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 "MEDCouplingMemArray.txx"
22 #include "MEDCouplingAutoRefCountObjectPtr.hxx"
25 #include "GenMathFormulae.hxx"
26 #include "InterpKernelAutoPtr.hxx"
27 #include "InterpKernelExprParser.hxx"
36 typedef double (*MYFUNCPTR)(double);
38 using namespace ParaMEDMEM;
40 template<int SPACEDIM>
41 void DataArrayDouble::findCommonTuplesAlg(const double *bbox, int nbNodes, int limitNodeId, double prec, DataArrayInt *c, DataArrayInt *cI) const
43 const double *coordsPtr=getConstPointer();
44 BBTreePts<SPACEDIM,int> myTree(bbox,0,0,nbNodes,prec);
45 std::vector<bool> isDone(nbNodes);
46 for(int i=0;i<nbNodes;i++)
50 std::vector<int> intersectingElems;
51 myTree.getElementsAroundPoint(coordsPtr+i*SPACEDIM,intersectingElems);
52 if(intersectingElems.size()>1)
54 std::vector<int> commonNodes;
55 for(std::vector<int>::const_iterator it=intersectingElems.begin();it!=intersectingElems.end();it++)
59 commonNodes.push_back(*it);
62 if(!commonNodes.empty())
64 cI->pushBackSilent(cI->back()+(int)commonNodes.size()+1);
66 c->insertAtTheEnd(commonNodes.begin(),commonNodes.end());
73 template<int SPACEDIM>
74 void DataArrayDouble::FindTupleIdsNearTuplesAlg(const BBTreePts<SPACEDIM,int>& myTree, const double *pos, int nbOfTuples, double eps,
75 DataArrayInt *c, DataArrayInt *cI)
77 for(int i=0;i<nbOfTuples;i++)
79 std::vector<int> intersectingElems;
80 myTree.getElementsAroundPoint(pos+i*SPACEDIM,intersectingElems);
81 std::vector<int> commonNodes;
82 for(std::vector<int>::const_iterator it=intersectingElems.begin();it!=intersectingElems.end();it++)
83 commonNodes.push_back(*it);
84 cI->pushBackSilent(cI->back()+(int)commonNodes.size());
85 c->insertAtTheEnd(commonNodes.begin(),commonNodes.end());
89 template<int SPACEDIM>
90 void DataArrayDouble::FindClosestTupleIdAlg(const BBTreePts<SPACEDIM,int>& myTree, double dist, const double *pos, int nbOfTuples, const double *thisPt, int thisNbOfTuples, int *res)
95 for(int i=0;i<nbOfTuples;i++,p+=SPACEDIM,r++)
100 double ret=myTree.getElementsAroundPoint2(p,distOpt,elem);
101 if(ret!=std::numeric_limits<double>::max())
103 distOpt=std::max(ret,1e-4);
108 { distOpt=2*distOpt; continue; }
113 std::size_t DataArray::getHeapMemorySizeWithoutChildren() const
115 std::size_t sz1=_name.capacity();
116 std::size_t sz2=_info_on_compo.capacity();
118 for(std::vector<std::string>::const_iterator it=_info_on_compo.begin();it!=_info_on_compo.end();it++)
119 sz3+=(*it).capacity();
123 std::vector<const BigMemoryObject *> DataArray::getDirectChildrenWithNull() const
125 return std::vector<const BigMemoryObject *>();
129 * Sets the attribute \a _name of \a this array.
130 * See \ref MEDCouplingArrayBasicsName "DataArrays infos" for more information.
131 * \param [in] name - new array name
133 void DataArray::setName(const std::string& name)
139 * Copies textual data from an \a other DataArray. The copied data are
140 * - the name attribute,
141 * - the information of components.
143 * For more information on these data see \ref MEDCouplingArrayBasicsName "DataArrays infos".
145 * \param [in] other - another instance of DataArray to copy the textual data from.
146 * \throw If number of components of \a this array differs from that of the \a other.
148 void DataArray::copyStringInfoFrom(const DataArray& other)
150 if(_info_on_compo.size()!=other._info_on_compo.size())
151 throw INTERP_KERNEL::Exception("Size of arrays mismatches on copyStringInfoFrom !");
153 _info_on_compo=other._info_on_compo;
156 void DataArray::copyPartOfStringInfoFrom(const DataArray& other, const std::vector<int>& compoIds)
158 int nbOfCompoOth=other.getNumberOfComponents();
159 std::size_t newNbOfCompo=compoIds.size();
160 for(std::size_t i=0;i<newNbOfCompo;i++)
161 if(compoIds[i]>=nbOfCompoOth || compoIds[i]<0)
163 std::ostringstream oss; oss << "Specified component id is out of range (" << compoIds[i] << ") compared with nb of actual components (" << nbOfCompoOth << ")";
164 throw INTERP_KERNEL::Exception(oss.str().c_str());
166 for(std::size_t i=0;i<newNbOfCompo;i++)
167 setInfoOnComponent((int)i,other.getInfoOnComponent(compoIds[i]));
170 void DataArray::copyPartOfStringInfoFrom2(const std::vector<int>& compoIds, const DataArray& other)
172 int nbOfCompo=getNumberOfComponents();
173 std::size_t partOfCompoToSet=compoIds.size();
174 if((int)partOfCompoToSet!=other.getNumberOfComponents())
175 throw INTERP_KERNEL::Exception("Given compoIds has not the same size as number of components of given array !");
176 for(std::size_t i=0;i<partOfCompoToSet;i++)
177 if(compoIds[i]>=nbOfCompo || compoIds[i]<0)
179 std::ostringstream oss; oss << "Specified component id is out of range (" << compoIds[i] << ") compared with nb of actual components (" << nbOfCompo << ")";
180 throw INTERP_KERNEL::Exception(oss.str().c_str());
182 for(std::size_t i=0;i<partOfCompoToSet;i++)
183 setInfoOnComponent(compoIds[i],other.getInfoOnComponent((int)i));
186 bool DataArray::areInfoEqualsIfNotWhy(const DataArray& other, std::string& reason) const
188 std::ostringstream oss;
189 if(_name!=other._name)
191 oss << "Names DataArray mismatch : this name=\"" << _name << " other name=\"" << other._name << "\" !";
195 if(_info_on_compo!=other._info_on_compo)
197 oss << "Components DataArray mismatch : \nThis components=";
198 for(std::vector<std::string>::const_iterator it=_info_on_compo.begin();it!=_info_on_compo.end();it++)
199 oss << "\"" << *it << "\",";
200 oss << "\nOther components=";
201 for(std::vector<std::string>::const_iterator it=other._info_on_compo.begin();it!=other._info_on_compo.end();it++)
202 oss << "\"" << *it << "\",";
210 * Compares textual information of \a this DataArray with that of an \a other one.
211 * The compared data are
212 * - the name attribute,
213 * - the information of components.
215 * For more information on these data see \ref MEDCouplingArrayBasicsName "DataArrays infos".
216 * \param [in] other - another instance of DataArray to compare the textual data of.
217 * \return bool - \a true if the textual information is same, \a false else.
219 bool DataArray::areInfoEquals(const DataArray& other) const
222 return areInfoEqualsIfNotWhy(other,tmp);
225 void DataArray::reprWithoutNameStream(std::ostream& stream) const
227 stream << "Number of components : "<< getNumberOfComponents() << "\n";
228 stream << "Info of these components : ";
229 for(std::vector<std::string>::const_iterator iter=_info_on_compo.begin();iter!=_info_on_compo.end();iter++)
230 stream << "\"" << *iter << "\" ";
234 std::string DataArray::cppRepr(const std::string& varName) const
236 std::ostringstream ret;
237 reprCppStream(varName,ret);
242 * Sets information on all components. To know more on format of this information
243 * see \ref MEDCouplingArrayBasicsCompoName "DataArrays infos".
244 * \param [in] info - a vector of strings.
245 * \throw If size of \a info differs from the number of components of \a this.
247 void DataArray::setInfoOnComponents(const std::vector<std::string>& info)
249 if(getNumberOfComponents()!=(int)info.size())
251 std::ostringstream oss; oss << "DataArray::setInfoOnComponents : input is of size " << info.size() << " whereas number of components is equal to " << getNumberOfComponents() << " !";
252 throw INTERP_KERNEL::Exception(oss.str().c_str());
258 * This method is only a dispatcher towards DataArrayDouble::setPartOfValues3, DataArrayInt::setPartOfValues3, DataArrayChar::setPartOfValues3 depending on the true
259 * type of \a this and \a aBase.
261 * \throw If \a aBase and \a this do not have the same type.
263 * \sa DataArrayDouble::setPartOfValues3, DataArrayInt::setPartOfValues3, DataArrayChar::setPartOfValues3.
265 void DataArray::setPartOfValuesBase3(const DataArray *aBase, const int *bgTuples, const int *endTuples, int bgComp, int endComp, int stepComp, bool strictCompoCompare)
268 throw INTERP_KERNEL::Exception("DataArray::setPartOfValuesBase3 : input aBase object is NULL !");
269 DataArrayDouble *this1(dynamic_cast<DataArrayDouble *>(this));
270 DataArrayInt *this2(dynamic_cast<DataArrayInt *>(this));
271 DataArrayChar *this3(dynamic_cast<DataArrayChar *>(this));
272 const DataArrayDouble *a1(dynamic_cast<const DataArrayDouble *>(aBase));
273 const DataArrayInt *a2(dynamic_cast<const DataArrayInt *>(aBase));
274 const DataArrayChar *a3(dynamic_cast<const DataArrayChar *>(aBase));
277 this1->setPartOfValues3(a1,bgTuples,endTuples,bgComp,endComp,stepComp,strictCompoCompare);
282 this2->setPartOfValues3(a2,bgTuples,endTuples,bgComp,endComp,stepComp,strictCompoCompare);
287 this3->setPartOfValues3(a3,bgTuples,endTuples,bgComp,endComp,stepComp,strictCompoCompare);
290 throw INTERP_KERNEL::Exception("DataArray::setPartOfValuesBase3 : input aBase object and this do not have the same type !");
293 std::vector<std::string> DataArray::getVarsOnComponent() const
295 int nbOfCompo=(int)_info_on_compo.size();
296 std::vector<std::string> ret(nbOfCompo);
297 for(int i=0;i<nbOfCompo;i++)
298 ret[i]=getVarOnComponent(i);
302 std::vector<std::string> DataArray::getUnitsOnComponent() const
304 int nbOfCompo=(int)_info_on_compo.size();
305 std::vector<std::string> ret(nbOfCompo);
306 for(int i=0;i<nbOfCompo;i++)
307 ret[i]=getUnitOnComponent(i);
312 * Returns information on a component specified by an index.
313 * To know more on format of this information
314 * see \ref MEDCouplingArrayBasicsCompoName "DataArrays infos".
315 * \param [in] i - the index (zero based) of the component of interest.
316 * \return std::string - a string containing the information on \a i-th component.
317 * \throw If \a i is not a valid component index.
319 std::string DataArray::getInfoOnComponent(int i) const
321 if(i<(int)_info_on_compo.size() && i>=0)
322 return _info_on_compo[i];
325 std::ostringstream oss; oss << "DataArray::getInfoOnComponent : Specified component id is out of range (" << i << ") compared with nb of actual components (" << (int) _info_on_compo.size();
326 throw INTERP_KERNEL::Exception(oss.str().c_str());
331 * Returns the var part of the full information of the \a i-th component.
332 * For example, if \c getInfoOnComponent(0) returns "SIGXY [N/m^2]", then
333 * \c getVarOnComponent(0) returns "SIGXY".
334 * If a unit part of information is not detected by presence of
335 * two square brackets, then the full information is returned.
336 * To read more about the component information format, see
337 * \ref MEDCouplingArrayBasicsCompoName "DataArrays infos".
338 * \param [in] i - the index (zero based) of the component of interest.
339 * \return std::string - a string containing the var information, or the full info.
340 * \throw If \a i is not a valid component index.
342 std::string DataArray::getVarOnComponent(int i) const
344 if(i<(int)_info_on_compo.size() && i>=0)
346 return GetVarNameFromInfo(_info_on_compo[i]);
350 std::ostringstream oss; oss << "DataArray::getVarOnComponent : Specified component id is out of range (" << i << ") compared with nb of actual components (" << (int) _info_on_compo.size();
351 throw INTERP_KERNEL::Exception(oss.str().c_str());
356 * Returns the unit part of the full information of the \a i-th component.
357 * For example, if \c getInfoOnComponent(0) returns "SIGXY [ N/m^2]", then
358 * \c getUnitOnComponent(0) returns " N/m^2".
359 * If a unit part of information is not detected by presence of
360 * two square brackets, then an empty string is returned.
361 * To read more about the component information format, see
362 * \ref MEDCouplingArrayBasicsCompoName "DataArrays infos".
363 * \param [in] i - the index (zero based) of the component of interest.
364 * \return std::string - a string containing the unit information, if any, or "".
365 * \throw If \a i is not a valid component index.
367 std::string DataArray::getUnitOnComponent(int i) const
369 if(i<(int)_info_on_compo.size() && i>=0)
371 return GetUnitFromInfo(_info_on_compo[i]);
375 std::ostringstream oss; oss << "DataArray::getUnitOnComponent : Specified component id is out of range (" << i << ") compared with nb of actual components (" << (int) _info_on_compo.size();
376 throw INTERP_KERNEL::Exception(oss.str().c_str());
381 * Returns the var part of the full component information.
382 * For example, if \a info == "SIGXY [N/m^2]", then this method returns "SIGXY".
383 * If a unit part of information is not detected by presence of
384 * two square brackets, then the whole \a info is returned.
385 * To read more about the component information format, see
386 * \ref MEDCouplingArrayBasicsCompoName "DataArrays infos".
387 * \param [in] info - the full component information.
388 * \return std::string - a string containing only var information, or the \a info.
390 std::string DataArray::GetVarNameFromInfo(const std::string& info)
392 std::size_t p1=info.find_last_of('[');
393 std::size_t p2=info.find_last_of(']');
394 if(p1==std::string::npos || p2==std::string::npos)
399 return std::string();
400 std::size_t p3=info.find_last_not_of(' ',p1-1);
401 return info.substr(0,p3+1);
405 * Returns the unit part of the full component information.
406 * For example, if \a info == "SIGXY [ N/m^2]", then this method returns " N/m^2".
407 * If a unit part of information is not detected by presence of
408 * two square brackets, then an empty string is returned.
409 * To read more about the component information format, see
410 * \ref MEDCouplingArrayBasicsCompoName "DataArrays infos".
411 * \param [in] info - the full component information.
412 * \return std::string - a string containing only unit information, if any, or "".
414 std::string DataArray::GetUnitFromInfo(const std::string& info)
416 std::size_t p1=info.find_last_of('[');
417 std::size_t p2=info.find_last_of(']');
418 if(p1==std::string::npos || p2==std::string::npos)
419 return std::string();
421 return std::string();
422 return info.substr(p1+1,p2-p1-1);
426 * This method put in info format the result of the merge of \a var and \a unit.
427 * The standard format for that is "var [unit]".
428 * Inversely you can retrieve the var part or the unit part of info string using resp. GetVarNameFromInfo and GetUnitFromInfo.
430 std::string DataArray::BuildInfoFromVarAndUnit(const std::string& var, const std::string& unit)
432 std::ostringstream oss;
433 oss << var << " [" << unit << "]";
438 * Returns a new DataArray by concatenating all given arrays, so that (1) the number
439 * of tuples in the result array is a sum of the number of tuples of given arrays and (2)
440 * the number of component in the result array is same as that of each of given arrays.
441 * Info on components is copied from the first of the given arrays. Number of components
442 * in the given arrays must be the same.
443 * \param [in] arrs - a sequence of arrays to include in the result array. All arrays must have the same type.
444 * \return DataArray * - the new instance of DataArray (that can be either DataArrayInt, DataArrayDouble, DataArrayChar).
445 * The caller is to delete this result array using decrRef() as it is no more
447 * \throw If all arrays within \a arrs are NULL.
448 * \throw If all not null arrays in \a arrs have not the same type.
449 * \throw If getNumberOfComponents() of arrays within \a arrs.
451 DataArray *DataArray::Aggregate(const std::vector<const DataArray *>& arrs)
453 std::vector<const DataArray *> arr2;
454 for(std::vector<const DataArray *>::const_iterator it=arrs.begin();it!=arrs.end();it++)
458 throw INTERP_KERNEL::Exception("DataArray::Aggregate : only null instance in input vector !");
459 std::vector<const DataArrayDouble *> arrd;
460 std::vector<const DataArrayInt *> arri;
461 std::vector<const DataArrayChar *> arrc;
462 for(std::vector<const DataArray *>::const_iterator it=arr2.begin();it!=arr2.end();it++)
464 const DataArrayDouble *a=dynamic_cast<const DataArrayDouble *>(*it);
466 { arrd.push_back(a); continue; }
467 const DataArrayInt *b=dynamic_cast<const DataArrayInt *>(*it);
469 { arri.push_back(b); continue; }
470 const DataArrayChar *c=dynamic_cast<const DataArrayChar *>(*it);
472 { arrc.push_back(c); continue; }
473 throw INTERP_KERNEL::Exception("DataArray::Aggregate : presence of not null instance in inuput that is not in [DataArrayDouble, DataArrayInt, DataArrayChar] !");
475 if(arr2.size()==arrd.size())
476 return DataArrayDouble::Aggregate(arrd);
477 if(arr2.size()==arri.size())
478 return DataArrayInt::Aggregate(arri);
479 if(arr2.size()==arrc.size())
480 return DataArrayChar::Aggregate(arrc);
481 throw INTERP_KERNEL::Exception("DataArray::Aggregate : all input arrays must have the same type !");
485 * Sets information on a component specified by an index.
486 * To know more on format of this information
487 * see \ref MEDCouplingArrayBasicsCompoName "DataArrays infos".
488 * \warning Don't pass NULL as \a info!
489 * \param [in] i - the index (zero based) of the component of interest.
490 * \param [in] info - the string containing the information.
491 * \throw If \a i is not a valid component index.
493 void DataArray::setInfoOnComponent(int i, const std::string& info)
495 if(i<(int)_info_on_compo.size() && i>=0)
496 _info_on_compo[i]=info;
499 std::ostringstream oss; oss << "DataArray::setInfoOnComponent : Specified component id is out of range (" << i << ") compared with nb of actual components (" << (int) _info_on_compo.size();
500 throw INTERP_KERNEL::Exception(oss.str().c_str());
505 * Sets information on all components. This method can change number of components
506 * at certain conditions; if the conditions are not respected, an exception is thrown.
507 * The number of components can be changed in \a this only if \a this is not allocated.
508 * The condition of number of components must not be changed.
510 * To know more on format of the component information see
511 * \ref MEDCouplingArrayBasicsCompoName "DataArrays infos".
512 * \param [in] info - a vector of component infos.
513 * \throw If \a this->getNumberOfComponents() != \a info.size() && \a this->isAllocated()
515 void DataArray::setInfoAndChangeNbOfCompo(const std::vector<std::string>& info)
517 if(getNumberOfComponents()!=(int)info.size())
523 std::ostringstream oss; oss << "DataArray::setInfoAndChangeNbOfCompo : input is of size " << info.size() << " whereas number of components is equal to " << getNumberOfComponents() << " and this is already allocated !";
524 throw INTERP_KERNEL::Exception(oss.str().c_str());
531 void DataArray::checkNbOfTuples(int nbOfTuples, const std::string& msg) const
533 if(getNumberOfTuples()!=nbOfTuples)
535 std::ostringstream oss; oss << msg << " : mismatch number of tuples : expected " << nbOfTuples << " having " << getNumberOfTuples() << " !";
536 throw INTERP_KERNEL::Exception(oss.str().c_str());
540 void DataArray::checkNbOfComps(int nbOfCompo, const std::string& msg) const
542 if(getNumberOfComponents()!=nbOfCompo)
544 std::ostringstream oss; oss << msg << " : mismatch number of components : expected " << nbOfCompo << " having " << getNumberOfComponents() << " !";
545 throw INTERP_KERNEL::Exception(oss.str().c_str());
549 void DataArray::checkNbOfElems(std::size_t nbOfElems, const std::string& msg) const
551 if(getNbOfElems()!=nbOfElems)
553 std::ostringstream oss; oss << msg << " : mismatch number of elems : Expected " << nbOfElems << " having " << getNbOfElems() << " !";
554 throw INTERP_KERNEL::Exception(oss.str().c_str());
558 void DataArray::checkNbOfTuplesAndComp(const DataArray& other, const std::string& msg) const
560 if(getNumberOfTuples()!=other.getNumberOfTuples())
562 std::ostringstream oss; oss << msg << " : mismatch number of tuples : expected " << other.getNumberOfTuples() << " having " << getNumberOfTuples() << " !";
563 throw INTERP_KERNEL::Exception(oss.str().c_str());
565 if(getNumberOfComponents()!=other.getNumberOfComponents())
567 std::ostringstream oss; oss << msg << " : mismatch number of components : expected " << other.getNumberOfComponents() << " having " << getNumberOfComponents() << " !";
568 throw INTERP_KERNEL::Exception(oss.str().c_str());
572 void DataArray::checkNbOfTuplesAndComp(int nbOfTuples, int nbOfCompo, const std::string& msg) const
574 checkNbOfTuples(nbOfTuples,msg);
575 checkNbOfComps(nbOfCompo,msg);
579 * Simply this method checks that \b value is in [0,\b ref).
581 void DataArray::CheckValueInRange(int ref, int value, const std::string& msg)
583 if(value<0 || value>=ref)
585 std::ostringstream oss; oss << "DataArray::CheckValueInRange : " << msg << " ! Expected in range [0," << ref << "[ having " << value << " !";
586 throw INTERP_KERNEL::Exception(oss.str().c_str());
591 * This method checks that [\b start, \b end) is compliant with ref length \b value.
592 * typicaly start in [0,\b value) and end in [0,\b value). If value==start and start==end, it is supported.
594 void DataArray::CheckValueInRangeEx(int value, int start, int end, const std::string& msg)
596 if(start<0 || start>=value)
598 if(value!=start || end!=start)
600 std::ostringstream oss; oss << "DataArray::CheckValueInRangeEx : " << msg << " ! Expected start " << start << " of input range, in [0," << value << "[ !";
601 throw INTERP_KERNEL::Exception(oss.str().c_str());
604 if(end<0 || end>value)
606 std::ostringstream oss; oss << "DataArray::CheckValueInRangeEx : " << msg << " ! Expected end " << end << " of input range, in [0," << value << "] !";
607 throw INTERP_KERNEL::Exception(oss.str().c_str());
611 void DataArray::CheckClosingParInRange(int ref, int value, const std::string& msg)
613 if(value<0 || value>ref)
615 std::ostringstream oss; oss << "DataArray::CheckClosingParInRange : " << msg << " ! Expected input range in [0," << ref << "] having closing open parenthesis " << value << " !";
616 throw INTERP_KERNEL::Exception(oss.str().c_str());
621 * This method is useful to slice work among a pool of threads or processes. \a begin, \a end \a step is the input whole slice of work to perform,
622 * typically it is a whole slice of tuples of DataArray or cells, nodes of a mesh...
624 * The input \a sliceId should be an id in [0, \a nbOfSlices) that specifies the slice of work.
626 * \param [in] start - the start of the input slice of the whole work to perform splitted into slices.
627 * \param [in] stop - the stop of the input slice of the whole work to perform splitted into slices.
628 * \param [in] step - the step (that can be <0) of the input slice of the whole work to perform splitted into slices.
629 * \param [in] sliceId - the slice id considered
630 * \param [in] nbOfSlices - the number of slices (typically the number of cores on which the work is expected to be sliced)
631 * \param [out] startSlice - the start of the slice considered
632 * \param [out] stopSlice - the stop of the slice consided
634 * \throw If \a step == 0
635 * \throw If \a nbOfSlices not > 0
636 * \throw If \a sliceId not in [0,nbOfSlices)
638 void DataArray::GetSlice(int start, int stop, int step, int sliceId, int nbOfSlices, int& startSlice, int& stopSlice)
642 std::ostringstream oss; oss << "DataArray::GetSlice : nbOfSlices (" << nbOfSlices << ") must be > 0 !";
643 throw INTERP_KERNEL::Exception(oss.str().c_str());
645 if(sliceId<0 || sliceId>=nbOfSlices)
647 std::ostringstream oss; oss << "DataArray::GetSlice : sliceId (" << nbOfSlices << ") must be in [0 , nbOfSlices (" << nbOfSlices << ") ) !";
648 throw INTERP_KERNEL::Exception(oss.str().c_str());
650 int nbElems=GetNumberOfItemGivenBESRelative(start,stop,step,"DataArray::GetSlice");
651 int minNbOfElemsPerSlice=nbElems/nbOfSlices;
652 startSlice=start+minNbOfElemsPerSlice*step*sliceId;
653 if(sliceId<nbOfSlices-1)
654 stopSlice=start+minNbOfElemsPerSlice*step*(sliceId+1);
659 int DataArray::GetNumberOfItemGivenBES(int begin, int end, int step, const std::string& msg)
663 std::ostringstream oss; oss << msg << " : end before begin !";
664 throw INTERP_KERNEL::Exception(oss.str().c_str());
670 std::ostringstream oss; oss << msg << " : invalid step should be > 0 !";
671 throw INTERP_KERNEL::Exception(oss.str().c_str());
673 return (end-1-begin)/step+1;
676 int DataArray::GetNumberOfItemGivenBESRelative(int begin, int end, int step, const std::string& msg)
679 throw INTERP_KERNEL::Exception("DataArray::GetNumberOfItemGivenBES : step=0 is not allowed !");
680 if(end<begin && step>0)
682 std::ostringstream oss; oss << msg << " : end before begin whereas step is positive !";
683 throw INTERP_KERNEL::Exception(oss.str().c_str());
685 if(begin<end && step<0)
687 std::ostringstream oss; oss << msg << " : invalid step should be > 0 !";
688 throw INTERP_KERNEL::Exception(oss.str().c_str());
691 return (std::max(begin,end)-1-std::min(begin,end))/std::abs(step)+1;
696 int DataArray::GetPosOfItemGivenBESRelativeNoThrow(int value, int begin, int end, int step)
702 if(begin<=value && value<end)
704 if((value-begin)%step==0)
705 return (value-begin)/step;
714 if(begin>=value && value>end)
716 if((begin-value)%(-step)==0)
717 return (begin-value)/(-step);
730 * Returns a new instance of DataArrayDouble. The caller is to delete this array
731 * using decrRef() as it is no more needed.
733 DataArrayDouble *DataArrayDouble::New()
735 return new DataArrayDouble;
739 * Checks if raw data is allocated. Read more on the raw data
740 * in \ref MEDCouplingArrayBasicsTuplesAndCompo "DataArrays infos" for more information.
741 * \return bool - \a true if the raw data is allocated, \a false else.
743 bool DataArrayDouble::isAllocated() const
745 return getConstPointer()!=0;
749 * Checks if raw data is allocated and throws an exception if it is not the case.
750 * \throw If the raw data is not allocated.
752 void DataArrayDouble::checkAllocated() const
755 throw INTERP_KERNEL::Exception("DataArrayDouble::checkAllocated : Array is defined but not allocated ! Call alloc or setValues method first !");
759 * This method desallocated \a this without modification of informations relative to the components.
760 * After call of this method, DataArrayDouble::isAllocated will return false.
761 * If \a this is already not allocated, \a this is let unchanged.
763 void DataArrayDouble::desallocate()
768 std::size_t DataArrayDouble::getHeapMemorySizeWithoutChildren() const
770 std::size_t sz(_mem.getNbOfElemAllocated());
772 return DataArray::getHeapMemorySizeWithoutChildren()+sz;
776 * Returns the only one value in \a this, if and only if number of elements
777 * (nb of tuples * nb of components) is equal to 1, and that \a this is allocated.
778 * \return double - the sole value stored in \a this array.
779 * \throw If at least one of conditions stated above is not fulfilled.
781 double DataArrayDouble::doubleValue() const
785 if(getNbOfElems()==1)
787 return *getConstPointer();
790 throw INTERP_KERNEL::Exception("DataArrayDouble::doubleValue : DataArrayDouble instance is allocated but number of elements is not equal to 1 !");
793 throw INTERP_KERNEL::Exception("DataArrayDouble::doubleValue : DataArrayDouble instance is not allocated !");
797 * Checks the number of tuples.
798 * \return bool - \a true if getNumberOfTuples() == 0, \a false else.
799 * \throw If \a this is not allocated.
801 bool DataArrayDouble::empty() const
804 return getNumberOfTuples()==0;
808 * Returns a full copy of \a this. For more info on copying data arrays see
809 * \ref MEDCouplingArrayBasicsCopyDeep.
810 * \return DataArrayDouble * - a new instance of DataArrayDouble. The caller is to
811 * delete this array using decrRef() as it is no more needed.
813 DataArrayDouble *DataArrayDouble::deepCpy() const
815 return new DataArrayDouble(*this);
819 * Returns either a \a deep or \a shallow copy of this array. For more info see
820 * \ref MEDCouplingArrayBasicsCopyDeep and \ref MEDCouplingArrayBasicsCopyShallow.
821 * \param [in] dCpy - if \a true, a deep copy is returned, else, a shallow one.
822 * \return DataArrayDouble * - either a new instance of DataArrayDouble (if \a dCpy
823 * == \a true) or \a this instance (if \a dCpy == \a false).
825 DataArrayDouble *DataArrayDouble::performCpy(bool dCpy) const
832 return const_cast<DataArrayDouble *>(this);
837 * Copies all the data from another DataArrayDouble. For more info see
838 * \ref MEDCouplingArrayBasicsCopyDeepAssign.
839 * \param [in] other - another instance of DataArrayDouble to copy data from.
840 * \throw If the \a other is not allocated.
842 void DataArrayDouble::cpyFrom(const DataArrayDouble& other)
844 other.checkAllocated();
845 int nbOfTuples=other.getNumberOfTuples();
846 int nbOfComp=other.getNumberOfComponents();
847 allocIfNecessary(nbOfTuples,nbOfComp);
848 std::size_t nbOfElems=(std::size_t)nbOfTuples*nbOfComp;
849 double *pt=getPointer();
850 const double *ptI=other.getConstPointer();
851 for(std::size_t i=0;i<nbOfElems;i++)
853 copyStringInfoFrom(other);
857 * This method reserve nbOfElems elements in memory ( nbOfElems*8 bytes ) \b without impacting the number of tuples in \a this.
858 * If \a this has already been allocated, this method checks that \a this has only one component. If not an INTERP_KERNEL::Exception will be thrown.
859 * If \a this has not already been allocated, number of components is set to one.
860 * This method allows to reduce number of reallocations on invokation of DataArrayDouble::pushBackSilent and DataArrayDouble::pushBackValsSilent on \a this.
862 * \sa DataArrayDouble::pack, DataArrayDouble::pushBackSilent, DataArrayDouble::pushBackValsSilent
864 void DataArrayDouble::reserve(std::size_t nbOfElems)
866 int nbCompo=getNumberOfComponents();
869 _mem.reserve(nbOfElems);
873 _mem.reserve(nbOfElems);
874 _info_on_compo.resize(1);
877 throw INTERP_KERNEL::Exception("DataArrayDouble::reserve : not available for DataArrayDouble with number of components different than 1 !");
881 * This method adds at the end of \a this the single value \a val. This method do \b not update its time label to avoid useless incrementation
882 * of counter. So the caller is expected to call TimeLabel::declareAsNew on \a this at the end of the push session.
884 * \param [in] val the value to be added in \a this
885 * \throw If \a this has already been allocated with number of components different from one.
886 * \sa DataArrayDouble::pushBackValsSilent
888 void DataArrayDouble::pushBackSilent(double val)
890 int nbCompo=getNumberOfComponents();
895 _info_on_compo.resize(1);
899 throw INTERP_KERNEL::Exception("DataArrayDouble::pushBackSilent : not available for DataArrayDouble with number of components different than 1 !");
903 * This method adds at the end of \a this a serie of values [\c valsBg,\c valsEnd). This method do \b not update its time label to avoid useless incrementation
904 * of counter. So the caller is expected to call TimeLabel::declareAsNew on \a this at the end of the push session.
906 * \param [in] valsBg - an array of values to push at the end of \this.
907 * \param [in] valsEnd - specifies the end of the array \a valsBg, so that
908 * the last value of \a valsBg is \a valsEnd[ -1 ].
909 * \throw If \a this has already been allocated with number of components different from one.
910 * \sa DataArrayDouble::pushBackSilent
912 void DataArrayDouble::pushBackValsSilent(const double *valsBg, const double *valsEnd)
914 int nbCompo=getNumberOfComponents();
916 _mem.insertAtTheEnd(valsBg,valsEnd);
919 _info_on_compo.resize(1);
920 _mem.insertAtTheEnd(valsBg,valsEnd);
923 throw INTERP_KERNEL::Exception("DataArrayDouble::pushBackValsSilent : not available for DataArrayDouble with number of components different than 1 !");
927 * This method returns silently ( without updating time label in \a this ) the last value, if any and suppress it.
928 * \throw If \a this is already empty.
929 * \throw If \a this has number of components different from one.
931 double DataArrayDouble::popBackSilent()
933 if(getNumberOfComponents()==1)
934 return _mem.popBack();
936 throw INTERP_KERNEL::Exception("DataArrayDouble::popBackSilent : not available for DataArrayDouble with number of components different than 1 !");
940 * This method \b do \b not modify content of \a this. It only modify its memory footprint if the allocated memory is to high regarding real data to store.
942 * \sa DataArrayDouble::getHeapMemorySizeWithoutChildren, DataArrayDouble::reserve
944 void DataArrayDouble::pack() const
950 * Allocates the raw data in memory. If exactly same memory as needed already
951 * allocated, it is not re-allocated.
952 * \param [in] nbOfTuple - number of tuples of data to allocate.
953 * \param [in] nbOfCompo - number of components of data to allocate.
954 * \throw If \a nbOfTuple < 0 or \a nbOfCompo < 0.
956 void DataArrayDouble::allocIfNecessary(int nbOfTuple, int nbOfCompo)
960 if(nbOfTuple!=getNumberOfTuples() || nbOfCompo!=getNumberOfComponents())
961 alloc(nbOfTuple,nbOfCompo);
964 alloc(nbOfTuple,nbOfCompo);
968 * Allocates the raw data in memory. If the memory was already allocated, then it is
969 * freed and re-allocated. See an example of this method use
970 * \ref MEDCouplingArraySteps1WC "here".
971 * \param [in] nbOfTuple - number of tuples of data to allocate.
972 * \param [in] nbOfCompo - number of components of data to allocate.
973 * \throw If \a nbOfTuple < 0 or \a nbOfCompo < 0.
975 void DataArrayDouble::alloc(int nbOfTuple, int nbOfCompo)
977 if(nbOfTuple<0 || nbOfCompo<0)
978 throw INTERP_KERNEL::Exception("DataArrayDouble::alloc : request for negative length of data !");
979 _info_on_compo.resize(nbOfCompo);
980 _mem.alloc(nbOfCompo*(std::size_t)nbOfTuple);
985 * Assign zero to all values in \a this array. To know more on filling arrays see
986 * \ref MEDCouplingArrayFill.
987 * \throw If \a this is not allocated.
989 void DataArrayDouble::fillWithZero()
992 _mem.fillWithValue(0.);
997 * Assign \a val to all values in \a this array. To know more on filling arrays see
998 * \ref MEDCouplingArrayFill.
999 * \param [in] val - the value to fill with.
1000 * \throw If \a this is not allocated.
1002 void DataArrayDouble::fillWithValue(double val)
1005 _mem.fillWithValue(val);
1010 * Set all values in \a this array so that the i-th element equals to \a init + i
1011 * (i starts from zero). To know more on filling arrays see \ref MEDCouplingArrayFill.
1012 * \param [in] init - value to assign to the first element of array.
1013 * \throw If \a this->getNumberOfComponents() != 1
1014 * \throw If \a this is not allocated.
1016 void DataArrayDouble::iota(double init)
1019 if(getNumberOfComponents()!=1)
1020 throw INTERP_KERNEL::Exception("DataArrayDouble::iota : works only for arrays with only one component, you can call 'rearrange' method before !");
1021 double *ptr=getPointer();
1022 int ntuples=getNumberOfTuples();
1023 for(int i=0;i<ntuples;i++)
1024 ptr[i]=init+double(i);
1029 * Checks if all values in \a this array are equal to \a val at precision \a eps.
1030 * \param [in] val - value to check equality of array values to.
1031 * \param [in] eps - precision to check the equality.
1032 * \return bool - \a true if all values are in range (_val_ - _eps_; _val_ + _eps_),
1034 * \throw If \a this->getNumberOfComponents() != 1
1035 * \throw If \a this is not allocated.
1037 bool DataArrayDouble::isUniform(double val, double eps) const
1040 if(getNumberOfComponents()!=1)
1041 throw INTERP_KERNEL::Exception("DataArrayDouble::isUniform : must be applied on DataArrayDouble with only one component, you can call 'rearrange' method before !");
1042 int nbOfTuples=getNumberOfTuples();
1043 const double *w=getConstPointer();
1044 const double *end2=w+nbOfTuples;
1045 const double vmin=val-eps;
1046 const double vmax=val+eps;
1048 if(*w<vmin || *w>vmax)
1054 * Sorts values of the array.
1055 * \param [in] asc - \a true means ascending order, \a false, descending.
1056 * \throw If \a this is not allocated.
1057 * \throw If \a this->getNumberOfComponents() != 1.
1059 void DataArrayDouble::sort(bool asc)
1062 if(getNumberOfComponents()!=1)
1063 throw INTERP_KERNEL::Exception("DataArrayDouble::sort : only supported with 'this' array with ONE component !");
1069 * Reverse the array values.
1070 * \throw If \a this->getNumberOfComponents() < 1.
1071 * \throw If \a this is not allocated.
1073 void DataArrayDouble::reverse()
1076 _mem.reverse(getNumberOfComponents());
1081 * Checks that \a this array is consistently **increasing** or **decreasing** in value,
1082 * with at least absolute difference value of |\a eps| at each step.
1083 * If not an exception is thrown.
1084 * \param [in] increasing - if \a true, the array values should be increasing.
1085 * \param [in] eps - minimal absolute difference between the neighbor values at which
1086 * the values are considered different.
1087 * \throw If sequence of values is not strictly monotonic in agreement with \a
1089 * \throw If \a this->getNumberOfComponents() != 1.
1090 * \throw If \a this is not allocated.
1092 void DataArrayDouble::checkMonotonic(bool increasing, double eps) const
1094 if(!isMonotonic(increasing,eps))
1097 throw INTERP_KERNEL::Exception("DataArrayDouble::checkMonotonic : 'this' is not INCREASING monotonic !");
1099 throw INTERP_KERNEL::Exception("DataArrayDouble::checkMonotonic : 'this' is not DECREASING monotonic !");
1104 * Checks that \a this array is consistently **increasing** or **decreasing** in value,
1105 * with at least absolute difference value of |\a eps| at each step.
1106 * \param [in] increasing - if \a true, array values should be increasing.
1107 * \param [in] eps - minimal absolute difference between the neighbor values at which
1108 * the values are considered different.
1109 * \return bool - \a true if values change in accordance with \a increasing arg.
1110 * \throw If \a this->getNumberOfComponents() != 1.
1111 * \throw If \a this is not allocated.
1113 bool DataArrayDouble::isMonotonic(bool increasing, double eps) const
1116 if(getNumberOfComponents()!=1)
1117 throw INTERP_KERNEL::Exception("DataArrayDouble::isMonotonic : only supported with 'this' array with ONE component !");
1118 int nbOfElements=getNumberOfTuples();
1119 const double *ptr=getConstPointer();
1123 double absEps=fabs(eps);
1126 for(int i=1;i<nbOfElements;i++)
1128 if(ptr[i]<(ref+absEps))
1136 for(int i=1;i<nbOfElements;i++)
1138 if(ptr[i]>(ref-absEps))
1147 * Returns a textual and human readable representation of \a this instance of
1148 * DataArrayDouble. This text is shown when a DataArrayDouble is printed in Python.
1149 * \return std::string - text describing \a this DataArrayDouble.
1151 std::string DataArrayDouble::repr() const
1153 std::ostringstream ret;
1158 std::string DataArrayDouble::reprZip() const
1160 std::ostringstream ret;
1165 void DataArrayDouble::writeVTK(std::ostream& ofs, int indent, const std::string& nameInFile, DataArrayByte *byteArr) const
1167 static const char SPACE[4]={' ',' ',' ',' '};
1169 std::string idt(indent,' ');
1171 ofs << idt << "<DataArray type=\"Float32\" Name=\"" << nameInFile << "\" NumberOfComponents=\"" << getNumberOfComponents() << "\"";
1173 bool areAllEmpty(true);
1174 for(std::vector<std::string>::const_iterator it=_info_on_compo.begin();it!=_info_on_compo.end();it++)
1178 for(std::size_t i=0;i<_info_on_compo.size();i++)
1179 ofs << " ComponentName" << i << "=\"" << _info_on_compo[i] << "\"";
1183 ofs << " format=\"appended\" offset=\"" << byteArr->getNumberOfTuples() << "\">";
1184 INTERP_KERNEL::AutoPtr<float> tmp(new float[getNbOfElems()]);
1186 // to make Visual C++ happy : instead of std::copy(begin(),end(),(float *)tmp);
1187 for(const double *src=begin();src!=end();src++,pt++)
1189 const char *data(reinterpret_cast<const char *>((float *)tmp));
1190 std::size_t sz(getNbOfElems()*sizeof(float));
1191 byteArr->insertAtTheEnd(data,data+sz);
1192 byteArr->insertAtTheEnd(SPACE,SPACE+4);
1196 ofs << " RangeMin=\"" << getMinValueInArray() << "\" RangeMax=\"" << getMaxValueInArray() << "\" format=\"ascii\">\n" << idt;
1197 std::copy(begin(),end(),std::ostream_iterator<double>(ofs," "));
1199 ofs << std::endl << idt << "</DataArray>\n";
1202 void DataArrayDouble::reprStream(std::ostream& stream) const
1204 stream << "Name of double array : \"" << _name << "\"\n";
1205 reprWithoutNameStream(stream);
1208 void DataArrayDouble::reprZipStream(std::ostream& stream) const
1210 stream << "Name of double array : \"" << _name << "\"\n";
1211 reprZipWithoutNameStream(stream);
1214 void DataArrayDouble::reprWithoutNameStream(std::ostream& stream) const
1216 DataArray::reprWithoutNameStream(stream);
1217 stream.precision(17);
1218 _mem.repr(getNumberOfComponents(),stream);
1221 void DataArrayDouble::reprZipWithoutNameStream(std::ostream& stream) const
1223 DataArray::reprWithoutNameStream(stream);
1224 stream.precision(17);
1225 _mem.reprZip(getNumberOfComponents(),stream);
1228 void DataArrayDouble::reprCppStream(const std::string& varName, std::ostream& stream) const
1230 int nbTuples=getNumberOfTuples(),nbComp=getNumberOfComponents();
1231 const double *data=getConstPointer();
1232 stream.precision(17);
1233 stream << "DataArrayDouble *" << varName << "=DataArrayDouble::New();" << std::endl;
1234 if(nbTuples*nbComp>=1)
1236 stream << "const double " << varName << "Data[" << nbTuples*nbComp << "]={";
1237 std::copy(data,data+nbTuples*nbComp-1,std::ostream_iterator<double>(stream,","));
1238 stream << data[nbTuples*nbComp-1] << "};" << std::endl;
1239 stream << varName << "->useArray(" << varName << "Data,false,CPP_DEALLOC," << nbTuples << "," << nbComp << ");" << std::endl;
1242 stream << varName << "->alloc(" << nbTuples << "," << nbComp << ");" << std::endl;
1243 stream << varName << "->setName(\"" << getName() << "\");" << std::endl;
1247 * Method that gives a quick overvien of \a this for python.
1249 void DataArrayDouble::reprQuickOverview(std::ostream& stream) const
1251 static const std::size_t MAX_NB_OF_BYTE_IN_REPR=300;
1252 stream << "DataArrayDouble C++ instance at " << this << ". ";
1255 int nbOfCompo=(int)_info_on_compo.size();
1258 int nbOfTuples=getNumberOfTuples();
1259 stream << "Number of tuples : " << nbOfTuples << ". Number of components : " << nbOfCompo << "." << std::endl;
1260 reprQuickOverviewData(stream,MAX_NB_OF_BYTE_IN_REPR);
1263 stream << "Number of components : 0.";
1266 stream << "*** No data allocated ****";
1269 void DataArrayDouble::reprQuickOverviewData(std::ostream& stream, std::size_t maxNbOfByteInRepr) const
1271 const double *data=begin();
1272 int nbOfTuples=getNumberOfTuples();
1273 int nbOfCompo=(int)_info_on_compo.size();
1274 std::ostringstream oss2; oss2 << "[";
1276 std::string oss2Str(oss2.str());
1277 bool isFinished=true;
1278 for(int i=0;i<nbOfTuples && isFinished;i++)
1283 for(int j=0;j<nbOfCompo;j++,data++)
1286 if(j!=nbOfCompo-1) oss2 << ", ";
1292 if(i!=nbOfTuples-1) oss2 << ", ";
1293 std::string oss3Str(oss2.str());
1294 if(oss3Str.length()<maxNbOfByteInRepr)
1306 * Equivalent to DataArrayDouble::isEqual except that if false the reason of
1307 * mismatch is given.
1309 * \param [in] other the instance to be compared with \a this
1310 * \param [in] prec the precision to compare numeric data of the arrays.
1311 * \param [out] reason In case of inequality returns the reason.
1312 * \sa DataArrayDouble::isEqual
1314 bool DataArrayDouble::isEqualIfNotWhy(const DataArrayDouble& other, double prec, std::string& reason) const
1316 if(!areInfoEqualsIfNotWhy(other,reason))
1318 return _mem.isEqual(other._mem,prec,reason);
1322 * Checks if \a this and another DataArrayDouble are fully equal. For more info see
1323 * \ref MEDCouplingArrayBasicsCompare.
1324 * \param [in] other - an instance of DataArrayDouble to compare with \a this one.
1325 * \param [in] prec - precision value to compare numeric data of the arrays.
1326 * \return bool - \a true if the two arrays are equal, \a false else.
1328 bool DataArrayDouble::isEqual(const DataArrayDouble& other, double prec) const
1331 return isEqualIfNotWhy(other,prec,tmp);
1335 * Checks if values of \a this and another DataArrayDouble are equal. For more info see
1336 * \ref MEDCouplingArrayBasicsCompare.
1337 * \param [in] other - an instance of DataArrayDouble to compare with \a this one.
1338 * \param [in] prec - precision value to compare numeric data of the arrays.
1339 * \return bool - \a true if the values of two arrays are equal, \a false else.
1341 bool DataArrayDouble::isEqualWithoutConsideringStr(const DataArrayDouble& other, double prec) const
1344 return _mem.isEqual(other._mem,prec,tmp);
1348 * Changes number of tuples in the array. If the new number of tuples is smaller
1349 * than the current number the array is truncated, otherwise the array is extended.
1350 * \param [in] nbOfTuples - new number of tuples.
1351 * \throw If \a this is not allocated.
1352 * \throw If \a nbOfTuples is negative.
1354 void DataArrayDouble::reAlloc(int nbOfTuples)
1357 throw INTERP_KERNEL::Exception("DataArrayDouble::reAlloc : input new number of tuples should be >=0 !");
1359 _mem.reAlloc(getNumberOfComponents()*(std::size_t)nbOfTuples);
1364 * Creates a new DataArrayInt and assigns all (textual and numerical) data of \a this
1365 * array to the new one.
1366 * \return DataArrayInt * - the new instance of DataArrayInt.
1368 DataArrayInt *DataArrayDouble::convertToIntArr() const
1370 DataArrayInt *ret=DataArrayInt::New();
1371 ret->alloc(getNumberOfTuples(),getNumberOfComponents());
1372 int *dest=ret->getPointer();
1373 // to make Visual C++ happy : instead of std::size_t nbOfVals=getNbOfElems(); std::copy(src,src+nbOfVals,dest);
1374 for(const double *src=begin();src!=end();src++,dest++)
1376 ret->copyStringInfoFrom(*this);
1381 * Returns a new DataArrayDouble holding the same values as \a this array but differently
1382 * arranged in memory. If \a this array holds 2 components of 3 values:
1383 * \f$ x_0,x_1,x_2,y_0,y_1,y_2 \f$, then the result array holds these values arranged
1384 * as follows: \f$ x_0,y_0,x_1,y_1,x_2,y_2 \f$.
1385 * \warning Do not confuse this method with transpose()!
1386 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1387 * is to delete using decrRef() as it is no more needed.
1388 * \throw If \a this is not allocated.
