1 // Copyright (C) 2007-2014 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, or (at your option) any later version.
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::getDirectChildrenWithNull() 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(bool isPflAlone, 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;
292 { const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(getGeoType()); oss << "_" << cm.getRepr(); }
299 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::assignFieldProfile : existing profile with empty name !");
300 if(_type!=ON_GAUSS_PT)
302 locIds->setName(oss.str().c_str());
303 glob.appendProfile(locIds);
312 _nval=idsInPfl->getNumberOfTuples();
313 getOrCreateAndGetArray()->setContigPartOfSelectedValues2(_start,arrr,0,arrr->getNumberOfTuples(),1);
319 _nval=idsInPfl->getNumberOfTuples();
320 getOrCreateAndGetArray()->setContigPartOfSelectedValues(_start,arrr,idsInPfl);
326 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr=field->getDiscretization()->getOffsetArr(mesh);
327 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr2=arr->deltaShiftIndex();
328 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr3=arr2->selectByTupleId(multiTypePfl->begin(),multiTypePfl->end());
329 arr3->computeOffsets2();
330 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> tmp=idsInPfl->buildExplicitArrByRanges(arr3);
331 int trueNval=tmp->getNumberOfTuples();
332 _nval=idsInPfl->getNumberOfTuples();
333 getOrCreateAndGetArray()->setContigPartOfSelectedValues(_start,arrr,tmp);
334 _end=_start+trueNval;
339 const MEDCouplingFieldDiscretizationGauss *disc2=dynamic_cast<const MEDCouplingFieldDiscretizationGauss *>(field->getDiscretization());
341 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : invalid call to this method ! Internal Error !");
342 const DataArrayInt *da1=disc2->getArrayOfDiscIds();
343 const MEDCouplingGaussLocalization& gsLoc=field->getGaussLocalization(_loc_id);
344 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da2=da1->selectByTupleId(idsInPfl->begin(),idsInPfl->end());
345 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da3=da2->getIdsEqual(_loc_id);
346 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da4=idsInPfl->selectByTupleId(da3->begin(),da3->end());
348 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> mesh2=mesh->buildPart(multiTypePfl->begin(),multiTypePfl->end());
349 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr=disc2->getOffsetArr(mesh2);
351 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> tmp=DataArrayInt::New();
353 for(const int *pt=da4->begin();pt!=da4->end();pt++)
354 trueNval+=arr->getIJ(*pt+1,0)-arr->getIJ(*pt,0);
355 tmp->alloc(trueNval,1);
356 int *tmpPtr=tmp->getPointer();
357 for(const int *pt=da4->begin();pt!=da4->end();pt++)
358 for(int j=arr->getIJ(*pt,0);j<arr->getIJ(*pt+1,0);j++)
361 _nval=da4->getNumberOfTuples();
362 getOrCreateAndGetArray()->setContigPartOfSelectedValues(_start,arrr,tmp);
363 _end=_start+trueNval;
364 oss << "_loc_" << _loc_id;
367 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da5=locIds->selectByTupleId(da3->begin(),da3->end());
368 da5->setName(oss.str().c_str());
369 glob.appendProfile(da5);
374 if(da3->getNumberOfTuples()!=nbOfEltsInWholeMesh || !da3->isIdentity())
376 da3->setName(oss.str().c_str());
377 glob.appendProfile(da3);
381 std::ostringstream oss2; oss2 << "Loc_" << nasc.getName() << "_" << INTERP_KERNEL::CellModel::GetCellModel(getGeoType()).getRepr() << "_" << _loc_id;
382 _localization=oss2.str();
383 glob.appendLoc(_localization.c_str(),getGeoType(),gsLoc.getRefCoords(),gsLoc.getGaussCoords(),gsLoc.getWeights());
387 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::assignFieldProfile : not implemented yet for such discretization type of field !");
392 void MEDFileFieldPerMeshPerTypePerDisc::assignNodeFieldNoProfile(int& start, const MEDCouplingFieldDouble *field, const DataArray *arrr, MEDFileFieldGlobsReal& glob)
395 _nval=arrr->getNumberOfTuples();
396 getOrCreateAndGetArray()->setContigPartOfSelectedValues2(_start,arrr,0,_nval,1);
401 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerTypePerDisc::NewOnRead(MEDFileFieldPerMeshPerType *fath, TypeOfField type, int profileIt, const PartDefinition *pd)
403 return new MEDFileFieldPerMeshPerTypePerDisc(fath,type,profileIt,pd);
406 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerTypePerDisc::New(MEDFileFieldPerMeshPerType *fath, TypeOfField type, int locId)
408 return new MEDFileFieldPerMeshPerTypePerDisc(fath,type,locId,std::string());
411 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerTypePerDisc::New(const MEDFileFieldPerMeshPerTypePerDisc& other)
413 return new MEDFileFieldPerMeshPerTypePerDisc(other);
416 std::size_t MEDFileFieldPerMeshPerTypePerDisc::getHeapMemorySizeWithoutChildren() const
418 return _profile.capacity()+_localization.capacity()+sizeof(MEDFileFieldPerMeshPerTypePerDisc);
421 std::vector<const BigMemoryObject *> MEDFileFieldPerMeshPerTypePerDisc::getDirectChildrenWithNull() const
423 std::vector<const BigMemoryObject *> ret(1);
424 ret[0]=(const PartDefinition*)_pd;
428 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerTypePerDisc::deepCpy(MEDFileFieldPerMeshPerType *father) const
430 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> ret=new MEDFileFieldPerMeshPerTypePerDisc(*this);
435 MEDFileFieldPerMeshPerTypePerDisc::MEDFileFieldPerMeshPerTypePerDisc(MEDFileFieldPerMeshPerType *fath, TypeOfField atype, int profileIt, const PartDefinition *pd)
436 try:_type(atype),_father(fath),_profile_it(profileIt),_pd(const_cast<PartDefinition *>(pd))
441 catch(INTERP_KERNEL::Exception& e)
446 MEDFileFieldPerMeshPerTypePerDisc::MEDFileFieldPerMeshPerTypePerDisc(MEDFileFieldPerMeshPerType *fath, TypeOfField type, int locId, const std::string& dummy):_type(type),_father(fath),_loc_id(locId)
450 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),_profile_it(other._profile_it),_pd(other._pd),_tmp_work1(other._tmp_work1)
454 MEDFileFieldPerMeshPerTypePerDisc::MEDFileFieldPerMeshPerTypePerDisc():_type(ON_CELLS),_father(0),_start(-std::numeric_limits<int>::max()),_end(-std::numeric_limits<int>::max()),
455 _nval(-std::numeric_limits<int>::max()),_loc_id(-std::numeric_limits<int>::max())
459 void MEDFileFieldPerMeshPerTypePerDisc::goReadZeValuesInFile(med_idt fid, const std::string& fieldName, int nbOfCompo, int iteration, int order, med_entity_type menti, med_geometry_type mgeoti, unsigned char *startFeedingPtr)
461 const PartDefinition *pd(_pd);
464 INTERP_KERNEL::AutoPtr<char> locname(MEDLoaderBase::buildEmptyString(MED_NAME_SIZE));
466 med_int nbValsInFile=MEDfieldnValueWithProfileByName(fid,fieldName.c_str(),iteration,order,menti,mgeoti,_profile.c_str(),MED_COMPACT_PFLMODE,&tmp1,locname,&nbi);
467 if(_end-_start!=nbValsInFile*nbi)
469 std::ostringstream oss; oss << "MEDFileFieldPerMeshPerTypePerDisc::goReadZeValuesInFile : The number of tuples to read is " << nbValsInFile << "*" << nbi << " (nb integration points) ! But in data structure it values " << _end-_start << " is expected !";
470 throw INTERP_KERNEL::Exception(oss.str().c_str());
472 MEDfieldValueWithProfileRd(fid,fieldName.c_str(),iteration,order,menti,mgeoti,MED_COMPACT_PFLMODE,_profile.c_str(),MED_FULL_INTERLACE,MED_ALL_CONSTITUENT,startFeedingPtr);
476 if(!_profile.empty())
477 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::goReadZeValuesInFile : not implemented !");
478 INTERP_KERNEL::AutoPtr<char> pflname(MEDLoaderBase::buildEmptyString(MED_NAME_SIZE)),locname(MEDLoaderBase::buildEmptyString(MED_NAME_SIZE));
480 int overallNval(MEDfieldnValueWithProfile(fid,fieldName.c_str(),iteration,order,menti,mgeoti,_profile_it+1,MED_COMPACT_PFLMODE,pflname,&profilesize,locname,&nbi));
481 const SlicePartDefinition *spd(dynamic_cast<const SlicePartDefinition *>(pd));
485 spd->getSlice(start,stop,step);
486 int nbOfEltsToLoad(DataArray::GetNumberOfItemGivenBES(start,stop,step,"MEDFileFieldPerMeshPerTypePerDisc::goReadZeValuesInFile"));
487 med_filter filter=MED_FILTER_INIT;
488 MEDfilterBlockOfEntityCr(fid,/*nentity*/overallNval,/*nvaluesperentity*/nbi,/*nconstituentpervalue*/nbOfCompo,
489 MED_ALL_CONSTITUENT,MED_FULL_INTERLACE,MED_COMPACT_STMODE,MED_NO_PROFILE,
490 /*start*/start+1,/*stride*/step,/*count*/1,/*blocksize*/nbOfEltsToLoad,
491 /*lastblocksize=useless because count=1*/0,&filter);
492 MEDfieldValueAdvancedRd(fid,fieldName.c_str(),iteration,order,menti,mgeoti,&filter,startFeedingPtr);
493 MEDfilterClose(&filter);
496 const DataArrayPartDefinition *dpd(dynamic_cast<const DataArrayPartDefinition *>(pd));
499 dpd->checkCoherency();
500 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> myIds(dpd->toDAI());
501 int a(myIds->getMinValueInArray()),b(myIds->getMaxValueInArray());
502 myIds->applyLin(1,-a);
503 int nbOfEltsToLoad(b-a+1);
504 med_filter filter=MED_FILTER_INIT;
505 {//TODO : manage int32 !
506 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> tmp(DataArrayDouble::New());
507 tmp->alloc(nbOfEltsToLoad,nbOfCompo);
508 MEDfilterBlockOfEntityCr(fid,/*nentity*/overallNval,/*nvaluesperentity*/nbi,/*nconstituentpervalue*/nbOfCompo,
509 MED_ALL_CONSTITUENT,MED_FULL_INTERLACE,MED_COMPACT_STMODE,MED_NO_PROFILE,
510 /*start*/a+1,/*stride*/1,/*count*/1,/*blocksize*/nbOfEltsToLoad,
511 /*lastblocksize=useless because count=1*/0,&filter);
512 MEDfieldValueAdvancedRd(fid,fieldName.c_str(),iteration,order,menti,mgeoti,&filter,reinterpret_cast<unsigned char *>(tmp->getPointer()));
513 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> feeder(DataArrayDouble::New());
514 feeder->useExternalArrayWithRWAccess(reinterpret_cast<double *>(startFeedingPtr),_nval,nbOfCompo);
515 feeder->setContigPartOfSelectedValues(0,tmp,myIds);
517 MEDfilterClose(&filter);
520 throw INTERP_KERNEL::Exception("Not implemented yet for not slices!");
524 const MEDFileFieldPerMeshPerType *MEDFileFieldPerMeshPerTypePerDisc::getFather() const
529 void MEDFileFieldPerMeshPerTypePerDisc::loadOnlyStructureOfDataRecursively(med_idt fid, int& start, const MEDFileFieldNameScope& nasc)
531 INTERP_KERNEL::AutoPtr<char> locname(MEDLoaderBase::buildEmptyString(MED_NAME_SIZE));
532 INTERP_KERNEL::AutoPtr<char> pflname(MEDLoaderBase::buildEmptyString(MED_NAME_SIZE));
533 std::string fieldName(nasc.getName()),meshName(getMeshName());
534 int iteration(getIteration()),order(getOrder());
535 TypeOfField type(getType());
536 INTERP_KERNEL::NormalizedCellType geoType(getGeoType());
538 med_geometry_type mgeoti;
539 med_entity_type menti(MEDFileFieldPerMeshPerType::ConvertIntoMEDFileType(type,geoType,mgeoti));
540 int zeNVal(MEDfieldnValueWithProfile(fid,fieldName.c_str(),iteration,order,menti,mgeoti,_profile_it+1,MED_COMPACT_PFLMODE,pflname,&profilesize,locname,&nbi));
541 _profile=MEDLoaderBase::buildStringFromFortran(pflname,MED_NAME_SIZE);
542 _localization=MEDLoaderBase::buildStringFromFortran(locname,MED_NAME_SIZE);
543 const PartDefinition *pd(_pd);
550 if(!_profile.empty())
551 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::loadOnlyStructureOfDataRecursively : profiles are not managed yet with part of def !");
552 _nval=pd->getNumberOfElems();
555 _end=start+_nval*nbi;
557 if(type==ON_CELLS && !_localization.empty())
559 if(_localization!="MED_GAUSS_ELNO")//For compatibily with MED2.3
560 setType(ON_GAUSS_PT);
563 setType(ON_GAUSS_NE);
564 _localization.clear();
569 void MEDFileFieldPerMeshPerTypePerDisc::loadBigArray(med_idt fid, const MEDFileFieldNameScope& nasc)
571 std::string fieldName(nasc.getName()),meshName(getMeshName());
572 int iteration(getIteration()),order(getOrder());
573 TypeOfField type(getType());
574 INTERP_KERNEL::NormalizedCellType geoType(getGeoType());
575 med_geometry_type mgeoti;
576 med_entity_type menti(MEDFileFieldPerMeshPerType::ConvertIntoMEDFileType(type,geoType,mgeoti));
578 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::loadBigArray : internal error in range !");
581 DataArray *arr(getOrCreateAndGetArray());//arr is not null due to the spec of getOrCreateAndGetArray
582 if(_start<0 || _start>=arr->getNumberOfTuples())
584 std::ostringstream oss; oss << "MEDFileFieldPerMeshPerTypePerDisc::loadBigArray : Invalid start ("<< _start << ") regarding admissible range of allocated array [0," << arr->getNumberOfTuples() << ") !";
585 throw INTERP_KERNEL::Exception(oss.str().c_str());
587 if(_end<0 || _end>arr->getNumberOfTuples())
589 std::ostringstream oss; oss << "MEDFileFieldPerMeshPerTypePerDisc::loadBigArray : Invalid start ("<< _start << ") regarding admissible range of allocated array [0," << arr->getNumberOfTuples() << "] !";
590 throw INTERP_KERNEL::Exception(oss.str().c_str());
592 int nbOfCompo(arr->getNumberOfComponents());
593 DataArrayDouble *arrD(dynamic_cast<DataArrayDouble *>(arr));
596 double *startFeeding(arrD->getPointer()+_start*nbOfCompo);
597 goReadZeValuesInFile(fid,fieldName,nbOfCompo,iteration,order,menti,mgeoti,reinterpret_cast<unsigned char*>(startFeeding));
600 DataArrayInt *arrI(dynamic_cast<DataArrayInt *>(arr));
603 int *startFeeding(arrI->getPointer()+_start*nbOfCompo);
604 goReadZeValuesInFile(fid,fieldName,nbOfCompo,iteration,order,menti,mgeoti,reinterpret_cast<unsigned char*>(startFeeding));
607 throw INTERP_KERNEL::Exception("Error on array reading ! Unrecognized type of field ! Should be in FLOAT64 or INT32 !");
611 * Set a \c this->_start **and** \c this->_end keeping the same delta between the two.
613 void MEDFileFieldPerMeshPerTypePerDisc::setNewStart(int newValueOfStart)
615 int delta=_end-_start;
616 _start=newValueOfStart;
620 int MEDFileFieldPerMeshPerTypePerDisc::getIteration() const
622 return _father->getIteration();
625 int MEDFileFieldPerMeshPerTypePerDisc::getOrder() const
627 return _father->getOrder();
630 double MEDFileFieldPerMeshPerTypePerDisc::getTime() const
632 return _father->getTime();
635 std::string MEDFileFieldPerMeshPerTypePerDisc::getMeshName() const
637 return _father->getMeshName();
640 void MEDFileFieldPerMeshPerTypePerDisc::simpleRepr(int bkOffset, std::ostream& oss, int id) const
642 const char startLine[]=" ## ";
643 std::string startLine2(bkOffset,' ');
644 startLine2+=startLine;
645 MEDCouplingFieldDiscretization *tmp=MEDCouplingFieldDiscretization::New(_type);
646 oss << startLine2 << "Localization #" << id << "." << std::endl;
647 oss << startLine2 << " Type=" << tmp->getRepr() << "." << std::endl;
649 oss << startLine2 << " This type discretization lies on profile : \"" << _profile << "\" and on the following localization : \"" << _localization << "\"." << std::endl;
650 oss << startLine2 << " This type discretization has " << _end-_start << " tuples (start=" << _start << ", end=" << _end << ")." << std::endl;
651 oss << startLine2 << " This type discretization has " << (_end-_start)/_nval << " integration points." << std::endl;
654 TypeOfField MEDFileFieldPerMeshPerTypePerDisc::getType() const
659 void MEDFileFieldPerMeshPerTypePerDisc::fillTypesOfFieldAvailable(std::set<TypeOfField>& types) const
664 void MEDFileFieldPerMeshPerTypePerDisc::setType(TypeOfField newType)
669 INTERP_KERNEL::NormalizedCellType MEDFileFieldPerMeshPerTypePerDisc::getGeoType() const
671 return _father->getGeoType();
674 int MEDFileFieldPerMeshPerTypePerDisc::getNumberOfComponents() const
676 return _father->getNumberOfComponents();
679 int MEDFileFieldPerMeshPerTypePerDisc::getNumberOfTuples() const
684 DataArray *MEDFileFieldPerMeshPerTypePerDisc::getOrCreateAndGetArray()
686 return _father->getOrCreateAndGetArray();
689 const DataArray *MEDFileFieldPerMeshPerTypePerDisc::getOrCreateAndGetArray() const
691 const MEDFileFieldPerMeshPerType *fath=_father;
692 return fath->getOrCreateAndGetArray();
695 const std::vector<std::string>& MEDFileFieldPerMeshPerTypePerDisc::getInfo() const
697 return _father->getInfo();
700 std::string MEDFileFieldPerMeshPerTypePerDisc::getProfile() const
705 void MEDFileFieldPerMeshPerTypePerDisc::setProfile(const std::string& newPflName)
710 std::string MEDFileFieldPerMeshPerTypePerDisc::getLocalization() const
712 return _localization;
715 void MEDFileFieldPerMeshPerTypePerDisc::setLocalization(const std::string& newLocName)
717 _localization=newLocName;
720 void MEDFileFieldPerMeshPerTypePerDisc::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
722 for(std::vector< std::pair<std::vector<std::string>, std::string > >::const_iterator it2=mapOfModif.begin();it2!=mapOfModif.end();it2++)
724 if(std::find((*it2).first.begin(),(*it2).first.end(),_profile)!=(*it2).first.end())
726 _profile=(*it2).second;
732 void MEDFileFieldPerMeshPerTypePerDisc::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
734 for(std::vector< std::pair<std::vector<std::string>, std::string > >::const_iterator it2=mapOfModif.begin();it2!=mapOfModif.end();it2++)
736 if(std::find((*it2).first.begin(),(*it2).first.end(),_localization)!=(*it2).first.end())
738 _localization=(*it2).second;
744 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
748 dads.push_back(std::pair<int,int>(_start,_end));
749 geoTypes.push_back(getGeoType());
754 pfls.push_back(glob->getProfile(_profile.c_str()));
756 if(_localization.empty())
760 locs.push_back(glob->getLocalizationId(_localization.c_str()));
764 void MEDFileFieldPerMeshPerTypePerDisc::fillValues(int discId, int& startEntryId, std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
766 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));
770 void MEDFileFieldPerMeshPerTypePerDisc::writeLL(med_idt fid, const MEDFileFieldNameScope& nasc) const
772 TypeOfField type=getType();
773 INTERP_KERNEL::NormalizedCellType geoType=getGeoType();
774 med_geometry_type mgeoti;
775 med_entity_type menti=MEDFileFieldPerMeshPerType::ConvertIntoMEDFileType(type,geoType,mgeoti);
776 const DataArray *arr=getOrCreateAndGetArray();
778 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::writeLL : no array set !");
779 const DataArrayDouble *arrD=dynamic_cast<const DataArrayDouble *>(arr);
780 const DataArrayInt *arrI=dynamic_cast<const DataArrayInt *>(arr);
781 const unsigned char *locToWrite=0;
783 locToWrite=reinterpret_cast<const unsigned char *>(arrD->getConstPointer()+_start*arr->getNumberOfComponents());
785 locToWrite=reinterpret_cast<const unsigned char *>(arrI->getConstPointer()+_start*arr->getNumberOfComponents());
787 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::writeLL : not recognized type of values ! Supported are FLOAT64 and INT32 !");
788 MEDfieldValueWithProfileWr(fid,nasc.getName().c_str(),getIteration(),getOrder(),getTime(),menti,mgeoti,
789 MED_COMPACT_PFLMODE,_profile.c_str(),_localization.c_str(),MED_FULL_INTERLACE,MED_ALL_CONSTITUENT,_nval,
793 void MEDFileFieldPerMeshPerTypePerDisc::getCoarseData(TypeOfField& type, std::pair<int,int>& dad, std::string& pfl, std::string& loc) const
798 dad.first=_start; dad.second=_end;
802 * \param [in] codeOfMesh is of format returned by MEDCouplingUMesh::getDistributionOfTypes. And for each *i* oldCode[3*i+2] gives the position (MEDFileUMesh::PutInThirdComponentOfCodeOffset).
803 * This code corresponds to the distribution of types in the corresponding mesh.
804 * \param [out] ptToFill memory zone where the output will be stored.
805 * \return the size of data pushed into output param \a ptToFill
807 int MEDFileFieldPerMeshPerTypePerDisc::fillEltIdsFromCode(int offset, const std::vector<int>& codeOfMesh, const MEDFileFieldGlobsReal& glob, int *ptToFill) const
810 std::ostringstream oss;
811 std::size_t nbOfType=codeOfMesh.size()/3;
813 for(std::size_t i=0;i<nbOfType && found==-1;i++)
814 if(getGeoType()==(INTERP_KERNEL::NormalizedCellType)codeOfMesh[3*i])
818 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(getGeoType());
819 oss << "MEDFileFieldPerMeshPerTypePerDisc::fillEltIdsFromCode : not found geometric type " << cm.getRepr() << " in the referenced mesh of field !";
820 throw INTERP_KERNEL::Exception(oss.str().c_str());
825 if(_nval!=codeOfMesh[3*found+1])
827 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(getGeoType());
828 oss << "MEDFileFieldPerMeshPerTypePerDisc::fillEltIdsFromCode : for geometric type " << cm.getRepr() << " number of elt ids in mesh is equal to " << _nval;
829 oss << " whereas mesh has " << codeOfMesh[3*found+1] << " for this geometric type !";
830 throw INTERP_KERNEL::Exception(oss.str().c_str());
832 for(int ii=codeOfMesh[3*found+2];ii<codeOfMesh[3*found+2]+_nval;ii++)
837 const DataArrayInt *pfl=glob.getProfile(_profile.c_str());
838 if(pfl->getNumberOfTuples()!=_nval)
840 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(getGeoType());
841 oss << "MEDFileFieldPerMeshPerTypePerDisc::fillEltIdsFromCode : for geometric type " << cm.getRepr() << ", field is defined on profile \"" << _profile << "\" and size of profile is ";
843 oss << pfl->getNumberOfTuples() << " whereas the number of ids is set to " << _nval << " for this geometric type !";
844 throw INTERP_KERNEL::Exception(oss.str().c_str());
846 int offset2=codeOfMesh[3*found+2];
847 for(const int *pflId=pfl->begin();pflId!=pfl->end();pflId++)
849 if(*pflId<codeOfMesh[3*found+1])
850 *work++=offset2+*pflId;
856 int MEDFileFieldPerMeshPerTypePerDisc::fillTupleIds(int *ptToFill) const
858 for(int i=_start;i<_end;i++)
863 int MEDFileFieldPerMeshPerTypePerDisc::ConvertType(TypeOfField type, int locId)
874 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::ConvertType : not managed type of field !");
878 std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> > MEDFileFieldPerMeshPerTypePerDisc::SplitPerDiscretization(const std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>& entries)
881 std::map<std::pair<std::string,TypeOfField>,int> m;
882 std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> > ret;
883 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=entries.begin();it!=entries.end();it++)
884 if(m.find(std::pair<std::string,TypeOfField>((*it)->getLocalization(),(*it)->getType()))==m.end())
885 m[std::pair<std::string,TypeOfField>((*it)->getLocalization(),(*it)->getType())]=id++;
887 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=entries.begin();it!=entries.end();it++)
888 ret[m[std::pair<std::string,TypeOfField>((*it)->getLocalization(),(*it)->getType())]].push_back(*it);
893 * - \c this->_loc_id mutable attribute is used for elt id in mesh offsets.
895 * \param [in] offset the offset id used to take into account that \a result is not compulsary empty in input
896 * \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.
897 * \param [in] explicitIdsInMesh ids in mesh of the considered chunk.
898 * \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)
899 * \param [in,out] glob if necessary by the method, new profiles can be added to it
900 * \param [in,out] arr after the call of this method \a arr is renumbered to be compliant with added entries to \a result.
901 * \param [out] result All new entries will be appended on it.
902 * \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 !)
904 bool MEDFileFieldPerMeshPerTypePerDisc::RenumberChunks(int offset, const std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>& entriesOnSameDisc,
905 const DataArrayInt *explicitIdsInMesh,
906 const std::vector<int>& newCode,
907 MEDFileFieldGlobsReal& glob, DataArrayDouble *arr,
908 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >& result)
910 if(entriesOnSameDisc.empty())
912 TypeOfField type=entriesOnSameDisc[0]->getType();
913 int szEntities=0,szTuples=0;
914 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=entriesOnSameDisc.begin();it!=entriesOnSameDisc.end();it++)
915 { szEntities+=(*it)->_nval; szTuples+=(*it)->_end-(*it)->_start; }
916 int nbi=szTuples/szEntities;
917 if(szTuples%szEntities!=0)
918 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::RenumberChunks : internal error the splitting into same dicretization failed !");
919 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> renumTuples=DataArrayInt::New(); renumTuples->alloc(szTuples,1);
920 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ranges=MEDCouplingUMesh::ComputeRangesFromTypeDistribution(newCode);
921 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > newGeoTypesPerChunk(entriesOnSameDisc.size());
922 std::vector< const DataArrayInt * > newGeoTypesPerChunk2(entriesOnSameDisc.size());
923 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > newGeoTypesPerChunk_bis(entriesOnSameDisc.size());
924 std::vector< const DataArrayInt * > newGeoTypesPerChunk3(entriesOnSameDisc.size());
925 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> newGeoTypesPerChunk4=DataArrayInt::New(); newGeoTypesPerChunk4->alloc(szEntities,nbi);
927 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=entriesOnSameDisc.begin();it!=entriesOnSameDisc.end();it++,id++)
929 int startOfEltIdOfChunk=(*it)->_start;
930 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> newEltIds=explicitIdsInMesh->substr(startOfEltIdOfChunk,startOfEltIdOfChunk+(*it)->_nval);
931 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> rangeIdsForChunk=newEltIds->findRangeIdForEachTuple(ranges);
932 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> idsInRrangeForChunk=newEltIds->findIdInRangeForEachTuple(ranges);
934 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> tmp=rangeIdsForChunk->duplicateEachTupleNTimes(nbi); rangeIdsForChunk->rearrange(nbi);
935 newGeoTypesPerChunk4->setPartOfValues1(tmp,(*it)->_tmp_work1-offset,(*it)->_tmp_work1+(*it)->_nval*nbi-offset,1,0,nbi,1);
937 newGeoTypesPerChunk[id]=rangeIdsForChunk; newGeoTypesPerChunk2[id]=rangeIdsForChunk;
938 newGeoTypesPerChunk_bis[id]=idsInRrangeForChunk; newGeoTypesPerChunk3[id]=idsInRrangeForChunk;
940 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> newGeoTypesEltIdsAllGather=DataArrayInt::Aggregate(newGeoTypesPerChunk2); newGeoTypesPerChunk.clear(); newGeoTypesPerChunk2.clear();
941 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> newGeoTypesEltIdsAllGather2=DataArrayInt::Aggregate(newGeoTypesPerChunk3); newGeoTypesPerChunk_bis.clear(); newGeoTypesPerChunk3.clear();
942 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> diffVals=newGeoTypesEltIdsAllGather->getDifferentValues();
943 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> renumEltIds=newGeoTypesEltIdsAllGather->buildPermArrPerLevel();
945 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> renumTupleIds=newGeoTypesPerChunk4->buildPermArrPerLevel();
947 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arrPart=arr->substr(offset,offset+szTuples);
948 arrPart->renumberInPlace(renumTupleIds->begin());
949 arr->setPartOfValues1(arrPart,offset,offset+szTuples,1,0,arrPart->getNumberOfComponents(),1);
951 const int *idIt=diffVals->begin();
952 std::list<const MEDFileFieldPerMeshPerTypePerDisc *> li(entriesOnSameDisc.begin(),entriesOnSameDisc.end());
954 for(int i=0;i<diffVals->getNumberOfTuples();i++,idIt++)
956 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ids=newGeoTypesEltIdsAllGather->getIdsEqual(*idIt);
957 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> subIds=newGeoTypesEltIdsAllGather2->selectByTupleId(ids->begin(),ids->end());
958 int nbEntityElts=subIds->getNumberOfTuples();
960 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> eltToAdd=MEDFileFieldPerMeshPerTypePerDisc::
961 NewObjectOnSameDiscThanPool(type,(INTERP_KERNEL::NormalizedCellType)newCode[3*(*idIt)],subIds,!subIds->isIdentity() || nbEntityElts!=newCode[3*(*idIt)+1],nbi,
965 result.push_back(eltToAdd);
966 offset2+=nbEntityElts*nbi;
968 ret=ret || li.empty();
973 * \param [in] typeF type of field of new chunk
974 * \param [in] geoType the geometric type of the chunk
975 * \param [in] idsOfMeshElt the entity ids of mesh (cells or nodes) of the new chunk.
976 * \param [in] isPfl specifies if a profile is requested regarding size of \a idsOfMeshElt and the number of such entities regarding underlying mesh.
977 * \param [in] nbi number of integration points
978 * \param [in] offset The offset in the **global array of data**.
979 * \param [in,out] entriesOnSameDisc the pool **on the same discretization** inside which it will be attempted to find an existing entry corresponding exactly
980 * to the new chunk to create.
981 * \param [in,out] glob the global shared info that will be requested for existing profiles or to append a new profile if needed.
982 * \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
983 * and corresponding entry erased from \a entriesOnSameDisc.
984 * \return a newly allocated chunk
986 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerTypePerDisc::NewObjectOnSameDiscThanPool(TypeOfField typeF, INTERP_KERNEL::NormalizedCellType geoType, DataArrayInt *idsOfMeshElt,
987 bool isPfl, int nbi, int offset,
988 std::list< const MEDFileFieldPerMeshPerTypePerDisc *>& entriesOnSameDisc,
989 MEDFileFieldGlobsReal& glob,
992 int nbMeshEntities=idsOfMeshElt->getNumberOfTuples();
993 std::list< const MEDFileFieldPerMeshPerTypePerDisc *>::iterator it=entriesOnSameDisc.begin();
994 for(;it!=entriesOnSameDisc.end();it++)
996 if(((INTERP_KERNEL::NormalizedCellType)(*it)->_loc_id)==geoType && (*it)->_nval==nbMeshEntities)
1000 if((*it)->_profile.empty())
1003 if(!(*it)->_profile.empty())
1005 const DataArrayInt *pfl=glob.getProfile((*it)->_profile.c_str());
1006 if(pfl->isEqualWithoutConsideringStr(*idsOfMeshElt))
1012 if(it==entriesOnSameDisc.end())
1015 MEDFileFieldPerMeshPerTypePerDisc *ret=new MEDFileFieldPerMeshPerTypePerDisc;
1017 ret->_loc_id=(int)geoType;
1018 ret->_nval=nbMeshEntities;
1020 ret->_end=ret->_start+ret->_nval*nbi;
1023 idsOfMeshElt->setName(glob.createNewNameOfPfl().c_str());
1024 glob.appendProfile(idsOfMeshElt);
1025 ret->_profile=idsOfMeshElt->getName();
1027 //tony treatment of localization
1032 notInExisting=false;
1033 MEDFileFieldPerMeshPerTypePerDisc *ret=MEDFileFieldPerMeshPerTypePerDisc::New(*(*it));
1034 ret->_loc_id=(int)geoType;
1035 ret->setNewStart(offset);
1036 entriesOnSameDisc.erase(it);
1042 MEDFileFieldPerMeshPerType *MEDFileFieldPerMeshPerType::NewOnRead(med_idt fid, MEDFileFieldPerMesh *fath, TypeOfField type, INTERP_KERNEL::NormalizedCellType geoType, const MEDFileFieldNameScope& nasc, const PartDefinition *pd)
1044 return new MEDFileFieldPerMeshPerType(fid,fath,type,geoType,nasc,pd);
1047 MEDFileFieldPerMeshPerType *MEDFileFieldPerMeshPerType::New(MEDFileFieldPerMesh *fath, INTERP_KERNEL::NormalizedCellType geoType)
1049 return new MEDFileFieldPerMeshPerType(fath,geoType);
1052 std::size_t MEDFileFieldPerMeshPerType::getHeapMemorySizeWithoutChildren() const
1054 return _field_pm_pt_pd.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc>);
1057 std::vector<const BigMemoryObject *> MEDFileFieldPerMeshPerType::getDirectChildrenWithNull() const
1059 std::vector<const BigMemoryObject *> ret;
1060 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1061 ret.push_back((const MEDFileFieldPerMeshPerTypePerDisc *)*it);
1065 MEDFileFieldPerMeshPerType *MEDFileFieldPerMeshPerType::deepCpy(MEDFileFieldPerMesh *father) const
1067 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerType> ret=new MEDFileFieldPerMeshPerType(*this);
1068 ret->_father=father;
1070 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++,i++)
1072 if((const MEDFileFieldPerMeshPerTypePerDisc *)*it)
1073 ret->_field_pm_pt_pd[i]=(*it)->deepCpy((MEDFileFieldPerMeshPerType *)ret);
1078 void MEDFileFieldPerMeshPerType::assignFieldNoProfile(int& start, int offset, int nbOfCells, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
1080 std::vector<int> pos=addNewEntryIfNecessary(field,offset,nbOfCells);
1081 for(std::vector<int>::const_iterator it=pos.begin();it!=pos.end();it++)
1082 _field_pm_pt_pd[*it]->assignFieldNoProfile(start,offset,nbOfCells,field,arr,glob,nasc);
1086 * This method is the most general one. No optimization is done here.
1087 * \param [in] multiTypePfl is the end user profile specified in high level API
1088 * \param [in] idsInPfl is the selection into the \a multiTypePfl whole profile that corresponds to the current geometric type.
1089 * \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.
1090 * \b WARNING if not null the MED file profile can be subdivided again in case of Gauss points.
1091 * \param [in] nbOfEltsInWholeMesh nb of elts of type \a this->_geo_type in \b WHOLE mesh
1092 * \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.
1094 void MEDFileFieldPerMeshPerType::assignFieldProfile(bool isPflAlone, 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)
1096 std::vector<int> pos=addNewEntryIfNecessary(field,idsInPfl);
1097 for(std::vector<int>::const_iterator it=pos.begin();it!=pos.end();it++)
1098 _field_pm_pt_pd[*it]->assignFieldProfile(isPflAlone,start,multiTypePfl,idsInPfl,locIds,nbOfEltsInWholeMesh,field,arr,mesh,glob,nasc);
1101 void MEDFileFieldPerMeshPerType::assignNodeFieldNoProfile(int& start, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob)
1103 _field_pm_pt_pd.resize(1);
1104 _field_pm_pt_pd[0]=MEDFileFieldPerMeshPerTypePerDisc::New(this,ON_NODES,-3);
1105 _field_pm_pt_pd[0]->assignNodeFieldNoProfile(start,field,arr,glob);
1108 void MEDFileFieldPerMeshPerType::assignNodeFieldProfile(int& start, const DataArrayInt *pfl, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
1110 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> pfl2=pfl->deepCpy();
1111 if(!arr || !arr->isAllocated())
1112 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerType::assignNodeFieldProfile : input array is null, or not allocated !");
1113 _field_pm_pt_pd.resize(1);
1114 _field_pm_pt_pd[0]=MEDFileFieldPerMeshPerTypePerDisc::New(this,ON_NODES,-3);
1115 _field_pm_pt_pd[0]->assignFieldProfile(true,start,pfl,pfl2,pfl2,-1,field,arr,0,glob,nasc);//mesh is not requested so 0 is send.
1118 std::vector<int> MEDFileFieldPerMeshPerType::addNewEntryIfNecessary(const MEDCouplingFieldDouble *field, int offset, int nbOfCells)
1120 TypeOfField type=field->getTypeOfField();
1121 if(type!=ON_GAUSS_PT)
1123 int locIdToFind=MEDFileFieldPerMeshPerTypePerDisc::ConvertType(type,0);
1124 int sz=_field_pm_pt_pd.size();
1126 for(int j=0;j<sz && !found;j++)
1128 if(_field_pm_pt_pd[j]->getLocId()==locIdToFind)
1130 _field_pm_pt_pd[j]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1136 _field_pm_pt_pd.resize(sz+1);
1137 _field_pm_pt_pd[sz]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1139 std::vector<int> ret(1,(int)sz);
1144 std::vector<int> ret2=addNewEntryIfNecessaryGauss(field,offset,nbOfCells);
1145 int sz2=ret2.size();
1146 std::vector<int> ret3(sz2);
1148 for(int i=0;i<sz2;i++)
1150 int sz=_field_pm_pt_pd.size();
1151 int locIdToFind=ret2[i];
1153 for(int j=0;j<sz && !found;j++)
1155 if(_field_pm_pt_pd[j]->getLocId()==locIdToFind)
1157 _field_pm_pt_pd[j]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1164 _field_pm_pt_pd.resize(sz+1);
1165 _field_pm_pt_pd[sz]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1173 std::vector<int> MEDFileFieldPerMeshPerType::addNewEntryIfNecessaryGauss(const MEDCouplingFieldDouble *field, int offset, int nbOfCells)
1175 const MEDCouplingFieldDiscretization *disc=field->getDiscretization();
1176 const MEDCouplingFieldDiscretizationGauss *disc2=dynamic_cast<const MEDCouplingFieldDiscretizationGauss *>(disc);
1178 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : invalid call to this method ! Internal Error !");
1179 const DataArrayInt *da=disc2->getArrayOfDiscIds();
1181 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss (no profile) : no localization ids per cell array available ! The input Gauss node field is maybe invalid !");
1182 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da2=da->selectByTupleId2(offset,offset+nbOfCells,1);
1183 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> retTmp=da2->getDifferentValues();
1184 if(retTmp->presenceOfValue(-1))
1185 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : some cells have no dicretization description !");
1186 std::vector<int> ret(retTmp->begin(),retTmp->end());
1190 std::vector<int> MEDFileFieldPerMeshPerType::addNewEntryIfNecessary(const MEDCouplingFieldDouble *field, const DataArrayInt *subCells)
1192 TypeOfField type=field->getTypeOfField();
1193 if(type!=ON_GAUSS_PT)
1195 int locIdToFind=MEDFileFieldPerMeshPerTypePerDisc::ConvertType(type,0);
1196 int sz=_field_pm_pt_pd.size();
1198 for(int j=0;j<sz && !found;j++)
1200 if(_field_pm_pt_pd[j]->getLocId()==locIdToFind)
1202 _field_pm_pt_pd[j]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1208 _field_pm_pt_pd.resize(sz+1);
1209 _field_pm_pt_pd[sz]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1211 std::vector<int> ret(1,0);
1216 std::vector<int> ret2=addNewEntryIfNecessaryGauss(field,subCells);
1217 int sz2=ret2.size();
1218 std::vector<int> ret3(sz2);
1220 for(int i=0;i<sz2;i++)
1222 int sz=_field_pm_pt_pd.size();
1223 int locIdToFind=ret2[i];
1225 for(int j=0;j<sz && !found;j++)
1227 if(_field_pm_pt_pd[j]->getLocId()==locIdToFind)
1229 _field_pm_pt_pd[j]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1236 _field_pm_pt_pd.resize(sz+1);
1237 _field_pm_pt_pd[sz]=MEDFileFieldPerMeshPerTypePerDisc::New(this,type,locIdToFind);
1245 std::vector<int> MEDFileFieldPerMeshPerType::addNewEntryIfNecessaryGauss(const MEDCouplingFieldDouble *field, const DataArrayInt *subCells)
1247 const MEDCouplingFieldDiscretization *disc=field->getDiscretization();
1248 const MEDCouplingFieldDiscretizationGauss *disc2=dynamic_cast<const MEDCouplingFieldDiscretizationGauss *>(disc);
1250 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : invalid call to this method ! Internal Error !");
1251 const DataArrayInt *da=disc2->getArrayOfDiscIds();
1253 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : no localization ids per cell array available ! The input Gauss node field is maybe invalid !");
1254 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da2=da->selectByTupleIdSafe(subCells->getConstPointer(),subCells->getConstPointer()+subCells->getNumberOfTuples());
1255 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> retTmp=da2->getDifferentValues();
1256 if(retTmp->presenceOfValue(-1))
1257 throw INTERP_KERNEL::Exception("addNewEntryIfNecessaryGauss : some cells have no dicretization description !");
1258 std::vector<int> ret(retTmp->begin(),retTmp->end());
1262 const MEDFileFieldPerMesh *MEDFileFieldPerMeshPerType::getFather() const
1267 void MEDFileFieldPerMeshPerType::getDimension(int& dim) const
1269 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1270 int curDim=(int)cm.getDimension();
1271 dim=std::max(dim,curDim);
1274 void MEDFileFieldPerMeshPerType::fillTypesOfFieldAvailable(std::set<TypeOfField>& types) const
1276 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1278 (*it)->fillTypesOfFieldAvailable(types);
1282 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
1284 int sz=_field_pm_pt_pd.size();
1285 dads.resize(sz); types.resize(sz); pfls.resize(sz); locs.resize(sz);
1286 for(int i=0;i<sz;i++)
1288 _field_pm_pt_pd[i]->getCoarseData(types[i],dads[i],pfls[i],locs[i]);
1292 int MEDFileFieldPerMeshPerType::getIteration() const
1294 return _father->getIteration();
1297 int MEDFileFieldPerMeshPerType::getOrder() const
1299 return _father->getOrder();
1302 double MEDFileFieldPerMeshPerType::getTime() const
1304 return _father->getTime();
1307 std::string MEDFileFieldPerMeshPerType::getMeshName() const
1309 return _father->getMeshName();
1312 void MEDFileFieldPerMeshPerType::simpleRepr(int bkOffset, std::ostream& oss, int id) const
1314 const char startLine[]=" ## ";
1315 std::string startLine2(bkOffset,' ');
1316 std::string startLine3(startLine2);
1317 startLine3+=startLine;
1318 if(_geo_type!=INTERP_KERNEL::NORM_ERROR)
1320 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1321 oss << startLine3 << "Entry geometry type #" << id << " is lying on geometry types " << cm.getRepr() << "." << std::endl;
1324 oss << startLine3 << "Entry geometry type #" << id << " is lying on NODES." << std::endl;
1325 oss << startLine3 << "Entry is defined on " << _field_pm_pt_pd.size() << " localizations." << std::endl;
1327 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++,i++)
1329 const MEDFileFieldPerMeshPerTypePerDisc *cur=(*it);
1331 cur->simpleRepr(bkOffset,oss,i);
1334 oss << startLine2 << " ## " << "Localization #" << i << " is empty !" << std::endl;
1339 void MEDFileFieldPerMeshPerType::getSizes(int& globalSz, int& nbOfEntries) const
1341 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1343 globalSz+=(*it)->getNumberOfTuples();
1345 nbOfEntries+=(int)_field_pm_pt_pd.size();
1348 INTERP_KERNEL::NormalizedCellType MEDFileFieldPerMeshPerType::getGeoType() const
1354 int MEDFileFieldPerMeshPerType::getNumberOfComponents() const
1356 return _father->getNumberOfComponents();
1359 bool MEDFileFieldPerMeshPerType::presenceOfMultiDiscPerGeoType() const
1362 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1364 const MEDFileFieldPerMeshPerTypePerDisc *fmtd(*it);
1371 DataArray *MEDFileFieldPerMeshPerType::getOrCreateAndGetArray()
1373 return _father->getOrCreateAndGetArray();
1376 const DataArray *MEDFileFieldPerMeshPerType::getOrCreateAndGetArray() const
1378 const MEDFileFieldPerMesh *fath=_father;
1379 return fath->getOrCreateAndGetArray();
1382 const std::vector<std::string>& MEDFileFieldPerMeshPerType::getInfo() const
1384 return _father->getInfo();
1387 std::vector<std::string> MEDFileFieldPerMeshPerType::getPflsReallyUsed() const
1389 std::vector<std::string> ret;
1390 std::set<std::string> ret2;
1391 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1393 std::string tmp=(*it1)->getProfile();
1395 if(ret2.find(tmp)==ret2.end())
1404 std::vector<std::string> MEDFileFieldPerMeshPerType::getLocsReallyUsed() const
1406 std::vector<std::string> ret;
1407 std::set<std::string> ret2;
1408 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1410 std::string tmp=(*it1)->getLocalization();
1411 if(!tmp.empty() && tmp!=MED_GAUSS_ELNO)
1412 if(ret2.find(tmp)==ret2.end())
1421 std::vector<std::string> MEDFileFieldPerMeshPerType::getPflsReallyUsedMulti() const
1423 std::vector<std::string> ret;
1424 std::set<std::string> ret2;
1425 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1427 std::string tmp=(*it1)->getProfile();
1434 std::vector<std::string> MEDFileFieldPerMeshPerType::getLocsReallyUsedMulti() const
1436 std::vector<std::string> ret;
1437 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1439 std::string tmp=(*it1)->getLocalization();
1440 if(!tmp.empty() && tmp!=MED_GAUSS_ELNO)
1446 void MEDFileFieldPerMeshPerType::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
1448 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1449 (*it1)->changePflsRefsNamesGen(mapOfModif);
1452 void MEDFileFieldPerMeshPerType::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
1454 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it1=_field_pm_pt_pd.begin();it1!=_field_pm_pt_pd.end();it1++)
1455 (*it1)->changeLocsRefsNamesGen(mapOfModif);
1458 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerType::getLeafGivenLocId(int locId)
1460 if(_field_pm_pt_pd.empty())
1462 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1463 std::ostringstream oss; oss << "MEDFileFieldPerMeshPerType::getLeafGivenLocId : no localizations for geotype \"" << cm.getRepr() << "\" !";
1464 throw INTERP_KERNEL::Exception(oss.str().c_str());
1466 if(locId>=0 && locId<(int)_field_pm_pt_pd.size())
1467 return _field_pm_pt_pd[locId];
1468 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1469 std::ostringstream oss2; oss2 << "MEDFileFieldPerMeshPerType::getLeafGivenLocId : no such locId available (" << locId;
1470 oss2 << ") for geometric type \"" << cm.getRepr() << "\" It should be in [0," << _field_pm_pt_pd.size() << ") !";
1471 throw INTERP_KERNEL::Exception(oss2.str().c_str());
1472 return static_cast<MEDFileFieldPerMeshPerTypePerDisc*>(0);
1475 const MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMeshPerType::getLeafGivenLocId(int locId) const
1477 if(_field_pm_pt_pd.empty())
1479 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1480 std::ostringstream oss; oss << "MEDFileFieldPerMeshPerType::getLeafGivenLocId : no localizations for geotype \"" << cm.getRepr() << "\" !";
1481 throw INTERP_KERNEL::Exception(oss.str().c_str());
1483 if(locId>=0 && locId<(int)_field_pm_pt_pd.size())
1484 return _field_pm_pt_pd[locId];
1485 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1486 std::ostringstream oss2; oss2 << "MEDFileFieldPerMeshPerType::getLeafGivenLocId : no such locId available (" << locId;
1487 oss2 << ") for geometric type \"" << cm.getRepr() << "\" It should be in [0," << _field_pm_pt_pd.size() << ") !";
1488 throw INTERP_KERNEL::Exception(oss2.str().c_str());
1489 return static_cast<const MEDFileFieldPerMeshPerTypePerDisc*>(0);
1492 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
1494 if(_geo_type!=INTERP_KERNEL::NORM_ERROR)
1496 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(_geo_type);
1497 if(meshDim!=(int)cm.getDimension())
1500 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1501 (*it)->getFieldAtLevel(type,glob,dads,pfls,locs,geoTypes);
1504 void MEDFileFieldPerMeshPerType::fillValues(int& startEntryId, std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
1507 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++,i++)
1509 (*it)->fillValues(i,startEntryId,entries);
1513 void MEDFileFieldPerMeshPerType::setLeaves(const std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerTypePerDisc > >& leaves)
1515 _field_pm_pt_pd=leaves;
1516 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1517 (*it)->setFather(this);
1521 * \param [in,out] globalNum a global numbering counter for the renumbering.
1522 * \param [out] its - list of pair (start,stop) kept
1523 * \return bool - false if the type of field \a tof is not contained in \a this.
1525 bool MEDFileFieldPerMeshPerType::keepOnlySpatialDiscretization(TypeOfField tof, int &globalNum, std::vector< std::pair<int,int> >& its)
1528 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> > newPmPtPd;
1529 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1530 if((*it)->getType()==tof)
1532 newPmPtPd.push_back(*it);
1533 std::pair<int,int> bgEnd; bgEnd.first=(*it)->getStart(); bgEnd.second=(*it)->getEnd();
1534 (*it)->setNewStart(globalNum);
1535 globalNum=(*it)->getEnd();
1536 its.push_back(bgEnd);
1540 _field_pm_pt_pd=newPmPtPd;
1545 * \param [in,out] globalNum a global numbering counter for the renumbering.
1546 * \param [out] its - list of pair (start,stop) kept
1547 * \return bool - false if the type of field \a tof is not contained in \a this.
