getIterations();
8326 { elt.push_back(curIt); it=lstFMTS.erase(it); }
8336 * This method splits the input list \a vectFMTS considering the aspect of the geometrical support over time.
8337 * All returned instances in a subvector can be safely loaded, rendered along time
8338 * All items must be defined on the same time step ids ( see MEDFileAnyTypeFieldMultiTS::SplitIntoCommonTimeSeries method ).
8339 * Each item in \a vectFMTS is expected to have one and exactly one spatial discretization along time.
8340 * All items in \a vectFMTS must lie on the mesh (located by meshname and time step) and compatible with the input mesh \a mesh (having the same name than those in items).
8341 * All items in \a vectFMTS whose spatial discretization is not ON_NODES will appear once.
8342 * For items in \a vectFMTS that are ON_NODES it is possible to appear several times (more than once or once) in the returned vector.
8344 * \param [in] vectFMTS - list of multi times step part all defined each on a same spatial discretization along time and pointing to a mesh whose name is equal to \c mesh->getName().
8345 * \param [in] mesh - the mesh shared by all items in \a vectFMTS across time.
8346 * \param [out] fsc - A vector having same size than returned vector. It specifies the support comporator of the corresponding vector of MEDFileAnyTypeFieldMultiTS in returned vector of vector.
8347 * \return - A vector of vector of objects that contains the same pointers (objects) than thoose in \a vectFMTS except that there are organized differently. So pointers included in returned vector of vector should \b not been dealt by the caller.
8349 * \throw If an element in \a vectFMTS has not only one spatial discretization set.
8350 * \throw If an element in \a vectFMTS change of spatial discretization along time.
8351 * \throw If an element in \a vectFMTS lies on a mesh with meshname different from those in \a mesh.
8352 * \thorw If some elements in \a vectFMTS do not have the same times steps.
8353 * \throw If mesh is null.
8354 * \throw If an element in \a vectFMTS is null.
8355 * \sa MEDFileAnyTypeFieldMultiTS::AreOnSameSupportAcrossTime
8357 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupport(const std::vector<MEDFileAnyTypeFieldMultiTS *>& vectFMTS, const MEDFileMesh *mesh, std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFastCellSupportComparator> >& fsc)
8359 static const char msg[]="MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupport : presence of a null instance in the input vector !";
8361 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupport : input mesh is null !");
8362 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > ret;
8363 if(vectFMTS.empty())
8365 std::vector<MEDFileAnyTypeFieldMultiTS *>::const_iterator it(vectFMTS.begin());
8366 MEDFileAnyTypeFieldMultiTS *frstElt(*it);
8368 throw INTERP_KERNEL::Exception(msg);
8370 std::vector<MEDFileAnyTypeFieldMultiTS *> vectFMTSNotNodes;
8371 std::vector<MEDFileAnyTypeFieldMultiTS *> vectFMTSNodes;
8372 for(;it!=vectFMTS.end();it++,i++)
8375 throw INTERP_KERNEL::Exception(msg);
8376 TypeOfField tof0,tof1;
8377 if(CheckSupportAcrossTime(frstElt,*it,mesh,tof0,tof1)>0)
8380 vectFMTSNotNodes.push_back(*it);
8382 vectFMTSNodes.push_back(*it);
8385 vectFMTSNotNodes.push_back(*it);
8387 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFastCellSupportComparator> > cmps;
8388 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > retCell=SplitPerCommonSupportNotNodesAlg(vectFMTSNotNodes,mesh,cmps);
8390 for(std::vector<MEDFileAnyTypeFieldMultiTS *>::const_iterator it2=vectFMTSNodes.begin();it2!=vectFMTSNodes.end();it2++)
8393 bool isFetched(false);
8394 for(std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> >::const_iterator it0=retCell.begin();it0!=retCell.end();it0++,i++)
8397 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupport : internal error !");
8398 if(cmps[i]->isCompatibleWithNodesDiscr(*it2))
8399 { ret[i].push_back(*it2); isFetched=true; }
8403 std::vector<MEDFileAnyTypeFieldMultiTS *> tmp(1,*it2);
8404 MEDCouplingAutoRefCountObjectPtr<MEDFileMeshStruct> tmp2(MEDFileMeshStruct::New(mesh));
8405 ret.push_back(tmp); retCell.push_back(tmp); cmps.push_back(MEDFileFastCellSupportComparator::New(tmp2,*it2));
8413 * WARNING no check here. The caller must be sure that all items in vectFMTS are coherent each other in time steps, only one same spatial discretization and not ON_NODES.
8414 * \param [out] cmps - same size than the returned vector.
8416 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupportNotNodesAlg(const std::vector<MEDFileAnyTypeFieldMultiTS *>& vectFMTS, const MEDFileMesh *mesh, std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFastCellSupportComparator> >& cmps)
8418 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > ret;
8419 std::list<MEDFileAnyTypeFieldMultiTS *> lstFMTS(vectFMTS.begin(),vectFMTS.end());
8420 while(!lstFMTS.empty())
8422 std::list<MEDFileAnyTypeFieldMultiTS *>::iterator it(lstFMTS.begin());
8423 MEDFileAnyTypeFieldMultiTS *ref(*it);
8424 std::vector<MEDFileAnyTypeFieldMultiTS *> elt;
8425 elt.push_back(ref); it=lstFMTS.erase(it);
8426 MEDCouplingAutoRefCountObjectPtr<MEDFileMeshStruct> mst(MEDFileMeshStruct::New(mesh));
8427 MEDCouplingAutoRefCountObjectPtr<MEDFileFastCellSupportComparator> cmp(MEDFileFastCellSupportComparator::New(mst,ref));
8428 while(it!=lstFMTS.end())
8430 MEDFileAnyTypeFieldMultiTS *curIt(*it);
8431 if(cmp->isEqual(curIt))
8432 { elt.push_back(curIt); it=lstFMTS.erase(it); }
8436 ret.push_back(elt); cmps.push_back(cmp);
8442 * This method scan the two main structs along time of \a f0 and \a f1 to see if there are all lying on the same mesh along time than those in \a mesh.
8443 * \a f0 and \a f1 must be defined each only on a same spatial discretization even if this can be different each other.
8445 * \throw If \a f0 or \a f1 has not only one spatial discretization set.
8446 * \throw If \a f0 or \a f1 change of spatial discretization along time.
8447 * \throw If \a f0 or \a f1 on a mesh with meshname different from those in \a mesh.
8448 * \thorw If \a f0 and \a f1 do not have the same times steps.
8449 * \throw If mesh is null.
8450 * \throw If \a f0 or \a f1 is null.
8451 * \sa MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupport
8453 int MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime(MEDFileAnyTypeFieldMultiTS *f0, MEDFileAnyTypeFieldMultiTS *f1, const MEDFileMesh *mesh, TypeOfField& tof0, TypeOfField& tof1)
8456 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : input mesh is null !");
8458 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : presence of null instance in fields over time !");
8459 if(f0->getMeshName()!=mesh->getName())
8461 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : first field points to mesh \""<< f0->getMeshName() << "\" and input mesh to compare has name \"" << mesh->getName() << "\" !";
8462 throw INTERP_KERNEL::Exception(oss.str().c_str());
8464 if(f1->getMeshName()!=mesh->getName())
8466 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : second field points to mesh \""<< f1->getMeshName() << "\" and input mesh to compare has name \"" << mesh->getName() << "\" !";
8467 throw INTERP_KERNEL::Exception(oss.str().c_str());
8469 int nts=f0->getNumberOfTS();
8470 if(nts!=f1->getNumberOfTS())
8471 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : number of time steps are not the same !");
8474 for(int i=0;i<nts;i++)
8476 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> f0cur=f0->getTimeStepAtPos(i);
8477 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> f1cur=f1->getTimeStepAtPos(i);
8478 std::vector<TypeOfField> tofs0(f0cur->getTypesOfFieldAvailable()),tofs1(f1cur->getTypesOfFieldAvailable());
8479 if(tofs0.size()!=1 || tofs1.size()!=1)
8480 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : All time steps must be defined on only one spatial discretization !");
8483 if(tof0!=tofs0[0] || tof1!=tofs1[0])
8484 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : Across times steps MEDFileAnyTypeFieldMultiTS instances have to keep the same unique spatial discretization !");
8487 { tof0=tofs0[0]; tof1=tofs1[0]; }
8488 if(f0cur->getMeshIteration()!=mesh->getIteration() || f0cur->getMeshOrder()!=mesh->getOrder())
8490 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : first field points to mesh time step (" << f0cur->getMeshIteration() << ","<< f0cur->getMeshOrder() << ") whereas input mesh points to time step (" << mesh->getIteration() << "," << mesh->getOrder() << ") !";
8491 throw INTERP_KERNEL::Exception(oss.str().c_str());
8493 if(f1cur->getMeshIteration()!=mesh->getIteration() || f1cur->getMeshOrder()!=mesh->getOrder())
8495 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : second field points to mesh time step (" << f1cur->getMeshIteration() << ","<< f1cur->getMeshOrder() << ") whereas input mesh points to time step (" << mesh->getIteration() << "," << mesh->getOrder() << ") !";
8496 throw INTERP_KERNEL::Exception(oss.str().c_str());
8498 if(f0cur->getIteration()!=f1cur->getIteration() || f0cur->getOrder()!=f1cur->getOrder())
8500 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : all the time steps must be the same ! it is not the case (" << f0cur->getIteration() << "," << f0cur->getOrder() << ")!=(" << f1cur->getIteration() << "," << f1cur->getOrder() << ") !";
8501 throw INTERP_KERNEL::Exception(oss.str().c_str());
8507 MEDFileAnyTypeFieldMultiTSIterator *MEDFileAnyTypeFieldMultiTS::iterator()
8509 return new MEDFileAnyTypeFieldMultiTSIterator(this);
8512 //= MEDFileFieldMultiTS
8515 * Returns a new empty instance of MEDFileFieldMultiTS.