1390 DataArrayDouble *DataArrayDouble::fromNoInterlace() const
1393 throw INTERP_KERNEL::Exception("DataArrayDouble::fromNoInterlace : Not defined array !");
1394 double *tab=_mem.fromNoInterlace(getNumberOfComponents());
1395 DataArrayDouble *ret=DataArrayDouble::New();
1396 ret->useArray(tab,true,C_DEALLOC,getNumberOfTuples(),getNumberOfComponents());
1401 * Returns a new DataArrayDouble holding the same values as \a this array but differently
1402 * arranged in memory. If \a this array holds 2 components of 3 values:
1403 * \f$ x_0,y_0,x_1,y_1,x_2,y_2 \f$, then the result array holds these values arranged
1404 * as follows: \f$ x_0,x_1,x_2,y_0,y_1,y_2 \f$.
1405 * \warning Do not confuse this method with transpose()!
1406 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1407 * is to delete using decrRef() as it is no more needed.
1408 * \throw If \a this is not allocated.
1410 DataArrayDouble *DataArrayDouble::toNoInterlace() const
1413 throw INTERP_KERNEL::Exception("DataArrayDouble::toNoInterlace : Not defined array !");
1414 double *tab=_mem.toNoInterlace(getNumberOfComponents());
1415 DataArrayDouble *ret=DataArrayDouble::New();
1416 ret->useArray(tab,true,C_DEALLOC,getNumberOfTuples(),getNumberOfComponents());
1421 * Permutes values of \a this array as required by \a old2New array. The values are
1422 * permuted so that \c new[ \a old2New[ i ]] = \c old[ i ]. Number of tuples remains
1423 * the same as in \this one.
1424 * If a permutation reduction is needed, substr() or selectByTupleId() should be used.
1425 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
1426 * \param [in] old2New - C array of length equal to \a this->getNumberOfTuples()
1427 * giving a new position for i-th old value.
1429 void DataArrayDouble::renumberInPlace(const int *old2New)
1432 int nbTuples=getNumberOfTuples();
1433 int nbOfCompo=getNumberOfComponents();
1434 double *tmp=new double[nbTuples*nbOfCompo];
1435 const double *iptr=getConstPointer();
1436 for(int i=0;i<nbTuples;i++)
1439 if(v>=0 && v<nbTuples)
1440 std::copy(iptr+nbOfCompo*i,iptr+nbOfCompo*(i+1),tmp+nbOfCompo*v);
1443 std::ostringstream oss; oss << "DataArrayDouble::renumberInPlace : At place #" << i << " value is " << v << " ! Should be in [0," << nbTuples << ") !";
1444 throw INTERP_KERNEL::Exception(oss.str().c_str());
1447 std::copy(tmp,tmp+nbTuples*nbOfCompo,getPointer());
1453 * Permutes values of \a this array as required by \a new2Old array. The values are
1454 * permuted so that \c new[ i ] = \c old[ \a new2Old[ i ]]. Number of tuples remains
1455 * the same as in \this one.
1456 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
1457 * \param [in] new2Old - C array of length equal to \a this->getNumberOfTuples()
1458 * giving a previous position of i-th new value.
1459 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1460 * is to delete using decrRef() as it is no more needed.
1462 void DataArrayDouble::renumberInPlaceR(const int *new2Old)
1465 int nbTuples=getNumberOfTuples();
1466 int nbOfCompo=getNumberOfComponents();
1467 double *tmp=new double[nbTuples*nbOfCompo];
1468 const double *iptr=getConstPointer();
1469 for(int i=0;i<nbTuples;i++)
1472 if(v>=0 && v<nbTuples)
1473 std::copy(iptr+nbOfCompo*v,iptr+nbOfCompo*(v+1),tmp+nbOfCompo*i);
1476 std::ostringstream oss; oss << "DataArrayDouble::renumberInPlaceR : At place #" << i << " value is " << v << " ! Should be in [0," << nbTuples << ") !";
1477 throw INTERP_KERNEL::Exception(oss.str().c_str());
1480 std::copy(tmp,tmp+nbTuples*nbOfCompo,getPointer());
1486 * Returns a copy of \a this array with values permuted as required by \a old2New array.
1487 * The values are permuted so that \c new[ \a old2New[ i ]] = \c old[ i ].
1488 * Number of tuples in the result array remains the same as in \this one.
1489 * If a permutation reduction is needed, renumberAndReduce() should be used.
1490 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
1491 * \param [in] old2New - C array of length equal to \a this->getNumberOfTuples()
1492 * giving a new position for i-th old value.
1493 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1494 * is to delete using decrRef() as it is no more needed.
1495 * \throw If \a this is not allocated.
1497 DataArrayDouble *DataArrayDouble::renumber(const int *old2New) const
1500 int nbTuples=getNumberOfTuples();
1501 int nbOfCompo=getNumberOfComponents();
1502 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
1503 ret->alloc(nbTuples,nbOfCompo);
1504 ret->copyStringInfoFrom(*this);
1505 const double *iptr=getConstPointer();
1506 double *optr=ret->getPointer();
1507 for(int i=0;i<nbTuples;i++)
1508 std::copy(iptr+nbOfCompo*i,iptr+nbOfCompo*(i+1),optr+nbOfCompo*old2New[i]);
1509 ret->copyStringInfoFrom(*this);
1514 * Returns a copy of \a this array with values permuted as required by \a new2Old array.
1515 * The values are permuted so that \c new[ i ] = \c old[ \a new2Old[ i ]]. Number of
1516 * tuples in the result array remains the same as in \this one.
1517 * If a permutation reduction is needed, substr() or selectByTupleId() should be used.
1518 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
1519 * \param [in] new2Old - C array of length equal to \a this->getNumberOfTuples()
1520 * giving a previous position of i-th new value.
1521 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1522 * is to delete using decrRef() as it is no more needed.
1524 DataArrayDouble *DataArrayDouble::renumberR(const int *new2Old) const
1527 int nbTuples=getNumberOfTuples();
1528 int nbOfCompo=getNumberOfComponents();
1529 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
1530 ret->alloc(nbTuples,nbOfCompo);
1531 ret->copyStringInfoFrom(*this);
1532 const double *iptr=getConstPointer();
1533 double *optr=ret->getPointer();
1534 for(int i=0;i<nbTuples;i++)
1535 std::copy(iptr+nbOfCompo*new2Old[i],iptr+nbOfCompo*(new2Old[i]+1),optr+i*nbOfCompo);
1536 ret->copyStringInfoFrom(*this);
1541 * Returns a shorten and permuted copy of \a this array. The new DataArrayDouble is
1542 * of size \a newNbOfTuple and it's values are permuted as required by \a old2New array.
1543 * The values are permuted so that \c new[ \a old2New[ i ]] = \c old[ i ] for all
1544 * \a old2New[ i ] >= 0. In other words every i-th tuple in \a this array, for which
1545 * \a old2New[ i ] is negative, is missing from the result array.
1546 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
1547 * \param [in] old2New - C array of length equal to \a this->getNumberOfTuples()
1548 * giving a new position for i-th old tuple and giving negative position for
1549 * for i-th old tuple that should be omitted.
1550 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1551 * is to delete using decrRef() as it is no more needed.
1553 DataArrayDouble *DataArrayDouble::renumberAndReduce(const int *old2New, int newNbOfTuple) const
1556 int nbTuples=getNumberOfTuples();
1557 int nbOfCompo=getNumberOfComponents();
1558 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
1559 ret->alloc(newNbOfTuple,nbOfCompo);
1560 const double *iptr=getConstPointer();
1561 double *optr=ret->getPointer();
1562 for(int i=0;i<nbTuples;i++)
1566 std::copy(iptr+i*nbOfCompo,iptr+(i+1)*nbOfCompo,optr+w*nbOfCompo);
1568 ret->copyStringInfoFrom(*this);
1573 * Returns a shorten and permuted copy of \a this array. The new DataArrayDouble is
1574 * of size \a new2OldEnd - \a new2OldBg and it's values are permuted as required by
1575 * \a new2OldBg array.
1576 * The values are permuted so that \c new[ i ] = \c old[ \a new2OldBg[ i ]].
1577 * This method is equivalent to renumberAndReduce() except that convention in input is
1578 * \c new2old and \b not \c old2new.
1579 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
1580 * \param [in] new2OldBg - pointer to the beginning of a permutation array that gives a
1581 * tuple index in \a this array to fill the i-th tuple in the new array.
1582 * \param [in] new2OldEnd - specifies the end of the permutation array that starts at
1583 * \a new2OldBg, so that pointer to a tuple index (\a pi) varies as this:
1584 * \a new2OldBg <= \a pi < \a new2OldEnd.
1585 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1586 * is to delete using decrRef() as it is no more needed.
1588 DataArrayDouble *DataArrayDouble::selectByTupleId(const int *new2OldBg, const int *new2OldEnd) const
1591 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
1592 int nbComp=getNumberOfComponents();
1593 ret->alloc((int)std::distance(new2OldBg,new2OldEnd),nbComp);
1594 ret->copyStringInfoFrom(*this);
1595 double *pt=ret->getPointer();
1596 const double *srcPt=getConstPointer();
1598 for(const int *w=new2OldBg;w!=new2OldEnd;w++,i++)
1599 std::copy(srcPt+(*w)*nbComp,srcPt+((*w)+1)*nbComp,pt+i*nbComp);
1600 ret->copyStringInfoFrom(*this);
1605 * Returns a shorten and permuted copy of \a this array. The new DataArrayDouble is
1606 * of size \a new2OldEnd - \a new2OldBg and it's values are permuted as required by
1607 * \a new2OldBg array.
1608 * The values are permuted so that \c new[ i ] = \c old[ \a new2OldBg[ i ]].
1609 * This method is equivalent to renumberAndReduce() except that convention in input is
1610 * \c new2old and \b not \c old2new.
1611 * This method is equivalent to selectByTupleId() except that it prevents coping data
1612 * from behind the end of \a this array.
1613 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
1614 * \param [in] new2OldBg - pointer to the beginning of a permutation array that gives a
1615 * tuple index in \a this array to fill the i-th tuple in the new array.
1616 * \param [in] new2OldEnd - specifies the end of the permutation array that starts at
1617 * \a new2OldBg, so that pointer to a tuple index (\a pi) varies as this:
1618 * \a new2OldBg <= \a pi < \a new2OldEnd.
1619 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1620 * is to delete using decrRef() as it is no more needed.
1621 * \throw If \a new2OldEnd - \a new2OldBg > \a this->getNumberOfTuples().
1623 DataArrayDouble *DataArrayDouble::selectByTupleIdSafe(const int *new2OldBg, const int *new2OldEnd) const
1626 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
1627 int nbComp=getNumberOfComponents();
1628 int oldNbOfTuples=getNumberOfTuples();
1629 ret->alloc((int)std::distance(new2OldBg,new2OldEnd),nbComp);
1630 ret->copyStringInfoFrom(*this);
1631 double *pt=ret->getPointer();
1632 const double *srcPt=getConstPointer();
1634 for(const int *w=new2OldBg;w!=new2OldEnd;w++,i++)
1635 if(*w>=0 && *w<oldNbOfTuples)
1636 std::copy(srcPt+(*w)*nbComp,srcPt+((*w)+1)*nbComp,pt+i*nbComp);
1638 throw INTERP_KERNEL::Exception("DataArrayDouble::selectByTupleIdSafe : some ids has been detected to be out of [0,this->getNumberOfTuples) !");
1639 ret->copyStringInfoFrom(*this);
1644 * Returns a shorten copy of \a this array. The new DataArrayDouble contains every
1645 * (\a bg + \c i * \a step)-th tuple of \a this array located before the \a end2-th
1646 * tuple. Indices of the selected tuples are the same as ones returned by the Python
1647 * command \c range( \a bg, \a end2, \a step ).
1648 * This method is equivalent to selectByTupleIdSafe() except that the input array is
1649 * not constructed explicitly.
1650 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
1651 * \param [in] bg - index of the first tuple to copy from \a this array.
1652 * \param [in] end2 - index of the tuple before which the tuples to copy are located.
1653 * \param [in] step - index increment to get index of the next tuple to copy.
1654 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1655 * is to delete using decrRef() as it is no more needed.
1656 * \sa DataArrayDouble::substr.
1658 DataArrayDouble *DataArrayDouble::selectByTupleId2(int bg, int end2, int step) const
1661 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
1662 int nbComp=getNumberOfComponents();
1663 int newNbOfTuples=GetNumberOfItemGivenBESRelative(bg,end2,step,"DataArrayDouble::selectByTupleId2 : ");
1664 ret->alloc(newNbOfTuples,nbComp);
1665 double *pt=ret->getPointer();
1666 const double *srcPt=getConstPointer()+bg*nbComp;
1667 for(int i=0;i<newNbOfTuples;i++,srcPt+=step*nbComp)
1668 std::copy(srcPt,srcPt+nbComp,pt+i*nbComp);
1669 ret->copyStringInfoFrom(*this);
1674 * Returns a shorten copy of \a this array. The new DataArrayDouble contains ranges
1675 * of tuples specified by \a ranges parameter.
1676 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
1677 * \param [in] ranges - std::vector of std::pair's each of which defines a range
1678 * of tuples in [\c begin,\c end) format.
1679 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1680 * is to delete using decrRef() as it is no more needed.
1681 * \throw If \a end < \a begin.
1682 * \throw If \a end > \a this->getNumberOfTuples().
1683 * \throw If \a this is not allocated.
1685 DataArray *DataArrayDouble::selectByTupleRanges(const std::vector<std::pair<int,int> >& ranges) const
1688 int nbOfComp=getNumberOfComponents();
1689 int nbOfTuplesThis=getNumberOfTuples();
1692 DataArrayDouble *ret=DataArrayDouble::New();
1693 ret->alloc(0,nbOfComp);
1694 ret->copyStringInfoFrom(*this);
1697 int ref=ranges.front().first;
1699 bool isIncreasing=true;
1700 for(std::vector<std::pair<int,int> >::const_iterator it=ranges.begin();it!=ranges.end();it++)
1702 if((*it).first<=(*it).second)
1704 if((*it).first>=0 && (*it).second<=nbOfTuplesThis)
1706 nbOfTuples+=(*it).second-(*it).first;
1708 isIncreasing=ref<=(*it).first;
1713 std::ostringstream oss; oss << "DataArrayDouble::selectByTupleRanges : on range #" << std::distance(ranges.begin(),it);
1714 oss << " (" << (*it).first << "," << (*it).second << ") is greater than number of tuples of this :" << nbOfTuples << " !";
1715 throw INTERP_KERNEL::Exception(oss.str().c_str());
1720 std::ostringstream oss; oss << "DataArrayDouble::selectByTupleRanges : on range #" << std::distance(ranges.begin(),it);
1721 oss << " (" << (*it).first << "," << (*it).second << ") end is before begin !";
1722 throw INTERP_KERNEL::Exception(oss.str().c_str());
1725 if(isIncreasing && nbOfTuplesThis==nbOfTuples)
1727 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
1728 ret->alloc(nbOfTuples,nbOfComp);
1729 ret->copyStringInfoFrom(*this);
1730 const double *src=getConstPointer();
1731 double *work=ret->getPointer();
1732 for(std::vector<std::pair<int,int> >::const_iterator it=ranges.begin();it!=ranges.end();it++)
1733 work=std::copy(src+(*it).first*nbOfComp,src+(*it).second*nbOfComp,work);
1738 * Returns a shorten copy of \a this array. The new DataArrayDouble contains all
1739 * tuples starting from the \a tupleIdBg-th tuple and including all tuples located before
1740 * the \a tupleIdEnd-th one. This methods has a similar behavior as std::string::substr().
1741 * This method is a specialization of selectByTupleId2().
1742 * \param [in] tupleIdBg - index of the first tuple to copy from \a this array.
1743 * \param [in] tupleIdEnd - index of the tuple before which the tuples to copy are located.
1744 * If \a tupleIdEnd == -1, all the tuples till the end of \a this array are copied.
1745 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1746 * is to delete using decrRef() as it is no more needed.
1747 * \throw If \a tupleIdBg < 0.
1748 * \throw If \a tupleIdBg > \a this->getNumberOfTuples().
1749 \throw If \a tupleIdEnd != -1 && \a tupleIdEnd < \a this->getNumberOfTuples().
1750 * \sa DataArrayDouble::selectByTupleId2
1752 DataArrayDouble *DataArrayDouble::substr(int tupleIdBg, int tupleIdEnd) const
1755 int nbt=getNumberOfTuples();
1757 throw INTERP_KERNEL::Exception("DataArrayDouble::substr : The tupleIdBg parameter must be greater than 0 !");
1759 throw INTERP_KERNEL::Exception("DataArrayDouble::substr : The tupleIdBg parameter is greater than number of tuples !");
1760 int trueEnd=tupleIdEnd;
1764 throw INTERP_KERNEL::Exception("DataArrayDouble::substr : The tupleIdBg parameter is greater or equal than number of tuples !");
1768 int nbComp=getNumberOfComponents();
1769 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
1770 ret->alloc(trueEnd-tupleIdBg,nbComp);
1771 ret->copyStringInfoFrom(*this);
1772 std::copy(getConstPointer()+tupleIdBg*nbComp,getConstPointer()+trueEnd*nbComp,ret->getPointer());
1777 * Returns a shorten or extended copy of \a this array. If \a newNbOfComp is less
1778 * than \a this->getNumberOfComponents() then the result array is shorten as each tuple
1779 * is truncated to have \a newNbOfComp components, keeping first components. If \a
1780 * newNbOfComp is more than \a this->getNumberOfComponents() then the result array is
1781 * expanded as each tuple is populated with \a dftValue to have \a newNbOfComp
1783 * \param [in] newNbOfComp - number of components for the new array to have.
1784 * \param [in] dftValue - value assigned to new values added to the new array.
1785 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1786 * is to delete using decrRef() as it is no more needed.
1787 * \throw If \a this is not allocated.
1789 DataArrayDouble *DataArrayDouble::changeNbOfComponents(int newNbOfComp, double dftValue) const
1792 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
1793 ret->alloc(getNumberOfTuples(),newNbOfComp);
1794 const double *oldc=getConstPointer();
1795 double *nc=ret->getPointer();
1796 int nbOfTuples=getNumberOfTuples();
1797 int oldNbOfComp=getNumberOfComponents();
1798 int dim=std::min(oldNbOfComp,newNbOfComp);
1799 for(int i=0;i<nbOfTuples;i++)
1803 nc[newNbOfComp*i+j]=oldc[i*oldNbOfComp+j];
1804 for(;j<newNbOfComp;j++)
1805 nc[newNbOfComp*i+j]=dftValue;
1807 ret->setName(getName());
1808 for(int i=0;i<dim;i++)
1809 ret->setInfoOnComponent(i,getInfoOnComponent(i));
1810 ret->setName(getName());
1815 * Changes the number of components within \a this array so that its raw data **does
1816 * not** change, instead splitting this data into tuples changes.
1817 * \warning This method erases all (name and unit) component info set before!
1818 * \param [in] newNbOfComp - number of components for \a this array to have.
1819 * \throw If \a this is not allocated
1820 * \throw If getNbOfElems() % \a newNbOfCompo != 0.
1821 * \throw If \a newNbOfCompo is lower than 1.
1822 * \throw If the rearrange method would lead to a number of tuples higher than 2147483647 (maximal capacity of int32 !).
1823 * \warning This method erases all (name and unit) component info set before!
1825 void DataArrayDouble::rearrange(int newNbOfCompo)
1829 throw INTERP_KERNEL::Exception("DataArrayDouble::rearrange : input newNbOfCompo must be > 0 !");
1830 std::size_t nbOfElems=getNbOfElems();
1831 if(nbOfElems%newNbOfCompo!=0)
1832 throw INTERP_KERNEL::Exception("DataArrayDouble::rearrange : nbOfElems%newNbOfCompo!=0 !");
1833 if(nbOfElems/newNbOfCompo>(std::size_t)std::numeric_limits<int>::max())
1834 throw INTERP_KERNEL::Exception("DataArrayDouble::rearrange : the rearrangement leads to too high number of tuples (> 2147483647) !");
1835 _info_on_compo.clear();
1836 _info_on_compo.resize(newNbOfCompo);
1841 * Changes the number of components within \a this array to be equal to its number
1842 * of tuples, and inversely its number of tuples to become equal to its number of
1843 * components. So that its raw data **does not** change, instead splitting this
1844 * data into tuples changes.
1845 * \warning This method erases all (name and unit) component info set before!
1846 * \warning Do not confuse this method with fromNoInterlace() and toNoInterlace()!
1847 * \throw If \a this is not allocated.
1850 void DataArrayDouble::transpose()
1853 int nbOfTuples=getNumberOfTuples();
1854 rearrange(nbOfTuples);
1858 * Returns a copy of \a this array composed of selected components.
1859 * The new DataArrayDouble has the same number of tuples but includes components
1860 * specified by \a compoIds parameter. So that getNbOfElems() of the result array
1861 * can be either less, same or more than \a this->getNbOfElems().
1862 * \param [in] compoIds - sequence of zero based indices of components to include
1863 * into the new array.
1864 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
1865 * is to delete using decrRef() as it is no more needed.
1866 * \throw If \a this is not allocated.
1867 * \throw If a component index (\a i) is not valid:
1868 * \a i < 0 || \a i >= \a this->getNumberOfComponents().
1870 * \if ENABLE_EXAMPLES
1871 * \ref py_mcdataarraydouble_KeepSelectedComponents "Here is a Python example".
1874 DataArrayDouble *DataArrayDouble::keepSelectedComponents(const std::vector<int>& compoIds) const
1877 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret(DataArrayDouble::New());
1878 std::size_t newNbOfCompo=compoIds.size();
1879 int oldNbOfCompo=getNumberOfComponents();
1880 for(std::vector<int>::const_iterator it=compoIds.begin();it!=compoIds.end();it++)
1881 if((*it)<0 || (*it)>=oldNbOfCompo)
1883 std::ostringstream oss; oss << "DataArrayDouble::keepSelectedComponents : invalid requested component : " << *it << " whereas it should be in [0," << oldNbOfCompo << ") !";
1884 throw INTERP_KERNEL::Exception(oss.str().c_str());
1886 int nbOfTuples=getNumberOfTuples();
1887 ret->alloc(nbOfTuples,(int)newNbOfCompo);
1888 ret->copyPartOfStringInfoFrom(*this,compoIds);
1889 const double *oldc=getConstPointer();
1890 double *nc=ret->getPointer();
1891 for(int i=0;i<nbOfTuples;i++)
1892 for(std::size_t j=0;j<newNbOfCompo;j++,nc++)
1893 *nc=oldc[i*oldNbOfCompo+compoIds[j]];
1898 * Appends components of another array to components of \a this one, tuple by tuple.
1899 * So that the number of tuples of \a this array remains the same and the number of
1900 * components increases.
1901 * \param [in] other - the DataArrayDouble to append to \a this one.
1902 * \throw If \a this is not allocated.
1903 * \throw If \a this and \a other arrays have different number of tuples.
1905 * \if ENABLE_EXAMPLES
1906 * \ref cpp_mcdataarraydouble_meldwith "Here is a C++ example".
1908 * \ref py_mcdataarraydouble_meldwith "Here is a Python example".
1911 void DataArrayDouble::meldWith(const DataArrayDouble *other)
1914 other->checkAllocated();
1915 int nbOfTuples=getNumberOfTuples();
1916 if(nbOfTuples!=other->getNumberOfTuples())
1917 throw INTERP_KERNEL::Exception("DataArrayDouble::meldWith : mismatch of number of tuples !");
1918 int nbOfComp1=getNumberOfComponents();
1919 int nbOfComp2=other->getNumberOfComponents();
1920 double *newArr=(double *)malloc((nbOfTuples*(nbOfComp1+nbOfComp2))*sizeof(double));
1922 const double *inp1=getConstPointer();
1923 const double *inp2=other->getConstPointer();
1924 for(int i=0;i<nbOfTuples;i++,inp1+=nbOfComp1,inp2+=nbOfComp2)
1926 w=std::copy(inp1,inp1+nbOfComp1,w);
1927 w=std::copy(inp2,inp2+nbOfComp2,w);
1929 useArray(newArr,true,C_DEALLOC,nbOfTuples,nbOfComp1+nbOfComp2);
1930 std::vector<int> compIds(nbOfComp2);
1931 for(int i=0;i<nbOfComp2;i++)
1932 compIds[i]=nbOfComp1+i;
1933 copyPartOfStringInfoFrom2(compIds,*other);
1937 * This method checks that all tuples in \a other are in \a this.
1938 * If true, the output param \a tupleIds contains the tuples ids of \a this that correspond to tupes in \a this.
1939 * For each i in [ 0 , other->getNumberOfTuples() ) tuple #i in \a other is equal ( regarding input precision \a prec ) to tuple tupleIds[i] in \a this.
1941 * \param [in] other - the array having the same number of components than \a this.
1942 * \param [out] tupleIds - the tuple ids containing the same number of tuples than \a other has.
1943 * \sa DataArrayDouble::findCommonTuples
1945 bool DataArrayDouble::areIncludedInMe(const DataArrayDouble *other, double prec, DataArrayInt *&tupleIds) const
1948 throw INTERP_KERNEL::Exception("DataArrayDouble::areIncludedInMe : input array is NULL !");
1949 checkAllocated(); other->checkAllocated();
1950 if(getNumberOfComponents()!=other->getNumberOfComponents())
1951 throw INTERP_KERNEL::Exception("DataArrayDouble::areIncludedInMe : the number of components does not match !");
1952 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> a=DataArrayDouble::Aggregate(this,other);
1953 DataArrayInt *c=0,*ci=0;
1954 a->findCommonTuples(prec,getNumberOfTuples(),c,ci);
1955 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> cSafe(c),ciSafe(ci);
1956 int newNbOfTuples=-1;
1957 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ids=DataArrayInt::BuildOld2NewArrayFromSurjectiveFormat2(a->getNumberOfTuples(),c->begin(),ci->begin(),ci->end(),newNbOfTuples);
1958 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret1=ids->selectByTupleId2(getNumberOfTuples(),a->getNumberOfTuples(),1);
1959 tupleIds=ret1.retn();
1960 return newNbOfTuples==getNumberOfTuples();
1964 * Searches for tuples coincident within \a prec tolerance. Each tuple is considered
1965 * as coordinates of a point in getNumberOfComponents()-dimensional space. The
1966 * distance separating two points is computed with the infinite norm.
1968 * Indices of coincident tuples are stored in output arrays.
1969 * A pair of arrays (\a comm, \a commIndex) is called "Surjective Format 2".
1971 * This method is typically used by MEDCouplingPointSet::findCommonNodes() and
1972 * MEDCouplingUMesh::mergeNodes().
1973 * \param [in] prec - minimal absolute distance between two tuples (infinite norm) at which they are
1974 * considered not coincident.
1975 * \param [in] limitTupleId - limit tuple id. If all tuples within a group of coincident
1976 * tuples have id strictly lower than \a limitTupleId then they are not returned.
1977 * \param [out] comm - the array holding ids (== indices) of coincident tuples.
1978 * \a comm->getNumberOfComponents() == 1.
1979 * \a comm->getNumberOfTuples() == \a commIndex->back().
1980 * \param [out] commIndex - the array dividing all indices stored in \a comm into
1981 * groups of (indices of) coincident tuples. Its every value is a tuple
1982 * index where a next group of tuples begins. For example the second
1983 * group of tuples in \a comm is described by following range of indices:
1984 * [ \a commIndex[1], \a commIndex[2] ). \a commIndex->getNumberOfTuples()-1
1985 * gives the number of groups of coincident tuples.
1986 * \throw If \a this is not allocated.
1987 * \throw If the number of components is not in [1,2,3,4].
1989 * \if ENABLE_EXAMPLES
1990 * \ref cpp_mcdataarraydouble_findcommontuples "Here is a C++ example".
1992 * \ref py_mcdataarraydouble_findcommontuples "Here is a Python example".
1994 * \sa DataArrayInt::BuildOld2NewArrayFromSurjectiveFormat2(), DataArrayDouble::areIncludedInMe
1996 void DataArrayDouble::findCommonTuples(double prec, int limitTupleId, DataArrayInt *&comm, DataArrayInt *&commIndex) const
1999 int nbOfCompo=getNumberOfComponents();
2000 if ((nbOfCompo<1) || (nbOfCompo>4)) //test before work
2001 throw INTERP_KERNEL::Exception("DataArrayDouble::findCommonTuples : Unexpected spacedim of coords. Must be 1, 2, 3 or 4.");
2003 int nbOfTuples=getNumberOfTuples();
2005 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> c(DataArrayInt::New()),cI(DataArrayInt::New()); c->alloc(0,1); cI->pushBackSilent(0);
2009 findCommonTuplesAlg<4>(begin(),nbOfTuples,limitTupleId,prec,c,cI);
2012 findCommonTuplesAlg<3>(begin(),nbOfTuples,limitTupleId,prec,c,cI);
2015 findCommonTuplesAlg<2>(begin(),nbOfTuples,limitTupleId,prec,c,cI);
2018 findCommonTuplesAlg<1>(begin(),nbOfTuples,limitTupleId,prec,c,cI);
2021 throw INTERP_KERNEL::Exception("DataArrayDouble::findCommonTuples : nb of components managed are 1,2,3 and 4 ! not implemented for other number of components !");
2024 commIndex=cI.retn();
2029 * \param [in] nbTimes specifies the nb of times each tuples in \a this will be duplicated contiguouly in returned DataArrayDouble instance.
2030 * \a nbTimes should be at least equal to 1.
2031 * \return a newly allocated DataArrayDouble having one component and number of tuples equal to \a nbTimes * \c this->getNumberOfTuples.
2032 * \throw if \a this is not allocated or if \a this has not number of components set to one or if \a nbTimes is lower than 1.
2034 DataArrayDouble *DataArrayDouble::duplicateEachTupleNTimes(int nbTimes) const
2037 if(getNumberOfComponents()!=1)
2038 throw INTERP_KERNEL::Exception("DataArrayDouble::duplicateEachTupleNTimes : this should have only one component !");
2040 throw INTERP_KERNEL::Exception("DataArrayDouble::duplicateEachTupleNTimes : nb times should be >= 1 !");
2041 int nbTuples=getNumberOfTuples();
2042 const double *inPtr=getConstPointer();
2043 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New(); ret->alloc(nbTimes*nbTuples,1);
2044 double *retPtr=ret->getPointer();
2045 for(int i=0;i<nbTuples;i++,inPtr++)
2048 for(int j=0;j<nbTimes;j++,retPtr++)
2051 ret->copyStringInfoFrom(*this);
2056 * This methods returns the minimal distance between the two set of points \a this and \a other.
2057 * So \a this and \a other have to have the same number of components. If not an INTERP_KERNEL::Exception will be thrown.
2058 * This method works only if number of components of \a this (equal to those of \a other) is in 1, 2 or 3.
2060 * \param [out] thisTupleId the tuple id in \a this corresponding to the returned minimal distance
2061 * \param [out] otherTupleId the tuple id in \a other corresponding to the returned minimal distance
2062 * \return the minimal distance between the two set of points \a this and \a other.
2063 * \sa DataArrayDouble::findClosestTupleId
2065 double DataArrayDouble::minimalDistanceTo(const DataArrayDouble *other, int& thisTupleId, int& otherTupleId) const
2067 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> part1=findClosestTupleId(other);
2068 int nbOfCompo(getNumberOfComponents());
2069 int otherNbTuples(other->getNumberOfTuples());
2070 const double *thisPt(begin()),*otherPt(other->begin());
2071 const int *part1Pt(part1->begin());
2072 double ret=std::numeric_limits<double>::max();
2073 for(int i=0;i<otherNbTuples;i++,part1Pt++,otherPt+=nbOfCompo)
2076 for(int j=0;j<nbOfCompo;j++)
2077 tmp+=(otherPt[j]-thisPt[nbOfCompo*(*part1Pt)+j])*(otherPt[j]-thisPt[nbOfCompo*(*part1Pt)+j]);
2079 { ret=tmp; thisTupleId=*part1Pt; otherTupleId=i; }
2085 * This methods returns for each tuple in \a other which tuple in \a this is the closest.
2086 * So \a this and \a other have to have the same number of components. If not an INTERP_KERNEL::Exception will be thrown.
2087 * This method works only if number of components of \a this (equal to those of \a other) is in 1, 2 or 3.
2089 * \return a newly allocated (new object to be dealt by the caller) DataArrayInt having \c other->getNumberOfTuples() tuples and one components.
2090 * \sa DataArrayDouble::minimalDistanceTo
2092 DataArrayInt *DataArrayDouble::findClosestTupleId(const DataArrayDouble *other) const
2095 throw INTERP_KERNEL::Exception("DataArrayDouble::findClosestTupleId : other instance is NULL !");
2096 checkAllocated(); other->checkAllocated();
2097 int nbOfCompo=getNumberOfComponents();
2098 if(nbOfCompo!=other->getNumberOfComponents())
2100 std::ostringstream oss; oss << "DataArrayDouble::findClosestTupleId : number of components in this is " << nbOfCompo;
2101 oss << ", whereas number of components in other is " << other->getNumberOfComponents() << "! Should be equal !";
2102 throw INTERP_KERNEL::Exception(oss.str().c_str());
2104 int nbOfTuples=other->getNumberOfTuples();
2105 int thisNbOfTuples=getNumberOfTuples();
2106 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New(); ret->alloc(nbOfTuples,1);
2108 getMinMaxPerComponent(bounds);
2113 double xDelta(fabs(bounds[1]-bounds[0])),yDelta(fabs(bounds[3]-bounds[2])),zDelta(fabs(bounds[5]-bounds[4]));
2114 double delta=std::max(xDelta,yDelta); delta=std::max(delta,zDelta);
2115 double characSize=pow((delta*delta*delta)/((double)thisNbOfTuples),1./3.);
2116 BBTreePts<3,int> myTree(begin(),0,0,getNumberOfTuples(),characSize*1e-12);
2117 FindClosestTupleIdAlg<3>(myTree,3.*characSize*characSize,other->begin(),nbOfTuples,begin(),thisNbOfTuples,ret->getPointer());
2122 double xDelta(fabs(bounds[1]-bounds[0])),yDelta(fabs(bounds[3]-bounds[2]));
2123 double delta=std::max(xDelta,yDelta);
2124 double characSize=sqrt(delta/(double)thisNbOfTuples);
2125 BBTreePts<2,int> myTree(begin(),0,0,getNumberOfTuples(),characSize*1e-12);
2126 FindClosestTupleIdAlg<2>(myTree,2.*characSize*characSize,other->begin(),nbOfTuples,begin(),thisNbOfTuples,ret->getPointer());
2131 double characSize=fabs(bounds[1]-bounds[0])/thisNbOfTuples;
2132 BBTreePts<1,int> myTree(begin(),0,0,getNumberOfTuples(),characSize*1e-12);
2133 FindClosestTupleIdAlg<1>(myTree,1.*characSize*characSize,other->begin(),nbOfTuples,begin(),thisNbOfTuples,ret->getPointer());
2137 throw INTERP_KERNEL::Exception("Unexpected spacedim of coords for findClosestTupleId. Must be 1, 2 or 3.");
2143 * This method expects that \a this and \a otherBBoxFrmt arrays are bounding box arrays ( as the output of MEDCouplingPointSet::getBoundingBoxForBBTree method ).
2144 * This method will return a DataArrayInt array having the same number of tuples than \a this. This returned array tells for each cell in \a this
2145 * how many bounding boxes in \a otherBBoxFrmt.
2146 * So, this method expects that \a this and \a otherBBoxFrmt have the same number of components.
2148 * \param [in] otherBBoxFrmt - It is an array .
2149 * \param [in] eps - the absolute precision of the detection. when eps < 0 the bboxes are enlarged so more interactions are detected. Inversely when > 0 the bboxes are stretched.
2150 * \sa MEDCouplingPointSet::getBoundingBoxForBBTree
2151 * \throw If \a this and \a otherBBoxFrmt have not the same number of components.
2152 * \throw If \a this and \a otherBBoxFrmt number of components is not even (BBox format).
2154 DataArrayInt *DataArrayDouble::computeNbOfInteractionsWith(const DataArrayDouble *otherBBoxFrmt, double eps) const
2157 throw INTERP_KERNEL::Exception("DataArrayDouble::computeNbOfInteractionsWith : input array is NULL !");
2158 if(!isAllocated() || !otherBBoxFrmt->isAllocated())
2159 throw INTERP_KERNEL::Exception("DataArrayDouble::computeNbOfInteractionsWith : this and input array must be allocated !");
2160 int nbOfComp(getNumberOfComponents()),nbOfTuples(getNumberOfTuples());
2161 if(nbOfComp!=otherBBoxFrmt->getNumberOfComponents())
2163 std::ostringstream oss; oss << "DataArrayDouble::computeNbOfInteractionsWith : this number of components (" << nbOfComp << ") must be equal to the number of components of input array (" << otherBBoxFrmt->getNumberOfComponents() << ") !";
2164 throw INTERP_KERNEL::Exception(oss.str().c_str());
2168 std::ostringstream oss; oss << "DataArrayDouble::computeNbOfInteractionsWith : Number of components (" << nbOfComp << ") is not even ! It should be to be compatible with bbox format !";
2169 throw INTERP_KERNEL::Exception(oss.str().c_str());
2171 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(nbOfTuples,1);
2172 const double *thisBBPtr(begin());
2173 int *retPtr(ret->getPointer());
2178 BBTree<3,int> bbt(otherBBoxFrmt->begin(),0,0,otherBBoxFrmt->getNumberOfTuples(),eps);
2179 for(int i=0;i<nbOfTuples;i++,retPtr++,thisBBPtr+=nbOfComp)
2180 *retPtr=bbt.getNbOfIntersectingElems(thisBBPtr);
2185 BBTree<2,int> bbt(otherBBoxFrmt->begin(),0,0,otherBBoxFrmt->getNumberOfTuples(),eps);
2186 for(int i=0;i<nbOfTuples;i++,retPtr++,thisBBPtr+=nbOfComp)
2187 *retPtr=bbt.getNbOfIntersectingElems(thisBBPtr);
2192 BBTree<1,int> bbt(otherBBoxFrmt->begin(),0,0,otherBBoxFrmt->getNumberOfTuples(),eps);
2193 for(int i=0;i<nbOfTuples;i++,retPtr++,thisBBPtr+=nbOfComp)
2194 *retPtr=bbt.getNbOfIntersectingElems(thisBBPtr);
2198 throw INTERP_KERNEL::Exception("DataArrayDouble::computeNbOfInteractionsWith : space dimension supported are [1,2,3] !");
2205 * Returns a copy of \a this array by excluding coincident tuples. Each tuple is
2206 * considered as coordinates of a point in getNumberOfComponents()-dimensional
2207 * space. The distance between tuples is computed using norm2. If several tuples are
2208 * not far each from other than \a prec, only one of them remains in the result
2209 * array. The order of tuples in the result array is same as in \a this one except
2210 * that coincident tuples are excluded.
2211 * \param [in] prec - minimal absolute distance between two tuples at which they are
2212 * considered not coincident.
2213 * \param [in] limitTupleId - limit tuple id. If all tuples within a group of coincident
2214 * tuples have id strictly lower than \a limitTupleId then they are not excluded.
2215 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
2216 * is to delete using decrRef() as it is no more needed.
2217 * \throw If \a this is not allocated.
2218 * \throw If the number of components is not in [1,2,3,4].
2220 * \if ENABLE_EXAMPLES
2221 * \ref py_mcdataarraydouble_getdifferentvalues "Here is a Python example".
2224 DataArrayDouble *DataArrayDouble::getDifferentValues(double prec, int limitTupleId) const
2227 DataArrayInt *c0=0,*cI0=0;
2228 findCommonTuples(prec,limitTupleId,c0,cI0);
2229 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> c(c0),cI(cI0);
2230 int newNbOfTuples=-1;
2231 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> o2n=DataArrayInt::BuildOld2NewArrayFromSurjectiveFormat2(getNumberOfTuples(),c0->begin(),cI0->begin(),cI0->end(),newNbOfTuples);
2232 return renumberAndReduce(o2n->getConstPointer(),newNbOfTuples);
2236 * Copy all components in a specified order from another DataArrayDouble.
2237 * Both numerical and textual data is copied. The number of tuples in \a this and
2238 * the other array can be different.
2239 * \param [in] a - the array to copy data from.
2240 * \param [in] compoIds - sequence of zero based indices of components, data of which is
2242 * \throw If \a a is NULL.
2243 * \throw If \a compoIds.size() != \a a->getNumberOfComponents().
2244 * \throw If \a compoIds[i] < 0 or \a compoIds[i] > \a this->getNumberOfComponents().
2246 * \if ENABLE_EXAMPLES
2247 * \ref py_mcdataarraydouble_setselectedcomponents "Here is a Python example".
2250 void DataArrayDouble::setSelectedComponents(const DataArrayDouble *a, const std::vector<int>& compoIds)
2253 throw INTERP_KERNEL::Exception("DataArrayDouble::setSelectedComponents : input DataArrayDouble is NULL !");
2255 copyPartOfStringInfoFrom2(compoIds,*a);
2256 std::size_t partOfCompoSz=compoIds.size();
2257 int nbOfCompo=getNumberOfComponents();
2258 int nbOfTuples=std::min(getNumberOfTuples(),a->getNumberOfTuples());
2259 const double *ac=a->getConstPointer();
2260 double *nc=getPointer();
2261 for(int i=0;i<nbOfTuples;i++)
2262 for(std::size_t j=0;j<partOfCompoSz;j++,ac++)
2263 nc[nbOfCompo*i+compoIds[j]]=*ac;
2267 * Copy all values from another DataArrayDouble into specified tuples and components
2268 * of \a this array. Textual data is not copied.
2269 * The tree parameters defining set of indices of tuples and components are similar to
2270 * the tree parameters of the Python function \c range(\c start,\c stop,\c step).
2271 * \param [in] a - the array to copy values from.
2272 * \param [in] bgTuples - index of the first tuple of \a this array to assign values to.
2273 * \param [in] endTuples - index of the tuple before which the tuples to assign to
2275 * \param [in] stepTuples - index increment to get index of the next tuple to assign to.
2276 * \param [in] bgComp - index of the first component of \a this array to assign values to.
2277 * \param [in] endComp - index of the component before which the components to assign
2279 * \param [in] stepComp - index increment to get index of the next component to assign to.
2280 * \param [in] strictCompoCompare - if \a true (by default), then \a a->getNumberOfComponents()
2281 * must be equal to the number of columns to assign to, else an
2282 * exception is thrown; if \a false, then it is only required that \a
2283 * a->getNbOfElems() equals to number of values to assign to (this condition
2284 * must be respected even if \a strictCompoCompare is \a true). The number of
2285 * values to assign to is given by following Python expression:
2286 * \a nbTargetValues =
2287 * \c len(\c range(\a bgTuples,\a endTuples,\a stepTuples)) *
2288 * \c len(\c range(\a bgComp,\a endComp,\a stepComp)).
2289 * \throw If \a a is NULL.
2290 * \throw If \a a is not allocated.
2291 * \throw If \a this is not allocated.
2292 * \throw If parameters specifying tuples and components to assign to do not give a
2293 * non-empty range of increasing indices.
2294 * \throw If \a a->getNbOfElems() != \a nbTargetValues.
2295 * \throw If \a strictCompoCompare == \a true && \a a->getNumberOfComponents() !=
2296 * \c len(\c range(\a bgComp,\a endComp,\a stepComp)).
2298 * \if ENABLE_EXAMPLES
2299 * \ref py_mcdataarraydouble_setpartofvalues1 "Here is a Python example".
2302 void DataArrayDouble::setPartOfValues1(const DataArrayDouble *a, int bgTuples, int endTuples, int stepTuples, int bgComp, int endComp, int stepComp, bool strictCompoCompare)
2305 throw INTERP_KERNEL::Exception("DataArrayDouble::setPartOfValues1 : input DataArrayDouble is NULL !");
2306 const char msg[]="DataArrayDouble::setPartOfValues1";
2308 a->checkAllocated();
2309 int newNbOfTuples=DataArray::GetNumberOfItemGivenBES(bgTuples,endTuples,stepTuples,msg);
2310 int newNbOfComp=DataArray::GetNumberOfItemGivenBES(bgComp,endComp,stepComp,msg);
2311 int nbComp=getNumberOfComponents();
2312 int nbOfTuples=getNumberOfTuples();
2313 DataArray::CheckValueInRangeEx(nbOfTuples,bgTuples,endTuples,"invalid tuple value");
2314 DataArray::CheckValueInRangeEx(nbComp,bgComp,endComp,"invalid component value");
2315 bool assignTech=true;
2316 if(a->getNbOfElems()==(std::size_t)newNbOfTuples*newNbOfComp)
2318 if(strictCompoCompare)
2319 a->checkNbOfTuplesAndComp(newNbOfTuples,newNbOfComp,msg);
2323 a->checkNbOfTuplesAndComp(1,newNbOfComp,msg);
2326 const double *srcPt=a->getConstPointer();
2327 double *pt=getPointer()+bgTuples*nbComp+bgComp;
2330 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
2331 for(int j=0;j<newNbOfComp;j++,srcPt++)
2332 pt[j*stepComp]=*srcPt;
2336 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
2338 const double *srcPt2=srcPt;
2339 for(int j=0;j<newNbOfComp;j++,srcPt2++)
2340 pt[j*stepComp]=*srcPt2;
2346 * Assign a given value to values at specified tuples and components of \a this array.
2347 * The tree parameters defining set of indices of tuples and components are similar to
2348 * the tree parameters of the Python function \c range(\c start,\c stop,\c step)..
2349 * \param [in] a - the value to assign.
2350 * \param [in] bgTuples - index of the first tuple of \a this array to assign to.
2351 * \param [in] endTuples - index of the tuple before which the tuples to assign to
2353 * \param [in] stepTuples - index increment to get index of the next tuple to assign to.
2354 * \param [in] bgComp - index of the first component of \a this array to assign to.
2355 * \param [in] endComp - index of the component before which the components to assign
2357 * \param [in] stepComp - index increment to get index of the next component to assign to.
2358 * \throw If \a this is not allocated.
2359 * \throw If parameters specifying tuples and components to assign to, do not give a
2360 * non-empty range of increasing indices or indices are out of a valid range
2363 * \if ENABLE_EXAMPLES
2364 * \ref py_mcdataarraydouble_setpartofvaluessimple1 "Here is a Python example".
2367 void DataArrayDouble::setPartOfValuesSimple1(double a, int bgTuples, int endTuples, int stepTuples, int bgComp, int endComp, int stepComp)
2369 const char msg[]="DataArrayDouble::setPartOfValuesSimple1";
2371 int newNbOfTuples=DataArray::GetNumberOfItemGivenBES(bgTuples,endTuples,stepTuples,msg);
2372 int newNbOfComp=DataArray::GetNumberOfItemGivenBES(bgComp,endComp,stepComp,msg);
2373 int nbComp=getNumberOfComponents();
2374 int nbOfTuples=getNumberOfTuples();
2375 DataArray::CheckValueInRangeEx(nbOfTuples,bgTuples,endTuples,"invalid tuple value");
2376 DataArray::CheckValueInRangeEx(nbComp,bgComp,endComp,"invalid component value");
2377 double *pt=getPointer()+bgTuples*nbComp+bgComp;
2378 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
2379 for(int j=0;j<newNbOfComp;j++)
2384 * Copy all values from another DataArrayDouble (\a a) into specified tuples and
2385 * components of \a this array. Textual data is not copied.
2386 * The tuples and components to assign to are defined by C arrays of indices.
2387 * There are two *modes of usage*:
2388 * - If \a a->getNbOfElems() equals to number of values to assign to, then every value
2389 * of \a a is assigned to its own location within \a this array.
2390 * - If \a a includes one tuple, then all values of \a a are assigned to the specified
2391 * components of every specified tuple of \a this array. In this mode it is required
2392 * that \a a->getNumberOfComponents() equals to the number of specified components.
2394 * \param [in] a - the array to copy values from.
2395 * \param [in] bgTuples - pointer to an array of tuple indices of \a this array to
2396 * assign values of \a a to.
2397 * \param [in] endTuples - specifies the end of the array \a bgTuples, so that
2398 * pointer to a tuple index <em>(pi)</em> varies as this:
2399 * \a bgTuples <= \a pi < \a endTuples.
2400 * \param [in] bgComp - pointer to an array of component indices of \a this array to
2401 * assign values of \a a to.
2402 * \param [in] endComp - specifies the end of the array \a bgTuples, so that
2403 * pointer to a component index <em>(pi)</em> varies as this:
2404 * \a bgComp <= \a pi < \a endComp.
2405 * \param [in] strictCompoCompare - this parameter is checked only if the
2406 * *mode of usage* is the first; if it is \a true (default),
2407 * then \a a->getNumberOfComponents() must be equal
2408 * to the number of specified columns, else this is not required.
2409 * \throw If \a a is NULL.
2410 * \throw If \a a is not allocated.
2411 * \throw If \a this is not allocated.
2412 * \throw If any index of tuple/component given by <em>bgTuples / bgComp</em> is
2413 * out of a valid range for \a this array.
2414 * \throw In the first *mode of usage*, if <em>strictCompoCompare == true </em> and
2415 * if <em> a->getNumberOfComponents() != (endComp - bgComp) </em>.