1549 bool MEDFileFieldPerMeshPerType::keepOnlyGaussDiscretization(std::size_t idOfDisc, int &globalNum, std::vector< std::pair<int,int> >& its)
1551 if(_field_pm_pt_pd.size()<=idOfDisc)
1553 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> elt(_field_pm_pt_pd[idOfDisc]);
1554 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> > newPmPtPd(1,elt);
1555 std::pair<int,int> bgEnd; bgEnd.first=_field_pm_pt_pd[idOfDisc]->getStart(); bgEnd.second=_field_pm_pt_pd[idOfDisc]->getEnd();
1556 elt->setNewStart(globalNum);
1557 globalNum=elt->getEnd();
1558 its.push_back(bgEnd);
1559 _field_pm_pt_pd=newPmPtPd;
1563 MEDFileFieldPerMeshPerType::MEDFileFieldPerMeshPerType(MEDFileFieldPerMesh *fath, INTERP_KERNEL::NormalizedCellType geoType):_father(fath),_geo_type(geoType)
1567 MEDFileFieldPerMeshPerType::MEDFileFieldPerMeshPerType(med_idt fid, MEDFileFieldPerMesh *fath, TypeOfField type, INTERP_KERNEL::NormalizedCellType geoType, const MEDFileFieldNameScope& nasc, const PartDefinition *pd):_father(fath),_geo_type(geoType)
1569 INTERP_KERNEL::AutoPtr<char> pflName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
1570 INTERP_KERNEL::AutoPtr<char> locName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
1571 med_geometry_type mgeoti;
1572 med_entity_type menti(ConvertIntoMEDFileType(type,geoType,mgeoti));
1573 int nbProfiles(MEDfieldnProfile(fid,nasc.getName().c_str(),getIteration(),getOrder(),menti,mgeoti,pflName,locName));
1574 _field_pm_pt_pd.resize(nbProfiles);
1575 for(int i=0;i<nbProfiles;i++)
1577 _field_pm_pt_pd[i]=MEDFileFieldPerMeshPerTypePerDisc::NewOnRead(this,type,i,pd);
1581 int nbProfiles2=MEDfieldnProfile(fid,nasc.getName().c_str(),getIteration(),getOrder(),MED_NODE_ELEMENT,mgeoti,pflName,locName);
1582 for(int i=0;i<nbProfiles2;i++)
1583 _field_pm_pt_pd.push_back(MEDFileFieldPerMeshPerTypePerDisc::NewOnRead(this,ON_GAUSS_NE,i,pd));
1587 void MEDFileFieldPerMeshPerType::loadOnlyStructureOfDataRecursively(med_idt fid, int &start, const MEDFileFieldNameScope& nasc)
1589 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1590 (*it)->loadOnlyStructureOfDataRecursively(fid,start,nasc);
1593 void MEDFileFieldPerMeshPerType::loadBigArraysRecursively(med_idt fid, const MEDFileFieldNameScope& nasc)
1595 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1596 (*it)->loadBigArray(fid,nasc);
1599 void MEDFileFieldPerMeshPerType::writeLL(med_idt fid, const MEDFileFieldNameScope& nasc) const
1601 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> >::const_iterator it=_field_pm_pt_pd.begin();it!=_field_pm_pt_pd.end();it++)
1603 (*it)->copyOptionsFrom(*this);
1604 (*it)->writeLL(fid,nasc);
1608 med_entity_type MEDFileFieldPerMeshPerType::ConvertIntoMEDFileType(TypeOfField ikType, INTERP_KERNEL::NormalizedCellType ikGeoType, med_geometry_type& medfGeoType)
1613 medfGeoType=typmai3[(int)ikGeoType];
1616 medfGeoType=MED_NONE;
1619 medfGeoType=typmai3[(int)ikGeoType];
1620 return MED_NODE_ELEMENT;
1622 medfGeoType=typmai3[(int)ikGeoType];
1625 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerType::ConvertIntoMEDFileType : unexpected entity type ! internal error");
1627 return MED_UNDEF_ENTITY_TYPE;
1630 MEDFileFieldPerMesh *MEDFileFieldPerMesh::NewOnRead(med_idt fid, MEDFileAnyTypeField1TSWithoutSDA *fath, int meshCsit, int meshIteration, int meshOrder, const MEDFileFieldNameScope& nasc, const MEDFileMesh *mm)
1632 return new MEDFileFieldPerMesh(fid,fath,meshCsit,meshIteration,meshOrder,nasc,mm);
1635 MEDFileFieldPerMesh *MEDFileFieldPerMesh::New(MEDFileAnyTypeField1TSWithoutSDA *fath, const MEDCouplingMesh *mesh)
1637 return new MEDFileFieldPerMesh(fath,mesh);
1640 std::size_t MEDFileFieldPerMesh::getHeapMemorySizeWithoutChildren() const
1642 return _mesh_name.capacity()+_field_pm_pt.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType >);
1645 std::vector<const BigMemoryObject *> MEDFileFieldPerMesh::getDirectChildrenWithNull() const
1647 std::vector<const BigMemoryObject *> ret;
1648 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1649 ret.push_back((const MEDFileFieldPerMeshPerType *)*it);
1653 MEDFileFieldPerMesh *MEDFileFieldPerMesh::deepCpy(MEDFileAnyTypeField1TSWithoutSDA *father) const
1655 MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > ret=new MEDFileFieldPerMesh(*this);
1656 ret->_father=father;
1658 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++,i++)
1660 if((const MEDFileFieldPerMeshPerType *)*it)
1661 ret->_field_pm_pt[i]=(*it)->deepCpy((MEDFileFieldPerMesh *)(ret));
1666 void MEDFileFieldPerMesh::simpleRepr(int bkOffset, std::ostream& oss, int id) const
1668 std::string startLine(bkOffset,' ');
1669 oss << startLine << "## Field part (" << id << ") lying on mesh \"" << _mesh_name << "\", Mesh iteration=" << _mesh_iteration << ". Mesh order=" << _mesh_order << "." << std::endl;
1670 oss << startLine << "## Field is defined on " << _field_pm_pt.size() << " types." << std::endl;
1672 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++,i++)
1674 const MEDFileFieldPerMeshPerType *cur=*it;
1676 cur->simpleRepr(bkOffset,oss,i);
1679 oss << startLine << " ## Entry geometry type #" << i << " is empty !" << std::endl;
1684 void MEDFileFieldPerMesh::copyTinyInfoFrom(const MEDCouplingMesh *mesh)
1686 _mesh_name=mesh->getName();
1687 mesh->getTime(_mesh_iteration,_mesh_order);
1690 void MEDFileFieldPerMesh::assignFieldNoProfileNoRenum(int& start, const std::vector<int>& code, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
1692 int nbOfTypes=code.size()/3;
1694 for(int i=0;i<nbOfTypes;i++)
1696 INTERP_KERNEL::NormalizedCellType type=(INTERP_KERNEL::NormalizedCellType)code[3*i];
1697 int nbOfCells=code[3*i+1];
1698 int pos=addNewEntryIfNecessary(type);
1699 _field_pm_pt[pos]->assignFieldNoProfile(start,offset,nbOfCells,field,arr,glob,nasc);
1705 * This method is the most general one. No optimization is done here.
1706 * \param [in] multiTypePfl is the end user profile specified in high level API
1707 * \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].
1708 * \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.
1709 * \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.
1710 * \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.
1711 * \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.
1713 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)
1715 int nbOfTypes(code.size()/3);
1716 for(int i=0;i<nbOfTypes;i++)
1718 INTERP_KERNEL::NormalizedCellType type=(INTERP_KERNEL::NormalizedCellType)code[3*i];
1719 int pos=addNewEntryIfNecessary(type);
1720 DataArrayInt *pfl=0;
1722 pfl=idsPerType[code[3*i+2]];
1723 int nbOfTupes2=code2.size()/3;
1725 for(;found<nbOfTupes2;found++)
1726 if(code[3*i]==code2[3*found])
1728 if(found==nbOfTupes2)
1729 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::assignFieldProfile : internal problem ! Should never happen ! Please report bug to anthony.geay@cea.fr !");
1730 _field_pm_pt[pos]->assignFieldProfile(nbOfTypes==1,start,multiTypePfl,idsInPflPerType[i],pfl,code2[3*found+1],field,arr,mesh,glob,nasc);
1734 void MEDFileFieldPerMesh::assignNodeFieldNoProfile(int& start, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob)
1736 int pos=addNewEntryIfNecessary(INTERP_KERNEL::NORM_ERROR);
1737 _field_pm_pt[pos]->assignNodeFieldNoProfile(start,field,arr,glob);
1740 void MEDFileFieldPerMesh::assignNodeFieldProfile(int& start, const DataArrayInt *pfl, const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
1742 int pos=addNewEntryIfNecessary(INTERP_KERNEL::NORM_ERROR);
1743 _field_pm_pt[pos]->assignNodeFieldProfile(start,pfl,field,arr,glob,nasc);
1746 void MEDFileFieldPerMesh::loadOnlyStructureOfDataRecursively(med_idt fid, int& start, const MEDFileFieldNameScope& nasc)
1748 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1749 (*it)->loadOnlyStructureOfDataRecursively(fid,start,nasc);
1752 void MEDFileFieldPerMesh::loadBigArraysRecursively(med_idt fid, const MEDFileFieldNameScope& nasc)
1754 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1755 (*it)->loadBigArraysRecursively(fid,nasc);
1758 void MEDFileFieldPerMesh::writeLL(med_idt fid, const MEDFileFieldNameScope& nasc) const
1760 int nbOfTypes=_field_pm_pt.size();
1761 for(int i=0;i<nbOfTypes;i++)
1763 _field_pm_pt[i]->copyOptionsFrom(*this);
1764 _field_pm_pt[i]->writeLL(fid,nasc);
1768 void MEDFileFieldPerMesh::getDimension(int& dim) const
1770 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1771 (*it)->getDimension(dim);
1774 void MEDFileFieldPerMesh::fillTypesOfFieldAvailable(std::set<TypeOfField>& types) const
1776 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1777 (*it)->fillTypesOfFieldAvailable(types);
1780 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
1782 int sz=_field_pm_pt.size();
1783 std::vector< std::vector<std::pair<int,int> > > ret(sz);
1784 types.resize(sz); typesF.resize(sz); pfls.resize(sz); locs.resize(sz);
1785 for(int i=0;i<sz;i++)
1787 types[i]=_field_pm_pt[i]->getGeoType();
1788 _field_pm_pt[i]->fillFieldSplitedByType(ret[i],typesF[i],pfls[i],locs[i]);
1793 double MEDFileFieldPerMesh::getTime() const
1796 return _father->getTime(tmp1,tmp2);
1799 int MEDFileFieldPerMesh::getIteration() const
1801 return _father->getIteration();
1804 int MEDFileFieldPerMesh::getOrder() const
1806 return _father->getOrder();
1809 int MEDFileFieldPerMesh::getNumberOfComponents() const
1811 return _father->getNumberOfComponents();
1814 bool MEDFileFieldPerMesh::presenceOfMultiDiscPerGeoType() const
1816 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1818 const MEDFileFieldPerMeshPerType *fpmt(*it);
1821 if(fpmt->presenceOfMultiDiscPerGeoType())
1827 DataArray *MEDFileFieldPerMesh::getOrCreateAndGetArray()
1830 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getOrCreateAndGetArray : no father ! internal error !");
1831 return _father->getOrCreateAndGetArray();
1834 const DataArray *MEDFileFieldPerMesh::getOrCreateAndGetArray() const
1837 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getOrCreateAndGetArray : no father ! internal error !");
1838 return _father->getOrCreateAndGetArray();
1841 const std::vector<std::string>& MEDFileFieldPerMesh::getInfo() const
1843 return _father->getInfo();
1847 * type,geoTypes,dads,pfls,locs are input parameters. They should have the same size.
1848 * 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.
1849 * It returns 2 output vectors :
1850 * - 'code' of size 3*sz where sz is the number of different values into 'geoTypes'
1851 * - 'notNullPfls' contains sz2 values that are extracted from 'pfls' in which null profiles have been removed.
1852 * 'code' and 'notNullPfls' are in MEDCouplingUMesh::checkTypeConsistencyAndContig format.
1854 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)
1856 int notNullPflsSz=0;
1857 int nbOfArrs=geoTypes.size();
1858 for(int i=0;i<nbOfArrs;i++)
1861 std::set<INTERP_KERNEL::NormalizedCellType> geoTypes3(geoTypes.begin(),geoTypes.end());
1862 int nbOfDiffGeoTypes=geoTypes3.size();
1863 code.resize(3*nbOfDiffGeoTypes);
1864 notNullPfls.resize(notNullPflsSz);
1867 for(int i=0;i<nbOfDiffGeoTypes;i++)
1870 INTERP_KERNEL::NormalizedCellType refType=geoTypes[j];
1871 std::vector<const DataArrayInt *> notNullTmp;
1873 notNullTmp.push_back(pfls[j]);
1875 for(;j<nbOfArrs;j++)
1876 if(geoTypes[j]==refType)
1879 notNullTmp.push_back(pfls[j]);
1883 std::vector< std::pair<int,int> > tmpDads(dads.begin()+startZone,dads.begin()+j);
1884 std::vector<const DataArrayInt *> tmpPfls(pfls.begin()+startZone,pfls.begin()+j);
1885 std::vector<int> tmpLocs(locs.begin()+startZone,locs.begin()+j);
1886 code[3*i]=(int)refType;
1887 std::vector<INTERP_KERNEL::NormalizedCellType> refType2(1,refType);
1888 code[3*i+1]=ComputeNbOfElems(glob,type,refType2,tmpDads,tmpLocs);
1889 if(notNullTmp.empty())
1893 notNullPfls[notNullPflsSz]=DataArrayInt::Aggregate(notNullTmp);
1894 code[3*i+2]=notNullPflsSz++;
1900 * 'dads' 'geoTypes' and 'locs' are input parameters that should have same size sz. sz should be >=1.
1902 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)
1906 for(int i=0;i<sz;i++)
1910 if(type!=ON_GAUSS_NE)
1911 ret+=dads[i].second-dads[i].first;
1914 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(geoTypes[i]);
1915 ret+=(dads[i].second-dads[i].first)/cm.getNumberOfNodes();
1920 int nbOfGaussPtPerCell=glob->getNbOfGaussPtPerCell(locs[i]);
1921 ret+=(dads[i].second-dads[i].first)/nbOfGaussPtPerCell;
1927 std::vector<std::string> MEDFileFieldPerMesh::getPflsReallyUsed() const
1929 std::vector<std::string> ret;
1930 std::set<std::string> ret2;
1931 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1933 std::vector<std::string> tmp=(*it)->getPflsReallyUsed();
1934 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
1935 if(ret2.find(*it2)==ret2.end())
1937 ret.push_back(*it2);
1944 std::vector<std::string> MEDFileFieldPerMesh::getPflsReallyUsedMulti() const
1946 std::vector<std::string> ret;
1947 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1949 std::vector<std::string> tmp=(*it)->getPflsReallyUsedMulti();
1950 ret.insert(ret.end(),tmp.begin(),tmp.end());
1955 std::vector<std::string> MEDFileFieldPerMesh::getLocsReallyUsed() const
1957 std::vector<std::string> ret;
1958 std::set<std::string> ret2;
1959 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1961 std::vector<std::string> tmp=(*it)->getLocsReallyUsed();
1962 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
1963 if(ret2.find(*it2)==ret2.end())
1965 ret.push_back(*it2);
1972 std::vector<std::string> MEDFileFieldPerMesh::getLocsReallyUsedMulti() const
1974 std::vector<std::string> ret;
1975 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
1977 std::vector<std::string> tmp=(*it)->getLocsReallyUsedMulti();
1978 ret.insert(ret.end(),tmp.begin(),tmp.end());
1983 bool MEDFileFieldPerMesh::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
1985 for(std::vector< std::pair<std::string,std::string> >::const_iterator it=modifTab.begin();it!=modifTab.end();it++)
1987 if((*it).first==_mesh_name)
1989 _mesh_name=(*it).second;
1996 bool MEDFileFieldPerMesh::renumberEntitiesLyingOnMesh(const std::string& meshName, const std::vector<int>& oldCode, const std::vector<int>& newCode, const DataArrayInt *renumO2N,
1997 MEDFileFieldGlobsReal& glob)
1999 if(_mesh_name!=meshName)
2001 std::set<INTERP_KERNEL::NormalizedCellType> typesToKeep;
2002 for(std::size_t i=0;i<oldCode.size()/3;i++) typesToKeep.insert((INTERP_KERNEL::NormalizedCellType)oldCode[3*i]);
2003 std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > > entries;
2004 std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> entriesKept;
2005 std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> otherEntries;
2006 getUndergroundDataArrayExt(entries);
2007 DataArray *arr0=getOrCreateAndGetArray();//tony
2009 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::renumberEntitiesLyingOnMesh : DataArray storing values of field is null !");
2010 DataArrayDouble *arr=dynamic_cast<DataArrayDouble *>(arr0);//tony
2012 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::renumberEntitiesLyingOnMesh : DataArray storing values is double ! Not managed for the moment !");
2015 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::renumberEntitiesLyingOnMesh : DataArrayDouble storing values of field is null !");
2016 for(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >::const_iterator it=entries.begin();it!=entries.end();it++)
2018 if(typesToKeep.find((*it).first.first)!=typesToKeep.end())
2020 entriesKept.push_back(getLeafGivenTypeAndLocId((*it).first.first,(*it).first.second));
2021 sz+=(*it).second.second-(*it).second.first;
2024 otherEntries.push_back(getLeafGivenTypeAndLocId((*it).first.first,(*it).first.second));
2026 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> renumDefrag=DataArrayInt::New(); renumDefrag->alloc(arr->getNumberOfTuples(),1); renumDefrag->fillWithZero();
2027 ////////////////////
2028 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> explicitIdsOldInMesh=DataArrayInt::New(); explicitIdsOldInMesh->alloc(sz,1);//sz is a majorant of the real size. A realloc will be done after
2029 int *workI2=explicitIdsOldInMesh->getPointer();
2030 int sz1=0,sz2=0,sid=1;
2031 std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> > entriesKeptML=MEDFileFieldPerMeshPerTypePerDisc::SplitPerDiscretization(entriesKept);
2032 // std::vector<int> tupleIdOfStartOfNewChuncksV(entriesKeptML.size());
2033 for(std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> >::const_iterator itL1=entriesKeptML.begin();itL1!=entriesKeptML.end();itL1++,sid++)
2035 // tupleIdOfStartOfNewChuncksV[sid-1]=sz2;
2036 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> explicitIdsOldInArr=DataArrayInt::New(); explicitIdsOldInArr->alloc(sz,1);
2037 int *workI=explicitIdsOldInArr->getPointer();
2038 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator itL2=(*itL1).begin();itL2!=(*itL1).end();itL2++)
2040 int delta1=(*itL2)->fillTupleIds(workI); workI+=delta1; sz1+=delta1;
2041 (*itL2)->setLocId(sz2);
2042 (*itL2)->_tmp_work1=(*itL2)->getStart();
2043 int delta2=(*itL2)->fillEltIdsFromCode(sz2,oldCode,glob,workI2); workI2+=delta2; sz2+=delta2;
2045 renumDefrag->setPartOfValuesSimple3(sid,explicitIdsOldInArr->begin(),explicitIdsOldInArr->end(),0,1,1);
2047 explicitIdsOldInMesh->reAlloc(sz2);
2048 int tupleIdOfStartOfNewChuncks=arr->getNumberOfTuples()-sz2;
2049 ////////////////////
2050 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> permArrDefrag=renumDefrag->buildPermArrPerLevel(); renumDefrag=0;
2051 // perform redispatching of non concerned MEDFileFieldPerMeshPerTypePerDisc
2052 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> > otherEntriesNew;
2053 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=otherEntries.begin();it!=otherEntries.end();it++)
2055 otherEntriesNew.push_back(MEDFileFieldPerMeshPerTypePerDisc::New(*(*it)));
2056 otherEntriesNew.back()->setNewStart(permArrDefrag->getIJ((*it)->getStart(),0));
2057 otherEntriesNew.back()->setLocId((*it)->getGeoType());
2059 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> > entriesKeptNew;
2060 std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> entriesKeptNew2;
2061 for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator it=entriesKept.begin();it!=entriesKept.end();it++)
2063 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerTypePerDisc> elt=MEDFileFieldPerMeshPerTypePerDisc::New(*(*it));
2064 int newStart=elt->getLocId();
2065 elt->setLocId((*it)->getGeoType());
2066 elt->setNewStart(newStart);
2067 elt->_tmp_work1=permArrDefrag->getIJ(elt->_tmp_work1,0);
2068 entriesKeptNew.push_back(elt);
2069 entriesKeptNew2.push_back(elt);
2071 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arr2=arr->renumber(permArrDefrag->getConstPointer());
2072 // perform redispatching of concerned MEDFileFieldPerMeshPerTypePerDisc -> values are in arr2
2073 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> explicitIdsNewInMesh=renumO2N->selectByTupleId(explicitIdsOldInMesh->begin(),explicitIdsOldInMesh->end());
2074 std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> > entriesKeptPerDisc=MEDFileFieldPerMeshPerTypePerDisc::SplitPerDiscretization(entriesKeptNew2);
2076 for(std::vector< std::vector< const MEDFileFieldPerMeshPerTypePerDisc *> >::const_iterator it4=entriesKeptPerDisc.begin();it4!=entriesKeptPerDisc.end();it4++)
2079 /*for(std::vector< const MEDFileFieldPerMeshPerTypePerDisc *>::const_iterator itL2=(*it4).begin();itL2!=(*it4).end();itL2++)
2081 MEDFileFieldPerMeshPerTypePerDisc *curNC=const_cast<MEDFileFieldPerMeshPerTypePerDisc *>(*itL2);
2082 curNC->setNewStart(permArrDefrag->getIJ((*itL2)->getStart(),0)-tupleIdOfStartOfNewChuncks+tupleIdOfStartOfNewChuncksV[sid]);
2084 ret=MEDFileFieldPerMeshPerTypePerDisc::RenumberChunks(tupleIdOfStartOfNewChuncks,*it4,explicitIdsNewInMesh,newCode,
2085 glob,arr2,otherEntriesNew) || ret;
2089 // Assign new dispatching
2090 assignNewLeaves(otherEntriesNew);
2091 arr->cpyFrom(*arr2);
2096 * \param [in,out] globalNum a global numbering counter for the renumbering.
2097 * \param [out] its - list of pair (start,stop) kept
2099 void MEDFileFieldPerMesh::keepOnlySpatialDiscretization(TypeOfField tof, int &globalNum, std::vector< std::pair<int,int> >& its)
2101 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > > ret;
2102 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2104 std::vector< std::pair<int,int> > its2;
2105 if((*it)->keepOnlySpatialDiscretization(tof,globalNum,its2))
2108 its.insert(its.end(),its2.begin(),its2.end());
2115 * \param [in,out] globalNum a global numbering counter for the renumbering.
2116 * \param [out] its - list of pair (start,stop) kept
2118 void MEDFileFieldPerMesh::keepOnlyGaussDiscretization(std::size_t idOfDisc, int &globalNum, std::vector< std::pair<int,int> >& its)
2120 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > > ret;
2121 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2123 std::vector< std::pair<int,int> > its2;
2124 if((*it)->keepOnlyGaussDiscretization(idOfDisc,globalNum,its2))
2127 its.insert(its.end(),its2.begin(),its2.end());
2133 void MEDFileFieldPerMesh::assignNewLeaves(const std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerTypePerDisc > >& leaves)
2135 std::map<INTERP_KERNEL::NormalizedCellType,std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerTypePerDisc> > > types;
2136 for( std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerTypePerDisc > >::const_iterator it=leaves.begin();it!=leaves.end();it++)
2137 types[(INTERP_KERNEL::NormalizedCellType)(*it)->getLocId()].push_back(*it);
2139 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > > fieldPmPt(types.size());
2140 std::map<INTERP_KERNEL::NormalizedCellType,std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerTypePerDisc> > >::const_iterator it1=types.begin();
2141 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it2=fieldPmPt.begin();
2142 for(;it1!=types.end();it1++,it2++)
2144 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldPerMeshPerType> elt=MEDFileFieldPerMeshPerType::New(this,(INTERP_KERNEL::NormalizedCellType)((*it1).second[0]->getLocId()));
2145 elt->setLeaves((*it1).second);
2148 _field_pm_pt=fieldPmPt;
2151 void MEDFileFieldPerMesh::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
2153 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2154 (*it)->changePflsRefsNamesGen(mapOfModif);
2157 void MEDFileFieldPerMesh::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
2159 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2160 (*it)->changeLocsRefsNamesGen(mapOfModif);
2164 * \param [in] mesh is the whole mesh
2166 MEDCouplingFieldDouble *MEDFileFieldPerMesh::getFieldOnMeshAtLevel(TypeOfField type, const MEDFileFieldGlobsReal *glob, const MEDCouplingMesh *mesh, bool& isPfl, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
2168 if(_field_pm_pt.empty())
2169 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getFieldOnMeshAtLevel : no types field set !");
2171 std::vector< std::pair<int,int> > dads;
2172 std::vector<const DataArrayInt *> pfls;
2173 std::vector<DataArrayInt *> notNullPflsPerGeoType;
2174 std::vector<int> locs,code;
2175 std::vector<INTERP_KERNEL::NormalizedCellType> geoTypes;
2176 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2177 (*it)->getFieldAtLevel(mesh->getMeshDimension(),type,glob,dads,pfls,locs,geoTypes);
2179 SortArraysPerType(glob,type,geoTypes,dads,pfls,locs,code,notNullPflsPerGeoType);
2182 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getFieldOnMeshAtLevel : " << "The field \"" << nasc.getName() << "\" exists but not with such spatial discretization or such dimension specified !";
2183 throw INTERP_KERNEL::Exception(oss.str().c_str());
2186 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > notNullPflsPerGeoType2(notNullPflsPerGeoType.begin(),notNullPflsPerGeoType.end());
2187 std::vector< const DataArrayInt *> notNullPflsPerGeoType3(notNullPflsPerGeoType.begin(),notNullPflsPerGeoType.end());
2190 DataArrayInt *arr=mesh->checkTypeConsistencyAndContig(code,notNullPflsPerGeoType3);
2192 return finishField(type,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2195 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr2(arr);
2196 return finishField2(type,glob,dads,locs,geoTypes,mesh,arr,isPfl,arrOut,nasc);
2202 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getFieldOnMeshAtLevel : internal error #1 !");
2206 if(nb!=mesh->getNumberOfNodes())
2208 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getFieldOnMeshAtLevel : There is a problem there is " << nb << " nodes in field whereas there is " << mesh->getNumberOfNodes();
2209 oss << " nodes in mesh !";
2210 throw INTERP_KERNEL::Exception(oss.str().c_str());
2212 return finishField(type,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2215 return finishFieldNode2(glob,dads,locs,mesh,notNullPflsPerGeoType3[0],isPfl,arrOut,nasc);
2219 DataArray *MEDFileFieldPerMesh::getFieldOnMeshAtLevelWithPfl(TypeOfField type, const MEDCouplingMesh *mesh, DataArrayInt *&pfl, const MEDFileFieldGlobsReal *glob, const MEDFileFieldNameScope& nasc) const
2221 if(_field_pm_pt.empty())
2222 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getFieldOnMeshAtLevel : no types field set !");
2224 std::vector<std::pair<int,int> > dads;
2225 std::vector<const DataArrayInt *> pfls;
2226 std::vector<DataArrayInt *> notNullPflsPerGeoType;
2227 std::vector<int> locs,code;
2228 std::vector<INTERP_KERNEL::NormalizedCellType> geoTypes;
2229 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2230 (*it)->getFieldAtLevel(mesh->getMeshDimension(),type,glob,dads,pfls,locs,geoTypes);
2232 SortArraysPerType(glob,type,geoTypes,dads,pfls,locs,code,notNullPflsPerGeoType);
2235 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getFieldOnMeshAtLevelWithPfl : " << "The field \"" << nasc.getName() << "\" exists but not with such spatial discretization or such dimension specified !";
2236 throw INTERP_KERNEL::Exception(oss.str().c_str());
2238 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > notNullPflsPerGeoType2(notNullPflsPerGeoType.begin(),notNullPflsPerGeoType.end());
2239 std::vector< const DataArrayInt *> notNullPflsPerGeoType3(notNullPflsPerGeoType.begin(),notNullPflsPerGeoType.end());
2242 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr=mesh->checkTypeConsistencyAndContig(code,notNullPflsPerGeoType3);
2243 return finishField4(dads,arr,mesh->getNumberOfCells(),pfl);
2248 throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::getFieldOnMeshAtLevel : internal error #1 !");
2252 if(nb!=mesh->getNumberOfNodes())
2254 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getFieldOnMeshAtLevel : There is a problem there is " << nb << " nodes in field whereas there is " << mesh->getNumberOfNodes();
2255 oss << " nodes in mesh !";
2256 throw INTERP_KERNEL::Exception(oss.str().c_str());
2259 return finishField4(dads,code[2]==-1?0:notNullPflsPerGeoType3[0],mesh->getNumberOfNodes(),pfl);
2265 void MEDFileFieldPerMesh::getUndergroundDataArrayExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
2269 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2271 (*it)->getSizes(globalSz,nbOfEntries);
2273 entries.resize(nbOfEntries);
2275 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2277 (*it)->fillValues(nbOfEntries,entries);
2281 MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMesh::getLeafGivenTypeAndLocId(INTERP_KERNEL::NormalizedCellType typ, int locId)
2283 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2285 if((*it)->getGeoType()==typ)
2286 return (*it)->getLeafGivenLocId(locId);
2288 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(typ);
2289 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getLeafGivenTypeAndLocId : no such geometric type \"" << cm.getRepr() << "\" in this !" << std::endl;
2290 oss << "Possiblities are : ";
2291 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2293 const INTERP_KERNEL::CellModel& cm2=INTERP_KERNEL::CellModel::GetCellModel((*it)->getGeoType());
2294 oss << "\"" << cm2.getRepr() << "\", ";
2296 throw INTERP_KERNEL::Exception(oss.str().c_str());
2299 const MEDFileFieldPerMeshPerTypePerDisc *MEDFileFieldPerMesh::getLeafGivenTypeAndLocId(INTERP_KERNEL::NormalizedCellType typ, int locId) const
2301 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2303 if((*it)->getGeoType()==typ)
2304 return (*it)->getLeafGivenLocId(locId);
2306 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(typ);
2307 std::ostringstream oss; oss << "MEDFileFieldPerMesh::getLeafGivenTypeAndLocId : no such geometric type \"" << cm.getRepr() << "\" in this !" << std::endl;
2308 oss << "Possiblities are : ";
2309 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::const_iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++)
2311 const INTERP_KERNEL::CellModel& cm2=INTERP_KERNEL::CellModel::GetCellModel((*it)->getGeoType());
2312 oss << "\"" << cm2.getRepr() << "\", ";
2314 throw INTERP_KERNEL::Exception(oss.str().c_str());
2317 int MEDFileFieldPerMesh::addNewEntryIfNecessary(INTERP_KERNEL::NormalizedCellType type)
2320 int pos=std::distance(typmai2,std::find(typmai2,typmai2+MED_N_CELL_FIXED_GEO,type));
2321 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it2=_field_pm_pt.begin();
2322 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMeshPerType > >::iterator it=_field_pm_pt.begin();it!=_field_pm_pt.end();it++,i++)
2324 INTERP_KERNEL::NormalizedCellType curType=(*it)->getGeoType();
2329 int pos2=std::distance(typmai2,std::find(typmai2,typmai2+MED_N_CELL_FIXED_GEO,curType));
2334 int ret=std::distance(_field_pm_pt.begin(),it2);
2335 _field_pm_pt.insert(it2,MEDFileFieldPerMeshPerType::New(this,type));
2340 * 'dads' and 'locs' input parameters have the same number of elements
2341 * \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
2343 MEDCouplingFieldDouble *MEDFileFieldPerMesh::finishField(TypeOfField type, const MEDFileFieldGlobsReal *glob,
2344 const std::vector< std::pair<int,int> >& dads, const std::vector<int>& locs,
2345 const MEDCouplingMesh *mesh, bool& isPfl, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
2348 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=MEDCouplingFieldDouble::New(type,ONE_TIME);
2349 ret->setMesh(mesh); ret->setName(nasc.getName().c_str()); ret->setTime(getTime(),getIteration(),getOrder()); ret->setTimeUnit(nasc.getDtUnit().c_str());
2350 MEDCouplingAutoRefCountObjectPtr<DataArray> da=getOrCreateAndGetArray()->selectByTupleRanges(dads);
2351 const std::vector<std::string>& infos=getInfo();
2352 da->setInfoOnComponents(infos);
2354 if(type==ON_GAUSS_PT)
2357 int nbOfArrs=dads.size();
2358 for(int i=0;i<nbOfArrs;i++)
2360 std::vector<std::pair<int,int> > dads2(1,dads[i]); const std::vector<int> locs2(1,locs[i]);
2361 const std::vector<INTERP_KERNEL::NormalizedCellType> geoTypes2(1,INTERP_KERNEL::NORM_ERROR);
2362 int nbOfElems=ComputeNbOfElems(glob,type,geoTypes2,dads2,locs2);
2363 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> di=DataArrayInt::New();
2364 di->alloc(nbOfElems,1);
2366 const MEDFileFieldLoc& fl=glob->getLocalizationFromId(locs[i]);
2367 ret->setGaussLocalizationOnCells(di->getConstPointer(),di->getConstPointer()+nbOfElems,fl.getRefCoords(),fl.getGaussCoords(),fl.getGaussWeights());
2376 * 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.
2377 * 'dads', 'locs' and 'geoTypes' input parameters have the same number of elements.
2378 * No check of this is performed. 'da' array contains an array in old2New style to be applyied to mesh to obtain the right support.
2379 * The order of cells in the returned field is those imposed by the profile.
2380 * \param [in] mesh is the global mesh.
2382 MEDCouplingFieldDouble *MEDFileFieldPerMesh::finishField2(TypeOfField type, const MEDFileFieldGlobsReal *glob,
2383 const std::vector<std::pair<int,int> >& dads, const std::vector<int>& locs,
2384 const std::vector<INTERP_KERNEL::NormalizedCellType>& geoTypes,
2385 const MEDCouplingMesh *mesh, const DataArrayInt *da, bool& isPfl, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
2387 if(da->isIdentity())
2389 int nbOfTuples=da->getNumberOfTuples();
2390 if(nbOfTuples==mesh->getNumberOfCells())
2391 return finishField(type,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2393 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> m2=mesh->buildPart(da->getConstPointer(),da->getConstPointer()+da->getNbOfElems());
2394 m2->setName(mesh->getName().c_str());
2395 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=finishField(type,glob,dads,locs,m2,isPfl,arrOut,nasc);
2401 * This method is the complement of MEDFileFieldPerMesh::finishField2 method except that this method works for node profiles.
2403 MEDCouplingFieldDouble *MEDFileFieldPerMesh::finishFieldNode2(const MEDFileFieldGlobsReal *glob,
2404 const std::vector<std::pair<int,int> >& dads, const std::vector<int>& locs,
2405 const MEDCouplingMesh *mesh, const DataArrayInt *da, bool& isPfl, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
2407 if(da->isIdentity())
2409 int nbOfTuples=da->getNumberOfTuples();
2410 if(nbOfTuples==mesh->getNumberOfNodes())//No problem for NORM_ERROR because it is in context of node
2411 return finishField(ON_NODES,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2413 // Treatment of particular case where nodal field on pfl is requested with a meshDimRelToMax=1.
2414 const MEDCouplingUMesh *meshu=dynamic_cast<const MEDCouplingUMesh *>(mesh);
2417 if(meshu->getNodalConnectivity()==0)
2419 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=finishField(ON_CELLS,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2420 int nb=da->getNbOfElems();
2421 const int *ptr=da->getConstPointer();
2422 MEDCouplingUMesh *meshuc=const_cast<MEDCouplingUMesh *>(meshu);
2423 meshuc->allocateCells(nb);
2424 for(int i=0;i<nb;i++)
2425 meshuc->insertNextCell(INTERP_KERNEL::NORM_POINT1,1,ptr+i);
2426 meshuc->finishInsertingCells();
2427 ret->setMesh(meshuc);
2428 const MEDCouplingFieldDiscretization *disc=ret->getDiscretization();
2429 if(!disc) throw INTERP_KERNEL::Exception("MEDFileFieldPerMesh::finishFieldNode2 : internal error, no discretization on field !");
2430 disc->checkCoherencyBetween(meshuc,arrOut);
2435 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=finishField(ON_NODES,glob,dads,locs,mesh,isPfl,arrOut,nasc);
2437 DataArrayInt *arr2=0;
2438 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> cellIds=mesh->getCellIdsFullyIncludedInNodeIds(da->getConstPointer(),da->getConstPointer()+da->getNbOfElems());
2439 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> mesh2=mesh->buildPartAndReduceNodes(cellIds->getConstPointer(),cellIds->getConstPointer()+cellIds->getNbOfElems(),arr2);
2440 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr3(arr2);
2441 int nnodes=mesh2->getNumberOfNodes();
2442 if(nnodes==(int)da->getNbOfElems())
2444 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da3=da->transformWithIndArrR(arr2->begin(),arr2->end());
2445 arrOut->renumberInPlace(da3->getConstPointer());
2446 mesh2->setName(mesh->getName().c_str());
2447 ret->setMesh(mesh2);
2452 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 !!!";
2453 oss << "So it is impossible to return a well definied MEDCouplingFieldDouble instance on specified mesh on a specified meshDim !" << std::endl;
2454 oss << "To retrieve correctly such a field you have 3 possibilities :" << std::endl;
2455 oss << " - use an another meshDim compatible with the field on nodes (MED file does not have such information)" << std::endl;
2456 oss << " - use an another a meshDimRelToMax equal to 1 -> it will return a mesh with artificial cell POINT1 containing the profile !" << std::endl;
2457 oss << " - if definitely the node profile has no link with mesh connectivity use MEDFileField1TS::getFieldWithProfile or MEDFileFieldMultiTS::getFieldWithProfile methods instead !";
2458 throw INTERP_KERNEL::Exception(oss.str().c_str());
2464 * This method is the most light method of field retrieving.
2466 DataArray *MEDFileFieldPerMesh::finishField4(const std::vector<std::pair<int,int> >& dads, const DataArrayInt *pflIn, int nbOfElems, DataArrayInt *&pflOut) const
2470 pflOut=DataArrayInt::New();
2471 pflOut->alloc(nbOfElems,1);
2476 pflOut=const_cast<DataArrayInt*>(pflIn);
2479 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> safePfl(pflOut);
2480 MEDCouplingAutoRefCountObjectPtr<DataArray> da=getOrCreateAndGetArray()->selectByTupleRanges(dads);
2481 const std::vector<std::string>& infos=getInfo();
2482 int nbOfComp=infos.size();
2483 for(int i=0;i<nbOfComp;i++)
2484 da->setInfoOnComponent(i,infos[i].c_str());
2489 MEDFileFieldPerMesh::MEDFileFieldPerMesh(med_idt fid, MEDFileAnyTypeField1TSWithoutSDA *fath, int meshCsit, int meshIteration, int meshOrder, const MEDFileFieldNameScope& nasc, const MEDFileMesh *mm):_mesh_iteration(meshIteration),_mesh_order(meshOrder),
2492 INTERP_KERNEL::AutoPtr<char> meshName(MEDLoaderBase::buildEmptyString(MED_NAME_SIZE));
2493 INTERP_KERNEL::AutoPtr<char> pflName(MEDLoaderBase::buildEmptyString(MED_NAME_SIZE));
2494 INTERP_KERNEL::AutoPtr<char> locName(MEDLoaderBase::buildEmptyString(MED_NAME_SIZE));
2495 const MEDFileUMesh *mmu(dynamic_cast<const MEDFileUMesh *>(mm));
2496 for(int i=0;i<MED_N_CELL_FIXED_GEO;i++)
2498 int nbProfile (MEDfield23nProfile(fid,nasc.getName().c_str(),getIteration(),getOrder(),MED_CELL ,typmai[i],meshCsit+1,meshName,pflName,locName));
2499 std::string name0(MEDLoaderBase::buildStringFromFortran(meshName,MED_NAME_SIZE+1));
2500 int nbProfile2(MEDfield23nProfile(fid,nasc.getName().c_str(),getIteration(),getOrder(),MED_NODE_ELEMENT,typmai[i],meshCsit+1,meshName,pflName,locName));
2501 std::string name1(MEDLoaderBase::buildStringFromFortran(meshName,MED_NAME_SIZE+1));
2502 if(nbProfile>0 || nbProfile2>0)
2504 const PartDefinition *pd(0);
2506 pd=mmu->getPartDefAtLevel(mmu->getRelativeLevOnGeoType(typmai2[i]),typmai2[i]);
2507 _field_pm_pt.push_back(MEDFileFieldPerMeshPerType::NewOnRead(fid,this,ON_CELLS,typmai2[i],nasc,pd));
2514 int nbProfile=MEDfield23nProfile(fid,nasc.getName().c_str(),getIteration(),getOrder(),MED_NODE,MED_NONE,meshCsit+1,meshName,pflName,locName);
2517 const PartDefinition *pd(0);
2519 pd=mmu->getPartDefAtLevel(1,INTERP_KERNEL::NORM_ERROR);
2520 _field_pm_pt.push_back(MEDFileFieldPerMeshPerType::NewOnRead(fid,this,ON_NODES,INTERP_KERNEL::NORM_ERROR,nasc,pd));
2521 _mesh_name=MEDLoaderBase::buildStringFromFortran(meshName,MED_NAME_SIZE+1);
2525 MEDFileFieldPerMesh::MEDFileFieldPerMesh(MEDFileAnyTypeField1TSWithoutSDA *fath, const MEDCouplingMesh *mesh):_father(fath)
2527 copyTinyInfoFrom(mesh);
2530 void MEDFileFieldGlobs::loadProfileInFile(med_idt fid, int id, const std::string& pflName)
2532 if(id>=(int)_pfls.size())
2534 _pfls[id]=DataArrayInt::New();
2535 int lgth=MEDprofileSizeByName(fid,pflName.c_str());
2536 _pfls[id]->setName(pflName);
2537 _pfls[id]->alloc(lgth,1);
2538 MEDprofileRd(fid,pflName.c_str(),_pfls[id]->getPointer());
2539 _pfls[id]->applyLin(1,-1,0);//Converting into C format
2542 void MEDFileFieldGlobs::loadProfileInFile(med_idt fid, int i)
2544 INTERP_KERNEL::AutoPtr<char> pflName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
2546 MEDprofileInfo(fid,i+1,pflName,&sz);
2547 std::string pflCpp=MEDLoaderBase::buildStringFromFortran(pflName,MED_NAME_SIZE);
2548 if(i>=(int)_pfls.size())
2550 _pfls[i]=DataArrayInt::New();
2551 _pfls[i]->alloc(sz,1);
2552 _pfls[i]->setName(pflCpp.c_str());
2553 MEDprofileRd(fid,pflName,_pfls[i]->getPointer());
2554 _pfls[i]->applyLin(1,-1,0);//Converting into C format
2557 void MEDFileFieldGlobs::writeGlobals(med_idt fid, const MEDFileWritable& opt) const
2559 int nbOfPfls=_pfls.size();
2560 for(int i=0;i<nbOfPfls;i++)
2562 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> cpy=_pfls[i]->deepCpy();
2563 cpy->applyLin(1,1,0);
2564 INTERP_KERNEL::AutoPtr<char> pflName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
2565 MEDLoaderBase::safeStrCpy(_pfls[i]->getName().c_str(),MED_NAME_SIZE,pflName,opt.getTooLongStrPolicy());
2566 MEDprofileWr(fid,pflName,_pfls[i]->getNumberOfTuples(),cpy->getConstPointer());
2569 int nbOfLocs=_locs.size();
2570 for(int i=0;i<nbOfLocs;i++)
2571 _locs[i]->writeLL(fid);
2574 void MEDFileFieldGlobs::appendGlobs(const MEDFileFieldGlobs& other, double eps)
2576 std::vector<std::string> pfls=getPfls();
2577 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=other._pfls.begin();it!=other._pfls.end();it++)
2579 std::vector<std::string>::iterator it2=std::find(pfls.begin(),pfls.end(),(*it)->getName());
2582 _pfls.push_back(*it);
2586 int id=std::distance(pfls.begin(),it2);
2587 if(!(*it)->isEqual(*_pfls[id]))
2589 std::ostringstream oss; oss << "MEDFileFieldGlobs::appendGlobs : Profile \"" << (*it)->getName() << "\" already exists and is different from those expecting to be append !";
2590 throw INTERP_KERNEL::Exception(oss.str().c_str());
2594 std::vector<std::string> locs=getLocs();
2595 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=other._locs.begin();it!=other._locs.end();it++)
2597 std::vector<std::string>::iterator it2=std::find(locs.begin(),locs.end(),(*it)->getName());
2600 _locs.push_back(*it);
2604 int id=std::distance(locs.begin(),it2);
2605 if(!(*it)->isEqual(*_locs[id],eps))
2607 std::ostringstream oss; oss << "MEDFileFieldGlobs::appendGlobs : Localization \"" << (*it)->getName() << "\" already exists and is different from those expecting to be append !";
2608 throw INTERP_KERNEL::Exception(oss.str().c_str());
2614 void MEDFileFieldGlobs::checkGlobsPflsPartCoherency(const std::vector<std::string>& pflsUsed) const
2616 for(std::vector<std::string>::const_iterator it=pflsUsed.begin();it!=pflsUsed.end();it++)
2617 getProfile((*it).c_str());
2620 void MEDFileFieldGlobs::checkGlobsLocsPartCoherency(const std::vector<std::string>& locsUsed) const
2622 for(std::vector<std::string>::const_iterator it=locsUsed.begin();it!=locsUsed.end();it++)
2623 getLocalization((*it).c_str());
2626 void MEDFileFieldGlobs::loadGlobals(med_idt fid, const MEDFileFieldGlobsReal& real)
2628 std::vector<std::string> profiles=real.getPflsReallyUsed();
2629 int sz=profiles.size();
2631 for(int i=0;i<sz;i++)
2632 loadProfileInFile(fid,i,profiles[i].c_str());
2634 std::vector<std::string> locs=real.getLocsReallyUsed();
2637 for(int i=0;i<sz;i++)
2638 _locs[i]=MEDFileFieldLoc::New(fid,locs[i].c_str());
2641 void MEDFileFieldGlobs::loadAllGlobals(med_idt fid)
2643 int nProfil=MEDnProfile(fid);
2644 for(int i=0;i<nProfil;i++)
2645 loadProfileInFile(fid,i);
2646 int sz=MEDnLocalization(fid);
2648 for(int i=0;i<sz;i++)
2650 _locs[i]=MEDFileFieldLoc::New(fid,i);
2654 MEDFileFieldGlobs *MEDFileFieldGlobs::New(const std::string& fname)
2656 return new MEDFileFieldGlobs(fname);
2659 MEDFileFieldGlobs *MEDFileFieldGlobs::New()
2661 return new MEDFileFieldGlobs;
2664 std::size_t MEDFileFieldGlobs::getHeapMemorySizeWithoutChildren() const
2666 return _file_name.capacity()+_pfls.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr<DataArrayInt>)+_locs.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc>);
2669 std::vector<const BigMemoryObject *> MEDFileFieldGlobs::getDirectChildrenWithNull() const
2671 std::vector<const BigMemoryObject *> ret;
2672 for(std::vector< MEDCouplingAutoRefCountObjectPtr< DataArrayInt > >::const_iterator it=_pfls.begin();it!=_pfls.end();it++)
2673 ret.push_back((const DataArrayInt *)*it);
2674 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=_locs.begin();it!=_locs.end();it++)
2675 ret.push_back((const MEDFileFieldLoc *)*it);
2679 MEDFileFieldGlobs *MEDFileFieldGlobs::deepCpy() const
2681 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldGlobs> ret=new MEDFileFieldGlobs(*this);
2683 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=_pfls.begin();it!=_pfls.end();it++,i++)
2685 if((const DataArrayInt *)*it)
2686 ret->_pfls[i]=(*it)->deepCpy();
2689 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=_locs.begin();it!=_locs.end();it++,i++)
2691 if((const MEDFileFieldLoc*)*it)
2692 ret->_locs[i]=(*it)->deepCpy();
2698 * \throw if a profile in \a pfls in not in \a this.
2699 * \throw if a localization in \a locs in not in \a this.
2700 * \sa MEDFileFieldGlobs::deepCpyPart
2702 MEDFileFieldGlobs *MEDFileFieldGlobs::shallowCpyPart(const std::vector<std::string>& pfls, const std::vector<std::string>& locs) const
2704 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldGlobs> ret=MEDFileFieldGlobs::New();
2705 for(std::vector<std::string>::const_iterator it1=pfls.begin();it1!=pfls.end();it1++)
2707 DataArrayInt *pfl=const_cast<DataArrayInt *>(getProfile((*it1).c_str()));
2709 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::shallowCpyPart : internal error ! pfl null !");
2711 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> pfl2(pfl);
2712 ret->_pfls.push_back(pfl2);
2714 for(std::vector<std::string>::const_iterator it2=locs.begin();it2!=locs.end();it2++)
2716 MEDFileFieldLoc *loc=const_cast<MEDFileFieldLoc *>(&getLocalization((*it2).c_str()));
2718 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::shallowCpyPart : internal error ! loc null !");
2720 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> loc2(loc);
2721 ret->_locs.push_back(loc2);
2723 ret->setFileName(getFileName());
2728 * \throw if a profile in \a pfls in not in \a this.
2729 * \throw if a localization in \a locs in not in \a this.