8516 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS. The caller
8517 * is to delete this field using decrRef() as it is no more needed.
8519 MEDFileFieldMultiTS *MEDFileFieldMultiTS::New()
8521 return new MEDFileFieldMultiTS;
8525 * Returns a new instance of MEDFileFieldMultiTS holding data of the first field
8526 * that has been read from a specified MED file.
8527 * \param [in] fileName - the name of the MED file to read.
8528 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS. The caller
8529 * is to delete this field using decrRef() as it is no more needed.
8530 * \throw If reading the file fails.
8532 MEDFileFieldMultiTS *MEDFileFieldMultiTS::New(const std::string& fileName, bool loadAll)
8534 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTS> ret=new MEDFileFieldMultiTS(fileName,loadAll);
8535 ret->contentNotNull();//to check that content type matches with \a this type.
8540 * Returns a new instance of MEDFileFieldMultiTS holding data of a given field
8541 * that has been read from a specified MED file.
8542 * \param [in] fileName - the name of the MED file to read.
8543 * \param [in] fieldName - the name of the field to read.
8544 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS. The caller
8545 * is to delete this field using decrRef() as it is no more needed.
8546 * \throw If reading the file fails.
8547 * \throw If there is no field named \a fieldName in the file.
8549 MEDFileFieldMultiTS *MEDFileFieldMultiTS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
8551 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTS> ret=new MEDFileFieldMultiTS(fileName,fieldName,loadAll);
8552 ret->contentNotNull();//to check that content type matches with \a this type.
8557 * Returns a new instance of MEDFileFieldMultiTS. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
8558 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
8560 * Returns a new instance of MEDFileFieldMultiTS holding either a shallow copy
8561 * of a given MEDFileFieldMultiTSWithoutSDA ( \a other ) or \a other itself.
8562 * \warning this is a shallow copy constructor
8563 * \param [in] other - a MEDFileField1TSWithoutSDA to copy.
8564 * \param [in] shallowCopyOfContent - if \c true, a shallow copy of \a other is created.
8565 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS. The caller
8566 * is to delete this field using decrRef() as it is no more needed.
8568 MEDFileFieldMultiTS *MEDFileFieldMultiTS::New(const MEDFileFieldMultiTSWithoutSDA& other, bool shallowCopyOfContent)
8570 return new MEDFileFieldMultiTS(other,shallowCopyOfContent);
8573 MEDFileAnyTypeFieldMultiTS *MEDFileFieldMultiTS::shallowCpy() const
8575 return new MEDFileFieldMultiTS(*this);
8578 void MEDFileFieldMultiTS::checkCoherencyOfType(const MEDFileAnyTypeField1TS *f1ts) const
8581 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::checkCoherencyOfType : input field1TS is NULL ! Impossible to check !");
8582 const MEDFileField1TS *f1tsC=dynamic_cast<const MEDFileField1TS *>(f1ts);
8584 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::checkCoherencyOfType : the input field1TS is not a FLOAT64 type !");
8588 * This method performs a copy with datatype modification ( float64->int32 ) of \a this. The globals information are copied
8589 * following the given input policy.
8591 * \param [in] isDeepCpyGlobs - a boolean that indicates the behaviour concerning globals (profiles and localizations)
8592 * By default (true) the globals are deeply copied.
8593 * \return MEDFileIntFieldMultiTS * - a new object that is the result of the conversion of \a this to int32 field.
8595 MEDFileIntFieldMultiTS *MEDFileFieldMultiTS::convertToInt(bool isDeepCpyGlobs) const
8597 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTS> ret;
8598 const MEDFileAnyTypeFieldMultiTSWithoutSDA *content(_content);
8601 const MEDFileFieldMultiTSWithoutSDA *contc=dynamic_cast<const MEDFileFieldMultiTSWithoutSDA *>(content);
8603 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::convertToInt : the content inside this is not FLOAT64 ! This is incoherent !");
8604 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTSWithoutSDA> newc(contc->convertToInt());
8605 ret=static_cast<MEDFileIntFieldMultiTS *>(MEDFileAnyTypeFieldMultiTS::BuildNewInstanceFromContent((MEDFileIntFieldMultiTSWithoutSDA *)newc,getFileName()));
8608 ret=MEDFileIntFieldMultiTS::New();
8610 ret->deepCpyGlobs(*this);
8612 ret->shallowCpyGlobs(*this);
8617 * Returns a new MEDFileField1TS holding data of a given time step of \a this field.
8618 * \param [in] pos - a time step id.
8619 * \return MEDFileField1TS * - a new instance of MEDFileField1TS. The caller is to
8620 * delete this field using decrRef() as it is no more needed.
8621 * \throw If \a pos is not a valid time step id.
8623 MEDFileAnyTypeField1TS *MEDFileFieldMultiTS::getTimeStepAtPos(int pos) const
8625 const MEDFileAnyTypeField1TSWithoutSDA *item=contentNotNullBase()->getTimeStepAtPos2(pos);
8628 std::ostringstream oss; oss << "MEDFileFieldMultiTS::getTimeStepAtPos : field at pos #" << pos << " is null !";
8629 throw INTERP_KERNEL::Exception(oss.str().c_str());
8631 const MEDFileField1TSWithoutSDA *itemC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(item);
8634 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret=MEDFileField1TS::New(*itemC,false);
8635 ret->shallowCpyGlobs(*this);
8638 std::ostringstream oss; oss << "MEDFileFieldMultiTS::getTimeStepAtPos : type of field at pos #" << pos << " is not FLOAT64 !";
8639 throw INTERP_KERNEL::Exception(oss.str().c_str());
8643 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
8644 * mesh entities of a given dimension of the first mesh in MED file.
8645 * For more info, see \ref AdvMEDLoaderAPIFieldRW
8646 * \param [in] type - a spatial discretization of interest.
8647 * \param [in] iteration - the iteration number of a required time step.
8648 * \param [in] order - the iteration order number of required time step.
8649 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
8650 * \param [in] renumPol - specifies how to permute values of the result field according to
8651 * the optional numbers of cells and nodes, if any. The valid values are
8652 * - 0 - do not permute.
8653 * - 1 - permute cells.
8654 * - 2 - permute nodes.
8655 * - 3 - permute cells and nodes.
8657 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
8658 * caller is to delete this field using decrRef() as it is no more needed.
8659 * \throw If the MED file is not readable.
8660 * \throw If there is no mesh in the MED file.
8661 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
8662 * \throw If no field values of the required parameters are available.
8664 MEDCouplingFieldDouble *MEDFileFieldMultiTS::getFieldAtLevel(TypeOfField type, int iteration, int order, int meshDimRelToMax, int renumPol) const
8666 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
8667 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
8669 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldAtLevel : mismatch of type of field expecting FLOAT64 !");
8670 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
8671 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtLevel(type,meshDimRelToMax,std::string(),renumPol,this,arrOut,*contentNotNullBase());
8672 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
8677 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
8678 * the top level cells of the first mesh in MED file.
8679 * For more info, see \ref AdvMEDLoaderAPIFieldRW
8680 * \param [in] type - a spatial discretization of interest.
8681 * \param [in] iteration - the iteration number of a required time step.
8682 * \param [in] order - the iteration order number of required time step.
8683 * \param [in] renumPol - specifies how to permute values of the result field according to
8684 * the optional numbers of cells and nodes, if any. The valid values are
8685 * - 0 - do not permute.
8686 * - 1 - permute cells.
8687 * - 2 - permute nodes.
8688 * - 3 - permute cells and nodes.