2416 * \throw In the second *mode of usage*, if \a a->getNumberOfTuples() != 1 or
2417 * <em> a->getNumberOfComponents() != (endComp - bgComp)</em>.
2419 * \if ENABLE_EXAMPLES
2420 * \ref py_mcdataarraydouble_setpartofvalues2 "Here is a Python example".
2423 void DataArrayDouble::setPartOfValues2(const DataArrayDouble *a, const int *bgTuples, const int *endTuples, const int *bgComp, const int *endComp, bool strictCompoCompare)
2426 throw INTERP_KERNEL::Exception("DataArrayDouble::setPartOfValues2 : input DataArrayDouble is NULL !");
2427 const char msg[]="DataArrayDouble::setPartOfValues2";
2429 a->checkAllocated();
2430 int nbComp=getNumberOfComponents();
2431 int nbOfTuples=getNumberOfTuples();
2432 for(const int *z=bgComp;z!=endComp;z++)
2433 DataArray::CheckValueInRange(nbComp,*z,"invalid component id");
2434 int newNbOfTuples=(int)std::distance(bgTuples,endTuples);
2435 int newNbOfComp=(int)std::distance(bgComp,endComp);
2436 bool assignTech=true;
2437 if(a->getNbOfElems()==(std::size_t)newNbOfTuples*newNbOfComp)
2439 if(strictCompoCompare)
2440 a->checkNbOfTuplesAndComp(newNbOfTuples,newNbOfComp,msg);
2444 a->checkNbOfTuplesAndComp(1,newNbOfComp,msg);
2447 double *pt=getPointer();
2448 const double *srcPt=a->getConstPointer();
2451 for(const int *w=bgTuples;w!=endTuples;w++)
2453 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
2454 for(const int *z=bgComp;z!=endComp;z++,srcPt++)
2456 pt[(std::size_t)(*w)*nbComp+(*z)]=*srcPt;
2462 for(const int *w=bgTuples;w!=endTuples;w++)
2464 const double *srcPt2=srcPt;
2465 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
2466 for(const int *z=bgComp;z!=endComp;z++,srcPt2++)
2468 pt[(std::size_t)(*w)*nbComp+(*z)]=*srcPt2;
2475 * Assign a given value to values at specified tuples and components of \a this array.
2476 * The tuples and components to assign to are defined by C arrays of indices.
2477 * \param [in] a - the value to assign.
2478 * \param [in] bgTuples - pointer to an array of tuple indices of \a this array to
2480 * \param [in] endTuples - specifies the end of the array \a bgTuples, so that
2481 * pointer to a tuple index (\a pi) varies as this:
2482 * \a bgTuples <= \a pi < \a endTuples.
2483 * \param [in] bgComp - pointer to an array of component indices of \a this array to
2485 * \param [in] endComp - specifies the end of the array \a bgTuples, so that
2486 * pointer to a component index (\a pi) varies as this:
2487 * \a bgComp <= \a pi < \a endComp.
2488 * \throw If \a this is not allocated.
2489 * \throw If any index of tuple/component given by <em>bgTuples / bgComp</em> is
2490 * out of a valid range for \a this array.
2492 * \if ENABLE_EXAMPLES
2493 * \ref py_mcdataarraydouble_setpartofvaluessimple2 "Here is a Python example".
2496 void DataArrayDouble::setPartOfValuesSimple2(double a, const int *bgTuples, const int *endTuples, const int *bgComp, const int *endComp)
2499 int nbComp=getNumberOfComponents();
2500 int nbOfTuples=getNumberOfTuples();
2501 for(const int *z=bgComp;z!=endComp;z++)
2502 DataArray::CheckValueInRange(nbComp,*z,"invalid component id");
2503 double *pt=getPointer();
2504 for(const int *w=bgTuples;w!=endTuples;w++)
2505 for(const int *z=bgComp;z!=endComp;z++)
2507 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
2508 pt[(std::size_t)(*w)*nbComp+(*z)]=a;
2513 * Copy all values from another DataArrayDouble (\a a) into specified tuples and
2514 * components of \a this array. Textual data is not copied.
2515 * The tuples to assign to are defined by a C array of indices.
2516 * The components to assign to are defined by three values similar to parameters of
2517 * the Python function \c range(\c start,\c stop,\c step).
2518 * There are two *modes of usage*:
2519 * - If \a a->getNbOfElems() equals to number of values to assign to, then every value
2520 * of \a a is assigned to its own location within \a this array.
2521 * - If \a a includes one tuple, then all values of \a a are assigned to the specified
2522 * components of every specified tuple of \a this array. In this mode it is required
2523 * that \a a->getNumberOfComponents() equals to the number of specified components.
2525 * \param [in] a - the array to copy values from.
2526 * \param [in] bgTuples - pointer to an array of tuple indices of \a this array to
2527 * assign values of \a a to.
2528 * \param [in] endTuples - specifies the end of the array \a bgTuples, so that
2529 * pointer to a tuple index <em>(pi)</em> varies as this:
2530 * \a bgTuples <= \a pi < \a endTuples.
2531 * \param [in] bgComp - index of the first component of \a this array to assign to.
2532 * \param [in] endComp - index of the component before which the components to assign
2534 * \param [in] stepComp - index increment to get index of the next component to assign to.
2535 * \param [in] strictCompoCompare - this parameter is checked only in the first
2536 * *mode of usage*; if \a strictCompoCompare is \a true (default),
2537 * then \a a->getNumberOfComponents() must be equal
2538 * to the number of specified columns, else this is not required.
2539 * \throw If \a a is NULL.
2540 * \throw If \a a is not allocated.
2541 * \throw If \a this is not allocated.
2542 * \throw If any index of tuple given by \a bgTuples is out of a valid range for
2544 * \throw In the first *mode of usage*, if <em>strictCompoCompare == true </em> and
2545 * if <em> a->getNumberOfComponents()</em> is unequal to the number of components
2546 * defined by <em>(bgComp,endComp,stepComp)</em>.
2547 * \throw In the second *mode of usage*, if \a a->getNumberOfTuples() != 1 or
2548 * <em> a->getNumberOfComponents()</em> is unequal to the number of components
2549 * defined by <em>(bgComp,endComp,stepComp)</em>.
2550 * \throw If parameters specifying components to assign to, do not give a
2551 * non-empty range of increasing indices or indices are out of a valid range
2554 * \if ENABLE_EXAMPLES
2555 * \ref py_mcdataarraydouble_setpartofvalues3 "Here is a Python example".
2558 void DataArrayDouble::setPartOfValues3(const DataArrayDouble *a, const int *bgTuples, const int *endTuples, int bgComp, int endComp, int stepComp, bool strictCompoCompare)
2561 throw INTERP_KERNEL::Exception("DataArrayDouble::setPartOfValues3 : input DataArrayDouble is NULL !");
2562 const char msg[]="DataArrayDouble::setPartOfValues3";
2564 a->checkAllocated();
2565 int newNbOfComp=DataArray::GetNumberOfItemGivenBES(bgComp,endComp,stepComp,msg);
2566 int nbComp=getNumberOfComponents();
2567 int nbOfTuples=getNumberOfTuples();
2568 DataArray::CheckValueInRangeEx(nbComp,bgComp,endComp,"invalid component value");
2569 int newNbOfTuples=(int)std::distance(bgTuples,endTuples);
2570 bool assignTech=true;
2571 if(a->getNbOfElems()==(std::size_t)newNbOfTuples*newNbOfComp)
2573 if(strictCompoCompare)
2574 a->checkNbOfTuplesAndComp(newNbOfTuples,newNbOfComp,msg);
2578 a->checkNbOfTuplesAndComp(1,newNbOfComp,msg);
2581 double *pt=getPointer()+bgComp;
2582 const double *srcPt=a->getConstPointer();
2585 for(const int *w=bgTuples;w!=endTuples;w++)
2586 for(int j=0;j<newNbOfComp;j++,srcPt++)
2588 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
2589 pt[(std::size_t)(*w)*nbComp+j*stepComp]=*srcPt;
2594 for(const int *w=bgTuples;w!=endTuples;w++)
2596 const double *srcPt2=srcPt;
2597 for(int j=0;j<newNbOfComp;j++,srcPt2++)
2599 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
2600 pt[(std::size_t)(*w)*nbComp+j*stepComp]=*srcPt2;
2607 * Assign a given value to values at specified tuples and components of \a this array.
2608 * The tuples to assign to are defined by a C array of indices.
2609 * The components to assign to are defined by three values similar to parameters of
2610 * the Python function \c range(\c start,\c stop,\c step).
2611 * \param [in] a - the value to assign.
2612 * \param [in] bgTuples - pointer to an array of tuple indices of \a this array to
2614 * \param [in] endTuples - specifies the end of the array \a bgTuples, so that
2615 * pointer to a tuple index <em>(pi)</em> varies as this:
2616 * \a bgTuples <= \a pi < \a endTuples.
2617 * \param [in] bgComp - index of the first component of \a this array to assign to.
2618 * \param [in] endComp - index of the component before which the components to assign
2620 * \param [in] stepComp - index increment to get index of the next component to assign to.
2621 * \throw If \a this is not allocated.
2622 * \throw If any index of tuple given by \a bgTuples is out of a valid range for
2624 * \throw If parameters specifying components to assign to, do not give a
2625 * non-empty range of increasing indices or indices are out of a valid range
2628 * \if ENABLE_EXAMPLES
2629 * \ref py_mcdataarraydouble_setpartofvaluessimple3 "Here is a Python example".
2632 void DataArrayDouble::setPartOfValuesSimple3(double a, const int *bgTuples, const int *endTuples, int bgComp, int endComp, int stepComp)
2634 const char msg[]="DataArrayDouble::setPartOfValuesSimple3";
2636 int newNbOfComp=DataArray::GetNumberOfItemGivenBES(bgComp,endComp,stepComp,msg);
2637 int nbComp=getNumberOfComponents();
2638 int nbOfTuples=getNumberOfTuples();
2639 DataArray::CheckValueInRangeEx(nbComp,bgComp,endComp,"invalid component value");
2640 double *pt=getPointer()+bgComp;
2641 for(const int *w=bgTuples;w!=endTuples;w++)
2642 for(int j=0;j<newNbOfComp;j++)
2644 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
2645 pt[(std::size_t)(*w)*nbComp+j*stepComp]=a;
2650 * Copy all values from another DataArrayDouble into specified tuples and components
2651 * of \a this array. Textual data is not copied.
2652 * The tree parameters defining set of indices of tuples and components are similar to
2653 * the tree parameters of the Python function \c range(\c start,\c stop,\c step).
2654 * \param [in] a - the array to copy values from.
2655 * \param [in] bgTuples - index of the first tuple of \a this array to assign values to.
2656 * \param [in] endTuples - index of the tuple before which the tuples to assign to
2658 * \param [in] stepTuples - index increment to get index of the next tuple to assign to.
2659 * \param [in] bgComp - pointer to an array of component indices of \a this array to
2661 * \param [in] endComp - specifies the end of the array \a bgTuples, so that
2662 * pointer to a component index (\a pi) varies as this:
2663 * \a bgComp <= \a pi < \a endComp.
2664 * \param [in] strictCompoCompare - if \a true (by default), then \a a->getNumberOfComponents()
2665 * must be equal to the number of columns to assign to, else an
2666 * exception is thrown; if \a false, then it is only required that \a
2667 * a->getNbOfElems() equals to number of values to assign to (this condition
2668 * must be respected even if \a strictCompoCompare is \a true). The number of
2669 * values to assign to is given by following Python expression:
2670 * \a nbTargetValues =
2671 * \c len(\c range(\a bgTuples,\a endTuples,\a stepTuples)) *
2672 * \c len(\c range(\a bgComp,\a endComp,\a stepComp)).
2673 * \throw If \a a is NULL.
2674 * \throw If \a a is not allocated.
2675 * \throw If \a this is not allocated.
2676 * \throw If parameters specifying tuples and components to assign to do not give a
2677 * non-empty range of increasing indices.
2678 * \throw If \a a->getNbOfElems() != \a nbTargetValues.
2679 * \throw If \a strictCompoCompare == \a true && \a a->getNumberOfComponents() !=
2680 * \c len(\c range(\a bgComp,\a endComp,\a stepComp)).
2683 void DataArrayDouble::setPartOfValues4(const DataArrayDouble *a, int bgTuples, int endTuples, int stepTuples, const int *bgComp, const int *endComp, bool strictCompoCompare)
2686 throw INTERP_KERNEL::Exception("DataArrayDouble::setPartOfValues4 : input DataArrayDouble is NULL !");
2687 const char msg[]="DataArrayDouble::setPartOfValues4";
2689 a->checkAllocated();
2690 int newNbOfTuples=DataArray::GetNumberOfItemGivenBES(bgTuples,endTuples,stepTuples,msg);
2691 int newNbOfComp=(int)std::distance(bgComp,endComp);
2692 int nbComp=getNumberOfComponents();
2693 for(const int *z=bgComp;z!=endComp;z++)
2694 DataArray::CheckValueInRange(nbComp,*z,"invalid component id");
2695 int nbOfTuples=getNumberOfTuples();
2696 DataArray::CheckValueInRangeEx(nbOfTuples,bgTuples,endTuples,"invalid tuple value");
2697 bool assignTech=true;
2698 if(a->getNbOfElems()==(std::size_t)newNbOfTuples*newNbOfComp)
2700 if(strictCompoCompare)
2701 a->checkNbOfTuplesAndComp(newNbOfTuples,newNbOfComp,msg);
2705 a->checkNbOfTuplesAndComp(1,newNbOfComp,msg);
2708 const double *srcPt=a->getConstPointer();
2709 double *pt=getPointer()+bgTuples*nbComp;
2712 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
2713 for(const int *z=bgComp;z!=endComp;z++,srcPt++)
2718 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
2720 const double *srcPt2=srcPt;
2721 for(const int *z=bgComp;z!=endComp;z++,srcPt2++)
2727 void DataArrayDouble::setPartOfValuesSimple4(double a, int bgTuples, int endTuples, int stepTuples, const int *bgComp, const int *endComp)
2729 const char msg[]="DataArrayDouble::setPartOfValuesSimple4";
2731 int newNbOfTuples=DataArray::GetNumberOfItemGivenBES(bgTuples,endTuples,stepTuples,msg);
2732 int nbComp=getNumberOfComponents();
2733 for(const int *z=bgComp;z!=endComp;z++)
2734 DataArray::CheckValueInRange(nbComp,*z,"invalid component id");
2735 int nbOfTuples=getNumberOfTuples();
2736 DataArray::CheckValueInRangeEx(nbOfTuples,bgTuples,endTuples,"invalid tuple value");
2737 double *pt=getPointer()+bgTuples*nbComp;
2738 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
2739 for(const int *z=bgComp;z!=endComp;z++)
2744 * Copy some tuples from another DataArrayDouble into specified tuples
2745 * of \a this array. Textual data is not copied. Both arrays must have equal number of
2747 * Both the tuples to assign and the tuples to assign to are defined by a DataArrayInt.
2748 * All components of selected tuples are copied.
2749 * \param [in] a - the array to copy values from.
2750 * \param [in] tuplesSelec - the array specifying both source tuples of \a a and
2751 * target tuples of \a this. \a tuplesSelec has two components, and the
2752 * first component specifies index of the source tuple and the second
2753 * one specifies index of the target tuple.
2754 * \throw If \a this is not allocated.
2755 * \throw If \a a is NULL.
2756 * \throw If \a a is not allocated.
2757 * \throw If \a tuplesSelec is NULL.
2758 * \throw If \a tuplesSelec is not allocated.
2759 * \throw If <em>this->getNumberOfComponents() != a->getNumberOfComponents()</em>.
2760 * \throw If \a tuplesSelec->getNumberOfComponents() != 2.
2761 * \throw If any tuple index given by \a tuplesSelec is out of a valid range for
2762 * the corresponding (\a this or \a a) array.
2764 void DataArrayDouble::setPartOfValuesAdv(const DataArrayDouble *a, const DataArrayInt *tuplesSelec)
2766 if(!a || !tuplesSelec)
2767 throw INTERP_KERNEL::Exception("DataArrayDouble::setPartOfValuesAdv : input DataArrayDouble is NULL !");
2769 a->checkAllocated();
2770 tuplesSelec->checkAllocated();
2771 int nbOfComp=getNumberOfComponents();
2772 if(nbOfComp!=a->getNumberOfComponents())
2773 throw INTERP_KERNEL::Exception("DataArrayDouble::setPartOfValuesAdv : This and a do not have the same number of components !");
2774 if(tuplesSelec->getNumberOfComponents()!=2)
2775 throw INTERP_KERNEL::Exception("DataArrayDouble::setPartOfValuesAdv : Expecting to have a tuple selector DataArrayInt instance with exactly 2 components !");
2776 int thisNt=getNumberOfTuples();
2777 int aNt=a->getNumberOfTuples();
2778 double *valsToSet=getPointer();
2779 const double *valsSrc=a->getConstPointer();
2780 for(const int *tuple=tuplesSelec->begin();tuple!=tuplesSelec->end();tuple+=2)
2782 if(tuple[1]>=0 && tuple[1]<aNt)
2784 if(tuple[0]>=0 && tuple[0]<thisNt)
2785 std::copy(valsSrc+nbOfComp*tuple[1],valsSrc+nbOfComp*(tuple[1]+1),valsToSet+nbOfComp*tuple[0]);
2788 std::ostringstream oss; oss << "DataArrayDouble::setPartOfValuesAdv : Tuple #" << std::distance(tuplesSelec->begin(),tuple)/2;
2789 oss << " of 'tuplesSelec' request of tuple id #" << tuple[0] << " in 'this' ! It should be in [0," << thisNt << ") !";
2790 throw INTERP_KERNEL::Exception(oss.str().c_str());
2795 std::ostringstream oss; oss << "DataArrayDouble::setPartOfValuesAdv : Tuple #" << std::distance(tuplesSelec->begin(),tuple)/2;
2796 oss << " of 'tuplesSelec' request of tuple id #" << tuple[1] << " in 'a' ! It should be in [0," << aNt << ") !";
2797 throw INTERP_KERNEL::Exception(oss.str().c_str());
2803 * Copy some tuples from another DataArrayDouble (\a aBase) into contiguous tuples
2804 * of \a this array. Textual data is not copied. Both arrays must have equal number of
2806 * The tuples to assign to are defined by index of the first tuple, and
2807 * their number is defined by \a tuplesSelec->getNumberOfTuples().
2808 * The tuples to copy are defined by values of a DataArrayInt.
2809 * All components of selected tuples are copied.
2810 * \param [in] tupleIdStart - index of the first tuple of \a this array to assign
2812 * \param [in] aBase - the array to copy values from.
2813 * \param [in] tuplesSelec - the array specifying tuples of \a a to copy.
2814 * \throw If \a this is not allocated.
2815 * \throw If \a aBase is NULL.
2816 * \throw If \a aBase is not allocated.
2817 * \throw If \a tuplesSelec is NULL.
2818 * \throw If \a tuplesSelec is not allocated.
2819 * \throw If <em>this->getNumberOfComponents() != aBase->getNumberOfComponents()</em>.
2820 * \throw If \a tuplesSelec->getNumberOfComponents() != 1.
2821 * \throw If <em>tupleIdStart + tuplesSelec->getNumberOfTuples() > this->getNumberOfTuples().</em>
2822 * \throw If any tuple index given by \a tuplesSelec is out of a valid range for
2825 void DataArrayDouble::setContigPartOfSelectedValues(int tupleIdStart, const DataArray *aBase, const DataArrayInt *tuplesSelec)
2827 if(!aBase || !tuplesSelec)
2828 throw INTERP_KERNEL::Exception("DataArrayDouble::setContigPartOfSelectedValues : input DataArray is NULL !");
2829 const DataArrayDouble *a=dynamic_cast<const DataArrayDouble *>(aBase);
2831 throw INTERP_KERNEL::Exception("DataArrayDouble::setContigPartOfSelectedValues : input DataArray aBase is not a DataArrayDouble !");
2833 a->checkAllocated();
2834 tuplesSelec->checkAllocated();
2835 int nbOfComp=getNumberOfComponents();
2836 if(nbOfComp!=a->getNumberOfComponents())
2837 throw INTERP_KERNEL::Exception("DataArrayDouble::setContigPartOfSelectedValues : This and a do not have the same number of components !");
2838 if(tuplesSelec->getNumberOfComponents()!=1)
2839 throw INTERP_KERNEL::Exception("DataArrayDouble::setContigPartOfSelectedValues : Expecting to have a tuple selector DataArrayInt instance with exactly 1 component !");
2840 int thisNt=getNumberOfTuples();
2841 int aNt=a->getNumberOfTuples();
2842 int nbOfTupleToWrite=tuplesSelec->getNumberOfTuples();
2843 double *valsToSet=getPointer()+tupleIdStart*nbOfComp;
2844 if(tupleIdStart+nbOfTupleToWrite>thisNt)
2845 throw INTERP_KERNEL::Exception("DataArrayDouble::setContigPartOfSelectedValues : invalid number range of values to write !");
2846 const double *valsSrc=a->getConstPointer();
2847 for(const int *tuple=tuplesSelec->begin();tuple!=tuplesSelec->end();tuple++,valsToSet+=nbOfComp)
2849 if(*tuple>=0 && *tuple<aNt)
2851 std::copy(valsSrc+nbOfComp*(*tuple),valsSrc+nbOfComp*(*tuple+1),valsToSet);
2855 std::ostringstream oss; oss << "DataArrayDouble::setContigPartOfSelectedValues : Tuple #" << std::distance(tuplesSelec->begin(),tuple);
2856 oss << " of 'tuplesSelec' request of tuple id #" << *tuple << " in 'a' ! It should be in [0," << aNt << ") !";
2857 throw INTERP_KERNEL::Exception(oss.str().c_str());
2863 * Copy some tuples from another DataArrayDouble (\a aBase) into contiguous tuples
2864 * of \a this array. Textual data is not copied. Both arrays must have equal number of
2866 * The tuples to copy are defined by three values similar to parameters of
2867 * the Python function \c range(\c start,\c stop,\c step).
2868 * The tuples to assign to are defined by index of the first tuple, and
2869 * their number is defined by number of tuples to copy.
2870 * All components of selected tuples are copied.
2871 * \param [in] tupleIdStart - index of the first tuple of \a this array to assign
2873 * \param [in] aBase - the array to copy values from.
2874 * \param [in] bg - index of the first tuple to copy of the array \a aBase.
2875 * \param [in] end2 - index of the tuple of \a aBase before which the tuples to copy
2877 * \param [in] step - index increment to get index of the next tuple to copy.
2878 * \throw If \a this is not allocated.
2879 * \throw If \a aBase is NULL.
2880 * \throw If \a aBase is not allocated.
2881 * \throw If <em>this->getNumberOfComponents() != aBase->getNumberOfComponents()</em>.
2882 * \throw If <em>tupleIdStart + len(range(bg,end2,step)) > this->getNumberOfTuples().</em>
2883 * \throw If parameters specifying tuples to copy, do not give a
2884 * non-empty range of increasing indices or indices are out of a valid range
2885 * for the array \a aBase.
2887 void DataArrayDouble::setContigPartOfSelectedValues2(int tupleIdStart, const DataArray *aBase, int bg, int end2, int step)
2890 throw INTERP_KERNEL::Exception("DataArrayDouble::setContigPartOfSelectedValues2 : input DataArray is NULL !");
2891 const DataArrayDouble *a=dynamic_cast<const DataArrayDouble *>(aBase);
2893 throw INTERP_KERNEL::Exception("DataArrayDouble::setContigPartOfSelectedValues2 : input DataArray aBase is not a DataArrayDouble !");
2895 a->checkAllocated();
2896 int nbOfComp=getNumberOfComponents();
2897 const char msg[]="DataArrayDouble::setContigPartOfSelectedValues2";
2898 int nbOfTupleToWrite=DataArray::GetNumberOfItemGivenBES(bg,end2,step,msg);
2899 if(nbOfComp!=a->getNumberOfComponents())
2900 throw INTERP_KERNEL::Exception("DataArrayDouble::setContigPartOfSelectedValues2 : This and a do not have the same number of components !");
2901 int thisNt=getNumberOfTuples();
2902 int aNt=a->getNumberOfTuples();
2903 double *valsToSet=getPointer()+tupleIdStart*nbOfComp;
2904 if(tupleIdStart+nbOfTupleToWrite>thisNt)
2905 throw INTERP_KERNEL::Exception("DataArrayDouble::setContigPartOfSelectedValues2 : invalid number range of values to write !");
2907 throw INTERP_KERNEL::Exception("DataArrayDouble::setContigPartOfSelectedValues2 : invalid range of values to read !");
2908 const double *valsSrc=a->getConstPointer()+bg*nbOfComp;
2909 for(int i=0;i<nbOfTupleToWrite;i++,valsToSet+=nbOfComp,valsSrc+=step*nbOfComp)
2911 std::copy(valsSrc,valsSrc+nbOfComp,valsToSet);
2916 * Returns a value located at specified tuple and component.
2917 * This method is equivalent to DataArrayDouble::getIJ() except that validity of
2918 * parameters is checked. So this method is safe but expensive if used to go through
2919 * all values of \a this.
2920 * \param [in] tupleId - index of tuple of interest.
2921 * \param [in] compoId - index of component of interest.
2922 * \return double - value located by \a tupleId and \a compoId.
2923 * \throw If \a this is not allocated.
2924 * \throw If condition <em>( 0 <= tupleId < this->getNumberOfTuples() )</em> is violated.
2925 * \throw If condition <em>( 0 <= compoId < this->getNumberOfComponents() )</em> is violated.
2927 double DataArrayDouble::getIJSafe(int tupleId, int compoId) const
2930 if(tupleId<0 || tupleId>=getNumberOfTuples())
2932 std::ostringstream oss; oss << "DataArrayDouble::getIJSafe : request for tupleId " << tupleId << " should be in [0," << getNumberOfTuples() << ") !";
2933 throw INTERP_KERNEL::Exception(oss.str().c_str());
2935 if(compoId<0 || compoId>=getNumberOfComponents())
2937 std::ostringstream oss; oss << "DataArrayDouble::getIJSafe : request for compoId " << compoId << " should be in [0," << getNumberOfComponents() << ") !";
2938 throw INTERP_KERNEL::Exception(oss.str().c_str());
2940 return _mem[tupleId*_info_on_compo.size()+compoId];
2944 * Returns the first value of \a this.
2945 * \return double - the last value of \a this array.
2946 * \throw If \a this is not allocated.
2947 * \throw If \a this->getNumberOfComponents() != 1.
2948 * \throw If \a this->getNumberOfTuples() < 1.
2950 double DataArrayDouble::front() const
2953 if(getNumberOfComponents()!=1)
2954 throw INTERP_KERNEL::Exception("DataArrayDouble::front : number of components not equal to one !");
2955 int nbOfTuples=getNumberOfTuples();
2957 throw INTERP_KERNEL::Exception("DataArrayDouble::front : number of tuples must be >= 1 !");
2958 return *(getConstPointer());
2962 * Returns the last value of \a this.
2963 * \return double - the last value of \a this array.
2964 * \throw If \a this is not allocated.
2965 * \throw If \a this->getNumberOfComponents() != 1.
2966 * \throw If \a this->getNumberOfTuples() < 1.
2968 double DataArrayDouble::back() const
2971 if(getNumberOfComponents()!=1)
2972 throw INTERP_KERNEL::Exception("DataArrayDouble::back : number of components not equal to one !");
2973 int nbOfTuples=getNumberOfTuples();
2975 throw INTERP_KERNEL::Exception("DataArrayDouble::back : number of tuples must be >= 1 !");
2976 return *(getConstPointer()+nbOfTuples-1);
2979 void DataArrayDouble::SetArrayIn(DataArrayDouble *newArray, DataArrayDouble* &arrayToSet)
2981 if(newArray!=arrayToSet)
2984 arrayToSet->decrRef();
2985 arrayToSet=newArray;
2987 arrayToSet->incrRef();
2992 * Sets a C array to be used as raw data of \a this. The previously set info
2993 * of components is retained and re-sized.
2994 * For more info see \ref MEDCouplingArraySteps1.
2995 * \param [in] array - the C array to be used as raw data of \a this.
2996 * \param [in] ownership - if \a true, \a array will be deallocated at destruction of \a this.
2997 * \param [in] type - specifies how to deallocate \a array. If \a type == ParaMEDMEM::CPP_DEALLOC,
2998 * \c delete [] \c array; will be called. If \a type == ParaMEDMEM::C_DEALLOC,
2999 * \c free(\c array ) will be called.
3000 * \param [in] nbOfTuple - new number of tuples in \a this.
3001 * \param [in] nbOfCompo - new number of components in \a this.
3003 void DataArrayDouble::useArray(const double *array, bool ownership, DeallocType type, int nbOfTuple, int nbOfCompo)
3005 _info_on_compo.resize(nbOfCompo);
3006 _mem.useArray(array,ownership,type,(std::size_t)nbOfTuple*nbOfCompo);
3010 void DataArrayDouble::useExternalArrayWithRWAccess(const double *array, int nbOfTuple, int nbOfCompo)
3012 _info_on_compo.resize(nbOfCompo);
3013 _mem.useExternalArrayWithRWAccess(array,(std::size_t)nbOfTuple*nbOfCompo);
3018 * Checks if 0.0 value is present in \a this array. If it is the case, an exception
3020 * \throw If zero is found in \a this array.
3022 void DataArrayDouble::checkNoNullValues() const
3024 const double *tmp=getConstPointer();
3025 std::size_t nbOfElems=getNbOfElems();
3026 const double *where=std::find(tmp,tmp+nbOfElems,0.);
3027 if(where!=tmp+nbOfElems)
3028 throw INTERP_KERNEL::Exception("A value 0.0 have been detected !");
3032 * Computes minimal and maximal value in each component. An output array is filled
3033 * with \c 2 * \a this->getNumberOfComponents() values, so the caller is to allocate
3034 * enough memory before calling this method.
3035 * \param [out] bounds - array of size at least 2 *\a this->getNumberOfComponents().
3036 * It is filled as follows:<br>
3037 * \a bounds[0] = \c min_of_component_0 <br>
3038 * \a bounds[1] = \c max_of_component_0 <br>
3039 * \a bounds[2] = \c min_of_component_1 <br>
3040 * \a bounds[3] = \c max_of_component_1 <br>
3043 void DataArrayDouble::getMinMaxPerComponent(double *bounds) const
3046 int dim=getNumberOfComponents();
3047 for (int idim=0; idim<dim; idim++)
3049 bounds[idim*2]=std::numeric_limits<double>::max();
3050 bounds[idim*2+1]=-std::numeric_limits<double>::max();
3052 const double *ptr=getConstPointer();
3053 int nbOfTuples=getNumberOfTuples();
3054 for(int i=0;i<nbOfTuples;i++)
3056 for(int idim=0;idim<dim;idim++)
3058 if(bounds[idim*2]>ptr[i*dim+idim])
3060 bounds[idim*2]=ptr[i*dim+idim];
3062 if(bounds[idim*2+1]<ptr[i*dim+idim])
3064 bounds[idim*2+1]=ptr[i*dim+idim];
3071 * This method retrieves a newly allocated DataArrayDouble instance having same number of tuples than \a this and twice number of components than \a this
3072 * to store both the min and max per component of each tuples.
3073 * \param [in] epsilon the width of the bbox (identical in each direction) - 0.0 by default
3075 * \return a newly created DataArrayDouble instance having \c this->getNumberOfTuples() tuples and 2 * \c this->getNumberOfComponent() components
3077 * \throw If \a this is not allocated yet.
3079 DataArrayDouble *DataArrayDouble::computeBBoxPerTuple(double epsilon) const
3082 const double *dataPtr=getConstPointer();
3083 int nbOfCompo=getNumberOfComponents();
3084 int nbTuples=getNumberOfTuples();
3085 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> bbox=DataArrayDouble::New();
3086 bbox->alloc(nbTuples,2*nbOfCompo);
3087 double *bboxPtr=bbox->getPointer();
3088 for(int i=0;i<nbTuples;i++)
3090 for(int j=0;j<nbOfCompo;j++)
3092 bboxPtr[2*nbOfCompo*i+2*j]=dataPtr[nbOfCompo*i+j]-epsilon;
3093 bboxPtr[2*nbOfCompo*i+2*j+1]=dataPtr[nbOfCompo*i+j]+epsilon;
3100 * For each tuples **t** in \a other, this method retrieves tuples in \a this that are equal to **t**.
3101 * Two tuples are considered equal if the euclidian distance between the two tuples is lower than \a eps.
3103 * \param [in] other a DataArrayDouble having same number of components than \a this.
3104 * \param [in] eps absolute precision representing distance (using infinite norm) between 2 tuples behind which 2 tuples are considered equal.
3105 * \param [out] c will contain the set of tuple ids in \a this that are equal to to the tuple ids in \a other contiguously.
3106 * \a cI allows to extract information in \a c.
3107 * \param [out] cI is an indirection array that allows to extract the data contained in \a c.
3109 * \throw In case of:
3110 * - \a this is not allocated
3111 * - \a other is not allocated or null
3112 * - \a this and \a other do not have the same number of components
3113 * - if number of components of \a this is not in [1,2,3]
3115 * \sa MEDCouplingPointSet::getNodeIdsNearPoints, DataArrayDouble::getDifferentValues
3117 void DataArrayDouble::computeTupleIdsNearTuples(const DataArrayDouble *other, double eps, DataArrayInt *& c, DataArrayInt *& cI) const
3120 throw INTERP_KERNEL::Exception("DataArrayDouble::computeTupleIdsNearTuples : input pointer other is null !");
3122 other->checkAllocated();
3123 int nbOfCompo=getNumberOfComponents();
3124 int otherNbOfCompo=other->getNumberOfComponents();
3125 if(nbOfCompo!=otherNbOfCompo)
3126 throw INTERP_KERNEL::Exception("DataArrayDouble::computeTupleIdsNearTuples : number of components should be equal between this and other !");
3127 int nbOfTuplesOther=other->getNumberOfTuples();
3128 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> cArr(DataArrayInt::New()),cIArr(DataArrayInt::New()); cArr->alloc(0,1); cIArr->pushBackSilent(0);
3133 BBTreePts<3,int> myTree(begin(),0,0,getNumberOfTuples(),eps);
3134 FindTupleIdsNearTuplesAlg<3>(myTree,other->getConstPointer(),nbOfTuplesOther,eps,cArr,cIArr);
3139 BBTreePts<2,int> myTree(begin(),0,0,getNumberOfTuples(),eps);
3140 FindTupleIdsNearTuplesAlg<2>(myTree,other->getConstPointer(),nbOfTuplesOther,eps,cArr,cIArr);
3145 BBTreePts<1,int> myTree(begin(),0,0,getNumberOfTuples(),eps);
3146 FindTupleIdsNearTuplesAlg<1>(myTree,other->getConstPointer(),nbOfTuplesOther,eps,cArr,cIArr);
3150 throw INTERP_KERNEL::Exception("Unexpected spacedim of coords for computeTupleIdsNearTuples. Must be 1, 2 or 3.");
3152 c=cArr.retn(); cI=cIArr.retn();
3156 * This method recenter tuples in \b this in order to be centered at the origin to benefit about the advantages of maximal precision to be around the box
3157 * around origin of 'radius' 1.
3159 * \param [in] eps absolute epsilon. under that value of delta between max and min no scale is performed.
3161 void DataArrayDouble::recenterForMaxPrecision(double eps)
3164 int dim=getNumberOfComponents();
3165 std::vector<double> bounds(2*dim);
3166 getMinMaxPerComponent(&bounds[0]);
3167 for(int i=0;i<dim;i++)
3169 double delta=bounds[2*i+1]-bounds[2*i];
3170 double offset=(bounds[2*i]+bounds[2*i+1])/2.;
3172 applyLin(1./delta,-offset/delta,i);
3174 applyLin(1.,-offset,i);
3179 * Returns the maximal value and its location within \a this one-dimensional array.
3180 * \param [out] tupleId - index of the tuple holding the maximal value.
3181 * \return double - the maximal value among all values of \a this array.
3182 * \throw If \a this->getNumberOfComponents() != 1
3183 * \throw If \a this->getNumberOfTuples() < 1
3185 double DataArrayDouble::getMaxValue(int& tupleId) const
3188 if(getNumberOfComponents()!=1)
3189 throw INTERP_KERNEL::Exception("DataArrayDouble::getMaxValue : must be applied on DataArrayDouble with only one component, you can call 'rearrange' method before or call 'getMaxValueInArray' method !");
3190 int nbOfTuples=getNumberOfTuples();
3192 throw INTERP_KERNEL::Exception("DataArrayDouble::getMaxValue : array exists but number of tuples must be > 0 !");
3193 const double *vals=getConstPointer();
3194 const double *loc=std::max_element(vals,vals+nbOfTuples);
3195 tupleId=(int)std::distance(vals,loc);
3200 * Returns the maximal value within \a this array that is allowed to have more than
3202 * \return double - the maximal value among all values of \a this array.
3203 * \throw If \a this is not allocated.
3205 double DataArrayDouble::getMaxValueInArray() const
3208 const double *loc=std::max_element(begin(),end());
3213 * Returns the maximal value and all its locations within \a this one-dimensional array.
3214 * \param [out] tupleIds - a new instance of DataArrayInt containg indices of
3215 * tuples holding the maximal value. The caller is to delete it using
3216 * decrRef() as it is no more needed.
3217 * \return double - the maximal value among all values of \a this array.
3218 * \throw If \a this->getNumberOfComponents() != 1
3219 * \throw If \a this->getNumberOfTuples() < 1
3221 double DataArrayDouble::getMaxValue2(DataArrayInt*& tupleIds) const
3225 double ret=getMaxValue(tmp);
3226 tupleIds=getIdsInRange(ret,ret);
3231 * Returns the minimal value and its location within \a this one-dimensional array.
3232 * \param [out] tupleId - index of the tuple holding the minimal value.
3233 * \return double - the minimal value among all values of \a this array.
3234 * \throw If \a this->getNumberOfComponents() != 1
3235 * \throw If \a this->getNumberOfTuples() < 1
3237 double DataArrayDouble::getMinValue(int& tupleId) const
3240 if(getNumberOfComponents()!=1)
3241 throw INTERP_KERNEL::Exception("DataArrayDouble::getMinValue : must be applied on DataArrayDouble with only one component, you can call 'rearrange' method before call 'getMinValueInArray' method !");
3242 int nbOfTuples=getNumberOfTuples();
3244 throw INTERP_KERNEL::Exception("DataArrayDouble::getMinValue : array exists but number of tuples must be > 0 !");
3245 const double *vals=getConstPointer();
3246 const double *loc=std::min_element(vals,vals+nbOfTuples);
3247 tupleId=(int)std::distance(vals,loc);
3252 * Returns the minimal value within \a this array that is allowed to have more than
3254 * \return double - the minimal value among all values of \a this array.
3255 * \throw If \a this is not allocated.
3257 double DataArrayDouble::getMinValueInArray() const
3260 const double *loc=std::min_element(begin(),end());
3265 * Returns the minimal value and all its locations within \a this one-dimensional array.
3266 * \param [out] tupleIds - a new instance of DataArrayInt containg indices of
3267 * tuples holding the minimal value. The caller is to delete it using
3268 * decrRef() as it is no more needed.
3269 * \return double - the minimal value among all values of \a this array.
3270 * \throw If \a this->getNumberOfComponents() != 1
3271 * \throw If \a this->getNumberOfTuples() < 1
3273 double DataArrayDouble::getMinValue2(DataArrayInt*& tupleIds) const
3277 double ret=getMinValue(tmp);
3278 tupleIds=getIdsInRange(ret,ret);
3283 * This method returns the number of values in \a this that are equals ( within an absolute precision of \a eps ) to input parameter \a value.
3284 * This method only works for single component array.
3286 * \return a value in [ 0, \c this->getNumberOfTuples() )
3288 * \throw If \a this is not allocated
3291 int DataArrayDouble::count(double value, double eps) const
3295 if(getNumberOfComponents()!=1)
3296 throw INTERP_KERNEL::Exception("DataArrayDouble::count : must be applied on DataArrayDouble with only one component, you can call 'rearrange' method before !");
3297 const double *vals=begin();
3298 int nbOfTuples=getNumberOfTuples();
3299 for(int i=0;i<nbOfTuples;i++,vals++)
3300 if(fabs(*vals-value)<=eps)
3306 * Returns the average value of \a this one-dimensional array.
3307 * \return double - the average value over all values of \a this array.
3308 * \throw If \a this->getNumberOfComponents() != 1
3309 * \throw If \a this->getNumberOfTuples() < 1
3311 double DataArrayDouble::getAverageValue() const
3313 if(getNumberOfComponents()!=1)
3314 throw INTERP_KERNEL::Exception("DataArrayDouble::getAverageValue : must be applied on DataArrayDouble with only one component, you can call 'rearrange' method before !");
3315 int nbOfTuples=getNumberOfTuples();
3317 throw INTERP_KERNEL::Exception("DataArrayDouble::getAverageValue : array exists but number of tuples must be > 0 !");
3318 const double *vals=getConstPointer();
3319 double ret=std::accumulate(vals,vals+nbOfTuples,0.);
3320 return ret/nbOfTuples;
3324 * Returns the Euclidean norm of the vector defined by \a this array.
3325 * \return double - the value of the Euclidean norm, i.e.
3326 * the square root of the inner product of vector.
3327 * \throw If \a this is not allocated.
3329 double DataArrayDouble::norm2() const
3333 std::size_t nbOfElems=getNbOfElems();
3334 const double *pt=getConstPointer();
3335 for(std::size_t i=0;i<nbOfElems;i++,pt++)
3341 * Returns the maximum norm of the vector defined by \a this array.
3342 * This method works even if the number of components is diferent from one.
3343 * If the number of elements in \a this is 0, -1. is returned.
3344 * \return double - the value of the maximum norm, i.e.
3345 * the maximal absolute value among values of \a this array (whatever its number of components).
3346 * \throw If \a this is not allocated.
3348 double DataArrayDouble::normMax() const
3352 std::size_t nbOfElems(getNbOfElems());
3353 const double *pt(getConstPointer());
3354 for(std::size_t i=0;i<nbOfElems;i++,pt++)
3356 double val(std::abs(*pt));
3364 * Returns the minimum norm (absolute value) of the vector defined by \a this array.
3365 * This method works even if the number of components is diferent from one.
3366 * If the number of elements in \a this is 0, std::numeric_limits<double>::max() is returned.
3367 * \return double - the value of the minimum norm, i.e.
3368 * the minimal absolute value among values of \a this array (whatever its number of components).
3369 * \throw If \a this is not allocated.
3371 double DataArrayDouble::normMin() const
3374 double ret(std::numeric_limits<double>::max());
3375 std::size_t nbOfElems(getNbOfElems());
3376 const double *pt(getConstPointer());
3377 for(std::size_t i=0;i<nbOfElems;i++,pt++)
3379 double val(std::abs(*pt));
3387 * Accumulates values of each component of \a this array.
3388 * \param [out] res - an array of length \a this->getNumberOfComponents(), allocated
3389 * by the caller, that is filled by this method with sum value for each
3391 * \throw If \a this is not allocated.
3393 void DataArrayDouble::accumulate(double *res) const
3396 const double *ptr=getConstPointer();
3397 int nbTuple=getNumberOfTuples();
3398 int nbComps=getNumberOfComponents();
3399 std::fill(res,res+nbComps,0.);
3400 for(int i=0;i<nbTuple;i++)
3401 std::transform(ptr+i*nbComps,ptr+(i+1)*nbComps,res,res,std::plus<double>());
3405 * This method returns the min distance from an external tuple defined by [ \a tupleBg , \a tupleEnd ) to \a this and
3406 * the first tuple in \a this that matches the returned distance. If there is no tuples in \a this an exception will be thrown.
3409 * \a this is expected to be allocated and expected to have a number of components equal to the distance from \a tupleBg to
3410 * \a tupleEnd. If not an exception will be thrown.
3412 * \param [in] tupleBg start pointer (included) of input external tuple
3413 * \param [in] tupleEnd end pointer (not included) of input external tuple
3414 * \param [out] tupleId the tuple id in \a this that matches the min of distance between \a this and input external tuple
3415 * \return the min distance.
3416 * \sa MEDCouplingUMesh::distanceToPoint
3418 double DataArrayDouble::distanceToTuple(const double *tupleBg, const double *tupleEnd, int& tupleId) const
3421 int nbTuple=getNumberOfTuples();
3422 int nbComps=getNumberOfComponents();
3423 if(nbComps!=(int)std::distance(tupleBg,tupleEnd))
3424 { std::ostringstream oss; oss << "DataArrayDouble::distanceToTuple : size of input tuple is " << std::distance(tupleBg,tupleEnd) << " should be equal to the number of components in this : " << nbComps << " !"; throw INTERP_KERNEL::Exception(oss.str().c_str()); }
3426 throw INTERP_KERNEL::Exception("DataArrayDouble::distanceToTuple : no tuple in this ! No distance to compute !");
3427 double ret0=std::numeric_limits<double>::max();
3429 const double *work=getConstPointer();
3430 for(int i=0;i<nbTuple;i++)
3433 for(int j=0;j<nbComps;j++,work++)
3434 val+=(*work-tupleBg[j])*((*work-tupleBg[j]));
3438 { ret0=val; tupleId=i; }
3444 * Accumulate values of the given component of \a this array.
3445 * \param [in] compId - the index of the component of interest.
3446 * \return double - a sum value of \a compId-th component.
3447 * \throw If \a this is not allocated.
3448 * \throw If \a the condition ( 0 <= \a compId < \a this->getNumberOfComponents() ) is
3451 double DataArrayDouble::accumulate(int compId) const
3454 const double *ptr=getConstPointer();
3455 int nbTuple=getNumberOfTuples();
3456 int nbComps=getNumberOfComponents();
3457 if(compId<0 || compId>=nbComps)
3458 throw INTERP_KERNEL::Exception("DataArrayDouble::accumulate : Invalid compId specified : No such nb of components !");
3460 for(int i=0;i<nbTuple;i++)
3461 ret+=ptr[i*nbComps+compId];
3466 * This method accumulate using addition tuples in \a this using input index array [ \a bgOfIndex, \a endOfIndex ).
3467 * The returned array will have same number of components than \a this and number of tuples equal to
3468 * \c std::distance(bgOfIndex,endOfIndex) \b minus \b one.
3470 * The input index array is expected to be ascendingly sorted in which the all referenced ids should be in [0, \c this->getNumberOfTuples).
3471 * This method is quite useful for users that need to put a field on cells to field on nodes on the same mesh without a need of conservation.
3473 * \param [in] bgOfIndex - begin (included) of the input index array.
3474 * \param [in] endOfIndex - end (excluded) of the input index array.
3475 * \return DataArrayDouble * - the new instance having the same number of components than \a this.
3477 * \throw If bgOfIndex or end is NULL.
3478 * \throw If input index array is not ascendingly sorted.
3479 * \throw If there is an id in [ \a bgOfIndex, \a endOfIndex ) not in [0, \c this->getNumberOfTuples).
3480 * \throw If std::distance(bgOfIndex,endOfIndex)==0.
3482 DataArrayDouble *DataArrayDouble::accumulatePerChunck(const int *bgOfIndex, const int *endOfIndex) const
3484 if(!bgOfIndex || !endOfIndex)
3485 throw INTERP_KERNEL::Exception("DataArrayDouble::accumulatePerChunck : input pointer NULL !");
3487 int nbCompo=getNumberOfComponents();
3488 int nbOfTuples=getNumberOfTuples();
3489 int sz=(int)std::distance(bgOfIndex,endOfIndex);
3491 throw INTERP_KERNEL::Exception("DataArrayDouble::accumulatePerChunck : invalid size of input index array !");
3493 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New(); ret->alloc(sz,nbCompo);
3494 const int *w=bgOfIndex;
3495 if(*w<0 || *w>=nbOfTuples)
3496 throw INTERP_KERNEL::Exception("DataArrayDouble::accumulatePerChunck : The first element of the input index not in [0,nbOfTuples) !");
3497 const double *srcPt=begin()+(*w)*nbCompo;
3498 double *tmp=ret->getPointer();
3499 for(int i=0;i<sz;i++,tmp+=nbCompo,w++)
3501 std::fill(tmp,tmp+nbCompo,0.);
3504 for(int j=w[0];j<w[1];j++,srcPt+=nbCompo)
3506 if(j>=0 && j<nbOfTuples)
3507 std::transform(srcPt,srcPt+nbCompo,tmp,tmp,std::plus<double>());
3510 std::ostringstream oss; oss << "DataArrayDouble::accumulatePerChunck : At rank #" << i << " the input index array points to id " << j << " should be in [0," << nbOfTuples << ") !";
3511 throw INTERP_KERNEL::Exception(oss.str().c_str());
3517 std::ostringstream oss; oss << "DataArrayDouble::accumulatePerChunck : At rank #" << i << " the input index array is not in ascendingly sorted.";
3518 throw INTERP_KERNEL::Exception(oss.str().c_str());
3521 ret->copyStringInfoFrom(*this);
3526 * Converts each 2D point defined by the tuple of \a this array from the Polar to the
3527 * Cartesian coordinate system. The two components of the tuple of \a this array are
3528 * considered to contain (1) radius and (2) angle of the point in the Polar CS.