2730 * \sa MEDFileFieldGlobs::shallowCpyPart
2732 MEDFileFieldGlobs *MEDFileFieldGlobs::deepCpyPart(const std::vector<std::string>& pfls, const std::vector<std::string>& locs) const
2734 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldGlobs> ret=MEDFileFieldGlobs::New();
2735 for(std::vector<std::string>::const_iterator it1=pfls.begin();it1!=pfls.end();it1++)
2737 DataArrayInt *pfl=const_cast<DataArrayInt *>(getProfile((*it1).c_str()));
2739 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::deepCpyPart : internal error ! pfl null !");
2740 ret->_pfls.push_back(pfl->deepCpy());
2742 for(std::vector<std::string>::const_iterator it2=locs.begin();it2!=locs.end();it2++)
2744 MEDFileFieldLoc *loc=const_cast<MEDFileFieldLoc *>(&getLocalization((*it2).c_str()));
2746 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::deepCpyPart : internal error ! loc null !");
2747 ret->_locs.push_back(loc->deepCpy());
2749 ret->setFileName(getFileName());
2753 MEDFileFieldGlobs::MEDFileFieldGlobs(const std::string& fname):_file_name(fname)
2757 MEDFileFieldGlobs::MEDFileFieldGlobs()
2761 MEDFileFieldGlobs::~MEDFileFieldGlobs()
2765 void MEDFileFieldGlobs::simpleRepr(std::ostream& oss) const
2767 oss << "Profiles :\n";
2768 std::size_t n=_pfls.size();
2769 for(std::size_t i=0;i<n;i++)
2771 oss << " - #" << i << " ";
2772 const DataArrayInt *pfl=_pfls[i];
2774 oss << "\"" << pfl->getName() << "\"\n";
2779 oss << "Localizations :\n";
2780 for(std::size_t i=0;i<n;i++)
2782 oss << " - #" << i << " ";
2783 const MEDFileFieldLoc *loc=_locs[i];
2785 loc->simpleRepr(oss);
2791 void MEDFileFieldGlobs::setFileName(const std::string& fileName)
2793 _file_name=fileName;
2796 void MEDFileFieldGlobs::changePflsNamesInStruct(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
2798 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::iterator it=_pfls.begin();it!=_pfls.end();it++)
2800 DataArrayInt *elt(*it);
2803 std::string name(elt->getName());
2804 for(std::vector< std::pair<std::vector<std::string>, std::string > >::const_iterator it2=mapOfModif.begin();it2!=mapOfModif.end();it2++)
2806 if(std::find((*it2).first.begin(),(*it2).first.end(),name)!=(*it2).first.end())
2808 elt->setName((*it2).second.c_str());
2816 void MEDFileFieldGlobs::changeLocsNamesInStruct(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
2818 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::iterator it=_locs.begin();it!=_locs.end();it++)
2820 MEDFileFieldLoc *elt(*it);
2823 std::string name(elt->getName());
2824 for(std::vector< std::pair<std::vector<std::string>, std::string > >::const_iterator it2=mapOfModif.begin();it2!=mapOfModif.end();it2++)
2826 if(std::find((*it2).first.begin(),(*it2).first.end(),name)!=(*it2).first.end())
2828 elt->setName((*it2).second.c_str());
2836 int MEDFileFieldGlobs::getNbOfGaussPtPerCell(int locId) const
2838 if(locId<0 || locId>=(int)_locs.size())
2839 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::getNbOfGaussPtPerCell : Invalid localization id !");
2840 return _locs[locId]->getNbOfGaussPtPerCell();
2843 const MEDFileFieldLoc& MEDFileFieldGlobs::getLocalization(const std::string& locName) const
2845 return getLocalizationFromId(getLocalizationId(locName));
2848 const MEDFileFieldLoc& MEDFileFieldGlobs::getLocalizationFromId(int locId) const
2850 if(locId<0 || locId>=(int)_locs.size())
2851 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::getLocalizationFromId : Invalid localization id !");
2852 return *_locs[locId];
2855 namespace ParaMEDMEMImpl
2860 LocFinder(const std::string& loc):_loc(loc) { }
2861 bool operator() (const MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc>& loc) { return loc->isName(_loc); }
2863 const std::string &_loc;
2869 PflFinder(const std::string& pfl):_pfl(pfl) { }
2870 bool operator() (const MEDCouplingAutoRefCountObjectPtr<DataArrayInt>& pfl) { return _pfl==pfl->getName(); }
2872 const std::string& _pfl;
2876 int MEDFileFieldGlobs::getLocalizationId(const std::string& loc) const
2878 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=std::find_if(_locs.begin(),_locs.end(),ParaMEDMEMImpl::LocFinder(loc));
2881 std::ostringstream oss; oss << "MEDFileFieldGlobs::getLocalisationId : no such localisation name : \"" << loc << "\" Possible localizations are : ";
2882 for(it=_locs.begin();it!=_locs.end();it++)
2883 oss << "\"" << (*it)->getName() << "\", ";
2884 throw INTERP_KERNEL::Exception(oss.str().c_str());
2886 return std::distance(_locs.begin(),it);
2890 * The returned value is never null.
2892 const DataArrayInt *MEDFileFieldGlobs::getProfile(const std::string& pflName) const
2894 std::string pflNameCpp(pflName);
2895 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=std::find_if(_pfls.begin(),_pfls.end(),ParaMEDMEMImpl::PflFinder(pflNameCpp));
2898 std::ostringstream oss; oss << "MEDFileFieldGlobs::getProfile: no such profile name : \"" << pflNameCpp << "\" Possible profiles are : ";
2899 for(it=_pfls.begin();it!=_pfls.end();it++)
2900 oss << "\"" << (*it)->getName() << "\", ";
2901 throw INTERP_KERNEL::Exception(oss.str().c_str());
2906 const DataArrayInt *MEDFileFieldGlobs::getProfileFromId(int pflId) const
2908 if(pflId<0 || pflId>=(int)_pfls.size())
2909 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::getProfileFromId : Invalid profile id !");
2910 return _pfls[pflId];
2913 MEDFileFieldLoc& MEDFileFieldGlobs::getLocalizationFromId(int locId)
2915 if(locId<0 || locId>=(int)_locs.size())
2916 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::getLocalizationFromId : Invalid localization id !");
2917 return *_locs[locId];
2920 MEDFileFieldLoc& MEDFileFieldGlobs::getLocalization(const std::string& locName)
2922 return getLocalizationFromId(getLocalizationId(locName));
2926 * The returned value is never null.
2928 DataArrayInt *MEDFileFieldGlobs::getProfile(const std::string& pflName)
2930 std::string pflNameCpp(pflName);
2931 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::iterator it=std::find_if(_pfls.begin(),_pfls.end(),ParaMEDMEMImpl::PflFinder(pflNameCpp));
2934 std::ostringstream oss; oss << "MEDFileFieldGlobs::getProfile: no such profile name : \"" << pflNameCpp << "\" Possible profiles are : ";
2935 for(it=_pfls.begin();it!=_pfls.end();it++)
2936 oss << "\"" << (*it)->getName() << "\", ";
2937 throw INTERP_KERNEL::Exception(oss.str().c_str());
2942 DataArrayInt *MEDFileFieldGlobs::getProfileFromId(int pflId)
2944 if(pflId<0 || pflId>=(int)_pfls.size())
2945 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::getProfileFromId : Invalid profile id !");
2946 return _pfls[pflId];
2949 void MEDFileFieldGlobs::killProfileIds(const std::vector<int>& pflIds)
2951 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > newPfls;
2953 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=_pfls.begin();it!=_pfls.end();it++,i++)
2955 if(std::find(pflIds.begin(),pflIds.end(),i)==pflIds.end())
2956 newPfls.push_back(*it);
2961 void MEDFileFieldGlobs::killLocalizationIds(const std::vector<int>& locIds)
2963 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> > newLocs;
2965 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=_locs.begin();it!=_locs.end();it++,i++)
2967 if(std::find(locIds.begin(),locIds.end(),i)==locIds.end())
2968 newLocs.push_back(*it);
2973 std::vector<std::string> MEDFileFieldGlobs::getPfls() const
2975 int sz=_pfls.size();
2976 std::vector<std::string> ret(sz);
2977 for(int i=0;i<sz;i++)
2978 ret[i]=_pfls[i]->getName();
2982 std::vector<std::string> MEDFileFieldGlobs::getLocs() const
2984 int sz=_locs.size();
2985 std::vector<std::string> ret(sz);
2986 for(int i=0;i<sz;i++)
2987 ret[i]=_locs[i]->getName();
2991 bool MEDFileFieldGlobs::existsPfl(const std::string& pflName) const
2993 std::vector<std::string> v=getPfls();
2994 std::string s(pflName);
2995 return std::find(v.begin(),v.end(),s)!=v.end();
2998 bool MEDFileFieldGlobs::existsLoc(const std::string& locName) const
3000 std::vector<std::string> v=getLocs();
3001 std::string s(locName);
3002 return std::find(v.begin(),v.end(),s)!=v.end();
3005 std::vector< std::vector<int> > MEDFileFieldGlobs::whichAreEqualProfiles() const
3007 std::map<int,std::vector<int> > m;
3009 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=_pfls.begin();it!=_pfls.end();it++,i++)
3011 const DataArrayInt *tmp=(*it);
3014 m[tmp->getHashCode()].push_back(i);
3017 std::vector< std::vector<int> > ret;
3018 for(std::map<int,std::vector<int> >::const_iterator it2=m.begin();it2!=m.end();it2++)
3020 if((*it2).second.size()>1)
3022 std::vector<int> ret0;
3023 bool equalityOrNot=false;
3024 for(std::vector<int>::const_iterator it3=(*it2).second.begin();it3!=(*it2).second.end();it3++)
3026 std::vector<int>::const_iterator it4=it3; it4++;
3027 for(;it4!=(*it2).second.end();it4++)
3029 if(_pfls[*it3]->isEqualWithoutConsideringStr(*_pfls[*it4]))
3032 ret0.push_back(*it3);
3033 ret0.push_back(*it4);
3039 ret.push_back(ret0);
3045 std::vector< std::vector<int> > MEDFileFieldGlobs::whichAreEqualLocs(double eps) const
3047 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::whichAreEqualLocs : no implemented yet ! Sorry !");
3050 void MEDFileFieldGlobs::appendProfile(DataArrayInt *pfl)
3052 std::string name(pfl->getName());
3054 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::appendProfile : unsupported profiles with no name !");
3055 for(std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> >::const_iterator it=_pfls.begin();it!=_pfls.end();it++)
3056 if(name==(*it)->getName())
3058 if(!pfl->isEqual(*(*it)))
3060 std::ostringstream oss; oss << "MEDFileFieldGlobs::appendProfile : profile \"" << name << "\" already exists and is different from existing !";
3061 throw INTERP_KERNEL::Exception(oss.str().c_str());
3065 _pfls.push_back(pfl);
3068 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)
3070 std::string name(locName);
3072 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::appendLoc : unsupported localizations with no name !");
3073 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> obj=MEDFileFieldLoc::New(locName,geoType,refCoo,gsCoo,w);
3074 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFieldLoc> >::const_iterator it=_locs.begin();it!=_locs.end();it++)
3075 if((*it)->isName(locName))
3077 if(!(*it)->isEqual(*obj,1e-12))
3079 std::ostringstream oss; oss << "MEDFileFieldGlobs::appendLoc : localization \"" << name << "\" already exists and is different from existing !";
3080 throw INTERP_KERNEL::Exception(oss.str().c_str());
3083 _locs.push_back(obj);
3086 std::string MEDFileFieldGlobs::createNewNameOfPfl() const
3088 std::vector<std::string> names=getPfls();
3089 return CreateNewNameNotIn("NewPfl_",names);
3092 std::string MEDFileFieldGlobs::createNewNameOfLoc() const
3094 std::vector<std::string> names=getLocs();
3095 return CreateNewNameNotIn("NewLoc_",names);
3098 std::string MEDFileFieldGlobs::CreateNewNameNotIn(const std::string& prefix, const std::vector<std::string>& namesToAvoid)
3100 for(std::size_t sz=0;sz<100000;sz++)
3102 std::ostringstream tryName;
3103 tryName << prefix << sz;
3104 if(std::find(namesToAvoid.begin(),namesToAvoid.end(),tryName.str())==namesToAvoid.end())
3105 return tryName.str();
3107 throw INTERP_KERNEL::Exception("MEDFileFieldGlobs::CreateNewNameNotIn : impossible to create an additional profile limit of 100000 profiles reached !");
3111 * Creates a MEDFileFieldGlobsReal on a given file name. Nothing is read here.
3112 * \param [in] fname - the file name.
3114 MEDFileFieldGlobsReal::MEDFileFieldGlobsReal(const std::string& fname):_globals(MEDFileFieldGlobs::New(fname))
3119 * Creates an empty MEDFileFieldGlobsReal.
3121 MEDFileFieldGlobsReal::MEDFileFieldGlobsReal():_globals(MEDFileFieldGlobs::New())
3125 std::size_t MEDFileFieldGlobsReal::getHeapMemorySizeWithoutChildren() const
3130 std::vector<const BigMemoryObject *> MEDFileFieldGlobsReal::getDirectChildrenWithNull() const
3132 std::vector<const BigMemoryObject *> ret;
3133 ret.push_back((const MEDFileFieldGlobs *)_globals);
3138 * Returns a string describing profiles and Gauss points held in \a this.
3139 * \return std::string - the description string.
3141 void MEDFileFieldGlobsReal::simpleReprGlobs(std::ostream& oss) const
3143 const MEDFileFieldGlobs *glob=_globals;
3144 std::ostringstream oss2; oss2 << glob;
3145 std::string stars(oss2.str().length(),'*');
3146 oss << "Globals information on fields (at " << oss2.str() << "):" << "\n************************************" << stars << "\n\n";
3148 glob->simpleRepr(oss);
3150 oss << "NO GLOBAL INFORMATION !\n";
3153 void MEDFileFieldGlobsReal::resetContent()
3155 _globals=MEDFileFieldGlobs::New();
3158 MEDFileFieldGlobsReal::~MEDFileFieldGlobsReal()
3163 * Copies references to profiles and Gauss points from another MEDFileFieldGlobsReal.
3164 * \param [in] other - the other MEDFileFieldGlobsReal to copy data from.
3166 void MEDFileFieldGlobsReal::shallowCpyGlobs(const MEDFileFieldGlobsReal& other)
3168 _globals=other._globals;
3172 * Copies references to ** only used ** by \a this, profiles and Gauss points from another MEDFileFieldGlobsReal.
3173 * \param [in] other - the other MEDFileFieldGlobsReal to copy data from.
3175 void MEDFileFieldGlobsReal::shallowCpyOnlyUsedGlobs(const MEDFileFieldGlobsReal& other)
3177 const MEDFileFieldGlobs *otherg(other._globals);
3180 _globals=otherg->shallowCpyPart(getPflsReallyUsed(),getLocsReallyUsed());
3184 * Copies deeply to ** only used ** by \a this, profiles and Gauss points from another MEDFileFieldGlobsReal.
3185 * \param [in] other - the other MEDFileFieldGlobsReal to copy data from.
3187 void MEDFileFieldGlobsReal::deepCpyOnlyUsedGlobs(const MEDFileFieldGlobsReal& other)
3189 const MEDFileFieldGlobs *otherg(other._globals);
3192 _globals=otherg->deepCpyPart(getPflsReallyUsed(),getLocsReallyUsed());
3195 void MEDFileFieldGlobsReal::deepCpyGlobs(const MEDFileFieldGlobsReal& other)
3197 _globals=other._globals;
3198 if((const MEDFileFieldGlobs *)_globals)
3199 _globals=other._globals->deepCpy();
3203 * Adds profiles and Gauss points held by another MEDFileFieldGlobsReal to \a this one.
3204 * \param [in] other - the MEDFileFieldGlobsReal to copy data from.
3205 * \param [in] eps - a precision used to compare Gauss points with same name held by
3206 * \a this and \a other MEDFileFieldGlobsReal.
3207 * \throw If \a this and \a other hold profiles with equal names but different ids.
3208 * \throw If \a this and \a other hold different Gauss points with equal names.
3210 void MEDFileFieldGlobsReal::appendGlobs(const MEDFileFieldGlobsReal& other, double eps)
3212 const MEDFileFieldGlobs *thisGlobals(_globals),*otherGlobals(other._globals);
3213 if(thisGlobals==otherGlobals)
3217 _globals=other._globals;
3220 _globals->appendGlobs(*other._globals,eps);
3223 void MEDFileFieldGlobsReal::checkGlobsCoherency() const
3225 checkGlobsPflsPartCoherency();
3226 checkGlobsLocsPartCoherency();
3229 void MEDFileFieldGlobsReal::checkGlobsPflsPartCoherency() const
3231 contentNotNull()->checkGlobsPflsPartCoherency(getPflsReallyUsed());
3234 void MEDFileFieldGlobsReal::checkGlobsLocsPartCoherency() const
3236 contentNotNull()->checkGlobsLocsPartCoherency(getLocsReallyUsed());
3239 void MEDFileFieldGlobsReal::loadProfileInFile(med_idt fid, int id, const std::string& pflName)
3241 contentNotNull()->loadProfileInFile(fid,id,pflName);
3244 void MEDFileFieldGlobsReal::loadProfileInFile(med_idt fid, int id)
3246 contentNotNull()->loadProfileInFile(fid,id);
3249 void MEDFileFieldGlobsReal::loadGlobals(med_idt fid)
3251 contentNotNull()->loadGlobals(fid,*this);
3254 void MEDFileFieldGlobsReal::loadAllGlobals(med_idt fid)
3256 contentNotNull()->loadAllGlobals(fid);
3259 void MEDFileFieldGlobsReal::writeGlobals(med_idt fid, const MEDFileWritable& opt) const
3261 contentNotNull()->writeGlobals(fid,opt);
3265 * Returns names of all profiles. To get only used profiles call getPflsReallyUsed()
3266 * or getPflsReallyUsedMulti().
3267 * \return std::vector<std::string> - a sequence of names of all profiles.
3269 std::vector<std::string> MEDFileFieldGlobsReal::getPfls() const
3271 return contentNotNull()->getPfls();
3275 * Returns names of all localizations. To get only used localizations call getLocsReallyUsed()
3276 * or getLocsReallyUsedMulti().
3277 * \return std::vector<std::string> - a sequence of names of all localizations.
3279 std::vector<std::string> MEDFileFieldGlobsReal::getLocs() const
3281 return contentNotNull()->getLocs();
3285 * Checks if the profile with a given name exists.
3286 * \param [in] pflName - the profile name of interest.
3287 * \return bool - \c true if the profile named \a pflName exists.
3289 bool MEDFileFieldGlobsReal::existsPfl(const std::string& pflName) const
3291 return contentNotNull()->existsPfl(pflName);
3295 * Checks if the localization with a given name exists.
3296 * \param [in] locName - the localization name of interest.
3297 * \return bool - \c true if the localization named \a locName exists.
3299 bool MEDFileFieldGlobsReal::existsLoc(const std::string& locName) const
3301 return contentNotNull()->existsLoc(locName);
3304 std::string MEDFileFieldGlobsReal::createNewNameOfPfl() const
3306 return contentNotNull()->createNewNameOfPfl();
3309 std::string MEDFileFieldGlobsReal::createNewNameOfLoc() const
3311 return contentNotNull()->createNewNameOfLoc();
3315 * Sets the name of a MED file.
3316 * \param [inout] fileName - the file name.
3318 void MEDFileFieldGlobsReal::setFileName(const std::string& fileName)
3320 contentNotNull()->setFileName(fileName);
3324 * Finds equal profiles. Two profiles are considered equal if they contain the same ids
3325 * in the same order.
3326 * \return std::vector< std::vector<int> > - a sequence of groups of equal profiles.
3327 * Each item of this sequence is a vector containing ids of equal profiles.
3329 std::vector< std::vector<int> > MEDFileFieldGlobsReal::whichAreEqualProfiles() const
3331 return contentNotNull()->whichAreEqualProfiles();
3335 * Finds equal localizations.
3336 * \param [in] eps - a precision used to compare real values of the localizations.
3337 * \return std::vector< std::vector<int> > - a sequence of groups of equal localizations.
3338 * Each item of this sequence is a vector containing ids of equal localizations.
3340 std::vector< std::vector<int> > MEDFileFieldGlobsReal::whichAreEqualLocs(double eps) const
3342 return contentNotNull()->whichAreEqualLocs(eps);
3346 * Renames the profiles. References to profiles (a reference is a profile name) are not changed.
3347 * \param [in] mapOfModif - a sequence describing required renaming. Each element of
3348 * this sequence is a pair whose
3349 * - the first item is a vector of profile names to replace by the second item,
3350 * - the second item is a profile name to replace every profile name of the first item.
3352 void MEDFileFieldGlobsReal::changePflsNamesInStruct(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
3354 contentNotNull()->changePflsNamesInStruct(mapOfModif);
3358 * Renames the localizations. References to localizations (a reference is a localization name) are not changed.
3359 * \param [in] mapOfModif - a sequence describing required renaming. Each element of
3360 * this sequence is a pair whose
3361 * - the first item is a vector of localization names to replace by the second item,
3362 * - the second item is a localization name to replace every localization name of the first item.
3364 void MEDFileFieldGlobsReal::changeLocsNamesInStruct(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
3366 contentNotNull()->changeLocsNamesInStruct(mapOfModif);
3370 * Replaces references to some profiles (a reference is a profile name) by references
3371 * to other profiles and, contrary to changePflsRefsNamesGen(), renames the profiles
3372 * them-selves accordingly. <br>
3373 * This method is a generalization of changePflName().
3374 * \param [in] mapOfModif - a sequence describing required replacements. Each element of
3375 * this sequence is a pair whose
3376 * - the first item is a vector of profile names to replace by the second item,
3377 * - the second item is a profile name to replace every profile of the first item.
3378 * \sa changePflsRefsNamesGen()
3379 * \sa changePflName()
3381 void MEDFileFieldGlobsReal::changePflsNames(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
3383 changePflsRefsNamesGen(mapOfModif);
3384 changePflsNamesInStruct(mapOfModif);
3388 * Replaces references to some localizations (a reference is a localization name) by references
3389 * to other localizations and, contrary to changeLocsRefsNamesGen(), renames the localizations
3390 * them-selves accordingly. <br>
3391 * This method is a generalization of changeLocName().
3392 * \param [in] mapOfModif - a sequence describing required replacements. Each element of
3393 * this sequence is a pair whose
3394 * - the first item is a vector of localization names to replace by the second item,
3395 * - the second item is a localization name to replace every localization of the first item.
3396 * \sa changeLocsRefsNamesGen()
3397 * \sa changeLocName()
3399 void MEDFileFieldGlobsReal::changeLocsNames(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
3401 changeLocsRefsNamesGen(mapOfModif);
3402 changeLocsNamesInStruct(mapOfModif);
3406 * Renames the profile having a given name and updates references to this profile.
3407 * \param [in] oldName - the name of the profile to rename.
3408 * \param [in] newName - a new name of the profile.
3409 * \sa changePflsNames().
3411 void MEDFileFieldGlobsReal::changePflName(const std::string& oldName, const std::string& newName)
3413 std::vector< std::pair<std::vector<std::string>, std::string > > mapOfModif(1);
3414 std::pair<std::vector<std::string>, std::string > p(std::vector<std::string>(1,std::string(oldName)),std::string(newName));
3416 changePflsNames(mapOfModif);
3420 * Renames the localization having a given name and updates references to this localization.
3421 * \param [in] oldName - the name of the localization to rename.
3422 * \param [in] newName - a new name of the localization.
3423 * \sa changeLocsNames().
3425 void MEDFileFieldGlobsReal::changeLocName(const std::string& oldName, const std::string& newName)
3427 std::vector< std::pair<std::vector<std::string>, std::string > > mapOfModif(1);
3428 std::pair<std::vector<std::string>, std::string > p(std::vector<std::string>(1,std::string(oldName)),std::string(newName));
3430 changeLocsNames(mapOfModif);
3434 * Removes duplicated profiles. Returns a map used to update references to removed
3435 * profiles via changePflsRefsNamesGen().
3436 * Equal profiles are found using whichAreEqualProfiles().
3437 * \return std::vector< std::pair<std::vector<std::string>, std::string > > -
3438 * a sequence describing the performed replacements of profiles. Each element of
3439 * this sequence is a pair whose
3440 * - the first item is a vector of profile names replaced by the second item,
3441 * - the second item is a profile name replacing every profile of the first item.
3443 std::vector< std::pair<std::vector<std::string>, std::string > > MEDFileFieldGlobsReal::zipPflsNames()
3445 std::vector< std::vector<int> > pseudoRet=whichAreEqualProfiles();
3446 std::vector< std::pair<std::vector<std::string>, std::string > > ret(pseudoRet.size());
3448 for(std::vector< std::vector<int> >::const_iterator it=pseudoRet.begin();it!=pseudoRet.end();it++,i++)
3450 std::vector< std::string > tmp((*it).size());
3452 for(std::vector<int>::const_iterator it2=(*it).begin();it2!=(*it).end();it2++,j++)
3453 tmp[j]=std::string(getProfileFromId(*it2)->getName());
3454 std::pair<std::vector<std::string>, std::string > p(tmp,tmp.front());
3456 std::vector<int> tmp2((*it).begin()+1,(*it).end());
3457 killProfileIds(tmp2);
3459 changePflsRefsNamesGen(ret);
3464 * Removes duplicated localizations. Returns a map used to update references to removed
3465 * localizations via changeLocsRefsNamesGen().
3466 * Equal localizations are found using whichAreEqualLocs().
3467 * \param [in] eps - a precision used to compare real values of the localizations.
3468 * \return std::vector< std::pair<std::vector<std::string>, std::string > > -
3469 * a sequence describing the performed replacements of localizations. Each element of
3470 * this sequence is a pair whose
3471 * - the first item is a vector of localization names replaced by the second item,
3472 * - the second item is a localization name replacing every localization of the first item.
3474 std::vector< std::pair<std::vector<std::string>, std::string > > MEDFileFieldGlobsReal::zipLocsNames(double eps)
3476 std::vector< std::vector<int> > pseudoRet=whichAreEqualLocs(eps);
3477 std::vector< std::pair<std::vector<std::string>, std::string > > ret(pseudoRet.size());
3479 for(std::vector< std::vector<int> >::const_iterator it=pseudoRet.begin();it!=pseudoRet.end();it++,i++)
3481 std::vector< std::string > tmp((*it).size());
3483 for(std::vector<int>::const_iterator it2=(*it).begin();it2!=(*it).end();it2++,j++)
3484 tmp[j]=std::string(getLocalizationFromId(*it2).getName());
3485 std::pair<std::vector<std::string>, std::string > p(tmp,tmp.front());
3487 std::vector<int> tmp2((*it).begin()+1,(*it).end());
3488 killLocalizationIds(tmp2);
3490 changeLocsRefsNamesGen(ret);
3495 * Returns number of Gauss points per cell in a given localization.
3496 * \param [in] locId - an id of the localization of interest.
3497 * \return int - the number of the Gauss points per cell.
3499 int MEDFileFieldGlobsReal::getNbOfGaussPtPerCell(int locId) const
3501 return contentNotNull()->getNbOfGaussPtPerCell(locId);
3505 * Returns an id of a localization by its name.
3506 * \param [in] loc - the localization name of interest.
3507 * \return int - the id of the localization.
3508 * \throw If there is no a localization named \a loc.
3510 int MEDFileFieldGlobsReal::getLocalizationId(const std::string& loc) const
3512 return contentNotNull()->getLocalizationId(loc);
3516 * Returns the name of the MED file.
3517 * \return const std::string& - the MED file name.
3519 std::string MEDFileFieldGlobsReal::getFileName() const
3521 return contentNotNull()->getFileName();
3525 * Returns a localization object by its name.
3526 * \param [in] locName - the name of the localization of interest.
3527 * \return const MEDFileFieldLoc& - the localization object having the name \a locName.
3528 * \throw If there is no a localization named \a locName.
3530 const MEDFileFieldLoc& MEDFileFieldGlobsReal::getLocalization(const std::string& locName) const
3532 return contentNotNull()->getLocalization(locName);
3536 * Returns a localization object by its id.
3537 * \param [in] locId - the id of the localization of interest.
3538 * \return const MEDFileFieldLoc& - the localization object having the id \a locId.
3539 * \throw If there is no a localization with id \a locId.
3541 const MEDFileFieldLoc& MEDFileFieldGlobsReal::getLocalizationFromId(int locId) const
3543 return contentNotNull()->getLocalizationFromId(locId);
3547 * Returns a profile array by its name.
3548 * \param [in] pflName - the name of the profile of interest.
3549 * \return const DataArrayInt * - the profile array having the name \a pflName.
3550 * \throw If there is no a profile named \a pflName.
3552 const DataArrayInt *MEDFileFieldGlobsReal::getProfile(const std::string& pflName) const
3554 return contentNotNull()->getProfile(pflName);
3558 * Returns a profile array by its id.
3559 * \param [in] pflId - the id of the profile of interest.
3560 * \return const DataArrayInt * - the profile array having the id \a pflId.
3561 * \throw If there is no a profile with id \a pflId.
3563 const DataArrayInt *MEDFileFieldGlobsReal::getProfileFromId(int pflId) const
3565 return contentNotNull()->getProfileFromId(pflId);
3569 * Returns a localization object, apt for modification, by its id.
3570 * \param [in] locId - the id of the localization of interest.
3571 * \return MEDFileFieldLoc& - a non-const reference to the localization object
3572 * having the id \a locId.
3573 * \throw If there is no a localization with id \a locId.
3575 MEDFileFieldLoc& MEDFileFieldGlobsReal::getLocalizationFromId(int locId)
3577 return contentNotNull()->getLocalizationFromId(locId);
3581 * Returns a localization object, apt for modification, by its name.
3582 * \param [in] locName - the name of the localization of interest.
3583 * \return MEDFileFieldLoc& - a non-const reference to the localization object
3584 * having the name \a locName.
3585 * \throw If there is no a localization named \a locName.
3587 MEDFileFieldLoc& MEDFileFieldGlobsReal::getLocalization(const std::string& locName)
3589 return contentNotNull()->getLocalization(locName);
3593 * Returns a profile array, apt for modification, by its name.
3594 * \param [in] pflName - the name of the profile of interest.
3595 * \return DataArrayInt * - a non-const pointer to the profile array having the name \a pflName.
3596 * \throw If there is no a profile named \a pflName.
3598 DataArrayInt *MEDFileFieldGlobsReal::getProfile(const std::string& pflName)
3600 return contentNotNull()->getProfile(pflName);
3604 * Returns a profile array, apt for modification, by its id.
3605 * \param [in] pflId - the id of the profile of interest.
3606 * \return DataArrayInt * - a non-const pointer to the profile array having the id \a pflId.
3607 * \throw If there is no a profile with id \a pflId.
3609 DataArrayInt *MEDFileFieldGlobsReal::getProfileFromId(int pflId)
3611 return contentNotNull()->getProfileFromId(pflId);
3615 * Removes profiles given by their ids. No data is updated to track this removal.
3616 * \param [in] pflIds - a sequence of ids of the profiles to remove.
3618 void MEDFileFieldGlobsReal::killProfileIds(const std::vector<int>& pflIds)
3620 contentNotNull()->killProfileIds(pflIds);
3624 * Removes localizations given by their ids. No data is updated to track this removal.
3625 * \param [in] locIds - a sequence of ids of the localizations to remove.
3627 void MEDFileFieldGlobsReal::killLocalizationIds(const std::vector<int>& locIds)
3629 contentNotNull()->killLocalizationIds(locIds);
3633 * Stores a profile array.
3634 * \param [in] pfl - the profile array to store.
3635 * \throw If the name of \a pfl is empty.
3636 * \throw If a profile with the same name as that of \a pfl already exists but contains
3639 void MEDFileFieldGlobsReal::appendProfile(DataArrayInt *pfl)
3641 contentNotNull()->appendProfile(pfl);
3645 * Adds a new localization of Gauss points.
3646 * \param [in] locName - the name of the new localization.
3647 * \param [in] geoType - a geometrical type of the reference cell.
3648 * \param [in] refCoo - coordinates of points of the reference cell. Size of this vector
3649 * must be \c nbOfNodesPerCell * \c dimOfType.
3650 * \param [in] gsCoo - coordinates of Gauss points on the reference cell. Size of this vector
3651 * must be _wg_.size() * \c dimOfType.
3652 * \param [in] w - the weights of Gauss points.
3653 * \throw If \a locName is empty.
3654 * \throw If a localization with the name \a locName already exists but is
3655 * different form the new one.
3657 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)
3659 contentNotNull()->appendLoc(locName,geoType,refCoo,gsCoo,w);
3662 MEDFileFieldGlobs *MEDFileFieldGlobsReal::contentNotNull()
3664 MEDFileFieldGlobs *g(_globals);
3666 throw INTERP_KERNEL::Exception("MEDFileFieldGlobsReal::contentNotNull : no content in not const !");
3670 const MEDFileFieldGlobs *MEDFileFieldGlobsReal::contentNotNull() const
3672 const MEDFileFieldGlobs *g(_globals);
3674 throw INTERP_KERNEL::Exception("MEDFileFieldGlobsReal::contentNotNull : no content in const !");
3678 //= MEDFileFieldNameScope
3680 MEDFileFieldNameScope::MEDFileFieldNameScope()
3684 MEDFileFieldNameScope::MEDFileFieldNameScope(const std::string& fieldName):_name(fieldName)
3689 * Returns the name of \a this field.
3690 * \return std::string - a string containing the field name.
3692 std::string MEDFileFieldNameScope::getName() const
3698 * Sets name of \a this field
3699 * \param [in] name - the new field name.
3701 void MEDFileFieldNameScope::setName(const std::string& fieldName)
3706 std::string MEDFileFieldNameScope::getDtUnit() const
3711 void MEDFileFieldNameScope::setDtUnit(const std::string& dtUnit)
3716 void MEDFileFieldNameScope::copyNameScope(const MEDFileFieldNameScope& other)
3719 _dt_unit=other._dt_unit;
3722 //= MEDFileAnyTypeField1TSWithoutSDA
3724 void MEDFileAnyTypeField1TSWithoutSDA::deepCpyLeavesFrom(const MEDFileAnyTypeField1TSWithoutSDA& other)
3726 _field_per_mesh.resize(other._field_per_mesh.size());
3728 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=other._field_per_mesh.begin();it!=other._field_per_mesh.end();it++,i++)
3730 if((const MEDFileFieldPerMesh *)*it)
3731 _field_per_mesh[i]=(*it)->deepCpy(this);
3736 * Prints a string describing \a this field into a stream. This string is outputted
3737 * by \c print Python command.
3738 * \param [in] bkOffset - number of white spaces printed at the beginning of each line.
3739 * \param [in,out] oss - the out stream.
3740 * \param [in] f1tsId - the field index within a MED file. If \a f1tsId < 0, the tiny
3741 * info id printed, else, not.
3743 void MEDFileAnyTypeField1TSWithoutSDA::simpleRepr(int bkOffset, std::ostream& oss, int f1tsId) const
3745 std::string startOfLine(bkOffset,' ');
3746 oss << startOfLine << "Field ";
3748 oss << "[Type=" << getTypeStr() << "] with name \"" << getName() << "\" ";
3749 oss << "on one time Step ";
3751 oss << "(" << f1tsId << ") ";
3752 oss << "on iteration=" << _iteration << " order=" << _order << "." << std::endl;
3753 oss << startOfLine << "Time attached is : " << _dt << " [" << _dt_unit << "]." << std::endl;
3754 const DataArray *arr=getUndergroundDataArray();
3757 const std::vector<std::string> &comps=arr->getInfoOnComponents();
3760 oss << startOfLine << "Field has " << comps.size() << " components with the following infos :" << std::endl;
3761 for(std::vector<std::string>::const_iterator it=comps.begin();it!=comps.end();it++)
3762 oss << startOfLine << " - \"" << (*it) << "\"" << std::endl;
3764 if(arr->isAllocated())
3766 oss << startOfLine << "Whole field contains " << arr->getNumberOfTuples() << " tuples." << std::endl;
3769 oss << startOfLine << "The array of the current field has not allocated yet !" << std::endl;
3773 oss << startOfLine << "Field infos are empty ! Not defined yet !" << std::endl;
3775 oss << startOfLine << "----------------------" << std::endl;
3776 if(!_field_per_mesh.empty())
3779 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it2=_field_per_mesh.begin();it2!=_field_per_mesh.end();it2++,i++)
3781 const MEDFileFieldPerMesh *cur=(*it2);
3783 cur->simpleRepr(bkOffset,oss,i);
3785 oss << startOfLine << "Field per mesh #" << i << " is not defined !" << std::endl;
3790 oss << startOfLine << "Field is not defined on any meshes !" << std::endl;
3792 oss << startOfLine << "----------------------" << std::endl;
3795 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > MEDFileAnyTypeField1TSWithoutSDA::splitComponents() const
3797 const DataArray *arr(getUndergroundDataArray());
3799 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::splitComponents : no array defined !");
3800 int nbOfCompo=arr->getNumberOfComponents();
3801 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > ret(nbOfCompo);
3802 for(int i=0;i<nbOfCompo;i++)
3805 std::vector<int> v(1,i);
3806 MEDCouplingAutoRefCountObjectPtr<DataArray> arr2=arr->keepSelectedComponents(v);
3807 ret[i]->setArray(arr2);
3812 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)
3816 MEDFileAnyTypeField1TSWithoutSDA::MEDFileAnyTypeField1TSWithoutSDA():_iteration(-1),_order(-1),_dt(0.),_csit(-1),_nb_of_tuples_to_be_allocated(-1)
3821 * Returns the maximal dimension of supporting elements. Returns -2 if \a this is
3822 * empty. Returns -1 if this in on nodes.
3823 * \return int - the dimension of \a this.
3825 int MEDFileAnyTypeField1TSWithoutSDA::getDimension() const
3828 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3829 (*it)->getDimension(ret);
3834 * Returns the mesh name.
3835 * \return std::string - a string holding the mesh name.
3836 * \throw If \c _field_per_mesh.empty()
3838 std::string MEDFileAnyTypeField1TSWithoutSDA::getMeshName() const
3840 if(_field_per_mesh.empty())
3841 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::getMeshName : No field set !");
3842 return _field_per_mesh[0]->getMeshName();
3845 void MEDFileAnyTypeField1TSWithoutSDA::setMeshName(const std::string& newMeshName)
3847 std::string oldName(getMeshName());
3848 std::vector< std::pair<std::string,std::string> > v(1);
3849 v[0].first=oldName; v[0].second=newMeshName;
3853 bool MEDFileAnyTypeField1TSWithoutSDA::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
3856 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3858 MEDFileFieldPerMesh *cur(*it);
3860 ret=cur->changeMeshNames(modifTab) || ret;
3866 * Returns the number of iteration of the state of underlying mesh.
3867 * \return int - the iteration number.
3868 * \throw If \c _field_per_mesh.empty()
3870 int MEDFileAnyTypeField1TSWithoutSDA::getMeshIteration() const
3872 if(_field_per_mesh.empty())
3873 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::getMeshIteration : No field set !");
3874 return _field_per_mesh[0]->getMeshIteration();
3878 * Returns the order number of iteration of the state of underlying mesh.
3879 * \return int - the order number.
3880 * \throw If \c _field_per_mesh.empty()
3882 int MEDFileAnyTypeField1TSWithoutSDA::getMeshOrder() const
3884 if(_field_per_mesh.empty())
3885 throw INTERP_KERNEL::Exception("MEDFileFieldPerMeshPerTypePerDisc::getMeshOrder : No field set !");
3886 return _field_per_mesh[0]->getMeshOrder();
3890 * Checks if \a this field is tagged by a given iteration number and a given
3891 * iteration order number.
3892 * \param [in] iteration - the iteration number of interest.
3893 * \param [in] order - the iteration order number of interest.
3894 * \return bool - \c true if \a this->getIteration() == \a iteration &&
3895 * \a this->getOrder() == \a order.
3897 bool MEDFileAnyTypeField1TSWithoutSDA::isDealingTS(int iteration, int order) const
3899 return iteration==_iteration && order==_order;
3903 * Returns number of iteration and order number of iteration when
3904 * \a this field has been calculated.
3905 * \return std::pair<int,int> - a pair of the iteration number and the iteration
3908 std::pair<int,int> MEDFileAnyTypeField1TSWithoutSDA::getDtIt() const
3910 std::pair<int,int> p;
3916 * Returns number of iteration and order number of iteration when
3917 * \a this field has been calculated.
3918 * \param [in,out] p - a pair returning the iteration number and the iteration
3921 void MEDFileAnyTypeField1TSWithoutSDA::fillIteration(std::pair<int,int>& p) const
3928 * Returns all types of spatial discretization of \a this field.
3929 * \param [in,out] types - a sequence of types of \a this field.
3931 void MEDFileAnyTypeField1TSWithoutSDA::fillTypesOfFieldAvailable(std::vector<TypeOfField>& types) const
3933 std::set<TypeOfField> types2;
3934 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3936 (*it)->fillTypesOfFieldAvailable(types2);
3938 std::back_insert_iterator< std::vector<TypeOfField> > bi(types);
3939 std::copy(types2.begin(),types2.end(),bi);
3943 * Returns all types of spatial discretization of \a this field.
3944 * \return std::vector<TypeOfField> - a sequence of types of spatial discretization
3947 std::vector<TypeOfField> MEDFileAnyTypeField1TSWithoutSDA::getTypesOfFieldAvailable() const
3949 std::vector<TypeOfField> ret;
3950 fillTypesOfFieldAvailable(ret);
3954 std::vector<std::string> MEDFileAnyTypeField1TSWithoutSDA::getPflsReallyUsed2() const
3956 std::vector<std::string> ret;
3957 std::set<std::string> ret2;
3958 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3960 std::vector<std::string> tmp=(*it)->getPflsReallyUsed();
3961 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
3962 if(ret2.find(*it2)==ret2.end())
3964 ret.push_back(*it2);
3971 std::vector<std::string> MEDFileAnyTypeField1TSWithoutSDA::getLocsReallyUsed2() const
3973 std::vector<std::string> ret;
3974 std::set<std::string> ret2;
3975 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3977 std::vector<std::string> tmp=(*it)->getLocsReallyUsed();
3978 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
3979 if(ret2.find(*it2)==ret2.end())
3981 ret.push_back(*it2);
3988 std::vector<std::string> MEDFileAnyTypeField1TSWithoutSDA::getPflsReallyUsedMulti2() const
3990 std::vector<std::string> ret;
3991 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
3993 std::vector<std::string> tmp=(*it)->getPflsReallyUsedMulti();
3994 ret.insert(ret.end(),tmp.begin(),tmp.end());
3999 std::vector<std::string> MEDFileAnyTypeField1TSWithoutSDA::getLocsReallyUsedMulti2() const
4001 std::vector<std::string> ret;
4002 std::set<std::string> ret2;
4003 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4005 std::vector<std::string> tmp=(*it)->getLocsReallyUsedMulti();
4006 ret.insert(ret.end(),tmp.begin(),tmp.end());
4011 void MEDFileAnyTypeField1TSWithoutSDA::changePflsRefsNamesGen2(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
4013 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4014 (*it)->changePflsRefsNamesGen(mapOfModif);
4017 void MEDFileAnyTypeField1TSWithoutSDA::changeLocsRefsNamesGen2(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
4019 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4020 (*it)->changeLocsRefsNamesGen(mapOfModif);
4024 * Returns all attributes of parts of \a this field lying on a given mesh.
4025 * Each part differs from other ones by a type of supporting mesh entity. The _i_-th
4026 * item of every of returned sequences refers to the _i_-th part of \a this field.
4027 * Thus all sequences returned by this method are of the same length equal to number
4028 * of different types of supporting entities.<br>
4029 * A field part can include sub-parts with several different spatial discretizations,
4030 * \ref ParaMEDMEM::ON_CELLS "ON_CELLS" and \ref ParaMEDMEM::ON_GAUSS_PT "ON_GAUSS_PT"
4031 * for example. Hence, some of the returned sequences contains nested sequences, and an item
4032 * of a nested sequence corresponds to a type of spatial discretization.<br>
4033 * This method allows for iteration over MEDFile DataStructure without any overhead.
4034 * \param [in] mname - a name of a mesh of interest. It can be \c NULL, which is valid
4035 * for the case with only one underlying mesh. (Actually, the number of meshes is
4036 * not checked if \a mname == \c NULL).
4037 * \param [in,out] types - a sequence of types of underlying mesh entities. A type per
4038 * a field part is returned.
4039 * \param [in,out] typesF - a sequence of sequences of types of spatial discretizations.
4040 * This sequence is of the same length as \a types.
4041 * \param [in,out] pfls - a sequence returning a profile name per each type of spatial
4042 * discretization. A profile name can be empty.
4043 * Length of this and of nested sequences is the same as that of \a typesF.
4044 * \param [in,out] locs - a sequence returning a localization name per each type of spatial
4045 * discretization. A localization name can be empty.
4046 * Length of this and of nested sequences is the same as that of \a typesF.
4047 * \return std::vector< std::vector< std::pair<int,int> > > - a sequence holding a range
4048 * of ids of tuples within the data array, per each type of spatial
4049 * discretization within one mesh entity type.
4050 * Length of this and of nested sequences is the same as that of \a typesF.
4051 * \throw If no field is lying on \a mname.
4053 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
4057 meshId=getMeshIdFromMeshName(mname);
4059 if(_field_per_mesh.empty())
4060 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getFieldSplitedByType : This is empty !");
4061 return _field_per_mesh[meshId]->getFieldSplitedByType(types,typesF,pfls,locs);
4065 * Returns dimensions of mesh elements \a this field lies on. The returned value is a
4066 * maximal absolute dimension and values returned via the out parameter \a levs are
4067 * dimensions relative to the maximal absolute dimension. <br>
4068 * This method is designed for MEDFileField1TS instances that have a discretization
4069 * \ref ParaMEDMEM::ON_CELLS "ON_CELLS",
4070 * \ref ParaMEDMEM::ON_GAUSS_PT "ON_GAUSS_PT",
4071 * \ref ParaMEDMEM::ON_GAUSS_NE "ON_GAUSS_NE".
4072 * Only these 3 discretizations will be taken into account here. If \a this is
4073 * \ref ParaMEDMEM::ON_NODES "ON_NODES", -1 is returned and \a levs are empty.<br>
4074 * This method is useful to make the link between the dimension of the underlying mesh
4075 * and the levels of \a this, because it is possible that the highest dimension of \a this
4076 * field is not equal to the dimension of the underlying mesh.
4078 * Let's consider the following case:
4079 * - mesh \a m1 has a meshDimension 3 and has non empty levels [0,-1,-2] with elements
4080 * TETRA4, HEXA8, TRI3 and SEG2.
4081 * - field \a f1 lies on \a m1 and is defined on 3D and 1D elements TETRA4 and SEG2.
4082 * - field \a f2 lies on \a m1 and is defined on 2D and 1D elements TRI3 and SEG2.
4084 * In this case \a f1->getNonEmptyLevels() returns (3,[0,-2]) and \a
4085 * f2->getNonEmptyLevels() returns (2,[0,-1]). <br>
4086 * The returned values can be used for example to retrieve a MEDCouplingFieldDouble lying
4087 * on elements of a certain relative level by calling getFieldAtLevel(). \a meshDimRelToMax
4088 * parameter of getFieldAtLevel() is computed basing on the returned values as this:
4089 * <em> meshDimRelToMax = absDim - meshDim + relativeLev </em>.
4091 * to retrieve the highest level of
4092 * \a f1: <em>f1->getFieldAtLevel( ON_CELLS, 3-3+0 ); // absDim - meshDim + relativeLev</em><br>
4093 * to retrieve the lowest level of \a f1: <em>f1->getFieldAtLevel( ON_CELLS, 3-3+(-2) );</em><br>
4094 * to retrieve the highest level of \a f2: <em>f2->getFieldAtLevel( ON_CELLS, 2-3+0 );</em><br>
4095 * to retrieve the lowest level of \a f2: <em>f2->getFieldAtLevel( ON_CELLS, 2-3+(-1) )</em>.
4096 * \param [in] mname - a name of a mesh of interest. It can be \c NULL, which is valid
4097 * for the case with only one underlying mesh. (Actually, the number of meshes is
4098 * not checked if \a mname == \c NULL).
4099 * \param [in,out] levs - a sequence returning the dimensions relative to the maximal
4100 * absolute one. They are in decreasing order. This sequence is cleared before
4102 * \return int - the maximal absolute dimension of elements \a this fields lies on.
4103 * \throw If no field is lying on \a mname.
4105 int MEDFileAnyTypeField1TSWithoutSDA::getNonEmptyLevels(const std::string& mname, std::vector<int>& levs) const
4108 int meshId=getMeshIdFromMeshName(mname);
4109 std::vector<INTERP_KERNEL::NormalizedCellType> types;
4110 std::vector< std::vector<TypeOfField> > typesF;
4111 std::vector< std::vector<std::string> > pfls, locs;
4112 _field_per_mesh[meshId]->getFieldSplitedByType(types,typesF,pfls,locs);
4114 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getNonEmptyLevels : 'this' is empty !");
4115 std::set<INTERP_KERNEL::NormalizedCellType> st(types.begin(),types.end());
4116 if(st.size()==1 && (*st.begin())==INTERP_KERNEL::NORM_ERROR)
4118 st.erase(INTERP_KERNEL::NORM_ERROR);
4120 for(std::set<INTERP_KERNEL::NormalizedCellType>::const_iterator it=st.begin();it!=st.end();it++)
4122 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(*it);
4123 ret1.insert((int)cm.getDimension());
4125 int ret=*std::max_element(ret1.begin(),ret1.end());
4126 std::copy(ret1.rbegin(),ret1.rend(),std::back_insert_iterator<std::vector<int> >(levs));
4127 std::transform(levs.begin(),levs.end(),levs.begin(),std::bind2nd(std::plus<int>(),-ret));
4132 * \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.
4133 * \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.
4134 * \param [in] locId is the localization id to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set. It corresponds to the position of
4135 * \c pfls[std::distance(types.begin(),std::find(types.begin(),typ)] vector in MEDFileField1TSWithoutSDA::getFieldSplitedByType. For non gausspoints field users, the value is 0.
4137 MEDFileFieldPerMeshPerTypePerDisc *MEDFileAnyTypeField1TSWithoutSDA::getLeafGivenMeshAndTypeAndLocId(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId)
4139 int mid=getMeshIdFromMeshName(mName);
4140 return _field_per_mesh[mid]->getLeafGivenTypeAndLocId(typ,locId);
4144 * \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.
4145 * \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.
4146 * \param [in] locId is the localization id to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set. It corresponds to the position of
4147 * \c pfls[std::distance(types.begin(),std::find(types.begin(),typ)] vector in MEDFileField1TSWithoutSDA::getFieldSplitedByType. For non gausspoints field users, the value is 0.