8690 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
8691 * caller is to delete this field using decrRef() as it is no more needed.
8692 * \throw If the MED file is not readable.
8693 * \throw If there is no mesh in the MED file.
8694 * \throw If no field values of the required parameters are available.
8696 MEDCouplingFieldDouble *MEDFileFieldMultiTS::getFieldAtTopLevel(TypeOfField type, int iteration, int order, int renumPol) const
8698 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
8699 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
8701 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldAtTopLevel : mismatch of type of field !");
8702 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
8703 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtTopLevel(type,std::string(),renumPol,this,arrOut,*contentNotNullBase());
8704 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
8709 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
8711 * For more info, see \ref AdvMEDLoaderAPIFieldRW
8712 * \param [in] type - a spatial discretization of interest.
8713 * \param [in] iteration - the iteration number of a required time step.
8714 * \param [in] order - the iteration order number of required time step.
8715 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
8716 * \param [in] mesh - the supporting mesh.
8717 * \param [in] renumPol - specifies how to permute values of the result field according to
8718 * the optional numbers of cells and nodes, if any. The valid values are
8719 * - 0 - do not permute.
8720 * - 1 - permute cells.
8721 * - 2 - permute nodes.
8722 * - 3 - permute cells and nodes.
8724 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
8725 * caller is to delete this field using decrRef() as it is no more needed.
8726 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
8727 * \throw If no field of \a this is lying on \a mesh.
8728 * \throw If no field values of the required parameters are available.
8730 MEDCouplingFieldDouble *MEDFileFieldMultiTS::getFieldOnMeshAtLevel(TypeOfField type, int iteration, int order, int meshDimRelToMax, const MEDFileMesh *mesh, int renumPol) const
8732 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
8733 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
8735 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldOnMeshAtLevel : mismatch of type of field !");
8736 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
8737 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,this,mesh,arrOut,*contentNotNullBase());
8738 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
8743 * Returns a new MEDCouplingFieldDouble of given type, of a given time step, lying on a
8745 * For more info, see \ref AdvMEDLoaderAPIFieldRW
8746 * \param [in] type - a spatial discretization of the new field.
8747 * \param [in] iteration - the iteration number of a required time step.
8748 * \param [in] order - the iteration order number of required time step.
8749 * \param [in] mesh - the supporting mesh.
8750 * \param [in] renumPol - specifies how to permute values of the result field according to
8751 * the optional numbers of cells and nodes, if any. The valid values are
8752 * - 0 - do not permute.
8753 * - 1 - permute cells.
8754 * - 2 - permute nodes.
8755 * - 3 - permute cells and nodes.
8757 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
8758 * caller is to delete this field using decrRef() as it is no more needed.
8759 * \throw If no field of \a this is lying on \a mesh.
8760 * \throw If no field values of the required parameters are available.
8762 MEDCouplingFieldDouble *MEDFileFieldMultiTS::getFieldOnMeshAtLevel(TypeOfField type, int iteration, int order, const MEDCouplingMesh *mesh, int renumPol) const
8764 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
8765 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
8767 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldOnMeshAtLevel : mismatch of type of field !");
8768 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
8769 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldOnMeshAtLevel(type,renumPol,this,mesh,0,0,arrOut,*contentNotNullBase());
8770 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
8775 * This method has a close behaviour than MEDFileFieldMultiTS::getFieldAtLevel.
8776 * This method is called 'old' because the user should give the mesh name he wants to use for it's field.
8777 * This method is useful for MED2 file format when field on different mesh was autorized.
8779 MEDCouplingFieldDouble *MEDFileFieldMultiTS::getFieldAtLevelOld(TypeOfField type, const std::string& mname, int iteration, int order, int meshDimRelToMax, int renumPol) const
8781 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
8782 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
8784 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldAtLevelOld : mismatch of type of field !");
8785 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
8786 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtLevel(type,meshDimRelToMax,mname,renumPol,this,arrOut,*contentNotNullBase());
8787 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
8792 * Returns values and a profile of the field of a given type, of a given time step,
8793 * lying on a given support.
8794 * For more info, see \ref AdvMEDLoaderAPIFieldRW
8795 * \param [in] type - a spatial discretization of the field.
8796 * \param [in] iteration - the iteration number of a required time step.
8797 * \param [in] order - the iteration order number of required time step.
8798 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
8799 * \param [in] mesh - the supporting mesh.
8800 * \param [out] pfl - a new instance of DataArrayInt holding ids of mesh entities the
8801 * field of interest lies on. If the field lies on all entities of the given
8802 * dimension, all ids in \a pfl are zero. The caller is to delete this array
8803 * using decrRef() as it is no more needed.
8804 * \param [in] glob - the global data storing profiles and localization.
8805 * \return DataArrayDouble * - a new instance of DataArrayDouble holding values of the
8806 * field. The caller is to delete this array using decrRef() as it is no more needed.
8807 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
8808 * \throw If no field of \a this is lying on \a mesh.
8809 * \throw If no field values of the required parameters are available.
8811 DataArrayDouble *MEDFileFieldMultiTS::getFieldWithProfile(TypeOfField type, int iteration, int order, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt *&pfl) const
8813 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
8814 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
8816 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldWithProfile : mismatch of type of field !");
8817 MEDCouplingAutoRefCountObjectPtr<DataArray> ret=myF1TSC->getFieldWithProfile(type,meshDimRelToMax,mesh,pfl,this,*contentNotNullBase());
8818 return MEDFileField1TS::ReturnSafelyDataArrayDouble(ret);
8821 const MEDFileFieldMultiTSWithoutSDA *MEDFileFieldMultiTS::contentNotNull() const
8823 const MEDFileAnyTypeFieldMultiTSWithoutSDA *pt(_content);
8825 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::contentNotNull : the content pointer is null !");
8826 const MEDFileFieldMultiTSWithoutSDA *ret=dynamic_cast<const MEDFileFieldMultiTSWithoutSDA *>(pt);
8828 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::contentNotNull : the content pointer is not null but it is not of type double ! Reason is maybe that the read field has not the type FLOAT64 !");
8832 MEDFileFieldMultiTSWithoutSDA *MEDFileFieldMultiTS::contentNotNull()
8834 MEDFileAnyTypeFieldMultiTSWithoutSDA *pt(_content);
8836 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::contentNotNull : the non const content pointer is null !");
8837 MEDFileFieldMultiTSWithoutSDA *ret=dynamic_cast<MEDFileFieldMultiTSWithoutSDA *>(pt);
8839 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::contentNotNull : the non const content pointer is not null but it is not of type double ! Reason is maybe that the read field has not the type FLOAT64 !");
8844 * Adds a MEDCouplingFieldDouble to \a this as another time step. The underlying mesh of
8845 * the given field is checked if its elements are sorted suitable for writing to MED file
8846 * ("STB" stands for "Sort By Type"), if not, an exception is thrown.
8847 * For more info, see \ref AdvMEDLoaderAPIFieldRW
8848 * \param [in] field - the field to add to \a this.
8849 * \throw If the name of \a field is empty.
8850 * \throw If the data array of \a field is not set.
8851 * \throw If existing time steps have different name or number of components than \a field.
8852 * \throw If the underlying mesh of \a field has no name.
8853 * \throw If elements in the mesh are not in the order suitable for writing to the MED file.
8855 void MEDFileFieldMultiTS::appendFieldNoProfileSBT(const MEDCouplingFieldDouble *field)
8857 const DataArrayDouble *arr=0;
8859 arr=field->getArray();
8860 contentNotNull()->appendFieldNoProfileSBT(field,arr,*this);
8864 * Adds a MEDCouplingFieldDouble to \a this as another time step.
8865 * The mesh support of input parameter \a field is ignored here, it can be NULL.
8866 * The support of field \a field is expected to be those computed with the input parameter \a mesh, \a meshDimRelToMax,
8869 * This method will check that the field based on the computed support is coherent. If not an exception will be thrown.
8870 * A new profile is added only if no equal profile is missing.
8871 * For more info, see \ref AdvMEDLoaderAPIFieldRW
8872 * \param [in] field - the field to add to \a this. The mesh support of field is ignored.
8873 * \param [in] mesh - the supporting mesh of \a field.
8874 * \param [in] meshDimRelToMax - a relative dimension of mesh entities \a field lies on (useless if field spatial discretization is ON_NODES).
8875 * \param [in] profile - ids of mesh entities on which corresponding field values lie.
8876 * \throw If either \a field or \a mesh or \a profile has an empty name.
8877 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
8878 * \throw If the data array of \a field is not set.
8879 * \throw If the data array of \a this is already allocated but has different number of
8880 * components than \a field.