3529 * \return DataArrayDouble * - the new instance of DataArrayDouble, whose each tuple
3530 * contains X and Y coordinates of the point in the Cartesian CS. The caller
3531 * is to delete this array using decrRef() as it is no more needed. The array
3532 * does not contain any textual info on components.
3533 * \throw If \a this->getNumberOfComponents() != 2.
3535 DataArrayDouble *DataArrayDouble::fromPolarToCart() const
3538 int nbOfComp=getNumberOfComponents();
3540 throw INTERP_KERNEL::Exception("DataArrayDouble::fromPolarToCart : must be an array with exactly 2 components !");
3541 int nbOfTuple=getNumberOfTuples();
3542 DataArrayDouble *ret=DataArrayDouble::New();
3543 ret->alloc(nbOfTuple,2);
3544 double *w=ret->getPointer();
3545 const double *wIn=getConstPointer();
3546 for(int i=0;i<nbOfTuple;i++,w+=2,wIn+=2)
3548 w[0]=wIn[0]*cos(wIn[1]);
3549 w[1]=wIn[0]*sin(wIn[1]);
3555 * Converts each 3D point defined by the tuple of \a this array from the Cylindrical to
3556 * the Cartesian coordinate system. The three components of the tuple of \a this array
3557 * are considered to contain (1) radius, (2) azimuth and (3) altitude of the point in
3558 * the Cylindrical CS.
3559 * \return DataArrayDouble * - the new instance of DataArrayDouble, whose each tuple
3560 * contains X, Y and Z coordinates of the point in the Cartesian CS. The info
3561 * on the third component is copied from \a this array. The caller
3562 * is to delete this array using decrRef() as it is no more needed.
3563 * \throw If \a this->getNumberOfComponents() != 3.
3565 DataArrayDouble *DataArrayDouble::fromCylToCart() const
3568 int nbOfComp=getNumberOfComponents();
3570 throw INTERP_KERNEL::Exception("DataArrayDouble::fromCylToCart : must be an array with exactly 3 components !");
3571 int nbOfTuple=getNumberOfTuples();
3572 DataArrayDouble *ret=DataArrayDouble::New();
3573 ret->alloc(getNumberOfTuples(),3);
3574 double *w=ret->getPointer();
3575 const double *wIn=getConstPointer();
3576 for(int i=0;i<nbOfTuple;i++,w+=3,wIn+=3)
3578 w[0]=wIn[0]*cos(wIn[1]);
3579 w[1]=wIn[0]*sin(wIn[1]);
3582 ret->setInfoOnComponent(2,getInfoOnComponent(2));
3587 * Converts each 3D point defined by the tuple of \a this array from the Spherical to
3588 * the Cartesian coordinate system. The three components of the tuple of \a this array
3589 * are considered to contain (1) radius, (2) polar angle and (3) azimuthal angle of the
3590 * point in the Cylindrical CS.
3591 * \return DataArrayDouble * - the new instance of DataArrayDouble, whose each tuple
3592 * contains X, Y and Z coordinates of the point in the Cartesian CS. The info
3593 * on the third component is copied from \a this array. The caller
3594 * is to delete this array using decrRef() as it is no more needed.
3595 * \throw If \a this->getNumberOfComponents() != 3.
3597 DataArrayDouble *DataArrayDouble::fromSpherToCart() const
3600 int nbOfComp=getNumberOfComponents();
3602 throw INTERP_KERNEL::Exception("DataArrayDouble::fromSpherToCart : must be an array with exactly 3 components !");
3603 int nbOfTuple=getNumberOfTuples();
3604 DataArrayDouble *ret=DataArrayDouble::New();
3605 ret->alloc(getNumberOfTuples(),3);
3606 double *w=ret->getPointer();
3607 const double *wIn=getConstPointer();
3608 for(int i=0;i<nbOfTuple;i++,w+=3,wIn+=3)
3610 w[0]=wIn[0]*cos(wIn[2])*sin(wIn[1]);
3611 w[1]=wIn[0]*sin(wIn[2])*sin(wIn[1]);
3612 w[2]=wIn[0]*cos(wIn[1]);
3618 * Computes the doubly contracted product of every tensor defined by the tuple of \a this
3619 * array contating 6 components.
3620 * \return DataArrayDouble * - the new instance of DataArrayDouble, whose each tuple
3621 * is calculated from the tuple <em>(t)</em> of \a this array as follows:
3622 * \f$ t[0]^2+t[1]^2+t[2]^2+2*t[3]^2+2*t[4]^2+2*t[5]^2\f$.
3623 * The caller is to delete this result array using decrRef() as it is no more needed.
3624 * \throw If \a this->getNumberOfComponents() != 6.
3626 DataArrayDouble *DataArrayDouble::doublyContractedProduct() const
3629 int nbOfComp=getNumberOfComponents();
3631 throw INTERP_KERNEL::Exception("DataArrayDouble::doublyContractedProduct : must be an array with exactly 6 components !");
3632 DataArrayDouble *ret=DataArrayDouble::New();
3633 int nbOfTuple=getNumberOfTuples();
3634 ret->alloc(nbOfTuple,1);
3635 const double *src=getConstPointer();
3636 double *dest=ret->getPointer();
3637 for(int i=0;i<nbOfTuple;i++,dest++,src+=6)
3638 *dest=src[0]*src[0]+src[1]*src[1]+src[2]*src[2]+2.*src[3]*src[3]+2.*src[4]*src[4]+2.*src[5]*src[5];
3643 * Computes the determinant of every square matrix defined by the tuple of \a this
3644 * array, which contains either 4, 6 or 9 components. The case of 6 components
3645 * corresponds to that of the upper triangular matrix.
3646 * \return DataArrayDouble * - the new instance of DataArrayDouble, whose each tuple
3647 * is the determinant of matrix of the corresponding tuple of \a this array.
3648 * The caller is to delete this result array using decrRef() as it is no more
3650 * \throw If \a this->getNumberOfComponents() is not in [4,6,9].
3652 DataArrayDouble *DataArrayDouble::determinant() const
3655 DataArrayDouble *ret=DataArrayDouble::New();
3656 int nbOfTuple=getNumberOfTuples();
3657 ret->alloc(nbOfTuple,1);
3658 const double *src=getConstPointer();
3659 double *dest=ret->getPointer();
3660 switch(getNumberOfComponents())
3663 for(int i=0;i<nbOfTuple;i++,dest++,src+=6)
3664 *dest=src[0]*src[1]*src[2]+2.*src[4]*src[5]*src[3]-src[0]*src[4]*src[4]-src[2]*src[3]*src[3]-src[1]*src[5]*src[5];
3667 for(int i=0;i<nbOfTuple;i++,dest++,src+=4)
3668 *dest=src[0]*src[3]-src[1]*src[2];
3671 for(int i=0;i<nbOfTuple;i++,dest++,src+=9)
3672 *dest=src[0]*src[4]*src[8]+src[1]*src[5]*src[6]+src[2]*src[3]*src[7]-src[0]*src[5]*src[7]-src[1]*src[3]*src[8]-src[2]*src[4]*src[6];
3676 throw INTERP_KERNEL::Exception("DataArrayDouble::determinant : Invalid number of components ! must be in 4,6,9 !");
3681 * Computes 3 eigenvalues of every upper triangular matrix defined by the tuple of
3682 * \a this array, which contains 6 components.
3683 * \return DataArrayDouble * - the new instance of DataArrayDouble containing 3
3684 * components, whose each tuple contains the eigenvalues of the matrix of
3685 * corresponding tuple of \a this array.
3686 * The caller is to delete this result array using decrRef() as it is no more
3688 * \throw If \a this->getNumberOfComponents() != 6.
3690 DataArrayDouble *DataArrayDouble::eigenValues() const
3693 int nbOfComp=getNumberOfComponents();
3695 throw INTERP_KERNEL::Exception("DataArrayDouble::eigenValues : must be an array with exactly 6 components !");
3696 DataArrayDouble *ret=DataArrayDouble::New();
3697 int nbOfTuple=getNumberOfTuples();
3698 ret->alloc(nbOfTuple,3);
3699 const double *src=getConstPointer();
3700 double *dest=ret->getPointer();
3701 for(int i=0;i<nbOfTuple;i++,dest+=3,src+=6)
3702 INTERP_KERNEL::computeEigenValues6(src,dest);
3707 * Computes 3 eigenvectors of every upper triangular matrix defined by the tuple of
3708 * \a this array, which contains 6 components.
3709 * \return DataArrayDouble * - the new instance of DataArrayDouble containing 9
3710 * components, whose each tuple contains 3 eigenvectors of the matrix of
3711 * corresponding tuple of \a this array.
3712 * The caller is to delete this result array using decrRef() as it is no more
3714 * \throw If \a this->getNumberOfComponents() != 6.
3716 DataArrayDouble *DataArrayDouble::eigenVectors() const
3719 int nbOfComp=getNumberOfComponents();
3721 throw INTERP_KERNEL::Exception("DataArrayDouble::eigenVectors : must be an array with exactly 6 components !");
3722 DataArrayDouble *ret=DataArrayDouble::New();
3723 int nbOfTuple=getNumberOfTuples();
3724 ret->alloc(nbOfTuple,9);
3725 const double *src=getConstPointer();
3726 double *dest=ret->getPointer();
3727 for(int i=0;i<nbOfTuple;i++,src+=6)
3730 INTERP_KERNEL::computeEigenValues6(src,tmp);
3731 for(int j=0;j<3;j++,dest+=3)
3732 INTERP_KERNEL::computeEigenVectorForEigenValue6(src,tmp[j],1e-12,dest);
3738 * Computes the inverse matrix of every matrix defined by the tuple of \a this
3739 * array, which contains either 4, 6 or 9 components. The case of 6 components
3740 * corresponds to that of the upper triangular matrix.
3741 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
3742 * same number of components as \a this one, whose each tuple is the inverse
3743 * matrix of the matrix of corresponding tuple of \a this array.
3744 * The caller is to delete this result array using decrRef() as it is no more
3746 * \throw If \a this->getNumberOfComponents() is not in [4,6,9].
3748 DataArrayDouble *DataArrayDouble::inverse() const
3751 int nbOfComp=getNumberOfComponents();
3752 if(nbOfComp!=6 && nbOfComp!=9 && nbOfComp!=4)
3753 throw INTERP_KERNEL::Exception("DataArrayDouble::inversion : must be an array with 4,6 or 9 components !");
3754 DataArrayDouble *ret=DataArrayDouble::New();
3755 int nbOfTuple=getNumberOfTuples();
3756 ret->alloc(nbOfTuple,nbOfComp);
3757 const double *src=getConstPointer();
3758 double *dest=ret->getPointer();
3760 for(int i=0;i<nbOfTuple;i++,dest+=6,src+=6)
3762 double det=src[0]*src[1]*src[2]+2.*src[4]*src[5]*src[3]-src[0]*src[4]*src[4]-src[2]*src[3]*src[3]-src[1]*src[5]*src[5];
3763 dest[0]=(src[1]*src[2]-src[4]*src[4])/det;
3764 dest[1]=(src[0]*src[2]-src[5]*src[5])/det;
3765 dest[2]=(src[0]*src[1]-src[3]*src[3])/det;
3766 dest[3]=(src[5]*src[4]-src[3]*src[2])/det;
3767 dest[4]=(src[5]*src[3]-src[0]*src[4])/det;
3768 dest[5]=(src[3]*src[4]-src[1]*src[5])/det;
3770 else if(nbOfComp==4)
3771 for(int i=0;i<nbOfTuple;i++,dest+=4,src+=4)
3773 double det=src[0]*src[3]-src[1]*src[2];
3775 dest[1]=-src[1]/det;
3776 dest[2]=-src[2]/det;
3780 for(int i=0;i<nbOfTuple;i++,dest+=9,src+=9)
3782 double det=src[0]*src[4]*src[8]+src[1]*src[5]*src[6]+src[2]*src[3]*src[7]-src[0]*src[5]*src[7]-src[1]*src[3]*src[8]-src[2]*src[4]*src[6];
3783 dest[0]=(src[4]*src[8]-src[7]*src[5])/det;
3784 dest[1]=(src[7]*src[2]-src[1]*src[8])/det;
3785 dest[2]=(src[1]*src[5]-src[4]*src[2])/det;
3786 dest[3]=(src[6]*src[5]-src[3]*src[8])/det;
3787 dest[4]=(src[0]*src[8]-src[6]*src[2])/det;
3788 dest[5]=(src[2]*src[3]-src[0]*src[5])/det;
3789 dest[6]=(src[3]*src[7]-src[6]*src[4])/det;
3790 dest[7]=(src[6]*src[1]-src[0]*src[7])/det;
3791 dest[8]=(src[0]*src[4]-src[1]*src[3])/det;
3797 * Computes the trace of every matrix defined by the tuple of \a this
3798 * array, which contains either 4, 6 or 9 components. The case of 6 components
3799 * corresponds to that of the upper triangular matrix.
3800 * \return DataArrayDouble * - the new instance of DataArrayDouble containing
3801 * 1 component, whose each tuple is the trace of
3802 * the matrix of corresponding tuple of \a this array.
3803 * The caller is to delete this result array using decrRef() as it is no more
3805 * \throw If \a this->getNumberOfComponents() is not in [4,6,9].
3807 DataArrayDouble *DataArrayDouble::trace() const
3810 int nbOfComp=getNumberOfComponents();
3811 if(nbOfComp!=6 && nbOfComp!=9 && nbOfComp!=4)
3812 throw INTERP_KERNEL::Exception("DataArrayDouble::trace : must be an array with 4,6 or 9 components !");
3813 DataArrayDouble *ret=DataArrayDouble::New();
3814 int nbOfTuple=getNumberOfTuples();
3815 ret->alloc(nbOfTuple,1);
3816 const double *src=getConstPointer();
3817 double *dest=ret->getPointer();
3819 for(int i=0;i<nbOfTuple;i++,dest++,src+=6)
3820 *dest=src[0]+src[1]+src[2];
3821 else if(nbOfComp==4)
3822 for(int i=0;i<nbOfTuple;i++,dest++,src+=4)
3823 *dest=src[0]+src[3];
3825 for(int i=0;i<nbOfTuple;i++,dest++,src+=9)
3826 *dest=src[0]+src[4]+src[8];
3831 * Computes the stress deviator tensor of every stress tensor defined by the tuple of
3832 * \a this array, which contains 6 components.
3833 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
3834 * same number of components and tuples as \a this array.
3835 * The caller is to delete this result array using decrRef() as it is no more
3837 * \throw If \a this->getNumberOfComponents() != 6.
3839 DataArrayDouble *DataArrayDouble::deviator() const
3842 int nbOfComp=getNumberOfComponents();
3844 throw INTERP_KERNEL::Exception("DataArrayDouble::deviator : must be an array with exactly 6 components !");
3845 DataArrayDouble *ret=DataArrayDouble::New();
3846 int nbOfTuple=getNumberOfTuples();
3847 ret->alloc(nbOfTuple,6);
3848 const double *src=getConstPointer();
3849 double *dest=ret->getPointer();
3850 for(int i=0;i<nbOfTuple;i++,dest+=6,src+=6)
3852 double tr=(src[0]+src[1]+src[2])/3.;
3864 * Computes the magnitude of every vector defined by the tuple of
3866 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
3867 * same number of tuples as \a this array and one component.
3868 * The caller is to delete this result array using decrRef() as it is no more
3870 * \throw If \a this is not allocated.
3872 DataArrayDouble *DataArrayDouble::magnitude() const
3875 int nbOfComp=getNumberOfComponents();
3876 DataArrayDouble *ret=DataArrayDouble::New();
3877 int nbOfTuple=getNumberOfTuples();
3878 ret->alloc(nbOfTuple,1);
3879 const double *src=getConstPointer();
3880 double *dest=ret->getPointer();
3881 for(int i=0;i<nbOfTuple;i++,dest++)
3884 for(int j=0;j<nbOfComp;j++,src++)
3892 * Computes for each tuple the sum of number of components values in the tuple and return it.
3894 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
3895 * same number of tuples as \a this array and one component.
3896 * The caller is to delete this result array using decrRef() as it is no more
3898 * \throw If \a this is not allocated.
3900 DataArrayDouble *DataArrayDouble::sumPerTuple() const
3903 int nbOfComp(getNumberOfComponents()),nbOfTuple(getNumberOfTuples());
3904 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret(DataArrayDouble::New());
3905 ret->alloc(nbOfTuple,1);
3906 const double *src(getConstPointer());
3907 double *dest(ret->getPointer());
3908 for(int i=0;i<nbOfTuple;i++,dest++,src+=nbOfComp)
3909 *dest=std::accumulate(src,src+nbOfComp,0.);
3914 * Computes the maximal value within every tuple of \a this array.
3915 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
3916 * same number of tuples as \a this array and one component.
3917 * The caller is to delete this result array using decrRef() as it is no more
3919 * \throw If \a this is not allocated.
3920 * \sa DataArrayDouble::maxPerTupleWithCompoId
3922 DataArrayDouble *DataArrayDouble::maxPerTuple() const
3925 int nbOfComp=getNumberOfComponents();
3926 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
3927 int nbOfTuple=getNumberOfTuples();
3928 ret->alloc(nbOfTuple,1);
3929 const double *src=getConstPointer();
3930 double *dest=ret->getPointer();
3931 for(int i=0;i<nbOfTuple;i++,dest++,src+=nbOfComp)
3932 *dest=*std::max_element(src,src+nbOfComp);
3937 * Computes the maximal value within every tuple of \a this array and it returns the first component
3938 * id for each tuple that corresponds to the maximal value within the tuple.
3940 * \param [out] compoIdOfMaxPerTuple - the new new instance of DataArrayInt containing the
3941 * same number of tuples and only one component.
3942 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
3943 * same number of tuples as \a this array and one component.
3944 * The caller is to delete this result array using decrRef() as it is no more
3946 * \throw If \a this is not allocated.
3947 * \sa DataArrayDouble::maxPerTuple
3949 DataArrayDouble *DataArrayDouble::maxPerTupleWithCompoId(DataArrayInt* &compoIdOfMaxPerTuple) const
3952 int nbOfComp=getNumberOfComponents();
3953 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret0=DataArrayDouble::New();
3954 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret1=DataArrayInt::New();
3955 int nbOfTuple=getNumberOfTuples();
3956 ret0->alloc(nbOfTuple,1); ret1->alloc(nbOfTuple,1);
3957 const double *src=getConstPointer();
3958 double *dest=ret0->getPointer(); int *dest1=ret1->getPointer();
3959 for(int i=0;i<nbOfTuple;i++,dest++,dest1++,src+=nbOfComp)
3961 const double *loc=std::max_element(src,src+nbOfComp);
3963 *dest1=(int)std::distance(src,loc);
3965 compoIdOfMaxPerTuple=ret1.retn();
3970 * This method returns a newly allocated DataArrayDouble instance having one component and \c this->getNumberOfTuples() * \c this->getNumberOfTuples() tuples.
3971 * \n This returned array contains the euclidian distance for each tuple in \a this.
3972 * \n So the returned array can be seen as a dense symmetrical matrix whose diagonal elements are equal to 0.
3973 * \n The returned array has only one component (and **not** \c this->getNumberOfTuples() components to avoid the useless memory consumption due to components info in returned DataArrayDouble)
3975 * \warning use this method with care because it can leads to big amount of consumed memory !
3977 * \return A newly allocated (huge) ParaMEDMEM::DataArrayDouble instance that the caller should deal with.
3979 * \throw If \a this is not allocated.
3981 * \sa DataArrayDouble::buildEuclidianDistanceDenseMatrixWith
3983 DataArrayDouble *DataArrayDouble::buildEuclidianDistanceDenseMatrix() const
3986 int nbOfComp=getNumberOfComponents();
3987 int nbOfTuples=getNumberOfTuples();
3988 const double *inData=getConstPointer();
3989 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
3990 ret->alloc(nbOfTuples*nbOfTuples,1);
3991 double *outData=ret->getPointer();
3992 for(int i=0;i<nbOfTuples;i++)
3994 outData[i*nbOfTuples+i]=0.;
3995 for(int j=i+1;j<nbOfTuples;j++)
3998 for(int k=0;k<nbOfComp;k++)
3999 { double delta=inData[i*nbOfComp+k]-inData[j*nbOfComp+k]; dist+=delta*delta; }
4001 outData[i*nbOfTuples+j]=dist;
4002 outData[j*nbOfTuples+i]=dist;
4009 * This method returns a newly allocated DataArrayDouble instance having one component and \c this->getNumberOfTuples() * \c other->getNumberOfTuples() tuples.
4010 * \n This returned array contains the euclidian distance for each tuple in \a other with each tuple in \a this.
4011 * \n So the returned array can be seen as a dense rectangular matrix with \c other->getNumberOfTuples() rows and \c this->getNumberOfTuples() columns.
4012 * \n Output rectangular matrix is sorted along rows.
4013 * \n The returned array has only one component (and **not** \c this->getNumberOfTuples() components to avoid the useless memory consumption due to components info in returned DataArrayDouble)
4015 * \warning use this method with care because it can leads to big amount of consumed memory !
4017 * \param [in] other DataArrayDouble instance having same number of components than \a this.
4018 * \return A newly allocated (huge) ParaMEDMEM::DataArrayDouble instance that the caller should deal with.
4020 * \throw If \a this is not allocated, or if \a other is null or if \a other is not allocated, or if number of components of \a other and \a this differs.
4022 * \sa DataArrayDouble::buildEuclidianDistanceDenseMatrix
4024 DataArrayDouble *DataArrayDouble::buildEuclidianDistanceDenseMatrixWith(const DataArrayDouble *other) const
4027 throw INTERP_KERNEL::Exception("DataArrayDouble::buildEuclidianDistanceDenseMatrixWith : input parameter is null !");
4029 other->checkAllocated();
4030 int nbOfComp=getNumberOfComponents();
4031 int otherNbOfComp=other->getNumberOfComponents();
4032 if(nbOfComp!=otherNbOfComp)
4034 std::ostringstream oss; oss << "DataArrayDouble::buildEuclidianDistanceDenseMatrixWith : this nb of compo=" << nbOfComp << " and other nb of compo=" << otherNbOfComp << ". It should match !";
4035 throw INTERP_KERNEL::Exception(oss.str().c_str());
4037 int nbOfTuples=getNumberOfTuples();
4038 int otherNbOfTuples=other->getNumberOfTuples();
4039 const double *inData=getConstPointer();
4040 const double *inDataOther=other->getConstPointer();
4041 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
4042 ret->alloc(otherNbOfTuples*nbOfTuples,1);
4043 double *outData=ret->getPointer();
4044 for(int i=0;i<otherNbOfTuples;i++,inDataOther+=nbOfComp)
4046 for(int j=0;j<nbOfTuples;j++)
4049 for(int k=0;k<nbOfComp;k++)
4050 { double delta=inDataOther[k]-inData[j*nbOfComp+k]; dist+=delta*delta; }
4052 outData[i*nbOfTuples+j]=dist;
4059 * Sorts value within every tuple of \a this array.
4060 * \param [in] asc - if \a true, the values are sorted in ascending order, else,
4061 * in descending order.
4062 * \throw If \a this is not allocated.
4064 void DataArrayDouble::sortPerTuple(bool asc)
4067 double *pt=getPointer();
4068 int nbOfTuple=getNumberOfTuples();
4069 int nbOfComp=getNumberOfComponents();
4071 for(int i=0;i<nbOfTuple;i++,pt+=nbOfComp)
4072 std::sort(pt,pt+nbOfComp);
4074 for(int i=0;i<nbOfTuple;i++,pt+=nbOfComp)
4075 std::sort(pt,pt+nbOfComp,std::greater<double>());
4080 * Converts every value of \a this array to its absolute value.
4081 * \b WARNING this method is non const. If a new DataArrayDouble instance should be built containing the result of abs DataArrayDouble::computeAbs
4082 * should be called instead.
4084 * \throw If \a this is not allocated.
4085 * \sa DataArrayDouble::computeAbs
4087 void DataArrayDouble::abs()
4090 double *ptr(getPointer());
4091 std::size_t nbOfElems(getNbOfElems());
4092 std::transform(ptr,ptr+nbOfElems,ptr,std::ptr_fun<double,double>(fabs));
4097 * This method builds a new instance of \a this object containing the result of std::abs applied of all elements in \a this.
4098 * This method is a const method (that do not change any values in \a this) contrary to DataArrayDouble::abs method.
4100 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
4101 * same number of tuples and component as \a this array.
4102 * The caller is to delete this result array using decrRef() as it is no more
4104 * \throw If \a this is not allocated.
4105 * \sa DataArrayDouble::abs
4107 DataArrayDouble *DataArrayDouble::computeAbs() const
4110 DataArrayDouble *newArr(DataArrayDouble::New());
4111 int nbOfTuples(getNumberOfTuples());
4112 int nbOfComp(getNumberOfComponents());
4113 newArr->alloc(nbOfTuples,nbOfComp);
4114 std::transform(begin(),end(),newArr->getPointer(),std::ptr_fun<double,double>(fabs));
4115 newArr->copyStringInfoFrom(*this);
4120 * Apply a linear function to a given component of \a this array, so that
4121 * an array element <em>(x)</em> becomes \f$ a * x + b \f$.
4122 * \param [in] a - the first coefficient of the function.
4123 * \param [in] b - the second coefficient of the function.
4124 * \param [in] compoId - the index of component to modify.
4125 * \throw If \a this is not allocated, or \a compoId is not in [0,\c this->getNumberOfComponents() ).
4127 void DataArrayDouble::applyLin(double a, double b, int compoId)
4130 double *ptr(getPointer()+compoId);
4131 int nbOfComp(getNumberOfComponents()),nbOfTuple(getNumberOfTuples());
4132 if(compoId<0 || compoId>=nbOfComp)
4134 std::ostringstream oss; oss << "DataArrayDouble::applyLin : The compoId requested (" << compoId << ") is not valid ! Must be in [0," << nbOfComp << ") !";
4135 throw INTERP_KERNEL::Exception(oss.str().c_str());
4137 for(int i=0;i<nbOfTuple;i++,ptr+=nbOfComp)
4143 * Apply a linear function to all elements of \a this array, so that
4144 * an element _x_ becomes \f$ a * x + b \f$.
4145 * \param [in] a - the first coefficient of the function.
4146 * \param [in] b - the second coefficient of the function.
4147 * \throw If \a this is not allocated.
4149 void DataArrayDouble::applyLin(double a, double b)
4152 double *ptr=getPointer();
4153 std::size_t nbOfElems=getNbOfElems();
4154 for(std::size_t i=0;i<nbOfElems;i++,ptr++)
4160 * Modify all elements of \a this array, so that
4161 * an element _x_ becomes \f$ numerator / x \f$.
4162 * \warning If an exception is thrown because of presence of 0.0 element in \a this
4163 * array, all elements processed before detection of the zero element remain
4165 * \param [in] numerator - the numerator used to modify array elements.
4166 * \throw If \a this is not allocated.
4167 * \throw If there is an element equal to 0.0 in \a this array.
4169 void DataArrayDouble::applyInv(double numerator)
4172 double *ptr=getPointer();
4173 std::size_t nbOfElems=getNbOfElems();
4174 for(std::size_t i=0;i<nbOfElems;i++,ptr++)
4176 if(std::abs(*ptr)>std::numeric_limits<double>::min())
4178 *ptr=numerator/(*ptr);
4182 std::ostringstream oss; oss << "DataArrayDouble::applyInv : presence of null value in tuple #" << i/getNumberOfComponents() << " component #" << i%getNumberOfComponents();
4184 throw INTERP_KERNEL::Exception(oss.str().c_str());
4191 * Returns a full copy of \a this array except that sign of all elements is reversed.
4192 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
4193 * same number of tuples and component as \a this array.
4194 * The caller is to delete this result array using decrRef() as it is no more
4196 * \throw If \a this is not allocated.
4198 DataArrayDouble *DataArrayDouble::negate() const
4201 DataArrayDouble *newArr=DataArrayDouble::New();
4202 int nbOfTuples=getNumberOfTuples();
4203 int nbOfComp=getNumberOfComponents();
4204 newArr->alloc(nbOfTuples,nbOfComp);
4205 const double *cptr=getConstPointer();
4206 std::transform(cptr,cptr+nbOfTuples*nbOfComp,newArr->getPointer(),std::negate<double>());
4207 newArr->copyStringInfoFrom(*this);
4212 * Modify all elements of \a this array, so that
4213 * an element _x_ becomes <em> val ^ x </em>. Contrary to DataArrayInt::applyPow
4214 * all values in \a this have to be >= 0 if val is \b not integer.
4215 * \param [in] val - the value used to apply pow on all array elements.
4216 * \throw If \a this is not allocated.
4217 * \warning If an exception is thrown because of presence of 0 element in \a this
4218 * array and \a val is \b not integer, all elements processed before detection of the zero element remain
4221 void DataArrayDouble::applyPow(double val)
4224 double *ptr=getPointer();
4225 std::size_t nbOfElems=getNbOfElems();
4227 bool isInt=((double)val2)==val;
4230 for(std::size_t i=0;i<nbOfElems;i++,ptr++)
4236 std::ostringstream oss; oss << "DataArrayDouble::applyPow (double) : At elem # " << i << " value is " << *ptr << " ! must be >=0. !";
4237 throw INTERP_KERNEL::Exception(oss.str().c_str());
4243 for(std::size_t i=0;i<nbOfElems;i++,ptr++)
4244 *ptr=pow(*ptr,val2);
4250 * Modify all elements of \a this array, so that
4251 * an element _x_ becomes \f$ val ^ x \f$.
4252 * \param [in] val - the value used to apply pow on all array elements.
4253 * \throw If \a this is not allocated.
4254 * \throw If \a val < 0.
4255 * \warning If an exception is thrown because of presence of 0 element in \a this
4256 * array, all elements processed before detection of the zero element remain
4259 void DataArrayDouble::applyRPow(double val)
4263 throw INTERP_KERNEL::Exception("DataArrayDouble::applyRPow : the input value has to be >= 0 !");
4264 double *ptr=getPointer();
4265 std::size_t nbOfElems=getNbOfElems();
4266 for(std::size_t i=0;i<nbOfElems;i++,ptr++)
4272 * Returns a new DataArrayDouble created from \a this one by applying \a
4273 * FunctionToEvaluate to every tuple of \a this array. Textual data is not copied.
4274 * For more info see \ref MEDCouplingArrayApplyFunc
4275 * \param [in] nbOfComp - number of components in the result array.
4276 * \param [in] func - the \a FunctionToEvaluate declared as
4277 * \c bool (*\a func)(\c const \c double *\a pos, \c double *\a res),
4278 * where \a pos points to the first component of a tuple of \a this array
4279 * and \a res points to the first component of a tuple of the result array.
4280 * Note that length (number of components) of \a pos can differ from
4282 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
4283 * same number of tuples as \a this array.
4284 * The caller is to delete this result array using decrRef() as it is no more
4286 * \throw If \a this is not allocated.
4287 * \throw If \a func returns \a false.
4289 DataArrayDouble *DataArrayDouble::applyFunc(int nbOfComp, FunctionToEvaluate func) const
4292 DataArrayDouble *newArr=DataArrayDouble::New();
4293 int nbOfTuples=getNumberOfTuples();
4294 int oldNbOfComp=getNumberOfComponents();
4295 newArr->alloc(nbOfTuples,nbOfComp);
4296 const double *ptr=getConstPointer();
4297 double *ptrToFill=newArr->getPointer();
4298 for(int i=0;i<nbOfTuples;i++)
4300 if(!func(ptr+i*oldNbOfComp,ptrToFill+i*nbOfComp))
4302 std::ostringstream oss; oss << "For tuple # " << i << " with value (";
4303 std::copy(ptr+oldNbOfComp*i,ptr+oldNbOfComp*(i+1),std::ostream_iterator<double>(oss,", "));
4304 oss << ") : Evaluation of function failed !";
4306 throw INTERP_KERNEL::Exception(oss.str().c_str());
4313 * Returns a new DataArrayDouble created from \a this one by applying a function to every
4314 * tuple of \a this array. Textual data is not copied.
4315 * For more info see \ref MEDCouplingArrayApplyFunc1.
4316 * \param [in] nbOfComp - number of components in the result array.
4317 * \param [in] func - the expression defining how to transform a tuple of \a this array.
4318 * Supported expressions are described \ref MEDCouplingArrayApplyFuncExpr "here".
4319 * \param [in] isSafe - By default true. If true invalid operation (division by 0. acos of value > 1. ...) leads to a throw of an exception.
4320 * If false the computation is carried on without any notification. When false the evaluation is a little faster.
4321 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
4322 * same number of tuples as \a this array and \a nbOfComp components.
4323 * The caller is to delete this result array using decrRef() as it is no more
4325 * \throw If \a this is not allocated.
4326 * \throw If computing \a func fails.
4328 DataArrayDouble *DataArrayDouble::applyFunc(int nbOfComp, const std::string& func, bool isSafe) const
4330 INTERP_KERNEL::ExprParser expr(func);
4332 std::set<std::string> vars;
4333 expr.getTrueSetOfVars(vars);
4334 std::vector<std::string> varsV(vars.begin(),vars.end());
4335 return applyFunc3(nbOfComp,varsV,func,isSafe);
4339 * Returns a new DataArrayDouble created from \a this one by applying a function to every
4340 * tuple of \a this array. Textual data is not copied. This method works by tuples (whatever its size).
4341 * If \a this is a one component array, call applyFuncOnThis instead that performs the same work faster.
4343 * For more info see \ref MEDCouplingArrayApplyFunc0.
4344 * \param [in] func - the expression defining how to transform a tuple of \a this array.
4345 * Supported expressions are described \ref MEDCouplingArrayApplyFuncExpr "here".
4346 * \param [in] isSafe - By default true. If true invalid operation (division by 0. acos of value > 1. ...) leads to a throw of an exception.
4347 * If false the computation is carried on without any notification. When false the evaluation is a little faster.
4348 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
4349 * same number of tuples and components as \a this array.
4350 * The caller is to delete this result array using decrRef() as it is no more
4352 * \sa applyFuncOnThis
4353 * \throw If \a this is not allocated.
4354 * \throw If computing \a func fails.
4356 DataArrayDouble *DataArrayDouble::applyFunc(const std::string& func, bool isSafe) const
4358 int nbOfComp(getNumberOfComponents());
4360 throw INTERP_KERNEL::Exception("DataArrayDouble::applyFunc : output number of component must be > 0 !");
4362 int nbOfTuples(getNumberOfTuples());
4363 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> newArr(DataArrayDouble::New());
4364 newArr->alloc(nbOfTuples,nbOfComp);
4365 INTERP_KERNEL::ExprParser expr(func);
4367 std::set<std::string> vars;
4368 expr.getTrueSetOfVars(vars);
4369 if((int)vars.size()>1)
4371 std::ostringstream oss; oss << "DataArrayDouble::applyFunc : this method works only with at most one var func expression ! If you need to map comps on variables please use applyFunc2 or applyFunc3 instead ! Vars in expr are : ";
4372 std::copy(vars.begin(),vars.end(),std::ostream_iterator<std::string>(oss," "));
4373 throw INTERP_KERNEL::Exception(oss.str().c_str());
4377 expr.prepareFastEvaluator();
4378 newArr->rearrange(1);
4379 newArr->fillWithValue(expr.evaluateDouble());
4380 newArr->rearrange(nbOfComp);
4381 return newArr.retn();
4383 std::vector<std::string> vars2(vars.begin(),vars.end());
4384 double buff,*ptrToFill(newArr->getPointer());
4385 const double *ptr(begin());
4386 std::vector<double> stck;
4387 expr.prepareExprEvaluationDouble(vars2,1,1,0,&buff,&buff+1);
4388 expr.prepareFastEvaluator();
4391 for(int i=0;i<nbOfTuples;i++)
4393 for(int iComp=0;iComp<nbOfComp;iComp++,ptr++,ptrToFill++)
4396 expr.evaluateDoubleInternal(stck);
4397 *ptrToFill=stck.back();
4404 for(int i=0;i<nbOfTuples;i++)
4406 for(int iComp=0;iComp<nbOfComp;iComp++,ptr++,ptrToFill++)
4411 expr.evaluateDoubleInternalSafe(stck);
4413 catch(INTERP_KERNEL::Exception& e)
4415 std::ostringstream oss; oss << "For tuple # " << i << " component # " << iComp << " with value (";
4417 oss << ") : Evaluation of function failed !" << e.what();
4418 throw INTERP_KERNEL::Exception(oss.str().c_str());
4420 *ptrToFill=stck.back();
4425 return newArr.retn();
4429 * This method is a non const method that modify the array in \a this.
4430 * This method only works on one component array. It means that function \a func must
4431 * contain at most one variable.
4432 * This method is a specialization of applyFunc method with one parameter on one component array.
4434 * \param [in] func - the expression defining how to transform a tuple of \a this array.
4435 * Supported expressions are described \ref MEDCouplingArrayApplyFuncExpr "here".
4436 * \param [in] isSafe - By default true. If true invalid operation (division by 0. acos of value > 1. ...) leads to a throw of an exception.
4437 * If false the computation is carried on without any notification. When false the evaluation is a little faster.
4441 void DataArrayDouble::applyFuncOnThis(const std::string& func, bool isSafe)
4443 int nbOfComp(getNumberOfComponents());
4445 throw INTERP_KERNEL::Exception("DataArrayDouble::applyFuncOnThis : output number of component must be > 0 !");
4447 int nbOfTuples(getNumberOfTuples());
4448 INTERP_KERNEL::ExprParser expr(func);
4450 std::set<std::string> vars;
4451 expr.getTrueSetOfVars(vars);
4452 if((int)vars.size()>1)
4454 std::ostringstream oss; oss << "DataArrayDouble::applyFuncOnThis : this method works only with at most one var func expression ! If you need to map comps on variables please use applyFunc2 or applyFunc3 instead ! Vars in expr are : ";
4455 std::copy(vars.begin(),vars.end(),std::ostream_iterator<std::string>(oss," "));
4456 throw INTERP_KERNEL::Exception(oss.str().c_str());
4460 expr.prepareFastEvaluator();
4461 std::vector<std::string> compInfo(getInfoOnComponents());
4463 fillWithValue(expr.evaluateDouble());
4464 rearrange(nbOfComp);
4465 setInfoOnComponents(compInfo);
4468 std::vector<std::string> vars2(vars.begin(),vars.end());
4469 double buff,*ptrToFill(getPointer());
4470 const double *ptr(begin());
4471 std::vector<double> stck;
4472 expr.prepareExprEvaluationDouble(vars2,1,1,0,&buff,&buff+1);
4473 expr.prepareFastEvaluator();
4476 for(int i=0;i<nbOfTuples;i++)
4478 for(int iComp=0;iComp<nbOfComp;iComp++,ptr++,ptrToFill++)
4481 expr.evaluateDoubleInternal(stck);
4482 *ptrToFill=stck.back();
4489 for(int i=0;i<nbOfTuples;i++)
4491 for(int iComp=0;iComp<nbOfComp;iComp++,ptr++,ptrToFill++)
4496 expr.evaluateDoubleInternalSafe(stck);
4498 catch(INTERP_KERNEL::Exception& e)
4500 std::ostringstream oss; oss << "For tuple # " << i << " component # " << iComp << " with value (";
4502 oss << ") : Evaluation of function failed !" << e.what();
4503 throw INTERP_KERNEL::Exception(oss.str().c_str());
4505 *ptrToFill=stck.back();
4513 * Returns a new DataArrayDouble created from \a this one by applying a function to every
4514 * tuple of \a this array. Textual data is not copied.
4515 * For more info see \ref MEDCouplingArrayApplyFunc2.
4516 * \param [in] nbOfComp - number of components in the result array.
4517 * \param [in] func - the expression defining how to transform a tuple of \a this array.
4518 * Supported expressions are described \ref MEDCouplingArrayApplyFuncExpr "here".
4519 * \param [in] isSafe - By default true. If true invalid operation (division by 0. acos of value > 1. ...) leads to a throw of an exception.
4520 * If false the computation is carried on without any notification. When false the evaluation is a little faster.
4521 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
4522 * same number of tuples as \a this array.
4523 * The caller is to delete this result array using decrRef() as it is no more
4525 * \throw If \a this is not allocated.
4526 * \throw If \a func contains vars that are not in \a this->getInfoOnComponent().
4527 * \throw If computing \a func fails.
4529 DataArrayDouble *DataArrayDouble::applyFunc2(int nbOfComp, const std::string& func, bool isSafe) const
4531 return applyFunc3(nbOfComp,getVarsOnComponent(),func,isSafe);
4535 * Returns a new DataArrayDouble created from \a this one by applying a function to every
4536 * tuple of \a this array. Textual data is not copied.
4537 * For more info see \ref MEDCouplingArrayApplyFunc3.
4538 * \param [in] nbOfComp - number of components in the result array.
4539 * \param [in] varsOrder - sequence of vars defining their order.
4540 * \param [in] func - the expression defining how to transform a tuple of \a this array.
4541 * Supported expressions are described \ref MEDCouplingArrayApplyFuncExpr "here".
4542 * \param [in] isSafe - By default true. If true invalid operation (division by 0. acos of value > 1. ...) leads to a throw of an exception.
4543 * If false the computation is carried on without any notification. When false the evaluation is a little faster.
4544 * \return DataArrayDouble * - the new instance of DataArrayDouble containing the
4545 * same number of tuples as \a this array.
4546 * The caller is to delete this result array using decrRef() as it is no more
4548 * \throw If \a this is not allocated.
4549 * \throw If \a func contains vars not in \a varsOrder.
4550 * \throw If computing \a func fails.
4552 DataArrayDouble *DataArrayDouble::applyFunc3(int nbOfComp, const std::vector<std::string>& varsOrder, const std::string& func, bool isSafe) const
4555 throw INTERP_KERNEL::Exception("DataArrayDouble::applyFunc3 : output number of component must be > 0 !");
4556 std::vector<std::string> varsOrder2(varsOrder);
4557 int oldNbOfComp(getNumberOfComponents());
4558 for(int i=(int)varsOrder.size();i<oldNbOfComp;i++)
4559 varsOrder2.push_back(std::string());
4561 int nbOfTuples(getNumberOfTuples());
4562 INTERP_KERNEL::ExprParser expr(func);
4564 std::set<std::string> vars;
4565 expr.getTrueSetOfVars(vars);
4566 if((int)vars.size()>oldNbOfComp)
4568 std::ostringstream oss; oss << "The field has " << oldNbOfComp << " components and there are ";
4569 oss << vars.size() << " variables : ";
4570 std::copy(vars.begin(),vars.end(),std::ostream_iterator<std::string>(oss," "));
4571 throw INTERP_KERNEL::Exception(oss.str().c_str());
4573 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> newArr(DataArrayDouble::New());
4574 newArr->alloc(nbOfTuples,nbOfComp);
4575 INTERP_KERNEL::AutoPtr<double> buff(new double[oldNbOfComp]);
4576 double *buffPtr(buff),*ptrToFill;
4577 std::vector<double> stck;
4578 for(int iComp=0;iComp<nbOfComp;iComp++)
4580 expr.prepareExprEvaluationDouble(varsOrder2,oldNbOfComp,nbOfComp,iComp,buffPtr,buffPtr+oldNbOfComp);
4581 expr.prepareFastEvaluator();
4582 const double *ptr(getConstPointer());
4583 ptrToFill=newArr->getPointer()+iComp;
4586 for(int i=0;i<nbOfTuples;i++,ptrToFill+=nbOfComp,ptr+=oldNbOfComp)
4588 std::copy(ptr,ptr+oldNbOfComp,buffPtr);
4589 expr.evaluateDoubleInternal(stck);
4590 *ptrToFill=stck.back();
4596 for(int i=0;i<nbOfTuples;i++,ptrToFill+=nbOfComp,ptr+=oldNbOfComp)
4598 std::copy(ptr,ptr+oldNbOfComp,buffPtr);
4601 expr.evaluateDoubleInternalSafe(stck);
4602 *ptrToFill=stck.back();
4605 catch(INTERP_KERNEL::Exception& e)
4607 std::ostringstream oss; oss << "For tuple # " << i << " with value (";
4608 std::copy(ptr+oldNbOfComp*i,ptr+oldNbOfComp*(i+1),std::ostream_iterator<double>(oss,", "));
4609 oss << ") : Evaluation of function failed !" << e.what();
4610 throw INTERP_KERNEL::Exception(oss.str().c_str());
4615 return newArr.retn();
4618 void DataArrayDouble::applyFuncFast32(const std::string& func)
4621 INTERP_KERNEL::ExprParser expr(func);
4623 char *funcStr=expr.compileX86();
4625 *((void **)&funcPtr)=funcStr;//he he...
4627 double *ptr=getPointer();
4628 int nbOfComp=getNumberOfComponents();
4629 int nbOfTuples=getNumberOfTuples();
4630 int nbOfElems=nbOfTuples*nbOfComp;
4631 for(int i=0;i<nbOfElems;i++,ptr++)
4636 void DataArrayDouble::applyFuncFast64(const std::string& func)
4639 INTERP_KERNEL::ExprParser expr(func);
4641 char *funcStr=expr.compileX86_64();
4643 *((void **)&funcPtr)=funcStr;//he he...
4645 double *ptr=getPointer();
4646 int nbOfComp=getNumberOfComponents();
4647 int nbOfTuples=getNumberOfTuples();
4648 int nbOfElems=nbOfTuples*nbOfComp;
4649 for(int i=0;i<nbOfElems;i++,ptr++)
4654 DataArrayDoubleIterator *DataArrayDouble::iterator()
4656 return new DataArrayDoubleIterator(this);
4660 * Returns a new DataArrayInt contating indices of tuples of \a this one-dimensional
4661 * array whose values are within a given range. Textual data is not copied.
4662 * \param [in] vmin - a lowest acceptable value (included).
4663 * \param [in] vmax - a greatest acceptable value (included).
4664 * \return DataArrayInt * - the new instance of DataArrayInt.
4665 * The caller is to delete this result array using decrRef() as it is no more
4667 * \throw If \a this->getNumberOfComponents() != 1.
4669 * \sa DataArrayDouble::getIdsNotInRange
4671 * \if ENABLE_EXAMPLES
4672 * \ref cpp_mcdataarraydouble_getidsinrange "Here is a C++ example".<br>
4673 * \ref py_mcdataarraydouble_getidsinrange "Here is a Python example".
4676 DataArrayInt *DataArrayDouble::getIdsInRange(double vmin, double vmax) const
4679 if(getNumberOfComponents()!=1)
4680 throw INTERP_KERNEL::Exception("DataArrayDouble::getIdsInRange : this must have exactly one component !");
4681 const double *cptr(begin());
4682 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
4683 int nbOfTuples(getNumberOfTuples());
4684 for(int i=0;i<nbOfTuples;i++,cptr++)
4685 if(*cptr>=vmin && *cptr<=vmax)
4686 ret->pushBackSilent(i);
4691 * Returns a new DataArrayInt contating indices of tuples of \a this one-dimensional
4692 * array whose values are not within a given range. Textual data is not copied.
4693 * \param [in] vmin - a lowest not acceptable value (excluded).
4694 * \param [in] vmax - a greatest not acceptable value (excluded).
4695 * \return DataArrayInt * - the new instance of DataArrayInt.
4696 * The caller is to delete this result array using decrRef() as it is no more
4698 * \throw If \a this->getNumberOfComponents() != 1.
4700 * \sa DataArrayDouble::getIdsInRange
4702 DataArrayInt *DataArrayDouble::getIdsNotInRange(double vmin, double vmax) const
4705 if(getNumberOfComponents()!=1)
4706 throw INTERP_KERNEL::Exception("DataArrayDouble::getIdsNotInRange : this must have exactly one component !");
4707 const double *cptr(begin());
4708 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
4709 int nbOfTuples(getNumberOfTuples());
4710 for(int i=0;i<nbOfTuples;i++,cptr++)
4711 if(*cptr<vmin || *cptr>vmax)
4712 ret->pushBackSilent(i);
4717 * Returns a new DataArrayDouble by concatenating two given arrays, so that (1) the number
4718 * of tuples in the result array is a sum of the number of tuples of given arrays and (2)
4719 * the number of component in the result array is same as that of each of given arrays.
4720 * Info on components is copied from the first of the given arrays. Number of components
4721 * in the given arrays must be the same.
4722 * \param [in] a1 - an array to include in the result array.
4723 * \param [in] a2 - another array to include in the result array.
4724 * \return DataArrayDouble * - the new instance of DataArrayDouble.
4725 * The caller is to delete this result array using decrRef() as it is no more
4727 * \throw If both \a a1 and \a a2 are NULL.
4728 * \throw If \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents().