4149 const MEDFileFieldPerMeshPerTypePerDisc *MEDFileAnyTypeField1TSWithoutSDA::getLeafGivenMeshAndTypeAndLocId(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId) const
4151 int mid=getMeshIdFromMeshName(mName);
4152 return _field_per_mesh[mid]->getLeafGivenTypeAndLocId(typ,locId);
4156 * \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.
4158 int MEDFileAnyTypeField1TSWithoutSDA::getMeshIdFromMeshName(const std::string& mName) const
4160 if(_field_per_mesh.empty())
4161 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getMeshIdFromMeshName : No field set !");
4164 std::string mName2(mName);
4166 std::vector<std::string> msg;
4167 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++,ret++)
4168 if(mName2==(*it)->getMeshName())
4171 msg.push_back((*it)->getMeshName());
4172 std::ostringstream oss; oss << "MEDFileField1TSWithoutSDA::getMeshIdFromMeshName : No such mesh \"" << mName2 << "\" as underlying mesh of field \"" << getName() << "\" !\n";
4173 oss << "Possible meshes are : ";
4174 for(std::vector<std::string>::const_iterator it2=msg.begin();it2!=msg.end();it2++)
4175 oss << "\"" << (*it2) << "\" ";
4176 throw INTERP_KERNEL::Exception(oss.str().c_str());
4179 int MEDFileAnyTypeField1TSWithoutSDA::addNewEntryIfNecessary(const MEDCouplingMesh *mesh)
4182 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::addNewEntryIfNecessary : input mesh is NULL !");
4183 std::string tmp(mesh->getName());
4185 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::addNewEntryIfNecessary : empty mesh name ! unsupported by MED file !");
4186 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();
4188 for(;it!=_field_per_mesh.end();it++,i++)
4190 if((*it)->getMeshName()==tmp)
4193 int sz=_field_per_mesh.size();
4194 _field_per_mesh.resize(sz+1);
4195 _field_per_mesh[sz]=MEDFileFieldPerMesh::New(this,mesh);
4199 bool MEDFileAnyTypeField1TSWithoutSDA::renumberEntitiesLyingOnMesh(const std::string& meshName, const std::vector<int>& oldCode, const std::vector<int>& newCode, const DataArrayInt *renumO2N,
4200 MEDFileFieldGlobsReal& glob)
4203 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4205 MEDFileFieldPerMesh *fpm(*it);
4207 ret=fpm->renumberEntitiesLyingOnMesh(meshName,oldCode,newCode,renumO2N,glob) || ret;
4213 * This method splits \a this into several sub-parts so that each sub parts have exactly one spatial discretization. This method implements the minimal
4214 * splitting that leads to single spatial discretization of this.
4216 * \sa splitMultiDiscrPerGeoTypes
4218 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > MEDFileAnyTypeField1TSWithoutSDA::splitDiscretizations() const
4220 std::vector<INTERP_KERNEL::NormalizedCellType> types;
4221 std::vector< std::vector<TypeOfField> > typesF;
4222 std::vector< std::vector<std::string> > pfls,locs;
4223 std::vector< std::vector<std::pair<int,int> > > bgEnd(getFieldSplitedByType(getMeshName().c_str(),types,typesF,pfls,locs));
4224 std::set<TypeOfField> allEnt;
4225 for(std::vector< std::vector<TypeOfField> >::const_iterator it1=typesF.begin();it1!=typesF.end();it1++)
4226 for(std::vector<TypeOfField>::const_iterator it2=(*it1).begin();it2!=(*it1).end();it2++)
4227 allEnt.insert(*it2);
4228 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > ret(allEnt.size());
4229 std::set<TypeOfField>::const_iterator it3(allEnt.begin());
4230 for(std::size_t i=0;i<allEnt.size();i++,it3++)
4232 std::vector< std::pair<int,int> > its;
4233 ret[i]=shallowCpy();
4234 int newLgth(ret[i]->keepOnlySpatialDiscretization(*it3,its));
4235 ret[i]->updateData(newLgth,its);
4241 * This method performs a sub splitting as splitDiscretizations does but finer. This is the finest spliting level that can be done.
4242 * This method implements the minimal splitting so that each returned elements are mono Gauss discretization per geometric type.
4244 * \sa splitDiscretizations
4246 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > MEDFileAnyTypeField1TSWithoutSDA::splitMultiDiscrPerGeoTypes() const
4248 std::vector<INTERP_KERNEL::NormalizedCellType> types;
4249 std::vector< std::vector<TypeOfField> > typesF;
4250 std::vector< std::vector<std::string> > pfls,locs;
4251 std::vector< std::vector<std::pair<int,int> > > bgEnd(getFieldSplitedByType(getMeshName().c_str(),types,typesF,pfls,locs));
4252 std::set<TypeOfField> allEnt;
4253 std::size_t nbOfMDPGT(0),ii(0);
4254 for(std::vector< std::vector<TypeOfField> >::const_iterator it1=typesF.begin();it1!=typesF.end();it1++,ii++)
4256 nbOfMDPGT=std::max(nbOfMDPGT,locs[ii].size());
4257 for(std::vector<TypeOfField>::const_iterator it2=(*it1).begin();it2!=(*it1).end();it2++)
4258 allEnt.insert(*it2);
4260 if(allEnt.size()!=1)
4261 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::splitMultiDiscrPerGeoTypes : this field is expected to be defined only on one spatial discretization !");
4263 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::splitMultiDiscrPerGeoTypes : empty field !");
4266 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > ret0(1);
4267 ret0[0]=const_cast<MEDFileAnyTypeField1TSWithoutSDA *>(this); this->incrRef();
4270 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > ret(nbOfMDPGT);
4271 for(std::size_t i=0;i<nbOfMDPGT;i++)
4273 std::vector< std::pair<int,int> > its;
4274 ret[i]=shallowCpy();
4275 int newLgth(ret[i]->keepOnlyGaussDiscretization(i,its));
4276 ret[i]->updateData(newLgth,its);
4281 int MEDFileAnyTypeField1TSWithoutSDA::keepOnlySpatialDiscretization(TypeOfField tof, std::vector< std::pair<int,int> >& its)
4283 int globalCounter(0);
4284 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4285 (*it)->keepOnlySpatialDiscretization(tof,globalCounter,its);
4286 return globalCounter;
4289 int MEDFileAnyTypeField1TSWithoutSDA::keepOnlyGaussDiscretization(std::size_t idOfDisc, std::vector< std::pair<int,int> >& its)
4291 int globalCounter(0);
4292 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4293 (*it)->keepOnlyGaussDiscretization(idOfDisc,globalCounter,its);
4294 return globalCounter;
4297 void MEDFileAnyTypeField1TSWithoutSDA::updateData(int newLgth, const std::vector< std::pair<int,int> >& oldStartStops)
4299 if(_nb_of_tuples_to_be_allocated>=0)
4301 _nb_of_tuples_to_be_allocated=newLgth;
4302 const DataArray *oldArr(getUndergroundDataArray());
4305 MEDCouplingAutoRefCountObjectPtr<DataArray> newArr(createNewEmptyDataArrayInstance());
4306 newArr->setInfoAndChangeNbOfCompo(oldArr->getInfoOnComponents());
4308 _nb_of_tuples_to_be_allocated=newLgth;//force the _nb_of_tuples_to_be_allocated because setArray has been used specialy
4312 if(_nb_of_tuples_to_be_allocated==-1)
4314 if(_nb_of_tuples_to_be_allocated==-2 || _nb_of_tuples_to_be_allocated==-3)
4316 const DataArray *oldArr(getUndergroundDataArray());
4317 if(!oldArr || !oldArr->isAllocated())
4318 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::updateData : internal error 1 !");
4319 MEDCouplingAutoRefCountObjectPtr<DataArray> newArr(createNewEmptyDataArrayInstance());
4320 newArr->alloc(newLgth,getNumberOfComponents());
4322 newArr->copyStringInfoFrom(*oldArr);
4324 for(std::vector< std::pair<int,int> >::const_iterator it=oldStartStops.begin();it!=oldStartStops.end();it++)
4326 if((*it).second<(*it).first)
4327 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::updateData : the range in the leaves was invalid !");
4328 newArr->setContigPartOfSelectedValues2(pos,oldArr,(*it).first,(*it).second,1);
4329 pos+=(*it).second-(*it).first;
4334 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::updateData : internal error 2 !");
4337 void MEDFileAnyTypeField1TSWithoutSDA::writeLL(med_idt fid, const MEDFileWritable& opts, const MEDFileFieldNameScope& nasc) const
4339 if(_field_per_mesh.empty())
4340 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::writeLL : empty field !");
4341 if(_field_per_mesh.size()>1)
4342 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::writeLL : In MED3.0 mode in writting mode only ONE underlying mesh supported !");
4343 _field_per_mesh[0]->copyOptionsFrom(opts);
4344 _field_per_mesh[0]->writeLL(fid,nasc);
4348 * 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.
4349 * If false is returned the memory allocation is not required.
4351 bool MEDFileAnyTypeField1TSWithoutSDA::allocIfNecessaryTheArrayToReceiveDataFromFile()
4353 if(_nb_of_tuples_to_be_allocated>=0)
4355 getOrCreateAndGetArray()->alloc(_nb_of_tuples_to_be_allocated,getNumberOfComponents());
4356 _nb_of_tuples_to_be_allocated=-2;
4359 if(_nb_of_tuples_to_be_allocated==-2 || _nb_of_tuples_to_be_allocated==-3)
4361 if(_nb_of_tuples_to_be_allocated==-1)
4362 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::allocIfNecessaryTheArrayToReceiveDataFromFile : trying to read from a file an empty instance ! Need to prepare the structure before !");
4363 if(_nb_of_tuples_to_be_allocated<-3)
4364 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::allocIfNecessaryTheArrayToReceiveDataFromFile : internal error !");
4365 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::allocIfNecessaryTheArrayToReceiveDataFromFile : internal error !");
4368 void MEDFileAnyTypeField1TSWithoutSDA::loadOnlyStructureOfDataRecursively(med_idt fid, const MEDFileFieldNameScope& nasc, const MEDFileMeshes *ms)
4370 med_int numdt,numit;
4374 med_int meshnumdt,meshnumit;
4375 INTERP_KERNEL::AutoPtr<char> meshName=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
4376 MEDfieldComputingStepInfo(fid,nasc.getName().c_str(),_csit,&numdt,&numit,&_dt);
4377 MEDfield23ComputingStepMeshInfo(fid,nasc.getName().c_str(),_csit,&numdt,&numit,&dt,&nmesh,meshName,&localMesh,&meshnumdt,&meshnumit);
4378 if(_iteration!=numdt || _order!=numit)
4379 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::loadBigArraysRecursively : unexpected exception internal error !");
4380 _field_per_mesh.resize(nmesh);
4385 std::string meshNameCpp(MEDLoaderBase::buildStringFromFortran(meshName,MED_NAME_SIZE+1));
4386 mm=ms->getMeshWithName(meshNameCpp);
4389 for(int i=0;i<nmesh;i++)
4390 _field_per_mesh[i]=MEDFileFieldPerMesh::NewOnRead(fid,this,i,meshnumdt,meshnumit,nasc,mm);
4391 _nb_of_tuples_to_be_allocated=0;
4392 for(int i=0;i<nmesh;i++)
4393 _field_per_mesh[i]->loadOnlyStructureOfDataRecursively(fid,_nb_of_tuples_to_be_allocated,nasc);
4396 void MEDFileAnyTypeField1TSWithoutSDA::loadBigArraysRecursively(med_idt fid, const MEDFileFieldNameScope& nasc)
4398 allocIfNecessaryTheArrayToReceiveDataFromFile();
4399 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4400 (*it)->loadBigArraysRecursively(fid,nasc);
4403 void MEDFileAnyTypeField1TSWithoutSDA::loadBigArraysRecursivelyIfNecessary(med_idt fid, const MEDFileFieldNameScope& nasc)
4405 if(allocIfNecessaryTheArrayToReceiveDataFromFile())
4406 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4407 (*it)->loadBigArraysRecursively(fid,nasc);
4410 void MEDFileAnyTypeField1TSWithoutSDA::loadStructureAndBigArraysRecursively(med_idt fid, const MEDFileFieldNameScope& nasc, const MEDFileMeshes *ms)
4412 loadOnlyStructureOfDataRecursively(fid,nasc,ms);
4413 loadBigArraysRecursively(fid,nasc);
4416 void MEDFileAnyTypeField1TSWithoutSDA::unloadArrays()
4418 DataArray *thisArr(getUndergroundDataArray());
4419 if(thisArr && thisArr->isAllocated())
4421 _nb_of_tuples_to_be_allocated=thisArr->getNumberOfTuples();
4422 thisArr->desallocate();
4426 std::size_t MEDFileAnyTypeField1TSWithoutSDA::getHeapMemorySizeWithoutChildren() const
4428 return _dt_unit.capacity()+_field_per_mesh.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh >);
4431 std::vector<const BigMemoryObject *> MEDFileAnyTypeField1TSWithoutSDA::getDirectChildrenWithNull() const
4433 std::vector<const BigMemoryObject *> ret;
4434 if(getUndergroundDataArray())
4435 ret.push_back(getUndergroundDataArray());
4436 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4437 ret.push_back((const MEDFileFieldPerMesh *)*it);
4442 * Adds a MEDCouplingFieldDouble to \a this. The underlying mesh of the given field is
4443 * checked if its elements are sorted suitable for writing to MED file ("STB" stands for
4444 * "Sort By Type"), if not, an exception is thrown.
4445 * \param [in] field - the field to add to \a this. The array of field \a field is ignored
4446 * \param [in] arr - the array of values.
4447 * \param [in,out] glob - the global data where profiles and localization present in
4448 * \a field, if any, are added.
4449 * \throw If the name of \a field is empty.
4450 * \throw If the data array of \a field is not set.
4451 * \throw If \a this->_arr is already allocated but has different number of components
4453 * \throw If the underlying mesh of \a field has no name.
4454 * \throw If elements in the mesh are not in the order suitable for writing to the MED file.
4456 void MEDFileAnyTypeField1TSWithoutSDA::setFieldNoProfileSBT(const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
4458 const MEDCouplingMesh *mesh=field->getMesh();
4460 TypeOfField type=field->getTypeOfField();
4461 std::vector<DataArrayInt *> dummy;
4462 int start=copyTinyInfoFrom(field,arr);
4463 int pos=addNewEntryIfNecessary(mesh);
4466 std::vector<int> code=MEDFileField1TSWithoutSDA::CheckSBTMesh(mesh);
4467 _field_per_mesh[pos]->assignFieldNoProfileNoRenum(start,code,field,arr,glob,nasc);
4470 _field_per_mesh[pos]->assignNodeFieldNoProfile(start,field,arr,glob);
4474 * Adds a MEDCouplingFieldDouble to \a this. Specified entities of a given dimension
4475 * of a given mesh are used as the support of the given field (a real support is not used).
4476 * Elements of the given mesh must be sorted suitable for writing to MED file.
4477 * Order of underlying mesh entities of the given field specified by \a profile parameter
4478 * is not prescribed; this method permutes field values to have them sorted by element
4479 * type as required for writing to MED file. A new profile is added only if no equal
4480 * profile is missing.
4481 * \param [in] field - the field to add to \a this. The field double values are ignored.
4482 * \param [in] arrOfVals - the values of the field \a field used.
4483 * \param [in] mesh - the supporting mesh of \a field.
4484 * \param [in] meshDimRelToMax - a relative dimension of mesh entities \a field lies on.
4485 * \param [in] profile - ids of mesh entities on which corresponding field values lie.
4486 * \param [in,out] glob - the global data where profiles and localization present in
4487 * \a field, if any, are added.
4488 * \throw If either \a field or \a mesh or \a profile has an empty name.
4489 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
4490 * \throw If the data array of \a field is not set.
4491 * \throw If \a this->_arr is already allocated but has different number of components
4493 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
4494 * \sa setFieldNoProfileSBT()
4496 void MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile(const MEDCouplingFieldDouble *field, const DataArray *arrOfVals, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile, MEDFileFieldGlobsReal& glob, const MEDFileFieldNameScope& nasc)
4499 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile : input field is null !");
4500 if(!arrOfVals || !arrOfVals->isAllocated())
4501 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile : input array is null or not allocated !");
4502 TypeOfField type=field->getTypeOfField();
4503 std::vector<DataArrayInt *> idsInPflPerType;
4504 std::vector<DataArrayInt *> idsPerType;
4505 std::vector<int> code,code2;
4506 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> m=mesh->getGenMeshAtLevel(meshDimRelToMax);
4509 m->splitProfilePerType(profile,code,idsInPflPerType,idsPerType);
4510 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > idsInPflPerType2(idsInPflPerType.size()); std::copy(idsInPflPerType.begin(),idsInPflPerType.end(),idsInPflPerType2.begin());
4511 std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > idsPerType2(idsPerType.size()); std::copy(idsPerType.begin(),idsPerType.end(),idsPerType2.begin());
4512 std::vector<const DataArrayInt *> idsPerType3(idsPerType.size()); std::copy(idsPerType.begin(),idsPerType.end(),idsPerType3.begin());
4514 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> field2=field->clone(false);
4515 int nbOfTuplesExp=field2->getNumberOfTuplesExpectedRegardingCode(code,idsPerType3);
4516 if(nbOfTuplesExp!=arrOfVals->getNumberOfTuples())
4518 std::ostringstream oss; oss << "MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile : The array is expected to have " << nbOfTuplesExp << " tuples ! It has " << arrOfVals->getNumberOfTuples() << " !";
4519 throw INTERP_KERNEL::Exception(oss.str().c_str());
4522 int start=copyTinyInfoFrom(field,arrOfVals);
4523 code2=m->getDistributionOfTypes();
4525 int pos=addNewEntryIfNecessary(m);
4526 _field_per_mesh[pos]->assignFieldProfile(start,profile,code,code2,idsInPflPerType,idsPerType,field,arrOfVals,m,glob,nasc);
4530 if(!profile || !profile->isAllocated() || profile->getNumberOfComponents()!=1)
4531 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile : input profile is null, not allocated or with number of components != 1 !");
4532 std::vector<int> v(3); v[0]=-1; v[1]=profile->getNumberOfTuples(); v[2]=0;
4533 std::vector<const DataArrayInt *> idsPerType3(1); idsPerType3[0]=profile;
4534 int nbOfTuplesExp=field->getNumberOfTuplesExpectedRegardingCode(v,idsPerType3);
4535 if(nbOfTuplesExp!=arrOfVals->getNumberOfTuples())
4537 std::ostringstream oss; oss << "MEDFileAnyTypeField1TSWithoutSDA::setFieldProfile : For node field, the array is expected to have " << nbOfTuplesExp << " tuples ! It has " << arrOfVals->getNumberOfTuples() << " !";
4538 throw INTERP_KERNEL::Exception(oss.str().c_str());
4540 int start=copyTinyInfoFrom(field,arrOfVals);
4541 int pos=addNewEntryIfNecessary(m);
4542 _field_per_mesh[pos]->assignNodeFieldProfile(start,profile,field,arrOfVals,glob,nasc);
4547 * \param [in] newNbOfTuples - The new nb of tuples to be allocated.
4549 void MEDFileAnyTypeField1TSWithoutSDA::allocNotFromFile(int newNbOfTuples)
4551 if(_nb_of_tuples_to_be_allocated>=0)
4552 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 !");
4553 DataArray *arr(getOrCreateAndGetArray());
4554 arr->alloc(newNbOfTuples,arr->getNumberOfComponents());
4555 _nb_of_tuples_to_be_allocated=-3;
4559 * Copies tiny info and allocates \a this->_arr instance of DataArrayDouble to
4560 * append data of a given MEDCouplingFieldDouble. So that the size of \a this->_arr becomes
4561 * larger by the size of \a field. Returns an id of the first not filled
4562 * tuple of \a this->_arr.
4563 * \param [in] field - the field to copy the info on components and the name from.
4564 * \return int - the id of first not initialized tuple of \a this->_arr.
4565 * \throw If the name of \a field is empty.
4566 * \throw If the data array of \a field is not set.
4567 * \throw If \a this->_arr is already allocated but has different number of components
4570 int MEDFileAnyTypeField1TSWithoutSDA::copyTinyInfoFrom(const MEDCouplingFieldDouble *field, const DataArray *arr)
4573 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::copyTinyInfoFrom : input field is NULL !");
4574 std::string name(field->getName());
4575 setName(name.c_str());
4576 setDtUnit(field->getTimeUnit());
4578 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::copyTinyInfoFrom : unsupported fields with no name in MED file !");
4580 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::copyTinyInfoFrom : no array set !");
4581 if(!arr->isAllocated())
4582 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::copyTinyInfoFrom : array is not allocated !");
4583 _dt=field->getTime(_iteration,_order);
4584 getOrCreateAndGetArray()->setInfoAndChangeNbOfCompo(arr->getInfoOnComponents());
4585 if(!getOrCreateAndGetArray()->isAllocated())
4587 allocNotFromFile(arr->getNumberOfTuples());
4592 int oldNbOfTuples=getOrCreateAndGetArray()->getNumberOfTuples();
4593 int newNbOfTuples=oldNbOfTuples+arr->getNumberOfTuples();
4594 getOrCreateAndGetArray()->reAlloc(newNbOfTuples);
4595 _nb_of_tuples_to_be_allocated=-3;
4596 return oldNbOfTuples;
4601 * Returns number of components in \a this field
4602 * \return int - the number of components.
4604 int MEDFileAnyTypeField1TSWithoutSDA::getNumberOfComponents() const
4606 return getOrCreateAndGetArray()->getNumberOfComponents();
4610 * Change info on components in \a this.
4611 * \throw If size of \a infos is not equal to the number of components already in \a this.
4613 void MEDFileAnyTypeField1TSWithoutSDA::setInfo(const std::vector<std::string>& infos)
4615 DataArray *arr=getOrCreateAndGetArray();
4616 arr->setInfoOnComponents(infos);//will throw an exception if number of components mimatches
4620 * Returns info on components of \a this field.
4621 * \return const std::vector<std::string>& - a sequence of strings each being an
4622 * information on _i_-th component.
4624 const std::vector<std::string>& MEDFileAnyTypeField1TSWithoutSDA::getInfo() const
4626 const DataArray *arr=getOrCreateAndGetArray();
4627 return arr->getInfoOnComponents();
4631 * Returns a mutable info on components of \a this field.
4632 * \return std::vector<std::string>& - a sequence of strings each being an
4633 * information on _i_-th component.
4635 std::vector<std::string>& MEDFileAnyTypeField1TSWithoutSDA::getInfo()
4637 DataArray *arr=getOrCreateAndGetArray();
4638 return arr->getInfoOnComponents();
4641 bool MEDFileAnyTypeField1TSWithoutSDA::presenceOfMultiDiscPerGeoType() const
4643 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileFieldPerMesh > >::const_iterator it=_field_per_mesh.begin();it!=_field_per_mesh.end();it++)
4645 const MEDFileFieldPerMesh *fpm(*it);
4648 if(fpm->presenceOfMultiDiscPerGeoType())
4655 * Returns a new MEDCouplingFieldDouble of given type lying on a given support.
4656 * \param [in] type - a spatial discretization of the new field.
4657 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
4658 * \param [in] mName - a name of the supporting mesh.
4659 * \param [in] renumPol - specifies how to permute values of the result field according to
4660 * the optional numbers of cells and nodes, if any. The valid values are
4661 * - 0 - do not permute.
4662 * - 1 - permute cells.
4663 * - 2 - permute nodes.
4664 * - 3 - permute cells and nodes.
4666 * \param [in] glob - the global data storing profiles and localization.
4667 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
4668 * caller is to delete this field using decrRef() as it is no more needed.
4669 * \throw If the MED file is not readable.
4670 * \throw If there is no mesh named \a mName in the MED file.
4671 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
4672 * \throw If no field of \a this is lying on the mesh \a mName.
4673 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
4675 MEDCouplingFieldDouble *MEDFileAnyTypeField1TSWithoutSDA::getFieldAtLevel(TypeOfField type, int meshDimRelToMax, const std::string& mName, int renumPol, const MEDFileFieldGlobsReal *glob, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
4677 MEDCouplingAutoRefCountObjectPtr<MEDFileMesh> mm;
4679 mm=MEDFileMesh::New(glob->getFileName(),getMeshName().c_str(),getMeshIteration(),getMeshOrder());
4681 mm=MEDFileMesh::New(glob->getFileName(),mName,getMeshIteration(),getMeshOrder());
4682 return MEDFileAnyTypeField1TSWithoutSDA::getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,glob,mm,arrOut,nasc);
4686 * Returns a new MEDCouplingFieldDouble of given type lying on a given support.
4687 * \param [in] type - a spatial discretization of the new field.
4688 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
4689 * \param [in] renumPol - specifies how to permute values of the result field according to
4690 * the optional numbers of cells and nodes, if any. The valid values are
4691 * - 0 - do not permute.
4692 * - 1 - permute cells.
4693 * - 2 - permute nodes.
4694 * - 3 - permute cells and nodes.
4696 * \param [in] glob - the global data storing profiles and localization.
4697 * \param [in] mesh - the supporting mesh.
4698 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
4699 * caller is to delete this field using decrRef() as it is no more needed.
4700 * \throw If the MED file is not readable.
4701 * \throw If no field of \a this is lying on \a mesh.
4702 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
4703 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
4705 MEDCouplingFieldDouble *MEDFileAnyTypeField1TSWithoutSDA::getFieldOnMeshAtLevel(TypeOfField type, int meshDimRelToMax, int renumPol, const MEDFileFieldGlobsReal *glob, const MEDFileMesh *mesh, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
4707 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> m=mesh->getGenMeshAtLevel(meshDimRelToMax,false);
4708 const DataArrayInt *d=mesh->getNumberFieldAtLevel(meshDimRelToMax);
4709 const DataArrayInt *e=mesh->getNumberFieldAtLevel(1);
4710 if(meshDimRelToMax==1)
4711 (static_cast<MEDCouplingUMesh *>((MEDCouplingMesh *)m))->setMeshDimension(0);
4712 return MEDFileAnyTypeField1TSWithoutSDA::getFieldOnMeshAtLevel(type,renumPol,glob,m,d,e,arrOut,nasc);
4716 * Returns a new MEDCouplingFieldDouble of a given type lying on the top level cells of a
4718 * \param [in] type - a spatial discretization of the new field.
4719 * \param [in] mName - a name of the supporting mesh.
4720 * \param [in] renumPol - specifies how to permute values of the result field according to
4721 * the optional numbers of cells and nodes, if any. The valid values are
4722 * - 0 - do not permute.
4723 * - 1 - permute cells.
4724 * - 2 - permute nodes.
4725 * - 3 - permute cells and nodes.
4727 * \param [in] glob - the global data storing profiles and localization.
4728 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
4729 * caller is to delete this field using decrRef() as it is no more needed.
4730 * \throw If the MED file is not readable.
4731 * \throw If there is no mesh named \a mName in the MED file.
4732 * \throw If there are no mesh entities in the mesh.
4733 * \throw If no field values of the given \a type are available.
4735 MEDCouplingFieldDouble *MEDFileAnyTypeField1TSWithoutSDA::getFieldAtTopLevel(TypeOfField type, const std::string& mName, int renumPol, const MEDFileFieldGlobsReal *glob, MEDCouplingAutoRefCountObjectPtr<DataArray>& arrOut, const MEDFileFieldNameScope& nasc) const
4737 MEDCouplingAutoRefCountObjectPtr<MEDFileMesh> mm;
4739 mm=MEDFileMesh::New(glob->getFileName(),getMeshName().c_str(),getMeshIteration(),getMeshOrder());
4741 mm=MEDFileMesh::New(glob->getFileName(),mName,getMeshIteration(),getMeshOrder());
4742 int absDim=getDimension();
4743 int meshDimRelToMax=absDim-mm->getMeshDimension();
4744 return MEDFileAnyTypeField1TSWithoutSDA::getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,glob,mm,arrOut,nasc);
4748 * Returns a new MEDCouplingFieldDouble of given type lying on a given support.
4749 * \param [in] type - a spatial discretization of the new field.
4750 * \param [in] renumPol - specifies how to permute values of the result field according to
4751 * the optional numbers of cells and nodes, if any. The valid values are
4752 * - 0 - do not permute.
4753 * - 1 - permute cells.
4754 * - 2 - permute nodes.
4755 * - 3 - permute cells and nodes.
4757 * \param [in] glob - the global data storing profiles and localization.
4758 * \param [in] mesh - the supporting mesh.
4759 * \param [in] cellRenum - the cell numbers array used for permutation of the result
4760 * field according to \a renumPol.
4761 * \param [in] nodeRenum - the node numbers array used for permutation of the result
4762 * field according to \a renumPol.
4763 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
4764 * caller is to delete this field using decrRef() as it is no more needed.
4765 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
4766 * \throw If no field of \a this is lying on \a mesh.
4767 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
4769 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
4771 static const char msg1[]="MEDFileField1TSWithoutSDA::getFieldOnMeshAtLevel : request for a renumbered field following mesh numbering whereas it is a profile field !";
4772 int meshId=getMeshIdFromMeshName(mesh->getName());
4774 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=_field_per_mesh[meshId]->getFieldOnMeshAtLevel(type,glob,mesh,isPfl,arrOut,nasc);
4779 //no need to test _field_per_mesh.empty() because geMeshName has already done it
4786 throw INTERP_KERNEL::Exception(msg1);
4787 //no need to test _field_per_mesh.empty() because geMeshName has already done it
4790 if((int)cellRenum->getNbOfElems()!=mesh->getNumberOfCells())
4792 std::ostringstream oss; oss << "MEDFileField1TSWithoutSDA::getFieldOnMeshAtLevel : Request of simple renumbering but it seems that underlying mesh \"" << mesh->getName() << "\" of requested field ";
4793 oss << "\"" << getName() << "\" has partial renumbering (some geotype has no renumber) !";
4794 throw INTERP_KERNEL::Exception(oss.str().c_str());
4796 MEDCouplingFieldDiscretization *disc=ret->getDiscretization();
4797 if(!disc) throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TSWithoutSDA::getFieldOnMeshAtLevel : internal error, no discretization on field !");
4798 std::vector<DataArray *> arrOut2(1,arrOut);
4799 // 2 following lines replace ret->renumberCells(cellRenum->getConstPointer()) if not DataArrayDouble
4800 disc->renumberArraysForCell(ret->getMesh(),arrOut2,cellRenum->getConstPointer(),true);
4801 (const_cast<MEDCouplingMesh*>(ret->getMesh()))->renumberCells(cellRenum->getConstPointer(),true);
4808 //no need to test _field_per_mesh.empty() because geMeshName has already done it
4810 throw INTERP_KERNEL::Exception(msg1);
4813 if((int)nodeRenum->getNbOfElems()!=mesh->getNumberOfNodes())
4815 std::ostringstream oss; oss << "MEDFileField1TSWithoutSDA::getFieldOnMeshAtLevel : Request of simple renumbering but it seems that underlying mesh \"" << mesh->getName() << "\" of requested field ";
4816 oss << "\"" << nasc.getName() << "\" not defined on all nodes !";
4817 throw INTERP_KERNEL::Exception(oss.str().c_str());
4819 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> nodeRenumSafe=nodeRenum->checkAndPreparePermutation();
4820 if(!dynamic_cast<DataArrayDouble *>((DataArray *)arrOut))
4821 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getFieldOnMeshAtLevel : node renumbering not implemented for not double DataArrays !");
4822 ret->renumberNodes(nodeRenumSafe->getConstPointer());
4827 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getFieldOnMeshAtLevel : unsupported renum policy ! Dealing with policy 0 1 2 and 3 !");
4832 * Returns values and a profile of the field of a given type lying on a given support.
4833 * \param [in] type - a spatial discretization of the field.
4834 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
4835 * \param [in] mesh - the supporting mesh.
4836 * \param [out] pfl - a new instance of DataArrayInt holding ids of mesh entities the
4837 * field of interest lies on. If the field lies on all entities of the given
4838 * dimension, all ids in \a pfl are zero. The caller is to delete this array
4839 * using decrRef() as it is no more needed.
4840 * \param [in] glob - the global data storing profiles and localization.
4841 * \return DataArrayDouble * - a new instance of DataArrayDouble holding values of the
4842 * field. The caller is to delete this array using decrRef() as it is no more needed.
4843 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
4844 * \throw If no field of \a this is lying on \a mesh.
4845 * \throw If no field values of the given \a type are available.
4847 DataArray *MEDFileAnyTypeField1TSWithoutSDA::getFieldWithProfile(TypeOfField type, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt *&pfl, const MEDFileFieldGlobsReal *glob, const MEDFileFieldNameScope& nasc) const
4849 MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> m=mesh->getGenMeshAtLevel(meshDimRelToMax);
4850 int meshId=getMeshIdFromMeshName(mesh->getName().c_str());
4851 MEDCouplingAutoRefCountObjectPtr<DataArray> ret=_field_per_mesh[meshId]->getFieldOnMeshAtLevelWithPfl(type,m,pfl,glob,nasc);
4852 ret->setName(nasc.getName().c_str());
4856 //= MEDFileField1TSWithoutSDA
4859 * Throws if a given value is not a valid (non-extended) relative dimension.
4860 * \param [in] meshDimRelToMax - the relative dimension value.
4861 * \throw If \a meshDimRelToMax > 0.
4863 void MEDFileField1TSWithoutSDA::CheckMeshDimRel(int meshDimRelToMax)
4865 if(meshDimRelToMax>0)
4866 throw INTERP_KERNEL::Exception("CheckMeshDimRel : This is a meshDimRel not a meshDimRelExt ! So value should be <=0 !");
4870 * Checks if elements of a given mesh are in the order suitable for writing
4871 * to the MED file. If this is not so, an exception is thrown. In a case of success, returns a
4872 * vector describing types of elements and their number.
4873 * \param [in] mesh - the mesh to check.
4874 * \return std::vector<int> - a vector holding for each element type (1) item of
4875 * INTERP_KERNEL::NormalizedCellType, (2) number of elements, (3) -1.
4876 * These values are in full-interlace mode.
4877 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
4879 std::vector<int> MEDFileField1TSWithoutSDA::CheckSBTMesh(const MEDCouplingMesh *mesh)
4882 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::CheckSBTMesh : input mesh is NULL !");
4883 std::set<INTERP_KERNEL::NormalizedCellType> geoTypes=mesh->getAllGeoTypes();
4884 int nbOfTypes=geoTypes.size();
4885 std::vector<int> code(3*nbOfTypes);
4886 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr1=DataArrayInt::New();
4887 arr1->alloc(nbOfTypes,1);
4888 int *arrPtr=arr1->getPointer();
4889 std::set<INTERP_KERNEL::NormalizedCellType>::const_iterator it=geoTypes.begin();
4890 for(int i=0;i<nbOfTypes;i++,it++)
4891 arrPtr[i]=std::distance(typmai2,std::find(typmai2,typmai2+MED_N_CELL_FIXED_GEO,*it));
4892 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr2=arr1->checkAndPreparePermutation();
4893 const int *arrPtr2=arr2->getConstPointer();
4895 for(it=geoTypes.begin();it!=geoTypes.end();it++,i++)
4898 int nbCells=mesh->getNumberOfCellsWithType(*it);
4899 code[3*pos]=(int)(*it);
4900 code[3*pos+1]=nbCells;
4901 code[3*pos+2]=-1;//no profiles
4903 std::vector<const DataArrayInt *> idsPerType;//no profiles
4904 DataArrayInt *da=mesh->checkTypeConsistencyAndContig(code,idsPerType);
4908 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::CheckSBTMesh : underlying mesh is not sorted by type as MED file expects !");
4913 MEDFileField1TSWithoutSDA *MEDFileField1TSWithoutSDA::New(const std::string& fieldName, int csit, int iteration, int order, const std::vector<std::string>& infos)
4915 return new MEDFileField1TSWithoutSDA(fieldName,csit,iteration,order,infos);
4919 * Returns all attributes and values of parts of \a this field lying on a given mesh.
4920 * Each part differs from other ones by a type of supporting mesh entity. The _i_-th
4921 * item of every of returned sequences refers to the _i_-th part of \a this field.
4922 * Thus all sequences returned by this method are of the same length equal to number
4923 * of different types of supporting entities.<br>
4924 * A field part can include sub-parts with several different spatial discretizations,
4925 * \ref ParaMEDMEM::ON_CELLS "ON_CELLS" and \ref ParaMEDMEM::ON_GAUSS_PT "ON_GAUSS_PT"
4926 * for example. Hence, some of the returned sequences contains nested sequences, and an item
4927 * of a nested sequence corresponds to a type of spatial discretization.<br>
4928 * This method allows for iteration over MEDFile DataStructure with a reduced overhead.
4929 * The overhead is due to selecting values into new instances of DataArrayDouble.
4930 * \param [in] mname - a name of a mesh of interest. It can be \c NULL, which is valid
4931 * for the case with only one underlying mesh. (Actually, the number of meshes is
4932 * not checked if \a mname == \c NULL).
4933 * \param [in,out] types - a sequence of types of underlying mesh entities. A type per
4934 * a field part is returned.
4935 * \param [in,out] typesF - a sequence of sequences of types of spatial discretizations.
4936 * A field part can include sub-parts with several different spatial discretizations,
4937 * \ref ParaMEDMEM::ON_CELLS "ON_CELLS" and
4938 * \ref ParaMEDMEM::ON_GAUSS_PT "ON_GAUSS_PT" for example.
4939 * This sequence is of the same length as \a types.
4940 * \param [in,out] pfls - a sequence returning a profile name per each type of spatial
4941 * discretization. A profile name can be empty.
4942 * Length of this and of nested sequences is the same as that of \a typesF.
4943 * \param [in,out] locs - a sequence returning a localization name per each type of spatial
4944 * discretization. A localization name can be empty.
4945 * Length of this and of nested sequences is the same as that of \a typesF.
4946 * \return std::vector< std::vector<DataArrayDouble *> > - a sequence holding arrays of values
4947 * per each type of spatial discretization within one mesh entity type.
4948 * The caller is to delete each DataArrayDouble using decrRef() as it is no more needed.
4949 * Length of this and of nested sequences is the same as that of \a typesF.
4950 * \throw If no field is lying on \a mname.
4952 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
4956 meshId=getMeshIdFromMeshName(mname);
4958 if(_field_per_mesh.empty())
4959 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getFieldSplitedByType : This is empty !");
4960 std::vector< std::vector< std::pair<int,int> > > ret0=_field_per_mesh[meshId]->getFieldSplitedByType(types,typesF,pfls,locs);
4961 int nbOfRet=ret0.size();
4962 std::vector< std::vector<DataArrayDouble *> > ret(nbOfRet);
4963 for(int i=0;i<nbOfRet;i++)
4965 const std::vector< std::pair<int,int> >& p=ret0[i];
4966 int nbOfRet1=p.size();
4967 ret[i].resize(nbOfRet1);
4968 for(int j=0;j<nbOfRet1;j++)
4970 DataArrayDouble *tmp=_arr->selectByTupleId2(p[j].first,p[j].second,1);
4978 * Returns a pointer to the underground DataArrayDouble instance. So the
4979 * caller should not decrRef() it. This method allows for a direct access to the field
4980 * values. This method is quite unusable if there is more than a nodal field or a cell
4981 * field on single geometric cell type.
4982 * \return DataArrayDouble * - the pointer to the field values array.
4984 DataArrayDouble *MEDFileField1TSWithoutSDA::getUndergroundDataArrayDouble() const
4986 const DataArrayDouble *ret=_arr;
4988 return const_cast<DataArrayDouble *>(ret);
4993 const char *MEDFileField1TSWithoutSDA::getTypeStr() const
4998 MEDFileIntField1TSWithoutSDA *MEDFileField1TSWithoutSDA::convertToInt() const
5000 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TSWithoutSDA> ret(new MEDFileIntField1TSWithoutSDA);
5001 ret->MEDFileAnyTypeField1TSWithoutSDA::operator =(*this);
5002 ret->deepCpyLeavesFrom(*this);
5003 const DataArrayDouble *arr(_arr);
5006 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> arr2(arr->convertToIntArr());
5007 ret->setArray(arr2);
5013 * Returns a pointer to the underground DataArrayDouble instance. So the
5014 * caller should not decrRef() it. This method allows for a direct access to the field
5015 * values. This method is quite unusable if there is more than a nodal field or a cell
5016 * field on single geometric cell type.
5017 * \return DataArrayDouble * - the pointer to the field values array.
5019 DataArray *MEDFileField1TSWithoutSDA::getUndergroundDataArray() const
5021 return getUndergroundDataArrayDouble();
5025 * Returns a pointer to the underground DataArrayDouble 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 DataArrayDouble. 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 DataArrayDouble * - 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 DataArrayDouble *MEDFileField1TSWithoutSDA::getUndergroundDataArrayDoubleExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
5042 if(_field_per_mesh.size()!=1)
5043 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt : field lies on several meshes, this method has no sense !");
5044 if(_field_per_mesh[0]==0)
5045 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt : no field specified !");
5046 _field_per_mesh[0]->getUndergroundDataArrayExt(entries);
5047 return getUndergroundDataArrayDouble();
5051 * Returns a pointer to the underground DataArrayDouble instance and a
5052 * sequence describing parameters of a support of each part of \a this field. The
5053 * caller should not decrRef() the returned DataArrayDouble. This method allows for a
5054 * direct access to the field values. This method is intended for the field lying on one
5056 * \param [in,out] entries - the sequence describing parameters of a support of each
5057 * part of \a this field. Each item of this sequence consists of two parts. The
5058 * first part describes a type of mesh entity and an id of discretization of a
5059 * current field part. The second part describes a range of values [begin,end)
5060 * within the returned array relating to the current field part.
5061 * \return DataArrayDouble * - the pointer to the field values array.
5062 * \throw If the number of underlying meshes is not equal to 1.
5063 * \throw If no field values are available.
5064 * \sa getUndergroundDataArray()
5066 DataArray *MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
5068 return getUndergroundDataArrayDoubleExt(entries);
5071 MEDFileField1TSWithoutSDA::MEDFileField1TSWithoutSDA(const std::string& fieldName, int csit, int iteration, int order, const std::vector<std::string>& infos):MEDFileAnyTypeField1TSWithoutSDA(fieldName,csit,iteration,order)
5073 DataArrayDouble *arr(getOrCreateAndGetArrayDouble());
5074 arr->setInfoAndChangeNbOfCompo(infos);
5077 MEDFileField1TSWithoutSDA::MEDFileField1TSWithoutSDA():MEDFileAnyTypeField1TSWithoutSDA()
5081 MEDFileAnyTypeField1TSWithoutSDA *MEDFileField1TSWithoutSDA::shallowCpy() const
5083 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TSWithoutSDA> ret(new MEDFileField1TSWithoutSDA(*this));
5084 ret->deepCpyLeavesFrom(*this);
5088 MEDFileAnyTypeField1TSWithoutSDA *MEDFileField1TSWithoutSDA::deepCpy() const
5090 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TSWithoutSDA> ret=static_cast<MEDFileField1TSWithoutSDA *>(shallowCpy());
5091 if((const DataArrayDouble *)_arr)
5092 ret->_arr=_arr->deepCpy();
5096 void MEDFileField1TSWithoutSDA::setArray(DataArray *arr)
5100 _nb_of_tuples_to_be_allocated=-1;
5104 DataArrayDouble *arrC=dynamic_cast<DataArrayDouble *>(arr);
5106 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::setArray : the input not null array is not of type DataArrayDouble !");
5108 _nb_of_tuples_to_be_allocated=-3;
5113 DataArray *MEDFileField1TSWithoutSDA::createNewEmptyDataArrayInstance() const
5115 return DataArrayDouble::New();
5118 DataArrayDouble *MEDFileField1TSWithoutSDA::getOrCreateAndGetArrayDouble()
5120 DataArrayDouble *ret=_arr;
5123 _arr=DataArrayDouble::New();
5127 DataArray *MEDFileField1TSWithoutSDA::getOrCreateAndGetArray()
5129 return getOrCreateAndGetArrayDouble();
5132 const DataArrayDouble *MEDFileField1TSWithoutSDA::getOrCreateAndGetArrayDouble() const
5134 const DataArrayDouble *ret=_arr;
5137 DataArrayDouble *ret2=DataArrayDouble::New();
5138 const_cast<MEDFileField1TSWithoutSDA *>(this)->_arr=DataArrayDouble::New();
5142 const DataArray *MEDFileField1TSWithoutSDA::getOrCreateAndGetArray() const
5144 return getOrCreateAndGetArrayDouble();
5147 //= MEDFileIntField1TSWithoutSDA
5149 MEDFileIntField1TSWithoutSDA *MEDFileIntField1TSWithoutSDA::New(const std::string& fieldName, int csit, int iteration, int order, const std::vector<std::string>& infos)
5151 return new MEDFileIntField1TSWithoutSDA(fieldName,csit,iteration,order,infos);
5154 MEDFileIntField1TSWithoutSDA::MEDFileIntField1TSWithoutSDA():MEDFileAnyTypeField1TSWithoutSDA()
5158 MEDFileIntField1TSWithoutSDA::MEDFileIntField1TSWithoutSDA(const std::string& fieldName, int csit, int iteration, int order,
5159 const std::vector<std::string>& infos):MEDFileAnyTypeField1TSWithoutSDA(fieldName,csit,iteration,order)
5161 DataArrayInt *arr(getOrCreateAndGetArrayInt());
5162 arr->setInfoAndChangeNbOfCompo(infos);
5165 const char *MEDFileIntField1TSWithoutSDA::getTypeStr() const
5170 MEDFileField1TSWithoutSDA *MEDFileIntField1TSWithoutSDA::convertToDouble() const
5172 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TSWithoutSDA> ret(new MEDFileField1TSWithoutSDA);
5173 ret->MEDFileAnyTypeField1TSWithoutSDA::operator =(*this);
5174 ret->deepCpyLeavesFrom(*this);
5175 const DataArrayInt *arr(_arr);
5178 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arr2(arr->convertToDblArr());
5179 ret->setArray(arr2);
5185 * Returns a pointer to the underground DataArrayInt instance. So the
5186 * caller should not decrRef() it. This method allows for a direct access to the field
5187 * values. This method is quite unusable if there is more than a nodal field or a cell
5188 * field on single geometric cell type.
5189 * \return DataArrayInt * - the pointer to the field values array.
5191 DataArray *MEDFileIntField1TSWithoutSDA::getUndergroundDataArray() const
5193 return getUndergroundDataArrayInt();
5197 * Returns a pointer to the underground DataArrayInt instance. So the
5198 * caller should not decrRef() it. This method allows for a direct access to the field
5199 * values. This method is quite unusable if there is more than a nodal field or a cell
5200 * field on single geometric cell type.
5201 * \return DataArrayInt * - the pointer to the field values array.
5203 DataArrayInt *MEDFileIntField1TSWithoutSDA::getUndergroundDataArrayInt() const
5205 const DataArrayInt *ret=_arr;
5207 return const_cast<DataArrayInt *>(ret);
5213 * Returns a pointer to the underground DataArrayInt instance and a
5214 * sequence describing parameters of a support of each part of \a this field. The
5215 * caller should not decrRef() the returned DataArrayInt. This method allows for a
5216 * direct access to the field values. This method is intended for the field lying on one
5218 * \param [in,out] entries - the sequence describing parameters of a support of each
5219 * part of \a this field. Each item of this sequence consists of two parts. The
5220 * first part describes a type of mesh entity and an id of discretization of a
5221 * current field part. The second part describes a range of values [begin,end)
5222 * within the returned array relating to the current field part.
5223 * \return DataArrayInt * - the pointer to the field values array.
5224 * \throw If the number of underlying meshes is not equal to 1.
5225 * \throw If no field values are available.
5226 * \sa getUndergroundDataArray()
5228 DataArray *MEDFileIntField1TSWithoutSDA::getUndergroundDataArrayExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
5230 return getUndergroundDataArrayIntExt(entries);
5234 * Returns a pointer to the underground DataArrayInt instance and a
5235 * sequence describing parameters of a support of each part of \a this field. The
5236 * caller should not decrRef() the returned DataArrayInt. This method allows for a
5237 * direct access to the field values. This method is intended for the field lying on one
5239 * \param [in,out] entries - the sequence describing parameters of a support of each
5240 * part of \a this field. Each item of this sequence consists of two parts. The
5241 * first part describes a type of mesh entity and an id of discretization of a
5242 * current field part. The second part describes a range of values [begin,end)
5243 * within the returned array relating to the current field part.
5244 * \return DataArrayInt * - the pointer to the field values array.
5245 * \throw If the number of underlying meshes is not equal to 1.
5246 * \throw If no field values are available.