8881 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
8882 * \sa setFieldNoProfileSBT()
8884 void MEDFileFieldMultiTS::appendFieldProfile(const MEDCouplingFieldDouble *field, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile)
8886 const DataArrayDouble *arr=0;
8888 arr=field->getArray();
8889 contentNotNull()->appendFieldProfile(field,arr,mesh,meshDimRelToMax,profile,*this);
8892 MEDFileFieldMultiTS::MEDFileFieldMultiTS()
8894 _content=new MEDFileFieldMultiTSWithoutSDA;
8897 MEDFileFieldMultiTS::MEDFileFieldMultiTS(const std::string& fileName, bool loadAll)
8898 try:MEDFileAnyTypeFieldMultiTS(fileName,loadAll)
8901 catch(INTERP_KERNEL::Exception& e)
8904 MEDFileFieldMultiTS::MEDFileFieldMultiTS(const std::string& fileName, const std::string& fieldName, bool loadAll)
8905 try:MEDFileAnyTypeFieldMultiTS(fileName,fieldName,loadAll)
8908 catch(INTERP_KERNEL::Exception& e)
8911 MEDFileFieldMultiTS::MEDFileFieldMultiTS(const MEDFileFieldMultiTSWithoutSDA& other, bool shallowCopyOfContent):MEDFileAnyTypeFieldMultiTS(other,shallowCopyOfContent)
8915 std::vector< std::vector<DataArrayDouble *> > MEDFileFieldMultiTS::getFieldSplitedByType2(int iteration, int order, const std::string& mname, std::vector<INTERP_KERNEL::NormalizedCellType>& types, std::vector< std::vector<TypeOfField> >& typesF, std::vector< std::vector<std::string> >& pfls, std::vector< std::vector<std::string> >& locs) const
8917 return contentNotNull()->getFieldSplitedByType2(iteration,order,mname,types,typesF,pfls,locs);
8920 DataArrayDouble *MEDFileFieldMultiTS::getUndergroundDataArray(int iteration, int order) const
8922 return static_cast<DataArrayDouble *>(contentNotNull()->getUndergroundDataArray(iteration,order));
8925 DataArrayDouble *MEDFileFieldMultiTS::getUndergroundDataArrayExt(int iteration, int order, std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
8927 return static_cast<DataArrayDouble *>(contentNotNull()->getUndergroundDataArrayExt(iteration,order,entries));
8930 //= MEDFileAnyTypeFieldMultiTSIterator
8932 MEDFileAnyTypeFieldMultiTSIterator::MEDFileAnyTypeFieldMultiTSIterator(MEDFileAnyTypeFieldMultiTS *fmts):_fmts(fmts),_iter_id(0),_nb_iter(0)
8937 _nb_iter=fmts->getNumberOfTS();
8941 MEDFileAnyTypeFieldMultiTSIterator::~MEDFileAnyTypeFieldMultiTSIterator()
8945 MEDFileAnyTypeField1TS *MEDFileAnyTypeFieldMultiTSIterator::nextt()
8947 if(_iter_id<_nb_iter)
8949 MEDFileAnyTypeFieldMultiTS *fmts(_fmts);
8951 return fmts->getTimeStepAtPos(_iter_id++);
8959 //= MEDFileIntFieldMultiTS
8962 * Returns a new empty instance of MEDFileFieldMultiTS.
8963 * \return MEDFileIntFieldMultiTS * - a new instance of MEDFileIntFieldMultiTS. The caller
8964 * is to delete this field using decrRef() as it is no more needed.
8966 MEDFileIntFieldMultiTS *MEDFileIntFieldMultiTS::New()
8968 return new MEDFileIntFieldMultiTS;
8972 * Returns a new instance of MEDFileIntFieldMultiTS holding data of the first field
8973 * that has been read from a specified MED file.
8974 * \param [in] fileName - the name of the MED file to read.
8975 * \return MEDFileFieldMultiTS * - a new instance of MEDFileIntFieldMultiTS. The caller
8976 * is to delete this field using decrRef() as it is no more needed.
8977 * \throw If reading the file fails.
8979 MEDFileIntFieldMultiTS *MEDFileIntFieldMultiTS::New(const std::string& fileName, bool loadAll)
8981 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTS> ret=new MEDFileIntFieldMultiTS(fileName,loadAll);
8982 ret->contentNotNull();//to check that content type matches with \a this type.
8987 * Returns a new instance of MEDFileIntFieldMultiTS holding data of a given field
8988 * that has been read from a specified MED file.
8989 * \param [in] fileName - the name of the MED file to read.
8990 * \param [in] fieldName - the name of the field to read.
8991 * \return MEDFileFieldMultiTS * - a new instance of MEDFileIntFieldMultiTS. The caller
8992 * is to delete this field using decrRef() as it is no more needed.
8993 * \throw If reading the file fails.
8994 * \throw If there is no field named \a fieldName in the file.
8996 MEDFileIntFieldMultiTS *MEDFileIntFieldMultiTS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
8998 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTS> ret=new MEDFileIntFieldMultiTS(fileName,fieldName,loadAll);
8999 ret->contentNotNull();//to check that content type matches with \a this type.
9004 * Returns a new instance of MEDFileIntFieldMultiTS. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
9005 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
9007 * Returns a new instance of MEDFileIntFieldMultiTS holding either a shallow copy
9008 * of a given MEDFileIntFieldMultiTSWithoutSDA ( \a other ) or \a other itself.
9009 * \warning this is a shallow copy constructor
9010 * \param [in] other - a MEDFileIntField1TSWithoutSDA to copy.
9011 * \param [in] shallowCopyOfContent - if \c true, a shallow copy of \a other is created.
9012 * \return MEDFileIntFieldMultiTS * - a new instance of MEDFileIntFieldMultiTS. The caller
9013 * is to delete this field using decrRef() as it is no more needed.
9015 MEDFileIntFieldMultiTS *MEDFileIntFieldMultiTS::New(const MEDFileIntFieldMultiTSWithoutSDA& other, bool shallowCopyOfContent)
9017 return new MEDFileIntFieldMultiTS(other,shallowCopyOfContent);
9021 * This method performs a copy with datatype modification ( int32->float64 ) of \a this. The globals information are copied
9022 * following the given input policy.
9024 * \param [in] isDeepCpyGlobs - a boolean that indicates the behaviour concerning globals (profiles and localizations)
9025 * By default (true) the globals are deeply copied.
9026 * \return MEDFileFieldMultiTS * - a new object that is the result of the conversion of \a this to float64 field.
9028 MEDFileFieldMultiTS *MEDFileIntFieldMultiTS::convertToDouble(bool isDeepCpyGlobs) const
9030 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTS> ret;
9031 const MEDFileAnyTypeFieldMultiTSWithoutSDA *content(_content);
9034 const MEDFileIntFieldMultiTSWithoutSDA *contc=dynamic_cast<const MEDFileIntFieldMultiTSWithoutSDA *>(content);
9036 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::convertToInt : the content inside this is not INT32 ! This is incoherent !");
9037 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTSWithoutSDA> newc(contc->convertToDouble());
9038 ret=static_cast<MEDFileFieldMultiTS *>(MEDFileAnyTypeFieldMultiTS::BuildNewInstanceFromContent((MEDFileFieldMultiTSWithoutSDA *)newc,getFileName()));
9041 ret=MEDFileFieldMultiTS::New();
9043 ret->deepCpyGlobs(*this);
9045 ret->shallowCpyGlobs(*this);
9049 MEDFileAnyTypeFieldMultiTS *MEDFileIntFieldMultiTS::shallowCpy() const
9051 return new MEDFileIntFieldMultiTS(*this);
9054 void MEDFileIntFieldMultiTS::checkCoherencyOfType(const MEDFileAnyTypeField1TS *f1ts) const
9057 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::checkCoherencyOfType : input field1TS is NULL ! Impossible to check !");
9058 const MEDFileIntField1TS *f1tsC=dynamic_cast<const MEDFileIntField1TS *>(f1ts);
9060 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::checkCoherencyOfType : the input field1TS is not a INT32 type !");
9064 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
9065 * mesh entities of a given dimension of the first mesh in MED file.
9066 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9067 * \param [in] type - a spatial discretization of interest.
9068 * \param [in] iteration - the iteration number of a required time step.
9069 * \param [in] order - the iteration order number of required time step.
9070 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
9071 * \param [out] arrOut - the DataArrayInt containing values of field.
9072 * \param [in] renumPol - specifies how to permute values of the result field according to
9073 * the optional numbers of cells and nodes, if any. The valid values are
9074 * - 0 - do not permute.
9075 * - 1 - permute cells.
9076 * - 2 - permute nodes.
9077 * - 3 - permute cells and nodes.
9079 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
9080 * caller is to delete this field using decrRef() as it is no more needed.
9081 * \throw If the MED file is not readable.