4730 DataArrayDouble *DataArrayDouble::Aggregate(const DataArrayDouble *a1, const DataArrayDouble *a2)
4732 std::vector<const DataArrayDouble *> tmp(2);
4733 tmp[0]=a1; tmp[1]=a2;
4734 return Aggregate(tmp);
4738 * Returns a new DataArrayDouble by concatenating all given arrays, so that (1) the number
4739 * of tuples in the result array is a sum of the number of tuples of given arrays and (2)
4740 * the number of component in the result array is same as that of each of given arrays.
4741 * Info on components is copied from the first of the given arrays. Number of components
4742 * in the given arrays must be the same.
4743 * If the number of non null of elements in \a arr is equal to one the returned object is a copy of it
4744 * not the object itself.
4745 * \param [in] arr - a sequence of arrays to include in the result array.
4746 * \return DataArrayDouble * - the new instance of DataArrayDouble.
4747 * The caller is to delete this result array using decrRef() as it is no more
4749 * \throw If all arrays within \a arr are NULL.
4750 * \throw If getNumberOfComponents() of arrays within \a arr.
4752 DataArrayDouble *DataArrayDouble::Aggregate(const std::vector<const DataArrayDouble *>& arr)
4754 std::vector<const DataArrayDouble *> a;
4755 for(std::vector<const DataArrayDouble *>::const_iterator it4=arr.begin();it4!=arr.end();it4++)
4759 throw INTERP_KERNEL::Exception("DataArrayDouble::Aggregate : input list must contain at least one NON EMPTY DataArrayDouble !");
4760 std::vector<const DataArrayDouble *>::const_iterator it=a.begin();
4761 int nbOfComp=(*it)->getNumberOfComponents();
4762 int nbt=(*it++)->getNumberOfTuples();
4763 for(int i=1;it!=a.end();it++,i++)
4765 if((*it)->getNumberOfComponents()!=nbOfComp)
4766 throw INTERP_KERNEL::Exception("DataArrayDouble::Aggregate : Nb of components mismatch for array aggregation !");
4767 nbt+=(*it)->getNumberOfTuples();
4769 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
4770 ret->alloc(nbt,nbOfComp);
4771 double *pt=ret->getPointer();
4772 for(it=a.begin();it!=a.end();it++)
4773 pt=std::copy((*it)->getConstPointer(),(*it)->getConstPointer()+(*it)->getNbOfElems(),pt);
4774 ret->copyStringInfoFrom(*(a[0]));
4779 * Returns a new DataArrayDouble by aggregating two given arrays, so that (1) the number
4780 * of components in the result array is a sum of the number of components of given arrays
4781 * and (2) the number of tuples in the result array is same as that of each of given
4782 * arrays. In other words the i-th tuple of result array includes all components of
4783 * i-th tuples of all given arrays.
4784 * Number of tuples in the given arrays must be the same.
4785 * \param [in] a1 - an array to include in the result array.
4786 * \param [in] a2 - another array to include in the result array.
4787 * \return DataArrayDouble * - the new instance of DataArrayDouble.
4788 * The caller is to delete this result array using decrRef() as it is no more
4790 * \throw If both \a a1 and \a a2 are NULL.
4791 * \throw If any given array is not allocated.
4792 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples()
4794 DataArrayDouble *DataArrayDouble::Meld(const DataArrayDouble *a1, const DataArrayDouble *a2)
4796 std::vector<const DataArrayDouble *> arr(2);
4797 arr[0]=a1; arr[1]=a2;
4802 * Returns a new DataArrayDouble by aggregating all given arrays, so that (1) the number
4803 * of components in the result array is a sum of the number of components of given arrays
4804 * and (2) the number of tuples in the result array is same as that of each of given
4805 * arrays. In other words the i-th tuple of result array includes all components of
4806 * i-th tuples of all given arrays.
4807 * Number of tuples in the given arrays must be the same.
4808 * \param [in] arr - a sequence of arrays to include in the result array.
4809 * \return DataArrayDouble * - the new instance of DataArrayDouble.
4810 * The caller is to delete this result array using decrRef() as it is no more
4812 * \throw If all arrays within \a arr are NULL.
4813 * \throw If any given array is not allocated.
4814 * \throw If getNumberOfTuples() of arrays within \a arr is different.
4816 DataArrayDouble *DataArrayDouble::Meld(const std::vector<const DataArrayDouble *>& arr)
4818 std::vector<const DataArrayDouble *> a;
4819 for(std::vector<const DataArrayDouble *>::const_iterator it4=arr.begin();it4!=arr.end();it4++)
4823 throw INTERP_KERNEL::Exception("DataArrayDouble::Meld : input list must contain at least one NON EMPTY DataArrayDouble !");
4824 std::vector<const DataArrayDouble *>::const_iterator it;
4825 for(it=a.begin();it!=a.end();it++)
4826 (*it)->checkAllocated();
4828 int nbOfTuples=(*it)->getNumberOfTuples();
4829 std::vector<int> nbc(a.size());
4830 std::vector<const double *> pts(a.size());
4831 nbc[0]=(*it)->getNumberOfComponents();
4832 pts[0]=(*it++)->getConstPointer();
4833 for(int i=1;it!=a.end();it++,i++)
4835 if(nbOfTuples!=(*it)->getNumberOfTuples())
4836 throw INTERP_KERNEL::Exception("DataArrayDouble::Meld : mismatch of number of tuples !");
4837 nbc[i]=(*it)->getNumberOfComponents();
4838 pts[i]=(*it)->getConstPointer();
4840 int totalNbOfComp=std::accumulate(nbc.begin(),nbc.end(),0);
4841 DataArrayDouble *ret=DataArrayDouble::New();
4842 ret->alloc(nbOfTuples,totalNbOfComp);
4843 double *retPtr=ret->getPointer();
4844 for(int i=0;i<nbOfTuples;i++)
4845 for(int j=0;j<(int)a.size();j++)
4847 retPtr=std::copy(pts[j],pts[j]+nbc[j],retPtr);
4851 for(int i=0;i<(int)a.size();i++)
4852 for(int j=0;j<nbc[i];j++,k++)
4853 ret->setInfoOnComponent(k,a[i]->getInfoOnComponent(j));
4858 * Returns a new DataArrayDouble containing a dot product of two given arrays, so that
4859 * the i-th tuple of the result array is a sum of products of j-th components of i-th
4860 * tuples of given arrays (\f$ a_i = \sum_{j=1}^n a1_j * a2_j \f$).
4861 * Info on components and name is copied from the first of the given arrays.
4862 * Number of tuples and components in the given arrays must be the same.
4863 * \param [in] a1 - a given array.
4864 * \param [in] a2 - another given array.
4865 * \return DataArrayDouble * - the new instance of DataArrayDouble.
4866 * The caller is to delete this result array using decrRef() as it is no more
4868 * \throw If either \a a1 or \a a2 is NULL.
4869 * \throw If any given array is not allocated.
4870 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples()
4871 * \throw If \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents()
4873 DataArrayDouble *DataArrayDouble::Dot(const DataArrayDouble *a1, const DataArrayDouble *a2)
4876 throw INTERP_KERNEL::Exception("DataArrayDouble::Dot : input DataArrayDouble instance is NULL !");
4877 a1->checkAllocated();
4878 a2->checkAllocated();
4879 int nbOfComp=a1->getNumberOfComponents();
4880 if(nbOfComp!=a2->getNumberOfComponents())
4881 throw INTERP_KERNEL::Exception("Nb of components mismatch for array Dot !");
4882 int nbOfTuple=a1->getNumberOfTuples();
4883 if(nbOfTuple!=a2->getNumberOfTuples())
4884 throw INTERP_KERNEL::Exception("Nb of tuples mismatch for array Dot !");
4885 DataArrayDouble *ret=DataArrayDouble::New();
4886 ret->alloc(nbOfTuple,1);
4887 double *retPtr=ret->getPointer();
4888 const double *a1Ptr=a1->getConstPointer();
4889 const double *a2Ptr=a2->getConstPointer();
4890 for(int i=0;i<nbOfTuple;i++)
4893 for(int j=0;j<nbOfComp;j++)
4894 sum+=a1Ptr[i*nbOfComp+j]*a2Ptr[i*nbOfComp+j];
4897 ret->setInfoOnComponent(0,a1->getInfoOnComponent(0));
4898 ret->setName(a1->getName());
4903 * Returns a new DataArrayDouble containing a cross product of two given arrays, so that
4904 * the i-th tuple of the result array contains 3 components of a vector which is a cross
4905 * product of two vectors defined by the i-th tuples of given arrays.
4906 * Info on components is copied from the first of the given arrays.
4907 * Number of tuples in the given arrays must be the same.
4908 * Number of components in the given arrays must be 3.
4909 * \param [in] a1 - a given array.
4910 * \param [in] a2 - another given array.
4911 * \return DataArrayDouble * - the new instance of DataArrayDouble.
4912 * The caller is to delete this result array using decrRef() as it is no more
4914 * \throw If either \a a1 or \a a2 is NULL.
4915 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples()
4916 * \throw If \a a1->getNumberOfComponents() != 3
4917 * \throw If \a a2->getNumberOfComponents() != 3
4919 DataArrayDouble *DataArrayDouble::CrossProduct(const DataArrayDouble *a1, const DataArrayDouble *a2)
4922 throw INTERP_KERNEL::Exception("DataArrayDouble::CrossProduct : input DataArrayDouble instance is NULL !");
4923 int nbOfComp=a1->getNumberOfComponents();
4924 if(nbOfComp!=a2->getNumberOfComponents())
4925 throw INTERP_KERNEL::Exception("Nb of components mismatch for array crossProduct !");
4927 throw INTERP_KERNEL::Exception("Nb of components must be equal to 3 for array crossProduct !");
4928 int nbOfTuple=a1->getNumberOfTuples();
4929 if(nbOfTuple!=a2->getNumberOfTuples())
4930 throw INTERP_KERNEL::Exception("Nb of tuples mismatch for array crossProduct !");
4931 DataArrayDouble *ret=DataArrayDouble::New();
4932 ret->alloc(nbOfTuple,3);
4933 double *retPtr=ret->getPointer();
4934 const double *a1Ptr=a1->getConstPointer();
4935 const double *a2Ptr=a2->getConstPointer();
4936 for(int i=0;i<nbOfTuple;i++)
4938 retPtr[3*i]=a1Ptr[3*i+1]*a2Ptr[3*i+2]-a1Ptr[3*i+2]*a2Ptr[3*i+1];
4939 retPtr[3*i+1]=a1Ptr[3*i+2]*a2Ptr[3*i]-a1Ptr[3*i]*a2Ptr[3*i+2];
4940 retPtr[3*i+2]=a1Ptr[3*i]*a2Ptr[3*i+1]-a1Ptr[3*i+1]*a2Ptr[3*i];
4942 ret->copyStringInfoFrom(*a1);
4947 * Returns a new DataArrayDouble containing maximal values of two given arrays.
4948 * Info on components is copied from the first of the given arrays.
4949 * Number of tuples and components in the given arrays must be the same.
4950 * \param [in] a1 - an array to compare values with another one.
4951 * \param [in] a2 - another array to compare values with the first one.
4952 * \return DataArrayDouble * - the new instance of DataArrayDouble.
4953 * The caller is to delete this result array using decrRef() as it is no more
4955 * \throw If either \a a1 or \a a2 is NULL.
4956 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples()
4957 * \throw If \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents()
4959 DataArrayDouble *DataArrayDouble::Max(const DataArrayDouble *a1, const DataArrayDouble *a2)
4962 throw INTERP_KERNEL::Exception("DataArrayDouble::Max : input DataArrayDouble instance is NULL !");
4963 int nbOfComp=a1->getNumberOfComponents();
4964 if(nbOfComp!=a2->getNumberOfComponents())
4965 throw INTERP_KERNEL::Exception("Nb of components mismatch for array Max !");
4966 int nbOfTuple=a1->getNumberOfTuples();
4967 if(nbOfTuple!=a2->getNumberOfTuples())
4968 throw INTERP_KERNEL::Exception("Nb of tuples mismatch for array Max !");
4969 DataArrayDouble *ret=DataArrayDouble::New();
4970 ret->alloc(nbOfTuple,nbOfComp);
4971 double *retPtr=ret->getPointer();
4972 const double *a1Ptr=a1->getConstPointer();
4973 const double *a2Ptr=a2->getConstPointer();
4974 int nbElem=nbOfTuple*nbOfComp;
4975 for(int i=0;i<nbElem;i++)
4976 retPtr[i]=std::max(a1Ptr[i],a2Ptr[i]);
4977 ret->copyStringInfoFrom(*a1);
4982 * Returns a new DataArrayDouble containing minimal values of two given arrays.
4983 * Info on components is copied from the first of the given arrays.
4984 * Number of tuples and components in the given arrays must be the same.
4985 * \param [in] a1 - an array to compare values with another one.
4986 * \param [in] a2 - another array to compare values with the first one.
4987 * \return DataArrayDouble * - the new instance of DataArrayDouble.
4988 * The caller is to delete this result array using decrRef() as it is no more
4990 * \throw If either \a a1 or \a a2 is NULL.
4991 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples()
4992 * \throw If \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents()
4994 DataArrayDouble *DataArrayDouble::Min(const DataArrayDouble *a1, const DataArrayDouble *a2)
4997 throw INTERP_KERNEL::Exception("DataArrayDouble::Min : input DataArrayDouble instance is NULL !");
4998 int nbOfComp=a1->getNumberOfComponents();
4999 if(nbOfComp!=a2->getNumberOfComponents())
5000 throw INTERP_KERNEL::Exception("Nb of components mismatch for array min !");
5001 int nbOfTuple=a1->getNumberOfTuples();
5002 if(nbOfTuple!=a2->getNumberOfTuples())
5003 throw INTERP_KERNEL::Exception("Nb of tuples mismatch for array min !");
5004 DataArrayDouble *ret=DataArrayDouble::New();
5005 ret->alloc(nbOfTuple,nbOfComp);
5006 double *retPtr=ret->getPointer();
5007 const double *a1Ptr=a1->getConstPointer();
5008 const double *a2Ptr=a2->getConstPointer();
5009 int nbElem=nbOfTuple*nbOfComp;
5010 for(int i=0;i<nbElem;i++)
5011 retPtr[i]=std::min(a1Ptr[i],a2Ptr[i]);
5012 ret->copyStringInfoFrom(*a1);
5017 * Returns a new DataArrayDouble that is a sum of two given arrays. There are 3
5019 * 1. The arrays have same number of tuples and components. Then each value of
5020 * the result array (_a_) is a sum of the corresponding values of \a a1 and \a a2,
5021 * i.e.: _a_ [ i, j ] = _a1_ [ i, j ] + _a2_ [ i, j ].
5022 * 2. The arrays have same number of tuples and one array, say _a2_, has one
5024 * _a_ [ i, j ] = _a1_ [ i, j ] + _a2_ [ i, 0 ].
5025 * 3. The arrays have same number of components and one array, say _a2_, has one
5027 * _a_ [ i, j ] = _a1_ [ i, j ] + _a2_ [ 0, j ].
5029 * Info on components is copied either from the first array (in the first case) or from
5030 * the array with maximal number of elements (getNbOfElems()).
5031 * \param [in] a1 - an array to sum up.
5032 * \param [in] a2 - another array to sum up.
5033 * \return DataArrayDouble * - the new instance of DataArrayDouble.
5034 * The caller is to delete this result array using decrRef() as it is no more
5036 * \throw If either \a a1 or \a a2 is NULL.
5037 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples() and
5038 * \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents() and
5039 * none of them has number of tuples or components equal to 1.
5041 DataArrayDouble *DataArrayDouble::Add(const DataArrayDouble *a1, const DataArrayDouble *a2)
5044 throw INTERP_KERNEL::Exception("DataArrayDouble::Add : input DataArrayDouble instance is NULL !");
5045 int nbOfTuple=a1->getNumberOfTuples();
5046 int nbOfTuple2=a2->getNumberOfTuples();
5047 int nbOfComp=a1->getNumberOfComponents();
5048 int nbOfComp2=a2->getNumberOfComponents();
5049 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=0;
5050 if(nbOfTuple==nbOfTuple2)
5052 if(nbOfComp==nbOfComp2)
5054 ret=DataArrayDouble::New();
5055 ret->alloc(nbOfTuple,nbOfComp);
5056 std::transform(a1->begin(),a1->end(),a2->begin(),ret->getPointer(),std::plus<double>());
5057 ret->copyStringInfoFrom(*a1);
5061 int nbOfCompMin,nbOfCompMax;
5062 const DataArrayDouble *aMin, *aMax;
5063 if(nbOfComp>nbOfComp2)
5065 nbOfCompMin=nbOfComp2; nbOfCompMax=nbOfComp;
5070 nbOfCompMin=nbOfComp; nbOfCompMax=nbOfComp2;
5075 ret=DataArrayDouble::New();
5076 ret->alloc(nbOfTuple,nbOfCompMax);
5077 const double *aMinPtr=aMin->getConstPointer();
5078 const double *aMaxPtr=aMax->getConstPointer();
5079 double *res=ret->getPointer();
5080 for(int i=0;i<nbOfTuple;i++)
5081 res=std::transform(aMaxPtr+i*nbOfCompMax,aMaxPtr+(i+1)*nbOfCompMax,res,std::bind2nd(std::plus<double>(),aMinPtr[i]));
5082 ret->copyStringInfoFrom(*aMax);
5085 throw INTERP_KERNEL::Exception("Nb of components mismatch for array Add !");
5088 else if((nbOfTuple==1 && nbOfTuple2>1) || (nbOfTuple>1 && nbOfTuple2==1))
5090 if(nbOfComp==nbOfComp2)
5092 int nbOfTupleMax=std::max(nbOfTuple,nbOfTuple2);
5093 const DataArrayDouble *aMin=nbOfTuple>nbOfTuple2?a2:a1;
5094 const DataArrayDouble *aMax=nbOfTuple>nbOfTuple2?a1:a2;
5095 const double *aMinPtr=aMin->getConstPointer(),*aMaxPtr=aMax->getConstPointer();
5096 ret=DataArrayDouble::New();
5097 ret->alloc(nbOfTupleMax,nbOfComp);
5098 double *res=ret->getPointer();
5099 for(int i=0;i<nbOfTupleMax;i++)
5100 res=std::transform(aMaxPtr+i*nbOfComp,aMaxPtr+(i+1)*nbOfComp,aMinPtr,res,std::plus<double>());
5101 ret->copyStringInfoFrom(*aMax);
5104 throw INTERP_KERNEL::Exception("Nb of components mismatch for array Add !");
5107 throw INTERP_KERNEL::Exception("Nb of tuples mismatch for array Add !");
5112 * Adds values of another DataArrayDouble to values of \a this one. There are 3
5114 * 1. The arrays have same number of tuples and components. Then each value of
5115 * \a other array is added to the corresponding value of \a this array, i.e.:
5116 * _a_ [ i, j ] += _other_ [ i, j ].
5117 * 2. The arrays have same number of tuples and \a other array has one component. Then
5118 * _a_ [ i, j ] += _other_ [ i, 0 ].
5119 * 3. The arrays have same number of components and \a other array has one tuple. Then
5120 * _a_ [ i, j ] += _a2_ [ 0, j ].
5122 * \param [in] other - an array to add to \a this one.
5123 * \throw If \a other is NULL.
5124 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples() and
5125 * \a this->getNumberOfComponents() != \a other->getNumberOfComponents() and
5126 * \a other has number of both tuples and components not equal to 1.
5128 void DataArrayDouble::addEqual(const DataArrayDouble *other)
5131 throw INTERP_KERNEL::Exception("DataArrayDouble::addEqual : input DataArrayDouble instance is NULL !");
5132 const char *msg="Nb of tuples mismatch for DataArrayDouble::addEqual !";
5134 other->checkAllocated();
5135 int nbOfTuple=getNumberOfTuples();
5136 int nbOfTuple2=other->getNumberOfTuples();
5137 int nbOfComp=getNumberOfComponents();
5138 int nbOfComp2=other->getNumberOfComponents();
5139 if(nbOfTuple==nbOfTuple2)
5141 if(nbOfComp==nbOfComp2)
5143 std::transform(begin(),end(),other->begin(),getPointer(),std::plus<double>());
5145 else if(nbOfComp2==1)
5147 double *ptr=getPointer();
5148 const double *ptrc=other->getConstPointer();
5149 for(int i=0;i<nbOfTuple;i++)
5150 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptr+i*nbOfComp,std::bind2nd(std::plus<double>(),*ptrc++));
5153 throw INTERP_KERNEL::Exception(msg);
5155 else if(nbOfTuple2==1)
5157 if(nbOfComp2==nbOfComp)
5159 double *ptr=getPointer();
5160 const double *ptrc=other->getConstPointer();
5161 for(int i=0;i<nbOfTuple;i++)
5162 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptrc,ptr+i*nbOfComp,std::plus<double>());
5165 throw INTERP_KERNEL::Exception(msg);
5168 throw INTERP_KERNEL::Exception(msg);
5173 * Returns a new DataArrayDouble that is a subtraction of two given arrays. There are 3
5175 * 1. The arrays have same number of tuples and components. Then each value of
5176 * the result array (_a_) is a subtraction of the corresponding values of \a a1 and
5177 * \a a2, i.e.: _a_ [ i, j ] = _a1_ [ i, j ] - _a2_ [ i, j ].
5178 * 2. The arrays have same number of tuples and one array, say _a2_, has one
5180 * _a_ [ i, j ] = _a1_ [ i, j ] - _a2_ [ i, 0 ].
5181 * 3. The arrays have same number of components and one array, say _a2_, has one
5183 * _a_ [ i, j ] = _a1_ [ i, j ] - _a2_ [ 0, j ].
5185 * Info on components is copied either from the first array (in the first case) or from
5186 * the array with maximal number of elements (getNbOfElems()).
5187 * \param [in] a1 - an array to subtract from.
5188 * \param [in] a2 - an array to subtract.
5189 * \return DataArrayDouble * - the new instance of DataArrayDouble.
5190 * The caller is to delete this result array using decrRef() as it is no more
5192 * \throw If either \a a1 or \a a2 is NULL.
5193 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples() and
5194 * \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents() and
5195 * none of them has number of tuples or components equal to 1.
5197 DataArrayDouble *DataArrayDouble::Substract(const DataArrayDouble *a1, const DataArrayDouble *a2)
5200 throw INTERP_KERNEL::Exception("DataArrayDouble::Substract : input DataArrayDouble instance is NULL !");
5201 int nbOfTuple1=a1->getNumberOfTuples();
5202 int nbOfTuple2=a2->getNumberOfTuples();
5203 int nbOfComp1=a1->getNumberOfComponents();
5204 int nbOfComp2=a2->getNumberOfComponents();
5205 if(nbOfTuple2==nbOfTuple1)
5207 if(nbOfComp1==nbOfComp2)
5209 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
5210 ret->alloc(nbOfTuple2,nbOfComp1);
5211 std::transform(a1->begin(),a1->end(),a2->begin(),ret->getPointer(),std::minus<double>());
5212 ret->copyStringInfoFrom(*a1);
5215 else if(nbOfComp2==1)
5217 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
5218 ret->alloc(nbOfTuple1,nbOfComp1);
5219 const double *a2Ptr=a2->getConstPointer();
5220 const double *a1Ptr=a1->getConstPointer();
5221 double *res=ret->getPointer();
5222 for(int i=0;i<nbOfTuple1;i++)
5223 res=std::transform(a1Ptr+i*nbOfComp1,a1Ptr+(i+1)*nbOfComp1,res,std::bind2nd(std::minus<double>(),a2Ptr[i]));
5224 ret->copyStringInfoFrom(*a1);
5229 a1->checkNbOfComps(nbOfComp2,"Nb of components mismatch for array Substract !");
5233 else if(nbOfTuple2==1)
5235 a1->checkNbOfComps(nbOfComp2,"Nb of components mismatch for array Substract !");
5236 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
5237 ret->alloc(nbOfTuple1,nbOfComp1);
5238 const double *a1ptr=a1->getConstPointer(),*a2ptr=a2->getConstPointer();
5239 double *pt=ret->getPointer();
5240 for(int i=0;i<nbOfTuple1;i++)
5241 pt=std::transform(a1ptr+i*nbOfComp1,a1ptr+(i+1)*nbOfComp1,a2ptr,pt,std::minus<double>());
5242 ret->copyStringInfoFrom(*a1);
5247 a1->checkNbOfTuples(nbOfTuple2,"Nb of tuples mismatch for array Substract !");//will always throw an exception
5253 * Subtract values of another DataArrayDouble from values of \a this one. There are 3
5255 * 1. The arrays have same number of tuples and components. Then each value of
5256 * \a other array is subtracted from the corresponding value of \a this array, i.e.:
5257 * _a_ [ i, j ] -= _other_ [ i, j ].
5258 * 2. The arrays have same number of tuples and \a other array has one component. Then
5259 * _a_ [ i, j ] -= _other_ [ i, 0 ].
5260 * 3. The arrays have same number of components and \a other array has one tuple. Then
5261 * _a_ [ i, j ] -= _a2_ [ 0, j ].
5263 * \param [in] other - an array to subtract from \a this one.
5264 * \throw If \a other is NULL.
5265 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples() and
5266 * \a this->getNumberOfComponents() != \a other->getNumberOfComponents() and
5267 * \a other has number of both tuples and components not equal to 1.
5269 void DataArrayDouble::substractEqual(const DataArrayDouble *other)
5272 throw INTERP_KERNEL::Exception("DataArrayDouble::substractEqual : input DataArrayDouble instance is NULL !");
5273 const char *msg="Nb of tuples mismatch for DataArrayDouble::substractEqual !";
5275 other->checkAllocated();
5276 int nbOfTuple=getNumberOfTuples();
5277 int nbOfTuple2=other->getNumberOfTuples();
5278 int nbOfComp=getNumberOfComponents();
5279 int nbOfComp2=other->getNumberOfComponents();
5280 if(nbOfTuple==nbOfTuple2)
5282 if(nbOfComp==nbOfComp2)
5284 std::transform(begin(),end(),other->begin(),getPointer(),std::minus<double>());
5286 else if(nbOfComp2==1)
5288 double *ptr=getPointer();
5289 const double *ptrc=other->getConstPointer();
5290 for(int i=0;i<nbOfTuple;i++)
5291 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptr+i*nbOfComp,std::bind2nd(std::minus<double>(),*ptrc++));
5294 throw INTERP_KERNEL::Exception(msg);
5296 else if(nbOfTuple2==1)
5298 if(nbOfComp2==nbOfComp)
5300 double *ptr=getPointer();
5301 const double *ptrc=other->getConstPointer();
5302 for(int i=0;i<nbOfTuple;i++)
5303 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptrc,ptr+i*nbOfComp,std::minus<double>());
5306 throw INTERP_KERNEL::Exception(msg);
5309 throw INTERP_KERNEL::Exception(msg);
5314 * Returns a new DataArrayDouble that is a product of two given arrays. There are 3
5316 * 1. The arrays have same number of tuples and components. Then each value of
5317 * the result array (_a_) is a product of the corresponding values of \a a1 and
5318 * \a a2, i.e. _a_ [ i, j ] = _a1_ [ i, j ] * _a2_ [ i, j ].
5319 * 2. The arrays have same number of tuples and one array, say _a2_, has one
5321 * _a_ [ i, j ] = _a1_ [ i, j ] * _a2_ [ i, 0 ].
5322 * 3. The arrays have same number of components and one array, say _a2_, has one
5324 * _a_ [ i, j ] = _a1_ [ i, j ] * _a2_ [ 0, j ].
5326 * Info on components is copied either from the first array (in the first case) or from
5327 * the array with maximal number of elements (getNbOfElems()).
5328 * \param [in] a1 - a factor array.
5329 * \param [in] a2 - another factor array.
5330 * \return DataArrayDouble * - the new instance of DataArrayDouble.
5331 * The caller is to delete this result array using decrRef() as it is no more
5333 * \throw If either \a a1 or \a a2 is NULL.
5334 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples() and
5335 * \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents() and
5336 * none of them has number of tuples or components equal to 1.
5338 DataArrayDouble *DataArrayDouble::Multiply(const DataArrayDouble *a1, const DataArrayDouble *a2)
5341 throw INTERP_KERNEL::Exception("DataArrayDouble::Multiply : input DataArrayDouble instance is NULL !");
5342 int nbOfTuple=a1->getNumberOfTuples();
5343 int nbOfTuple2=a2->getNumberOfTuples();
5344 int nbOfComp=a1->getNumberOfComponents();
5345 int nbOfComp2=a2->getNumberOfComponents();
5346 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=0;
5347 if(nbOfTuple==nbOfTuple2)
5349 if(nbOfComp==nbOfComp2)
5351 ret=DataArrayDouble::New();
5352 ret->alloc(nbOfTuple,nbOfComp);
5353 std::transform(a1->begin(),a1->end(),a2->begin(),ret->getPointer(),std::multiplies<double>());
5354 ret->copyStringInfoFrom(*a1);
5358 int nbOfCompMin,nbOfCompMax;
5359 const DataArrayDouble *aMin, *aMax;
5360 if(nbOfComp>nbOfComp2)
5362 nbOfCompMin=nbOfComp2; nbOfCompMax=nbOfComp;
5367 nbOfCompMin=nbOfComp; nbOfCompMax=nbOfComp2;
5372 ret=DataArrayDouble::New();
5373 ret->alloc(nbOfTuple,nbOfCompMax);
5374 const double *aMinPtr=aMin->getConstPointer();
5375 const double *aMaxPtr=aMax->getConstPointer();
5376 double *res=ret->getPointer();
5377 for(int i=0;i<nbOfTuple;i++)
5378 res=std::transform(aMaxPtr+i*nbOfCompMax,aMaxPtr+(i+1)*nbOfCompMax,res,std::bind2nd(std::multiplies<double>(),aMinPtr[i]));
5379 ret->copyStringInfoFrom(*aMax);
5382 throw INTERP_KERNEL::Exception("Nb of components mismatch for array Multiply !");
5385 else if((nbOfTuple==1 && nbOfTuple2>1) || (nbOfTuple>1 && nbOfTuple2==1))
5387 if(nbOfComp==nbOfComp2)
5389 int nbOfTupleMax=std::max(nbOfTuple,nbOfTuple2);
5390 const DataArrayDouble *aMin=nbOfTuple>nbOfTuple2?a2:a1;
5391 const DataArrayDouble *aMax=nbOfTuple>nbOfTuple2?a1:a2;
5392 const double *aMinPtr=aMin->getConstPointer(),*aMaxPtr=aMax->getConstPointer();
5393 ret=DataArrayDouble::New();
5394 ret->alloc(nbOfTupleMax,nbOfComp);
5395 double *res=ret->getPointer();
5396 for(int i=0;i<nbOfTupleMax;i++)
5397 res=std::transform(aMaxPtr+i*nbOfComp,aMaxPtr+(i+1)*nbOfComp,aMinPtr,res,std::multiplies<double>());
5398 ret->copyStringInfoFrom(*aMax);
5401 throw INTERP_KERNEL::Exception("Nb of components mismatch for array Multiply !");
5404 throw INTERP_KERNEL::Exception("Nb of tuples mismatch for array Multiply !");
5409 * Multiply values of another DataArrayDouble to values of \a this one. There are 3
5411 * 1. The arrays have same number of tuples and components. Then each value of
5412 * \a other array is multiplied to the corresponding value of \a this array, i.e.
5413 * _this_ [ i, j ] *= _other_ [ i, j ].
5414 * 2. The arrays have same number of tuples and \a other array has one component. Then
5415 * _this_ [ i, j ] *= _other_ [ i, 0 ].
5416 * 3. The arrays have same number of components and \a other array has one tuple. Then
5417 * _this_ [ i, j ] *= _a2_ [ 0, j ].
5419 * \param [in] other - an array to multiply to \a this one.
5420 * \throw If \a other is NULL.
5421 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples() and
5422 * \a this->getNumberOfComponents() != \a other->getNumberOfComponents() and
5423 * \a other has number of both tuples and components not equal to 1.
5425 void DataArrayDouble::multiplyEqual(const DataArrayDouble *other)
5428 throw INTERP_KERNEL::Exception("DataArrayDouble::multiplyEqual : input DataArrayDouble instance is NULL !");
5429 const char *msg="Nb of tuples mismatch for DataArrayDouble::multiplyEqual !";
5431 other->checkAllocated();
5432 int nbOfTuple=getNumberOfTuples();
5433 int nbOfTuple2=other->getNumberOfTuples();
5434 int nbOfComp=getNumberOfComponents();
5435 int nbOfComp2=other->getNumberOfComponents();
5436 if(nbOfTuple==nbOfTuple2)
5438 if(nbOfComp==nbOfComp2)
5440 std::transform(begin(),end(),other->begin(),getPointer(),std::multiplies<double>());
5442 else if(nbOfComp2==1)
5444 double *ptr=getPointer();
5445 const double *ptrc=other->getConstPointer();
5446 for(int i=0;i<nbOfTuple;i++)
5447 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptr+i*nbOfComp,std::bind2nd(std::multiplies<double>(),*ptrc++));
5450 throw INTERP_KERNEL::Exception(msg);
5452 else if(nbOfTuple2==1)
5454 if(nbOfComp2==nbOfComp)
5456 double *ptr=getPointer();
5457 const double *ptrc=other->getConstPointer();
5458 for(int i=0;i<nbOfTuple;i++)
5459 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptrc,ptr+i*nbOfComp,std::multiplies<double>());
5462 throw INTERP_KERNEL::Exception(msg);
5465 throw INTERP_KERNEL::Exception(msg);
5470 * Returns a new DataArrayDouble that is a division of two given arrays. There are 3
5472 * 1. The arrays have same number of tuples and components. Then each value of
5473 * the result array (_a_) is a division of the corresponding values of \a a1 and
5474 * \a a2, i.e.: _a_ [ i, j ] = _a1_ [ i, j ] / _a2_ [ i, j ].
5475 * 2. The arrays have same number of tuples and one array, say _a2_, has one
5477 * _a_ [ i, j ] = _a1_ [ i, j ] / _a2_ [ i, 0 ].
5478 * 3. The arrays have same number of components and one array, say _a2_, has one
5480 * _a_ [ i, j ] = _a1_ [ i, j ] / _a2_ [ 0, j ].
5482 * Info on components is copied either from the first array (in the first case) or from
5483 * the array with maximal number of elements (getNbOfElems()).
5484 * \warning No check of division by zero is performed!
5485 * \param [in] a1 - a numerator array.
5486 * \param [in] a2 - a denominator array.
5487 * \return DataArrayDouble * - the new instance of DataArrayDouble.
5488 * The caller is to delete this result array using decrRef() as it is no more
5490 * \throw If either \a a1 or \a a2 is NULL.
5491 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples() and
5492 * \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents() and
5493 * none of them has number of tuples or components equal to 1.
5495 DataArrayDouble *DataArrayDouble::Divide(const DataArrayDouble *a1, const DataArrayDouble *a2)
5498 throw INTERP_KERNEL::Exception("DataArrayDouble::Divide : input DataArrayDouble instance is NULL !");
5499 int nbOfTuple1=a1->getNumberOfTuples();
5500 int nbOfTuple2=a2->getNumberOfTuples();
5501 int nbOfComp1=a1->getNumberOfComponents();
5502 int nbOfComp2=a2->getNumberOfComponents();
5503 if(nbOfTuple2==nbOfTuple1)
5505 if(nbOfComp1==nbOfComp2)
5507 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
5508 ret->alloc(nbOfTuple2,nbOfComp1);
5509 std::transform(a1->begin(),a1->end(),a2->begin(),ret->getPointer(),std::divides<double>());
5510 ret->copyStringInfoFrom(*a1);
5513 else if(nbOfComp2==1)
5515 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
5516 ret->alloc(nbOfTuple1,nbOfComp1);
5517 const double *a2Ptr=a2->getConstPointer();
5518 const double *a1Ptr=a1->getConstPointer();
5519 double *res=ret->getPointer();
5520 for(int i=0;i<nbOfTuple1;i++)
5521 res=std::transform(a1Ptr+i*nbOfComp1,a1Ptr+(i+1)*nbOfComp1,res,std::bind2nd(std::divides<double>(),a2Ptr[i]));
5522 ret->copyStringInfoFrom(*a1);
5527 a1->checkNbOfComps(nbOfComp2,"Nb of components mismatch for array Divide !");
5531 else if(nbOfTuple2==1)
5533 a1->checkNbOfComps(nbOfComp2,"Nb of components mismatch for array Divide !");
5534 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
5535 ret->alloc(nbOfTuple1,nbOfComp1);
5536 const double *a1ptr=a1->getConstPointer(),*a2ptr=a2->getConstPointer();
5537 double *pt=ret->getPointer();
5538 for(int i=0;i<nbOfTuple1;i++)
5539 pt=std::transform(a1ptr+i*nbOfComp1,a1ptr+(i+1)*nbOfComp1,a2ptr,pt,std::divides<double>());
5540 ret->copyStringInfoFrom(*a1);
5545 a1->checkNbOfTuples(nbOfTuple2,"Nb of tuples mismatch for array Divide !");//will always throw an exception
5551 * Divide values of \a this array by values of another DataArrayDouble. There are 3
5553 * 1. The arrays have same number of tuples and components. Then each value of
5554 * \a this array is divided by the corresponding value of \a other one, i.e.:
5555 * _a_ [ i, j ] /= _other_ [ i, j ].
5556 * 2. The arrays have same number of tuples and \a other array has one component. Then
5557 * _a_ [ i, j ] /= _other_ [ i, 0 ].
5558 * 3. The arrays have same number of components and \a other array has one tuple. Then
5559 * _a_ [ i, j ] /= _a2_ [ 0, j ].
5561 * \warning No check of division by zero is performed!
5562 * \param [in] other - an array to divide \a this one by.
5563 * \throw If \a other is NULL.
5564 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples() and
5565 * \a this->getNumberOfComponents() != \a other->getNumberOfComponents() and
5566 * \a other has number of both tuples and components not equal to 1.
5568 void DataArrayDouble::divideEqual(const DataArrayDouble *other)
5571 throw INTERP_KERNEL::Exception("DataArrayDouble::divideEqual : input DataArrayDouble instance is NULL !");
5572 const char *msg="Nb of tuples mismatch for DataArrayDouble::divideEqual !";
5574 other->checkAllocated();
5575 int nbOfTuple=getNumberOfTuples();
5576 int nbOfTuple2=other->getNumberOfTuples();
5577 int nbOfComp=getNumberOfComponents();
5578 int nbOfComp2=other->getNumberOfComponents();
5579 if(nbOfTuple==nbOfTuple2)
5581 if(nbOfComp==nbOfComp2)
5583 std::transform(begin(),end(),other->begin(),getPointer(),std::divides<double>());
5585 else if(nbOfComp2==1)
5587 double *ptr=getPointer();
5588 const double *ptrc=other->getConstPointer();
5589 for(int i=0;i<nbOfTuple;i++)
5590 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptr+i*nbOfComp,std::bind2nd(std::divides<double>(),*ptrc++));
5593 throw INTERP_KERNEL::Exception(msg);
5595 else if(nbOfTuple2==1)
5597 if(nbOfComp2==nbOfComp)
5599 double *ptr=getPointer();
5600 const double *ptrc=other->getConstPointer();
5601 for(int i=0;i<nbOfTuple;i++)
5602 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptrc,ptr+i*nbOfComp,std::divides<double>());
5605 throw INTERP_KERNEL::Exception(msg);
5608 throw INTERP_KERNEL::Exception(msg);
5613 * Returns a new DataArrayDouble that is the result of pow of two given arrays. There are 3
5616 * \param [in] a1 - an array to pow up.
5617 * \param [in] a2 - another array to sum up.
5618 * \return DataArrayDouble * - the new instance of DataArrayDouble.
5619 * The caller is to delete this result array using decrRef() as it is no more
5621 * \throw If either \a a1 or \a a2 is NULL.
5622 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples()
5623 * \throw If \a a1->getNumberOfComponents() != 1 or \a a2->getNumberOfComponents() != 1.
5624 * \throw If there is a negative value in \a a1.
5626 DataArrayDouble *DataArrayDouble::Pow(const DataArrayDouble *a1, const DataArrayDouble *a2)
5629 throw INTERP_KERNEL::Exception("DataArrayDouble::Pow : at least one of input instances is null !");
5630 int nbOfTuple=a1->getNumberOfTuples();
5631 int nbOfTuple2=a2->getNumberOfTuples();
5632 int nbOfComp=a1->getNumberOfComponents();
5633 int nbOfComp2=a2->getNumberOfComponents();
5634 if(nbOfTuple!=nbOfTuple2)
5635 throw INTERP_KERNEL::Exception("DataArrayDouble::Pow : number of tuples mismatches !");
5636 if(nbOfComp!=1 || nbOfComp2!=1)
5637 throw INTERP_KERNEL::Exception("DataArrayDouble::Pow : number of components of both arrays must be equal to 1 !");
5638 MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New(); ret->alloc(nbOfTuple,1);
5639 const double *ptr1(a1->begin()),*ptr2(a2->begin());
5640 double *ptr=ret->getPointer();
5641 for(int i=0;i<nbOfTuple;i++,ptr1++,ptr2++,ptr++)
5645 *ptr=pow(*ptr1,*ptr2);
5649 std::ostringstream oss; oss << "DataArrayDouble::Pow : on tuple #" << i << " of a1 value is < 0 (" << *ptr1 << ") !";
5650 throw INTERP_KERNEL::Exception(oss.str().c_str());
5657 * Apply pow on values of another DataArrayDouble to values of \a this one.
5659 * \param [in] other - an array to pow to \a this one.
5660 * \throw If \a other is NULL.
5661 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples()
5662 * \throw If \a this->getNumberOfComponents() != 1 or \a other->getNumberOfComponents() != 1
5663 * \throw If there is a negative value in \a this.
5665 void DataArrayDouble::powEqual(const DataArrayDouble *other)
5668 throw INTERP_KERNEL::Exception("DataArrayDouble::powEqual : input instance is null !");
5669 int nbOfTuple=getNumberOfTuples();
5670 int nbOfTuple2=other->getNumberOfTuples();
5671 int nbOfComp=getNumberOfComponents();
5672 int nbOfComp2=other->getNumberOfComponents();
5673 if(nbOfTuple!=nbOfTuple2)
5674 throw INTERP_KERNEL::Exception("DataArrayDouble::powEqual : number of tuples mismatches !");
5675 if(nbOfComp!=1 || nbOfComp2!=1)
5676 throw INTERP_KERNEL::Exception("DataArrayDouble::powEqual : number of components of both arrays must be equal to 1 !");
5677 double *ptr=getPointer();
5678 const double *ptrc=other->begin();
5679 for(int i=0;i<nbOfTuple;i++,ptrc++,ptr++)
5682 *ptr=pow(*ptr,*ptrc);
5685 std::ostringstream oss; oss << "DataArrayDouble::powEqual : on tuple #" << i << " of this value is < 0 (" << *ptr << ") !";
5686 throw INTERP_KERNEL::Exception(oss.str().c_str());
5693 * This method is \b NOT wrapped into python because it can be useful only for performance reasons in C++ context.
5694 * All values in \a this must be 0. or 1. within eps error. 0 means false, 1 means true.
5695 * If an another value than 0 or 1 appear (within eps precision) an INTERP_KERNEL::Exception will be thrown.
5697 * \throw if \a this is not allocated.
5698 * \throw if \a this has not exactly one component.
5700 std::vector<bool> DataArrayDouble::toVectorOfBool(double eps) const
5703 if(getNumberOfComponents()!=1)
5704 throw INTERP_KERNEL::Exception("DataArrayDouble::toVectorOfBool : must be applied on single component array !");
5705 int nbt(getNumberOfTuples());
5706 std::vector<bool> ret(nbt);
5707 const double *pt(begin());
5708 for(int i=0;i<nbt;i++)
5712 else if(fabs(pt[i]-1.)<eps)
5716 std::ostringstream oss; oss << "DataArrayDouble::toVectorOfBool : the tuple #" << i << " has value " << pt[i] << " is invalid ! must be 0. or 1. !";
5717 throw INTERP_KERNEL::Exception(oss.str().c_str());
5724 * Useless method for end user. Only for MPI/Corba/File serialsation for multi arrays class.
5727 void DataArrayDouble::getTinySerializationIntInformation(std::vector<int>& tinyInfo) const
5732 tinyInfo[0]=getNumberOfTuples();
5733 tinyInfo[1]=getNumberOfComponents();
5743 * Useless method for end user. Only for MPI/Corba/File serialsation for multi arrays class.
5746 void DataArrayDouble::getTinySerializationStrInformation(std::vector<std::string>& tinyInfo) const
5750 int nbOfCompo=getNumberOfComponents();
5751 tinyInfo.resize(nbOfCompo+1);
5752 tinyInfo[0]=getName();
5753 for(int i=0;i<nbOfCompo;i++)
5754 tinyInfo[i+1]=getInfoOnComponent(i);
5759 tinyInfo[0]=getName();
5764 * Useless method for end user. Only for MPI/Corba/File serialsation for multi arrays class.
5765 * This method returns if a feeding is needed.
5767 bool DataArrayDouble::resizeForUnserialization(const std::vector<int>& tinyInfoI)
5769 int nbOfTuple=tinyInfoI[0];
5770 int nbOfComp=tinyInfoI[1];
5771 if(nbOfTuple!=-1 || nbOfComp!=-1)
5773 alloc(nbOfTuple,nbOfComp);
5780 * Useless method for end user. Only for MPI/Corba/File serialsation for multi arrays class.
5782 void DataArrayDouble::finishUnserialization(const std::vector<int>& tinyInfoI, const std::vector<std::string>& tinyInfoS)
5784 setName(tinyInfoS[0]);
5787 int nbOfCompo=getNumberOfComponents();
5788 for(int i=0;i<nbOfCompo;i++)
5789 setInfoOnComponent(i,tinyInfoS[i+1]);
5793 DataArrayDoubleIterator::DataArrayDoubleIterator(DataArrayDouble *da):_da(da),_tuple_id(0),_nb_comp(0),_nb_tuple(0)
5798 if(_da->isAllocated())
5800 _nb_comp=da->getNumberOfComponents();
5801 _nb_tuple=da->getNumberOfTuples();
5802 _pt=da->getPointer();
5807 DataArrayDoubleIterator::~DataArrayDoubleIterator()
5813 DataArrayDoubleTuple *DataArrayDoubleIterator::nextt()
5815 if(_tuple_id<_nb_tuple)
5818 DataArrayDoubleTuple *ret=new DataArrayDoubleTuple(_pt,_nb_comp);
5826 DataArrayDoubleTuple::DataArrayDoubleTuple(double *pt, int nbOfComp):_pt(pt),_nb_of_compo(nbOfComp)
5831 std::string DataArrayDoubleTuple::repr() const
5833 std::ostringstream oss; oss.precision(17); oss << "(";
5834 for(int i=0;i<_nb_of_compo-1;i++)
5835 oss << _pt[i] << ", ";
5836 oss << _pt[_nb_of_compo-1] << ")";
5840 double DataArrayDoubleTuple::doubleValue() const
5844 throw INTERP_KERNEL::Exception("DataArrayDoubleTuple::doubleValue : DataArrayDoubleTuple instance has not exactly 1 component -> Not possible to convert it into a double precision float !");
5848 * This method returns a newly allocated instance the caller should dealed with by a ParaMEDMEM::DataArrayDouble::decrRef.
5849 * This method performs \b no copy of data. The content is only referenced using ParaMEDMEM::DataArrayDouble::useArray with ownership set to \b false.
5850 * This method throws an INTERP_KERNEL::Exception is it is impossible to match sizes of \b this that is too say \b nbOfCompo=this->_nb_of_elem and \bnbOfTuples==1 or
5851 * \b nbOfCompo=1 and \bnbOfTuples==this->_nb_of_elem.
5853 DataArrayDouble *DataArrayDoubleTuple::buildDADouble(int nbOfTuples, int nbOfCompo) const
5855 if((_nb_of_compo==nbOfCompo && nbOfTuples==1) || (_nb_of_compo==nbOfTuples && nbOfCompo==1))
5857 DataArrayDouble *ret=DataArrayDouble::New();
5858 ret->useExternalArrayWithRWAccess(_pt,nbOfTuples,nbOfCompo);
5863 std::ostringstream oss; oss << "DataArrayDoubleTuple::buildDADouble : unable to build a requested DataArrayDouble instance with nbofTuple=" << nbOfTuples << " and nbOfCompo=" << nbOfCompo;
5864 oss << ".\nBecause the number of elements in this is " << _nb_of_compo << " !";
5865 throw INTERP_KERNEL::Exception(oss.str().c_str());
5870 * Returns a new instance of DataArrayInt. The caller is to delete this array
5871 * using decrRef() as it is no more needed.
5873 DataArrayInt *DataArrayInt::New()
5875 return new DataArrayInt;
5879 * Checks if raw data is allocated. Read more on the raw data
5880 * in \ref MEDCouplingArrayBasicsTuplesAndCompo "DataArrays infos" for more information.
5881 * \return bool - \a true if the raw data is allocated, \a false else.
5883 bool DataArrayInt::isAllocated() const
5885 return getConstPointer()!=0;
5889 * Checks if raw data is allocated and throws an exception if it is not the case.