5247 * \sa getUndergroundDataArray()
5249 DataArrayInt *MEDFileIntField1TSWithoutSDA::getUndergroundDataArrayIntExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
5251 if(_field_per_mesh.size()!=1)
5252 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt : field lies on several meshes, this method has no sense !");
5253 if(_field_per_mesh[0]==0)
5254 throw INTERP_KERNEL::Exception("MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt : no field specified !");
5255 _field_per_mesh[0]->getUndergroundDataArrayExt(entries);
5256 return getUndergroundDataArrayInt();
5259 MEDFileAnyTypeField1TSWithoutSDA *MEDFileIntField1TSWithoutSDA::shallowCpy() const
5261 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TSWithoutSDA> ret(new MEDFileIntField1TSWithoutSDA(*this));
5262 ret->deepCpyLeavesFrom(*this);
5266 MEDFileAnyTypeField1TSWithoutSDA *MEDFileIntField1TSWithoutSDA::deepCpy() const
5268 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TSWithoutSDA> ret=static_cast<MEDFileIntField1TSWithoutSDA *>(shallowCpy());
5269 if((const DataArrayInt *)_arr)
5270 ret->_arr=_arr->deepCpy();
5274 void MEDFileIntField1TSWithoutSDA::setArray(DataArray *arr)
5278 _nb_of_tuples_to_be_allocated=-1;
5282 DataArrayInt *arrC=dynamic_cast<DataArrayInt *>(arr);
5284 throw INTERP_KERNEL::Exception("MEDFileIntField1TSWithoutSDA::setArray : the input not null array is not of type DataArrayInt !");
5286 _nb_of_tuples_to_be_allocated=-3;
5291 DataArray *MEDFileIntField1TSWithoutSDA::createNewEmptyDataArrayInstance() const
5293 return DataArrayInt::New();
5296 DataArrayInt *MEDFileIntField1TSWithoutSDA::getOrCreateAndGetArrayInt()
5298 DataArrayInt *ret=_arr;
5301 _arr=DataArrayInt::New();
5305 DataArray *MEDFileIntField1TSWithoutSDA::getOrCreateAndGetArray()
5307 return getOrCreateAndGetArrayInt();
5310 const DataArrayInt *MEDFileIntField1TSWithoutSDA::getOrCreateAndGetArrayInt() const
5312 const DataArrayInt *ret=_arr;
5315 DataArrayInt *ret2=DataArrayInt::New();
5316 const_cast<MEDFileIntField1TSWithoutSDA *>(this)->_arr=DataArrayInt::New();
5320 const DataArray *MEDFileIntField1TSWithoutSDA::getOrCreateAndGetArray() const
5322 return getOrCreateAndGetArrayInt();
5325 MEDFileAnyTypeField1TS::MEDFileAnyTypeField1TS()
5329 //= MEDFileAnyTypeField1TS
5331 MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeField1TS::BuildContentFrom(med_idt fid, const std::string& fileName, bool loadAll, const MEDFileMeshes *ms)
5333 med_field_type typcha;
5335 std::vector<std::string> infos;
5336 std::string dtunit,fieldName;
5337 LocateField2(fid,fileName,0,true,fieldName,typcha,infos,dtunit);
5338 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> ret;
5343 ret=MEDFileField1TSWithoutSDA::New(fieldName.c_str(),-1,-1/*iteration*/,-1/*order*/,std::vector<std::string>());
5348 ret=MEDFileIntField1TSWithoutSDA::New(fieldName.c_str(),-1,-1/*iteration*/,-1/*order*/,std::vector<std::string>());
5353 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] !";
5354 throw INTERP_KERNEL::Exception(oss.str().c_str());
5357 ret->setDtUnit(dtunit.c_str());
5358 ret->getOrCreateAndGetArray()->setInfoAndChangeNbOfCompo(infos);
5360 med_int numdt,numit;
5362 MEDfieldComputingStepInfo(fid,fieldName.c_str(),1,&numdt,&numit,&dt);
5363 ret->setTime(numdt,numit,dt);
5366 ret->loadStructureAndBigArraysRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret),ms);
5368 ret->loadOnlyStructureOfDataRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret),ms);
5372 MEDFileAnyTypeField1TS::MEDFileAnyTypeField1TS(const std::string& fileName, bool loadAll, const MEDFileMeshes *ms)
5373 try:MEDFileFieldGlobsReal(fileName)
5375 MEDFileUtilities::CheckFileForRead(fileName);
5376 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5377 _content=BuildContentFrom(fid,fileName,loadAll,ms);
5380 catch(INTERP_KERNEL::Exception& e)
5385 MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeField1TS::BuildContentFrom(med_idt fid, const std::string& fileName, const std::string& fieldName, bool loadAll, const MEDFileMeshes *ms)
5387 med_field_type typcha;
5388 std::vector<std::string> infos;
5391 int nbSteps=LocateField(fid,fileName,fieldName,iii,typcha,infos,dtunit);
5392 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> ret;
5397 ret=MEDFileField1TSWithoutSDA::New(fieldName,-1,-1/*iteration*/,-1/*order*/,std::vector<std::string>());
5402 ret=MEDFileIntField1TSWithoutSDA::New(fieldName,-1,-1/*iteration*/,-1/*order*/,std::vector<std::string>());
5407 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] !";
5408 throw INTERP_KERNEL::Exception(oss.str().c_str());
5411 ret->setDtUnit(dtunit.c_str());
5412 ret->getOrCreateAndGetArray()->setInfoAndChangeNbOfCompo(infos);
5416 std::ostringstream oss; oss << "MEDFileField1TS(fileName,fieldName) : file \'" << fileName << "\' contains field with name \'" << fieldName << "\' but there is no time steps on it !";
5417 throw INTERP_KERNEL::Exception(oss.str().c_str());
5420 med_int numdt,numit;
5422 MEDfieldComputingStepInfo(fid,fieldName.c_str(),1,&numdt,&numit,&dt);
5423 ret->setTime(numdt,numit,dt);
5426 ret->loadStructureAndBigArraysRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret),ms);
5428 ret->loadOnlyStructureOfDataRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret),ms);
5432 MEDFileAnyTypeField1TS::MEDFileAnyTypeField1TS(const std::string& fileName, const std::string& fieldName, bool loadAll, const MEDFileMeshes *ms)
5433 try:MEDFileFieldGlobsReal(fileName)
5435 MEDFileUtilities::CheckFileForRead(fileName);
5436 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5437 _content=BuildContentFrom(fid,fileName,fieldName,loadAll,ms);
5440 catch(INTERP_KERNEL::Exception& e)
5445 MEDFileAnyTypeField1TS *MEDFileAnyTypeField1TS::BuildNewInstanceFromContent(MEDFileAnyTypeField1TSWithoutSDA *c, const std::string& fileName)
5448 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS::BuildNewInstanceFromContent : empty content in input : unable to build a new instance !");
5449 if(dynamic_cast<const MEDFileField1TSWithoutSDA *>(c))
5451 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret=MEDFileField1TS::New();
5452 ret->setFileName(fileName);
5453 ret->_content=c; c->incrRef();
5456 if(dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(c))
5458 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret=MEDFileIntField1TS::New();
5459 ret->setFileName(fileName);
5460 ret->_content=c; c->incrRef();
5463 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS::BuildNewInstanceFromContent : internal error ! a content of type different from FLOAT64 and INT32 has been built but not intercepted !");
5466 MEDFileAnyTypeField1TS *MEDFileAnyTypeField1TS::New(const std::string& fileName, bool loadAll)
5468 MEDFileUtilities::CheckFileForRead(fileName);
5469 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5470 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> c=BuildContentFrom(fid,fileName,loadAll,0);
5471 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> ret=BuildNewInstanceFromContent(c,fileName);
5472 ret->loadGlobals(fid);
5476 MEDFileAnyTypeField1TS *MEDFileAnyTypeField1TS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
5478 MEDFileUtilities::CheckFileForRead(fileName);
5479 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5480 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> c=BuildContentFrom(fid,fileName,fieldName,loadAll,0);
5481 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> ret=BuildNewInstanceFromContent(c,fileName);
5482 ret->loadGlobals(fid);
5486 MEDFileAnyTypeField1TS *MEDFileAnyTypeField1TS::New(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll)
5488 MEDFileUtilities::CheckFileForRead(fileName);
5489 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5490 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> c=BuildContentFrom(fid,fileName,fieldName,iteration,order,loadAll,0);
5491 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> ret=BuildNewInstanceFromContent(c,fileName);
5492 ret->loadGlobals(fid);
5496 MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeField1TS::BuildContentFrom(med_idt fid, const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll, const MEDFileMeshes *ms)
5498 med_field_type typcha;
5499 std::vector<std::string> infos;
5502 int nbOfStep2=LocateField(fid,fileName,fieldName,iii,typcha,infos,dtunit);
5503 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> ret;
5508 ret=MEDFileField1TSWithoutSDA::New(fieldName,-1,iteration,order,std::vector<std::string>());
5513 ret=MEDFileIntField1TSWithoutSDA::New(fieldName,-1,iteration,order,std::vector<std::string>());
5518 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] !";
5519 throw INTERP_KERNEL::Exception(oss.str().c_str());
5522 ret->setDtUnit(dtunit.c_str());
5523 ret->getOrCreateAndGetArray()->setInfoAndChangeNbOfCompo(infos);
5526 std::vector< std::pair<int,int> > dtits(nbOfStep2);
5527 for(int i=0;i<nbOfStep2 && !found;i++)
5529 med_int numdt,numit;
5531 MEDfieldComputingStepInfo(fid,fieldName.c_str(),i+1,&numdt,&numit,&dt);
5532 if(numdt==iteration && numit==order)
5538 dtits[i]=std::pair<int,int>(numdt,numit);
5542 std::ostringstream oss; oss << "No such iteration (" << iteration << "," << order << ") in existing field '" << fieldName << "' in file '" << fileName << "' ! Available iterations are : ";
5543 for(std::vector< std::pair<int,int> >::const_iterator iter=dtits.begin();iter!=dtits.end();iter++)
5544 oss << "(" << (*iter).first << "," << (*iter).second << "), ";
5545 throw INTERP_KERNEL::Exception(oss.str().c_str());
5548 ret->loadStructureAndBigArraysRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret),ms);
5550 ret->loadOnlyStructureOfDataRecursively(fid,*((const MEDFileAnyTypeField1TSWithoutSDA*)ret),ms);
5554 MEDFileAnyTypeField1TS::MEDFileAnyTypeField1TS(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll, const MEDFileMeshes *ms)
5555 try:MEDFileFieldGlobsReal(fileName)
5557 MEDFileUtilities::CheckFileForRead(fileName);
5558 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
5559 _content=BuildContentFrom(fid,fileName.c_str(),fieldName.c_str(),iteration,order,loadAll,ms);
5562 catch(INTERP_KERNEL::Exception& e)
5568 * This constructor is a shallow copy constructor. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
5569 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
5571 * \warning this is a shallow copy constructor
5573 MEDFileAnyTypeField1TS::MEDFileAnyTypeField1TS(const MEDFileAnyTypeField1TSWithoutSDA& other, bool shallowCopyOfContent)
5575 if(!shallowCopyOfContent)
5577 const MEDFileAnyTypeField1TSWithoutSDA *otherPtr(&other);
5578 otherPtr->incrRef();
5579 _content=const_cast<MEDFileAnyTypeField1TSWithoutSDA *>(otherPtr);
5583 _content=other.shallowCpy();
5587 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)
5591 int nbFields=MEDnField(fid);
5592 if(fieldIdCFormat>=nbFields)
5594 std::ostringstream oss; oss << "MEDFileAnyTypeField1TS::LocateField2(fileName) : in file \'" << fileName << "\' number of fields is " << nbFields << " ! Trying to request for id " << fieldIdCFormat << " !";
5595 throw INTERP_KERNEL::Exception(oss.str().c_str());
5598 int ncomp=MEDfieldnComponent(fid,fieldIdCFormat+1);
5599 INTERP_KERNEL::AutoPtr<char> comp=MEDLoaderBase::buildEmptyString(ncomp*MED_SNAME_SIZE);
5600 INTERP_KERNEL::AutoPtr<char> unit=MEDLoaderBase::buildEmptyString(ncomp*MED_SNAME_SIZE);
5601 INTERP_KERNEL::AutoPtr<char> dtunit=MEDLoaderBase::buildEmptyString(MED_LNAME_SIZE);
5602 INTERP_KERNEL::AutoPtr<char> nomcha=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
5603 INTERP_KERNEL::AutoPtr<char> nomMaa=MEDLoaderBase::buildEmptyString(MED_NAME_SIZE);
5606 MEDfieldInfo(fid,fieldIdCFormat+1,nomcha,nomMaa,&localMesh,&typcha,comp,unit,dtunit,&nbOfStep);
5607 fieldName=MEDLoaderBase::buildStringFromFortran(nomcha,MED_NAME_SIZE);
5608 dtunitOut=MEDLoaderBase::buildStringFromFortran(dtunit,MED_LNAME_SIZE);
5609 infos.clear(); infos.resize(ncomp);
5610 for(int j=0;j<ncomp;j++)
5611 infos[j]=MEDLoaderBase::buildUnionUnit((char *)comp+j*MED_SNAME_SIZE,MED_SNAME_SIZE,(char *)unit+j*MED_SNAME_SIZE,MED_SNAME_SIZE);
5616 * This method throws an INTERP_KERNEL::Exception if \a fieldName field is not in file pointed by \a fid and with name \a fileName.
5619 * \return in case of success the number of time steps available for the field with name \a fieldName.
5621 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)
5623 int nbFields=MEDnField(fid);
5625 std::vector<std::string> fns(nbFields);
5627 for(int i=0;i<nbFields && !found;i++)
5630 nbOfStep2=LocateField2(fid,fileName,i,false,tmp,typcha,infos,dtunitOut);
5632 found=(tmp==fieldName);
5638 std::ostringstream oss; oss << "No such field '" << fieldName << "' in file '" << fileName << "' ! Available fields are : ";
5639 for(std::vector<std::string>::const_iterator it=fns.begin();it!=fns.end();it++)
5640 oss << "\"" << *it << "\" ";
5641 throw INTERP_KERNEL::Exception(oss.str().c_str());
5647 * This method as MEDFileField1TSW::setLocNameOnLeaf, is dedicated for advanced user that a want a very fine control on their data structure
5648 * without overhead. This method can be called only regarding information returned by MEDFileField1TSWithoutSDA::getFieldSplitedByType or MEDFileField1TSWithoutSDA::getFieldSplitedByType2.
5649 * This method changes the attribute (here it's profile name) of the leaf datastructure (MEDFileFieldPerMeshPerTypePerDisc instance).
5650 * It is the responsability of the caller to invoke MEDFileFieldGlobs::appendProfile or MEDFileFieldGlobs::getProfile
5651 * to keep a valid instance.
5652 * 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.
5653 * If \b newPflName profile name does not already exist the profile with old name will be renamed with name \b newPflName.
5654 * 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.
5656 * \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.
5657 * \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.
5658 * \param [in] locId is the localization id to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set. It corresponds to the position of
5659 * \c pfls[std::distance(types.begin(),std::find(types.begin(),typ)] vector in MEDFileField1TSWithoutSDA::getFieldSplitedByType. For non gausspoints field users, the value is 0.
5660 * \param [in] newLocName is the new localization name.
5661 * \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.
5662 * If false, an exception will be thrown to force user to change previously the name of the profile with name \b newPflName
5664 void MEDFileAnyTypeField1TS::setProfileNameOnLeaf(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId, const std::string& newPflName, bool forceRenameOnGlob)
5666 MEDFileFieldPerMeshPerTypePerDisc *disc=getLeafGivenMeshAndTypeAndLocId(mName,typ,locId);
5667 std::string oldPflName=disc->getProfile();
5668 std::vector<std::string> vv=getPflsReallyUsedMulti();
5669 int nbOfOcc=std::count(vv.begin(),vv.end(),oldPflName);
5670 if(forceRenameOnGlob || (!existsPfl(newPflName) && nbOfOcc==1))
5672 disc->setProfile(newPflName);
5673 DataArrayInt *pfl=getProfile(oldPflName.c_str());
5674 pfl->setName(newPflName);
5678 std::ostringstream oss; oss << "MEDFileField1TS::setProfileNameOnLeaf : Profile \"" << newPflName << "\" already exists or referenced more than one !";
5679 throw INTERP_KERNEL::Exception(oss.str().c_str());
5684 * This method as MEDFileField1TSW::setProfileNameOnLeaf, is dedicated for advanced user that a want a very fine control on their data structure
5685 * without overhead. This method can be called only regarding information returned by MEDFileField1TSWithoutSDA::getFieldSplitedByType or MEDFileField1TSWithoutSDA::getFieldSplitedByType2.
5686 * This method changes the attribute (here it's localization name) of the leaf datastructure (MEDFileFieldPerMeshPerTypePerDisc instance).
5687 * It is the responsability of the caller to invoke MEDFileFieldGlobs::appendProfile or MEDFileFieldGlobs::getProfile
5688 * to keep a valid instance.
5689 * 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.
5690 * This method is an extension of MEDFileField1TSWithoutSDA::setProfileNameOnLeafExt method because it performs a modification of global info.
5691 * If \b newLocName profile name does not already exist the localization with old name will be renamed with name \b newLocName.
5692 * 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.
5694 * \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.
5695 * \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.
5696 * \param [in] locId is the localization id to find the right MEDFileFieldPerMeshPerTypePerDisc instance to set. It corresponds to the position of
5697 * \c pfls[std::distance(types.begin(),std::find(types.begin(),typ)] vector in MEDFileField1TSWithoutSDA::getFieldSplitedByType. For non gausspoints field users, the value is 0.
5698 * \param [in] newLocName is the new localization name.
5699 * \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.
5700 * If false, an exception will be thrown to force user to change previously the name of the profile with name \b newLocName
5702 void MEDFileAnyTypeField1TS::setLocNameOnLeaf(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId, const std::string& newLocName, bool forceRenameOnGlob)
5704 MEDFileFieldPerMeshPerTypePerDisc *disc=getLeafGivenMeshAndTypeAndLocId(mName,typ,locId);
5705 std::string oldLocName=disc->getLocalization();
5706 std::vector<std::string> vv=getLocsReallyUsedMulti();
5707 int nbOfOcc=std::count(vv.begin(),vv.end(),oldLocName);
5708 if(forceRenameOnGlob || (!existsLoc(newLocName) && nbOfOcc==1))
5710 disc->setLocalization(newLocName);
5711 MEDFileFieldLoc& loc=getLocalization(oldLocName.c_str());
5712 loc.setName(newLocName);
5716 std::ostringstream oss; oss << "MEDFileField1TS::setLocNameOnLeaf : Localization \"" << newLocName << "\" already exists or referenced more than one !";
5717 throw INTERP_KERNEL::Exception(oss.str().c_str());
5721 MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeField1TS::contentNotNullBase()
5723 MEDFileAnyTypeField1TSWithoutSDA *ret=_content;
5725 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS : content is expected to be not null !");
5729 const MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeField1TS::contentNotNullBase() const
5731 const MEDFileAnyTypeField1TSWithoutSDA *ret=_content;
5733 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS : const content is expected to be not null !");
5738 * Writes \a this field into a MED file specified by its name.
5739 * \param [in] fileName - the MED file name.
5740 * \param [in] mode - the writing mode. For more on \a mode, see \ref AdvMEDLoaderBasics.
5741 * - 2 - erase; an existing file is removed.
5742 * - 1 - append; same data should not be present in an existing file.
5743 * - 0 - overwrite; same data present in an existing file is overwritten.
5744 * \throw If the field name is not set.
5745 * \throw If no field data is set.
5746 * \throw If \a mode == 1 and the same data is present in an existing file.
5748 void MEDFileAnyTypeField1TS::write(const std::string& fileName, int mode) const
5750 med_access_mode medmod=MEDFileUtilities::TraduceWriteMode(mode);
5751 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),medmod);
5756 * This method alloc the arrays and load potentially huge arrays contained in this field.
5757 * This method should be called when a MEDFileAnyTypeField1TS::New constructor has been with false as the last parameter.
5758 * This method can be also called to refresh or reinit values from a file.
5760 * \throw If the fileName is not set or points to a non readable MED file.
5761 * \sa MEDFileAnyTypeField1TS::loadArraysIfNecessary
5763 void MEDFileAnyTypeField1TS::loadArrays()
5765 if(getFileName().empty())
5766 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS::loadArrays : the structure does not come from a file !");
5767 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
5768 contentNotNullBase()->loadBigArraysRecursively(fid,*contentNotNullBase());
5772 * This method behaves as MEDFileAnyTypeField1TS::loadArrays does, the first call, if \a this was built using a file without loading big arrays.
5773 * But once data loaded once, this method does nothing. Contrary to MEDFileAnyTypeField1TS::loadArrays and MEDFileAnyTypeField1TS::unloadArrays
5774 * this method does not throw if \a this does not come from file read.
5776 * \sa MEDFileAnyTypeField1TS::loadArrays, MEDFileAnyTypeField1TS::unloadArrays
5778 void MEDFileAnyTypeField1TS::loadArraysIfNecessary()
5780 if(!getFileName().empty())
5782 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
5783 contentNotNullBase()->loadBigArraysRecursivelyIfNecessary(fid,*contentNotNullBase());
5788 * This method releases potentially big data arrays and so returns to the same heap memory than status loaded with 'loadAll' parameter set to false.
5789 * \b WARNING, this method does release arrays even if \a this does not come from a load of a MED file.
5790 * So this method can lead to a loss of data. If you want to unload arrays safely call MEDFileAnyTypeField1TS::unloadArraysWithoutDataLoss instead.
5792 * \sa MEDFileAnyTypeField1TS::loadArrays, MEDFileAnyTypeField1TS::loadArraysIfNecessary, MEDFileAnyTypeField1TS::unloadArraysWithoutDataLoss
5794 void MEDFileAnyTypeField1TS::unloadArrays()
5796 contentNotNullBase()->unloadArrays();
5800 * This method potentially releases big data arrays if \a this is coming from a file. If \a this has been built from scratch this method will have no effect.
5801 * This method is the symetrical method of MEDFileAnyTypeField1TS::loadArraysIfNecessary.
5802 * This method is useful to reduce \b safely amount of heap memory necessary for \a this by using MED file as database.
5804 * \sa MEDFileAnyTypeField1TS::loadArraysIfNecessary
5806 void MEDFileAnyTypeField1TS::unloadArraysWithoutDataLoss()
5808 if(!getFileName().empty())
5809 contentNotNullBase()->unloadArrays();
5812 void MEDFileAnyTypeField1TS::writeLL(med_idt fid) const
5814 int nbComp=getNumberOfComponents();
5815 INTERP_KERNEL::AutoPtr<char> comp=MEDLoaderBase::buildEmptyString(nbComp*MED_SNAME_SIZE);
5816 INTERP_KERNEL::AutoPtr<char> unit=MEDLoaderBase::buildEmptyString(nbComp*MED_SNAME_SIZE);
5817 for(int i=0;i<nbComp;i++)
5819 std::string info=getInfo()[i];
5821 MEDLoaderBase::splitIntoNameAndUnit(info,c,u);
5822 MEDLoaderBase::safeStrCpy2(c.c_str(),MED_SNAME_SIZE,comp+i*MED_SNAME_SIZE,_too_long_str);
5823 MEDLoaderBase::safeStrCpy2(u.c_str(),MED_SNAME_SIZE,unit+i*MED_SNAME_SIZE,_too_long_str);
5825 if(getName().empty())
5826 throw INTERP_KERNEL::Exception("MEDFileField1TS::write : MED file does not accept field with empty name !");
5827 MEDfieldCr(fid,getName().c_str(),getMEDFileFieldType(),nbComp,comp,unit,getDtUnit().c_str(),getMeshName().c_str());
5828 writeGlobals(fid,*this);
5829 contentNotNullBase()->writeLL(fid,*this,*contentNotNullBase());
5832 std::size_t MEDFileAnyTypeField1TS::getHeapMemorySizeWithoutChildren() const
5834 return MEDFileFieldGlobsReal::getHeapMemorySizeWithoutChildren();
5837 std::vector<const BigMemoryObject *> MEDFileAnyTypeField1TS::getDirectChildrenWithNull() const
5839 std::vector<const BigMemoryObject *> ret(MEDFileFieldGlobsReal::getDirectChildrenWithNull());
5840 ret.push_back((const MEDFileAnyTypeField1TSWithoutSDA *)_content);
5845 * Returns a string describing \a this field. This string is outputted
5846 * by \c print Python command.
5848 std::string MEDFileAnyTypeField1TS::simpleRepr() const
5850 std::ostringstream oss;
5851 contentNotNullBase()->simpleRepr(0,oss,-1);
5852 simpleReprGlobs(oss);
5857 * This method returns all profiles whose name is non empty used.
5858 * \b WARNING If profile is used several times it will be reported \b only \b once.
5859 * To get non empty name profiles as time as they appear in \b this call MEDFileField1TS::getPflsReallyUsedMulti instead.
5861 std::vector<std::string> MEDFileAnyTypeField1TS::getPflsReallyUsed() const
5863 return contentNotNullBase()->getPflsReallyUsed2();
5867 * This method returns all localizations whose name is non empty used.
5868 * \b WARNING If localization is used several times it will be reported \b only \b once.
5870 std::vector<std::string> MEDFileAnyTypeField1TS::getLocsReallyUsed() const
5872 return contentNotNullBase()->getLocsReallyUsed2();
5876 * This method returns all profiles whose name is non empty used.
5877 * \b WARNING contrary to MEDFileField1TS::getPflsReallyUsed, if profile is used several times it will be reported as time as it appears.
5879 std::vector<std::string> MEDFileAnyTypeField1TS::getPflsReallyUsedMulti() const
5881 return contentNotNullBase()->getPflsReallyUsedMulti2();
5885 * This method returns all localizations whose name is non empty used.
5886 * \b WARNING contrary to MEDFileField1TS::getLocsReallyUsed if localization is used several times it will be reported as time as it appears.
5888 std::vector<std::string> MEDFileAnyTypeField1TS::getLocsReallyUsedMulti() const
5890 return contentNotNullBase()->getLocsReallyUsedMulti2();
5893 void MEDFileAnyTypeField1TS::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
5895 contentNotNullBase()->changePflsRefsNamesGen2(mapOfModif);
5898 void MEDFileAnyTypeField1TS::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
5900 contentNotNullBase()->changeLocsRefsNamesGen2(mapOfModif);
5903 int MEDFileAnyTypeField1TS::getDimension() const
5905 return contentNotNullBase()->getDimension();
5908 int MEDFileAnyTypeField1TS::getIteration() const
5910 return contentNotNullBase()->getIteration();
5913 int MEDFileAnyTypeField1TS::getOrder() const
5915 return contentNotNullBase()->getOrder();
5918 double MEDFileAnyTypeField1TS::getTime(int& iteration, int& order) const
5920 return contentNotNullBase()->getTime(iteration,order);
5923 void MEDFileAnyTypeField1TS::setTime(int iteration, int order, double val)
5925 contentNotNullBase()->setTime(iteration,order,val);
5928 std::string MEDFileAnyTypeField1TS::getName() const
5930 return contentNotNullBase()->getName();
5933 void MEDFileAnyTypeField1TS::setName(const std::string& name)
5935 contentNotNullBase()->setName(name);
5938 void MEDFileAnyTypeField1TS::simpleRepr(int bkOffset, std::ostream& oss, int f1tsId) const
5940 contentNotNullBase()->simpleRepr(bkOffset,oss,f1tsId);
5943 std::string MEDFileAnyTypeField1TS::getDtUnit() const
5945 return contentNotNullBase()->getDtUnit();
5948 void MEDFileAnyTypeField1TS::setDtUnit(const std::string& dtUnit)
5950 contentNotNullBase()->setDtUnit(dtUnit);
5953 std::string MEDFileAnyTypeField1TS::getMeshName() const
5955 return contentNotNullBase()->getMeshName();
5958 void MEDFileAnyTypeField1TS::setMeshName(const std::string& newMeshName)
5960 contentNotNullBase()->setMeshName(newMeshName);
5963 bool MEDFileAnyTypeField1TS::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
5965 return contentNotNullBase()->changeMeshNames(modifTab);
5968 int MEDFileAnyTypeField1TS::getMeshIteration() const
5970 return contentNotNullBase()->getMeshIteration();
5973 int MEDFileAnyTypeField1TS::getMeshOrder() const
5975 return contentNotNullBase()->getMeshOrder();
5978 int MEDFileAnyTypeField1TS::getNumberOfComponents() const
5980 return contentNotNullBase()->getNumberOfComponents();
5983 bool MEDFileAnyTypeField1TS::isDealingTS(int iteration, int order) const
5985 return contentNotNullBase()->isDealingTS(iteration,order);
5988 std::pair<int,int> MEDFileAnyTypeField1TS::getDtIt() const
5990 return contentNotNullBase()->getDtIt();
5993 void MEDFileAnyTypeField1TS::fillIteration(std::pair<int,int>& p) const
5995 contentNotNullBase()->fillIteration(p);
5998 void MEDFileAnyTypeField1TS::fillTypesOfFieldAvailable(std::vector<TypeOfField>& types) const
6000 contentNotNullBase()->fillTypesOfFieldAvailable(types);
6003 void MEDFileAnyTypeField1TS::setInfo(const std::vector<std::string>& infos)
6005 contentNotNullBase()->setInfo(infos);
6008 const std::vector<std::string>& MEDFileAnyTypeField1TS::getInfo() const
6010 return contentNotNullBase()->getInfo();
6012 std::vector<std::string>& MEDFileAnyTypeField1TS::getInfo()
6014 return contentNotNullBase()->getInfo();
6017 bool MEDFileAnyTypeField1TS::presenceOfMultiDiscPerGeoType() const
6019 return contentNotNullBase()->presenceOfMultiDiscPerGeoType();
6022 MEDFileFieldPerMeshPerTypePerDisc *MEDFileAnyTypeField1TS::getLeafGivenMeshAndTypeAndLocId(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId)
6024 return contentNotNullBase()->getLeafGivenMeshAndTypeAndLocId(mName,typ,locId);
6027 const MEDFileFieldPerMeshPerTypePerDisc *MEDFileAnyTypeField1TS::getLeafGivenMeshAndTypeAndLocId(const std::string& mName, INTERP_KERNEL::NormalizedCellType typ, int locId) const
6029 return contentNotNullBase()->getLeafGivenMeshAndTypeAndLocId(mName,typ,locId);
6032 int MEDFileAnyTypeField1TS::getNonEmptyLevels(const std::string& mname, std::vector<int>& levs) const
6034 return contentNotNullBase()->getNonEmptyLevels(mname,levs);
6037 std::vector<TypeOfField> MEDFileAnyTypeField1TS::getTypesOfFieldAvailable() const
6039 return contentNotNullBase()->getTypesOfFieldAvailable();
6042 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,
6043 std::vector< std::vector<std::string> >& pfls, std::vector< std::vector<std::string> >& locs) const
6045 return contentNotNullBase()->getFieldSplitedByType(mname,types,typesF,pfls,locs);
6049 * This method returns as MEDFileAnyTypeField1TS new instances as number of components in \a this.
6050 * The returned instances are deep copy of \a this except that for globals that are share with those contained in \a this.
6051 * ** WARNING ** do no forget to rename the ouput instances to avoid to write n-times in the same MED file field !
6053 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TS > > MEDFileAnyTypeField1TS::splitComponents() const
6055 const MEDFileAnyTypeField1TSWithoutSDA *content(_content);
6057 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS::splitComponents : no content in this ! Unable to split components !");
6058 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > contentsSplit=content->splitComponents();
6059 std::size_t sz(contentsSplit.size());
6060 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TS > > ret(sz);
6061 for(std::size_t i=0;i<sz;i++)
6063 ret[i]=shallowCpy();
6064 ret[i]->_content=contentsSplit[i];
6070 * This method returns as MEDFileAnyTypeField1TS new instances as number of spatial discretizations in \a this.
6071 * The returned instances are shallowed copied of \a this except that for globals that are share with those contained in \a this.
6073 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TS > > MEDFileAnyTypeField1TS::splitDiscretizations() const
6075 const MEDFileAnyTypeField1TSWithoutSDA *content(_content);
6077 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS::splitDiscretizations : no content in this ! Unable to split discretization !");
6078 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > contentsSplit(content->splitDiscretizations());
6079 std::size_t sz(contentsSplit.size());
6080 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TS > > ret(sz);
6081 for(std::size_t i=0;i<sz;i++)
6083 ret[i]=shallowCpy();
6084 ret[i]->_content=contentsSplit[i];
6090 * This method returns as MEDFileAnyTypeField1TS new instances as number of maximal number of discretization in \a this.
6091 * The returned instances are shallowed copied of \a this except that for globals that are share with those contained in \a this.
6093 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TS > > MEDFileAnyTypeField1TS::splitMultiDiscrPerGeoTypes() const
6095 const MEDFileAnyTypeField1TSWithoutSDA *content(_content);
6097 throw INTERP_KERNEL::Exception("MEDFileAnyTypeField1TS::splitMultiDiscrPerGeoTypes : no content in this ! Unable to split discretization !");
6098 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > contentsSplit(content->splitMultiDiscrPerGeoTypes());
6099 std::size_t sz(contentsSplit.size());
6100 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TS > > ret(sz);
6101 for(std::size_t i=0;i<sz;i++)
6103 ret[i]=shallowCpy();
6104 ret[i]->_content=contentsSplit[i];
6109 MEDFileAnyTypeField1TS *MEDFileAnyTypeField1TS::deepCpy() const
6111 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> ret=shallowCpy();
6112 if((const MEDFileAnyTypeField1TSWithoutSDA *)_content)
6113 ret->_content=_content->deepCpy();
6114 ret->deepCpyGlobs(*this);
6118 int MEDFileAnyTypeField1TS::copyTinyInfoFrom(const MEDCouplingFieldDouble *field, const DataArray *arr)
6120 return contentNotNullBase()->copyTinyInfoFrom(field,arr);
6126 * Returns a new instance of MEDFileField1TS holding data of the first time step of
6127 * the first field that has been read from a specified MED file.
6128 * \param [in] fileName - the name of the MED file to read.
6129 * \return MEDFileField1TS * - a new instance of MEDFileFieldMultiTS. The caller
6130 * is to delete this field using decrRef() as it is no more needed.
6131 * \throw If reading the file fails.
6133 MEDFileField1TS *MEDFileField1TS::New(const std::string& fileName, bool loadAll)
6135 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret(new MEDFileField1TS(fileName,loadAll,0));
6136 ret->contentNotNull();
6141 * Returns a new instance of MEDFileField1TS holding data of the first time step of
6142 * a given field that has been read from a specified MED file.
6143 * \param [in] fileName - the name of the MED file to read.
6144 * \param [in] fieldName - the name of the field to read.
6145 * \return MEDFileField1TS * - a new instance of MEDFileFieldMultiTS. The caller
6146 * is to delete this field using decrRef() as it is no more needed.
6147 * \throw If reading the file fails.
6148 * \throw If there is no field named \a fieldName in the file.
6150 MEDFileField1TS *MEDFileField1TS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
6152 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret(new MEDFileField1TS(fileName,fieldName,loadAll,0));
6153 ret->contentNotNull();
6158 * Returns a new instance of MEDFileField1TS holding data of a given time step of
6159 * a given field that has been read from a specified MED file.
6160 * \param [in] fileName - the name of the MED file to read.
6161 * \param [in] fieldName - the name of the field to read.
6162 * \param [in] iteration - the iteration number of a required time step.
6163 * \param [in] order - the iteration order number of required time step.
6164 * \return MEDFileField1TS * - a new instance of MEDFileFieldMultiTS. The caller
6165 * is to delete this field using decrRef() as it is no more needed.
6166 * \throw If reading the file fails.
6167 * \throw If there is no field named \a fieldName in the file.
6168 * \throw If the required time step is missing from the file.
6170 MEDFileField1TS *MEDFileField1TS::New(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll)
6172 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret(new MEDFileField1TS(fileName,fieldName,iteration,order,loadAll,0));
6173 ret->contentNotNull();
6178 * Returns a new instance of MEDFileField1TS. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
6179 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
6181 * Returns a new instance of MEDFileField1TS holding either a shallow copy
6182 * of a given MEDFileField1TSWithoutSDA ( \a other ) or \a other itself.
6183 * \warning this is a shallow copy constructor
6184 * \param [in] other - a MEDFileField1TSWithoutSDA to copy.
6185 * \param [in] shallowCopyOfContent - if \c true, a shallow copy of \a other is created.
6186 * \return MEDFileField1TS * - a new instance of MEDFileField1TS. The caller
6187 * is to delete this field using decrRef() as it is no more needed.
6189 MEDFileField1TS *MEDFileField1TS::New(const MEDFileField1TSWithoutSDA& other, bool shallowCopyOfContent)
6191 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret=new MEDFileField1TS(other,shallowCopyOfContent);
6192 ret->contentNotNull();
6197 * Returns a new empty instance of MEDFileField1TS.
6198 * \return MEDFileField1TS * - a new instance of MEDFileField1TS. The caller
6199 * is to delete this field using decrRef() as it is no more needed.
6201 MEDFileField1TS *MEDFileField1TS::New()
6203 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret=new MEDFileField1TS;
6204 ret->contentNotNull();
6209 * This method performs a copy with datatype modification ( float64->int32 ) of \a this. The globals information are copied
6210 * following the given input policy.
6212 * \param [in] isDeepCpyGlobs - a boolean that indicates the behaviour concerning globals (profiles and localizations)
6213 * By default (true) the globals are deeply copied.
6214 * \return MEDFileIntField1TS * - a new object that is the result of the conversion of \a this to int32 field.
6216 MEDFileIntField1TS *MEDFileField1TS::convertToInt(bool isDeepCpyGlobs) const
6218 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret;
6219 const MEDFileAnyTypeField1TSWithoutSDA *content(_content);
6222 const MEDFileField1TSWithoutSDA *contc=dynamic_cast<const MEDFileField1TSWithoutSDA *>(content);
6224 throw INTERP_KERNEL::Exception("MEDFileField1TS::convertToInt : the content inside this is not FLOAT64 ! This is incoherent !");
6225 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TSWithoutSDA> newc(contc->convertToInt());
6226 ret=static_cast<MEDFileIntField1TS *>(MEDFileAnyTypeField1TS::BuildNewInstanceFromContent((MEDFileIntField1TSWithoutSDA *)newc,getFileName()));
6229 ret=MEDFileIntField1TS::New();
6231 ret->deepCpyGlobs(*this);
6233 ret->shallowCpyGlobs(*this);
6237 const MEDFileField1TSWithoutSDA *MEDFileField1TS::contentNotNull() const
6239 const MEDFileAnyTypeField1TSWithoutSDA *pt(_content);
6241 throw INTERP_KERNEL::Exception("MEDFileField1TS::contentNotNull : the content pointer is null !");
6242 const MEDFileField1TSWithoutSDA *ret=dynamic_cast<const MEDFileField1TSWithoutSDA *>(pt);
6244 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 !");
6248 MEDFileField1TSWithoutSDA *MEDFileField1TS::contentNotNull()
6250 MEDFileAnyTypeField1TSWithoutSDA *pt(_content);
6252 throw INTERP_KERNEL::Exception("MEDFileField1TS::contentNotNull : the non const content pointer is null !");
6253 MEDFileField1TSWithoutSDA *ret=dynamic_cast<MEDFileField1TSWithoutSDA *>(pt);
6255 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 !");
6259 void MEDFileField1TS::SetDataArrayDoubleInField(MEDCouplingFieldDouble *f, MEDCouplingAutoRefCountObjectPtr<DataArray>& arr)
6262 throw INTERP_KERNEL::Exception("MEDFileField1TS::SetDataArrayDoubleInField : input field is NULL !");
6263 if(!((DataArray*)arr))
6264 throw INTERP_KERNEL::Exception("MEDFileField1TS::SetDataArrayDoubleInField : no array !");
6265 DataArrayDouble *arrOutC=dynamic_cast<DataArrayDouble *>((DataArray*)arr);
6267 throw INTERP_KERNEL::Exception("MEDFileField1TS::SetDataArrayDoubleInField : mismatch between dataArrays type and MEDFileField1TS ! Expected double !");
6268 f->setArray(arrOutC);
6271 DataArrayDouble *MEDFileField1TS::ReturnSafelyDataArrayDouble(MEDCouplingAutoRefCountObjectPtr<DataArray>& arr)
6273 if(!((DataArray*)arr))
6274 throw INTERP_KERNEL::Exception("MEDFileField1TS::ReturnSafelyDataArrayDouble : no array !");
6275 DataArrayDouble *arrOutC=dynamic_cast<DataArrayDouble *>((DataArray*)arr);
6277 throw INTERP_KERNEL::Exception("MEDFileField1TS::ReturnSafelyDataArrayDouble : mismatch between dataArrays type and MEDFileField1TS ! Expected double !");
6282 MEDFileField1TS::MEDFileField1TS(const std::string& fileName, bool loadAll, const MEDFileMeshes *ms)
6283 try:MEDFileAnyTypeField1TS(fileName,loadAll,ms)
6286 catch(INTERP_KERNEL::Exception& e)
6289 MEDFileField1TS::MEDFileField1TS(const std::string& fileName, const std::string& fieldName, bool loadAll, const MEDFileMeshes *ms)
6290 try:MEDFileAnyTypeField1TS(fileName,fieldName,loadAll,ms)
6293 catch(INTERP_KERNEL::Exception& e)
6296 MEDFileField1TS::MEDFileField1TS(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll, const MEDFileMeshes *ms)
6297 try:MEDFileAnyTypeField1TS(fileName,fieldName,iteration,order,loadAll,ms)
6300 catch(INTERP_KERNEL::Exception& e)
6304 * This constructor is a shallow copy constructor. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
6305 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
6307 * \warning this is a shallow copy constructor
6309 MEDFileField1TS::MEDFileField1TS(const MEDFileField1TSWithoutSDA& other, bool shallowCopyOfContent)
6310 try:MEDFileAnyTypeField1TS(other,shallowCopyOfContent)
6313 catch(INTERP_KERNEL::Exception& e)
6316 MEDFileField1TS::MEDFileField1TS()
6318 _content=new MEDFileField1TSWithoutSDA;
6322 * Returns a new MEDCouplingFieldDouble of a given type lying on
6323 * mesh entities of a given dimension of the first mesh in MED file. If \a this field
6324 * has not been constructed via file reading, an exception is thrown.
6325 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6326 * \param [in] type - a spatial discretization of interest.
6327 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6328 * \param [in] renumPol - specifies how to permute values of the result field according to
6329 * the optional numbers of cells and nodes, if any. The valid values are
6330 * - 0 - do not permute.
6331 * - 1 - permute cells.
6332 * - 2 - permute nodes.
6333 * - 3 - permute cells and nodes.
6335 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6336 * caller is to delete this field using decrRef() as it is no more needed.
6337 * \throw If \a this field has not been constructed via file reading.
6338 * \throw If the MED file is not readable.
6339 * \throw If there is no mesh in the MED file.
6340 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
6341 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6342 * \sa getFieldOnMeshAtLevel()
6344 MEDCouplingFieldDouble *MEDFileField1TS::getFieldAtLevel(TypeOfField type, int meshDimRelToMax, int renumPol) const
6346 if(getFileName().empty())
6347 throw INTERP_KERNEL::Exception("MEDFileField1TS::getFieldAtLevel : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtLevel method instead !");
6348 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
6349 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtLevel(type,meshDimRelToMax,std::string(),renumPol,this,arrOut,*contentNotNull());
6350 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
6355 * Returns a new MEDCouplingFieldDouble of a given type lying on
6356 * the top level cells of the first mesh in MED file. If \a this field
6357 * has not been constructed via file reading, an exception is thrown.
6358 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6359 * \param [in] type - a spatial discretization of interest.
6360 * \param [in] renumPol - specifies how to permute values of the result field according to
6361 * the optional numbers of cells and nodes, if any. The valid values are
6362 * - 0 - do not permute.
6363 * - 1 - permute cells.
6364 * - 2 - permute nodes.
6365 * - 3 - permute cells and nodes.
6367 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6368 * caller is to delete this field using decrRef() as it is no more needed.
6369 * \throw If \a this field has not been constructed via file reading.
6370 * \throw If the MED file is not readable.
6371 * \throw If there is no mesh in the MED file.
6372 * \throw If no field values of the given \a type.
6373 * \throw If no field values lying on the top level support.
6374 * \sa getFieldAtLevel()
6376 MEDCouplingFieldDouble *MEDFileField1TS::getFieldAtTopLevel(TypeOfField type, int renumPol) const
6378 if(getFileName().empty())
6379 throw INTERP_KERNEL::Exception("MEDFileField1TS::getFieldAtTopLevel : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtTopLevel method instead !");
6380 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
6381 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtTopLevel(type,std::string(),renumPol,this,arrOut,*contentNotNull());
6382 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
6387 * Returns a new MEDCouplingFieldDouble of given type lying on a given mesh.
6388 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6389 * \param [in] type - a spatial discretization of the new field.
6390 * \param [in] mesh - the supporting mesh.
6391 * \param [in] renumPol - specifies how to permute values of the result field according to
6392 * the optional numbers of cells and nodes, if any. The valid values are
6393 * - 0 - do not permute.
6394 * - 1 - permute cells.
6395 * - 2 - permute nodes.
6396 * - 3 - permute cells and nodes.
6398 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6399 * caller is to delete this field using decrRef() as it is no more needed.
6400 * \throw If no field of \a this is lying on \a mesh.
6401 * \throw If the mesh is empty.
6402 * \throw If no field values of the given \a type are available.
6403 * \sa getFieldAtLevel()
6404 * \sa getFieldOnMeshAtLevel()
6406 MEDCouplingFieldDouble *MEDFileField1TS::getFieldOnMeshAtLevel(TypeOfField type, const MEDCouplingMesh *mesh, int renumPol) const
6408 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
6409 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldOnMeshAtLevel(type,renumPol,this,mesh,0,0,arrOut,*contentNotNull());
6410 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
6415 * Returns a new MEDCouplingFieldDouble of a given type lying on a given support.
6416 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6417 * \param [in] type - a spatial discretization of interest.
6418 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6419 * \param [in] mesh - the supporting mesh.
6420 * \param [in] renumPol - specifies how to permute values of the result field according to
6421 * the optional numbers of cells and nodes, if any. The valid values are
6422 * - 0 - do not permute.
6423 * - 1 - permute cells.
6424 * - 2 - permute nodes.
6425 * - 3 - permute cells and nodes.
6427 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6428 * caller is to delete this field using decrRef() as it is no more needed.
6429 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
6430 * \throw If no field of \a this is lying on \a mesh.
6431 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6432 * \sa getFieldAtLevel()
6433 * \sa getFieldOnMeshAtLevel()
6435 MEDCouplingFieldDouble *MEDFileField1TS::getFieldOnMeshAtLevel(TypeOfField type, int meshDimRelToMax, const MEDFileMesh *mesh, int renumPol) const
6437 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
6438 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,this,mesh,arrOut,*contentNotNull());
6439 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
6444 * Returns a new MEDCouplingFieldDouble of a given type lying on a given support.
6445 * This method is called "Old" because in MED3 norm a field has only one meshName
6446 * attached, so this method is for readers of MED2 files. If \a this field
6447 * has not been constructed via file reading, an exception is thrown.
6448 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6449 * \param [in] type - a spatial discretization of interest.
6450 * \param [in] mName - a name of the supporting mesh.
6451 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6452 * \param [in] renumPol - specifies how to permute values of the result field according to
6453 * the optional numbers of cells and nodes, if any. The valid values are
6454 * - 0 - do not permute.
6455 * - 1 - permute cells.
6456 * - 2 - permute nodes.
6457 * - 3 - permute cells and nodes.
6459 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6460 * caller is to delete this field using decrRef() as it is no more needed.
6461 * \throw If the MED file is not readable.
6462 * \throw If there is no mesh named \a mName in the MED file.
6463 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
6464 * \throw If \a this field has not been constructed via file reading.
6465 * \throw If no field of \a this is lying on the mesh named \a mName.
6466 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6467 * \sa getFieldAtLevel()
6469 MEDCouplingFieldDouble *MEDFileField1TS::getFieldAtLevelOld(TypeOfField type, const std::string& mname, int meshDimRelToMax, int renumPol) const
6471 if(getFileName().empty())
6472 throw INTERP_KERNEL::Exception("MEDFileField1TS::getFieldAtLevelOld : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtLevel method instead !");
6473 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
6474 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtLevel(type,meshDimRelToMax,mname,renumPol,this,arrOut,*contentNotNull());
6475 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
6480 * Returns values and a profile of the field of a given type lying on a given support.
6481 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6482 * \param [in] type - a spatial discretization of the field.
6483 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6484 * \param [in] mesh - the supporting mesh.
6485 * \param [out] pfl - a new instance of DataArrayInt holding ids of mesh entities the
6486 * field of interest lies on. If the field lies on all entities of the given
6487 * dimension, all ids in \a pfl are zero. The caller is to delete this array
6488 * using decrRef() as it is no more needed.
6489 * \return DataArrayDouble * - a new instance of DataArrayDouble holding values of the
6490 * field. The caller is to delete this array using decrRef() as it is no more needed.
6491 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
6492 * \throw If no field of \a this is lying on \a mesh.
6493 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6495 DataArrayDouble *MEDFileField1TS::getFieldWithProfile(TypeOfField type, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt *&pfl) const
6497 MEDCouplingAutoRefCountObjectPtr<DataArray> ret=contentNotNull()->getFieldWithProfile(type,meshDimRelToMax,mesh,pfl,this,*contentNotNull());
6498 return MEDFileField1TS::ReturnSafelyDataArrayDouble(ret);
6502 * Adds a MEDCouplingFieldDouble to \a this. The underlying mesh of the given field is
6503 * checked if its elements are sorted suitable for writing to MED file ("STB" stands for
6504 * "Sort By Type"), if not, an exception is thrown.
6505 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6506 * \param [in] field - the field to add to \a this.
6507 * \throw If the name of \a field is empty.
6508 * \throw If the data array of \a field is not set.
6509 * \throw If the data array is already allocated but has different number of components
6511 * \throw If the underlying mesh of \a field has no name.
6512 * \throw If elements in the mesh are not in the order suitable for writing to the MED file.
6514 void MEDFileField1TS::setFieldNoProfileSBT(const MEDCouplingFieldDouble *field)
6517 contentNotNull()->setFieldNoProfileSBT(field,field->getArray(),*this,*contentNotNull());
6521 * Adds a MEDCouplingFieldDouble to \a this. As described in \ref MEDLoaderMainC a field in MED file sense
6522 * can be an aggregation of several MEDCouplingFieldDouble instances.
6523 * The mesh support of input parameter \a field is ignored here, it can be NULL.
6524 * The support of field \a field is expected to be those computed with the input parameter \a mesh, \a meshDimRelToMax,
6527 * This method will check that the field based on the computed support is coherent. If not an exception will be thrown.
6528 * A new profile is added only if no equal profile is missing.
6529 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6530 * \param [in] field - the field to add to \a this. The mesh support of field is ignored.
6531 * \param [in] mesh - the supporting mesh of \a field.
6532 * \param [in] meshDimRelToMax - a relative dimension of mesh entities \a field lies on (useless if field spatial discretization is ON_NODES).
6533 * \param [in] profile - ids of mesh entities on which corresponding field values lie.
6534 * \throw If either \a field or \a mesh or \a profile has an empty name.
6535 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
6536 * \throw If the data array of \a field is not set.
6537 * \throw If the data array of \a this is already allocated but has different number of
6538 * components than \a field.