9082 * \throw If there is no mesh in the MED file.
9083 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
9084 * \throw If no field values of the required parameters are available.
9086 MEDCouplingFieldDouble *MEDFileIntFieldMultiTS::getFieldAtLevel(TypeOfField type, int iteration, int order, int meshDimRelToMax, DataArrayInt* &arrOut, int renumPol) const
9088 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9089 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9091 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::getFieldAtLevel : mismatch of type of field expecting INT32 !");
9092 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
9093 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtLevel(type,meshDimRelToMax,std::string(),renumPol,this,arr,*contentNotNullBase());
9094 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
9099 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
9100 * the top level cells of the first mesh in MED file.
9101 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9102 * \param [in] type - a spatial discretization of interest.
9103 * \param [in] iteration - the iteration number of a required time step.
9104 * \param [in] order - the iteration order number of required time step.
9105 * \param [out] arrOut - the DataArrayInt containing values of field.
9106 * \param [in] renumPol - specifies how to permute values of the result field according to
9107 * the optional numbers of cells and nodes, if any. The valid values are
9108 * - 0 - do not permute.
9109 * - 1 - permute cells.
9110 * - 2 - permute nodes.
9111 * - 3 - permute cells and nodes.
9113 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
9114 * caller is to delete this field using decrRef() as it is no more needed.
9115 * \throw If the MED file is not readable.
9116 * \throw If there is no mesh in the MED file.
9117 * \throw If no field values of the required parameters are available.
9119 MEDCouplingFieldDouble *MEDFileIntFieldMultiTS::getFieldAtTopLevel(TypeOfField type, int iteration, int order, DataArrayInt* &arrOut, int renumPol) const
9121 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9122 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9124 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::getFieldAtTopLevel : mismatch of type of field ! INT32 expected !");
9125 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
9126 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtTopLevel(type,std::string(),renumPol,this,arr,*contentNotNullBase());
9127 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
9132 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
9134 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9135 * \param [in] type - a spatial discretization of interest.
9136 * \param [in] iteration - the iteration number of a required time step.
9137 * \param [in] order - the iteration order number of required time step.
9138 * \param [out] arrOut - the DataArrayInt containing values of field.
9139 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
9140 * \param [in] mesh - the supporting mesh.
9141 * \param [in] renumPol - specifies how to permute values of the result field according to
9142 * the optional numbers of cells and nodes, if any. The valid values are
9143 * - 0 - do not permute.
9144 * - 1 - permute cells.
9145 * - 2 - permute nodes.
9146 * - 3 - permute cells and nodes.
9148 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
9149 * caller is to delete this field using decrRef() as it is no more needed.
9150 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
9151 * \throw If no field of \a this is lying on \a mesh.
9152 * \throw If no field values of the required parameters are available.
9154 MEDCouplingFieldDouble *MEDFileIntFieldMultiTS::getFieldOnMeshAtLevel(TypeOfField type, int iteration, int order, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt* &arrOut, int renumPol) const
9156 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9157 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9159 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldOnMeshAtLevel : mismatch of type of field ! INT32 expected !");
9160 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
9161 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,this,mesh,arr,*contentNotNullBase());
9162 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
9167 * Returns a new MEDCouplingFieldDouble of given type, of a given time step, lying on a
9169 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9170 * \param [in] type - a spatial discretization of the new field.
9171 * \param [in] iteration - the iteration number of a required time step.
9172 * \param [in] order - the iteration order number of required time step.
9173 * \param [in] mesh - the supporting mesh.
9174 * \param [out] arrOut - the DataArrayInt containing values of field.
9175 * \param [in] renumPol - specifies how to permute values of the result field according to
9176 * the optional numbers of cells and nodes, if any. The valid values are
9177 * - 0 - do not permute.
9178 * - 1 - permute cells.
9179 * - 2 - permute nodes.
9180 * - 3 - permute cells and nodes.
9182 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
9183 * caller is to delete this field using decrRef() as it is no more needed.
9184 * \throw If no field of \a this is lying on \a mesh.
9185 * \throw If no field values of the required parameters are available.
9187 MEDCouplingFieldDouble *MEDFileIntFieldMultiTS::getFieldOnMeshAtLevel(TypeOfField type, int iteration, int order, const MEDCouplingMesh *mesh, DataArrayInt* &arrOut, int renumPol) const
9189 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9190 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9192 throw INTERP_KERNEL::Exception("MEDFileFieldIntMultiTS::getFieldOnMeshAtLevel : mismatch of type of field ! INT32 expected !");
9193 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
9194 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldOnMeshAtLevel(type,renumPol,this,mesh,0,0,arr,*contentNotNullBase());
9195 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
9200 * This method has a close behaviour than MEDFileIntFieldMultiTS::getFieldAtLevel.
9201 * This method is called 'old' because the user should give the mesh name he wants to use for it's field.
9202 * This method is useful for MED2 file format when field on different mesh was autorized.
9204 MEDCouplingFieldDouble *MEDFileIntFieldMultiTS::getFieldAtLevelOld(TypeOfField type, int iteration, int order, const std::string& mname, int meshDimRelToMax, DataArrayInt* &arrOut, int renumPol) const
9206 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9207 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9209 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldOnMeshAtLevel : mismatch of type of field ! INT32 expected !");
9210 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
9211 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtLevel(type,meshDimRelToMax,mname,renumPol,this,arr,*contentNotNullBase());
9212 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
9217 * Returns values and a profile of the field of a given type, of a given time step,
9218 * lying on a given support.
9219 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9220 * \param [in] type - a spatial discretization of the field.
9221 * \param [in] iteration - the iteration number of a required time step.
9222 * \param [in] order - the iteration order number of required time step.
9223 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
9224 * \param [in] mesh - the supporting mesh.
9225 * \param [out] pfl - a new instance of DataArrayInt holding ids of mesh entities the
9226 * field of interest lies on. If the field lies on all entities of the given
9227 * dimension, all ids in \a pfl are zero. The caller is to delete this array
9228 * using decrRef() as it is no more needed.
9229 * \param [in] glob - the global data storing profiles and localization.
9230 * \return DataArrayInt * - a new instance of DataArrayInt holding values of the
9231 * field. The caller is to delete this array using decrRef() as it is no more needed.
9232 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
9233 * \throw If no field of \a this is lying on \a mesh.
9234 * \throw If no field values of the required parameters are available.
9236 DataArrayInt *MEDFileIntFieldMultiTS::getFieldWithProfile(TypeOfField type, int iteration, int order, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt *&pfl) const
9238 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9239 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9241 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::getFieldWithProfile : mismatch of type of field ! INT32 expected !");
9242 MEDCouplingAutoRefCountObjectPtr<DataArray> ret=myF1TSC->getFieldWithProfile(type,meshDimRelToMax,mesh,pfl,this,*contentNotNullBase());
9243 return MEDFileIntField1TS::ReturnSafelyDataArrayInt(ret);
9247 * Returns a new MEDFileIntField1TS holding data of a given time step of \a this field.
9248 * \param [in] pos - a time step id.
9249 * \return MEDFileIntField1TS * - a new instance of MEDFileIntField1TS. The caller is to
9250 * delete this field using decrRef() as it is no more needed.
9251 * \throw If \a pos is not a valid time step id.
9253 MEDFileAnyTypeField1TS *MEDFileIntFieldMultiTS::getTimeStepAtPos(int pos) const
9255 const MEDFileAnyTypeField1TSWithoutSDA *item=contentNotNullBase()->getTimeStepAtPos2(pos);
9258 std::ostringstream oss; oss << "MEDFileIntFieldMultiTS::getTimeStepAtPos : field at pos #" << pos << " is null !";
9259 throw INTERP_KERNEL::Exception(oss.str().c_str());
9261 const MEDFileIntField1TSWithoutSDA *itemC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(item);
9264 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret=MEDFileIntField1TS::New(*itemC,false);
9265 ret->shallowCpyGlobs(*this);
9268 std::ostringstream oss; oss << "MEDFileIntFieldMultiTS::getTimeStepAtPos : type of field at pos #" << pos << " is not INT32 !";
9269 throw INTERP_KERNEL::Exception(oss.str().c_str());
9273 * Adds a MEDCouplingFieldDouble to \a this as another time step. The underlying mesh of
9274 * the given field is checked if its elements are sorted suitable for writing to MED file
9275 * ("STB" stands for "Sort By Type"), if not, an exception is thrown.
9276 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9277 * \param [in] field - the field to add to \a this.
9278 * \throw If the name of \a field is empty.
9279 * \throw If the data array of \a field is not set.
9280 * \throw If existing time steps have different name or number of components than \a field.
9281 * \throw If the underlying mesh of \a field has no name.