5890 * \throw If the raw data is not allocated.
5892 void DataArrayInt::checkAllocated() const
5895 throw INTERP_KERNEL::Exception("DataArrayInt::checkAllocated : Array is defined but not allocated ! Call alloc or setValues method first !");
5899 * This method desallocated \a this without modification of informations relative to the components.
5900 * After call of this method, DataArrayInt::isAllocated will return false.
5901 * If \a this is already not allocated, \a this is let unchanged.
5903 void DataArrayInt::desallocate()
5908 std::size_t DataArrayInt::getHeapMemorySizeWithoutChildren() const
5910 std::size_t sz(_mem.getNbOfElemAllocated());
5912 return DataArray::getHeapMemorySizeWithoutChildren()+sz;
5916 * Returns the only one value in \a this, if and only if number of elements
5917 * (nb of tuples * nb of components) is equal to 1, and that \a this is allocated.
5918 * \return double - the sole value stored in \a this array.
5919 * \throw If at least one of conditions stated above is not fulfilled.
5921 int DataArrayInt::intValue() const
5925 if(getNbOfElems()==1)
5927 return *getConstPointer();
5930 throw INTERP_KERNEL::Exception("DataArrayInt::intValue : DataArrayInt instance is allocated but number of elements is not equal to 1 !");
5933 throw INTERP_KERNEL::Exception("DataArrayInt::intValue : DataArrayInt instance is not allocated !");
5937 * Returns an integer value characterizing \a this array, which is useful for a quick
5938 * comparison of many instances of DataArrayInt.
5939 * \return int - the hash value.
5940 * \throw If \a this is not allocated.
5942 int DataArrayInt::getHashCode() const
5945 std::size_t nbOfElems=getNbOfElems();
5946 int ret=nbOfElems*65536;
5951 const int *pt=begin();
5952 for(std::size_t i=0;i<nbOfElems;i+=delta)
5953 ret0+=pt[i] & 0x1FFF;
5958 * Checks the number of tuples.
5959 * \return bool - \a true if getNumberOfTuples() == 0, \a false else.
5960 * \throw If \a this is not allocated.
5962 bool DataArrayInt::empty() const
5965 return getNumberOfTuples()==0;
5969 * Returns a full copy of \a this. For more info on copying data arrays see
5970 * \ref MEDCouplingArrayBasicsCopyDeep.
5971 * \return DataArrayInt * - a new instance of DataArrayInt.
5973 DataArrayInt *DataArrayInt::deepCpy() const
5975 return new DataArrayInt(*this);
5979 * Returns either a \a deep or \a shallow copy of this array. For more info see
5980 * \ref MEDCouplingArrayBasicsCopyDeep and \ref MEDCouplingArrayBasicsCopyShallow.
5981 * \param [in] dCpy - if \a true, a deep copy is returned, else, a shallow one.
5982 * \return DataArrayInt * - either a new instance of DataArrayInt (if \a dCpy
5983 * == \a true) or \a this instance (if \a dCpy == \a false).
5985 DataArrayInt *DataArrayInt::performCpy(bool dCpy) const
5992 return const_cast<DataArrayInt *>(this);
5997 * Copies all the data from another DataArrayInt. For more info see
5998 * \ref MEDCouplingArrayBasicsCopyDeepAssign.
5999 * \param [in] other - another instance of DataArrayInt to copy data from.
6000 * \throw If the \a other is not allocated.
6002 void DataArrayInt::cpyFrom(const DataArrayInt& other)
6004 other.checkAllocated();
6005 int nbOfTuples=other.getNumberOfTuples();
6006 int nbOfComp=other.getNumberOfComponents();
6007 allocIfNecessary(nbOfTuples,nbOfComp);
6008 std::size_t nbOfElems=(std::size_t)nbOfTuples*nbOfComp;
6009 int *pt=getPointer();
6010 const int *ptI=other.getConstPointer();
6011 for(std::size_t i=0;i<nbOfElems;i++)
6013 copyStringInfoFrom(other);
6017 * This method reserve nbOfElems elements in memory ( nbOfElems*4 bytes ) \b without impacting the number of tuples in \a this.
6018 * If \a this has already been allocated, this method checks that \a this has only one component. If not an INTERP_KERNEL::Exception will be thrown.
6019 * If \a this has not already been allocated, number of components is set to one.
6020 * This method allows to reduce number of reallocations on invokation of DataArrayInt::pushBackSilent and DataArrayInt::pushBackValsSilent on \a this.
6022 * \sa DataArrayInt::pack, DataArrayInt::pushBackSilent, DataArrayInt::pushBackValsSilent
6024 void DataArrayInt::reserve(std::size_t nbOfElems)
6026 int nbCompo=getNumberOfComponents();
6029 _mem.reserve(nbOfElems);
6033 _mem.reserve(nbOfElems);
6034 _info_on_compo.resize(1);
6037 throw INTERP_KERNEL::Exception("DataArrayInt::reserve : not available for DataArrayInt with number of components different than 1 !");
6041 * This method adds at the end of \a this the single value \a val. This method do \b not update its time label to avoid useless incrementation
6042 * of counter. So the caller is expected to call TimeLabel::declareAsNew on \a this at the end of the push session.
6044 * \param [in] val the value to be added in \a this
6045 * \throw If \a this has already been allocated with number of components different from one.
6046 * \sa DataArrayInt::pushBackValsSilent
6048 void DataArrayInt::pushBackSilent(int val)
6050 int nbCompo=getNumberOfComponents();
6055 _info_on_compo.resize(1);
6059 throw INTERP_KERNEL::Exception("DataArrayInt::pushBackSilent : not available for DataArrayInt with number of components different than 1 !");
6063 * This method adds at the end of \a this a serie of values [\c valsBg,\c valsEnd). This method do \b not update its time label to avoid useless incrementation
6064 * of counter. So the caller is expected to call TimeLabel::declareAsNew on \a this at the end of the push session.
6066 * \param [in] valsBg - an array of values to push at the end of \this.
6067 * \param [in] valsEnd - specifies the end of the array \a valsBg, so that
6068 * the last value of \a valsBg is \a valsEnd[ -1 ].
6069 * \throw If \a this has already been allocated with number of components different from one.
6070 * \sa DataArrayInt::pushBackSilent
6072 void DataArrayInt::pushBackValsSilent(const int *valsBg, const int *valsEnd)
6074 int nbCompo=getNumberOfComponents();
6076 _mem.insertAtTheEnd(valsBg,valsEnd);
6079 _info_on_compo.resize(1);
6080 _mem.insertAtTheEnd(valsBg,valsEnd);
6083 throw INTERP_KERNEL::Exception("DataArrayInt::pushBackValsSilent : not available for DataArrayInt with number of components different than 1 !");
6087 * This method returns silently ( without updating time label in \a this ) the last value, if any and suppress it.
6088 * \throw If \a this is already empty.
6089 * \throw If \a this has number of components different from one.
6091 int DataArrayInt::popBackSilent()
6093 if(getNumberOfComponents()==1)
6094 return _mem.popBack();
6096 throw INTERP_KERNEL::Exception("DataArrayInt::popBackSilent : not available for DataArrayInt with number of components different than 1 !");
6100 * This method \b do \b not modify content of \a this. It only modify its memory footprint if the allocated memory is to high regarding real data to store.
6102 * \sa DataArrayInt::getHeapMemorySizeWithoutChildren, DataArrayInt::reserve
6104 void DataArrayInt::pack() const
6110 * Allocates the raw data in memory. If exactly as same memory as needed already
6111 * allocated, it is not re-allocated.
6112 * \param [in] nbOfTuple - number of tuples of data to allocate.
6113 * \param [in] nbOfCompo - number of components of data to allocate.
6114 * \throw If \a nbOfTuple < 0 or \a nbOfCompo < 0.
6116 void DataArrayInt::allocIfNecessary(int nbOfTuple, int nbOfCompo)
6120 if(nbOfTuple!=getNumberOfTuples() || nbOfCompo!=getNumberOfComponents())
6121 alloc(nbOfTuple,nbOfCompo);
6124 alloc(nbOfTuple,nbOfCompo);
6128 * Allocates the raw data in memory. If the memory was already allocated, then it is
6129 * freed and re-allocated. See an example of this method use
6130 * \ref MEDCouplingArraySteps1WC "here".
6131 * \param [in] nbOfTuple - number of tuples of data to allocate.
6132 * \param [in] nbOfCompo - number of components of data to allocate.
6133 * \throw If \a nbOfTuple < 0 or \a nbOfCompo < 0.
6135 void DataArrayInt::alloc(int nbOfTuple, int nbOfCompo)
6137 if(nbOfTuple<0 || nbOfCompo<0)
6138 throw INTERP_KERNEL::Exception("DataArrayInt::alloc : request for negative length of data !");
6139 _info_on_compo.resize(nbOfCompo);
6140 _mem.alloc(nbOfCompo*(std::size_t)nbOfTuple);
6145 * Assign zero to all values in \a this array. To know more on filling arrays see
6146 * \ref MEDCouplingArrayFill.
6147 * \throw If \a this is not allocated.
6149 void DataArrayInt::fillWithZero()
6152 _mem.fillWithValue(0);
6157 * Assign \a val to all values in \a this array. To know more on filling arrays see
6158 * \ref MEDCouplingArrayFill.
6159 * \param [in] val - the value to fill with.
6160 * \throw If \a this is not allocated.
6162 void DataArrayInt::fillWithValue(int val)
6165 _mem.fillWithValue(val);
6170 * Set all values in \a this array so that the i-th element equals to \a init + i
6171 * (i starts from zero). To know more on filling arrays see \ref MEDCouplingArrayFill.
6172 * \param [in] init - value to assign to the first element of array.
6173 * \throw If \a this->getNumberOfComponents() != 1
6174 * \throw If \a this is not allocated.
6176 void DataArrayInt::iota(int init)
6179 if(getNumberOfComponents()!=1)
6180 throw INTERP_KERNEL::Exception("DataArrayInt::iota : works only for arrays with only one component, you can call 'rearrange' method before !");
6181 int *ptr=getPointer();
6182 int ntuples=getNumberOfTuples();
6183 for(int i=0;i<ntuples;i++)
6189 * Returns a textual and human readable representation of \a this instance of
6190 * DataArrayInt. This text is shown when a DataArrayInt is printed in Python.
6191 * \return std::string - text describing \a this DataArrayInt.
6193 std::string DataArrayInt::repr() const
6195 std::ostringstream ret;
6200 std::string DataArrayInt::reprZip() const
6202 std::ostringstream ret;
6207 void DataArrayInt::writeVTK(std::ostream& ofs, int indent, const std::string& type, const std::string& nameInFile, DataArrayByte *byteArr) const
6209 static const char SPACE[4]={' ',' ',' ',' '};
6211 std::string idt(indent,' ');
6212 ofs << idt << "<DataArray type=\"" << type << "\" Name=\"" << nameInFile << "\" NumberOfComponents=\"" << getNumberOfComponents() << "\"";
6215 ofs << " format=\"appended\" offset=\"" << byteArr->getNumberOfTuples() << "\">";
6216 if(std::string(type)=="Int32")
6218 const char *data(reinterpret_cast<const char *>(begin()));
6219 std::size_t sz(getNbOfElems()*sizeof(int));
6220 byteArr->insertAtTheEnd(data,data+sz);
6221 byteArr->insertAtTheEnd(SPACE,SPACE+4);
6223 else if(std::string(type)=="Int8")
6225 INTERP_KERNEL::AutoPtr<char> tmp(new char[getNbOfElems()]);
6226 std::copy(begin(),end(),(char *)tmp);
6227 byteArr->insertAtTheEnd((char *)tmp,(char *)tmp+getNbOfElems());
6228 byteArr->insertAtTheEnd(SPACE,SPACE+4);
6230 else if(std::string(type)=="UInt8")
6232 INTERP_KERNEL::AutoPtr<unsigned char> tmp(new unsigned char[getNbOfElems()]);
6233 std::copy(begin(),end(),(unsigned char *)tmp);
6234 byteArr->insertAtTheEnd((unsigned char *)tmp,(unsigned char *)tmp+getNbOfElems());
6235 byteArr->insertAtTheEnd(SPACE,SPACE+4);
6238 throw INTERP_KERNEL::Exception("DataArrayInt::writeVTK : Only Int32, Int8 and UInt8 supported !");
6242 ofs << " RangeMin=\"" << getMinValueInArray() << "\" RangeMax=\"" << getMaxValueInArray() << "\" format=\"ascii\">\n" << idt;
6243 std::copy(begin(),end(),std::ostream_iterator<int>(ofs," "));
6245 ofs << std::endl << idt << "</DataArray>\n";
6248 void DataArrayInt::reprStream(std::ostream& stream) const
6250 stream << "Name of int array : \"" << _name << "\"\n";
6251 reprWithoutNameStream(stream);
6254 void DataArrayInt::reprZipStream(std::ostream& stream) const
6256 stream << "Name of int array : \"" << _name << "\"\n";
6257 reprZipWithoutNameStream(stream);
6260 void DataArrayInt::reprWithoutNameStream(std::ostream& stream) const
6262 DataArray::reprWithoutNameStream(stream);
6263 _mem.repr(getNumberOfComponents(),stream);
6266 void DataArrayInt::reprZipWithoutNameStream(std::ostream& stream) const
6268 DataArray::reprWithoutNameStream(stream);
6269 _mem.reprZip(getNumberOfComponents(),stream);
6272 void DataArrayInt::reprCppStream(const std::string& varName, std::ostream& stream) const
6274 int nbTuples=getNumberOfTuples(),nbComp=getNumberOfComponents();
6275 const int *data=getConstPointer();
6276 stream << "DataArrayInt *" << varName << "=DataArrayInt::New();" << std::endl;
6277 if(nbTuples*nbComp>=1)
6279 stream << "const int " << varName << "Data[" << nbTuples*nbComp << "]={";
6280 std::copy(data,data+nbTuples*nbComp-1,std::ostream_iterator<int>(stream,","));
6281 stream << data[nbTuples*nbComp-1] << "};" << std::endl;
6282 stream << varName << "->useArray(" << varName << "Data,false,CPP_DEALLOC," << nbTuples << "," << nbComp << ");" << std::endl;
6285 stream << varName << "->alloc(" << nbTuples << "," << nbComp << ");" << std::endl;
6286 stream << varName << "->setName(\"" << getName() << "\");" << std::endl;
6290 * Method that gives a quick overvien of \a this for python.
6292 void DataArrayInt::reprQuickOverview(std::ostream& stream) const
6294 static const std::size_t MAX_NB_OF_BYTE_IN_REPR=300;
6295 stream << "DataArrayInt C++ instance at " << this << ". ";
6298 int nbOfCompo=(int)_info_on_compo.size();
6301 int nbOfTuples=getNumberOfTuples();
6302 stream << "Number of tuples : " << nbOfTuples << ". Number of components : " << nbOfCompo << "." << std::endl;
6303 reprQuickOverviewData(stream,MAX_NB_OF_BYTE_IN_REPR);
6306 stream << "Number of components : 0.";
6309 stream << "*** No data allocated ****";
6312 void DataArrayInt::reprQuickOverviewData(std::ostream& stream, std::size_t maxNbOfByteInRepr) const
6314 const int *data=begin();
6315 int nbOfTuples=getNumberOfTuples();
6316 int nbOfCompo=(int)_info_on_compo.size();
6317 std::ostringstream oss2; oss2 << "[";
6318 std::string oss2Str(oss2.str());
6319 bool isFinished=true;
6320 for(int i=0;i<nbOfTuples && isFinished;i++)
6325 for(int j=0;j<nbOfCompo;j++,data++)
6328 if(j!=nbOfCompo-1) oss2 << ", ";
6334 if(i!=nbOfTuples-1) oss2 << ", ";
6335 std::string oss3Str(oss2.str());
6336 if(oss3Str.length()<maxNbOfByteInRepr)
6348 * Modifies \a this one-dimensional array so that each value \a v = \a indArrBg[ \a v ],
6349 * i.e. a current value is used as in index to get a new value from \a indArrBg.
6350 * \param [in] indArrBg - pointer to the first element of array of new values to assign
6352 * \param [in] indArrEnd - specifies the end of the array \a indArrBg, so that
6353 * the last value of \a indArrBg is \a indArrEnd[ -1 ].
6354 * \throw If \a this->getNumberOfComponents() != 1
6355 * \throw If any value of \a this can't be used as a valid index for
6356 * [\a indArrBg, \a indArrEnd).
6358 void DataArrayInt::transformWithIndArr(const int *indArrBg, const int *indArrEnd)
6361 if(getNumberOfComponents()!=1)
6362 throw INTERP_KERNEL::Exception("Call transformWithIndArr method on DataArrayInt with only one component, you can call 'rearrange' method before !");
6363 int nbElemsIn=(int)std::distance(indArrBg,indArrEnd);
6364 int nbOfTuples=getNumberOfTuples();
6365 int *pt=getPointer();
6366 for(int i=0;i<nbOfTuples;i++,pt++)
6368 if(*pt>=0 && *pt<nbElemsIn)
6372 std::ostringstream oss; oss << "DataArrayInt::transformWithIndArr : error on tuple #" << i << " of this value is " << *pt << ", should be in [0," << nbElemsIn << ") !";
6373 throw INTERP_KERNEL::Exception(oss.str().c_str());
6380 * Computes distribution of values of \a this one-dimensional array between given value
6381 * ranges (casts). This method is typically useful for entity number spliting by types,
6383 * \warning The values contained in \a arrBg should be sorted ascendently. No
6384 * check of this is be done. If not, the result is not warranted.
6385 * \param [in] arrBg - the array of ascending values defining the value ranges. The i-th
6386 * value of \a arrBg (\a arrBg[ i ]) gives the lowest value of the i-th range,
6387 * and the greatest value of the i-th range equals to \a arrBg[ i+1 ] - 1. \a
6388 * arrBg containing \a n values defines \a n-1 ranges. The last value of \a arrBg
6389 * should be more than every value in \a this array.
6390 * \param [in] arrEnd - specifies the end of the array \a arrBg, so that
6391 * the last value of \a arrBg is \a arrEnd[ -1 ].
6392 * \param [out] castArr - a new instance of DataArrayInt, of same size as \a this array
6393 * (same number of tuples and components), the caller is to delete
6394 * using decrRef() as it is no more needed.
6395 * This array contains indices of ranges for every value of \a this array. I.e.
6396 * the i-th value of \a castArr gives the index of range the i-th value of \a this
6397 * belongs to. Or, in other words, this parameter contains for each tuple in \a
6398 * this in which cast it holds.
6399 * \param [out] rankInsideCast - a new instance of DataArrayInt, of same size as \a this
6400 * array, the caller is to delete using decrRef() as it is no more needed.
6401 * This array contains ranks of values of \a this array within ranges
6402 * they belongs to. I.e. the i-th value of \a rankInsideCast gives the rank of
6403 * the i-th value of \a this array within the \a castArr[ i ]-th range, to which
6404 * the i-th value of \a this belongs to. Or, in other words, this param contains
6405 * for each tuple its rank inside its cast. The rank is computed as difference
6406 * between the value and the lowest value of range.
6407 * \param [out] castsPresent - a new instance of DataArrayInt, containing indices of
6408 * ranges (casts) to which at least one value of \a this array belongs.
6409 * Or, in other words, this param contains the casts that \a this contains.
6410 * The caller is to delete this array using decrRef() as it is no more needed.
6412 * \b Example: If \a this contains [6,5,0,3,2,7,8,1,4] and \a arrBg contains [0,4,9] then
6413 * the output of this method will be :
6414 * - \a castArr : [1,1,0,0,0,1,1,0,1]
6415 * - \a rankInsideCast: [2,1,0,3,2,3,4,1,0]
6416 * - \a castsPresent : [0,1]
6418 * I.e. values of \a this array belong to 2 ranges: #0 and #1. Value 6 belongs to the
6419 * range #1 and its rank within this range is 2; etc.
6421 * \throw If \a this->getNumberOfComponents() != 1.
6422 * \throw If \a arrEnd - arrBg < 2.
6423 * \throw If any value of \a this is not less than \a arrEnd[-1].
6425 void DataArrayInt::splitByValueRange(const int *arrBg, const int *arrEnd,
6426 DataArrayInt *& castArr, DataArrayInt *& rankInsideCast, DataArrayInt *& castsPresent) const
6429 if(getNumberOfComponents()!=1)
6430 throw INTERP_KERNEL::Exception("Call splitByValueRange method on DataArrayInt with only one component, you can call 'rearrange' method before !");
6431 int nbOfTuples=getNumberOfTuples();
6432 std::size_t nbOfCast=std::distance(arrBg,arrEnd);
6434 throw INTERP_KERNEL::Exception("DataArrayInt::splitByValueRange : The input array giving the cast range values should be of size >=2 !");
6436 const int *work=getConstPointer();
6437 typedef std::reverse_iterator<const int *> rintstart;
6438 rintstart bg(arrEnd);//OK no problem because size of 'arr' is greater or equal 2
6439 rintstart end2(arrBg);
6440 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret1=DataArrayInt::New();
6441 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret2=DataArrayInt::New();
6442 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret3=DataArrayInt::New();
6443 ret1->alloc(nbOfTuples,1);
6444 ret2->alloc(nbOfTuples,1);
6445 int *ret1Ptr=ret1->getPointer();
6446 int *ret2Ptr=ret2->getPointer();
6447 std::set<std::size_t> castsDetected;
6448 for(int i=0;i<nbOfTuples;i++)
6450 rintstart res=std::find_if(bg,end2,std::bind2nd(std::less_equal<int>(), work[i]));
6451 std::size_t pos=std::distance(bg,res);
6452 std::size_t pos2=nbOfCast-pos;
6455 ret1Ptr[i]=(int)pos2;
6456 ret2Ptr[i]=work[i]-arrBg[pos2];
6457 castsDetected.insert(pos2);
6461 std::ostringstream oss; oss << "DataArrayInt::splitByValueRange : At rank #" << i << " the value is " << work[i] << " should be in [0," << *bg << ") !";
6462 throw INTERP_KERNEL::Exception(oss.str().c_str());
6465 ret3->alloc((int)castsDetected.size(),1);
6466 std::copy(castsDetected.begin(),castsDetected.end(),ret3->getPointer());
6467 castArr=ret1.retn();
6468 rankInsideCast=ret2.retn();
6469 castsPresent=ret3.retn();
6473 * Creates a one-dimensional DataArrayInt (\a res) whose contents are computed from
6474 * values of \a this (\a a) and the given (\a indArr) arrays as follows:
6475 * \a res[ \a indArr[ \a a[ i ]]] = i. I.e. for each value in place i \a v = \a a[ i ],
6476 * new value in place \a indArr[ \a v ] is i.
6477 * \param [in] indArrBg - the array holding indices within the result array to assign
6478 * indices of values of \a this array pointing to values of \a indArrBg.
6479 * \param [in] indArrEnd - specifies the end of the array \a indArrBg, so that
6480 * the last value of \a indArrBg is \a indArrEnd[ -1 ].
6481 * \return DataArrayInt * - the new instance of DataArrayInt.
6482 * The caller is to delete this result array using decrRef() as it is no more
6484 * \throw If \a this->getNumberOfComponents() != 1.
6485 * \throw If any value of \a this array is not a valid index for \a indArrBg array.
6486 * \throw If any value of \a indArrBg is not a valid index for \a this array.
6488 DataArrayInt *DataArrayInt::transformWithIndArrR(const int *indArrBg, const int *indArrEnd) const
6491 if(getNumberOfComponents()!=1)
6492 throw INTERP_KERNEL::Exception("Call transformWithIndArrR method on DataArrayInt with only one component, you can call 'rearrange' method before !");
6493 int nbElemsIn=(int)std::distance(indArrBg,indArrEnd);
6494 int nbOfTuples=getNumberOfTuples();
6495 const int *pt=getConstPointer();
6496 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
6497 ret->alloc(nbOfTuples,1);
6498 ret->fillWithValue(-1);
6499 int *tmp=ret->getPointer();
6500 for(int i=0;i<nbOfTuples;i++,pt++)
6502 if(*pt>=0 && *pt<nbElemsIn)
6504 int pos=indArrBg[*pt];
6505 if(pos>=0 && pos<nbOfTuples)
6509 std::ostringstream oss; oss << "DataArrayInt::transformWithIndArrR : error on tuple #" << i << " value of new pos is " << pos << " ( indArrBg[" << *pt << "]) ! Should be in [0," << nbOfTuples << ") !";
6510 throw INTERP_KERNEL::Exception(oss.str().c_str());
6515 std::ostringstream oss; oss << "DataArrayInt::transformWithIndArrR : error on tuple #" << i << " value is " << *pt << " and indirectionnal array as a size equal to " << nbElemsIn << " !";
6516 throw INTERP_KERNEL::Exception(oss.str().c_str());
6523 * Creates a one-dimensional DataArrayInt of given length, whose contents are computed
6524 * from values of \a this array, which is supposed to contain a renumbering map in
6525 * "Old to New" mode. The result array contains a renumbering map in "New to Old" mode.
6526 * To know how to use the renumbering maps see \ref MEDCouplingArrayRenumbering.
6527 * \param [in] newNbOfElem - the number of tuples in the result array.
6528 * \return DataArrayInt * - the new instance of DataArrayInt.
6529 * The caller is to delete this result array using decrRef() as it is no more
6532 * \if ENABLE_EXAMPLES
6533 * \ref cpp_mcdataarrayint_invertarrayo2n2n2o "Here is a C++ example".<br>
6534 * \ref py_mcdataarrayint_invertarrayo2n2n2o "Here is a Python example".
6537 DataArrayInt *DataArrayInt::invertArrayO2N2N2O(int newNbOfElem) const
6539 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
6540 ret->alloc(newNbOfElem,1);
6541 int nbOfOldNodes=getNumberOfTuples();
6542 const int *old2New=getConstPointer();
6543 int *pt=ret->getPointer();
6544 for(int i=0;i!=nbOfOldNodes;i++)
6546 int newp(old2New[i]);
6549 if(newp>=0 && newp<newNbOfElem)
6553 std::ostringstream oss; oss << "DataArrayInt::invertArrayO2N2N2O : At place #" << i << " the newplace is " << newp << " must be in [0," << newNbOfElem << ") !";
6554 throw INTERP_KERNEL::Exception(oss.str().c_str());
6562 * This method is similar to DataArrayInt::invertArrayO2N2N2O except that
6563 * Example : If \a this contains [0,1,2,0,3,4,5,4,6,4] this method will return [0,1,2,4,5,6,8] whereas DataArrayInt::invertArrayO2N2N2O returns [3,1,2,4,9,6,8]
6565 DataArrayInt *DataArrayInt::invertArrayO2N2N2OBis(int newNbOfElem) const
6567 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
6568 ret->alloc(newNbOfElem,1);
6569 int nbOfOldNodes=getNumberOfTuples();
6570 const int *old2New=getConstPointer();
6571 int *pt=ret->getPointer();
6572 for(int i=nbOfOldNodes-1;i>=0;i--)
6574 int newp(old2New[i]);
6577 if(newp>=0 && newp<newNbOfElem)
6581 std::ostringstream oss; oss << "DataArrayInt::invertArrayO2N2N2OBis : At place #" << i << " the newplace is " << newp << " must be in [0," << newNbOfElem << ") !";
6582 throw INTERP_KERNEL::Exception(oss.str().c_str());
6590 * Creates a one-dimensional DataArrayInt of given length, whose contents are computed
6591 * from values of \a this array, which is supposed to contain a renumbering map in
6592 * "New to Old" mode. The result array contains a renumbering map in "Old to New" mode.
6593 * To know how to use the renumbering maps see \ref MEDCouplingArrayRenumbering.
6594 * \param [in] newNbOfElem - the number of tuples in the result array.
6595 * \return DataArrayInt * - the new instance of DataArrayInt.
6596 * The caller is to delete this result array using decrRef() as it is no more
6599 * \if ENABLE_EXAMPLES
6600 * \ref cpp_mcdataarrayint_invertarrayn2o2o2n "Here is a C++ example".
6602 * \ref py_mcdataarrayint_invertarrayn2o2o2n "Here is a Python example".
6605 DataArrayInt *DataArrayInt::invertArrayN2O2O2N(int oldNbOfElem) const
6608 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
6609 ret->alloc(oldNbOfElem,1);
6610 const int *new2Old=getConstPointer();
6611 int *pt=ret->getPointer();
6612 std::fill(pt,pt+oldNbOfElem,-1);
6613 int nbOfNewElems=getNumberOfTuples();
6614 for(int i=0;i<nbOfNewElems;i++)
6617 if(v>=0 && v<oldNbOfElem)
6621 std::ostringstream oss; oss << "DataArrayInt::invertArrayN2O2O2N : in new id #" << i << " old value is " << v << " expected to be in [0," << oldNbOfElem << ") !";
6622 throw INTERP_KERNEL::Exception(oss.str().c_str());
6629 * Equivalent to DataArrayInt::isEqual except that if false the reason of
6630 * mismatch is given.
6632 * \param [in] other the instance to be compared with \a this
6633 * \param [out] reason In case of inequality returns the reason.
6634 * \sa DataArrayInt::isEqual
6636 bool DataArrayInt::isEqualIfNotWhy(const DataArrayInt& other, std::string& reason) const
6638 if(!areInfoEqualsIfNotWhy(other,reason))
6640 return _mem.isEqual(other._mem,0,reason);
6644 * Checks if \a this and another DataArrayInt are fully equal. For more info see
6645 * \ref MEDCouplingArrayBasicsCompare.
6646 * \param [in] other - an instance of DataArrayInt to compare with \a this one.
6647 * \return bool - \a true if the two arrays are equal, \a false else.
6649 bool DataArrayInt::isEqual(const DataArrayInt& other) const
6652 return isEqualIfNotWhy(other,tmp);
6656 * Checks if values of \a this and another DataArrayInt are equal. For more info see
6657 * \ref MEDCouplingArrayBasicsCompare.
6658 * \param [in] other - an instance of DataArrayInt to compare with \a this one.
6659 * \return bool - \a true if the values of two arrays are equal, \a false else.
6661 bool DataArrayInt::isEqualWithoutConsideringStr(const DataArrayInt& other) const
6664 return _mem.isEqual(other._mem,0,tmp);
6668 * Checks if values of \a this and another DataArrayInt are equal. Comparison is
6669 * performed on sorted value sequences.
6670 * For more info see\ref MEDCouplingArrayBasicsCompare.
6671 * \param [in] other - an instance of DataArrayInt to compare with \a this one.
6672 * \return bool - \a true if the sorted values of two arrays are equal, \a false else.
6674 bool DataArrayInt::isEqualWithoutConsideringStrAndOrder(const DataArrayInt& other) const
6676 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> a=deepCpy();
6677 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> b=other.deepCpy();
6680 return a->isEqualWithoutConsideringStr(*b);
6684 * This method compares content of input vector \a v and \a this.
6685 * If for each id in \a this v[id]==True and for all other ids id2 not in \a this v[id2]==False, true is returned.
6686 * For performance reasons \a this is expected to be sorted ascendingly. If not an exception will be thrown.
6688 * \param [in] v - the vector of 'flags' to be compared with \a this.
6690 * \throw If \a this is not sorted ascendingly.
6691 * \throw If \a this has not exactly one component.
6692 * \throw If \a this is not allocated.
6694 bool DataArrayInt::isFittingWith(const std::vector<bool>& v) const
6697 if(getNumberOfComponents()!=1)
6698 throw INTERP_KERNEL::Exception("DataArrayInt::isFittingWith : number of components of this should be equal to one !");
6699 const int *w(begin()),*end2(end());
6700 int refVal=-std::numeric_limits<int>::max();
6702 std::vector<bool>::const_iterator it(v.begin());
6703 for(;it!=v.end();it++,i++)
6715 std::ostringstream oss; oss << "DataArrayInt::isFittingWith : At pos #" << std::distance(begin(),w-1) << " this is not sorted ascendingly !";
6716 throw INTERP_KERNEL::Exception(oss.str().c_str());
6730 * Sorts values of the array.
6731 * \param [in] asc - \a true means ascending order, \a false, descending.
6732 * \throw If \a this is not allocated.
6733 * \throw If \a this->getNumberOfComponents() != 1.
6735 void DataArrayInt::sort(bool asc)
6738 if(getNumberOfComponents()!=1)
6739 throw INTERP_KERNEL::Exception("DataArrayInt::sort : only supported with 'this' array with ONE component !");
6745 * Computes for each tuple the sum of number of components values in the tuple and return it.
6747 * \return DataArrayInt * - the new instance of DataArrayInt containing the
6748 * same number of tuples as \a this array and one component.
6749 * The caller is to delete this result array using decrRef() as it is no more
6751 * \throw If \a this is not allocated.
6753 DataArrayInt *DataArrayInt::sumPerTuple() const
6756 int nbOfComp(getNumberOfComponents()),nbOfTuple(getNumberOfTuples());
6757 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New());
6758 ret->alloc(nbOfTuple,1);
6759 const int *src(getConstPointer());
6760 int *dest(ret->getPointer());
6761 for(int i=0;i<nbOfTuple;i++,dest++,src+=nbOfComp)
6762 *dest=std::accumulate(src,src+nbOfComp,0);
6767 * Reverse the array values.
6768 * \throw If \a this->getNumberOfComponents() < 1.
6769 * \throw If \a this is not allocated.
6771 void DataArrayInt::reverse()
6774 _mem.reverse(getNumberOfComponents());
6779 * Checks that \a this array is consistently **increasing** or **decreasing** in value.
6780 * If not an exception is thrown.
6781 * \param [in] increasing - if \a true, the array values should be increasing.
6782 * \throw If sequence of values is not strictly monotonic in agreement with \a
6784 * \throw If \a this->getNumberOfComponents() != 1.
6785 * \throw If \a this is not allocated.
6787 void DataArrayInt::checkMonotonic(bool increasing) const
6789 if(!isMonotonic(increasing))
6792 throw INTERP_KERNEL::Exception("DataArrayInt::checkMonotonic : 'this' is not INCREASING monotonic !");
6794 throw INTERP_KERNEL::Exception("DataArrayInt::checkMonotonic : 'this' is not DECREASING monotonic !");
6799 * Checks that \a this array is consistently **increasing** or **decreasing** in value.
6800 * \param [in] increasing - if \a true, array values should be increasing.
6801 * \return bool - \a true if values change in accordance with \a increasing arg.
6802 * \throw If \a this->getNumberOfComponents() != 1.
6803 * \throw If \a this is not allocated.
6805 bool DataArrayInt::isMonotonic(bool increasing) const
6808 if(getNumberOfComponents()!=1)
6809 throw INTERP_KERNEL::Exception("DataArrayInt::isMonotonic : only supported with 'this' array with ONE component !");
6810 int nbOfElements=getNumberOfTuples();
6811 const int *ptr=getConstPointer();
6817 for(int i=1;i<nbOfElements;i++)
6827 for(int i=1;i<nbOfElements;i++)
6839 * This method check that array consistently INCREASING or DECREASING in value.
6841 bool DataArrayInt::isStrictlyMonotonic(bool increasing) const
6844 if(getNumberOfComponents()!=1)
6845 throw INTERP_KERNEL::Exception("DataArrayInt::isStrictlyMonotonic : only supported with 'this' array with ONE component !");
6846 int nbOfElements=getNumberOfTuples();
6847 const int *ptr=getConstPointer();
6853 for(int i=1;i<nbOfElements;i++)
6863 for(int i=1;i<nbOfElements;i++)
6875 * This method check that array consistently INCREASING or DECREASING in value.
6877 void DataArrayInt::checkStrictlyMonotonic(bool increasing) const
6879 if(!isStrictlyMonotonic(increasing))
6882 throw INTERP_KERNEL::Exception("DataArrayInt::checkStrictlyMonotonic : 'this' is not strictly INCREASING monotonic !");
6884 throw INTERP_KERNEL::Exception("DataArrayInt::checkStrictlyMonotonic : 'this' is not strictly DECREASING monotonic !");
6889 * Creates a new one-dimensional DataArrayInt of the same size as \a this and a given
6890 * one-dimensional arrays that must be of the same length. The result array describes
6891 * correspondence between \a this and \a other arrays, so that
6892 * <em> other.getIJ(i,0) == this->getIJ(ret->getIJ(i),0)</em>. If such a permutation is
6893 * not possible because some element in \a other is not in \a this, an exception is thrown.
6894 * \param [in] other - an array to compute permutation to.
6895 * \return DataArrayInt * - a new instance of DataArrayInt, which is a permutation array
6896 * from \a this to \a other. The caller is to delete this array using decrRef() as it is
6898 * \throw If \a this->getNumberOfComponents() != 1.
6899 * \throw If \a other->getNumberOfComponents() != 1.
6900 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples().
6901 * \throw If \a other includes a value which is not in \a this array.
6903 * \if ENABLE_EXAMPLES
6904 * \ref cpp_mcdataarrayint_buildpermutationarr "Here is a C++ example".
6906 * \ref py_mcdataarrayint_buildpermutationarr "Here is a Python example".
6909 DataArrayInt *DataArrayInt::buildPermutationArr(const DataArrayInt& other) const
6912 if(getNumberOfComponents()!=1 || other.getNumberOfComponents()!=1)
6913 throw INTERP_KERNEL::Exception("DataArrayInt::buildPermutationArr : 'this' and 'other' have to have exactly ONE component !");
6914 int nbTuple=getNumberOfTuples();
6915 other.checkAllocated();
6916 if(nbTuple!=other.getNumberOfTuples())
6917 throw INTERP_KERNEL::Exception("DataArrayInt::buildPermutationArr : 'this' and 'other' must have the same number of tuple !");
6918 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
6919 ret->alloc(nbTuple,1);
6920 ret->fillWithValue(-1);
6921 const int *pt=getConstPointer();
6922 std::map<int,int> mm;
6923 for(int i=0;i<nbTuple;i++)
6925 pt=other.getConstPointer();
6926 int *retToFill=ret->getPointer();
6927 for(int i=0;i<nbTuple;i++)
6929 std::map<int,int>::const_iterator it=mm.find(pt[i]);
6932 std::ostringstream oss; oss << "DataArrayInt::buildPermutationArr : Arrays mismatch : element (" << pt[i] << ") in 'other' not findable in 'this' !";
6933 throw INTERP_KERNEL::Exception(oss.str().c_str());
6935 retToFill[i]=(*it).second;
6941 * Sets a C array to be used as raw data of \a this. The previously set info
6942 * of components is retained and re-sized.
6943 * For more info see \ref MEDCouplingArraySteps1.
6944 * \param [in] array - the C array to be used as raw data of \a this.
6945 * \param [in] ownership - if \a true, \a array will be deallocated at destruction of \a this.
6946 * \param [in] type - specifies how to deallocate \a array. If \a type == ParaMEDMEM::CPP_DEALLOC,
6947 * \c delete [] \c array; will be called. If \a type == ParaMEDMEM::C_DEALLOC,
6948 * \c free(\c array ) will be called.
6949 * \param [in] nbOfTuple - new number of tuples in \a this.
6950 * \param [in] nbOfCompo - new number of components in \a this.
6952 void DataArrayInt::useArray(const int *array, bool ownership, DeallocType type, int nbOfTuple, int nbOfCompo)
6954 _info_on_compo.resize(nbOfCompo);
6955 _mem.useArray(array,ownership,type,nbOfTuple*nbOfCompo);
6959 void DataArrayInt::useExternalArrayWithRWAccess(const int *array, int nbOfTuple, int nbOfCompo)
6961 _info_on_compo.resize(nbOfCompo);
6962 _mem.useExternalArrayWithRWAccess(array,nbOfTuple*nbOfCompo);
6967 * Returns a new DataArrayInt holding the same values as \a this array but differently
6968 * arranged in memory. If \a this array holds 2 components of 3 values:
6969 * \f$ x_0,x_1,x_2,y_0,y_1,y_2 \f$, then the result array holds these values arranged
6970 * as follows: \f$ x_0,y_0,x_1,y_1,x_2,y_2 \f$.
6971 * \warning Do not confuse this method with transpose()!
6972 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
6973 * is to delete using decrRef() as it is no more needed.
6974 * \throw If \a this is not allocated.
6976 DataArrayInt *DataArrayInt::fromNoInterlace() const
6980 throw INTERP_KERNEL::Exception("DataArrayInt::fromNoInterlace : Not defined array !");
6981 int *tab=_mem.fromNoInterlace(getNumberOfComponents());
6982 DataArrayInt *ret=DataArrayInt::New();
6983 ret->useArray(tab,true,C_DEALLOC,getNumberOfTuples(),getNumberOfComponents());
6988 * Returns a new DataArrayInt holding the same values as \a this array but differently
6989 * arranged in memory. If \a this array holds 2 components of 3 values:
6990 * \f$ x_0,y_0,x_1,y_1,x_2,y_2 \f$, then the result array holds these values arranged
6991 * as follows: \f$ x_0,x_1,x_2,y_0,y_1,y_2 \f$.
6992 * \warning Do not confuse this method with transpose()!
6993 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
6994 * is to delete using decrRef() as it is no more needed.
6995 * \throw If \a this is not allocated.
6997 DataArrayInt *DataArrayInt::toNoInterlace() const
7001 throw INTERP_KERNEL::Exception("DataArrayInt::toNoInterlace : Not defined array !");
7002 int *tab=_mem.toNoInterlace(getNumberOfComponents());
7003 DataArrayInt *ret=DataArrayInt::New();
7004 ret->useArray(tab,true,C_DEALLOC,getNumberOfTuples(),getNumberOfComponents());
7009 * Permutes values of \a this array as required by \a old2New array. The values are
7010 * permuted so that \c new[ \a old2New[ i ]] = \c old[ i ]. Number of tuples remains
7011 * the same as in \this one.
7012 * If a permutation reduction is needed, substr() or selectByTupleId() should be used.
7013 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
7014 * \param [in] old2New - C array of length equal to \a this->getNumberOfTuples()
7015 * giving a new position for i-th old value.
7017 void DataArrayInt::renumberInPlace(const int *old2New)
7020 int nbTuples=getNumberOfTuples();
7021 int nbOfCompo=getNumberOfComponents();
7022 int *tmp=new int[nbTuples*nbOfCompo];
7023 const int *iptr=getConstPointer();
7024 for(int i=0;i<nbTuples;i++)
7027 if(v>=0 && v<nbTuples)
7028 std::copy(iptr+nbOfCompo*i,iptr+nbOfCompo*(i+1),tmp+nbOfCompo*v);
7031 std::ostringstream oss; oss << "DataArrayInt::renumberInPlace : At place #" << i << " value is " << v << " ! Should be in [0," << nbTuples << ") !";
7032 throw INTERP_KERNEL::Exception(oss.str().c_str());
7035 std::copy(tmp,tmp+nbTuples*nbOfCompo,getPointer());
7041 * Permutes values of \a this array as required by \a new2Old array. The values are
7042 * permuted so that \c new[ i ] = \c old[ \a new2Old[ i ]]. Number of tuples remains
7043 * the same as in \this one.
7044 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
7045 * \param [in] new2Old - C array of length equal to \a this->getNumberOfTuples()
7046 * giving a previous position of i-th new value.
7047 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
7048 * is to delete using decrRef() as it is no more needed.
7050 void DataArrayInt::renumberInPlaceR(const int *new2Old)
7053 int nbTuples=getNumberOfTuples();
7054 int nbOfCompo=getNumberOfComponents();
7055 int *tmp=new int[nbTuples*nbOfCompo];
7056 const int *iptr=getConstPointer();
7057 for(int i=0;i<nbTuples;i++)
7060 if(v>=0 && v<nbTuples)
7061 std::copy(iptr+nbOfCompo*v,iptr+nbOfCompo*(v+1),tmp+nbOfCompo*i);
7064 std::ostringstream oss; oss << "DataArrayInt::renumberInPlaceR : At place #" << i << " value is " << v << " ! Should be in [0," << nbTuples << ") !";
7065 throw INTERP_KERNEL::Exception(oss.str().c_str());
7068 std::copy(tmp,tmp+nbTuples*nbOfCompo,getPointer());
7074 * Returns a copy of \a this array with values permuted as required by \a old2New array.
7075 * The values are permuted so that \c new[ \a old2New[ i ]] = \c old[ i ].
7076 * Number of tuples in the result array remains the same as in \this one.
7077 * If a permutation reduction is needed, renumberAndReduce() should be used.
7078 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
7079 * \param [in] old2New - C array of length equal to \a this->getNumberOfTuples()
7080 * giving a new position for i-th old value.
7081 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
7082 * is to delete using decrRef() as it is no more needed.
7083 * \throw If \a this is not allocated.
7085 DataArrayInt *DataArrayInt::renumber(const int *old2New) const
7088 int nbTuples=getNumberOfTuples();
7089 int nbOfCompo=getNumberOfComponents();
7090 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7091 ret->alloc(nbTuples,nbOfCompo);
7092 ret->copyStringInfoFrom(*this);
7093 const int *iptr=getConstPointer();
7094 int *optr=ret->getPointer();
7095 for(int i=0;i<nbTuples;i++)
7096 std::copy(iptr+nbOfCompo*i,iptr+nbOfCompo*(i+1),optr+nbOfCompo*old2New[i]);
7097 ret->copyStringInfoFrom(*this);
7102 * Returns a copy of \a this array with values permuted as required by \a new2Old array.
7103 * The values are permuted so that \c new[ i ] = \c old[ \a new2Old[ i ]]. Number of
7104 * tuples in the result array remains the same as in \this one.
7105 * If a permutation reduction is needed, substr() or selectByTupleId() should be used.
7106 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
7107 * \param [in] new2Old - C array of length equal to \a this->getNumberOfTuples()
7108 * giving a previous position of i-th new value.
7109 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
7110 * is to delete using decrRef() as it is no more needed.
7112 DataArrayInt *DataArrayInt::renumberR(const int *new2Old) const
7115 int nbTuples=getNumberOfTuples();
7116 int nbOfCompo=getNumberOfComponents();
7117 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7118 ret->alloc(nbTuples,nbOfCompo);
7119 ret->copyStringInfoFrom(*this);
7120 const int *iptr=getConstPointer();
7121 int *optr=ret->getPointer();
7122 for(int i=0;i<nbTuples;i++)
7123 std::copy(iptr+nbOfCompo*new2Old[i],iptr+nbOfCompo*(new2Old[i]+1),optr+nbOfCompo*i);
7124 ret->copyStringInfoFrom(*this);
7129 * Returns a shorten and permuted copy of \a this array. The new DataArrayInt is
7130 * of size \a newNbOfTuple and it's values are permuted as required by \a old2New array.
7131 * The values are permuted so that \c new[ \a old2New[ i ]] = \c old[ i ] for all
7132 * \a old2New[ i ] >= 0. In other words every i-th tuple in \a this array, for which
7133 * \a old2New[ i ] is negative, is missing from the result array.
7134 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
7135 * \param [in] old2New - C array of length equal to \a this->getNumberOfTuples()
7136 * giving a new position for i-th old tuple and giving negative position for
7137 * for i-th old tuple that should be omitted.
7138 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
7139 * is to delete using decrRef() as it is no more needed.
7141 DataArrayInt *DataArrayInt::renumberAndReduce(const int *old2New, int newNbOfTuple) const
7144 int nbTuples=getNumberOfTuples();
7145 int nbOfCompo=getNumberOfComponents();
7146 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7147 ret->alloc(newNbOfTuple,nbOfCompo);
7148 const int *iptr=getConstPointer();
7149 int *optr=ret->getPointer();
7150 for(int i=0;i<nbTuples;i++)
7154 std::copy(iptr+i*nbOfCompo,iptr+(i+1)*nbOfCompo,optr+w*nbOfCompo);
7156 ret->copyStringInfoFrom(*this);
7161 * Returns a shorten and permuted copy of \a this array. The new DataArrayInt is
7162 * of size \a new2OldEnd - \a new2OldBg and it's values are permuted as required by
7163 * \a new2OldBg array.
7164 * The values are permuted so that \c new[ i ] = \c old[ \a new2OldBg[ i ]].
7165 * This method is equivalent to renumberAndReduce() except that convention in input is
7166 * \c new2old and \b not \c old2new.
7167 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
7168 * \param [in] new2OldBg - pointer to the beginning of a permutation array that gives a
7169 * tuple index in \a this array to fill the i-th tuple in the new array.
7170 * \param [in] new2OldEnd - specifies the end of the permutation array that starts at
7171 * \a new2OldBg, so that pointer to a tuple index (\a pi) varies as this:
7172 * \a new2OldBg <= \a pi < \a new2OldEnd.
7173 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
7174 * is to delete using decrRef() as it is no more needed.
7176 DataArrayInt *DataArrayInt::selectByTupleId(const int *new2OldBg, const int *new2OldEnd) const
7179 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7180 int nbComp=getNumberOfComponents();
7181 ret->alloc((int)std::distance(new2OldBg,new2OldEnd),nbComp);
7182 ret->copyStringInfoFrom(*this);
7183 int *pt=ret->getPointer();
7184 const int *srcPt=getConstPointer();
7186 for(const int *w=new2OldBg;w!=new2OldEnd;w++,i++)
7187 std::copy(srcPt+(*w)*nbComp,srcPt+((*w)+1)*nbComp,pt+i*nbComp);
7188 ret->copyStringInfoFrom(*this);
7193 * Returns a shorten and permuted copy of \a this array. The new DataArrayInt is
7194 * of size \a new2OldEnd - \a new2OldBg and it's values are permuted as required by
7195 * \a new2OldBg array.