6539 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
6540 * \sa setFieldNoProfileSBT()
6542 void MEDFileField1TS::setFieldProfile(const MEDCouplingFieldDouble *field, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile)
6545 contentNotNull()->setFieldProfile(field,field->getArray(),mesh,meshDimRelToMax,profile,*this,*contentNotNull());
6548 MEDFileAnyTypeField1TS *MEDFileField1TS::shallowCpy() const
6550 return new MEDFileField1TS(*this);
6553 DataArrayDouble *MEDFileField1TS::getUndergroundDataArray() const
6555 return contentNotNull()->getUndergroundDataArrayDouble();
6558 DataArrayDouble *MEDFileField1TS::getUndergroundDataArrayExt(std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
6560 return contentNotNull()->getUndergroundDataArrayDoubleExt(entries);
6563 std::vector< std::vector<DataArrayDouble *> > MEDFileField1TS::getFieldSplitedByType2(const std::string& mname, std::vector<INTERP_KERNEL::NormalizedCellType>& types, std::vector< std::vector<TypeOfField> >& typesF,
6564 std::vector< std::vector<std::string> >& pfls, std::vector< std::vector<std::string> >& locs) const
6566 return contentNotNull()->getFieldSplitedByType2(mname,types,typesF,pfls,locs);
6569 //= MEDFileIntField1TS
6571 MEDFileIntField1TS *MEDFileIntField1TS::New()
6573 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret=new MEDFileIntField1TS;
6574 ret->contentNotNull();
6578 MEDFileIntField1TS *MEDFileIntField1TS::New(const std::string& fileName, bool loadAll)
6580 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret(new MEDFileIntField1TS(fileName,loadAll,0));
6581 ret->contentNotNull();
6585 MEDFileIntField1TS *MEDFileIntField1TS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
6587 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret(new MEDFileIntField1TS(fileName,fieldName,loadAll,0));
6588 ret->contentNotNull();
6592 MEDFileIntField1TS *MEDFileIntField1TS::New(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll)
6594 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret(new MEDFileIntField1TS(fileName,fieldName,iteration,order,loadAll,0));
6595 ret->contentNotNull();
6599 MEDFileIntField1TS *MEDFileIntField1TS::New(const MEDFileIntField1TSWithoutSDA& other, bool shallowCopyOfContent)
6601 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret=new MEDFileIntField1TS(other,shallowCopyOfContent);
6602 ret->contentNotNull();
6606 MEDFileIntField1TS::MEDFileIntField1TS()
6608 _content=new MEDFileIntField1TSWithoutSDA;
6611 MEDFileIntField1TS::MEDFileIntField1TS(const std::string& fileName, bool loadAll, const MEDFileMeshes *ms)
6612 try:MEDFileAnyTypeField1TS(fileName,loadAll,ms)
6615 catch(INTERP_KERNEL::Exception& e)
6618 MEDFileIntField1TS::MEDFileIntField1TS(const std::string& fileName, const std::string& fieldName, bool loadAll, const MEDFileMeshes *ms)
6619 try:MEDFileAnyTypeField1TS(fileName,fieldName,loadAll,ms)
6622 catch(INTERP_KERNEL::Exception& e)
6625 MEDFileIntField1TS::MEDFileIntField1TS(const std::string& fileName, const std::string& fieldName, int iteration, int order, bool loadAll, const MEDFileMeshes *ms)
6626 try:MEDFileAnyTypeField1TS(fileName,fieldName,iteration,order,loadAll,ms)
6629 catch(INTERP_KERNEL::Exception& e)
6633 * This constructor is a shallow copy constructor. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
6634 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
6636 * \warning this is a shallow copy constructor
6638 MEDFileIntField1TS::MEDFileIntField1TS(const MEDFileIntField1TSWithoutSDA& other, bool shallowCopyOfContent):MEDFileAnyTypeField1TS(other,shallowCopyOfContent)
6642 MEDFileAnyTypeField1TS *MEDFileIntField1TS::shallowCpy() const
6644 return new MEDFileIntField1TS(*this);
6648 * This method performs a copy with datatype modification ( int32->float64 ) of \a this. The globals information are copied
6649 * following the given input policy.
6651 * \param [in] isDeepCpyGlobs - a boolean that indicates the behaviour concerning globals (profiles and localizations)
6652 * By default (true) the globals are deeply copied.
6653 * \return MEDFileField1TS * - a new object that is the result of the conversion of \a this to float64 field.
6655 MEDFileField1TS *MEDFileIntField1TS::convertToDouble(bool isDeepCpyGlobs) const
6657 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret;
6658 const MEDFileAnyTypeField1TSWithoutSDA *content(_content);
6661 const MEDFileIntField1TSWithoutSDA *contc=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(content);
6663 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::convertToInt : the content inside this is not INT32 ! This is incoherent !");
6664 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TSWithoutSDA> newc(contc->convertToDouble());
6665 ret=static_cast<MEDFileField1TS *>(MEDFileAnyTypeField1TS::BuildNewInstanceFromContent((MEDFileField1TSWithoutSDA *)newc,getFileName()));
6668 ret=MEDFileField1TS::New();
6670 ret->deepCpyGlobs(*this);
6672 ret->shallowCpyGlobs(*this);
6677 * Adds a MEDCouplingFieldDouble to \a this. The underlying mesh of the given field is
6678 * checked if its elements are sorted suitable for writing to MED file ("STB" stands for
6679 * "Sort By Type"), if not, an exception is thrown.
6680 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6681 * \param [in] field - the field to add to \a this. The field double values are ignored.
6682 * \param [in] arrOfVals - the values of the field \a field used.
6683 * \throw If the name of \a field is empty.
6684 * \throw If the data array of \a field is not set.
6685 * \throw If the data array is already allocated but has different number of components
6687 * \throw If the underlying mesh of \a field has no name.
6688 * \throw If elements in the mesh are not in the order suitable for writing to the MED file.
6690 void MEDFileIntField1TS::setFieldNoProfileSBT(const MEDCouplingFieldDouble *field, const DataArrayInt *arrOfVals)
6693 contentNotNull()->setFieldNoProfileSBT(field,arrOfVals,*this,*contentNotNull());
6697 * Adds a MEDCouplingFieldDouble to \a this. As described in \ref MEDLoaderMainC a field in MED file sense
6698 * can be an aggregation of several MEDCouplingFieldDouble instances.
6699 * The mesh support of input parameter \a field is ignored here, it can be NULL.
6700 * The support of field \a field is expected to be those computed with the input parameter \a mesh, \a meshDimRelToMax,
6703 * This method will check that the field based on the computed support is coherent. If not an exception will be thrown.
6704 * A new profile is added only if no equal profile is missing.
6705 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6706 * \param [in] field - the field to add to \a this. The field double values and mesh support are ignored.
6707 * \param [in] arrOfVals - the values of the field \a field used.
6708 * \param [in] mesh - the supporting mesh of \a field.
6709 * \param [in] meshDimRelToMax - a relative dimension of mesh entities \a field lies on (useless if field spatial discretization is ON_NODES).
6710 * \param [in] profile - ids of mesh entities on which corresponding field values lie.
6711 * \throw If either \a field or \a mesh or \a profile has an empty name.
6712 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
6713 * \throw If the data array of \a field is not set.
6714 * \throw If the data array of \a this is already allocated but has different number of
6715 * components than \a field.
6716 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
6717 * \sa setFieldNoProfileSBT()
6719 void MEDFileIntField1TS::setFieldProfile(const MEDCouplingFieldDouble *field, const DataArrayInt *arrOfVals, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile)
6722 contentNotNull()->setFieldProfile(field,arrOfVals,mesh,meshDimRelToMax,profile,*this,*contentNotNull());
6725 const MEDFileIntField1TSWithoutSDA *MEDFileIntField1TS::contentNotNull() const
6727 const MEDFileAnyTypeField1TSWithoutSDA *pt(_content);
6729 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::contentNotNull : the content pointer is null !");
6730 const MEDFileIntField1TSWithoutSDA *ret=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(pt);
6732 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 !");
6736 MEDCouplingFieldDouble *MEDFileIntField1TS::getFieldAtLevel(TypeOfField type, int meshDimRelToMax, DataArrayInt* &arrOut, int renumPol) const
6738 if(getFileName().empty())
6739 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::getFieldAtLevel : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtLevel method instead !");
6740 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut2;
6741 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtLevel(type,meshDimRelToMax,std::string(),renumPol,this,arrOut2,*contentNotNull());
6742 DataArrayInt *arrOutC=dynamic_cast<DataArrayInt *>((DataArray *)arrOut2);
6744 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::getFieldAtLevelOld : mismatch between dataArrays type and MEDFileIntField1TS ! Expected int32 !");
6749 DataArrayInt *MEDFileIntField1TS::ReturnSafelyDataArrayInt(MEDCouplingAutoRefCountObjectPtr<DataArray>& arr)
6751 if(!((DataArray *)arr))
6752 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::ReturnSafelyDataArrayInt : input DataArray is NULL !");
6753 DataArrayInt *arrC=dynamic_cast<DataArrayInt *>((DataArray *)arr);
6755 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::ReturnSafelyDataArrayInt : input DataArray is not of type INT32 !");
6761 * Returns a new MEDCouplingFieldDouble of a given type lying on
6762 * the top level cells of the first mesh in MED file. If \a this field
6763 * has not been constructed via file reading, an exception is thrown.
6764 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6765 * \param [in] type - a spatial discretization of interest.
6766 * \param [out] arrOut - the DataArrayInt containing values of field.
6767 * \param [in] renumPol - specifies how to permute values of the result field according to
6768 * the optional numbers of cells and nodes, if any. The valid values are
6769 * - 0 - do not permute.
6770 * - 1 - permute cells.
6771 * - 2 - permute nodes.
6772 * - 3 - permute cells and nodes.
6774 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6775 * caller is to delete this field using decrRef() as it is no more needed.
6776 * \throw If \a this field has not been constructed via file reading.
6777 * \throw If the MED file is not readable.
6778 * \throw If there is no mesh in the MED file.
6779 * \throw If no field values of the given \a type.
6780 * \throw If no field values lying on the top level support.
6781 * \sa getFieldAtLevel()
6783 MEDCouplingFieldDouble *MEDFileIntField1TS::getFieldAtTopLevel(TypeOfField type, DataArrayInt* &arrOut, int renumPol) const
6785 if(getFileName().empty())
6786 throw INTERP_KERNEL::Exception("MEDFileField1TS::getFieldAtTopLevel : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtTopLevel method instead !");
6787 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
6788 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtTopLevel(type,std::string(),renumPol,this,arr,*contentNotNull());
6789 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
6794 * Returns a new MEDCouplingFieldDouble of given type lying on a given mesh.
6795 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6796 * \param [in] type - a spatial discretization of the new field.
6797 * \param [in] mesh - the supporting mesh.
6798 * \param [out] arrOut - the DataArrayInt containing values of field.
6799 * \param [in] renumPol - specifies how to permute values of the result field according to
6800 * the optional numbers of cells and nodes, if any. The valid values are
6801 * - 0 - do not permute.
6802 * - 1 - permute cells.
6803 * - 2 - permute nodes.
6804 * - 3 - permute cells and nodes.
6806 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6807 * caller is to delete this field using decrRef() as it is no more needed.
6808 * \throw If no field of \a this is lying on \a mesh.
6809 * \throw If the mesh is empty.
6810 * \throw If no field values of the given \a type are available.
6811 * \sa getFieldAtLevel()
6812 * \sa getFieldOnMeshAtLevel()
6814 MEDCouplingFieldDouble *MEDFileIntField1TS::getFieldOnMeshAtLevel(TypeOfField type, const MEDCouplingMesh *mesh, DataArrayInt* &arrOut, int renumPol) const
6816 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
6817 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldOnMeshAtLevel(type,renumPol,this,mesh,0,0,arr,*contentNotNull());
6818 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
6823 * Returns a new MEDCouplingFieldDouble of a given type lying on a given support.
6824 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6825 * \param [in] type - a spatial discretization of interest.
6826 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6827 * \param [out] arrOut - the DataArrayInt containing values of field.
6828 * \param [in] mesh - the supporting mesh.
6829 * \param [in] renumPol - specifies how to permute values of the result field according to
6830 * the optional numbers of cells and nodes, if any. The valid values are
6831 * - 0 - do not permute.
6832 * - 1 - permute cells.
6833 * - 2 - permute nodes.
6834 * - 3 - permute cells and nodes.
6836 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6837 * caller is to delete this field using decrRef() as it is no more needed.
6838 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
6839 * \throw If no field of \a this is lying on \a mesh.
6840 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6841 * \sa getFieldAtLevel()
6842 * \sa getFieldOnMeshAtLevel()
6844 MEDCouplingFieldDouble *MEDFileIntField1TS::getFieldOnMeshAtLevel(TypeOfField type, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt* &arrOut, int renumPol) const
6846 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
6847 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,this,mesh,arr,*contentNotNull());
6848 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
6853 * Returns a new MEDCouplingFieldDouble of a given type lying on a given support.
6854 * This method is called "Old" because in MED3 norm a field has only one meshName
6855 * attached, so this method is for readers of MED2 files. If \a this field
6856 * has not been constructed via file reading, an exception is thrown.
6857 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6858 * \param [in] type - a spatial discretization of interest.
6859 * \param [in] mName - a name of the supporting mesh.
6860 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6861 * \param [out] arrOut - the DataArrayInt containing values of field.
6862 * \param [in] renumPol - specifies how to permute values of the result field according to
6863 * the optional numbers of cells and nodes, if any. The valid values are
6864 * - 0 - do not permute.
6865 * - 1 - permute cells.
6866 * - 2 - permute nodes.
6867 * - 3 - permute cells and nodes.
6869 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
6870 * caller is to delete this field using decrRef() as it is no more needed.
6871 * \throw If the MED file is not readable.
6872 * \throw If there is no mesh named \a mName in the MED file.
6873 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
6874 * \throw If \a this field has not been constructed via file reading.
6875 * \throw If no field of \a this is lying on the mesh named \a mName.
6876 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6877 * \sa getFieldAtLevel()
6879 MEDCouplingFieldDouble *MEDFileIntField1TS::getFieldAtLevelOld(TypeOfField type, const std::string& mname, int meshDimRelToMax, DataArrayInt* &arrOut, int renumPol) const
6881 if(getFileName().empty())
6882 throw INTERP_KERNEL::Exception("MEDFileField1TS::getFieldAtLevelOld : Request for a method that can be used for instances coming from file loading ! Use getFieldOnMeshAtLevel method instead !");
6883 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
6884 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=contentNotNull()->getFieldAtLevel(type,meshDimRelToMax,mname,renumPol,this,arr,*contentNotNull());
6885 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
6890 * Returns values and a profile of the field of a given type lying on a given support.
6891 * For more info, see \ref AdvMEDLoaderAPIFieldRW
6892 * \param [in] type - a spatial discretization of the field.
6893 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
6894 * \param [in] mesh - the supporting mesh.
6895 * \param [out] pfl - a new instance of DataArrayInt holding ids of mesh entities the
6896 * field of interest lies on. If the field lies on all entities of the given
6897 * dimension, all ids in \a pfl are zero. The caller is to delete this array
6898 * using decrRef() as it is no more needed.
6899 * \return DataArrayInt * - a new instance of DataArrayInt holding values of the
6900 * field. The caller is to delete this array using decrRef() as it is no more needed.
6901 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
6902 * \throw If no field of \a this is lying on \a mesh.
6903 * \throw If no field values of the given \a type or given \a meshDimRelToMax are available.
6905 DataArrayInt *MEDFileIntField1TS::getFieldWithProfile(TypeOfField type, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt *&pfl) const
6907 MEDCouplingAutoRefCountObjectPtr<DataArray> arr=contentNotNull()->getFieldWithProfile(type,meshDimRelToMax,mesh,pfl,this,*contentNotNull());
6908 return MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
6911 MEDFileIntField1TSWithoutSDA *MEDFileIntField1TS::contentNotNull()
6913 MEDFileAnyTypeField1TSWithoutSDA *pt(_content);
6915 throw INTERP_KERNEL::Exception("MEDFileIntField1TS::contentNotNull : the non const content pointer is null !");
6916 MEDFileIntField1TSWithoutSDA *ret=dynamic_cast<MEDFileIntField1TSWithoutSDA *>(pt);
6918 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 !");
6922 DataArrayInt *MEDFileIntField1TS::getUndergroundDataArray() const
6924 return contentNotNull()->getUndergroundDataArrayInt();
6927 //= MEDFileAnyTypeFieldMultiTSWithoutSDA
6929 MEDFileAnyTypeFieldMultiTSWithoutSDA::MEDFileAnyTypeFieldMultiTSWithoutSDA()
6933 MEDFileAnyTypeFieldMultiTSWithoutSDA::MEDFileAnyTypeFieldMultiTSWithoutSDA(const std::string& fieldName):MEDFileFieldNameScope(fieldName)
6938 * \param [in] fieldId field id in C mode
6940 MEDFileAnyTypeFieldMultiTSWithoutSDA::MEDFileAnyTypeFieldMultiTSWithoutSDA(med_idt fid, int fieldId, bool loadAll, const MEDFileMeshes *ms)
6942 med_field_type typcha;
6943 std::string dtunitOut;
6944 int nbOfStep=MEDFileAnyTypeField1TS::LocateField2(fid,"",fieldId,false,_name,typcha,_infos,dtunitOut);
6945 setDtUnit(dtunitOut.c_str());
6946 loadStructureOrStructureAndBigArraysRecursively(fid,nbOfStep,typcha,loadAll,ms);
6949 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, const MEDFileMeshes *ms)
6950 try:MEDFileFieldNameScope(fieldName),_infos(infos)
6952 setDtUnit(dtunit.c_str());
6953 loadStructureOrStructureAndBigArraysRecursively(fid,nbOfStep,fieldTyp,loadAll,ms);
6955 catch(INTERP_KERNEL::Exception& e)
6960 std::size_t MEDFileAnyTypeFieldMultiTSWithoutSDA::getHeapMemorySizeWithoutChildren() const
6962 std::size_t ret(_name.capacity()+_infos.capacity()*sizeof(std::string)+_time_steps.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr<MEDFileField1TSWithoutSDA>));
6963 for(std::vector<std::string>::const_iterator it=_infos.begin();it!=_infos.end();it++)
6964 ret+=(*it).capacity();
6968 std::vector<const BigMemoryObject *> MEDFileAnyTypeFieldMultiTSWithoutSDA::getDirectChildrenWithNull() const
6970 std::vector<const BigMemoryObject *> ret;
6971 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
6972 ret.push_back((const MEDFileAnyTypeField1TSWithoutSDA *)*it);
6977 * 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
6980 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::buildFromTimeStepIds(const int *startIds, const int *endIds) const
6982 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> ret=createNew();
6983 ret->setInfo(_infos);
6984 int sz=(int)_time_steps.size();
6985 for(const int *id=startIds;id!=endIds;id++)
6987 if(*id>=0 && *id<sz)
6989 const MEDFileAnyTypeField1TSWithoutSDA *tse=_time_steps[*id];
6990 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> tse2;
6994 tse2=(const_cast<MEDFileAnyTypeField1TSWithoutSDA *>(tse));
6996 ret->pushBackTimeStep(tse2);
7000 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::buildFromTimeStepIds : At pos #" << std::distance(startIds,id) << " value is " << *id;
7001 oss << " ! Should be in [0," << sz << ") !";
7002 throw INTERP_KERNEL::Exception(oss.str().c_str());
7005 if(ret->getNumberOfTS()>0)
7006 ret->synchronizeNameScope();
7007 ret->copyNameScope(*this);
7012 * 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
7015 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::buildFromTimeStepIds2(int bg, int end, int step) const
7017 static const char msg[]="MEDFileAnyTypeFieldMultiTSWithoutSDA::buildFromTimeStepIds2";
7018 int nbOfEntriesToKeep=DataArrayInt::GetNumberOfItemGivenBESRelative(bg,end,step,msg);
7019 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> ret=createNew();
7020 ret->setInfo(_infos);
7021 int sz=(int)_time_steps.size();
7023 for(int i=0;i<nbOfEntriesToKeep;i++,j+=step)
7027 const MEDFileAnyTypeField1TSWithoutSDA *tse=_time_steps[j];
7028 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> tse2;
7032 tse2=(const_cast<MEDFileAnyTypeField1TSWithoutSDA *>(tse));
7034 ret->pushBackTimeStep(tse2);
7038 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::buildFromTimeStepIds : At pos #" << i << " value is " << j;
7039 oss << " ! Should be in [0," << sz << ") !";
7040 throw INTERP_KERNEL::Exception(oss.str().c_str());
7043 if(ret->getNumberOfTS()>0)
7044 ret->synchronizeNameScope();
7045 ret->copyNameScope(*this);
7049 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::partOfThisLyingOnSpecifiedTimeSteps(const std::vector< std::pair<int,int> >& timeSteps) const
7052 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ids=DataArrayInt::New(); ids->alloc(0,1);
7053 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,id++)
7055 const MEDFileAnyTypeField1TSWithoutSDA *cur(*it);
7058 std::pair<int,int> p(cur->getIteration(),cur->getOrder());
7059 if(std::find(timeSteps.begin(),timeSteps.end(),p)!=timeSteps.end())
7060 ids->pushBackSilent(id);
7062 return buildFromTimeStepIds(ids->begin(),ids->end());
7065 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::partOfThisNotLyingOnSpecifiedTimeSteps(const std::vector< std::pair<int,int> >& timeSteps) const
7068 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ids=DataArrayInt::New(); ids->alloc(0,1);
7069 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,id++)
7071 const MEDFileAnyTypeField1TSWithoutSDA *cur(*it);
7074 std::pair<int,int> p(cur->getIteration(),cur->getOrder());
7075 if(std::find(timeSteps.begin(),timeSteps.end(),p)==timeSteps.end())
7076 ids->pushBackSilent(id);
7078 return buildFromTimeStepIds(ids->begin(),ids->end());
7081 bool MEDFileAnyTypeFieldMultiTSWithoutSDA::presenceOfMultiDiscPerGeoType() const
7083 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7085 const MEDFileAnyTypeField1TSWithoutSDA *cur(*it);
7088 if(cur->presenceOfMultiDiscPerGeoType())
7094 const std::vector<std::string>& MEDFileAnyTypeFieldMultiTSWithoutSDA::getInfo() const
7099 void MEDFileAnyTypeFieldMultiTSWithoutSDA::setInfo(const std::vector<std::string>& info)
7104 int MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepPos(int iteration, int order) const
7107 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,ret++)
7109 const MEDFileAnyTypeField1TSWithoutSDA *pt(*it);
7110 if(pt->isDealingTS(iteration,order))
7113 std::ostringstream oss; oss << "MEDFileFieldMultiTS::getTimeStepPos : Muli timestep field on time (" << iteration << "," << order << ") does not exist ! Available (iteration,order) are :\n";
7114 std::vector< std::pair<int,int> > vp=getIterations();
7115 for(std::vector< std::pair<int,int> >::const_iterator it2=vp.begin();it2!=vp.end();it2++)
7116 oss << "(" << (*it2).first << "," << (*it2).second << ") ";
7117 throw INTERP_KERNEL::Exception(oss.str().c_str());
7120 const MEDFileAnyTypeField1TSWithoutSDA& MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepEntry(int iteration, int order) const
7122 return *_time_steps[getTimeStepPos(iteration,order)];
7125 MEDFileAnyTypeField1TSWithoutSDA& MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepEntry(int iteration, int order)
7127 return *_time_steps[getTimeStepPos(iteration,order)];
7130 std::string MEDFileAnyTypeFieldMultiTSWithoutSDA::getMeshName() const
7132 if(_time_steps.empty())
7133 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::getMeshName : not time steps !");
7134 return _time_steps[0]->getMeshName();
7137 void MEDFileAnyTypeFieldMultiTSWithoutSDA::setMeshName(const std::string& newMeshName)
7139 std::string oldName(getMeshName());
7140 std::vector< std::pair<std::string,std::string> > v(1);
7141 v[0].first=oldName; v[0].second=newMeshName;
7145 bool MEDFileAnyTypeFieldMultiTSWithoutSDA::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
7148 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7150 MEDFileAnyTypeField1TSWithoutSDA *cur(*it);
7152 ret=cur->changeMeshNames(modifTab) || ret;
7158 * See doc at MEDFileField1TSWithoutSDA::getUndergroundDataArray
7160 DataArray *MEDFileAnyTypeFieldMultiTSWithoutSDA::getUndergroundDataArray(int iteration, int order) const
7162 return getTimeStepEntry(iteration,order).getUndergroundDataArray();
7166 * See doc at MEDFileField1TSWithoutSDA::getUndergroundDataArrayExt
7168 DataArray *MEDFileAnyTypeFieldMultiTSWithoutSDA::getUndergroundDataArrayExt(int iteration, int order, std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
7170 return getTimeStepEntry(iteration,order).getUndergroundDataArrayExt(entries);
7173 bool MEDFileAnyTypeFieldMultiTSWithoutSDA::renumberEntitiesLyingOnMesh(const std::string& meshName, const std::vector<int>& oldCode, const std::vector<int>& newCode, const DataArrayInt *renumO2N,
7174 MEDFileFieldGlobsReal& glob)
7177 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7179 MEDFileAnyTypeField1TSWithoutSDA *f1ts(*it);
7181 ret=f1ts->renumberEntitiesLyingOnMesh(meshName,oldCode,newCode,renumO2N,glob) || ret;
7186 void MEDFileAnyTypeFieldMultiTSWithoutSDA::simpleRepr(int bkOffset, std::ostream& oss, int fmtsId) const
7188 std::string startLine(bkOffset,' ');
7189 oss << startLine << "Field multi time steps [Type=" << getTypeStr() << "]";
7191 oss << " (" << fmtsId << ")";
7192 oss << " has the following name: \"" << _name << "\"." << std::endl;
7193 oss << startLine << "Field multi time steps has " << _infos.size() << " components with the following infos :" << std::endl;
7194 for(std::vector<std::string>::const_iterator it=_infos.begin();it!=_infos.end();it++)
7196 oss << startLine << " - \"" << *it << "\"" << std::endl;
7199 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,i++)
7201 std::string chapter(17,'0'+i);
7202 oss << startLine << chapter << std::endl;
7203 const MEDFileAnyTypeField1TSWithoutSDA *cur=(*it);
7205 cur->simpleRepr(bkOffset+2,oss,i);
7207 oss << startLine << " Field on one time step #" << i << " is not defined !" << std::endl;
7208 oss << startLine << chapter << std::endl;
7212 std::vector< std::pair<int,int> > MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeSteps(std::vector<double>& ret1) const
7214 std::size_t sz=_time_steps.size();
7215 std::vector< std::pair<int,int> > ret(sz);
7217 for(std::size_t i=0;i<sz;i++)
7219 const MEDFileAnyTypeField1TSWithoutSDA *f1ts=_time_steps[i];
7222 ret1[i]=f1ts->getTime(ret[i].first,ret[i].second);
7226 std::ostringstream oss; oss << "MEDFileFieldMultiTSWithoutSDA::getTimeSteps : At rank #" << i << " time step is not defined. Invoke eraseEmptyTS method !";
7227 throw INTERP_KERNEL::Exception(oss.str().c_str());
7233 void MEDFileAnyTypeFieldMultiTSWithoutSDA::pushBackTimeStep(MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA>& tse)
7235 MEDFileAnyTypeField1TSWithoutSDA *tse2(tse);
7237 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::pushBackTimeStep : input content object is null !");
7238 checkCoherencyOfType(tse2);
7239 if(_time_steps.empty())
7241 setName(tse2->getName().c_str());
7242 setInfo(tse2->getInfo());
7244 checkThatComponentsMatch(tse2->getInfo());
7245 _time_steps.push_back(tse);
7248 void MEDFileAnyTypeFieldMultiTSWithoutSDA::synchronizeNameScope()
7250 std::size_t nbOfCompo=_infos.size();
7251 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7253 MEDFileAnyTypeField1TSWithoutSDA *cur=(*it);
7256 if((cur->getInfo()).size()!=nbOfCompo)
7258 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::synchronizeNameScope : Mismatch in the number of components of parts ! Should be " << nbOfCompo;
7259 oss << " ! but the field at iteration=" << cur->getIteration() << " order=" << cur->getOrder() << " has " << (cur->getInfo()).size() << " components !";
7260 throw INTERP_KERNEL::Exception(oss.str().c_str());
7262 cur->copyNameScope(*this);
7267 void MEDFileAnyTypeFieldMultiTSWithoutSDA::loadStructureOrStructureAndBigArraysRecursively(med_idt fid, int nbPdt, med_field_type fieldTyp, bool loadAll, const MEDFileMeshes *ms)
7269 _time_steps.resize(nbPdt);
7270 for(int i=0;i<nbPdt;i++)
7272 std::vector< std::pair<int,int> > ts;
7273 med_int numdt=0,numo=0;
7274 med_int meshIt=0,meshOrder=0;
7276 MEDfieldComputingStepMeshInfo(fid,_name.c_str(),i+1,&numdt,&numo,&dt,&meshIt,&meshOrder);
7281 _time_steps[i]=MEDFileField1TSWithoutSDA::New(_name.c_str(),i+1,numdt,numo,_infos);
7286 _time_steps[i]=MEDFileIntField1TSWithoutSDA::New(_name.c_str(),i+1,numdt,numo,_infos);
7290 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::loadStructureOrStructureAndBigArraysRecursively : managed field type are : FLOAT64, INT32 !");
7293 _time_steps[i]->loadStructureAndBigArraysRecursively(fid,*this,ms);
7295 _time_steps[i]->loadOnlyStructureOfDataRecursively(fid,*this,ms);
7299 void MEDFileAnyTypeFieldMultiTSWithoutSDA::writeLL(med_idt fid, const MEDFileWritable& opts) const
7301 if(_time_steps.empty())
7302 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::writeLL : no time steps set !");
7303 checkThatNbOfCompoOfTSMatchThis();
7304 std::vector<std::string> infos(getInfo());
7305 int nbComp=infos.size();
7306 INTERP_KERNEL::AutoPtr<char> comp=MEDLoaderBase::buildEmptyString(nbComp*MED_SNAME_SIZE);
7307 INTERP_KERNEL::AutoPtr<char> unit=MEDLoaderBase::buildEmptyString(nbComp*MED_SNAME_SIZE);
7308 for(int i=0;i<nbComp;i++)
7310 std::string info=infos[i];
7312 MEDLoaderBase::splitIntoNameAndUnit(info,c,u);
7313 MEDLoaderBase::safeStrCpy2(c.c_str(),MED_SNAME_SIZE,comp+i*MED_SNAME_SIZE,opts.getTooLongStrPolicy());
7314 MEDLoaderBase::safeStrCpy2(u.c_str(),MED_SNAME_SIZE,unit+i*MED_SNAME_SIZE,opts.getTooLongStrPolicy());
7317 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::write : MED file does not accept field with empty name !");
7318 MEDfieldCr(fid,_name.c_str(),getMEDFileFieldType(),nbComp,comp,unit,getDtUnit().c_str(),getMeshName().c_str());
7319 int nbOfTS=_time_steps.size();
7320 for(int i=0;i<nbOfTS;i++)
7321 _time_steps[i]->writeLL(fid,opts,*this);
7324 void MEDFileAnyTypeFieldMultiTSWithoutSDA::loadBigArraysRecursively(med_idt fid, const MEDFileFieldNameScope& nasc)
7326 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7328 MEDFileAnyTypeField1TSWithoutSDA *elt(*it);
7330 elt->loadBigArraysRecursively(fid,nasc);
7334 void MEDFileAnyTypeFieldMultiTSWithoutSDA::loadBigArraysRecursivelyIfNecessary(med_idt fid, const MEDFileFieldNameScope& nasc)
7336 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7338 MEDFileAnyTypeField1TSWithoutSDA *elt(*it);
7340 elt->loadBigArraysRecursivelyIfNecessary(fid,nasc);
7344 void MEDFileAnyTypeFieldMultiTSWithoutSDA::unloadArrays()
7346 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7348 MEDFileAnyTypeField1TSWithoutSDA *elt(*it);
7350 elt->unloadArrays();
7354 int MEDFileAnyTypeFieldMultiTSWithoutSDA::getNumberOfTS() const
7356 return _time_steps.size();
7359 void MEDFileAnyTypeFieldMultiTSWithoutSDA::eraseEmptyTS()
7361 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > newTS;
7362 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7364 const MEDFileAnyTypeField1TSWithoutSDA *tmp=(*it);
7366 newTS.push_back(*it);
7371 void MEDFileAnyTypeFieldMultiTSWithoutSDA::eraseTimeStepIds(const int *startIds, const int *endIds)
7373 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > newTS;
7374 int maxId=(int)_time_steps.size();
7376 std::set<int> idsToDel;
7377 for(const int *id=startIds;id!=endIds;id++,ii++)
7379 if(*id>=0 && *id<maxId)
7381 idsToDel.insert(*id);
7385 std::ostringstream oss; oss << "MEDFileFieldMultiTSWithoutSDA::eraseTimeStepIds : At pos #" << ii << " request for id=" << *id << " not in [0," << maxId << ") !";
7386 throw INTERP_KERNEL::Exception(oss.str().c_str());
7389 for(int iii=0;iii<maxId;iii++)
7390 if(idsToDel.find(iii)==idsToDel.end())
7391 newTS.push_back(_time_steps[iii]);
7395 void MEDFileAnyTypeFieldMultiTSWithoutSDA::eraseTimeStepIds2(int bg, int end, int step)
7397 static const char msg[]="MEDFileAnyTypeFieldMultiTSWithoutSDA::eraseTimeStepIds2";
7398 int nbOfEntriesToKill=DataArrayInt::GetNumberOfItemGivenBESRelative(bg,end,step,msg);
7399 if(nbOfEntriesToKill==0)
7401 std::size_t sz=_time_steps.size();
7402 std::vector<bool> b(sz,true);
7404 for(int i=0;i<nbOfEntriesToKill;i++,j+=step)
7406 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > newTS;
7407 for(std::size_t i=0;i<sz;i++)
7409 newTS.push_back(_time_steps[i]);
7413 int MEDFileAnyTypeFieldMultiTSWithoutSDA::getPosOfTimeStep(int iteration, int order) const
7416 std::ostringstream oss; oss << "MEDFileFieldMultiTSWithoutSDA::getPosOfTimeStep : No such time step (" << iteration << "," << order << ") !\nPossibilities are : ";
7417 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,ret++)
7419 const MEDFileAnyTypeField1TSWithoutSDA *tmp(*it);
7423 tmp->getTime(it2,ord);
7424 if(it2==iteration && order==ord)
7427 oss << "(" << it2 << "," << ord << "), ";
7430 throw INTERP_KERNEL::Exception(oss.str().c_str());
7433 int MEDFileAnyTypeFieldMultiTSWithoutSDA::getPosGivenTime(double time, double eps) const
7436 std::ostringstream oss; oss << "MEDFileFieldMultiTSWithoutSDA::getPosGivenTime : No such time step " << time << "! \nPossibilities are : ";
7438 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,ret++)
7440 const MEDFileAnyTypeField1TSWithoutSDA *tmp(*it);
7444 double ti=tmp->getTime(it2,ord);
7445 if(fabs(time-ti)<eps)
7451 throw INTERP_KERNEL::Exception(oss.str().c_str());
7454 std::vector< std::pair<int,int> > MEDFileAnyTypeFieldMultiTSWithoutSDA::getIterations() const
7456 int lgth=_time_steps.size();
7457 std::vector< std::pair<int,int> > ret(lgth);
7458 for(int i=0;i<lgth;i++)
7459 _time_steps[i]->fillIteration(ret[i]);
7464 * 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'
7465 * This method returns two things.
7466 * - The absolute dimension of 'this' in first parameter.
7467 * - The available ext levels relative to the absolute dimension returned in first parameter. These relative levels are relative
7468 * to the first output parameter. The values in 'levs' will be returned in decreasing order.
7470 * This method is designed for MEDFileFieldMultiTS instances that have a discritization ON_CELLS, ON_GAUSS_NE and ON_GAUSS.
7471 * Only these 3 discretizations will be taken into account here.
7473 * If 'this' is empty this method will throw an INTERP_KERNEL::Exception.
7474 * If there is \b only node fields defined in 'this' -1 is returned and 'levs' output parameter will be empty. In this
7475 * case the caller has to know the underlying mesh it refers to. By defaut it is the level 0 of the corresponding mesh.
7477 * This method is usefull to make the link between meshDimension of the underlying mesh in 'this' and the levels on 'this'.
7478 * 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'.
7480 * Let's consider the typical following case :
7481 * - a mesh 'm1' has a meshDimension 3 and has the following non empty levels
7482 * [0,-1,-2] for example 'm1' lies on TETRA4, HEXA8 TRI3 and SEG2
7483 * - 'f1' lies on 'm1' and is defined on 3D and 1D cells for example
7485 * - 'f2' lies on 'm1' too and is defined on 2D and 1D cells for example TRI3 and SEG2
7487 * In this case f1->getNonEmptyLevelsExt will return (3,[0,-2]) and f2->getNonEmptyLevelsExt will return (2,[0,-1])
7489 * To retrieve the highest level of f1 it should be done, f1->getFieldAtLevel(ON_CELLS,3-3+0);//absDim-meshDim+relativeLev
7490 * To retrieve the lowest level of f1 it should be done, f1->getFieldAtLevel(ON_CELLS,3-3+(-2));//absDim-meshDim+relativeLev
7491 * To retrieve the highest level of f2 it should be done, f1->getFieldAtLevel(ON_CELLS,2-3+0);//absDim-meshDim+relativeLev
7492 * To retrieve the lowest level of f2 it should be done, f1->getFieldAtLevel(ON_CELLS,2-3+(-1));//absDim-meshDim+relativeLev
7494 int MEDFileAnyTypeFieldMultiTSWithoutSDA::getNonEmptyLevels(int iteration, int order, const std::string& mname, std::vector<int>& levs) const
7496 return getTimeStepEntry(iteration,order).getNonEmptyLevels(mname,levs);
7499 const MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2(int pos) const
7501 if(pos<0 || pos>=(int)_time_steps.size())
7503 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2 : request for pos #" << pos << " whereas should be in [0," << _time_steps.size() << ") !";
7504 throw INTERP_KERNEL::Exception(oss.str().c_str());
7506 const MEDFileAnyTypeField1TSWithoutSDA *item=_time_steps[pos];
7509 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2 : request for pos #" << pos << ", this pos id exists but the underlying Field1TS is null !";
7510 oss << "\nTry to use following method eraseEmptyTS !";
7511 throw INTERP_KERNEL::Exception(oss.str().c_str());
7516 MEDFileAnyTypeField1TSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2(int pos)
7518 if(pos<0 || pos>=(int)_time_steps.size())
7520 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2 : request for pos #" << pos << " whereas should be in [0," << _time_steps.size() << ") !";
7521 throw INTERP_KERNEL::Exception(oss.str().c_str());
7523 MEDFileAnyTypeField1TSWithoutSDA *item=_time_steps[pos];
7526 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::getTimeStepAtPos2 : request for pos #" << pos << ", this pos id exists but the underlying Field1TS is null !";
7527 oss << "\nTry to use following method eraseEmptyTS !";
7528 throw INTERP_KERNEL::Exception(oss.str().c_str());
7533 std::vector<std::string> MEDFileAnyTypeFieldMultiTSWithoutSDA::getPflsReallyUsed2() const
7535 std::vector<std::string> ret;
7536 std::set<std::string> ret2;
7537 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7539 std::vector<std::string> tmp=(*it)->getPflsReallyUsed2();
7540 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
7541 if(ret2.find(*it2)==ret2.end())
7543 ret.push_back(*it2);
7550 std::vector<std::string> MEDFileAnyTypeFieldMultiTSWithoutSDA::getLocsReallyUsed2() const
7552 std::vector<std::string> ret;
7553 std::set<std::string> ret2;
7554 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7556 std::vector<std::string> tmp=(*it)->getLocsReallyUsed2();
7557 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
7558 if(ret2.find(*it2)==ret2.end())
7560 ret.push_back(*it2);
7567 std::vector<std::string> MEDFileAnyTypeFieldMultiTSWithoutSDA::getPflsReallyUsedMulti2() const
7569 std::vector<std::string> ret;
7570 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7572 std::vector<std::string> tmp=(*it)->getPflsReallyUsedMulti2();
7573 ret.insert(ret.end(),tmp.begin(),tmp.end());
7578 std::vector<std::string> MEDFileAnyTypeFieldMultiTSWithoutSDA::getLocsReallyUsedMulti2() const
7580 std::vector<std::string> ret;
7581 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7583 std::vector<std::string> tmp=(*it)->getLocsReallyUsedMulti2();
7584 ret.insert(ret.end(),tmp.begin(),tmp.end());
7589 void MEDFileAnyTypeFieldMultiTSWithoutSDA::changePflsRefsNamesGen2(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
7591 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7592 (*it)->changePflsRefsNamesGen2(mapOfModif);
7595 void MEDFileAnyTypeFieldMultiTSWithoutSDA::changeLocsRefsNamesGen2(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
7597 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeField1TSWithoutSDA > >::iterator it=_time_steps.begin();it!=_time_steps.end();it++)
7598 (*it)->changeLocsRefsNamesGen2(mapOfModif);
7601 std::vector< std::vector<TypeOfField> > MEDFileAnyTypeFieldMultiTSWithoutSDA::getTypesOfFieldAvailable() const
7603 int lgth=_time_steps.size();
7604 std::vector< std::vector<TypeOfField> > ret(lgth);
7605 for(int i=0;i<lgth;i++)
7606 _time_steps[i]->fillTypesOfFieldAvailable(ret[i]);
7611 * entry point for users that want to iterate into MEDFile DataStructure without any overhead.
7613 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
7615 return getTimeStepEntry(iteration,order).getFieldSplitedByType(mname,types,typesF,pfls,locs);
7618 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTSWithoutSDA::deepCpy() const
7620 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> ret=shallowCpy();
7622 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,i++)
7624 if((const MEDFileAnyTypeField1TSWithoutSDA *)*it)
7625 ret->_time_steps[i]=(*it)->deepCpy();
7630 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > MEDFileAnyTypeFieldMultiTSWithoutSDA::splitComponents() const
7632 std::size_t sz(_infos.size()),sz2(_time_steps.size());
7633 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > ret(sz);
7634 std::vector< std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > > ts(sz2);
7635 for(std::size_t i=0;i<sz;i++)
7637 ret[i]=shallowCpy();
7638 ret[i]->_infos.resize(1); ret[i]->_infos[0]=_infos[i];
7640 for(std::size_t i=0;i<sz2;i++)
7642 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > ret1=_time_steps[i]->splitComponents();
7645 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::splitComponents : At rank #" << i << " number of components is " << ret1.size() << " whereas it should be for all time steps " << sz << " !";
7646 throw INTERP_KERNEL::Exception(oss.str().c_str());
7650 for(std::size_t i=0;i<sz;i++)
7651 for(std::size_t j=0;j<sz2;j++)
7652 ret[i]->_time_steps[j]=ts[j][i];
7657 * This method splits into discretization each time steps in \a this.
7658 * ** WARNING ** the returned instances are not compulsary defined on the same time steps series !
7660 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > MEDFileAnyTypeFieldMultiTSWithoutSDA::splitDiscretizations() const
7662 std::size_t sz(_time_steps.size());
7663 std::vector< std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > > items(sz);
7664 for(std::size_t i=0;i<sz;i++)
7666 const MEDFileAnyTypeField1TSWithoutSDA *timeStep(_time_steps[i]);
7669 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::splitDiscretizations : time step #" << i << " is null !";
7670 throw INTERP_KERNEL::Exception(oss.str().c_str());
7672 items[i]=timeStep->splitDiscretizations();
7675 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > ret;
7676 std::vector< std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > > ret2;
7677 std::vector< TypeOfField > types;
7678 for(std::vector< std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > >::const_iterator it0=items.begin();it0!=items.end();it0++)
7679 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it1=(*it0).begin();it1!=(*it0).end();it1++)
7681 std::vector<TypeOfField> ts=(*it1)->getTypesOfFieldAvailable();
7683 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::splitDiscretizations : it appears that the splitting of MEDFileAnyTypeField1TSWithoutSDA::splitDiscretizations has returned invalid result !");
7684 std::vector< TypeOfField >::iterator it2=std::find(types.begin(),types.end(),ts[0]);
7685 if(it2==types.end())
7686 types.push_back(ts[0]);
7688 ret.resize(types.size()); ret2.resize(types.size());
7689 for(std::vector< std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > >::const_iterator it0=items.begin();it0!=items.end();it0++)
7690 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it1=(*it0).begin();it1!=(*it0).end();it1++)
7692 TypeOfField typ=(*it1)->getTypesOfFieldAvailable()[0];
7693 std::size_t pos=std::distance(types.begin(),std::find(types.begin(),types.end(),typ));
7694 ret2[pos].push_back(*it1);
7696 for(std::size_t i=0;i<types.size();i++)
7698 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> elt(createNew());
7699 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::iterator it1=ret2[i].begin();it1!=ret2[i].end();it1++)
7700 elt->pushBackTimeStep(*it1);//also updates infos in elt
7702 elt->MEDFileFieldNameScope::operator=(*this);
7708 * Contrary to splitDiscretizations method this method makes the hypothesis that the times series are **NOT** impacted by the splitting of multi discretization.
7710 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > MEDFileAnyTypeFieldMultiTSWithoutSDA::splitMultiDiscrPerGeoTypes() const
7712 std::size_t sz(_time_steps.size());
7713 std::vector< std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> > > items(sz);
7714 std::size_t szOut(std::numeric_limits<std::size_t>::max());
7715 for(std::size_t i=0;i<sz;i++)
7717 const MEDFileAnyTypeField1TSWithoutSDA *timeStep(_time_steps[i]);
7720 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::splitMultiDiscrPerGeoTypes : time step #" << i << " is null !";
7721 throw INTERP_KERNEL::Exception(oss.str().c_str());
7723 items[i]=timeStep->splitMultiDiscrPerGeoTypes();
7724 if(szOut==std::numeric_limits<std::size_t>::max())
7725 szOut=items[i].size();
7727 if(items[i].size()!=szOut)
7728 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::splitMultiDiscrPerGeoTypes : The splitting per discretization is expected to be same among time steps !");
7730 if(szOut==std::numeric_limits<std::size_t>::max())
7731 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::splitMultiDiscrPerGeoTypes : empty field !");
7732 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > ret(szOut);
7733 for(std::size_t i=0;i<szOut;i++)
7735 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> elt(createNew());
7736 for(std::size_t j=0;j<sz;j++)
7737 elt->pushBackTimeStep(items[j][i]);
7739 elt->MEDFileFieldNameScope::operator=(*this);
7744 void MEDFileAnyTypeFieldMultiTSWithoutSDA::copyTinyInfoFrom(const MEDCouplingFieldDouble *field, const DataArray *arr)
7746 _name=field->getName();
7748 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::copyTinyInfoFrom : unsupported fields with no name in MED file !");
7750 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::copyTinyInfoFrom : no array set !");
7751 _infos=arr->getInfoOnComponents();
7754 void MEDFileAnyTypeFieldMultiTSWithoutSDA::checkCoherencyOfTinyInfo(const MEDCouplingFieldDouble *field, const DataArray *arr) const
7756 static const char MSG[]="MEDFileFieldMultiTSWithoutSDA::checkCoherencyOfTinyInfo : invalid ";
7757 if(_name!=field->getName())
7759 std::ostringstream oss; oss << MSG << "name ! should be \"" << _name;
7760 oss << "\" and it is set in input field to \"" << field->getName() << "\" !";
7761 throw INTERP_KERNEL::Exception(oss.str().c_str());
7764 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::checkCoherencyOfTinyInfo : no array set !");
7765 checkThatComponentsMatch(arr->getInfoOnComponents());
7768 void MEDFileAnyTypeFieldMultiTSWithoutSDA::checkThatComponentsMatch(const std::vector<std::string>& compos) const
7770 static const char MSG[]="MEDFileFieldMultiTSWithoutSDA::checkThatComponentsMatch : ";
7771 if(getInfo().size()!=compos.size())
7773 std::ostringstream oss; oss << MSG << "mismatch of number of components between this (" << getInfo().size() << ") and ";
7774 oss << " number of components of element to append (" << compos.size() << ") !";
7775 throw INTERP_KERNEL::Exception(oss.str().c_str());
7779 std::ostringstream oss; oss << MSG << "components have same size but are different ! should be \"";
7780 std::copy(_infos.begin(),_infos.end(),std::ostream_iterator<std::string>(oss,", "));
7781 oss << " But compo in input fields are : ";
7782 std::copy(compos.begin(),compos.end(),std::ostream_iterator<std::string>(oss,", "));
7784 throw INTERP_KERNEL::Exception(oss.str().c_str());
7788 void MEDFileAnyTypeFieldMultiTSWithoutSDA::checkThatNbOfCompoOfTSMatchThis() const
7790 std::size_t sz=_infos.size();
7792 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,j++)
7794 const MEDFileAnyTypeField1TSWithoutSDA *elt(*it);
7796 if(elt->getInfo().size()!=sz)
7798 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::checkThatNbOfCompoOfTSMatchThis : At pos #" << j << " the number of components is equal to ";
7799 oss << elt->getInfo().size() << " whereas it is expected to be equal to " << sz << " !";
7800 throw INTERP_KERNEL::Exception(oss.str().c_str());
7805 void MEDFileAnyTypeFieldMultiTSWithoutSDA::appendFieldNoProfileSBT(const MEDCouplingFieldDouble *field, const DataArray *arr, MEDFileFieldGlobsReal& glob)
7808 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::appendFieldNoProfileSBT : input field is NULL !");
7809 if(!_time_steps.empty())
7810 checkCoherencyOfTinyInfo(field,arr);
7811 MEDFileAnyTypeField1TSWithoutSDA *objC=createNew1TSWithoutSDAEmptyInstance();
7812 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> obj(objC);
7813 objC->setFieldNoProfileSBT(field,arr,glob,*this);
7814 copyTinyInfoFrom(field,arr);
7815 _time_steps.push_back(obj);
7818 void MEDFileAnyTypeFieldMultiTSWithoutSDA::appendFieldProfile(const MEDCouplingFieldDouble *field, const DataArray *arr, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile, MEDFileFieldGlobsReal& glob)
7821 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTSWithoutSDA::appendFieldNoProfileSBT : input field is NULL !");
7822 if(!_time_steps.empty())
7823 checkCoherencyOfTinyInfo(field,arr);
7824 MEDFileField1TSWithoutSDA *objC=new MEDFileField1TSWithoutSDA;
7825 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> obj(objC);
7826 objC->setFieldProfile(field,arr,mesh,meshDimRelToMax,profile,glob,*this);
7827 copyTinyInfoFrom(field,arr);
7828 _time_steps.push_back(obj);
7831 void MEDFileAnyTypeFieldMultiTSWithoutSDA::setIteration(int i, MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> ts)
7833 int sz=(int)_time_steps.size();
7836 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::setIteration : trying to set element at place #" << i << " should be in [0," << sz << ") !";
7837 throw INTERP_KERNEL::Exception(oss.str().c_str());
7839 const MEDFileAnyTypeField1TSWithoutSDA *tsPtr(ts);
7842 if(tsPtr->getNumberOfComponents()!=(int)_infos.size())
7844 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTSWithoutSDA::setIteration : trying to set element with " << tsPtr->getNumberOfComponents() << " components ! Should be " << _infos.size() << " !";
7845 throw INTERP_KERNEL::Exception(oss.str().c_str());
7851 //= MEDFileFieldMultiTSWithoutSDA
7853 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, const MEDFileMeshes *ms)
7855 return new MEDFileFieldMultiTSWithoutSDA(fid,fieldName,fieldTyp,infos,nbOfStep,dtunit,loadAll,ms);
7858 MEDFileFieldMultiTSWithoutSDA::MEDFileFieldMultiTSWithoutSDA()
7862 MEDFileFieldMultiTSWithoutSDA::MEDFileFieldMultiTSWithoutSDA(const std::string& fieldName):MEDFileAnyTypeFieldMultiTSWithoutSDA(fieldName)
7867 * \param [in] fieldId field id in C mode
7869 MEDFileFieldMultiTSWithoutSDA::MEDFileFieldMultiTSWithoutSDA(med_idt fid, int fieldId, bool loadAll, const MEDFileMeshes *ms)
7870 try:MEDFileAnyTypeFieldMultiTSWithoutSDA(fid,fieldId,loadAll,ms)
7873 catch(INTERP_KERNEL::Exception& e)
7876 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, const MEDFileMeshes *ms)
7877 try:MEDFileAnyTypeFieldMultiTSWithoutSDA(fid,fieldName,fieldTyp,infos,nbOfStep,dtunit,loadAll,ms)
7880 catch(INTERP_KERNEL::Exception& e)
7883 MEDFileAnyTypeField1TSWithoutSDA *MEDFileFieldMultiTSWithoutSDA::createNew1TSWithoutSDAEmptyInstance() const
7885 return new MEDFileField1TSWithoutSDA;
7888 void MEDFileFieldMultiTSWithoutSDA::checkCoherencyOfType(const MEDFileAnyTypeField1TSWithoutSDA *f1ts) const
7891 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::checkCoherencyOfType : input field1TS is NULL ! Impossible to check !");
7892 const MEDFileField1TSWithoutSDA *f1tsC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(f1ts);
7894 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::checkCoherencyOfType : the input field1TS is not a FLOAT64 type !");
7897 const char *MEDFileFieldMultiTSWithoutSDA::getTypeStr() const
7899 return MEDFileField1TSWithoutSDA::TYPE_STR;
7902 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileFieldMultiTSWithoutSDA::shallowCpy() const
7904 return new MEDFileFieldMultiTSWithoutSDA(*this);
7907 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileFieldMultiTSWithoutSDA::createNew() const
7909 return new MEDFileFieldMultiTSWithoutSDA;
7913 * entry point for users that want to iterate into MEDFile DataStructure with a reduced overhead because output arrays are extracted (created) specially
7914 * for the call of this method. That's why the DataArrayDouble instance in returned vector of vector should be dealed by the caller.