9282 * \throw If elements in the mesh are not in the order suitable for writing to the MED file.
9284 void MEDFileIntFieldMultiTS::appendFieldNoProfileSBT(const MEDCouplingFieldDouble *field, const DataArrayInt *arrOfVals)
9286 contentNotNull()->appendFieldNoProfileSBT(field,arrOfVals,*this);
9290 * Adds a MEDCouplingFieldDouble to \a this as another time step.
9291 * The mesh support of input parameter \a field is ignored here, it can be NULL.
9292 * The support of field \a field is expected to be those computed with the input parameter \a mesh, \a meshDimRelToMax,
9295 * This method will check that the field based on the computed support is coherent. If not an exception will be thrown.
9296 * A new profile is added only if no equal profile is missing.
9297 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9298 * \param [in] field - the field to add to \a this. The field double values and mesh support are ignored.
9299 * \param [in] arrOfVals - the values of the field \a field used.
9300 * \param [in] mesh - the supporting mesh of \a field.
9301 * \param [in] meshDimRelToMax - a relative dimension of mesh entities \a field lies on (useless if field spatial discretization is ON_NODES).
9302 * \param [in] profile - ids of mesh entities on which corresponding field values lie.
9303 * \throw If either \a field or \a mesh or \a profile has an empty name.
9304 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
9305 * \throw If the data array of \a field is not set.
9306 * \throw If the data array of \a this is already allocated but has different number of
9307 * components than \a field.
9308 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
9309 * \sa setFieldNoProfileSBT()
9311 void MEDFileIntFieldMultiTS::appendFieldProfile(const MEDCouplingFieldDouble *field, const DataArrayInt *arrOfVals, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile)
9313 contentNotNull()->appendFieldProfile(field,arrOfVals,mesh,meshDimRelToMax,profile,*this);
9316 const MEDFileIntFieldMultiTSWithoutSDA *MEDFileIntFieldMultiTS::contentNotNull() const
9318 const MEDFileAnyTypeFieldMultiTSWithoutSDA *pt(_content);
9320 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::contentNotNull : the content pointer is null !");
9321 const MEDFileIntFieldMultiTSWithoutSDA *ret=dynamic_cast<const MEDFileIntFieldMultiTSWithoutSDA *>(pt);
9323 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::contentNotNull : the content pointer is not null but it is not of type int ! Reason is maybe that the read field has not the type INT32 !");
9327 MEDFileIntFieldMultiTSWithoutSDA *MEDFileIntFieldMultiTS::contentNotNull()
9329 MEDFileAnyTypeFieldMultiTSWithoutSDA *pt(_content);
9331 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::contentNotNull : the non const content pointer is null !");
9332 MEDFileIntFieldMultiTSWithoutSDA *ret=dynamic_cast<MEDFileIntFieldMultiTSWithoutSDA *>(pt);
9334 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::contentNotNull : the non const content pointer is not null but it is not of type int ! Reason is maybe that the read field has not the type INT32 !");
9338 MEDFileIntFieldMultiTS::MEDFileIntFieldMultiTS()
9340 _content=new MEDFileIntFieldMultiTSWithoutSDA;
9343 MEDFileIntFieldMultiTS::MEDFileIntFieldMultiTS(const MEDFileIntFieldMultiTSWithoutSDA& other, bool shallowCopyOfContent):MEDFileAnyTypeFieldMultiTS(other,shallowCopyOfContent)
9347 MEDFileIntFieldMultiTS::MEDFileIntFieldMultiTS(const std::string& fileName, bool loadAll)
9348 try:MEDFileAnyTypeFieldMultiTS(fileName,loadAll)
9351 catch(INTERP_KERNEL::Exception& e)
9354 MEDFileIntFieldMultiTS::MEDFileIntFieldMultiTS(const std::string& fileName, const std::string& fieldName, bool loadAll)
9355 try:MEDFileAnyTypeFieldMultiTS(fileName,fieldName,loadAll)
9358 catch(INTERP_KERNEL::Exception& e)
9361 DataArrayInt *MEDFileIntFieldMultiTS::getUndergroundDataArray(int iteration, int order) const
9363 return static_cast<DataArrayInt *>(contentNotNull()->getUndergroundDataArray(iteration,order));
9368 MEDFileFields *MEDFileFields::New()
9370 return new MEDFileFields;
9373 MEDFileFields *MEDFileFields::New(const std::string& fileName, bool loadAll)
9375 return new MEDFileFields(fileName,loadAll);
9378 std::size_t MEDFileFields::getHeapMemorySizeWithoutChildren() const
9380 std::size_t ret(MEDFileFieldGlobsReal::getHeapMemorySizeWithoutChildren());
9381 ret+=_fields.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA>);
9385 std::vector<const BigMemoryObject *> MEDFileFields::getDirectChildren() const
9387 std::vector<const BigMemoryObject *> ret;
9388 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9390 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur(*it);
9397 MEDFileFields *MEDFileFields::deepCpy() const
9399 MEDCouplingAutoRefCountObjectPtr<MEDFileFields> ret=shallowCpy();
9401 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++,i++)
9403 if((const MEDFileAnyTypeFieldMultiTSWithoutSDA*)*it)
9404 ret->_fields[i]=(*it)->deepCpy();
9406 ret->deepCpyGlobs(*this);
9410 MEDFileFields *MEDFileFields::shallowCpy() const
9412 return new MEDFileFields(*this);
9416 * This method scans for all fields in \a this which time steps ids are common. Time step are discriminated by the pair of integer (iteration,order) whatever
9417 * the double time value. If all returned time steps are \b exactly those for all fields in \a this output parameter \a areThereSomeForgottenTS will be set to false.
9418 * If \a areThereSomeForgottenTS is set to true, only the sorted intersection of time steps present for all fields in \a this will be returned.
9420 * \param [out] areThereSomeForgottenTS - indicates to the caller if there is some time steps in \a this that are not present for all fields in \a this.
9421 * \return the sorted list of time steps (specified with a pair of integer iteration first and order second) present for all fields in \a this.
9423 * \sa MEDFileFields::partOfThisLyingOnSpecifiedTimeSteps, MEDFileFields::partOfThisNotLyingOnSpecifiedTimeSteps
9425 std::vector< std::pair<int,int> > MEDFileFields::getCommonIterations(bool& areThereSomeForgottenTS) const
9427 std::set< std::pair<int,int> > s;
9428 bool firstShot=true;
9429 areThereSomeForgottenTS=false;
9430 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9432 if(!(const MEDFileAnyTypeFieldMultiTSWithoutSDA*)*it)
9434 std::vector< std::pair<int,int> > v=(*it)->getIterations();
9435 std::set< std::pair<int,int> > s1; std::copy(v.begin(),v.end(),std::inserter(s1,s1.end()));
9437 { s=s1; firstShot=false; }
9440 std::set< std::pair<int,int> > s2; std::set_intersection(s.begin(),s.end(),s1.begin(),s1.end(),std::inserter(s2,s2.end()));
9442 areThereSomeForgottenTS=true;
9446 std::vector< std::pair<int,int> > ret;
9447 std::copy(s.begin(),s.end(),std::back_insert_iterator< std::vector< std::pair<int,int> > >(ret));
9451 int MEDFileFields::getNumberOfFields() const
9453 return _fields.size();
9456 std::vector<std::string> MEDFileFields::getFieldsNames() const
9458 std::vector<std::string> ret(_fields.size());
9460 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++,i++)
9462 const MEDFileAnyTypeFieldMultiTSWithoutSDA *f=(*it);
9465 ret[i]=f->getName();
9469 std::ostringstream oss; oss << "MEDFileFields::getFieldsNames : At rank #" << i << " field is not defined !";
9470 throw INTERP_KERNEL::Exception(oss.str().c_str());
9476 std::vector<std::string> MEDFileFields::getMeshesNames() const
9478 std::vector<std::string> ret;
9479 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9481 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur(*it);
9483 ret.push_back(cur->getMeshName());
9488 std::string MEDFileFields::simpleRepr() const
9490 std::ostringstream oss;
9491 oss << "(*****************)\n(* MEDFileFields *)\n(*****************)\n\n";
9496 void MEDFileFields::simpleRepr(int bkOffset, std::ostream& oss) const
9498 int nbOfFields=getNumberOfFields();
9499 std::string startLine(bkOffset,' ');
9500 oss << startLine << "There are " << nbOfFields << " fields in this :" << std::endl;
9502 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++,i++)
9504 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur=(*it);
9507 oss << startLine << " - # "<< i << " has the following name : \"" << cur->getName() << "\"." << std::endl;
9511 oss << startLine << " - not defined !" << std::endl;
9515 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++,i++)
9517 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur=(*it);
9518 std::string chapter(17,'0'+i);
9519 oss << startLine << chapter << std::endl;
9522 cur->simpleRepr(bkOffset+2,oss,i);
9526 oss << startLine << " - not defined !" << std::endl;
9528 oss << startLine << chapter << std::endl;
9530 simpleReprGlobs(oss);
9533 MEDFileFields::MEDFileFields()
9537 MEDFileFields::MEDFileFields(const std::string& fileName, bool loadAll)
9538 try:MEDFileFieldGlobsReal(fileName)
9540 MEDFileUtilities::CheckFileForRead(fileName);
9541 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
9542 int nbFields=MEDnField(fid);
9543 _fields.resize(nbFields);
9544 med_field_type typcha;
9545 for(int i=0;i<nbFields;i++)
9547 std::vector<std::string> infos;
9548 std::string fieldName,dtunit;
9549 int nbOfStep=MEDFileAnyTypeField1TS::LocateField2(fid,fileName,i,false,fieldName,typcha,infos,dtunit);
9554 _fields[i]=MEDFileFieldMultiTSWithoutSDA::New(fid,fieldName.c_str(),typcha,infos,nbOfStep,dtunit,loadAll);
9559 _fields[i]=MEDFileIntFieldMultiTSWithoutSDA::New(fid,fieldName.c_str(),typcha,infos,nbOfStep,dtunit,loadAll);
9564 std::ostringstream oss; oss << "constructor MEDFileFields(fileName) : file \'" << fileName << "\' at pos #" << i << " field has name \'" << fieldName << "\' but the type of field is not in [MED_FLOAT64, MED_INT32] !";
9565 throw INTERP_KERNEL::Exception(oss.str().c_str());
9569 loadAllGlobals(fid);
9571 catch(INTERP_KERNEL::Exception& e)
9576 void MEDFileFields::writeLL(med_idt fid) const
9579 writeGlobals(fid,*this);
9580 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++,i++)
9582 const MEDFileAnyTypeFieldMultiTSWithoutSDA *elt=*it;
9585 std::ostringstream oss; oss << "MEDFileFields::write : at rank #" << i << "/" << _fields.size() << " field is empty !";
9586 throw INTERP_KERNEL::Exception(oss.str().c_str());
9588 elt->writeLL(fid,*this);
9592 void MEDFileFields::write(const std::string& fileName, int mode) const
9594 med_access_mode medmod=MEDFileUtilities::TraduceWriteMode(mode);
9595 MEDFileUtilities::AutoFid fid(MEDfileOpen(fileName.c_str(),medmod));
9600 * This method alloc the arrays and load potentially huge arrays contained in this field.