7196 * The values are permuted so that \c new[ i ] = \c old[ \a new2OldBg[ i ]].
7197 * This method is equivalent to renumberAndReduce() except that convention in input is
7198 * \c new2old and \b not \c old2new.
7199 * This method is equivalent to selectByTupleId() except that it prevents coping data
7200 * from behind the end of \a this array.
7201 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
7202 * \param [in] new2OldBg - pointer to the beginning of a permutation array that gives a
7203 * tuple index in \a this array to fill the i-th tuple in the new array.
7204 * \param [in] new2OldEnd - specifies the end of the permutation array that starts at
7205 * \a new2OldBg, so that pointer to a tuple index (\a pi) varies as this:
7206 * \a new2OldBg <= \a pi < \a new2OldEnd.
7207 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
7208 * is to delete using decrRef() as it is no more needed.
7209 * \throw If \a new2OldEnd - \a new2OldBg > \a this->getNumberOfTuples().
7211 DataArrayInt *DataArrayInt::selectByTupleIdSafe(const int *new2OldBg, const int *new2OldEnd) const
7214 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7215 int nbComp=getNumberOfComponents();
7216 int oldNbOfTuples=getNumberOfTuples();
7217 ret->alloc((int)std::distance(new2OldBg,new2OldEnd),nbComp);
7218 ret->copyStringInfoFrom(*this);
7219 int *pt=ret->getPointer();
7220 const int *srcPt=getConstPointer();
7222 for(const int *w=new2OldBg;w!=new2OldEnd;w++,i++)
7223 if(*w>=0 && *w<oldNbOfTuples)
7224 std::copy(srcPt+(*w)*nbComp,srcPt+((*w)+1)*nbComp,pt+i*nbComp);
7226 throw INTERP_KERNEL::Exception("DataArrayInt::selectByTupleIdSafe : some ids has been detected to be out of [0,this->getNumberOfTuples) !");
7227 ret->copyStringInfoFrom(*this);
7232 * Returns a shorten copy of \a this array. The new DataArrayInt contains every
7233 * (\a bg + \c i * \a step)-th tuple of \a this array located before the \a end2-th
7234 * tuple. Indices of the selected tuples are the same as ones returned by the Python
7235 * command \c range( \a bg, \a end2, \a step ).
7236 * This method is equivalent to selectByTupleIdSafe() except that the input array is
7237 * not constructed explicitly.
7238 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
7239 * \param [in] bg - index of the first tuple to copy from \a this array.
7240 * \param [in] end2 - index of the tuple before which the tuples to copy are located.
7241 * \param [in] step - index increment to get index of the next tuple to copy.
7242 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
7243 * is to delete using decrRef() as it is no more needed.
7244 * \sa DataArrayInt::substr.
7246 DataArrayInt *DataArrayInt::selectByTupleId2(int bg, int end2, int step) const
7249 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7250 int nbComp=getNumberOfComponents();
7251 int newNbOfTuples=GetNumberOfItemGivenBESRelative(bg,end2,step,"DataArrayInt::selectByTupleId2 : ");
7252 ret->alloc(newNbOfTuples,nbComp);
7253 int *pt=ret->getPointer();
7254 const int *srcPt=getConstPointer()+bg*nbComp;
7255 for(int i=0;i<newNbOfTuples;i++,srcPt+=step*nbComp)
7256 std::copy(srcPt,srcPt+nbComp,pt+i*nbComp);
7257 ret->copyStringInfoFrom(*this);
7262 * Returns a shorten copy of \a this array. The new DataArrayInt contains ranges
7263 * of tuples specified by \a ranges parameter.
7264 * For more info on renumbering see \ref MEDCouplingArrayRenumbering.
7265 * \param [in] ranges - std::vector of std::pair's each of which defines a range
7266 * of tuples in [\c begin,\c end) format.
7267 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
7268 * is to delete using decrRef() as it is no more needed.
7269 * \throw If \a end < \a begin.
7270 * \throw If \a end > \a this->getNumberOfTuples().
7271 * \throw If \a this is not allocated.
7273 DataArray *DataArrayInt::selectByTupleRanges(const std::vector<std::pair<int,int> >& ranges) const
7276 int nbOfComp=getNumberOfComponents();
7277 int nbOfTuplesThis=getNumberOfTuples();
7280 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7281 ret->alloc(0,nbOfComp);
7282 ret->copyStringInfoFrom(*this);
7285 int ref=ranges.front().first;
7287 bool isIncreasing=true;
7288 for(std::vector<std::pair<int,int> >::const_iterator it=ranges.begin();it!=ranges.end();it++)
7290 if((*it).first<=(*it).second)
7292 if((*it).first>=0 && (*it).second<=nbOfTuplesThis)
7294 nbOfTuples+=(*it).second-(*it).first;
7296 isIncreasing=ref<=(*it).first;
7301 std::ostringstream oss; oss << "DataArrayInt::selectByTupleRanges : on range #" << std::distance(ranges.begin(),it);
7302 oss << " (" << (*it).first << "," << (*it).second << ") is greater than number of tuples of this :" << nbOfTuples << " !";
7303 throw INTERP_KERNEL::Exception(oss.str().c_str());
7308 std::ostringstream oss; oss << "DataArrayInt::selectByTupleRanges : on range #" << std::distance(ranges.begin(),it);
7309 oss << " (" << (*it).first << "," << (*it).second << ") end is before begin !";
7310 throw INTERP_KERNEL::Exception(oss.str().c_str());
7313 if(isIncreasing && nbOfTuplesThis==nbOfTuples)
7315 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7316 ret->alloc(nbOfTuples,nbOfComp);
7317 ret->copyStringInfoFrom(*this);
7318 const int *src=getConstPointer();
7319 int *work=ret->getPointer();
7320 for(std::vector<std::pair<int,int> >::const_iterator it=ranges.begin();it!=ranges.end();it++)
7321 work=std::copy(src+(*it).first*nbOfComp,src+(*it).second*nbOfComp,work);
7326 * Returns a new DataArrayInt containing a renumbering map in "Old to New" mode.
7327 * This map, if applied to \a this array, would make it sorted. For example, if
7328 * \a this array contents are [9,10,0,6,4,11,3,7] then the contents of the result array
7329 * are [5,6,0,3,2,7,1,4]; if this result array (\a res) is used as an argument in call
7330 * \a this->renumber(\a res) then the returned array contains [0,3,4,6,7,9,10,11].
7331 * This method is useful for renumbering (in MED file for example). For more info
7332 * on renumbering see \ref MEDCouplingArrayRenumbering.
7333 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
7334 * array using decrRef() as it is no more needed.
7335 * \throw If \a this is not allocated.
7336 * \throw If \a this->getNumberOfComponents() != 1.
7337 * \throw If there are equal values in \a this array.
7339 DataArrayInt *DataArrayInt::checkAndPreparePermutation() const
7342 if(getNumberOfComponents()!=1)
7343 throw INTERP_KERNEL::Exception("DataArrayInt::checkAndPreparePermutation : number of components must == 1 !");
7344 int nbTuples=getNumberOfTuples();
7345 const int *pt=getConstPointer();
7346 int *pt2=CheckAndPreparePermutation(pt,pt+nbTuples);
7347 DataArrayInt *ret=DataArrayInt::New();
7348 ret->useArray(pt2,true,C_DEALLOC,nbTuples,1);
7353 * This method tries to find the permutation to apply to the first input \a ids1 to obtain the same array (without considering strings informations) the second
7354 * input array \a ids2.
7355 * \a ids1 and \a ids2 are expected to be both a list of ids (both with number of components equal to one) not sorted and with values that can be negative.
7356 * This method will throw an exception is no such permutation array can be obtained. It is typically the case if there is some ids in \a ids1 not in \a ids2 or
7358 * In case of success (no throw) : \c ids1->renumber(ret)->isEqual(ids2) where \a ret is the return of this method.
7360 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
7361 * array using decrRef() as it is no more needed.
7362 * \throw If either ids1 or ids2 is null not allocated or not with one components.
7365 DataArrayInt *DataArrayInt::FindPermutationFromFirstToSecond(const DataArrayInt *ids1, const DataArrayInt *ids2)
7368 throw INTERP_KERNEL::Exception("DataArrayInt::FindPermutationFromFirstToSecond : the two input arrays must be not null !");
7369 if(!ids1->isAllocated() || !ids2->isAllocated())
7370 throw INTERP_KERNEL::Exception("DataArrayInt::FindPermutationFromFirstToSecond : the two input arrays must be allocated !");
7371 if(ids1->getNumberOfComponents()!=1 || ids2->getNumberOfComponents()!=1)
7372 throw INTERP_KERNEL::Exception("DataArrayInt::FindPermutationFromFirstToSecond : the two input arrays have exactly one component !");
7373 if(ids1->getNumberOfTuples()!=ids2->getNumberOfTuples())
7375 std::ostringstream oss; oss << "DataArrayInt::FindPermutationFromFirstToSecond : first array has " << ids1->getNumberOfTuples() << " tuples and the second one " << ids2->getNumberOfTuples() << " tuples ! No chance to find a permutation between the 2 arrays !";
7376 throw INTERP_KERNEL::Exception(oss.str().c_str());
7378 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> p1(ids1->deepCpy());
7379 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> p2(ids2->deepCpy());
7380 p1->sort(true); p2->sort(true);
7381 if(!p1->isEqualWithoutConsideringStr(*p2))
7382 throw INTERP_KERNEL::Exception("DataArrayInt::FindPermutationFromFirstToSecond : the two arrays are not lying on same ids ! Impossible to find a permutation between the 2 arrays !");
7383 p1=ids1->checkAndPreparePermutation();
7384 p2=ids2->checkAndPreparePermutation();
7385 p2=p2->invertArrayO2N2N2O(p2->getNumberOfTuples());
7386 p2=p2->selectByTupleIdSafe(p1->begin(),p1->end());
7391 * Returns two arrays describing a surjective mapping from \a this set of values (\a A)
7392 * onto a set of values of size \a targetNb (\a B). The surjective function is
7393 * \a B[ \a A[ i ]] = i. That is to say that for each \a id in [0,\a targetNb), where \a
7394 * targetNb < \a this->getNumberOfTuples(), there exists at least one tupleId (\a tid) so
7395 * that <em> this->getIJ( tid, 0 ) == id</em>. <br>
7396 * The first of out arrays returns indices of elements of \a this array, grouped by their
7397 * place in the set \a B. The second out array is the index of the first one; it shows how
7398 * many elements of \a A are mapped into each element of \a B. <br>
7400 * mapping and its usage in renumbering see \ref MEDCouplingArrayRenumbering. <br>
7402 * - \a this: [0,3,2,3,2,2,1,2]
7404 * - \a arr: [0, 6, 2,4,5,7, 1,3]
7405 * - \a arrI: [0,1,2,6,8]
7407 * This result means: <br>
7408 * the element of \a B 0 encounters within \a A once (\a arrI[ 0+1 ] - \a arrI[ 0 ]) and
7409 * its index within \a A is 0 ( \a arr[ 0:1 ] == \a arr[ \a arrI[ 0 ] : \a arrI[ 0+1 ]]);<br>
7410 * the element of \a B 2 encounters within \a A 4 times (\a arrI[ 2+1 ] - \a arrI[ 2 ]) and
7411 * its indices within \a A are [2,4,5,7] ( \a arr[ 2:6 ] == \a arr[ \a arrI[ 2 ] :
7412 * \a arrI[ 2+1 ]]); <br> etc.
7413 * \param [in] targetNb - the size of the set \a B. \a targetNb must be equal or more
7414 * than the maximal value of \a A.
7415 * \param [out] arr - a new instance of DataArrayInt returning indices of
7416 * elements of \a this, grouped by their place in the set \a B. The caller is to delete
7417 * this array using decrRef() as it is no more needed.
7418 * \param [out] arrI - a new instance of DataArrayInt returning size of groups of equal
7419 * elements of \a this. The caller is to delete this array using decrRef() as it
7420 * is no more needed.
7421 * \throw If \a this is not allocated.
7422 * \throw If \a this->getNumberOfComponents() != 1.
7423 * \throw If any value in \a this is more or equal to \a targetNb.
7425 void DataArrayInt::changeSurjectiveFormat(int targetNb, DataArrayInt *&arr, DataArrayInt *&arrI) const
7428 if(getNumberOfComponents()!=1)
7429 throw INTERP_KERNEL::Exception("DataArrayInt::changeSurjectiveFormat : number of components must == 1 !");
7430 int nbOfTuples=getNumberOfTuples();
7431 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New());
7432 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> retI(DataArrayInt::New());
7433 retI->alloc(targetNb+1,1);
7434 const int *input=getConstPointer();
7435 std::vector< std::vector<int> > tmp(targetNb);
7436 for(int i=0;i<nbOfTuples;i++)
7439 if(tmp2>=0 && tmp2<targetNb)
7440 tmp[tmp2].push_back(i);
7443 std::ostringstream oss; oss << "DataArrayInt::changeSurjectiveFormat : At pos " << i << " presence of element " << tmp2 << " ! should be in [0," << targetNb << ") !";
7444 throw INTERP_KERNEL::Exception(oss.str().c_str());
7447 int *retIPtr=retI->getPointer();
7449 for(std::vector< std::vector<int> >::const_iterator it1=tmp.begin();it1!=tmp.end();it1++,retIPtr++)
7450 retIPtr[1]=retIPtr[0]+(int)((*it1).size());
7451 if(nbOfTuples!=retI->getIJ(targetNb,0))
7452 throw INTERP_KERNEL::Exception("DataArrayInt::changeSurjectiveFormat : big problem should never happen !");
7453 ret->alloc(nbOfTuples,1);
7454 int *retPtr=ret->getPointer();
7455 for(std::vector< std::vector<int> >::const_iterator it1=tmp.begin();it1!=tmp.end();it1++)
7456 retPtr=std::copy((*it1).begin(),(*it1).end(),retPtr);
7463 * Returns a new DataArrayInt containing a renumbering map in "Old to New" mode computed
7464 * from a zip representation of a surjective format (returned e.g. by
7465 * \ref ParaMEDMEM::DataArrayDouble::findCommonTuples() "DataArrayDouble::findCommonTuples()"
7466 * for example). The result array minimizes the permutation. <br>
7467 * For more info on renumbering see \ref MEDCouplingArrayRenumbering. <br>
7469 * - \a nbOfOldTuples: 10
7470 * - \a arr : [0,3, 5,7,9]
7471 * - \a arrIBg : [0,2,5]
7472 * - \a newNbOfTuples: 7
7473 * - result array : [0,1,2,0,3,4,5,4,6,4]
7475 * \param [in] nbOfOldTuples - number of tuples in the initial array \a arr.
7476 * \param [in] arr - the array of tuple indices grouped by \a arrIBg array.
7477 * \param [in] arrIBg - the array dividing all indices stored in \a arr into groups of
7478 * (indices of) equal values. Its every element (except the last one) points to
7479 * the first element of a group of equal values.
7480 * \param [in] arrIEnd - specifies the end of \a arrIBg, so that the last element of \a
7481 * arrIBg is \a arrIEnd[ -1 ].
7482 * \param [out] newNbOfTuples - number of tuples after surjection application.
7483 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
7484 * array using decrRef() as it is no more needed.
7485 * \throw If any value of \a arr breaks condition ( 0 <= \a arr[ i ] < \a nbOfOldTuples ).
7487 DataArrayInt *DataArrayInt::BuildOld2NewArrayFromSurjectiveFormat2(int nbOfOldTuples, const int *arr, const int *arrIBg, const int *arrIEnd, int &newNbOfTuples)
7489 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7490 ret->alloc(nbOfOldTuples,1);
7491 int *pt=ret->getPointer();
7492 std::fill(pt,pt+nbOfOldTuples,-1);
7493 int nbOfGrps=((int)std::distance(arrIBg,arrIEnd))-1;
7494 const int *cIPtr=arrIBg;
7495 for(int i=0;i<nbOfGrps;i++)
7496 pt[arr[cIPtr[i]]]=-(i+2);
7498 for(int iNode=0;iNode<nbOfOldTuples;iNode++)
7506 int grpId=-(pt[iNode]+2);
7507 for(int j=cIPtr[grpId];j<cIPtr[grpId+1];j++)
7509 if(arr[j]>=0 && arr[j]<nbOfOldTuples)
7513 std::ostringstream oss; oss << "DataArrayInt::BuildOld2NewArrayFromSurjectiveFormat2 : With element #" << j << " value is " << arr[j] << " should be in [0," << nbOfOldTuples << ") !";
7514 throw INTERP_KERNEL::Exception(oss.str().c_str());
7521 newNbOfTuples=newNb;
7526 * Returns a new DataArrayInt containing a renumbering map in "New to Old" mode,
7527 * which if applied to \a this array would make it sorted ascendingly.
7528 * For more info on renumbering see \ref MEDCouplingArrayRenumbering. <br>
7530 * - \a this: [2,0,1,1,0,1,2,0,1,1,0,0]
7531 * - result: [10,0,5,6,1,7,11,2,8,9,3,4]
7532 * - after applying result to \a this: [0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 2, 2]
7534 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
7535 * array using decrRef() as it is no more needed.
7536 * \throw If \a this is not allocated.
7537 * \throw If \a this->getNumberOfComponents() != 1.
7539 DataArrayInt *DataArrayInt::buildPermArrPerLevel() const
7542 if(getNumberOfComponents()!=1)
7543 throw INTERP_KERNEL::Exception("DataArrayInt::buildPermArrPerLevel : number of components must == 1 !");
7544 int nbOfTuples=getNumberOfTuples();
7545 const int *pt=getConstPointer();
7546 std::map<int,int> m;
7547 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7548 ret->alloc(nbOfTuples,1);
7549 int *opt=ret->getPointer();
7550 for(int i=0;i<nbOfTuples;i++,pt++,opt++)
7553 std::map<int,int>::iterator it=m.find(val);
7562 m.insert(std::pair<int,int>(val,1));
7566 for(std::map<int,int>::iterator it=m.begin();it!=m.end();it++)
7568 int vt=(*it).second;
7572 pt=getConstPointer();
7573 opt=ret->getPointer();
7574 for(int i=0;i<nbOfTuples;i++,pt++,opt++)
7581 * Checks if contents of \a this array are equal to that of an array filled with
7582 * iota(). This method is particularly useful for DataArrayInt instances that represent
7583 * a renumbering array to check the real need in renumbering.
7584 * \return bool - \a true if \a this array contents == \a range( \a this->getNumberOfTuples())
7585 * \throw If \a this is not allocated.
7586 * \throw If \a this->getNumberOfComponents() != 1.
7588 bool DataArrayInt::isIdentity() const
7591 if(getNumberOfComponents()!=1)
7593 int nbOfTuples=getNumberOfTuples();
7594 const int *pt=getConstPointer();
7595 for(int i=0;i<nbOfTuples;i++,pt++)
7602 * Checks if all values in \a this array are equal to \a val.
7603 * \param [in] val - value to check equality of array values to.
7604 * \return bool - \a true if all values are \a val.
7605 * \throw If \a this is not allocated.
7606 * \throw If \a this->getNumberOfComponents() != 1
7608 bool DataArrayInt::isUniform(int val) const
7611 if(getNumberOfComponents()!=1)
7612 throw INTERP_KERNEL::Exception("DataArrayInt::isUniform : must be applied on DataArrayInt with only one component, you can call 'rearrange' method before !");
7613 int nbOfTuples=getNumberOfTuples();
7614 const int *w=getConstPointer();
7615 const int *end2=w+nbOfTuples;
7623 * Creates a new DataArrayDouble and assigns all (textual and numerical) data of \a this
7624 * array to the new one.
7625 * \return DataArrayDouble * - the new instance of DataArrayInt.
7627 DataArrayDouble *DataArrayInt::convertToDblArr() const
7630 DataArrayDouble *ret=DataArrayDouble::New();
7631 ret->alloc(getNumberOfTuples(),getNumberOfComponents());
7632 std::size_t nbOfVals=getNbOfElems();
7633 const int *src=getConstPointer();
7634 double *dest=ret->getPointer();
7635 std::copy(src,src+nbOfVals,dest);
7636 ret->copyStringInfoFrom(*this);
7641 * Returns a shorten copy of \a this array. The new DataArrayInt contains all
7642 * tuples starting from the \a tupleIdBg-th tuple and including all tuples located before
7643 * the \a tupleIdEnd-th one. This methods has a similar behavior as std::string::substr().
7644 * This method is a specialization of selectByTupleId2().
7645 * \param [in] tupleIdBg - index of the first tuple to copy from \a this array.
7646 * \param [in] tupleIdEnd - index of the tuple before which the tuples to copy are located.
7647 * If \a tupleIdEnd == -1, all the tuples till the end of \a this array are copied.
7648 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
7649 * is to delete using decrRef() as it is no more needed.
7650 * \throw If \a tupleIdBg < 0.
7651 * \throw If \a tupleIdBg > \a this->getNumberOfTuples().
7652 \throw If \a tupleIdEnd != -1 && \a tupleIdEnd < \a this->getNumberOfTuples().
7653 * \sa DataArrayInt::selectByTupleId2
7655 DataArrayInt *DataArrayInt::substr(int tupleIdBg, int tupleIdEnd) const
7658 int nbt=getNumberOfTuples();
7660 throw INTERP_KERNEL::Exception("DataArrayInt::substr : The tupleIdBg parameter must be greater than 0 !");
7662 throw INTERP_KERNEL::Exception("DataArrayInt::substr : The tupleIdBg parameter is greater than number of tuples !");
7663 int trueEnd=tupleIdEnd;
7667 throw INTERP_KERNEL::Exception("DataArrayInt::substr : The tupleIdBg parameter is greater or equal than number of tuples !");
7671 int nbComp=getNumberOfComponents();
7672 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7673 ret->alloc(trueEnd-tupleIdBg,nbComp);
7674 ret->copyStringInfoFrom(*this);
7675 std::copy(getConstPointer()+tupleIdBg*nbComp,getConstPointer()+trueEnd*nbComp,ret->getPointer());
7680 * Changes the number of components within \a this array so that its raw data **does
7681 * not** change, instead splitting this data into tuples changes.
7682 * \warning This method erases all (name and unit) component info set before!
7683 * \param [in] newNbOfComp - number of components for \a this array to have.
7684 * \throw If \a this is not allocated
7685 * \throw If getNbOfElems() % \a newNbOfCompo != 0.
7686 * \throw If \a newNbOfCompo is lower than 1.
7687 * \throw If the rearrange method would lead to a number of tuples higher than 2147483647 (maximal capacity of int32 !).
7688 * \warning This method erases all (name and unit) component info set before!
7690 void DataArrayInt::rearrange(int newNbOfCompo)
7694 throw INTERP_KERNEL::Exception("DataArrayInt::rearrange : input newNbOfCompo must be > 0 !");
7695 std::size_t nbOfElems=getNbOfElems();
7696 if(nbOfElems%newNbOfCompo!=0)
7697 throw INTERP_KERNEL::Exception("DataArrayInt::rearrange : nbOfElems%newNbOfCompo!=0 !");
7698 if(nbOfElems/newNbOfCompo>(std::size_t)std::numeric_limits<int>::max())
7699 throw INTERP_KERNEL::Exception("DataArrayInt::rearrange : the rearrangement leads to too high number of tuples (> 2147483647) !");
7700 _info_on_compo.clear();
7701 _info_on_compo.resize(newNbOfCompo);
7706 * Changes the number of components within \a this array to be equal to its number
7707 * of tuples, and inversely its number of tuples to become equal to its number of
7708 * components. So that its raw data **does not** change, instead splitting this
7709 * data into tuples changes.
7710 * \warning This method erases all (name and unit) component info set before!
7711 * \warning Do not confuse this method with fromNoInterlace() and toNoInterlace()!
7712 * \throw If \a this is not allocated.
7715 void DataArrayInt::transpose()
7718 int nbOfTuples=getNumberOfTuples();
7719 rearrange(nbOfTuples);
7723 * Returns a shorten or extended copy of \a this array. If \a newNbOfComp is less
7724 * than \a this->getNumberOfComponents() then the result array is shorten as each tuple
7725 * is truncated to have \a newNbOfComp components, keeping first components. If \a
7726 * newNbOfComp is more than \a this->getNumberOfComponents() then the result array is
7727 * expanded as each tuple is populated with \a dftValue to have \a newNbOfComp
7729 * \param [in] newNbOfComp - number of components for the new array to have.
7730 * \param [in] dftValue - value assigned to new values added to the new array.
7731 * \return DataArrayDouble * - the new instance of DataArrayDouble that the caller
7732 * is to delete using decrRef() as it is no more needed.
7733 * \throw If \a this is not allocated.
7735 DataArrayInt *DataArrayInt::changeNbOfComponents(int newNbOfComp, int dftValue) const
7738 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
7739 ret->alloc(getNumberOfTuples(),newNbOfComp);
7740 const int *oldc=getConstPointer();
7741 int *nc=ret->getPointer();
7742 int nbOfTuples=getNumberOfTuples();
7743 int oldNbOfComp=getNumberOfComponents();
7744 int dim=std::min(oldNbOfComp,newNbOfComp);
7745 for(int i=0;i<nbOfTuples;i++)
7749 nc[newNbOfComp*i+j]=oldc[i*oldNbOfComp+j];
7750 for(;j<newNbOfComp;j++)
7751 nc[newNbOfComp*i+j]=dftValue;
7753 ret->setName(getName());
7754 for(int i=0;i<dim;i++)
7755 ret->setInfoOnComponent(i,getInfoOnComponent(i));
7756 ret->setName(getName());
7761 * Changes number of tuples in the array. If the new number of tuples is smaller
7762 * than the current number the array is truncated, otherwise the array is extended.
7763 * \param [in] nbOfTuples - new number of tuples.
7764 * \throw If \a this is not allocated.
7765 * \throw If \a nbOfTuples is negative.
7767 void DataArrayInt::reAlloc(int nbOfTuples)
7770 throw INTERP_KERNEL::Exception("DataArrayInt::reAlloc : input new number of tuples should be >=0 !");
7772 _mem.reAlloc(getNumberOfComponents()*(std::size_t)nbOfTuples);
7778 * Returns a copy of \a this array composed of selected components.
7779 * The new DataArrayInt has the same number of tuples but includes components
7780 * specified by \a compoIds parameter. So that getNbOfElems() of the result array
7781 * can be either less, same or more than \a this->getNbOfElems().
7782 * \param [in] compoIds - sequence of zero based indices of components to include
7783 * into the new array.
7784 * \return DataArrayInt * - the new instance of DataArrayInt that the caller
7785 * is to delete using decrRef() as it is no more needed.
7786 * \throw If \a this is not allocated.
7787 * \throw If a component index (\a i) is not valid:
7788 * \a i < 0 || \a i >= \a this->getNumberOfComponents().
7790 * \if ENABLE_EXAMPLES
7791 * \ref py_mcdataarrayint_keepselectedcomponents "Here is a Python example".
7794 DataArrayInt *DataArrayInt::keepSelectedComponents(const std::vector<int>& compoIds) const
7797 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New());
7798 int newNbOfCompo=(int)compoIds.size();
7799 int oldNbOfCompo=getNumberOfComponents();
7800 for(std::vector<int>::const_iterator it=compoIds.begin();it!=compoIds.end();it++)
7801 DataArray::CheckValueInRange(oldNbOfCompo,(*it),"keepSelectedComponents invalid requested component");
7802 int nbOfTuples=getNumberOfTuples();
7803 ret->alloc(nbOfTuples,newNbOfCompo);
7804 ret->copyPartOfStringInfoFrom(*this,compoIds);
7805 const int *oldc=getConstPointer();
7806 int *nc=ret->getPointer();
7807 for(int i=0;i<nbOfTuples;i++)
7808 for(int j=0;j<newNbOfCompo;j++,nc++)
7809 *nc=oldc[i*oldNbOfCompo+compoIds[j]];
7814 * Appends components of another array to components of \a this one, tuple by tuple.
7815 * So that the number of tuples of \a this array remains the same and the number of
7816 * components increases.
7817 * \param [in] other - the DataArrayInt to append to \a this one.
7818 * \throw If \a this is not allocated.
7819 * \throw If \a this and \a other arrays have different number of tuples.
7821 * \if ENABLE_EXAMPLES
7822 * \ref cpp_mcdataarrayint_meldwith "Here is a C++ example".
7824 * \ref py_mcdataarrayint_meldwith "Here is a Python example".
7827 void DataArrayInt::meldWith(const DataArrayInt *other)
7830 throw INTERP_KERNEL::Exception("DataArrayInt::meldWith : DataArrayInt pointer in input is NULL !");
7832 other->checkAllocated();
7833 int nbOfTuples=getNumberOfTuples();
7834 if(nbOfTuples!=other->getNumberOfTuples())
7835 throw INTERP_KERNEL::Exception("DataArrayInt::meldWith : mismatch of number of tuples !");
7836 int nbOfComp1=getNumberOfComponents();
7837 int nbOfComp2=other->getNumberOfComponents();
7838 int *newArr=(int *)malloc(nbOfTuples*(nbOfComp1+nbOfComp2)*sizeof(int));
7840 const int *inp1=getConstPointer();
7841 const int *inp2=other->getConstPointer();
7842 for(int i=0;i<nbOfTuples;i++,inp1+=nbOfComp1,inp2+=nbOfComp2)
7844 w=std::copy(inp1,inp1+nbOfComp1,w);
7845 w=std::copy(inp2,inp2+nbOfComp2,w);
7847 useArray(newArr,true,C_DEALLOC,nbOfTuples,nbOfComp1+nbOfComp2);
7848 std::vector<int> compIds(nbOfComp2);
7849 for(int i=0;i<nbOfComp2;i++)
7850 compIds[i]=nbOfComp1+i;
7851 copyPartOfStringInfoFrom2(compIds,*other);
7855 * Copy all components in a specified order from another DataArrayInt.
7856 * The specified components become the first ones in \a this array.
7857 * Both numerical and textual data is copied. The number of tuples in \a this and
7858 * the other array can be different.
7859 * \param [in] a - the array to copy data from.
7860 * \param [in] compoIds - sequence of zero based indices of components, data of which is
7862 * \throw If \a a is NULL.
7863 * \throw If \a compoIds.size() != \a a->getNumberOfComponents().
7864 * \throw If \a compoIds[i] < 0 or \a compoIds[i] > \a this->getNumberOfComponents().
7866 * \if ENABLE_EXAMPLES
7867 * \ref py_mcdataarrayint_setselectedcomponents "Here is a Python example".
7870 void DataArrayInt::setSelectedComponents(const DataArrayInt *a, const std::vector<int>& compoIds)
7873 throw INTERP_KERNEL::Exception("DataArrayInt::setSelectedComponents : input DataArrayInt is NULL !");
7875 a->checkAllocated();
7876 copyPartOfStringInfoFrom2(compoIds,*a);
7877 std::size_t partOfCompoSz=compoIds.size();
7878 int nbOfCompo=getNumberOfComponents();
7879 int nbOfTuples=std::min(getNumberOfTuples(),a->getNumberOfTuples());
7880 const int *ac=a->getConstPointer();
7881 int *nc=getPointer();
7882 for(int i=0;i<nbOfTuples;i++)
7883 for(std::size_t j=0;j<partOfCompoSz;j++,ac++)
7884 nc[nbOfCompo*i+compoIds[j]]=*ac;
7888 * Copy all values from another DataArrayInt into specified tuples and components
7889 * of \a this array. Textual data is not copied.
7890 * The tree parameters defining set of indices of tuples and components are similar to
7891 * the tree parameters of the Python function \c range(\c start,\c stop,\c step).
7892 * \param [in] a - the array to copy values from.
7893 * \param [in] bgTuples - index of the first tuple of \a this array to assign values to.
7894 * \param [in] endTuples - index of the tuple before which the tuples to assign to
7896 * \param [in] stepTuples - index increment to get index of the next tuple to assign to.
7897 * \param [in] bgComp - index of the first component of \a this array to assign values to.
7898 * \param [in] endComp - index of the component before which the components to assign
7900 * \param [in] stepComp - index increment to get index of the next component to assign to.
7901 * \param [in] strictCompoCompare - if \a true (by default), then \a a->getNumberOfComponents()
7902 * must be equal to the number of columns to assign to, else an
7903 * exception is thrown; if \a false, then it is only required that \a
7904 * a->getNbOfElems() equals to number of values to assign to (this condition
7905 * must be respected even if \a strictCompoCompare is \a true). The number of
7906 * values to assign to is given by following Python expression:
7907 * \a nbTargetValues =
7908 * \c len(\c range(\a bgTuples,\a endTuples,\a stepTuples)) *
7909 * \c len(\c range(\a bgComp,\a endComp,\a stepComp)).
7910 * \throw If \a a is NULL.
7911 * \throw If \a a is not allocated.
7912 * \throw If \a this is not allocated.
7913 * \throw If parameters specifying tuples and components to assign to do not give a
7914 * non-empty range of increasing indices.
7915 * \throw If \a a->getNbOfElems() != \a nbTargetValues.
7916 * \throw If \a strictCompoCompare == \a true && \a a->getNumberOfComponents() !=
7917 * \c len(\c range(\a bgComp,\a endComp,\a stepComp)).
7919 * \if ENABLE_EXAMPLES
7920 * \ref py_mcdataarrayint_setpartofvalues1 "Here is a Python example".
7923 void DataArrayInt::setPartOfValues1(const DataArrayInt *a, int bgTuples, int endTuples, int stepTuples, int bgComp, int endComp, int stepComp, bool strictCompoCompare)
7926 throw INTERP_KERNEL::Exception("DataArrayInt::setPartOfValues1 : DataArrayInt pointer in input is NULL !");
7927 const char msg[]="DataArrayInt::setPartOfValues1";
7929 a->checkAllocated();
7930 int newNbOfTuples=DataArray::GetNumberOfItemGivenBES(bgTuples,endTuples,stepTuples,msg);
7931 int newNbOfComp=DataArray::GetNumberOfItemGivenBES(bgComp,endComp,stepComp,msg);
7932 int nbComp=getNumberOfComponents();
7933 int nbOfTuples=getNumberOfTuples();
7934 DataArray::CheckValueInRangeEx(nbOfTuples,bgTuples,endTuples,"invalid tuple value");
7935 DataArray::CheckValueInRangeEx(nbComp,bgComp,endComp,"invalid component value");
7936 bool assignTech=true;
7937 if(a->getNbOfElems()==(std::size_t)newNbOfTuples*newNbOfComp)
7939 if(strictCompoCompare)
7940 a->checkNbOfTuplesAndComp(newNbOfTuples,newNbOfComp,msg);
7944 a->checkNbOfTuplesAndComp(1,newNbOfComp,msg);
7947 int *pt=getPointer()+bgTuples*nbComp+bgComp;
7948 const int *srcPt=a->getConstPointer();
7951 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
7952 for(int j=0;j<newNbOfComp;j++,srcPt++)
7953 pt[j*stepComp]=*srcPt;
7957 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
7959 const int *srcPt2=srcPt;
7960 for(int j=0;j<newNbOfComp;j++,srcPt2++)
7961 pt[j*stepComp]=*srcPt2;
7967 * Assign a given value to values at specified tuples and components of \a this array.
7968 * The tree parameters defining set of indices of tuples and components are similar to
7969 * the tree parameters of the Python function \c range(\c start,\c stop,\c step)..
7970 * \param [in] a - the value to assign.
7971 * \param [in] bgTuples - index of the first tuple of \a this array to assign to.
7972 * \param [in] endTuples - index of the tuple before which the tuples to assign to
7974 * \param [in] stepTuples - index increment to get index of the next tuple to assign to.
7975 * \param [in] bgComp - index of the first component of \a this array to assign to.
7976 * \param [in] endComp - index of the component before which the components to assign
7978 * \param [in] stepComp - index increment to get index of the next component to assign to.
7979 * \throw If \a this is not allocated.
7980 * \throw If parameters specifying tuples and components to assign to, do not give a
7981 * non-empty range of increasing indices or indices are out of a valid range
7984 * \if ENABLE_EXAMPLES
7985 * \ref py_mcdataarrayint_setpartofvaluessimple1 "Here is a Python example".
7988 void DataArrayInt::setPartOfValuesSimple1(int a, int bgTuples, int endTuples, int stepTuples, int bgComp, int endComp, int stepComp)
7990 const char msg[]="DataArrayInt::setPartOfValuesSimple1";
7992 int newNbOfTuples=DataArray::GetNumberOfItemGivenBES(bgTuples,endTuples,stepTuples,msg);
7993 int newNbOfComp=DataArray::GetNumberOfItemGivenBES(bgComp,endComp,stepComp,msg);
7994 int nbComp=getNumberOfComponents();
7995 int nbOfTuples=getNumberOfTuples();
7996 DataArray::CheckValueInRangeEx(nbOfTuples,bgTuples,endTuples,"invalid tuple value");
7997 DataArray::CheckValueInRangeEx(nbComp,bgComp,endComp,"invalid component value");
7998 int *pt=getPointer()+bgTuples*nbComp+bgComp;
7999 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
8000 for(int j=0;j<newNbOfComp;j++)
8006 * Copy all values from another DataArrayInt (\a a) into specified tuples and
8007 * components of \a this array. Textual data is not copied.
8008 * The tuples and components to assign to are defined by C arrays of indices.
8009 * There are two *modes of usage*:
8010 * - If \a a->getNbOfElems() equals to number of values to assign to, then every value
8011 * of \a a is assigned to its own location within \a this array.
8012 * - If \a a includes one tuple, then all values of \a a are assigned to the specified
8013 * components of every specified tuple of \a this array. In this mode it is required
8014 * that \a a->getNumberOfComponents() equals to the number of specified components.
8016 * \param [in] a - the array to copy values from.
8017 * \param [in] bgTuples - pointer to an array of tuple indices of \a this array to
8018 * assign values of \a a to.
8019 * \param [in] endTuples - specifies the end of the array \a bgTuples, so that
8020 * pointer to a tuple index <em>(pi)</em> varies as this:
8021 * \a bgTuples <= \a pi < \a endTuples.
8022 * \param [in] bgComp - pointer to an array of component indices of \a this array to
8023 * assign values of \a a to.
8024 * \param [in] endComp - specifies the end of the array \a bgTuples, so that
8025 * pointer to a component index <em>(pi)</em> varies as this:
8026 * \a bgComp <= \a pi < \a endComp.
8027 * \param [in] strictCompoCompare - this parameter is checked only if the
8028 * *mode of usage* is the first; if it is \a true (default),
8029 * then \a a->getNumberOfComponents() must be equal
8030 * to the number of specified columns, else this is not required.
8031 * \throw If \a a is NULL.
8032 * \throw If \a a is not allocated.
8033 * \throw If \a this is not allocated.
8034 * \throw If any index of tuple/component given by <em>bgTuples / bgComp</em> is
8035 * out of a valid range for \a this array.
8036 * \throw In the first *mode of usage*, if <em>strictCompoCompare == true </em> and
8037 * if <em> a->getNumberOfComponents() != (endComp - bgComp) </em>.
8038 * \throw In the second *mode of usage*, if \a a->getNumberOfTuples() != 1 or
8039 * <em> a->getNumberOfComponents() != (endComp - bgComp)</em>.
8041 * \if ENABLE_EXAMPLES
8042 * \ref py_mcdataarrayint_setpartofvalues2 "Here is a Python example".
8045 void DataArrayInt::setPartOfValues2(const DataArrayInt *a, const int *bgTuples, const int *endTuples, const int *bgComp, const int *endComp, bool strictCompoCompare)
8048 throw INTERP_KERNEL::Exception("DataArrayInt::setPartOfValues2 : DataArrayInt pointer in input is NULL !");
8049 const char msg[]="DataArrayInt::setPartOfValues2";
8051 a->checkAllocated();
8052 int nbComp=getNumberOfComponents();
8053 int nbOfTuples=getNumberOfTuples();
8054 for(const int *z=bgComp;z!=endComp;z++)
8055 DataArray::CheckValueInRange(nbComp,*z,"invalid component id");
8056 int newNbOfTuples=(int)std::distance(bgTuples,endTuples);
8057 int newNbOfComp=(int)std::distance(bgComp,endComp);
8058 bool assignTech=true;
8059 if(a->getNbOfElems()==(std::size_t)newNbOfTuples*newNbOfComp)
8061 if(strictCompoCompare)
8062 a->checkNbOfTuplesAndComp(newNbOfTuples,newNbOfComp,msg);
8066 a->checkNbOfTuplesAndComp(1,newNbOfComp,msg);
8069 int *pt=getPointer();
8070 const int *srcPt=a->getConstPointer();
8073 for(const int *w=bgTuples;w!=endTuples;w++)
8075 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
8076 for(const int *z=bgComp;z!=endComp;z++,srcPt++)
8078 pt[(std::size_t)(*w)*nbComp+(*z)]=*srcPt;
8084 for(const int *w=bgTuples;w!=endTuples;w++)
8086 const int *srcPt2=srcPt;
8087 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
8088 for(const int *z=bgComp;z!=endComp;z++,srcPt2++)
8090 pt[(std::size_t)(*w)*nbComp+(*z)]=*srcPt2;
8097 * Assign a given value to values at specified tuples and components of \a this array.
8098 * The tuples and components to assign to are defined by C arrays of indices.
8099 * \param [in] a - the value to assign.
8100 * \param [in] bgTuples - pointer to an array of tuple indices of \a this array to
8102 * \param [in] endTuples - specifies the end of the array \a bgTuples, so that
8103 * pointer to a tuple index (\a pi) varies as this:
8104 * \a bgTuples <= \a pi < \a endTuples.
8105 * \param [in] bgComp - pointer to an array of component indices of \a this array to
8107 * \param [in] endComp - specifies the end of the array \a bgTuples, so that
8108 * pointer to a component index (\a pi) varies as this:
8109 * \a bgComp <= \a pi < \a endComp.
8110 * \throw If \a this is not allocated.
8111 * \throw If any index of tuple/component given by <em>bgTuples / bgComp</em> is
8112 * out of a valid range for \a this array.
8114 * \if ENABLE_EXAMPLES
8115 * \ref py_mcdataarrayint_setpartofvaluessimple2 "Here is a Python example".
8118 void DataArrayInt::setPartOfValuesSimple2(int a, const int *bgTuples, const int *endTuples, const int *bgComp, const int *endComp)
8121 int nbComp=getNumberOfComponents();
8122 int nbOfTuples=getNumberOfTuples();
8123 for(const int *z=bgComp;z!=endComp;z++)
8124 DataArray::CheckValueInRange(nbComp,*z,"invalid component id");
8125 int *pt=getPointer();
8126 for(const int *w=bgTuples;w!=endTuples;w++)
8127 for(const int *z=bgComp;z!=endComp;z++)
8129 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
8130 pt[(std::size_t)(*w)*nbComp+(*z)]=a;
8135 * Copy all values from another DataArrayInt (\a a) into specified tuples and
8136 * components of \a this array. Textual data is not copied.
8137 * The tuples to assign to are defined by a C array of indices.
8138 * The components to assign to are defined by three values similar to parameters of
8139 * the Python function \c range(\c start,\c stop,\c step).
8140 * There are two *modes of usage*:
8141 * - If \a a->getNbOfElems() equals to number of values to assign to, then every value
8142 * of \a a is assigned to its own location within \a this array.
8143 * - If \a a includes one tuple, then all values of \a a are assigned to the specified
8144 * components of every specified tuple of \a this array. In this mode it is required
8145 * that \a a->getNumberOfComponents() equals to the number of specified components.
8147 * \param [in] a - the array to copy values from.
8148 * \param [in] bgTuples - pointer to an array of tuple indices of \a this array to
8149 * assign values of \a a to.
8150 * \param [in] endTuples - specifies the end of the array \a bgTuples, so that
8151 * pointer to a tuple index <em>(pi)</em> varies as this:
8152 * \a bgTuples <= \a pi < \a endTuples.
8153 * \param [in] bgComp - index of the first component of \a this array to assign to.
8154 * \param [in] endComp - index of the component before which the components to assign
8156 * \param [in] stepComp - index increment to get index of the next component to assign to.
8157 * \param [in] strictCompoCompare - this parameter is checked only in the first
8158 * *mode of usage*; if \a strictCompoCompare is \a true (default),
8159 * then \a a->getNumberOfComponents() must be equal
8160 * to the number of specified columns, else this is not required.
8161 * \throw If \a a is NULL.
8162 * \throw If \a a is not allocated.
8163 * \throw If \a this is not allocated.
8164 * \throw If any index of tuple given by \a bgTuples is out of a valid range for
8166 * \throw In the first *mode of usage*, if <em>strictCompoCompare == true </em> and
8167 * if <em> a->getNumberOfComponents()</em> is unequal to the number of components
8168 * defined by <em>(bgComp,endComp,stepComp)</em>.
8169 * \throw In the second *mode of usage*, if \a a->getNumberOfTuples() != 1 or
8170 * <em> a->getNumberOfComponents()</em> is unequal to the number of components
8171 * defined by <em>(bgComp,endComp,stepComp)</em>.
8172 * \throw If parameters specifying components to assign to, do not give a
8173 * non-empty range of increasing indices or indices are out of a valid range
8176 * \if ENABLE_EXAMPLES
8177 * \ref py_mcdataarrayint_setpartofvalues3 "Here is a Python example".
8180 void DataArrayInt::setPartOfValues3(const DataArrayInt *a, const int *bgTuples, const int *endTuples, int bgComp, int endComp, int stepComp, bool strictCompoCompare)
8183 throw INTERP_KERNEL::Exception("DataArrayInt::setPartOfValues3 : DataArrayInt pointer in input is NULL !");
8184 const char msg[]="DataArrayInt::setPartOfValues3";
8186 a->checkAllocated();
8187 int newNbOfComp=DataArray::GetNumberOfItemGivenBES(bgComp,endComp,stepComp,msg);
8188 int nbComp=getNumberOfComponents();
8189 int nbOfTuples=getNumberOfTuples();
8190 DataArray::CheckValueInRangeEx(nbComp,bgComp,endComp,"invalid component value");
8191 int newNbOfTuples=(int)std::distance(bgTuples,endTuples);
8192 bool assignTech=true;
8193 if(a->getNbOfElems()==(std::size_t)newNbOfTuples*newNbOfComp)
8195 if(strictCompoCompare)
8196 a->checkNbOfTuplesAndComp(newNbOfTuples,newNbOfComp,msg);
8200 a->checkNbOfTuplesAndComp(1,newNbOfComp,msg);
8203 int *pt=getPointer()+bgComp;
8204 const int *srcPt=a->getConstPointer();
8207 for(const int *w=bgTuples;w!=endTuples;w++)
8208 for(int j=0;j<newNbOfComp;j++,srcPt++)
8210 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
8211 pt[(std::size_t)(*w)*nbComp+j*stepComp]=*srcPt;
8216 for(const int *w=bgTuples;w!=endTuples;w++)
8218 const int *srcPt2=srcPt;
8219 for(int j=0;j<newNbOfComp;j++,srcPt2++)
8221 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
8222 pt[(std::size_t)(*w)*nbComp+j*stepComp]=*srcPt2;
8229 * Assign a given value to values at specified tuples and components of \a this array.
8230 * The tuples to assign to are defined by a C array of indices.
8231 * The components to assign to are defined by three values similar to parameters of
8232 * the Python function \c range(\c start,\c stop,\c step).
8233 * \param [in] a - the value to assign.
8234 * \param [in] bgTuples - pointer to an array of tuple indices of \a this array to
8236 * \param [in] endTuples - specifies the end of the array \a bgTuples, so that
8237 * pointer to a tuple index <em>(pi)</em> varies as this:
8238 * \a bgTuples <= \a pi < \a endTuples.
8239 * \param [in] bgComp - index of the first component of \a this array to assign to.
8240 * \param [in] endComp - index of the component before which the components to assign
8242 * \param [in] stepComp - index increment to get index of the next component to assign to.
8243 * \throw If \a this is not allocated.
8244 * \throw If any index of tuple given by \a bgTuples is out of a valid range for
8246 * \throw If parameters specifying components to assign to, do not give a
8247 * non-empty range of increasing indices or indices are out of a valid range
8250 * \if ENABLE_EXAMPLES
8251 * \ref py_mcdataarrayint_setpartofvaluessimple3 "Here is a Python example".