7916 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
7918 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=getTimeStepEntry(iteration,order);
7919 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
7921 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::getFieldSplitedByType2 : mismatch of type of field expecting FLOAT64 !");
7922 return myF1TSC->getFieldSplitedByType2(mname,types,typesF,pfls,locs);
7925 MEDFileIntFieldMultiTSWithoutSDA *MEDFileFieldMultiTSWithoutSDA::convertToInt() const
7927 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTSWithoutSDA> ret(new MEDFileIntFieldMultiTSWithoutSDA);
7928 ret->MEDFileAnyTypeFieldMultiTSWithoutSDA::operator =(*this);
7930 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,i++)
7932 const MEDFileAnyTypeField1TSWithoutSDA *eltToConv(*it);
7935 const MEDFileField1TSWithoutSDA *eltToConvC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(eltToConv);
7937 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTSWithoutSDA::convertToInt : presence of an invalid 1TS type ! Should be of type FLOAT64 !");
7938 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> elt=eltToConvC->convertToInt();
7939 ret->setIteration(i,elt);
7945 //= MEDFileAnyTypeFieldMultiTS
7947 MEDFileAnyTypeFieldMultiTS::MEDFileAnyTypeFieldMultiTS()
7951 MEDFileAnyTypeFieldMultiTS::MEDFileAnyTypeFieldMultiTS(const std::string& fileName, bool loadAll, const MEDFileMeshes *ms)
7952 try:MEDFileFieldGlobsReal(fileName)
7954 MEDFileUtilities::CheckFileForRead(fileName);
7955 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
7956 _content=BuildContentFrom(fid,fileName,loadAll,ms);
7959 catch(INTERP_KERNEL::Exception& e)
7964 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTS::BuildContentFrom(med_idt fid, const std::string& fileName, const std::string& fieldName, bool loadAll, const MEDFileMeshes *ms)
7966 med_field_type typcha;
7967 std::vector<std::string> infos;
7970 MEDFileAnyTypeField1TS::LocateField(fid,fileName,fieldName,i,typcha,infos,dtunit);
7971 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> ret;
7976 ret=new MEDFileFieldMultiTSWithoutSDA(fid,i,loadAll,ms);
7981 ret=new MEDFileIntFieldMultiTSWithoutSDA(fid,i,loadAll,ms);
7986 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] !";
7987 throw INTERP_KERNEL::Exception(oss.str().c_str());
7990 ret->setDtUnit(dtunit.c_str());
7994 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTS::BuildContentFrom(med_idt fid, const std::string& fileName, bool loadAll, const MEDFileMeshes *ms)
7996 med_field_type typcha;
7998 std::vector<std::string> infos;
7999 std::string dtunit,fieldName;
8000 MEDFileAnyTypeField1TS::LocateField2(fid,fileName,0,true,fieldName,typcha,infos,dtunit);
8001 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> ret;
8006 ret=new MEDFileFieldMultiTSWithoutSDA(fid,0,loadAll,ms);
8011 ret=new MEDFileIntFieldMultiTSWithoutSDA(fid,0,loadAll,ms);
8016 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] !";
8017 throw INTERP_KERNEL::Exception(oss.str().c_str());
8020 ret->setDtUnit(dtunit.c_str());
8024 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::BuildNewInstanceFromContent(MEDFileAnyTypeFieldMultiTSWithoutSDA *c, const std::string& fileName)
8027 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::BuildNewInstanceFromContent : empty content in input : unable to build a new instance !");
8028 if(dynamic_cast<const MEDFileFieldMultiTSWithoutSDA *>(c))
8030 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTS> ret=MEDFileFieldMultiTS::New();
8031 ret->setFileName(fileName);
8032 ret->_content=c; c->incrRef();
8035 if(dynamic_cast<const MEDFileIntFieldMultiTSWithoutSDA *>(c))
8037 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTS> ret=MEDFileIntFieldMultiTS::New();
8038 ret->setFileName(fileName);
8039 ret->_content=c; c->incrRef();
8042 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::BuildNewInstanceFromContent : internal error ! a content of type different from FLOAT64 and INT32 has been built but not intercepted !");
8045 MEDFileAnyTypeFieldMultiTS::MEDFileAnyTypeFieldMultiTS(const std::string& fileName, const std::string& fieldName, bool loadAll, const MEDFileMeshes *ms)
8046 try:MEDFileFieldGlobsReal(fileName)
8048 MEDFileUtilities::CheckFileForRead(fileName);
8049 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
8050 _content=BuildContentFrom(fid,fileName,fieldName,loadAll,ms);
8053 catch(INTERP_KERNEL::Exception& e)
8058 //= MEDFileIntFieldMultiTSWithoutSDA
8060 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, const MEDFileMeshes *ms)
8062 return new MEDFileIntFieldMultiTSWithoutSDA(fid,fieldName,fieldTyp,infos,nbOfStep,dtunit,loadAll,ms);
8065 MEDFileIntFieldMultiTSWithoutSDA::MEDFileIntFieldMultiTSWithoutSDA()
8069 MEDFileIntFieldMultiTSWithoutSDA::MEDFileIntFieldMultiTSWithoutSDA(const std::string& fieldName):MEDFileAnyTypeFieldMultiTSWithoutSDA(fieldName)
8073 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, const MEDFileMeshes *ms)
8074 try:MEDFileAnyTypeFieldMultiTSWithoutSDA(fid,fieldName,fieldTyp,infos,nbOfStep,dtunit,loadAll,ms)
8077 catch(INTERP_KERNEL::Exception& e)
8081 * \param [in] fieldId field id in C mode
8083 MEDFileIntFieldMultiTSWithoutSDA::MEDFileIntFieldMultiTSWithoutSDA(med_idt fid, int fieldId, bool loadAll, const MEDFileMeshes *ms)
8084 try:MEDFileAnyTypeFieldMultiTSWithoutSDA(fid,fieldId,loadAll,ms)
8087 catch(INTERP_KERNEL::Exception& e)
8090 MEDFileAnyTypeField1TSWithoutSDA *MEDFileIntFieldMultiTSWithoutSDA::createNew1TSWithoutSDAEmptyInstance() const
8092 return new MEDFileIntField1TSWithoutSDA;
8095 void MEDFileIntFieldMultiTSWithoutSDA::checkCoherencyOfType(const MEDFileAnyTypeField1TSWithoutSDA *f1ts) const
8098 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTSWithoutSDA::checkCoherencyOfType : input field1TS is NULL ! Impossible to check !");
8099 const MEDFileIntField1TSWithoutSDA *f1tsC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(f1ts);
8101 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTSWithoutSDA::checkCoherencyOfType : the input field1TS is not a INT32 type !");
8104 const char *MEDFileIntFieldMultiTSWithoutSDA::getTypeStr() const
8106 return MEDFileIntField1TSWithoutSDA::TYPE_STR;
8109 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileIntFieldMultiTSWithoutSDA::shallowCpy() const
8111 return new MEDFileIntFieldMultiTSWithoutSDA(*this);
8114 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileIntFieldMultiTSWithoutSDA::createNew() const
8116 return new MEDFileIntFieldMultiTSWithoutSDA;
8119 MEDFileFieldMultiTSWithoutSDA *MEDFileIntFieldMultiTSWithoutSDA::convertToDouble() const
8121 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTSWithoutSDA> ret(new MEDFileFieldMultiTSWithoutSDA);
8122 ret->MEDFileAnyTypeFieldMultiTSWithoutSDA::operator =(*this);
8124 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> >::const_iterator it=_time_steps.begin();it!=_time_steps.end();it++,i++)
8126 const MEDFileAnyTypeField1TSWithoutSDA *eltToConv(*it);
8129 const MEDFileIntField1TSWithoutSDA *eltToConvC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(eltToConv);
8131 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTSWithoutSDA::convertToInt : presence of an invalid 1TS type ! Should be of type INT32 !");
8132 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> elt=eltToConvC->convertToDouble();
8133 ret->setIteration(i,elt);
8139 //= MEDFileAnyTypeFieldMultiTS
8142 * Returns a new instance of MEDFileFieldMultiTS or MEDFileIntFieldMultiTS holding data of the first field
8143 * that has been read from a specified MED file.
8144 * \param [in] fileName - the name of the MED file to read.
8145 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS or MEDFileIntFieldMultiTS. The caller
8146 * is to delete this field using decrRef() as it is no more needed.
8147 * \throw If reading the file fails.
8149 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::New(const std::string& fileName, bool loadAll)
8151 MEDFileUtilities::CheckFileForRead(fileName);
8152 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
8153 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> c=BuildContentFrom(fid,fileName,loadAll,0);
8154 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret=BuildNewInstanceFromContent(c,fileName);
8155 ret->loadGlobals(fid);
8160 * Returns a new instance of MEDFileFieldMultiTS or MEDFileIntFieldMultiTS holding data of a given field
8161 * that has been read from a specified MED file.
8162 * \param [in] fileName - the name of the MED file to read.
8163 * \param [in] fieldName - the name of the field to read.
8164 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS or MEDFileIntFieldMultiTS. The caller
8165 * is to delete this field using decrRef() as it is no more needed.
8166 * \throw If reading the file fails.
8167 * \throw If there is no field named \a fieldName in the file.
8169 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
8171 MEDFileUtilities::CheckFileForRead(fileName);
8172 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY);
8173 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> c=BuildContentFrom(fid,fileName,fieldName,loadAll,0);
8174 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret=BuildNewInstanceFromContent(c,fileName);
8175 ret->loadGlobals(fid);
8180 * This constructor is a shallow copy constructor. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
8181 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
8183 * \warning this is a shallow copy constructor
8185 MEDFileAnyTypeFieldMultiTS::MEDFileAnyTypeFieldMultiTS(const MEDFileAnyTypeFieldMultiTSWithoutSDA& other, bool shallowCopyOfContent)
8187 if(!shallowCopyOfContent)
8189 const MEDFileAnyTypeFieldMultiTSWithoutSDA *otherPtr(&other);
8190 otherPtr->incrRef();
8191 _content=const_cast<MEDFileAnyTypeFieldMultiTSWithoutSDA *>(otherPtr);
8195 _content=other.shallowCpy();
8199 MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTS::contentNotNullBase()
8201 MEDFileAnyTypeFieldMultiTSWithoutSDA *ret=_content;
8203 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS : content is expected to be not null !");
8207 const MEDFileAnyTypeFieldMultiTSWithoutSDA *MEDFileAnyTypeFieldMultiTS::contentNotNullBase() const
8209 const MEDFileAnyTypeFieldMultiTSWithoutSDA *ret=_content;
8211 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS : const content is expected to be not null !");
8215 std::vector<std::string> MEDFileAnyTypeFieldMultiTS::getPflsReallyUsed() const
8217 return contentNotNullBase()->getPflsReallyUsed2();
8220 std::vector<std::string> MEDFileAnyTypeFieldMultiTS::getLocsReallyUsed() const
8222 return contentNotNullBase()->getLocsReallyUsed2();
8225 std::vector<std::string> MEDFileAnyTypeFieldMultiTS::getPflsReallyUsedMulti() const
8227 return contentNotNullBase()->getPflsReallyUsedMulti2();
8230 std::vector<std::string> MEDFileAnyTypeFieldMultiTS::getLocsReallyUsedMulti() const
8232 return contentNotNullBase()->getLocsReallyUsedMulti2();
8235 void MEDFileAnyTypeFieldMultiTS::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
8237 contentNotNullBase()->changePflsRefsNamesGen2(mapOfModif);
8240 void MEDFileAnyTypeFieldMultiTS::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
8242 contentNotNullBase()->changeLocsRefsNamesGen2(mapOfModif);
8245 int MEDFileAnyTypeFieldMultiTS::getNumberOfTS() const
8247 return contentNotNullBase()->getNumberOfTS();
8250 void MEDFileAnyTypeFieldMultiTS::eraseEmptyTS()
8252 contentNotNullBase()->eraseEmptyTS();
8255 void MEDFileAnyTypeFieldMultiTS::eraseTimeStepIds(const int *startIds, const int *endIds)
8257 contentNotNullBase()->eraseTimeStepIds(startIds,endIds);
8260 void MEDFileAnyTypeFieldMultiTS::eraseTimeStepIds2(int bg, int end, int step)
8262 contentNotNullBase()->eraseTimeStepIds2(bg,end,step);
8265 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::buildSubPart(const int *startIds, const int *endIds) const
8267 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> c=contentNotNullBase()->buildFromTimeStepIds(startIds,endIds);
8268 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret=shallowCpy();
8273 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::buildSubPartSlice(int bg, int end, int step) const
8275 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> c=contentNotNullBase()->buildFromTimeStepIds2(bg,end,step);
8276 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret=shallowCpy();
8281 std::vector< std::pair<int,int> > MEDFileAnyTypeFieldMultiTS::getIterations() const
8283 return contentNotNullBase()->getIterations();
8286 void MEDFileAnyTypeFieldMultiTS::pushBackTimeSteps(const std::vector<MEDFileAnyTypeField1TS *>& f1ts)
8288 for(std::vector<MEDFileAnyTypeField1TS *>::const_iterator it=f1ts.begin();it!=f1ts.end();it++)
8289 pushBackTimeStep(*it);
8292 void MEDFileAnyTypeFieldMultiTS::pushBackTimeStep(MEDFileAnyTypeField1TS *f1ts)
8295 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::pushBackTimeStep : input pointer is NULL !");
8296 checkCoherencyOfType(f1ts);
8298 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> f1tsSafe(f1ts);
8299 MEDFileAnyTypeField1TSWithoutSDA *c=f1ts->contentNotNullBase();
8301 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TSWithoutSDA> cSafe(c);
8302 if(!((MEDFileAnyTypeFieldMultiTSWithoutSDA *)_content))
8303 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTSWithoutSDA::pushBackTimeStep : no content in this !");
8304 _content->pushBackTimeStep(cSafe);
8305 appendGlobs(*f1ts,1e-12);
8308 void MEDFileAnyTypeFieldMultiTS::synchronizeNameScope()
8310 contentNotNullBase()->synchronizeNameScope();
8313 int MEDFileAnyTypeFieldMultiTS::getPosOfTimeStep(int iteration, int order) const
8315 return contentNotNullBase()->getPosOfTimeStep(iteration,order);
8318 int MEDFileAnyTypeFieldMultiTS::getPosGivenTime(double time, double eps) const
8320 return contentNotNullBase()->getPosGivenTime(time,eps);
8323 int MEDFileAnyTypeFieldMultiTS::getNonEmptyLevels(int iteration, int order, const std::string& mname, std::vector<int>& levs) const
8325 return contentNotNullBase()->getNonEmptyLevels(iteration,order,mname,levs);
8328 std::vector< std::vector<TypeOfField> > MEDFileAnyTypeFieldMultiTS::getTypesOfFieldAvailable() const
8330 return contentNotNullBase()->getTypesOfFieldAvailable();
8333 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
8335 return contentNotNullBase()->getFieldSplitedByType(iteration,order,mname,types,typesF,pfls,locs);
8338 std::string MEDFileAnyTypeFieldMultiTS::getName() const
8340 return contentNotNullBase()->getName();
8343 void MEDFileAnyTypeFieldMultiTS::setName(const std::string& name)
8345 contentNotNullBase()->setName(name);
8348 std::string MEDFileAnyTypeFieldMultiTS::getDtUnit() const
8350 return contentNotNullBase()->getDtUnit();
8353 void MEDFileAnyTypeFieldMultiTS::setDtUnit(const std::string& dtUnit)
8355 contentNotNullBase()->setDtUnit(dtUnit);
8358 void MEDFileAnyTypeFieldMultiTS::simpleRepr(int bkOffset, std::ostream& oss, int fmtsId) const
8360 contentNotNullBase()->simpleRepr(bkOffset,oss,fmtsId);
8363 std::vector< std::pair<int,int> > MEDFileAnyTypeFieldMultiTS::getTimeSteps(std::vector<double>& ret1) const
8365 return contentNotNullBase()->getTimeSteps(ret1);
8368 std::string MEDFileAnyTypeFieldMultiTS::getMeshName() const
8370 return contentNotNullBase()->getMeshName();
8373 void MEDFileAnyTypeFieldMultiTS::setMeshName(const std::string& newMeshName)
8375 contentNotNullBase()->setMeshName(newMeshName);
8378 bool MEDFileAnyTypeFieldMultiTS::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
8380 return contentNotNullBase()->changeMeshNames(modifTab);
8383 const std::vector<std::string>& MEDFileAnyTypeFieldMultiTS::getInfo() const
8385 return contentNotNullBase()->getInfo();
8388 bool MEDFileAnyTypeFieldMultiTS::presenceOfMultiDiscPerGeoType() const
8390 return contentNotNullBase()->presenceOfMultiDiscPerGeoType();
8393 void MEDFileAnyTypeFieldMultiTS::setInfo(const std::vector<std::string>& info)
8395 return contentNotNullBase()->setInfo(info);
8398 int MEDFileAnyTypeFieldMultiTS::getNumberOfComponents() const
8400 const std::vector<std::string> ret=getInfo();
8401 return (int)ret.size();
8404 void MEDFileAnyTypeFieldMultiTS::writeLL(med_idt fid) const
8406 writeGlobals(fid,*this);
8407 contentNotNullBase()->writeLL(fid,*this);
8411 * Writes \a this field into a MED file specified by its name.
8412 * \param [in] fileName - the MED file name.
8413 * \param [in] mode - the writing mode. For more on \a mode, see \ref AdvMEDLoaderBasics.
8414 * - 2 - erase; an existing file is removed.
8415 * - 1 - append; same data should not be present in an existing file.
8416 * - 0 - overwrite; same data present in an existing file is overwritten.
8417 * \throw If the field name is not set.
8418 * \throw If no field data is set.
8419 * \throw If \a mode == 1 and the same data is present in an existing file.
8421 void MEDFileAnyTypeFieldMultiTS::write(const std::string& fileName, int mode) const
8423 med_access_mode medmod=MEDFileUtilities::TraduceWriteMode(mode);
8424 MEDFileUtilities::AutoFid fid=MEDfileOpen(fileName.c_str(),medmod);
8429 * This method alloc the arrays and load potentially huge arrays contained in this field.
8430 * This method should be called when a MEDFileAnyTypeFieldMultiTS::New constructor has been with false as the last parameter.
8431 * This method can be also called to refresh or reinit values from a file.
8433 * \throw If the fileName is not set or points to a non readable MED file.
8435 void MEDFileAnyTypeFieldMultiTS::loadArrays()
8437 if(getFileName().empty())
8438 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::loadArrays : the structure does not come from a file !");
8439 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
8440 contentNotNullBase()->loadBigArraysRecursively(fid,*contentNotNullBase());
8444 * This method behaves as MEDFileAnyTypeFieldMultiTS::loadArrays does, the first call, if \a this was built using a file without loading big arrays.
8445 * But once data loaded once, this method does nothing.
8447 * \throw If the fileName is not set or points to a non readable MED file.
8448 * \sa MEDFileAnyTypeFieldMultiTS::loadArrays, MEDFileAnyTypeFieldMultiTS::unloadArrays
8450 void MEDFileAnyTypeFieldMultiTS::loadArraysIfNecessary()
8452 if(!getFileName().empty())
8454 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
8455 contentNotNullBase()->loadBigArraysRecursivelyIfNecessary(fid,*contentNotNullBase());
8460 * This method releases potentially big data arrays and so returns to the same heap memory than status loaded with 'loadAll' parameter set to false.
8461 * \b WARNING, this method does release arrays even if \a this does not come from a load of a MED file.
8462 * So this method can lead to a loss of data. If you want to unload arrays safely call MEDFileAnyTypeFieldMultiTS::unloadArraysWithoutDataLoss instead.
8464 * \sa MEDFileAnyTypeFieldMultiTS::loadArrays, MEDFileAnyTypeFieldMultiTS::loadArraysIfNecessary, MEDFileAnyTypeFieldMultiTS::unloadArraysWithoutDataLoss
8466 void MEDFileAnyTypeFieldMultiTS::unloadArrays()
8468 contentNotNullBase()->unloadArrays();
8472 * This method potentially releases big data arrays if \a this is coming from a file. If \a this has been built from scratch this method will have no effect.
8473 * This method is the symetrical method of MEDFileAnyTypeFieldMultiTS::loadArraysIfNecessary.
8474 * This method is useful to reduce \b safely amount of heap memory necessary for \a this by using MED file as database.
8476 * \sa MEDFileAnyTypeFieldMultiTS::loadArraysIfNecessary
8478 void MEDFileAnyTypeFieldMultiTS::unloadArraysWithoutDataLoss()
8480 if(!getFileName().empty())
8481 contentNotNullBase()->unloadArrays();
8484 std::string MEDFileAnyTypeFieldMultiTS::simpleRepr() const
8486 std::ostringstream oss;
8487 contentNotNullBase()->simpleRepr(0,oss,-1);
8488 simpleReprGlobs(oss);
8492 std::size_t MEDFileAnyTypeFieldMultiTS::getHeapMemorySizeWithoutChildren() const
8494 return MEDFileFieldGlobsReal::getHeapMemorySizeWithoutChildren();
8497 std::vector<const BigMemoryObject *> MEDFileAnyTypeFieldMultiTS::getDirectChildrenWithNull() const
8499 std::vector<const BigMemoryObject *> ret(MEDFileFieldGlobsReal::getDirectChildrenWithNull());
8500 ret.push_back((const MEDFileAnyTypeFieldMultiTSWithoutSDA *)_content);
8505 * This method returns as MEDFileAnyTypeFieldMultiTS new instances as number of components in \a this.
8506 * The returned instances are deep copy of \a this except that for globals that are share with those contained in \a this.
8507 * ** WARNING ** do no forget to rename the ouput instances to avoid to write n-times in the same MED file field !
8509 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTS > > MEDFileAnyTypeFieldMultiTS::splitComponents() const
8511 const MEDFileAnyTypeFieldMultiTSWithoutSDA *content(_content);
8513 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::splitComponents : no content in this ! Unable to split components !");
8514 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > contentsSplit=content->splitComponents();
8515 std::size_t sz(contentsSplit.size());
8516 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTS > > ret(sz);
8517 for(std::size_t i=0;i<sz;i++)
8519 ret[i]=shallowCpy();
8520 ret[i]->_content=contentsSplit[i];
8526 * This method returns as MEDFileAnyTypeFieldMultiTS new instances as number of discretizations over time steps in \a this.
8527 * The returned instances are shallow copied of \a this included globals that are share with those contained in \a this.
8529 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTS > > MEDFileAnyTypeFieldMultiTS::splitDiscretizations() const
8531 const MEDFileAnyTypeFieldMultiTSWithoutSDA *content(_content);
8533 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::splitDiscretizations : no content in this ! Unable to split discretizations !");
8534 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > contentsSplit(content->splitDiscretizations());
8535 std::size_t sz(contentsSplit.size());
8536 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTS > > ret(sz);
8537 for(std::size_t i=0;i<sz;i++)
8539 ret[i]=shallowCpy();
8540 ret[i]->_content=contentsSplit[i];
8546 * This method returns as MEDFileAnyTypeFieldMultiTS new instances as number of sub-discretizations over time steps in \a this.
8547 * The returned instances are shallow copied of \a this included globals that are share with those contained in \a this.
8549 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTS > > MEDFileAnyTypeFieldMultiTS::splitMultiDiscrPerGeoTypes() const
8551 const MEDFileAnyTypeFieldMultiTSWithoutSDA *content(_content);
8553 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::splitMultiDiscrPerGeoTypes : no content in this ! Unable to split discretizations !");
8554 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > contentsSplit(content->splitMultiDiscrPerGeoTypes());
8555 std::size_t sz(contentsSplit.size());
8556 std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTS > > ret(sz);
8557 for(std::size_t i=0;i<sz;i++)
8559 ret[i]=shallowCpy();
8560 ret[i]->_content=contentsSplit[i];
8565 MEDFileAnyTypeFieldMultiTS *MEDFileAnyTypeFieldMultiTS::deepCpy() const
8567 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret=shallowCpy();
8568 if((const MEDFileAnyTypeFieldMultiTSWithoutSDA *)_content)
8569 ret->_content=_content->deepCpy();
8570 ret->deepCpyGlobs(*this);
8574 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> MEDFileAnyTypeFieldMultiTS::getContent()
8580 * Returns a new MEDFileField1TS or MEDFileIntField1TS holding data of a given time step of \a this field.
8581 * \param [in] iteration - the iteration number of a required time step.
8582 * \param [in] order - the iteration order number of required time step.
8583 * \return MEDFileField1TS * or MEDFileIntField1TS *- a new instance of MEDFileField1TS or MEDFileIntField1TS. The caller is to
8584 * delete this field using decrRef() as it is no more needed.
8585 * \throw If there is no required time step in \a this field.
8587 MEDFileAnyTypeField1TS *MEDFileAnyTypeFieldMultiTS::getTimeStep(int iteration, int order) const
8589 int pos=getPosOfTimeStep(iteration,order);
8590 return getTimeStepAtPos(pos);
8594 * Returns a new MEDFileField1TS or MEDFileIntField1TS holding data of a given time step of \a this field.
8595 * \param [in] time - the time of the time step of interest.
8596 * \param [in] eps - a precision used to compare time values.
8597 * \return MEDFileField1TS * - a new instance of MEDFileField1TS. The caller is to
8598 * delete this field using decrRef() as it is no more needed.
8599 * \throw If there is no required time step in \a this field.
8601 MEDFileAnyTypeField1TS *MEDFileAnyTypeFieldMultiTS::getTimeStepGivenTime(double time, double eps) const
8603 int pos=getPosGivenTime(time,eps);
8604 return getTimeStepAtPos(pos);
8608 * 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.
8609 * The float64 value of time attached to the pair of integers are not considered here.
8610 * WARNING the returned pointers are not incremented. The caller is \b not responsible to deallocate them ! This method only reorganizes entries in \a vectFMTS.
8612 * \param [in] vectFMTS - vector of not null fields defined on a same global data pointer.
8613 * \throw If there is a null pointer in \a vectFMTS.
8615 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > MEDFileAnyTypeFieldMultiTS::SplitIntoCommonTimeSeries(const std::vector<MEDFileAnyTypeFieldMultiTS *>& vectFMTS)
8617 static const char msg[]="MEDFileAnyTypeFieldMultiTS::SplitIntoCommonTimeSeries : presence of null instance in input vector !";
8618 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > ret;
8619 std::list<MEDFileAnyTypeFieldMultiTS *> lstFMTS(vectFMTS.begin(),vectFMTS.end());
8620 while(!lstFMTS.empty())
8622 std::list<MEDFileAnyTypeFieldMultiTS *>::iterator it(lstFMTS.begin());
8623 MEDFileAnyTypeFieldMultiTS *curIt(*it);
8625 throw INTERP_KERNEL::Exception(msg);
8626 std::vector< std::pair<int,int> > refIts=curIt->getIterations();
8627 std::vector<MEDFileAnyTypeFieldMultiTS *> elt;
8628 elt.push_back(curIt); it=lstFMTS.erase(it);
8629 while(it!=lstFMTS.end())
8633 throw INTERP_KERNEL::Exception(msg);
8634 std::vector< std::pair<int,int> > curIts=curIt->getIterations();
8636 { elt.push_back(curIt); it=lstFMTS.erase(it); }
8646 * This method splits the input list \a vectFMTS considering the aspect of the geometrical support over time.
8647 * All returned instances in a subvector can be safely loaded, rendered along time
8648 * All items must be defined on the same time step ids ( see MEDFileAnyTypeFieldMultiTS::SplitIntoCommonTimeSeries method ).
8649 * Each item in \a vectFMTS is expected to have one and exactly one spatial discretization along time.
8650 * 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).
8651 * All items in \a vectFMTS whose spatial discretization is not ON_NODES will appear once.
8652 * 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.
8654 * \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().
8655 * \param [in] mesh - the mesh shared by all items in \a vectFMTS across time.
8656 * \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.
8657 * \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.
8659 * \throw If an element in \a vectFMTS has not only one spatial discretization set.
8660 * \throw If an element in \a vectFMTS change of spatial discretization along time.
8661 * \throw If an element in \a vectFMTS lies on a mesh with meshname different from those in \a mesh.
8662 * \thorw If some elements in \a vectFMTS do not have the same times steps.
8663 * \throw If mesh is null.
8664 * \throw If an element in \a vectFMTS is null.
8665 * \sa MEDFileAnyTypeFieldMultiTS::AreOnSameSupportAcrossTime
8667 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupport(const std::vector<MEDFileAnyTypeFieldMultiTS *>& vectFMTS, const MEDFileMesh *mesh, std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFastCellSupportComparator> >& fsc)
8669 static const char msg[]="MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupport : presence of a null instance in the input vector !";
8671 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupport : input mesh is null !");
8672 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > ret;
8673 if(vectFMTS.empty())
8675 std::vector<MEDFileAnyTypeFieldMultiTS *>::const_iterator it(vectFMTS.begin());
8676 MEDFileAnyTypeFieldMultiTS *frstElt(*it);
8678 throw INTERP_KERNEL::Exception(msg);
8680 std::vector<MEDFileAnyTypeFieldMultiTS *> vectFMTSNotNodes;
8681 std::vector<MEDFileAnyTypeFieldMultiTS *> vectFMTSNodes;
8682 for(;it!=vectFMTS.end();it++,i++)
8685 throw INTERP_KERNEL::Exception(msg);
8686 TypeOfField tof0,tof1;
8687 if(CheckSupportAcrossTime(frstElt,*it,mesh,tof0,tof1)>0)
8690 vectFMTSNotNodes.push_back(*it);
8692 vectFMTSNodes.push_back(*it);
8695 vectFMTSNotNodes.push_back(*it);
8697 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFastCellSupportComparator> > cmps;
8698 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > retCell=SplitPerCommonSupportNotNodesAlg(vectFMTSNotNodes,mesh,cmps);
8700 for(std::vector<MEDFileAnyTypeFieldMultiTS *>::const_iterator it2=vectFMTSNodes.begin();it2!=vectFMTSNodes.end();it2++)
8703 bool isFetched(false);
8704 for(std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> >::const_iterator it0=retCell.begin();it0!=retCell.end();it0++,i++)
8707 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupport : internal error !");
8708 if(cmps[i]->isCompatibleWithNodesDiscr(*it2))
8709 { ret[i].push_back(*it2); isFetched=true; }
8713 std::vector<MEDFileAnyTypeFieldMultiTS *> tmp(1,*it2);
8714 MEDCouplingAutoRefCountObjectPtr<MEDFileMeshStruct> tmp2(MEDFileMeshStruct::New(mesh));
8715 ret.push_back(tmp); retCell.push_back(tmp); cmps.push_back(MEDFileFastCellSupportComparator::New(tmp2,*it2));
8723 * 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.
8724 * \param [out] cmps - same size than the returned vector.
8726 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupportNotNodesAlg(const std::vector<MEDFileAnyTypeFieldMultiTS *>& vectFMTS, const MEDFileMesh *mesh, std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileFastCellSupportComparator> >& cmps)
8728 std::vector< std::vector<MEDFileAnyTypeFieldMultiTS *> > ret;
8729 std::list<MEDFileAnyTypeFieldMultiTS *> lstFMTS(vectFMTS.begin(),vectFMTS.end());
8730 while(!lstFMTS.empty())
8732 std::list<MEDFileAnyTypeFieldMultiTS *>::iterator it(lstFMTS.begin());
8733 MEDFileAnyTypeFieldMultiTS *ref(*it);
8734 std::vector<MEDFileAnyTypeFieldMultiTS *> elt;
8735 elt.push_back(ref); it=lstFMTS.erase(it);
8736 MEDCouplingAutoRefCountObjectPtr<MEDFileMeshStruct> mst(MEDFileMeshStruct::New(mesh));
8737 MEDCouplingAutoRefCountObjectPtr<MEDFileFastCellSupportComparator> cmp(MEDFileFastCellSupportComparator::New(mst,ref));
8738 while(it!=lstFMTS.end())
8740 MEDFileAnyTypeFieldMultiTS *curIt(*it);
8741 if(cmp->isEqual(curIt))
8742 { elt.push_back(curIt); it=lstFMTS.erase(it); }
8746 ret.push_back(elt); cmps.push_back(cmp);
8752 * 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.
8753 * \a f0 and \a f1 must be defined each only on a same spatial discretization even if this can be different each other.
8755 * \throw If \a f0 or \a f1 has not only one spatial discretization set.
8756 * \throw If \a f0 or \a f1 change of spatial discretization along time.
8757 * \throw If \a f0 or \a f1 on a mesh with meshname different from those in \a mesh.
8758 * \thorw If \a f0 and \a f1 do not have the same times steps.
8759 * \throw If mesh is null.
8760 * \throw If \a f0 or \a f1 is null.
8761 * \sa MEDFileAnyTypeFieldMultiTS::SplitPerCommonSupport
8763 int MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime(MEDFileAnyTypeFieldMultiTS *f0, MEDFileAnyTypeFieldMultiTS *f1, const MEDFileMesh *mesh, TypeOfField& tof0, TypeOfField& tof1)
8766 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : input mesh is null !");
8768 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : presence of null instance in fields over time !");
8769 if(f0->getMeshName()!=mesh->getName())
8771 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : first field points to mesh \""<< f0->getMeshName() << "\" and input mesh to compare has name \"" << mesh->getName() << "\" !";
8772 throw INTERP_KERNEL::Exception(oss.str().c_str());
8774 if(f1->getMeshName()!=mesh->getName())
8776 std::ostringstream oss; oss << "MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : second field points to mesh \""<< f1->getMeshName() << "\" and input mesh to compare has name \"" << mesh->getName() << "\" !";
8777 throw INTERP_KERNEL::Exception(oss.str().c_str());
8779 int nts=f0->getNumberOfTS();
8780 if(nts!=f1->getNumberOfTS())
8781 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : number of time steps are not the same !");
8784 for(int i=0;i<nts;i++)
8786 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> f0cur=f0->getTimeStepAtPos(i);
8787 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeField1TS> f1cur=f1->getTimeStepAtPos(i);
8788 std::vector<TypeOfField> tofs0(f0cur->getTypesOfFieldAvailable()),tofs1(f1cur->getTypesOfFieldAvailable());
8789 if(tofs0.size()!=1 || tofs1.size()!=1)
8790 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : All time steps must be defined on only one spatial discretization !");
8793 if(tof0!=tofs0[0] || tof1!=tofs1[0])
8794 throw INTERP_KERNEL::Exception("MEDFileAnyTypeFieldMultiTS::CheckSupportAcrossTime : Across times steps MEDFileAnyTypeFieldMultiTS instances have to keep the same unique spatial discretization !");
8797 { tof0=tofs0[0]; tof1=tofs1[0]; }
8798 if(f0cur->getMeshIteration()!=mesh->getIteration() || f0cur->getMeshOrder()!=mesh->getOrder())
8800 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() << ") !";
8801 throw INTERP_KERNEL::Exception(oss.str().c_str());
8803 if(f1cur->getMeshIteration()!=mesh->getIteration() || f1cur->getMeshOrder()!=mesh->getOrder())
8805 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() << ") !";
8806 throw INTERP_KERNEL::Exception(oss.str().c_str());
8808 if(f0cur->getIteration()!=f1cur->getIteration() || f0cur->getOrder()!=f1cur->getOrder())
8810 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() << ") !";
8811 throw INTERP_KERNEL::Exception(oss.str().c_str());
8817 MEDFileAnyTypeFieldMultiTSIterator *MEDFileAnyTypeFieldMultiTS::iterator()
8819 return new MEDFileAnyTypeFieldMultiTSIterator(this);
8822 //= MEDFileFieldMultiTS
8825 * Returns a new empty instance of MEDFileFieldMultiTS.
8826 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS. The caller
8827 * is to delete this field using decrRef() as it is no more needed.
8829 MEDFileFieldMultiTS *MEDFileFieldMultiTS::New()
8831 return new MEDFileFieldMultiTS;
8835 * Returns a new instance of MEDFileFieldMultiTS holding data of the first field
8836 * that has been read from a specified MED file.
8837 * \param [in] fileName - the name of the MED file to read.
8838 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS. The caller
8839 * is to delete this field using decrRef() as it is no more needed.
8840 * \throw If reading the file fails.
8842 MEDFileFieldMultiTS *MEDFileFieldMultiTS::New(const std::string& fileName, bool loadAll)
8844 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTS> ret=new MEDFileFieldMultiTS(fileName,loadAll,0);
8845 ret->contentNotNull();//to check that content type matches with \a this type.
8850 * Returns a new instance of MEDFileFieldMultiTS holding data of a given field
8851 * that has been read from a specified MED file.
8852 * \param [in] fileName - the name of the MED file to read.
8853 * \param [in] fieldName - the name of the field to read.
8854 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS. The caller
8855 * is to delete this field using decrRef() as it is no more needed.
8856 * \throw If reading the file fails.
8857 * \throw If there is no field named \a fieldName in the file.
8859 MEDFileFieldMultiTS *MEDFileFieldMultiTS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
8861 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTS> ret=new MEDFileFieldMultiTS(fileName,fieldName,loadAll,0);
8862 ret->contentNotNull();//to check that content type matches with \a this type.
8867 * Returns a new instance of MEDFileFieldMultiTS. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
8868 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
8870 * Returns a new instance of MEDFileFieldMultiTS holding either a shallow copy
8871 * of a given MEDFileFieldMultiTSWithoutSDA ( \a other ) or \a other itself.
8872 * \warning this is a shallow copy constructor
8873 * \param [in] other - a MEDFileField1TSWithoutSDA to copy.
8874 * \param [in] shallowCopyOfContent - if \c true, a shallow copy of \a other is created.
8875 * \return MEDFileFieldMultiTS * - a new instance of MEDFileFieldMultiTS. The caller
8876 * is to delete this field using decrRef() as it is no more needed.
8878 MEDFileFieldMultiTS *MEDFileFieldMultiTS::New(const MEDFileFieldMultiTSWithoutSDA& other, bool shallowCopyOfContent)
8880 return new MEDFileFieldMultiTS(other,shallowCopyOfContent);
8883 MEDFileAnyTypeFieldMultiTS *MEDFileFieldMultiTS::shallowCpy() const
8885 return new MEDFileFieldMultiTS(*this);
8888 void MEDFileFieldMultiTS::checkCoherencyOfType(const MEDFileAnyTypeField1TS *f1ts) const
8891 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::checkCoherencyOfType : input field1TS is NULL ! Impossible to check !");
8892 const MEDFileField1TS *f1tsC=dynamic_cast<const MEDFileField1TS *>(f1ts);
8894 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::checkCoherencyOfType : the input field1TS is not a FLOAT64 type !");
8898 * This method performs a copy with datatype modification ( float64->int32 ) of \a this. The globals information are copied
8899 * following the given input policy.
8901 * \param [in] isDeepCpyGlobs - a boolean that indicates the behaviour concerning globals (profiles and localizations)
8902 * By default (true) the globals are deeply copied.
8903 * \return MEDFileIntFieldMultiTS * - a new object that is the result of the conversion of \a this to int32 field.
8905 MEDFileIntFieldMultiTS *MEDFileFieldMultiTS::convertToInt(bool isDeepCpyGlobs) const
8907 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTS> ret;
8908 const MEDFileAnyTypeFieldMultiTSWithoutSDA *content(_content);
8911 const MEDFileFieldMultiTSWithoutSDA *contc=dynamic_cast<const MEDFileFieldMultiTSWithoutSDA *>(content);
8913 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::convertToInt : the content inside this is not FLOAT64 ! This is incoherent !");
8914 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTSWithoutSDA> newc(contc->convertToInt());
8915 ret=static_cast<MEDFileIntFieldMultiTS *>(MEDFileAnyTypeFieldMultiTS::BuildNewInstanceFromContent((MEDFileIntFieldMultiTSWithoutSDA *)newc,getFileName()));
8918 ret=MEDFileIntFieldMultiTS::New();
8920 ret->deepCpyGlobs(*this);
8922 ret->shallowCpyGlobs(*this);
8927 * Returns a new MEDFileField1TS holding data of a given time step of \a this field.
8928 * \param [in] pos - a time step id.
8929 * \return MEDFileField1TS * - a new instance of MEDFileField1TS. The caller is to
8930 * delete this field using decrRef() as it is no more needed.
8931 * \throw If \a pos is not a valid time step id.
8933 MEDFileAnyTypeField1TS *MEDFileFieldMultiTS::getTimeStepAtPos(int pos) const
8935 const MEDFileAnyTypeField1TSWithoutSDA *item=contentNotNullBase()->getTimeStepAtPos2(pos);
8938 std::ostringstream oss; oss << "MEDFileFieldMultiTS::getTimeStepAtPos : field at pos #" << pos << " is null !";
8939 throw INTERP_KERNEL::Exception(oss.str().c_str());
8941 const MEDFileField1TSWithoutSDA *itemC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(item);
8944 MEDCouplingAutoRefCountObjectPtr<MEDFileField1TS> ret=MEDFileField1TS::New(*itemC,false);
8945 ret->shallowCpyGlobs(*this);
8948 std::ostringstream oss; oss << "MEDFileFieldMultiTS::getTimeStepAtPos : type of field at pos #" << pos << " is not FLOAT64 !";
8949 throw INTERP_KERNEL::Exception(oss.str().c_str());
8953 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
8954 * mesh entities of a given dimension of the first mesh in MED file.
8955 * For more info, see \ref AdvMEDLoaderAPIFieldRW
8956 * \param [in] type - a spatial discretization of interest.
8957 * \param [in] iteration - the iteration number of a required time step.
8958 * \param [in] order - the iteration order number of required time step.
8959 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
8960 * \param [in] renumPol - specifies how to permute values of the result field according to
8961 * the optional numbers of cells and nodes, if any. The valid values are
8962 * - 0 - do not permute.
8963 * - 1 - permute cells.
8964 * - 2 - permute nodes.
8965 * - 3 - permute cells and nodes.
8967 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
8968 * caller is to delete this field using decrRef() as it is no more needed.
8969 * \throw If the MED file is not readable.
8970 * \throw If there is no mesh in the MED file.
8971 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
8972 * \throw If no field values of the required parameters are available.
8974 MEDCouplingFieldDouble *MEDFileFieldMultiTS::getFieldAtLevel(TypeOfField type, int iteration, int order, int meshDimRelToMax, int renumPol) const
8976 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
8977 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
8979 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldAtLevel : mismatch of type of field expecting FLOAT64 !");
8980 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
8981 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtLevel(type,meshDimRelToMax,std::string(),renumPol,this,arrOut,*contentNotNullBase());
8982 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
8987 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
8988 * the top level cells of the first mesh in MED file.
8989 * For more info, see \ref AdvMEDLoaderAPIFieldRW
8990 * \param [in] type - a spatial discretization of interest.
8991 * \param [in] iteration - the iteration number of a required time step.
8992 * \param [in] order - the iteration order number of required time step.
8993 * \param [in] renumPol - specifies how to permute values of the result field according to
8994 * the optional numbers of cells and nodes, if any. The valid values are
8995 * - 0 - do not permute.
8996 * - 1 - permute cells.
8997 * - 2 - permute nodes.
8998 * - 3 - permute cells and nodes.
9000 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
9001 * caller is to delete this field using decrRef() as it is no more needed.
9002 * \throw If the MED file is not readable.
9003 * \throw If there is no mesh in the MED file.
9004 * \throw If no field values of the required parameters are available.
9006 MEDCouplingFieldDouble *MEDFileFieldMultiTS::getFieldAtTopLevel(TypeOfField type, int iteration, int order, int renumPol) const
9008 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9009 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
9011 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldAtTopLevel : mismatch of type of field !");
9012 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
9013 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtTopLevel(type,std::string(),renumPol,this,arrOut,*contentNotNullBase());
9014 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
9019 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
9021 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9022 * \param [in] type - a spatial discretization of interest.
9023 * \param [in] iteration - the iteration number of a required time step.
9024 * \param [in] order - the iteration order number of required time step.
9025 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
9026 * \param [in] mesh - the supporting mesh.
9027 * \param [in] renumPol - specifies how to permute values of the result field according to
9028 * the optional numbers of cells and nodes, if any. The valid values are
9029 * - 0 - do not permute.
9030 * - 1 - permute cells.
9031 * - 2 - permute nodes.
9032 * - 3 - permute cells and nodes.
9034 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
9035 * caller is to delete this field using decrRef() as it is no more needed.
9036 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
9037 * \throw If no field of \a this is lying on \a mesh.
9038 * \throw If no field values of the required parameters are available.
9040 MEDCouplingFieldDouble *MEDFileFieldMultiTS::getFieldOnMeshAtLevel(TypeOfField type, int iteration, int order, int meshDimRelToMax, const MEDFileMesh *mesh, int renumPol) const
9042 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9043 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
9045 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldOnMeshAtLevel : mismatch of type of field !");
9046 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
9047 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,this,mesh,arrOut,*contentNotNullBase());
9048 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
9053 * Returns a new MEDCouplingFieldDouble of given type, of a given time step, lying on a
9055 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9056 * \param [in] type - a spatial discretization of the new field.
9057 * \param [in] iteration - the iteration number of a required time step.
9058 * \param [in] order - the iteration order number of required time step.
9059 * \param [in] mesh - the supporting mesh.
9060 * \param [in] renumPol - specifies how to permute values of the result field according to
9061 * the optional numbers of cells and nodes, if any. The valid values are
9062 * - 0 - do not permute.
9063 * - 1 - permute cells.
9064 * - 2 - permute nodes.
9065 * - 3 - permute cells and nodes.
9067 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
9068 * caller is to delete this field using decrRef() as it is no more needed.
9069 * \throw If no field of \a this is lying on \a mesh.
9070 * \throw If no field values of the required parameters are available.
9072 MEDCouplingFieldDouble *MEDFileFieldMultiTS::getFieldOnMeshAtLevel(TypeOfField type, int iteration, int order, const MEDCouplingMesh *mesh, int renumPol) const
9074 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9075 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
9077 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldOnMeshAtLevel : mismatch of type of field !");
9078 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
9079 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldOnMeshAtLevel(type,renumPol,this,mesh,0,0,arrOut,*contentNotNullBase());
9080 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
9085 * This method has a close behaviour than MEDFileFieldMultiTS::getFieldAtLevel.
9086 * This method is called 'old' because the user should give the mesh name he wants to use for it's field.
9087 * This method is useful for MED2 file format when field on different mesh was autorized.
9089 MEDCouplingFieldDouble *MEDFileFieldMultiTS::getFieldAtLevelOld(TypeOfField type, const std::string& mname, int iteration, int order, int meshDimRelToMax, int renumPol) const
9091 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9092 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
9094 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldAtLevelOld : mismatch of type of field !");
9095 MEDCouplingAutoRefCountObjectPtr<DataArray> arrOut;
9096 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtLevel(type,meshDimRelToMax,mname,renumPol,this,arrOut,*contentNotNullBase());
9097 MEDFileField1TS::SetDataArrayDoubleInField(ret,arrOut);
9102 * Returns values and a profile of the field of a given type, of a given time step,
9103 * lying on a given support.