9601 * This method should be called when a MEDFileAnyTypeFieldMultiTS::New constructor has been with false as the last parameter.
9602 * This method can be also called to refresh or reinit values from a file.
9604 * \throw If the fileName is not set or points to a non readable MED file.
9606 void MEDFileFields::loadArrays()
9608 if(getFileName().empty())
9609 throw INTERP_KERNEL::Exception("MEDFileFields::loadArrays : the structure does not come from a file !");
9610 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
9611 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::iterator it=_fields.begin();it!=_fields.end();it++)
9613 MEDFileAnyTypeFieldMultiTSWithoutSDA *elt(*it);
9615 elt->loadBigArraysRecursively(fid,*elt);
9620 * This method behaves as MEDFileFields::loadArrays does, the first call, if \a this was built using a file without loading big arrays.
9621 * But once data loaded once, this method does nothing.
9623 * \throw If the fileName is not set or points to a non readable MED file.
9624 * \sa MEDFileFields::loadArrays, MEDFileFields::unloadArrays
9626 void MEDFileFields::loadArraysIfNecessary()
9628 if(!getFileName().empty())
9630 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
9631 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::iterator it=_fields.begin();it!=_fields.end();it++)
9633 MEDFileAnyTypeFieldMultiTSWithoutSDA *elt(*it);
9635 elt->loadBigArraysRecursivelyIfNecessary(fid,*elt);
9641 * This method releases potentially big data arrays and so returns to the same heap memory than status loaded with 'loadAll' parameter set to false.
9642 * This method does not release arrays set outside the context of a MED file.
9644 * \sa MEDFileFields::loadArrays, MEDFileFields::loadArraysIfNecessary
9646 void MEDFileFields::unloadArrays()
9648 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::iterator it=_fields.begin();it!=_fields.end();it++)
9650 MEDFileAnyTypeFieldMultiTSWithoutSDA *elt(*it);
9652 elt->unloadArrays();
9656 std::vector<std::string> MEDFileFields::getPflsReallyUsed() const
9658 std::vector<std::string> ret;
9659 std::set<std::string> ret2;
9660 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9662 std::vector<std::string> tmp=(*it)->getPflsReallyUsed2();
9663 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
9664 if(ret2.find(*it2)==ret2.end())
9666 ret.push_back(*it2);
9673 std::vector<std::string> MEDFileFields::getLocsReallyUsed() const
9675 std::vector<std::string> ret;
9676 std::set<std::string> ret2;
9677 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9679 std::vector<std::string> tmp=(*it)->getLocsReallyUsed2();
9680 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
9681 if(ret2.find(*it2)==ret2.end())
9683 ret.push_back(*it2);
9690 std::vector<std::string> MEDFileFields::getPflsReallyUsedMulti() const
9692 std::vector<std::string> ret;
9693 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9695 std::vector<std::string> tmp=(*it)->getPflsReallyUsedMulti2();
9696 ret.insert(ret.end(),tmp.begin(),tmp.end());
9701 std::vector<std::string> MEDFileFields::getLocsReallyUsedMulti() const
9703 std::vector<std::string> ret;
9704 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9706 std::vector<std::string> tmp=(*it)->getLocsReallyUsed2();
9707 ret.insert(ret.end(),tmp.begin(),tmp.end());
9712 void MEDFileFields::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
9714 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::iterator it=_fields.begin();it!=_fields.end();it++)
9715 (*it)->changePflsRefsNamesGen2(mapOfModif);
9718 void MEDFileFields::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
9720 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::iterator it=_fields.begin();it!=_fields.end();it++)
9721 (*it)->changeLocsRefsNamesGen2(mapOfModif);
9724 void MEDFileFields::resize(int newSize)
9726 _fields.resize(newSize);
9729 void MEDFileFields::pushFields(const std::vector<MEDFileAnyTypeFieldMultiTS *>& fields)
9731 for(std::vector<MEDFileAnyTypeFieldMultiTS *>::const_iterator it=fields.begin();it!=fields.end();it++)
9735 void MEDFileFields::pushField(MEDFileAnyTypeFieldMultiTS *field)
9738 throw INTERP_KERNEL::Exception("MEDFileFields::pushMesh : invalid input pointer ! should be different from 0 !");
9739 _fields.push_back(field->getContent());
9740 appendGlobs(*field,1e-12);
9743 void MEDFileFields::setFieldAtPos(int i, MEDFileAnyTypeFieldMultiTS *field)
9746 throw INTERP_KERNEL::Exception("MEDFileFields::setFieldAtPos : invalid input pointer ! should be different from 0 !");
9747 if(i>=(int)_fields.size())
9748 _fields.resize(i+1);
9749 _fields[i]=field->getContent();
9750 appendGlobs(*field,1e-12);
9753 void MEDFileFields::destroyFieldAtPos(int i)
9755 destroyFieldsAtPos(&i,&i+1);
9758 void MEDFileFields::destroyFieldsAtPos(const int *startIds, const int *endIds)
9760 std::vector<bool> b(_fields.size(),true);
9761 for(const int *i=startIds;i!=endIds;i++)
9763 if(*i<0 || *i>=(int)_fields.size())
9765 std::ostringstream oss; oss << "MEDFileFields::destroyFieldsAtPos : Invalid given id in input (" << *i << ") should be in [0," << _fields.size() << ") !";
9766 throw INTERP_KERNEL::Exception(oss.str().c_str());
9770 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > fields(std::count(b.begin(),b.end(),true));
9772 for(std::size_t i=0;i<_fields.size();i++)
9774 fields[j++]=_fields[i];
9778 void MEDFileFields::destroyFieldsAtPos2(int bg, int end, int step)
9780 static const char msg[]="MEDFileFields::destroyFieldsAtPos2";
9781 int nbOfEntriesToKill=DataArrayInt::GetNumberOfItemGivenBESRelative(bg,end,step,msg);
9782 std::vector<bool> b(_fields.size(),true);
9784 for(int i=0;i<nbOfEntriesToKill;i++,k+=step)
9786 if(k<0 || k>=(int)_fields.size())
9788 std::ostringstream oss; oss << "MEDFileFields::destroyFieldsAtPos2 : Invalid given id in input (" << k << ") should be in [0," << _fields.size() << ") !";
9789 throw INTERP_KERNEL::Exception(oss.str().c_str());
9793 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > fields(std::count(b.begin(),b.end(),true));
9795 for(std::size_t i=0;i<_fields.size();i++)
9797 fields[j++]=_fields[i];
9801 bool MEDFileFields::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
9804 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::iterator it=_fields.begin();it!=_fields.end();it++)
9806 MEDFileAnyTypeFieldMultiTSWithoutSDA *cur(*it);
9808 ret=cur->changeMeshNames(modifTab) || ret;
9814 * \param [in] meshName the name of the mesh that will be renumbered.