9104 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9105 * \param [in] type - a spatial discretization of the field.
9106 * \param [in] iteration - the iteration number of a required time step.
9107 * \param [in] order - the iteration order number of required time step.
9108 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
9109 * \param [in] mesh - the supporting mesh.
9110 * \param [out] pfl - a new instance of DataArrayInt holding ids of mesh entities the
9111 * field of interest lies on. If the field lies on all entities of the given
9112 * dimension, all ids in \a pfl are zero. The caller is to delete this array
9113 * using decrRef() as it is no more needed.
9114 * \param [in] glob - the global data storing profiles and localization.
9115 * \return DataArrayDouble * - a new instance of DataArrayDouble holding values of the
9116 * field. The caller is to delete this array using decrRef() as it is no more needed.
9117 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
9118 * \throw If no field of \a this is lying on \a mesh.
9119 * \throw If no field values of the required parameters are available.
9121 DataArrayDouble *MEDFileFieldMultiTS::getFieldWithProfile(TypeOfField type, int iteration, int order, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt *&pfl) const
9123 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9124 const MEDFileField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileField1TSWithoutSDA *>(&myF1TS);
9126 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldWithProfile : mismatch of type of field !");
9127 MEDCouplingAutoRefCountObjectPtr<DataArray> ret=myF1TSC->getFieldWithProfile(type,meshDimRelToMax,mesh,pfl,this,*contentNotNullBase());
9128 return MEDFileField1TS::ReturnSafelyDataArrayDouble(ret);
9131 const MEDFileFieldMultiTSWithoutSDA *MEDFileFieldMultiTS::contentNotNull() const
9133 const MEDFileAnyTypeFieldMultiTSWithoutSDA *pt(_content);
9135 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::contentNotNull : the content pointer is null !");
9136 const MEDFileFieldMultiTSWithoutSDA *ret=dynamic_cast<const MEDFileFieldMultiTSWithoutSDA *>(pt);
9138 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 !");
9142 MEDFileFieldMultiTSWithoutSDA *MEDFileFieldMultiTS::contentNotNull()
9144 MEDFileAnyTypeFieldMultiTSWithoutSDA *pt(_content);
9146 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::contentNotNull : the non const content pointer is null !");
9147 MEDFileFieldMultiTSWithoutSDA *ret=dynamic_cast<MEDFileFieldMultiTSWithoutSDA *>(pt);
9149 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 !");
9154 * Adds a MEDCouplingFieldDouble to \a this as another time step. The underlying mesh of
9155 * the given field is checked if its elements are sorted suitable for writing to MED file
9156 * ("STB" stands for "Sort By Type"), if not, an exception is thrown.
9157 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9158 * \param [in] field - the field to add to \a this.
9159 * \throw If the name of \a field is empty.
9160 * \throw If the data array of \a field is not set.
9161 * \throw If existing time steps have different name or number of components than \a field.
9162 * \throw If the underlying mesh of \a field has no name.
9163 * \throw If elements in the mesh are not in the order suitable for writing to the MED file.
9165 void MEDFileFieldMultiTS::appendFieldNoProfileSBT(const MEDCouplingFieldDouble *field)
9167 const DataArrayDouble *arr=0;
9169 arr=field->getArray();
9170 contentNotNull()->appendFieldNoProfileSBT(field,arr,*this);
9174 * Adds a MEDCouplingFieldDouble to \a this as another time step.
9175 * The mesh support of input parameter \a field is ignored here, it can be NULL.
9176 * The support of field \a field is expected to be those computed with the input parameter \a mesh, \a meshDimRelToMax,
9179 * This method will check that the field based on the computed support is coherent. If not an exception will be thrown.
9180 * A new profile is added only if no equal profile is missing.
9181 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9182 * \param [in] field - the field to add to \a this. The mesh support of field is ignored.
9183 * \param [in] mesh - the supporting mesh of \a field.
9184 * \param [in] meshDimRelToMax - a relative dimension of mesh entities \a field lies on (useless if field spatial discretization is ON_NODES).
9185 * \param [in] profile - ids of mesh entities on which corresponding field values lie.
9186 * \throw If either \a field or \a mesh or \a profile has an empty name.
9187 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
9188 * \throw If the data array of \a field is not set.
9189 * \throw If the data array of \a this is already allocated but has different number of
9190 * components than \a field.
9191 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
9192 * \sa setFieldNoProfileSBT()
9194 void MEDFileFieldMultiTS::appendFieldProfile(const MEDCouplingFieldDouble *field, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile)
9196 const DataArrayDouble *arr=0;
9198 arr=field->getArray();
9199 contentNotNull()->appendFieldProfile(field,arr,mesh,meshDimRelToMax,profile,*this);
9202 MEDFileFieldMultiTS::MEDFileFieldMultiTS()
9204 _content=new MEDFileFieldMultiTSWithoutSDA;
9207 MEDFileFieldMultiTS::MEDFileFieldMultiTS(const std::string& fileName, bool loadAll, const MEDFileMeshes *ms)
9208 try:MEDFileAnyTypeFieldMultiTS(fileName,loadAll,ms)
9211 catch(INTERP_KERNEL::Exception& e)
9214 MEDFileFieldMultiTS::MEDFileFieldMultiTS(const std::string& fileName, const std::string& fieldName, bool loadAll, const MEDFileMeshes *ms)
9215 try:MEDFileAnyTypeFieldMultiTS(fileName,fieldName,loadAll,ms)
9218 catch(INTERP_KERNEL::Exception& e)
9221 MEDFileFieldMultiTS::MEDFileFieldMultiTS(const MEDFileFieldMultiTSWithoutSDA& other, bool shallowCopyOfContent):MEDFileAnyTypeFieldMultiTS(other,shallowCopyOfContent)
9225 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
9227 return contentNotNull()->getFieldSplitedByType2(iteration,order,mname,types,typesF,pfls,locs);
9230 DataArrayDouble *MEDFileFieldMultiTS::getUndergroundDataArray(int iteration, int order) const
9232 return static_cast<DataArrayDouble *>(contentNotNull()->getUndergroundDataArray(iteration,order));
9235 DataArrayDouble *MEDFileFieldMultiTS::getUndergroundDataArrayExt(int iteration, int order, std::vector< std::pair<std::pair<INTERP_KERNEL::NormalizedCellType,int>,std::pair<int,int> > >& entries) const
9237 return static_cast<DataArrayDouble *>(contentNotNull()->getUndergroundDataArrayExt(iteration,order,entries));
9240 //= MEDFileAnyTypeFieldMultiTSIterator
9242 MEDFileAnyTypeFieldMultiTSIterator::MEDFileAnyTypeFieldMultiTSIterator(MEDFileAnyTypeFieldMultiTS *fmts):_fmts(fmts),_iter_id(0),_nb_iter(0)
9247 _nb_iter=fmts->getNumberOfTS();
9251 MEDFileAnyTypeFieldMultiTSIterator::~MEDFileAnyTypeFieldMultiTSIterator()
9255 MEDFileAnyTypeField1TS *MEDFileAnyTypeFieldMultiTSIterator::nextt()
9257 if(_iter_id<_nb_iter)
9259 MEDFileAnyTypeFieldMultiTS *fmts(_fmts);
9261 return fmts->getTimeStepAtPos(_iter_id++);
9269 //= MEDFileIntFieldMultiTS
9272 * Returns a new empty instance of MEDFileFieldMultiTS.
9273 * \return MEDFileIntFieldMultiTS * - a new instance of MEDFileIntFieldMultiTS. The caller
9274 * is to delete this field using decrRef() as it is no more needed.
9276 MEDFileIntFieldMultiTS *MEDFileIntFieldMultiTS::New()
9278 return new MEDFileIntFieldMultiTS;
9282 * Returns a new instance of MEDFileIntFieldMultiTS holding data of the first field
9283 * that has been read from a specified MED file.
9284 * \param [in] fileName - the name of the MED file to read.
9285 * \return MEDFileFieldMultiTS * - a new instance of MEDFileIntFieldMultiTS. The caller
9286 * is to delete this field using decrRef() as it is no more needed.
9287 * \throw If reading the file fails.
9289 MEDFileIntFieldMultiTS *MEDFileIntFieldMultiTS::New(const std::string& fileName, bool loadAll)
9291 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTS> ret=new MEDFileIntFieldMultiTS(fileName,loadAll,0);
9292 ret->contentNotNull();//to check that content type matches with \a this type.
9297 * Returns a new instance of MEDFileIntFieldMultiTS holding data of a given field
9298 * that has been read from a specified MED file.
9299 * \param [in] fileName - the name of the MED file to read.
9300 * \param [in] fieldName - the name of the field to read.
9301 * \return MEDFileFieldMultiTS * - a new instance of MEDFileIntFieldMultiTS. The caller
9302 * is to delete this field using decrRef() as it is no more needed.
9303 * \throw If reading the file fails.
9304 * \throw If there is no field named \a fieldName in the file.
9306 MEDFileIntFieldMultiTS *MEDFileIntFieldMultiTS::New(const std::string& fileName, const std::string& fieldName, bool loadAll)
9308 MEDCouplingAutoRefCountObjectPtr<MEDFileIntFieldMultiTS> ret=new MEDFileIntFieldMultiTS(fileName,fieldName,loadAll,0);
9309 ret->contentNotNull();//to check that content type matches with \a this type.
9314 * Returns a new instance of MEDFileIntFieldMultiTS. If \a shallowCopyOfContent is true the content of \a other is shallow copied.
9315 * If \a shallowCopyOfContent is false, \a other is taken to be the content of \a this.
9317 * Returns a new instance of MEDFileIntFieldMultiTS holding either a shallow copy
9318 * of a given MEDFileIntFieldMultiTSWithoutSDA ( \a other ) or \a other itself.
9319 * \warning this is a shallow copy constructor
9320 * \param [in] other - a MEDFileIntField1TSWithoutSDA to copy.
9321 * \param [in] shallowCopyOfContent - if \c true, a shallow copy of \a other is created.
9322 * \return MEDFileIntFieldMultiTS * - a new instance of MEDFileIntFieldMultiTS. The caller
9323 * is to delete this field using decrRef() as it is no more needed.
9325 MEDFileIntFieldMultiTS *MEDFileIntFieldMultiTS::New(const MEDFileIntFieldMultiTSWithoutSDA& other, bool shallowCopyOfContent)
9327 return new MEDFileIntFieldMultiTS(other,shallowCopyOfContent);
9331 * This method performs a copy with datatype modification ( int32->float64 ) of \a this. The globals information are copied
9332 * following the given input policy.
9334 * \param [in] isDeepCpyGlobs - a boolean that indicates the behaviour concerning globals (profiles and localizations)
9335 * By default (true) the globals are deeply copied.
9336 * \return MEDFileFieldMultiTS * - a new object that is the result of the conversion of \a this to float64 field.
9338 MEDFileFieldMultiTS *MEDFileIntFieldMultiTS::convertToDouble(bool isDeepCpyGlobs) const
9340 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTS> ret;
9341 const MEDFileAnyTypeFieldMultiTSWithoutSDA *content(_content);
9344 const MEDFileIntFieldMultiTSWithoutSDA *contc=dynamic_cast<const MEDFileIntFieldMultiTSWithoutSDA *>(content);
9346 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::convertToInt : the content inside this is not INT32 ! This is incoherent !");
9347 MEDCouplingAutoRefCountObjectPtr<MEDFileFieldMultiTSWithoutSDA> newc(contc->convertToDouble());
9348 ret=static_cast<MEDFileFieldMultiTS *>(MEDFileAnyTypeFieldMultiTS::BuildNewInstanceFromContent((MEDFileFieldMultiTSWithoutSDA *)newc,getFileName()));
9351 ret=MEDFileFieldMultiTS::New();
9353 ret->deepCpyGlobs(*this);
9355 ret->shallowCpyGlobs(*this);
9359 MEDFileAnyTypeFieldMultiTS *MEDFileIntFieldMultiTS::shallowCpy() const
9361 return new MEDFileIntFieldMultiTS(*this);
9364 void MEDFileIntFieldMultiTS::checkCoherencyOfType(const MEDFileAnyTypeField1TS *f1ts) const
9367 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::checkCoherencyOfType : input field1TS is NULL ! Impossible to check !");
9368 const MEDFileIntField1TS *f1tsC=dynamic_cast<const MEDFileIntField1TS *>(f1ts);
9370 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::checkCoherencyOfType : the input field1TS is not a INT32 type !");
9374 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
9375 * mesh entities of a given dimension of the first mesh in MED file.
9376 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9377 * \param [in] type - a spatial discretization of interest.
9378 * \param [in] iteration - the iteration number of a required time step.
9379 * \param [in] order - the iteration order number of required time step.
9380 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
9381 * \param [out] arrOut - the DataArrayInt containing values of field.
9382 * \param [in] renumPol - specifies how to permute values of the result field according to
9383 * the optional numbers of cells and nodes, if any. The valid values are
9384 * - 0 - do not permute.
9385 * - 1 - permute cells.
9386 * - 2 - permute nodes.
9387 * - 3 - permute cells and nodes.
9389 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
9390 * caller is to delete this field using decrRef() as it is no more needed.
9391 * \throw If the MED file is not readable.
9392 * \throw If there is no mesh in the MED file.
9393 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
9394 * \throw If no field values of the required parameters are available.
9396 MEDCouplingFieldDouble *MEDFileIntFieldMultiTS::getFieldAtLevel(TypeOfField type, int iteration, int order, int meshDimRelToMax, DataArrayInt* &arrOut, int renumPol) const
9398 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9399 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9401 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::getFieldAtLevel : mismatch of type of field expecting INT32 !");
9402 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
9403 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtLevel(type,meshDimRelToMax,std::string(),renumPol,this,arr,*contentNotNullBase());
9404 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
9409 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
9410 * the top level cells of the first mesh in MED file.
9411 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9412 * \param [in] type - a spatial discretization of interest.
9413 * \param [in] iteration - the iteration number of a required time step.
9414 * \param [in] order - the iteration order number of required time step.
9415 * \param [out] arrOut - the DataArrayInt containing values of field.
9416 * \param [in] renumPol - specifies how to permute values of the result field according to
9417 * the optional numbers of cells and nodes, if any. The valid values are
9418 * - 0 - do not permute.
9419 * - 1 - permute cells.
9420 * - 2 - permute nodes.
9421 * - 3 - permute cells and nodes.
9423 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
9424 * caller is to delete this field using decrRef() as it is no more needed.
9425 * \throw If the MED file is not readable.
9426 * \throw If there is no mesh in the MED file.
9427 * \throw If no field values of the required parameters are available.
9429 MEDCouplingFieldDouble *MEDFileIntFieldMultiTS::getFieldAtTopLevel(TypeOfField type, int iteration, int order, DataArrayInt* &arrOut, int renumPol) const
9431 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9432 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9434 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::getFieldAtTopLevel : mismatch of type of field ! INT32 expected !");
9435 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
9436 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtTopLevel(type,std::string(),renumPol,this,arr,*contentNotNullBase());
9437 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
9442 * Returns a new MEDCouplingFieldDouble of a given type, of a given time step, lying on
9444 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9445 * \param [in] type - a spatial discretization of interest.
9446 * \param [in] iteration - the iteration number of a required time step.
9447 * \param [in] order - the iteration order number of required time step.
9448 * \param [out] arrOut - the DataArrayInt containing values of field.
9449 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
9450 * \param [in] mesh - the supporting mesh.
9451 * \param [in] renumPol - specifies how to permute values of the result field according to
9452 * the optional numbers of cells and nodes, if any. The valid values are
9453 * - 0 - do not permute.
9454 * - 1 - permute cells.
9455 * - 2 - permute nodes.
9456 * - 3 - permute cells and nodes.
9458 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
9459 * caller is to delete this field using decrRef() as it is no more needed.
9460 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in the mesh.
9461 * \throw If no field of \a this is lying on \a mesh.
9462 * \throw If no field values of the required parameters are available.
9464 MEDCouplingFieldDouble *MEDFileIntFieldMultiTS::getFieldOnMeshAtLevel(TypeOfField type, int iteration, int order, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt* &arrOut, int renumPol) const
9466 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9467 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9469 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldOnMeshAtLevel : mismatch of type of field ! INT32 expected !");
9470 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
9471 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldOnMeshAtLevel(type,meshDimRelToMax,renumPol,this,mesh,arr,*contentNotNullBase());
9472 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
9477 * Returns a new MEDCouplingFieldDouble of given type, of a given time step, lying on a
9479 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9480 * \param [in] type - a spatial discretization of the new field.
9481 * \param [in] iteration - the iteration number of a required time step.
9482 * \param [in] order - the iteration order number of required time step.
9483 * \param [in] mesh - the supporting mesh.
9484 * \param [out] arrOut - the DataArrayInt containing values of field.
9485 * \param [in] renumPol - specifies how to permute values of the result field according to
9486 * the optional numbers of cells and nodes, if any. The valid values are
9487 * - 0 - do not permute.
9488 * - 1 - permute cells.
9489 * - 2 - permute nodes.
9490 * - 3 - permute cells and nodes.
9492 * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
9493 * caller is to delete this field using decrRef() as it is no more needed.
9494 * \throw If no field of \a this is lying on \a mesh.
9495 * \throw If no field values of the required parameters are available.
9497 MEDCouplingFieldDouble *MEDFileIntFieldMultiTS::getFieldOnMeshAtLevel(TypeOfField type, int iteration, int order, const MEDCouplingMesh *mesh, DataArrayInt* &arrOut, int renumPol) const
9499 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9500 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9502 throw INTERP_KERNEL::Exception("MEDFileFieldIntMultiTS::getFieldOnMeshAtLevel : mismatch of type of field ! INT32 expected !");
9503 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
9504 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldOnMeshAtLevel(type,renumPol,this,mesh,0,0,arr,*contentNotNullBase());
9505 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
9510 * This method has a close behaviour than MEDFileIntFieldMultiTS::getFieldAtLevel.
9511 * This method is called 'old' because the user should give the mesh name he wants to use for it's field.
9512 * This method is useful for MED2 file format when field on different mesh was autorized.
9514 MEDCouplingFieldDouble *MEDFileIntFieldMultiTS::getFieldAtLevelOld(TypeOfField type, int iteration, int order, const std::string& mname, int meshDimRelToMax, DataArrayInt* &arrOut, int renumPol) const
9516 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9517 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9519 throw INTERP_KERNEL::Exception("MEDFileFieldMultiTS::getFieldOnMeshAtLevel : mismatch of type of field ! INT32 expected !");
9520 MEDCouplingAutoRefCountObjectPtr<DataArray> arr;
9521 MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=myF1TSC->getFieldAtLevel(type,meshDimRelToMax,mname,renumPol,this,arr,*contentNotNullBase());
9522 arrOut=MEDFileIntField1TS::ReturnSafelyDataArrayInt(arr);
9527 * Returns values and a profile of the field of a given type, of a given time step,
9528 * lying on a given support.
9529 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9530 * \param [in] type - a spatial discretization of the field.
9531 * \param [in] iteration - the iteration number of a required time step.
9532 * \param [in] order - the iteration order number of required time step.
9533 * \param [in] meshDimRelToMax - a relative dimension of the supporting mesh entities.
9534 * \param [in] mesh - the supporting mesh.
9535 * \param [out] pfl - a new instance of DataArrayInt holding ids of mesh entities the
9536 * field of interest lies on. If the field lies on all entities of the given
9537 * dimension, all ids in \a pfl are zero. The caller is to delete this array
9538 * using decrRef() as it is no more needed.
9539 * \param [in] glob - the global data storing profiles and localization.
9540 * \return DataArrayInt * - a new instance of DataArrayInt holding values of the
9541 * field. The caller is to delete this array using decrRef() as it is no more needed.
9542 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
9543 * \throw If no field of \a this is lying on \a mesh.
9544 * \throw If no field values of the required parameters are available.
9546 DataArrayInt *MEDFileIntFieldMultiTS::getFieldWithProfile(TypeOfField type, int iteration, int order, int meshDimRelToMax, const MEDFileMesh *mesh, DataArrayInt *&pfl) const
9548 const MEDFileAnyTypeField1TSWithoutSDA& myF1TS=contentNotNullBase()->getTimeStepEntry(iteration,order);
9549 const MEDFileIntField1TSWithoutSDA *myF1TSC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(&myF1TS);
9551 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::getFieldWithProfile : mismatch of type of field ! INT32 expected !");
9552 MEDCouplingAutoRefCountObjectPtr<DataArray> ret=myF1TSC->getFieldWithProfile(type,meshDimRelToMax,mesh,pfl,this,*contentNotNullBase());
9553 return MEDFileIntField1TS::ReturnSafelyDataArrayInt(ret);
9557 * Returns a new MEDFileIntField1TS holding data of a given time step of \a this field.
9558 * \param [in] pos - a time step id.
9559 * \return MEDFileIntField1TS * - a new instance of MEDFileIntField1TS. The caller is to
9560 * delete this field using decrRef() as it is no more needed.
9561 * \throw If \a pos is not a valid time step id.
9563 MEDFileAnyTypeField1TS *MEDFileIntFieldMultiTS::getTimeStepAtPos(int pos) const
9565 const MEDFileAnyTypeField1TSWithoutSDA *item=contentNotNullBase()->getTimeStepAtPos2(pos);
9568 std::ostringstream oss; oss << "MEDFileIntFieldMultiTS::getTimeStepAtPos : field at pos #" << pos << " is null !";
9569 throw INTERP_KERNEL::Exception(oss.str().c_str());
9571 const MEDFileIntField1TSWithoutSDA *itemC=dynamic_cast<const MEDFileIntField1TSWithoutSDA *>(item);
9574 MEDCouplingAutoRefCountObjectPtr<MEDFileIntField1TS> ret=MEDFileIntField1TS::New(*itemC,false);
9575 ret->shallowCpyGlobs(*this);
9578 std::ostringstream oss; oss << "MEDFileIntFieldMultiTS::getTimeStepAtPos : type of field at pos #" << pos << " is not INT32 !";
9579 throw INTERP_KERNEL::Exception(oss.str().c_str());
9583 * Adds a MEDCouplingFieldDouble to \a this as another time step. The underlying mesh of
9584 * the given field is checked if its elements are sorted suitable for writing to MED file
9585 * ("STB" stands for "Sort By Type"), if not, an exception is thrown.
9586 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9587 * \param [in] field - the field to add to \a this.
9588 * \throw If the name of \a field is empty.
9589 * \throw If the data array of \a field is not set.
9590 * \throw If existing time steps have different name or number of components than \a field.
9591 * \throw If the underlying mesh of \a field has no name.
9592 * \throw If elements in the mesh are not in the order suitable for writing to the MED file.
9594 void MEDFileIntFieldMultiTS::appendFieldNoProfileSBT(const MEDCouplingFieldDouble *field, const DataArrayInt *arrOfVals)
9596 contentNotNull()->appendFieldNoProfileSBT(field,arrOfVals,*this);
9600 * Adds a MEDCouplingFieldDouble to \a this as another time step.
9601 * The mesh support of input parameter \a field is ignored here, it can be NULL.
9602 * The support of field \a field is expected to be those computed with the input parameter \a mesh, \a meshDimRelToMax,
9605 * This method will check that the field based on the computed support is coherent. If not an exception will be thrown.
9606 * A new profile is added only if no equal profile is missing.
9607 * For more info, see \ref AdvMEDLoaderAPIFieldRW
9608 * \param [in] field - the field to add to \a this. The field double values and mesh support are ignored.
9609 * \param [in] arrOfVals - the values of the field \a field used.
9610 * \param [in] mesh - the supporting mesh of \a field.
9611 * \param [in] meshDimRelToMax - a relative dimension of mesh entities \a field lies on (useless if field spatial discretization is ON_NODES).
9612 * \param [in] profile - ids of mesh entities on which corresponding field values lie.
9613 * \throw If either \a field or \a mesh or \a profile has an empty name.
9614 * \throw If there are no mesh entities of \a meshDimRelToMax dimension in \a mesh.
9615 * \throw If the data array of \a field is not set.
9616 * \throw If the data array of \a this is already allocated but has different number of
9617 * components than \a field.
9618 * \throw If elements in \a mesh are not in the order suitable for writing to the MED file.
9619 * \sa setFieldNoProfileSBT()
9621 void MEDFileIntFieldMultiTS::appendFieldProfile(const MEDCouplingFieldDouble *field, const DataArrayInt *arrOfVals, const MEDFileMesh *mesh, int meshDimRelToMax, const DataArrayInt *profile)
9623 contentNotNull()->appendFieldProfile(field,arrOfVals,mesh,meshDimRelToMax,profile,*this);
9626 const MEDFileIntFieldMultiTSWithoutSDA *MEDFileIntFieldMultiTS::contentNotNull() const
9628 const MEDFileAnyTypeFieldMultiTSWithoutSDA *pt(_content);
9630 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::contentNotNull : the content pointer is null !");
9631 const MEDFileIntFieldMultiTSWithoutSDA *ret=dynamic_cast<const MEDFileIntFieldMultiTSWithoutSDA *>(pt);
9633 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 !");
9637 MEDFileIntFieldMultiTSWithoutSDA *MEDFileIntFieldMultiTS::contentNotNull()
9639 MEDFileAnyTypeFieldMultiTSWithoutSDA *pt(_content);
9641 throw INTERP_KERNEL::Exception("MEDFileIntFieldMultiTS::contentNotNull : the non const content pointer is null !");
9642 MEDFileIntFieldMultiTSWithoutSDA *ret=dynamic_cast<MEDFileIntFieldMultiTSWithoutSDA *>(pt);
9644 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 !");
9648 MEDFileIntFieldMultiTS::MEDFileIntFieldMultiTS()
9650 _content=new MEDFileIntFieldMultiTSWithoutSDA;
9653 MEDFileIntFieldMultiTS::MEDFileIntFieldMultiTS(const MEDFileIntFieldMultiTSWithoutSDA& other, bool shallowCopyOfContent):MEDFileAnyTypeFieldMultiTS(other,shallowCopyOfContent)
9657 MEDFileIntFieldMultiTS::MEDFileIntFieldMultiTS(const std::string& fileName, bool loadAll, const MEDFileMeshes *ms)
9658 try:MEDFileAnyTypeFieldMultiTS(fileName,loadAll,ms)
9661 catch(INTERP_KERNEL::Exception& e)
9664 MEDFileIntFieldMultiTS::MEDFileIntFieldMultiTS(const std::string& fileName, const std::string& fieldName, bool loadAll, const MEDFileMeshes *ms)
9665 try:MEDFileAnyTypeFieldMultiTS(fileName,fieldName,loadAll,ms)
9668 catch(INTERP_KERNEL::Exception& e)
9671 DataArrayInt *MEDFileIntFieldMultiTS::getUndergroundDataArray(int iteration, int order) const
9673 return static_cast<DataArrayInt *>(contentNotNull()->getUndergroundDataArray(iteration,order));
9678 MEDFileFields *MEDFileFields::New()
9680 return new MEDFileFields;
9683 MEDFileFields *MEDFileFields::New(const std::string& fileName, bool loadAll)
9685 return new MEDFileFields(fileName,loadAll,0);
9688 MEDFileFields *MEDFileFields::LoadPartOf(const std::string& fileName, bool loadAll, const MEDFileMeshes *ms)
9690 return new MEDFileFields(fileName,loadAll,ms);
9693 std::size_t MEDFileFields::getHeapMemorySizeWithoutChildren() const
9695 std::size_t ret(MEDFileFieldGlobsReal::getHeapMemorySizeWithoutChildren());
9696 ret+=_fields.capacity()*sizeof(MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA>);
9700 std::vector<const BigMemoryObject *> MEDFileFields::getDirectChildrenWithNull() const
9702 std::vector<const BigMemoryObject *> ret;
9703 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9704 ret.push_back((const MEDFileAnyTypeFieldMultiTSWithoutSDA *)*it);
9708 MEDFileFields *MEDFileFields::deepCpy() const
9710 MEDCouplingAutoRefCountObjectPtr<MEDFileFields> ret=shallowCpy();
9712 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++,i++)
9714 if((const MEDFileAnyTypeFieldMultiTSWithoutSDA*)*it)
9715 ret->_fields[i]=(*it)->deepCpy();
9717 ret->deepCpyGlobs(*this);
9721 MEDFileFields *MEDFileFields::shallowCpy() const
9723 return new MEDFileFields(*this);
9727 * 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
9728 * 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.
9729 * If \a areThereSomeForgottenTS is set to true, only the sorted intersection of time steps present for all fields in \a this will be returned.
9731 * \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.
9732 * \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.
9734 * \sa MEDFileFields::partOfThisLyingOnSpecifiedTimeSteps, MEDFileFields::partOfThisNotLyingOnSpecifiedTimeSteps
9736 std::vector< std::pair<int,int> > MEDFileFields::getCommonIterations(bool& areThereSomeForgottenTS) const
9738 std::set< std::pair<int,int> > s;
9739 bool firstShot=true;
9740 areThereSomeForgottenTS=false;
9741 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9743 if(!(const MEDFileAnyTypeFieldMultiTSWithoutSDA*)*it)
9745 std::vector< std::pair<int,int> > v=(*it)->getIterations();
9746 std::set< std::pair<int,int> > s1; std::copy(v.begin(),v.end(),std::inserter(s1,s1.end()));
9748 { s=s1; firstShot=false; }
9751 std::set< std::pair<int,int> > s2; std::set_intersection(s.begin(),s.end(),s1.begin(),s1.end(),std::inserter(s2,s2.end()));
9753 areThereSomeForgottenTS=true;
9757 std::vector< std::pair<int,int> > ret;
9758 std::copy(s.begin(),s.end(),std::back_insert_iterator< std::vector< std::pair<int,int> > >(ret));
9762 int MEDFileFields::getNumberOfFields() const
9764 return _fields.size();
9767 std::vector<std::string> MEDFileFields::getFieldsNames() const
9769 std::vector<std::string> ret(_fields.size());
9771 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++,i++)
9773 const MEDFileAnyTypeFieldMultiTSWithoutSDA *f=(*it);
9776 ret[i]=f->getName();
9780 std::ostringstream oss; oss << "MEDFileFields::getFieldsNames : At rank #" << i << " field is not defined !";
9781 throw INTERP_KERNEL::Exception(oss.str().c_str());
9787 std::vector<std::string> MEDFileFields::getMeshesNames() const
9789 std::vector<std::string> ret;
9790 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9792 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur(*it);
9794 ret.push_back(cur->getMeshName());
9799 std::string MEDFileFields::simpleRepr() const
9801 std::ostringstream oss;
9802 oss << "(*****************)\n(* MEDFileFields *)\n(*****************)\n\n";
9807 void MEDFileFields::simpleRepr(int bkOffset, std::ostream& oss) const
9809 int nbOfFields=getNumberOfFields();
9810 std::string startLine(bkOffset,' ');
9811 oss << startLine << "There are " << nbOfFields << " fields in this :" << std::endl;
9813 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++,i++)
9815 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur=(*it);
9818 oss << startLine << " - # "<< i << " has the following name : \"" << cur->getName() << "\"." << std::endl;
9822 oss << startLine << " - not defined !" << std::endl;
9826 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++,i++)
9828 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur=(*it);
9829 std::string chapter(17,'0'+i);
9830 oss << startLine << chapter << std::endl;
9833 cur->simpleRepr(bkOffset+2,oss,i);
9837 oss << startLine << " - not defined !" << std::endl;
9839 oss << startLine << chapter << std::endl;
9841 simpleReprGlobs(oss);
9844 MEDFileFields::MEDFileFields()
9848 MEDFileFields::MEDFileFields(const std::string& fileName, bool loadAll, const MEDFileMeshes *ms)
9849 try:MEDFileFieldGlobsReal(fileName)
9851 MEDFileUtilities::CheckFileForRead(fileName);
9852 MEDFileUtilities::AutoFid fid(MEDfileOpen(fileName.c_str(),MED_ACC_RDONLY));
9853 int nbFields(MEDnField(fid));
9854 _fields.resize(nbFields);
9855 med_field_type typcha;
9856 for(int i=0;i<nbFields;i++)
9858 std::vector<std::string> infos;
9859 std::string fieldName,dtunit;
9860 int nbOfStep(MEDFileAnyTypeField1TS::LocateField2(fid,fileName,i,false,fieldName,typcha,infos,dtunit));
9865 _fields[i]=MEDFileFieldMultiTSWithoutSDA::New(fid,fieldName.c_str(),typcha,infos,nbOfStep,dtunit,loadAll,ms);
9870 _fields[i]=MEDFileIntFieldMultiTSWithoutSDA::New(fid,fieldName.c_str(),typcha,infos,nbOfStep,dtunit,loadAll,ms);
9875 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] !";
9876 throw INTERP_KERNEL::Exception(oss.str().c_str());
9880 loadAllGlobals(fid);
9882 catch(INTERP_KERNEL::Exception& e)
9887 void MEDFileFields::writeLL(med_idt fid) const
9890 writeGlobals(fid,*this);
9891 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++,i++)
9893 const MEDFileAnyTypeFieldMultiTSWithoutSDA *elt=*it;
9896 std::ostringstream oss; oss << "MEDFileFields::write : at rank #" << i << "/" << _fields.size() << " field is empty !";
9897 throw INTERP_KERNEL::Exception(oss.str().c_str());
9899 elt->writeLL(fid,*this);
9903 void MEDFileFields::write(const std::string& fileName, int mode) const
9905 med_access_mode medmod=MEDFileUtilities::TraduceWriteMode(mode);
9906 MEDFileUtilities::AutoFid fid(MEDfileOpen(fileName.c_str(),medmod));
9911 * This method alloc the arrays and load potentially huge arrays contained in this field.
9912 * This method should be called when a MEDFileAnyTypeFieldMultiTS::New constructor has been with false as the last parameter.
9913 * This method can be also called to refresh or reinit values from a file.
9915 * \throw If the fileName is not set or points to a non readable MED file.
9917 void MEDFileFields::loadArrays()
9919 if(getFileName().empty())
9920 throw INTERP_KERNEL::Exception("MEDFileFields::loadArrays : the structure does not come from a file !");
9921 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
9922 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::iterator it=_fields.begin();it!=_fields.end();it++)
9924 MEDFileAnyTypeFieldMultiTSWithoutSDA *elt(*it);
9926 elt->loadBigArraysRecursively(fid,*elt);
9931 * This method behaves as MEDFileFields::loadArrays does, the first call, if \a this was built using a file without loading big arrays.
9932 * But once data loaded once, this method does nothing.
9934 * \throw If the fileName is not set or points to a non readable MED file.
9935 * \sa MEDFileFields::loadArrays, MEDFileFields::unloadArrays
9937 void MEDFileFields::loadArraysIfNecessary()
9939 if(!getFileName().empty())
9941 MEDFileUtilities::AutoFid fid=MEDfileOpen(getFileName().c_str(),MED_ACC_RDONLY);
9942 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::iterator it=_fields.begin();it!=_fields.end();it++)
9944 MEDFileAnyTypeFieldMultiTSWithoutSDA *elt(*it);
9946 elt->loadBigArraysRecursivelyIfNecessary(fid,*elt);
9952 * This method releases potentially big data arrays and so returns to the same heap memory than status loaded with 'loadAll' parameter set to false.
9953 * \b WARNING, this method does release arrays even if \a this does not come from a load of a MED file.
9954 * So this method can lead to a loss of data. If you want to unload arrays safely call MEDFileFields::unloadArraysWithoutDataLoss instead.
9956 * \sa MEDFileFields::loadArrays, MEDFileFields::loadArraysIfNecessary, MEDFileFields::unloadArraysWithoutDataLoss
9958 void MEDFileFields::unloadArrays()
9960 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::iterator it=_fields.begin();it!=_fields.end();it++)
9962 MEDFileAnyTypeFieldMultiTSWithoutSDA *elt(*it);
9964 elt->unloadArrays();
9969 * This method potentially releases big data arrays if \a this is coming from a file. If \a this has been built from scratch this method will have no effect.
9970 * This method is the symetrical method of MEDFileFields::loadArraysIfNecessary.
9971 * This method is useful to reduce \b safely amount of heap memory necessary for \a this by using MED file as database.
9973 * \sa MEDFileFields::loadArraysIfNecessary
9975 void MEDFileFields::unloadArraysWithoutDataLoss()
9977 if(!getFileName().empty())
9981 std::vector<std::string> MEDFileFields::getPflsReallyUsed() const
9983 std::vector<std::string> ret;
9984 std::set<std::string> ret2;
9985 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::const_iterator it=_fields.begin();it!=_fields.end();it++)
9987 std::vector<std::string> tmp=(*it)->getPflsReallyUsed2();
9988 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
9989 if(ret2.find(*it2)==ret2.end())
9991 ret.push_back(*it2);
9998 std::vector<std::string> MEDFileFields::getLocsReallyUsed() const
10000 std::vector<std::string> ret;
10001 std::set<std::string> ret2;
10002 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::const_iterator it=_fields.begin();it!=_fields.end();it++)
10004 std::vector<std::string> tmp=(*it)->getLocsReallyUsed2();
10005 for(std::vector<std::string>::const_iterator it2=tmp.begin();it2!=tmp.end();it2++)
10006 if(ret2.find(*it2)==ret2.end())
10008 ret.push_back(*it2);
10015 std::vector<std::string> MEDFileFields::getPflsReallyUsedMulti() const
10017 std::vector<std::string> ret;
10018 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::const_iterator it=_fields.begin();it!=_fields.end();it++)
10020 std::vector<std::string> tmp=(*it)->getPflsReallyUsedMulti2();
10021 ret.insert(ret.end(),tmp.begin(),tmp.end());
10026 std::vector<std::string> MEDFileFields::getLocsReallyUsedMulti() const
10028 std::vector<std::string> ret;
10029 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::const_iterator it=_fields.begin();it!=_fields.end();it++)
10031 std::vector<std::string> tmp=(*it)->getLocsReallyUsed2();
10032 ret.insert(ret.end(),tmp.begin(),tmp.end());
10037 void MEDFileFields::changePflsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
10039 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::iterator it=_fields.begin();it!=_fields.end();it++)
10040 (*it)->changePflsRefsNamesGen2(mapOfModif);
10043 void MEDFileFields::changeLocsRefsNamesGen(const std::vector< std::pair<std::vector<std::string>, std::string > >& mapOfModif)
10045 for(std::vector< MEDCouplingAutoRefCountObjectPtr< MEDFileAnyTypeFieldMultiTSWithoutSDA > >::iterator it=_fields.begin();it!=_fields.end();it++)
10046 (*it)->changeLocsRefsNamesGen2(mapOfModif);
10049 void MEDFileFields::resize(int newSize)
10051 _fields.resize(newSize);
10054 void MEDFileFields::pushFields(const std::vector<MEDFileAnyTypeFieldMultiTS *>& fields)
10056 for(std::vector<MEDFileAnyTypeFieldMultiTS *>::const_iterator it=fields.begin();it!=fields.end();it++)
10060 void MEDFileFields::pushField(MEDFileAnyTypeFieldMultiTS *field)
10063 throw INTERP_KERNEL::Exception("MEDFileFields::pushMesh : invalid input pointer ! should be different from 0 !");
10064 _fields.push_back(field->getContent());
10065 appendGlobs(*field,1e-12);
10068 void MEDFileFields::setFieldAtPos(int i, MEDFileAnyTypeFieldMultiTS *field)
10071 throw INTERP_KERNEL::Exception("MEDFileFields::setFieldAtPos : invalid input pointer ! should be different from 0 !");
10072 if(i>=(int)_fields.size())
10073 _fields.resize(i+1);
10074 _fields[i]=field->getContent();
10075 appendGlobs(*field,1e-12);
10078 void MEDFileFields::destroyFieldAtPos(int i)
10080 destroyFieldsAtPos(&i,&i+1);
10083 void MEDFileFields::destroyFieldsAtPos(const int *startIds, const int *endIds)
10085 std::vector<bool> b(_fields.size(),true);
10086 for(const int *i=startIds;i!=endIds;i++)
10088 if(*i<0 || *i>=(int)_fields.size())
10090 std::ostringstream oss; oss << "MEDFileFields::destroyFieldsAtPos : Invalid given id in input (" << *i << ") should be in [0," << _fields.size() << ") !";
10091 throw INTERP_KERNEL::Exception(oss.str().c_str());
10095 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > fields(std::count(b.begin(),b.end(),true));
10097 for(std::size_t i=0;i<_fields.size();i++)
10099 fields[j++]=_fields[i];
10103 void MEDFileFields::destroyFieldsAtPos2(int bg, int end, int step)
10105 static const char msg[]="MEDFileFields::destroyFieldsAtPos2";
10106 int nbOfEntriesToKill=DataArrayInt::GetNumberOfItemGivenBESRelative(bg,end,step,msg);
10107 std::vector<bool> b(_fields.size(),true);
10109 for(int i=0;i<nbOfEntriesToKill;i++,k+=step)
10111 if(k<0 || k>=(int)_fields.size())
10113 std::ostringstream oss; oss << "MEDFileFields::destroyFieldsAtPos2 : Invalid given id in input (" << k << ") should be in [0," << _fields.size() << ") !";
10114 throw INTERP_KERNEL::Exception(oss.str().c_str());
10118 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > fields(std::count(b.begin(),b.end(),true));
10120 for(std::size_t i=0;i<_fields.size();i++)
10122 fields[j++]=_fields[i];
10126 bool MEDFileFields::changeMeshNames(const std::vector< std::pair<std::string,std::string> >& modifTab)
10129 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::iterator it=_fields.begin();it!=_fields.end();it++)
10131 MEDFileAnyTypeFieldMultiTSWithoutSDA *cur(*it);
10133 ret=cur->changeMeshNames(modifTab) || ret;
10139 * \param [in] meshName the name of the mesh that will be renumbered.
10140 * \param [in] oldCode is of format returned by MEDCouplingUMesh::getDistributionOfTypes. And for each *i* oldCode[3*i+2] gives the position (MEDFileUMesh::PutInThirdComponentOfCodeOffset).
10141 * This code corresponds to the distribution of types in the corresponding mesh.
10142 * \param [in] newCode idem to param \a oldCode except that here the new distribution is given.
10143 * \param [in] renumO2N the old to new renumber array.
10144 * \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
10145 * field in \a this.
10147 bool MEDFileFields::renumberEntitiesLyingOnMesh(const std::string& meshName, const std::vector<int>& oldCode, const std::vector<int>& newCode, const DataArrayInt *renumO2N)
10150 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::iterator it=_fields.begin();it!=_fields.end();it++)
10152 MEDFileAnyTypeFieldMultiTSWithoutSDA *fmts(*it);
10155 ret=fmts->renumberEntitiesLyingOnMesh(meshName,oldCode,newCode,renumO2N,*this) || ret;
10161 MEDFileAnyTypeFieldMultiTS *MEDFileFields::getFieldAtPos(int i) const
10163 if(i<0 || i>=(int)_fields.size())
10165 std::ostringstream oss; oss << "MEDFileFields::getFieldAtPos : Invalid given id in input (" << i << ") should be in [0," << _fields.size() << ") !";
10166 throw INTERP_KERNEL::Exception(oss.str().c_str());
10168 const MEDFileAnyTypeFieldMultiTSWithoutSDA *fmts=_fields[i];
10171 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTS> ret;
10172 const MEDFileFieldMultiTSWithoutSDA *fmtsC=dynamic_cast<const MEDFileFieldMultiTSWithoutSDA *>(fmts);
10173 const MEDFileIntFieldMultiTSWithoutSDA *fmtsC2=dynamic_cast<const MEDFileIntFieldMultiTSWithoutSDA *>(fmts);
10175 ret=MEDFileFieldMultiTS::New(*fmtsC,false);
10177 ret=MEDFileIntFieldMultiTS::New(*fmtsC2,false);
10180 std::ostringstream oss; oss << "MEDFileFields::getFieldAtPos : At pos #" << i << " field is neither double (FLOAT64) nor integer (INT32) !";
10181 throw INTERP_KERNEL::Exception(oss.str().c_str());
10183 ret->shallowCpyGlobs(*this);
10188 * Return a shallow copy of \a this reduced to the fields ids defined in [ \a startIds , endIds ).
10189 * This method is accessible in python using __getitem__ with a list in input.
10190 * \return a new object that the caller should deal with.
10192 MEDFileFields *MEDFileFields::buildSubPart(const int *startIds, const int *endIds) const
10194 MEDCouplingAutoRefCountObjectPtr<MEDFileFields> ret=shallowCpy();
10195 std::size_t sz=std::distance(startIds,endIds);
10196 std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > fields(sz);
10198 for(const int *i=startIds;i!=endIds;i++,j++)
10200 if(*i<0 || *i>=(int)_fields.size())
10202 std::ostringstream oss; oss << "MEDFileFields::buildSubPart : Invalid given id in input (" << *i << ") should be in [0," << _fields.size() << ") !";
10203 throw INTERP_KERNEL::Exception(oss.str().c_str());
10205 fields[j]=_fields[*i];
10207 ret->_fields=fields;
10211 MEDFileAnyTypeFieldMultiTS *MEDFileFields::getFieldWithName(const std::string& fieldName) const
10213 return getFieldAtPos(getPosFromFieldName(fieldName));
10217 * This method removes, if any, fields in \a this having no time steps.
10218 * If there is one or more than one such field in \a this true is returned and those fields will not be referenced anymore in \a this.
10220 * If false is returned \a this does not contain such fields. If false is returned this method can be considered as const.
10222 bool MEDFileFields::removeFieldsWithoutAnyTimeStep()
10224 std::vector<MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> > newFields;
10225 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
10227 const MEDFileAnyTypeFieldMultiTSWithoutSDA *elt(*it);
10230 if(elt->getNumberOfTS()>0)
10231 newFields.push_back(*it);
10234 if(_fields.size()==newFields.size())
10241 * This method returns a new object containing part of \a this fields lying on mesh name specified by the input parameter \a meshName.
10242 * This method can be seen as a filter applied on \a this, that returns an object containing
10243 * 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
10244 * shallow copied from \a this.
10246 * \param [in] meshName - the name of the mesh on w
10247 * \return a new object that the caller should deal with.
10249 MEDFileFields *MEDFileFields::partOfThisLyingOnSpecifiedMeshName(const std::string& meshName) const
10251 MEDCouplingAutoRefCountObjectPtr<MEDFileFields> ret=MEDFileFields::New();
10252 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
10254 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur=(*it);
10257 if(cur->getMeshName()==meshName)
10260 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> cur2(const_cast<MEDFileAnyTypeFieldMultiTSWithoutSDA *>(cur));
10261 ret->_fields.push_back(cur2);
10264 ret->shallowCpyOnlyUsedGlobs(*this);
10269 * This method returns a new object containing part of \a this fields lying ** exactly ** on the time steps specified by input parameter \a timeSteps.
10270 * Input time steps are specified using a pair of integer (iteration, order).
10271 * 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,
10272 * but for each multitimestep only the time steps in \a timeSteps are kept.
10273 * Typically the input parameter \a timeSteps comes from the call of MEDFileFields::getCommonIterations.
10275 * The returned object points to shallow copy of elements in \a this.
10277 * \param [in] timeSteps - the time steps given by a vector of pair of integers (iteration,order)
10278 * \throw If there is a field in \a this that is \b not defined on a time step in the input \a timeSteps.
10279 * \sa MEDFileFields::getCommonIterations, MEDFileFields::partOfThisNotLyingOnSpecifiedTimeSteps
10281 MEDFileFields *MEDFileFields::partOfThisLyingOnSpecifiedTimeSteps(const std::vector< std::pair<int,int> >& timeSteps) const
10283 MEDCouplingAutoRefCountObjectPtr<MEDFileFields> ret=MEDFileFields::New();
10284 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
10286 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur=(*it);
10289 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> elt=cur->partOfThisLyingOnSpecifiedTimeSteps(timeSteps);
10290 ret->_fields.push_back(elt);
10292 ret->shallowCpyOnlyUsedGlobs(*this);
10297 * \sa MEDFileFields::getCommonIterations, MEDFileFields::partOfThisLyingOnSpecifiedTimeSteps
10299 MEDFileFields *MEDFileFields::partOfThisNotLyingOnSpecifiedTimeSteps(const std::vector< std::pair<int,int> >& timeSteps) const
10301 MEDCouplingAutoRefCountObjectPtr<MEDFileFields> ret=MEDFileFields::New();
10302 for(std::vector< MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> >::const_iterator it=_fields.begin();it!=_fields.end();it++)
10304 const MEDFileAnyTypeFieldMultiTSWithoutSDA *cur=(*it);
10307 MEDCouplingAutoRefCountObjectPtr<MEDFileAnyTypeFieldMultiTSWithoutSDA> elt=cur->partOfThisNotLyingOnSpecifiedTimeSteps(timeSteps);
10308 if(elt->getNumberOfTS()!=0)
10309 ret->_fields.push_back(elt);
10311 ret->shallowCpyOnlyUsedGlobs(*this);
10315 MEDFileFieldsIterator *MEDFileFields::iterator()
10317 return new MEDFileFieldsIterator(this);
10320 int MEDFileFields::getPosFromFieldName(const std::string& fieldName) const
10322 std::string tmp(fieldName);
10323 std::vector<std::string> poss;
10324 for(std::size_t i=0;i<_fields.size();i++)
10326 const MEDFileAnyTypeFieldMultiTSWithoutSDA *f=_fields[i];
10329 std::string fname(f->getName());
10333 poss.push_back(fname);
10336 std::ostringstream oss; oss << "MEDFileFields::getPosFromFieldName : impossible to find field '" << tmp << "' in this ! Possibilities are : ";
10337 std::copy(poss.begin(),poss.end(),std::ostream_iterator<std::string>(oss,", "));
10339 throw INTERP_KERNEL::Exception(oss.str().c_str());
10342 MEDFileFieldsIterator::MEDFileFieldsIterator(MEDFileFields *fs):_fs(fs),_iter_id(0),_nb_iter(0)
10347 _nb_iter=fs->getNumberOfFields();
10351 MEDFileFieldsIterator::~MEDFileFieldsIterator()
10355 MEDFileAnyTypeFieldMultiTS *MEDFileFieldsIterator::nextt()
10357 if(_iter_id<_nb_iter)
10359 MEDFileFields *fs(_fs);
10361 return fs->getFieldAtPos(_iter_id++);