9815 * \param [in] oldCode is of format returned by MEDCouplingUMesh::getDistributionOfTypes. And for each *i* oldCode[3*i+2] gives the position (MEDFileUMesh::PutInThirdComponentOfCodeOffset).
9816 * This code corresponds to the distribution of types in the corresponding mesh.
9817 * \param [in] newCode idem to param \a oldCode except that here the new distribution is given.
9818 * \param [in] renumO2N the old to new renumber array.
9819 * \return If true a renumbering has been performed. The structure in \a this has been modified. If false, nothing has been done: it is typically the case if \a meshName is not refered by any
9822 bool MEDFileFields::renumberEntitiesLyingOnMesh(const std::string& meshName, const std::vector<int>& oldCode, const std::vector<int>& newCode, const DataArrayInt *renumO2N)
9825 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::iterator it=_fields.begin();it!=_fields.end();it++)
9827 MEDFileAnyTypeFieldMultiTSWithoutSDA *fmts(*it);
9830 ret=fmts->renumberEntitiesLyingOnMesh(meshName,oldCode,newCode,renumO2N,*this) || ret;
9836 MEDFileAnyTypeFieldMultiTS *MEDFileFields::getFieldAtPos(int i) const
9838 if(i<0 || i>=(int)_fields.size())
9840 std::ostringstream oss; oss << "MEDFileFields::getFieldAtPos : Invalid given id in input (" << i << ") should be in [0," << _fields.size() << ") !";
9841 throw INTERP_KERNEL::Exception(oss.str().c_str());
9843 const MEDFileAnyTypeFieldMultiTSWithoutSDA *fmts=_fields[i];
9846 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret;
9847 const MEDFileFieldMultiTSWithoutSDA *fmtsC=dynamic_cast<const MEDFileFieldMultiTSWithoutSDA *>(fmts);
9848 const MEDFileIntFieldMultiTSWithoutSDA *fmtsC2=dynamic_cast<const MEDFileIntFieldMultiTSWithoutSDA *>(fmts);
9850 ret=MEDFileFieldMultiTS::New(*fmtsC,false);
9852 ret=MEDFileIntFieldMultiTS::New(*fmtsC2,false);
9855 std::ostringstream oss; oss << "MEDFileFields::getFieldAtPos : At pos #" << i << " field is neither double (FLOAT64) nor integer (INT32) !";
9856 throw INTERP_KERNEL::Exception(oss.str().c_str());
9858 ret->shallowCpyGlobs(*this);
9863 * Return a shallow copy of \a this reduced to the fields ids defined in [ \a startIds , endIds ).
9864 * This method is accessible in python using __getitem__ with a list in input.
9865 * \return a new object that the caller should deal with.
9867 MEDFileFields *MEDFileFields::buildSubPart(const int *startIds, const int *endIds) const
9869 MEDCouplingAutoRefCountObjectPtr<MEDFileFields> ret=shallowCpy();
9870 std::size_t sz=std::distance(startIds,endIds);
9871 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > fields(sz);
9873 for(const int *i=startIds;i!=endIds;i++,j++)
9875 if(*i<0 || *i>=(int)_fields.size())
9877 std::ostringstream oss; oss << "MEDFileFields::buildSubPart : Invalid given id in input (" << *i << ") should be in [0," << _fields.size() << ") !";
9878 throw INTERP_KERNEL::Exception(oss.str().c_str());
9880 fields[j]=_fields[*i];
9882 ret->_fields=fields;
9886 MEDFileAnyTypeFieldMultiTS *MEDFileFields::getFieldWithName(const std::string& fieldName) const
9888 return getFieldAtPos(getPosFromFieldName(fieldName));
9892 * This method returns a new object containing part of \a this fields lying on mesh name specified by the input parameter \a meshName.
9893 * This method can be seen as a filter applied on \a this, that returns an object containing
9894 * reduced the list of fields compared to those in \a this. The returned object is a new object but the object on which it lies are only
9895 * shallow copied from \a this.
9897 * \param [in] meshName - the name of the mesh on w
9898 * \return a new object that the caller should deal with.
9900 MEDFileFields *MEDFileFields::partOfThisLyingOnSpecifiedMeshName(const std::string& meshName) const
9902 MEDCouplingAutoRefCountObjectPtr<MEDFileFields> ret=MEDFileFields::New();
9903 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9905 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur=(*it);
9908 if(cur->getMeshName()==meshName)
9911 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> cur2(const_cast<MEDFileAnyTypeFieldMultiTSWithoutSDA *>(cur));
9912 ret->_fields.push_back(cur2);
9915 ret->shallowCpyOnlyUsedGlobs(*this);
9920 * This method returns a new object containing part of \a this fields lying ** exactly ** on the time steps specified by input parameter \a timeSteps.
9921 * Input time steps are specified using a pair of integer (iteration, order).
9922 * This method can be seen as a filter applied on \a this, that returns an object containing the same number of fields than those in \a this,
9923 * but for each multitimestep only the time steps in \a timeSteps are kept.
9924 * Typically the input parameter \a timeSteps comes from the call of MEDFileFields::getCommonIterations.
9926 * The returned object points to shallow copy of elements in \a this.
9928 * \param [in] timeSteps - the time steps given by a vector of pair of integers (iteration,order)
9929 * \throw If there is a field in \a this that is \b not defined on a time step in the input \a timeSteps.
9930 * \sa MEDFileFields::getCommonIterations, MEDFileFields::partOfThisNotLyingOnSpecifiedTimeSteps
9932 MEDFileFields *MEDFileFields::partOfThisLyingOnSpecifiedTimeSteps(const std::vector< std::pair<int,int> >& timeSteps) const
9934 MEDCouplingAutoRefCountObjectPtr<MEDFileFields> ret=MEDFileFields::New();
9935 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9937 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur=(*it);
9940 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> elt=cur->partOfThisLyingOnSpecifiedTimeSteps(timeSteps);
9941 ret->_fields.push_back(elt);
9943 ret->shallowCpyOnlyUsedGlobs(*this);
9948 * \sa MEDFileFields::getCommonIterations, MEDFileFields::partOfThisLyingOnSpecifiedTimeSteps
9950 MEDFileFields *MEDFileFields::partOfThisNotLyingOnSpecifiedTimeSteps(const std::vector< std::pair<int,int> >& timeSteps) const
9952 MEDCouplingAutoRefCountObjectPtr<MEDFileFields> ret=MEDFileFields::New();
9953 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9955 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur=(*it);
9958 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> elt=cur->partOfThisNotLyingOnSpecifiedTimeSteps(timeSteps);
9959 if(elt->getNumberOfTS()!=0)
9960 ret->_fields.push_back(elt);
9962 ret->shallowCpyOnlyUsedGlobs(*this);
9966 MEDFileFieldsIterator *MEDFileFields::iterator()
9968 return new MEDFileFieldsIterator(this);
9971 int MEDFileFields::getPosFromFieldName(const std::string& fieldName) const
9973 std::string tmp(fieldName);
9974 std::vector<std::string> poss;
9975 for(std::size_t i=0;i<_fields.size();i++)
9977 const MEDFileAnyTypeFieldMultiTSWithoutSDA *f=_fields[i];
9980 std::string fname(f->getName());
9984 poss.push_back(fname);
9987 std::ostringstream oss; oss << "MEDFileFields::getPosFromFieldName : impossible to find field '" << tmp << "' in this ! Possibilities are : ";
9988 std::copy(poss.begin(),poss.end(),std::ostream_iterator<std::string>(oss,", "));
9990 throw INTERP_KERNEL::Exception(oss.str().c_str());
9993 MEDFileFieldsIterator::MEDFileFieldsIterator(MEDFileFields *fs):_fs(fs),_iter_id(0),_nb_iter(0)
9998 _nb_iter=fs->getNumberOfFields();
10002 MEDFileFieldsIterator::~MEDFileFieldsIterator()
10006 MEDFileAnyTypeFieldMultiTS *MEDFileFieldsIterator::nextt()
10008 if(_iter_id<_nb_iter)
10010 MEDFileFields *fs(_fs);
10012 return fs->getFieldAtPos(_iter_id++);