8254 void DataArrayInt::setPartOfValuesSimple3(int a, const int *bgTuples, const int *endTuples, int bgComp, int endComp, int stepComp)
8256 const char msg[]="DataArrayInt::setPartOfValuesSimple3";
8258 int newNbOfComp=DataArray::GetNumberOfItemGivenBES(bgComp,endComp,stepComp,msg);
8259 int nbComp=getNumberOfComponents();
8260 int nbOfTuples=getNumberOfTuples();
8261 DataArray::CheckValueInRangeEx(nbComp,bgComp,endComp,"invalid component value");
8262 int *pt=getPointer()+bgComp;
8263 for(const int *w=bgTuples;w!=endTuples;w++)
8264 for(int j=0;j<newNbOfComp;j++)
8266 DataArray::CheckValueInRange(nbOfTuples,*w,"invalid tuple id");
8267 pt[(std::size_t)(*w)*nbComp+j*stepComp]=a;
8271 void DataArrayInt::setPartOfValues4(const DataArrayInt *a, int bgTuples, int endTuples, int stepTuples, const int *bgComp, const int *endComp, bool strictCompoCompare)
8274 throw INTERP_KERNEL::Exception("DataArrayInt::setPartOfValues4 : input DataArrayInt is NULL !");
8275 const char msg[]="DataArrayInt::setPartOfValues4";
8277 a->checkAllocated();
8278 int newNbOfTuples=DataArray::GetNumberOfItemGivenBES(bgTuples,endTuples,stepTuples,msg);
8279 int newNbOfComp=(int)std::distance(bgComp,endComp);
8280 int nbComp=getNumberOfComponents();
8281 for(const int *z=bgComp;z!=endComp;z++)
8282 DataArray::CheckValueInRange(nbComp,*z,"invalid component id");
8283 int nbOfTuples=getNumberOfTuples();
8284 DataArray::CheckValueInRangeEx(nbOfTuples,bgTuples,endTuples,"invalid tuple value");
8285 bool assignTech=true;
8286 if(a->getNbOfElems()==(std::size_t)newNbOfTuples*newNbOfComp)
8288 if(strictCompoCompare)
8289 a->checkNbOfTuplesAndComp(newNbOfTuples,newNbOfComp,msg);
8293 a->checkNbOfTuplesAndComp(1,newNbOfComp,msg);
8296 const int *srcPt=a->getConstPointer();
8297 int *pt=getPointer()+bgTuples*nbComp;
8300 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
8301 for(const int *z=bgComp;z!=endComp;z++,srcPt++)
8306 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
8308 const int *srcPt2=srcPt;
8309 for(const int *z=bgComp;z!=endComp;z++,srcPt2++)
8315 void DataArrayInt::setPartOfValuesSimple4(int a, int bgTuples, int endTuples, int stepTuples, const int *bgComp, const int *endComp)
8317 const char msg[]="DataArrayInt::setPartOfValuesSimple4";
8319 int newNbOfTuples=DataArray::GetNumberOfItemGivenBES(bgTuples,endTuples,stepTuples,msg);
8320 int nbComp=getNumberOfComponents();
8321 for(const int *z=bgComp;z!=endComp;z++)
8322 DataArray::CheckValueInRange(nbComp,*z,"invalid component id");
8323 int nbOfTuples=getNumberOfTuples();
8324 DataArray::CheckValueInRangeEx(nbOfTuples,bgTuples,endTuples,"invalid tuple value");
8325 int *pt=getPointer()+bgTuples*nbComp;
8326 for(int i=0;i<newNbOfTuples;i++,pt+=stepTuples*nbComp)
8327 for(const int *z=bgComp;z!=endComp;z++)
8332 * Copy some tuples from another DataArrayInt into specified tuples
8333 * of \a this array. Textual data is not copied. Both arrays must have equal number of
8335 * Both the tuples to assign and the tuples to assign to are defined by a DataArrayInt.
8336 * All components of selected tuples are copied.
8337 * \param [in] a - the array to copy values from.
8338 * \param [in] tuplesSelec - the array specifying both source tuples of \a a and
8339 * target tuples of \a this. \a tuplesSelec has two components, and the
8340 * first component specifies index of the source tuple and the second
8341 * one specifies index of the target tuple.
8342 * \throw If \a this is not allocated.
8343 * \throw If \a a is NULL.
8344 * \throw If \a a is not allocated.
8345 * \throw If \a tuplesSelec is NULL.
8346 * \throw If \a tuplesSelec is not allocated.
8347 * \throw If <em>this->getNumberOfComponents() != a->getNumberOfComponents()</em>.
8348 * \throw If \a tuplesSelec->getNumberOfComponents() != 2.
8349 * \throw If any tuple index given by \a tuplesSelec is out of a valid range for
8350 * the corresponding (\a this or \a a) array.
8352 void DataArrayInt::setPartOfValuesAdv(const DataArrayInt *a, const DataArrayInt *tuplesSelec)
8354 if(!a || !tuplesSelec)
8355 throw INTERP_KERNEL::Exception("DataArrayInt::setPartOfValuesAdv : DataArrayInt pointer in input is NULL !");
8357 a->checkAllocated();
8358 tuplesSelec->checkAllocated();
8359 int nbOfComp=getNumberOfComponents();
8360 if(nbOfComp!=a->getNumberOfComponents())
8361 throw INTERP_KERNEL::Exception("DataArrayInt::setPartOfValuesAdv : This and a do not have the same number of components !");
8362 if(tuplesSelec->getNumberOfComponents()!=2)
8363 throw INTERP_KERNEL::Exception("DataArrayInt::setPartOfValuesAdv : Expecting to have a tuple selector DataArrayInt instance with exactly 2 components !");
8364 int thisNt=getNumberOfTuples();
8365 int aNt=a->getNumberOfTuples();
8366 int *valsToSet=getPointer();
8367 const int *valsSrc=a->getConstPointer();
8368 for(const int *tuple=tuplesSelec->begin();tuple!=tuplesSelec->end();tuple+=2)
8370 if(tuple[1]>=0 && tuple[1]<aNt)
8372 if(tuple[0]>=0 && tuple[0]<thisNt)
8373 std::copy(valsSrc+nbOfComp*tuple[1],valsSrc+nbOfComp*(tuple[1]+1),valsToSet+nbOfComp*tuple[0]);
8376 std::ostringstream oss; oss << "DataArrayInt::setPartOfValuesAdv : Tuple #" << std::distance(tuplesSelec->begin(),tuple)/2;
8377 oss << " of 'tuplesSelec' request of tuple id #" << tuple[0] << " in 'this' ! It should be in [0," << thisNt << ") !";
8378 throw INTERP_KERNEL::Exception(oss.str().c_str());
8383 std::ostringstream oss; oss << "DataArrayInt::setPartOfValuesAdv : Tuple #" << std::distance(tuplesSelec->begin(),tuple)/2;
8384 oss << " of 'tuplesSelec' request of tuple id #" << tuple[1] << " in 'a' ! It should be in [0," << aNt << ") !";
8385 throw INTERP_KERNEL::Exception(oss.str().c_str());
8391 * Copy some tuples from another DataArrayInt (\a aBase) into contiguous tuples
8392 * of \a this array. Textual data is not copied. Both arrays must have equal number of
8394 * The tuples to assign to are defined by index of the first tuple, and
8395 * their number is defined by \a tuplesSelec->getNumberOfTuples().
8396 * The tuples to copy are defined by values of a DataArrayInt.
8397 * All components of selected tuples are copied.
8398 * \param [in] tupleIdStart - index of the first tuple of \a this array to assign
8400 * \param [in] aBase - the array to copy values from.
8401 * \param [in] tuplesSelec - the array specifying tuples of \a aBase to copy.
8402 * \throw If \a this is not allocated.
8403 * \throw If \a aBase is NULL.
8404 * \throw If \a aBase is not allocated.
8405 * \throw If \a tuplesSelec is NULL.
8406 * \throw If \a tuplesSelec is not allocated.
8407 * \throw If <em>this->getNumberOfComponents() != a->getNumberOfComponents()</em>.
8408 * \throw If \a tuplesSelec->getNumberOfComponents() != 1.
8409 * \throw If <em>tupleIdStart + tuplesSelec->getNumberOfTuples() > this->getNumberOfTuples().</em>
8410 * \throw If any tuple index given by \a tuplesSelec is out of a valid range for
8413 void DataArrayInt::setContigPartOfSelectedValues(int tupleIdStart, const DataArray *aBase, const DataArrayInt *tuplesSelec)
8415 if(!aBase || !tuplesSelec)
8416 throw INTERP_KERNEL::Exception("DataArrayInt::setContigPartOfSelectedValues : input DataArray is NULL !");
8417 const DataArrayInt *a=dynamic_cast<const DataArrayInt *>(aBase);
8419 throw INTERP_KERNEL::Exception("DataArrayInt::setContigPartOfSelectedValues : input DataArray aBase is not a DataArrayInt !");
8421 a->checkAllocated();
8422 tuplesSelec->checkAllocated();
8423 int nbOfComp=getNumberOfComponents();
8424 if(nbOfComp!=a->getNumberOfComponents())
8425 throw INTERP_KERNEL::Exception("DataArrayInt::setContigPartOfSelectedValues : This and a do not have the same number of components !");
8426 if(tuplesSelec->getNumberOfComponents()!=1)
8427 throw INTERP_KERNEL::Exception("DataArrayInt::setContigPartOfSelectedValues : Expecting to have a tuple selector DataArrayInt instance with exactly 1 component !");
8428 int thisNt=getNumberOfTuples();
8429 int aNt=a->getNumberOfTuples();
8430 int nbOfTupleToWrite=tuplesSelec->getNumberOfTuples();
8431 int *valsToSet=getPointer()+tupleIdStart*nbOfComp;
8432 if(tupleIdStart+nbOfTupleToWrite>thisNt)
8433 throw INTERP_KERNEL::Exception("DataArrayInt::setContigPartOfSelectedValues : invalid number range of values to write !");
8434 const int *valsSrc=a->getConstPointer();
8435 for(const int *tuple=tuplesSelec->begin();tuple!=tuplesSelec->end();tuple++,valsToSet+=nbOfComp)
8437 if(*tuple>=0 && *tuple<aNt)
8439 std::copy(valsSrc+nbOfComp*(*tuple),valsSrc+nbOfComp*(*tuple+1),valsToSet);
8443 std::ostringstream oss; oss << "DataArrayInt::setContigPartOfSelectedValues : Tuple #" << std::distance(tuplesSelec->begin(),tuple);
8444 oss << " of 'tuplesSelec' request of tuple id #" << *tuple << " in 'a' ! It should be in [0," << aNt << ") !";
8445 throw INTERP_KERNEL::Exception(oss.str().c_str());
8451 * Copy some tuples from another DataArrayInt (\a aBase) into contiguous tuples
8452 * of \a this array. Textual data is not copied. Both arrays must have equal number of
8454 * The tuples to copy are defined by three values similar to parameters of
8455 * the Python function \c range(\c start,\c stop,\c step).
8456 * The tuples to assign to are defined by index of the first tuple, and
8457 * their number is defined by number of tuples to copy.
8458 * All components of selected tuples are copied.
8459 * \param [in] tupleIdStart - index of the first tuple of \a this array to assign
8461 * \param [in] aBase - the array to copy values from.
8462 * \param [in] bg - index of the first tuple to copy of the array \a aBase.
8463 * \param [in] end2 - index of the tuple of \a aBase before which the tuples to copy
8465 * \param [in] step - index increment to get index of the next tuple to copy.
8466 * \throw If \a this is not allocated.
8467 * \throw If \a aBase is NULL.
8468 * \throw If \a aBase is not allocated.
8469 * \throw If <em>this->getNumberOfComponents() != aBase->getNumberOfComponents()</em>.
8470 * \throw If <em>tupleIdStart + len(range(bg,end2,step)) > this->getNumberOfTuples().</em>
8471 * \throw If parameters specifying tuples to copy, do not give a
8472 * non-empty range of increasing indices or indices are out of a valid range
8473 * for the array \a aBase.
8475 void DataArrayInt::setContigPartOfSelectedValues2(int tupleIdStart, const DataArray *aBase, int bg, int end2, int step)
8478 throw INTERP_KERNEL::Exception("DataArrayInt::setContigPartOfSelectedValues2 : input DataArray is NULL !");
8479 const DataArrayInt *a=dynamic_cast<const DataArrayInt *>(aBase);
8481 throw INTERP_KERNEL::Exception("DataArrayInt::setContigPartOfSelectedValues2 : input DataArray aBase is not a DataArrayInt !");
8483 a->checkAllocated();
8484 int nbOfComp=getNumberOfComponents();
8485 const char msg[]="DataArrayInt::setContigPartOfSelectedValues2";
8486 int nbOfTupleToWrite=DataArray::GetNumberOfItemGivenBES(bg,end2,step,msg);
8487 if(nbOfComp!=a->getNumberOfComponents())
8488 throw INTERP_KERNEL::Exception("DataArrayInt::setContigPartOfSelectedValues2 : This and a do not have the same number of components !");
8489 int thisNt=getNumberOfTuples();
8490 int aNt=a->getNumberOfTuples();
8491 int *valsToSet=getPointer()+tupleIdStart*nbOfComp;
8492 if(tupleIdStart+nbOfTupleToWrite>thisNt)
8493 throw INTERP_KERNEL::Exception("DataArrayInt::setContigPartOfSelectedValues2 : invalid number range of values to write !");
8495 throw INTERP_KERNEL::Exception("DataArrayInt::setContigPartOfSelectedValues2 : invalid range of values to read !");
8496 const int *valsSrc=a->getConstPointer()+bg*nbOfComp;
8497 for(int i=0;i<nbOfTupleToWrite;i++,valsToSet+=nbOfComp,valsSrc+=step*nbOfComp)
8499 std::copy(valsSrc,valsSrc+nbOfComp,valsToSet);
8504 * Returns a value located at specified tuple and component.
8505 * This method is equivalent to DataArrayInt::getIJ() except that validity of
8506 * parameters is checked. So this method is safe but expensive if used to go through
8507 * all values of \a this.
8508 * \param [in] tupleId - index of tuple of interest.
8509 * \param [in] compoId - index of component of interest.
8510 * \return double - value located by \a tupleId and \a compoId.
8511 * \throw If \a this is not allocated.
8512 * \throw If condition <em>( 0 <= tupleId < this->getNumberOfTuples() )</em> is violated.
8513 * \throw If condition <em>( 0 <= compoId < this->getNumberOfComponents() )</em> is violated.
8515 int DataArrayInt::getIJSafe(int tupleId, int compoId) const
8518 if(tupleId<0 || tupleId>=getNumberOfTuples())
8520 std::ostringstream oss; oss << "DataArrayInt::getIJSafe : request for tupleId " << tupleId << " should be in [0," << getNumberOfTuples() << ") !";
8521 throw INTERP_KERNEL::Exception(oss.str().c_str());
8523 if(compoId<0 || compoId>=getNumberOfComponents())
8525 std::ostringstream oss; oss << "DataArrayInt::getIJSafe : request for compoId " << compoId << " should be in [0," << getNumberOfComponents() << ") !";
8526 throw INTERP_KERNEL::Exception(oss.str().c_str());
8528 return _mem[tupleId*_info_on_compo.size()+compoId];
8532 * Returns the first value of \a this.
8533 * \return int - the last value of \a this array.
8534 * \throw If \a this is not allocated.
8535 * \throw If \a this->getNumberOfComponents() != 1.
8536 * \throw If \a this->getNumberOfTuples() < 1.
8538 int DataArrayInt::front() const
8541 if(getNumberOfComponents()!=1)
8542 throw INTERP_KERNEL::Exception("DataArrayInt::front : number of components not equal to one !");
8543 int nbOfTuples=getNumberOfTuples();
8545 throw INTERP_KERNEL::Exception("DataArrayInt::front : number of tuples must be >= 1 !");
8546 return *(getConstPointer());
8550 * Returns the last value of \a this.
8551 * \return int - the last value of \a this array.
8552 * \throw If \a this is not allocated.
8553 * \throw If \a this->getNumberOfComponents() != 1.
8554 * \throw If \a this->getNumberOfTuples() < 1.
8556 int DataArrayInt::back() const
8559 if(getNumberOfComponents()!=1)
8560 throw INTERP_KERNEL::Exception("DataArrayInt::back : number of components not equal to one !");
8561 int nbOfTuples=getNumberOfTuples();
8563 throw INTERP_KERNEL::Exception("DataArrayInt::back : number of tuples must be >= 1 !");
8564 return *(getConstPointer()+nbOfTuples-1);
8568 * Assign pointer to one array to a pointer to another appay. Reference counter of
8569 * \a arrayToSet is incremented / decremented.
8570 * \param [in] newArray - the pointer to array to assign to \a arrayToSet.
8571 * \param [in,out] arrayToSet - the pointer to array to assign to.
8573 void DataArrayInt::SetArrayIn(DataArrayInt *newArray, DataArrayInt* &arrayToSet)
8575 if(newArray!=arrayToSet)
8578 arrayToSet->decrRef();
8579 arrayToSet=newArray;
8581 arrayToSet->incrRef();
8585 DataArrayIntIterator *DataArrayInt::iterator()
8587 return new DataArrayIntIterator(this);
8591 * Creates a new DataArrayInt containing IDs (indices) of tuples holding value equal to a
8592 * given one. The ids are sorted in the ascending order.
8593 * \param [in] val - the value to find within \a this.
8594 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
8595 * array using decrRef() as it is no more needed.
8596 * \throw If \a this is not allocated.
8597 * \throw If \a this->getNumberOfComponents() != 1.
8598 * \sa DataArrayInt::getIdsEqualTuple
8600 DataArrayInt *DataArrayInt::getIdsEqual(int val) const
8603 if(getNumberOfComponents()!=1)
8604 throw INTERP_KERNEL::Exception("DataArrayInt::getIdsEqual : the array must have only one component, you can call 'rearrange' method before !");
8605 const int *cptr(getConstPointer());
8606 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
8607 int nbOfTuples=getNumberOfTuples();
8608 for(int i=0;i<nbOfTuples;i++,cptr++)
8610 ret->pushBackSilent(i);
8615 * Creates a new DataArrayInt containing IDs (indices) of tuples holding value \b not
8616 * equal to a given one.
8617 * \param [in] val - the value to ignore within \a this.
8618 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
8619 * array using decrRef() as it is no more needed.
8620 * \throw If \a this is not allocated.
8621 * \throw If \a this->getNumberOfComponents() != 1.
8623 DataArrayInt *DataArrayInt::getIdsNotEqual(int val) const
8626 if(getNumberOfComponents()!=1)
8627 throw INTERP_KERNEL::Exception("DataArrayInt::getIdsNotEqual : the array must have only one component, you can call 'rearrange' method before !");
8628 const int *cptr(getConstPointer());
8629 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
8630 int nbOfTuples=getNumberOfTuples();
8631 for(int i=0;i<nbOfTuples;i++,cptr++)
8633 ret->pushBackSilent(i);
8638 * Creates a new DataArrayInt containing IDs (indices) of tuples holding tuple equal to those defined by [ \a tupleBg , \a tupleEnd )
8639 * This method is an extension of DataArrayInt::getIdsEqual method.
8641 * \param [in] tupleBg - the begin (included) of the input tuple to find within \a this.
8642 * \param [in] tupleEnd - the end (excluded) of the input tuple to find within \a this.
8643 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
8644 * array using decrRef() as it is no more needed.
8645 * \throw If \a this is not allocated.
8646 * \throw If \a this->getNumberOfComponents() != std::distance(tupleBg,tupleEnd).
8647 * \throw If \a this->getNumberOfComponents() is equal to 0.
8648 * \sa DataArrayInt::getIdsEqual
8650 DataArrayInt *DataArrayInt::getIdsEqualTuple(const int *tupleBg, const int *tupleEnd) const
8652 std::size_t nbOfCompoExp(std::distance(tupleBg,tupleEnd));
8654 if(getNumberOfComponents()!=(int)nbOfCompoExp)
8656 std::ostringstream oss; oss << "DataArrayInt::getIdsEqualTuple : mismatch of number of components. Input tuple has " << nbOfCompoExp << " whereas this array has " << getNumberOfComponents() << " components !";
8657 throw INTERP_KERNEL::Exception(oss.str().c_str());
8660 throw INTERP_KERNEL::Exception("DataArrayInt::getIdsEqualTuple : number of components should be > 0 !");
8661 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
8662 const int *bg(begin()),*end2(end()),*work(begin());
8665 work=std::search(work,end2,tupleBg,tupleEnd);
8668 std::size_t pos(std::distance(bg,work));
8669 if(pos%nbOfCompoExp==0)
8670 ret->pushBackSilent(pos/nbOfCompoExp);
8678 * Assigns \a newValue to all elements holding \a oldValue within \a this
8679 * one-dimensional array.
8680 * \param [in] oldValue - the value to replace.
8681 * \param [in] newValue - the value to assign.
8682 * \return int - number of replacements performed.
8683 * \throw If \a this is not allocated.
8684 * \throw If \a this->getNumberOfComponents() != 1.
8686 int DataArrayInt::changeValue(int oldValue, int newValue)
8689 if(getNumberOfComponents()!=1)
8690 throw INTERP_KERNEL::Exception("DataArrayInt::changeValue : the array must have only one component, you can call 'rearrange' method before !");
8691 int *start=getPointer();
8692 int *end2=start+getNbOfElems();
8694 for(int *val=start;val!=end2;val++)
8706 * Creates a new DataArrayInt containing IDs (indices) of tuples holding value equal to
8707 * one of given values.
8708 * \param [in] valsBg - an array of values to find within \a this array.
8709 * \param [in] valsEnd - specifies the end of the array \a valsBg, so that
8710 * the last value of \a valsBg is \a valsEnd[ -1 ].
8711 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
8712 * array using decrRef() as it is no more needed.
8713 * \throw If \a this->getNumberOfComponents() != 1.
8715 DataArrayInt *DataArrayInt::getIdsEqualList(const int *valsBg, const int *valsEnd) const
8717 if(getNumberOfComponents()!=1)
8718 throw INTERP_KERNEL::Exception("DataArrayInt::getIdsEqualList : the array must have only one component, you can call 'rearrange' method before !");
8719 std::set<int> vals2(valsBg,valsEnd);
8720 const int *cptr=getConstPointer();
8721 std::vector<int> res;
8722 int nbOfTuples=getNumberOfTuples();
8723 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
8724 for(int i=0;i<nbOfTuples;i++,cptr++)
8725 if(vals2.find(*cptr)!=vals2.end())
8726 ret->pushBackSilent(i);
8731 * Creates a new DataArrayInt containing IDs (indices) of tuples holding values \b not
8732 * equal to any of given values.
8733 * \param [in] valsBg - an array of values to ignore within \a this array.
8734 * \param [in] valsEnd - specifies the end of the array \a valsBg, so that
8735 * the last value of \a valsBg is \a valsEnd[ -1 ].
8736 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
8737 * array using decrRef() as it is no more needed.
8738 * \throw If \a this->getNumberOfComponents() != 1.
8740 DataArrayInt *DataArrayInt::getIdsNotEqualList(const int *valsBg, const int *valsEnd) const
8742 if(getNumberOfComponents()!=1)
8743 throw INTERP_KERNEL::Exception("DataArrayInt::getIdsNotEqualList : the array must have only one component, you can call 'rearrange' method before !");
8744 std::set<int> vals2(valsBg,valsEnd);
8745 const int *cptr=getConstPointer();
8746 std::vector<int> res;
8747 int nbOfTuples=getNumberOfTuples();
8748 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
8749 for(int i=0;i<nbOfTuples;i++,cptr++)
8750 if(vals2.find(*cptr)==vals2.end())
8751 ret->pushBackSilent(i);
8756 * This method is an extension of DataArrayInt::locateValue method because this method works for DataArrayInt with
8757 * any number of components excepted 0 (an INTERP_KERNEL::Exception is thrown in this case).
8758 * This method searches in \b this is there is a tuple that matched the input parameter \b tupl.
8759 * If any the tuple id is returned. If not -1 is returned.
8761 * This method throws an INTERP_KERNEL::Exception if the number of components in \b this mismatches with the size of
8762 * the input vector. An INTERP_KERNEL::Exception is thrown too if \b this is not allocated.
8764 * \return tuple id where \b tupl is. -1 if no such tuple exists in \b this.
8765 * \sa DataArrayInt::search, DataArrayInt::presenceOfTuple.
8767 int DataArrayInt::locateTuple(const std::vector<int>& tupl) const
8770 int nbOfCompo=getNumberOfComponents();
8772 throw INTERP_KERNEL::Exception("DataArrayInt::locateTuple : 0 components in 'this' !");
8773 if(nbOfCompo!=(int)tupl.size())
8775 std::ostringstream oss; oss << "DataArrayInt::locateTuple : 'this' contains " << nbOfCompo << " components and searching for a tuple of length " << tupl.size() << " !";
8776 throw INTERP_KERNEL::Exception(oss.str().c_str());
8778 const int *cptr=getConstPointer();
8779 std::size_t nbOfVals=getNbOfElems();
8780 for(const int *work=cptr;work!=cptr+nbOfVals;)
8782 work=std::search(work,cptr+nbOfVals,tupl.begin(),tupl.end());
8783 if(work!=cptr+nbOfVals)
8785 if(std::distance(cptr,work)%nbOfCompo!=0)
8788 return std::distance(cptr,work)/nbOfCompo;
8795 * This method searches the sequence specified in input parameter \b vals in \b this.
8796 * This works only for DataArrayInt having number of components equal to one (if not an INTERP_KERNEL::Exception will be thrown).
8797 * This method differs from DataArrayInt::locateTuple in that the position is internal raw data is not considered here contrary to DataArrayInt::locateTuple.
8798 * \sa DataArrayInt::locateTuple
8800 int DataArrayInt::search(const std::vector<int>& vals) const
8803 int nbOfCompo=getNumberOfComponents();
8805 throw INTERP_KERNEL::Exception("DataArrayInt::search : works only for DataArrayInt instance with one component !");
8806 const int *cptr=getConstPointer();
8807 std::size_t nbOfVals=getNbOfElems();
8808 const int *loc=std::search(cptr,cptr+nbOfVals,vals.begin(),vals.end());
8809 if(loc!=cptr+nbOfVals)
8810 return std::distance(cptr,loc);
8815 * This method expects to be called when number of components of this is equal to one.
8816 * This method returns the tuple id, if it exists, of the first tuple equal to \b value.
8817 * If not any tuple contains \b value -1 is returned.
8818 * \sa DataArrayInt::presenceOfValue
8820 int DataArrayInt::locateValue(int value) const
8823 if(getNumberOfComponents()!=1)
8824 throw INTERP_KERNEL::Exception("DataArrayInt::presenceOfValue : the array must have only one component, you can call 'rearrange' method before !");
8825 const int *cptr=getConstPointer();
8826 int nbOfTuples=getNumberOfTuples();
8827 const int *ret=std::find(cptr,cptr+nbOfTuples,value);
8828 if(ret!=cptr+nbOfTuples)
8829 return std::distance(cptr,ret);
8834 * This method expects to be called when number of components of this is equal to one.
8835 * This method returns the tuple id, if it exists, of the first tuple so that the value is contained in \b vals.
8836 * If not any tuple contains one of the values contained in 'vals' false is returned.
8837 * \sa DataArrayInt::presenceOfValue
8839 int DataArrayInt::locateValue(const std::vector<int>& vals) const
8842 if(getNumberOfComponents()!=1)
8843 throw INTERP_KERNEL::Exception("DataArrayInt::presenceOfValue : the array must have only one component, you can call 'rearrange' method before !");
8844 std::set<int> vals2(vals.begin(),vals.end());
8845 const int *cptr=getConstPointer();
8846 int nbOfTuples=getNumberOfTuples();
8847 for(const int *w=cptr;w!=cptr+nbOfTuples;w++)
8848 if(vals2.find(*w)!=vals2.end())
8849 return std::distance(cptr,w);
8854 * This method returns the number of values in \a this that are equals to input parameter \a value.
8855 * This method only works for single component array.
8857 * \return a value in [ 0, \c this->getNumberOfTuples() )
8859 * \throw If \a this is not allocated
8862 int DataArrayInt::count(int value) const
8866 if(getNumberOfComponents()!=1)
8867 throw INTERP_KERNEL::Exception("DataArrayInt::count : must be applied on DataArrayInt with only one component, you can call 'rearrange' method before !");
8868 const int *vals=begin();
8869 int nbOfTuples=getNumberOfTuples();
8870 for(int i=0;i<nbOfTuples;i++,vals++)
8877 * This method is an extension of DataArrayInt::presenceOfValue method because this method works for DataArrayInt with
8878 * any number of components excepted 0 (an INTERP_KERNEL::Exception is thrown in this case).
8879 * This method searches in \b this is there is a tuple that matched the input parameter \b tupl.
8880 * This method throws an INTERP_KERNEL::Exception if the number of components in \b this mismatches with the size of
8881 * the input vector. An INTERP_KERNEL::Exception is thrown too if \b this is not allocated.
8882 * \sa DataArrayInt::locateTuple
8884 bool DataArrayInt::presenceOfTuple(const std::vector<int>& tupl) const
8886 return locateTuple(tupl)!=-1;
8891 * Returns \a true if a given value is present within \a this one-dimensional array.
8892 * \param [in] value - the value to find within \a this array.
8893 * \return bool - \a true in case if \a value is present within \a this array.
8894 * \throw If \a this is not allocated.
8895 * \throw If \a this->getNumberOfComponents() != 1.
8898 bool DataArrayInt::presenceOfValue(int value) const
8900 return locateValue(value)!=-1;
8904 * This method expects to be called when number of components of this is equal to one.
8905 * This method returns true if it exists a tuple so that the value is contained in \b vals.
8906 * If not any tuple contains one of the values contained in 'vals' false is returned.
8907 * \sa DataArrayInt::locateValue
8909 bool DataArrayInt::presenceOfValue(const std::vector<int>& vals) const
8911 return locateValue(vals)!=-1;
8915 * Accumulates values of each component of \a this array.
8916 * \param [out] res - an array of length \a this->getNumberOfComponents(), allocated
8917 * by the caller, that is filled by this method with sum value for each
8919 * \throw If \a this is not allocated.
8921 void DataArrayInt::accumulate(int *res) const
8924 const int *ptr=getConstPointer();
8925 int nbTuple=getNumberOfTuples();
8926 int nbComps=getNumberOfComponents();
8927 std::fill(res,res+nbComps,0);
8928 for(int i=0;i<nbTuple;i++)
8929 std::transform(ptr+i*nbComps,ptr+(i+1)*nbComps,res,res,std::plus<int>());
8932 int DataArrayInt::accumulate(int compId) const
8935 const int *ptr=getConstPointer();
8936 int nbTuple=getNumberOfTuples();
8937 int nbComps=getNumberOfComponents();
8938 if(compId<0 || compId>=nbComps)
8939 throw INTERP_KERNEL::Exception("DataArrayInt::accumulate : Invalid compId specified : No such nb of components !");
8941 for(int i=0;i<nbTuple;i++)
8942 ret+=ptr[i*nbComps+compId];
8947 * This method accumulate using addition tuples in \a this using input index array [ \a bgOfIndex, \a endOfIndex ).
8948 * The returned array will have same number of components than \a this and number of tuples equal to
8949 * \c std::distance(bgOfIndex,endOfIndex) \b minus \b one.
8951 * The input index array is expected to be ascendingly sorted in which the all referenced ids should be in [0, \c this->getNumberOfTuples).
8953 * \param [in] bgOfIndex - begin (included) of the input index array.
8954 * \param [in] endOfIndex - end (excluded) of the input index array.
8955 * \return DataArrayInt * - the new instance having the same number of components than \a this.
8957 * \throw If bgOfIndex or end is NULL.
8958 * \throw If input index array is not ascendingly sorted.
8959 * \throw If there is an id in [ \a bgOfIndex, \a endOfIndex ) not in [0, \c this->getNumberOfTuples).
8960 * \throw If std::distance(bgOfIndex,endOfIndex)==0.
8962 DataArrayInt *DataArrayInt::accumulatePerChunck(const int *bgOfIndex, const int *endOfIndex) const
8964 if(!bgOfIndex || !endOfIndex)
8965 throw INTERP_KERNEL::Exception("DataArrayInt::accumulatePerChunck : input pointer NULL !");
8967 int nbCompo=getNumberOfComponents();
8968 int nbOfTuples=getNumberOfTuples();
8969 int sz=(int)std::distance(bgOfIndex,endOfIndex);
8971 throw INTERP_KERNEL::Exception("DataArrayInt::accumulatePerChunck : invalid size of input index array !");
8973 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New(); ret->alloc(sz,nbCompo);
8974 const int *w=bgOfIndex;
8975 if(*w<0 || *w>=nbOfTuples)
8976 throw INTERP_KERNEL::Exception("DataArrayInt::accumulatePerChunck : The first element of the input index not in [0,nbOfTuples) !");
8977 const int *srcPt=begin()+(*w)*nbCompo;
8978 int *tmp=ret->getPointer();
8979 for(int i=0;i<sz;i++,tmp+=nbCompo,w++)
8981 std::fill(tmp,tmp+nbCompo,0);
8984 for(int j=w[0];j<w[1];j++,srcPt+=nbCompo)
8986 if(j>=0 && j<nbOfTuples)
8987 std::transform(srcPt,srcPt+nbCompo,tmp,tmp,std::plus<int>());
8990 std::ostringstream oss; oss << "DataArrayInt::accumulatePerChunck : At rank #" << i << " the input index array points to id " << j << " should be in [0," << nbOfTuples << ") !";
8991 throw INTERP_KERNEL::Exception(oss.str().c_str());
8997 std::ostringstream oss; oss << "DataArrayInt::accumulatePerChunck : At rank #" << i << " the input index array is not in ascendingly sorted.";
8998 throw INTERP_KERNEL::Exception(oss.str().c_str());
9001 ret->copyStringInfoFrom(*this);
9006 * Returns a new DataArrayInt by concatenating two given arrays, so that (1) the number
9007 * of tuples in the result array is <em> a1->getNumberOfTuples() + a2->getNumberOfTuples() -
9008 * offsetA2</em> and (2)
9009 * the number of component in the result array is same as that of each of given arrays.
9010 * First \a offsetA2 tuples of \a a2 are skipped and thus are missing from the result array.
9011 * Info on components is copied from the first of the given arrays. Number of components
9012 * in the given arrays must be the same.
9013 * \param [in] a1 - an array to include in the result array.
9014 * \param [in] a2 - another array to include in the result array.
9015 * \param [in] offsetA2 - number of tuples of \a a2 to skip.
9016 * \return DataArrayInt * - the new instance of DataArrayInt.
9017 * The caller is to delete this result array using decrRef() as it is no more
9019 * \throw If either \a a1 or \a a2 is NULL.
9020 * \throw If \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents().
9022 DataArrayInt *DataArrayInt::Aggregate(const DataArrayInt *a1, const DataArrayInt *a2, int offsetA2)
9025 throw INTERP_KERNEL::Exception("DataArrayInt::Aggregate : input DataArrayInt instance is NULL !");
9026 int nbOfComp=a1->getNumberOfComponents();
9027 if(nbOfComp!=a2->getNumberOfComponents())
9028 throw INTERP_KERNEL::Exception("Nb of components mismatch for array Aggregation !");
9029 int nbOfTuple1=a1->getNumberOfTuples();
9030 int nbOfTuple2=a2->getNumberOfTuples();
9031 DataArrayInt *ret=DataArrayInt::New();
9032 ret->alloc(nbOfTuple1+nbOfTuple2-offsetA2,nbOfComp);
9033 int *pt=std::copy(a1->getConstPointer(),a1->getConstPointer()+nbOfTuple1*nbOfComp,ret->getPointer());
9034 std::copy(a2->getConstPointer()+offsetA2*nbOfComp,a2->getConstPointer()+nbOfTuple2*nbOfComp,pt);
9035 ret->copyStringInfoFrom(*a1);
9040 * Returns a new DataArrayInt by concatenating all given arrays, so that (1) the number
9041 * of tuples in the result array is a sum of the number of tuples of given arrays and (2)
9042 * the number of component in the result array is same as that of each of given arrays.
9043 * Info on components is copied from the first of the given arrays. Number of components
9044 * in the given arrays must be the same.
9045 * If the number of non null of elements in \a arr is equal to one the returned object is a copy of it
9046 * not the object itself.
9047 * \param [in] arr - a sequence of arrays to include in the result array.
9048 * \return DataArrayInt * - the new instance of DataArrayInt.
9049 * The caller is to delete this result array using decrRef() as it is no more
9051 * \throw If all arrays within \a arr are NULL.
9052 * \throw If getNumberOfComponents() of arrays within \a arr.
9054 DataArrayInt *DataArrayInt::Aggregate(const std::vector<const DataArrayInt *>& arr)
9056 std::vector<const DataArrayInt *> a;
9057 for(std::vector<const DataArrayInt *>::const_iterator it4=arr.begin();it4!=arr.end();it4++)
9061 throw INTERP_KERNEL::Exception("DataArrayInt::Aggregate : input list must be NON EMPTY !");
9062 std::vector<const DataArrayInt *>::const_iterator it=a.begin();
9063 int nbOfComp=(*it)->getNumberOfComponents();
9064 int nbt=(*it++)->getNumberOfTuples();
9065 for(int i=1;it!=a.end();it++,i++)
9067 if((*it)->getNumberOfComponents()!=nbOfComp)
9068 throw INTERP_KERNEL::Exception("DataArrayInt::Aggregate : Nb of components mismatch for array aggregation !");
9069 nbt+=(*it)->getNumberOfTuples();
9071 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
9072 ret->alloc(nbt,nbOfComp);
9073 int *pt=ret->getPointer();
9074 for(it=a.begin();it!=a.end();it++)
9075 pt=std::copy((*it)->getConstPointer(),(*it)->getConstPointer()+(*it)->getNbOfElems(),pt);
9076 ret->copyStringInfoFrom(*(a[0]));
9081 * This method takes as input a list of DataArrayInt instances \a arrs that represent each a packed index arrays.
9082 * A packed index array is an allocated array with one component, and at least one tuple. The first element
9083 * of each array in \a arrs must be 0. Each array in \a arrs is expected to be increasingly monotonic.
9084 * This method is useful for users that want to aggregate a pair of DataArrayInt representing an indexed data (typically nodal connectivity index in unstructured meshes.
9086 * \return DataArrayInt * - a new object to be managed by the caller.
9088 DataArrayInt *DataArrayInt::AggregateIndexes(const std::vector<const DataArrayInt *>& arrs)
9091 for(std::vector<const DataArrayInt *>::const_iterator it4=arrs.begin();it4!=arrs.end();it4++)
9095 (*it4)->checkAllocated();
9096 if((*it4)->getNumberOfComponents()!=1)
9098 std::ostringstream oss; oss << "DataArrayInt::AggregateIndexes : presence of a DataArrayInt instance with nb of compo != 1 at pos " << std::distance(arrs.begin(),it4) << " !";
9099 throw INTERP_KERNEL::Exception(oss.str().c_str());
9101 int nbTupl=(*it4)->getNumberOfTuples();
9104 std::ostringstream oss; oss << "DataArrayInt::AggregateIndexes : presence of a DataArrayInt instance with nb of tuples < 1 at pos " << std::distance(arrs.begin(),it4) << " !";
9105 throw INTERP_KERNEL::Exception(oss.str().c_str());
9107 if((*it4)->front()!=0)
9109 std::ostringstream oss; oss << "DataArrayInt::AggregateIndexes : presence of a DataArrayInt instance with front value != 0 at pos " << std::distance(arrs.begin(),it4) << " !";
9110 throw INTERP_KERNEL::Exception(oss.str().c_str());
9116 std::ostringstream oss; oss << "DataArrayInt::AggregateIndexes : presence of a null instance at pos " << std::distance(arrs.begin(),it4) << " !";
9117 throw INTERP_KERNEL::Exception(oss.str().c_str());
9121 throw INTERP_KERNEL::Exception("DataArrayInt::AggregateIndexes : input list must be NON EMPTY !");
9122 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
9123 ret->alloc(retSz,1);
9124 int *pt=ret->getPointer(); *pt++=0;
9125 for(std::vector<const DataArrayInt *>::const_iterator it=arrs.begin();it!=arrs.end();it++)
9126 pt=std::transform((*it)->begin()+1,(*it)->end(),pt,std::bind2nd(std::plus<int>(),pt[-1]));
9127 ret->copyStringInfoFrom(*(arrs[0]));
9132 * Returns the maximal value and its location within \a this one-dimensional array.
9133 * \param [out] tupleId - index of the tuple holding the maximal value.
9134 * \return int - the maximal value among all values of \a this array.
9135 * \throw If \a this->getNumberOfComponents() != 1
9136 * \throw If \a this->getNumberOfTuples() < 1
9138 int DataArrayInt::getMaxValue(int& tupleId) const
9141 if(getNumberOfComponents()!=1)
9142 throw INTERP_KERNEL::Exception("DataArrayInt::getMaxValue : must be applied on DataArrayInt with only one component !");
9143 int nbOfTuples=getNumberOfTuples();
9145 throw INTERP_KERNEL::Exception("DataArrayInt::getMaxValue : array exists but number of tuples must be > 0 !");
9146 const int *vals=getConstPointer();
9147 const int *loc=std::max_element(vals,vals+nbOfTuples);
9148 tupleId=(int)std::distance(vals,loc);
9153 * Returns the maximal value within \a this array that is allowed to have more than
9155 * \return int - the maximal value among all values of \a this array.
9156 * \throw If \a this is not allocated.
9158 int DataArrayInt::getMaxValueInArray() const
9161 const int *loc=std::max_element(begin(),end());
9166 * Returns the minimal value and its location within \a this one-dimensional array.
9167 * \param [out] tupleId - index of the tuple holding the minimal value.
9168 * \return int - the minimal value among all values of \a this array.
9169 * \throw If \a this->getNumberOfComponents() != 1
9170 * \throw If \a this->getNumberOfTuples() < 1
9172 int DataArrayInt::getMinValue(int& tupleId) const
9175 if(getNumberOfComponents()!=1)
9176 throw INTERP_KERNEL::Exception("DataArrayInt::getMaxValue : must be applied on DataArrayInt with only one component !");
9177 int nbOfTuples=getNumberOfTuples();
9179 throw INTERP_KERNEL::Exception("DataArrayInt::getMaxValue : array exists but number of tuples must be > 0 !");
9180 const int *vals=getConstPointer();
9181 const int *loc=std::min_element(vals,vals+nbOfTuples);
9182 tupleId=(int)std::distance(vals,loc);
9187 * Returns the minimal value within \a this array that is allowed to have more than
9189 * \return int - the minimal value among all values of \a this array.
9190 * \throw If \a this is not allocated.
9192 int DataArrayInt::getMinValueInArray() const
9195 const int *loc=std::min_element(begin(),end());
9200 * Converts every value of \a this array to its absolute value.
9201 * \b WARNING this method is non const. If a new DataArrayInt instance should be built containing the result of abs DataArrayInt::computeAbs
9202 * should be called instead.
9204 * \throw If \a this is not allocated.
9205 * \sa DataArrayInt::computeAbs
9207 void DataArrayInt::abs()
9210 int *ptr(getPointer());
9211 std::size_t nbOfElems(getNbOfElems());
9212 std::transform(ptr,ptr+nbOfElems,ptr,std::ptr_fun<int,int>(std::abs));
9217 * This method builds a new instance of \a this object containing the result of std::abs applied of all elements in \a this.
9218 * This method is a const method (that do not change any values in \a this) contrary to DataArrayInt::abs method.
9220 * \return DataArrayInt * - the new instance of DataArrayInt containing the
9221 * same number of tuples and component as \a this array.
9222 * The caller is to delete this result array using decrRef() as it is no more
9224 * \throw If \a this is not allocated.
9225 * \sa DataArrayInt::abs
9227 DataArrayInt *DataArrayInt::computeAbs() const
9230 DataArrayInt *newArr(DataArrayInt::New());
9231 int nbOfTuples(getNumberOfTuples());
9232 int nbOfComp(getNumberOfComponents());
9233 newArr->alloc(nbOfTuples,nbOfComp);
9234 std::transform(begin(),end(),newArr->getPointer(),std::ptr_fun<int,int>(std::abs));
9235 newArr->copyStringInfoFrom(*this);
9240 * Apply a liner function to a given component of \a this array, so that
9241 * an array element <em>(x)</em> becomes \f$ a * x + b \f$.
9242 * \param [in] a - the first coefficient of the function.
9243 * \param [in] b - the second coefficient of the function.
9244 * \param [in] compoId - the index of component to modify.
9245 * \throw If \a this is not allocated.
9247 void DataArrayInt::applyLin(int a, int b, int compoId)
9250 int *ptr=getPointer()+compoId;
9251 int nbOfComp=getNumberOfComponents();
9252 int nbOfTuple=getNumberOfTuples();
9253 for(int i=0;i<nbOfTuple;i++,ptr+=nbOfComp)
9259 * Apply a liner function to all elements of \a this array, so that
9260 * an element _x_ becomes \f$ a * x + b \f$.
9261 * \param [in] a - the first coefficient of the function.
9262 * \param [in] b - the second coefficient of the function.
9263 * \throw If \a this is not allocated.
9265 void DataArrayInt::applyLin(int a, int b)
9268 int *ptr=getPointer();
9269 std::size_t nbOfElems=getNbOfElems();
9270 for(std::size_t i=0;i<nbOfElems;i++,ptr++)
9276 * Returns a full copy of \a this array except that sign of all elements is reversed.
9277 * \return DataArrayInt * - the new instance of DataArrayInt containing the
9278 * same number of tuples and component as \a this array.
9279 * The caller is to delete this result array using decrRef() as it is no more
9281 * \throw If \a this is not allocated.
9283 DataArrayInt *DataArrayInt::negate() const
9286 DataArrayInt *newArr=DataArrayInt::New();
9287 int nbOfTuples=getNumberOfTuples();
9288 int nbOfComp=getNumberOfComponents();
9289 newArr->alloc(nbOfTuples,nbOfComp);
9290 const int *cptr=getConstPointer();
9291 std::transform(cptr,cptr+nbOfTuples*nbOfComp,newArr->getPointer(),std::negate<int>());
9292 newArr->copyStringInfoFrom(*this);
9297 * Modify all elements of \a this array, so that
9298 * an element _x_ becomes \f$ numerator / x \f$.
9299 * \warning If an exception is thrown because of presence of 0 element in \a this
9300 * array, all elements processed before detection of the zero element remain
9302 * \param [in] numerator - the numerator used to modify array elements.
9303 * \throw If \a this is not allocated.
9304 * \throw If there is an element equal to 0 in \a this array.
9306 void DataArrayInt::applyInv(int numerator)
9309 int *ptr=getPointer();
9310 std::size_t nbOfElems=getNbOfElems();
9311 for(std::size_t i=0;i<nbOfElems;i++,ptr++)
9315 *ptr=numerator/(*ptr);
9319 std::ostringstream oss; oss << "DataArrayInt::applyInv : presence of null value in tuple #" << i/getNumberOfComponents() << " component #" << i%getNumberOfComponents();
9321 throw INTERP_KERNEL::Exception(oss.str().c_str());
9328 * Modify all elements of \a this array, so that
9329 * an element _x_ becomes \f$ x / val \f$.
9330 * \param [in] val - the denominator used to modify array elements.
9331 * \throw If \a this is not allocated.
9332 * \throw If \a val == 0.
9334 void DataArrayInt::applyDivideBy(int val)
9337 throw INTERP_KERNEL::Exception("DataArrayInt::applyDivideBy : Trying to divide by 0 !");
9339 int *ptr=getPointer();
9340 std::size_t nbOfElems=getNbOfElems();
9341 std::transform(ptr,ptr+nbOfElems,ptr,std::bind2nd(std::divides<int>(),val));
9346 * Modify all elements of \a this array, so that
9347 * an element _x_ becomes <em> x % val </em>.
9348 * \param [in] val - the divisor used to modify array elements.
9349 * \throw If \a this is not allocated.
9350 * \throw If \a val <= 0.
9352 void DataArrayInt::applyModulus(int val)
9355 throw INTERP_KERNEL::Exception("DataArrayInt::applyDivideBy : Trying to operate modulus on value <= 0 !");
9357 int *ptr=getPointer();
9358 std::size_t nbOfElems=getNbOfElems();
9359 std::transform(ptr,ptr+nbOfElems,ptr,std::bind2nd(std::modulus<int>(),val));
9364 * This method works only on data array with one component.
9365 * This method returns a newly allocated array storing stored ascendantly tuple ids in \b this so that
9366 * this[*id] in [\b vmin,\b vmax)
9368 * \param [in] vmin begin of range. This value is included in range (included).
9369 * \param [in] vmax end of range. This value is \b not included in range (excluded).
9370 * \return a newly allocated data array that the caller should deal with.
9372 * \sa DataArrayInt::getIdsNotInRange
9374 DataArrayInt *DataArrayInt::getIdsInRange(int vmin, int vmax) const
9377 if(getNumberOfComponents()!=1)
9378 throw INTERP_KERNEL::Exception("DataArrayInt::getIdsInRange : this must have exactly one component !");
9379 const int *cptr(begin());
9380 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
9381 int nbOfTuples(getNumberOfTuples());
9382 for(int i=0;i<nbOfTuples;i++,cptr++)
9383 if(*cptr>=vmin && *cptr<vmax)
9384 ret->pushBackSilent(i);
9389 * This method works only on data array with one component.
9390 * This method returns a newly allocated array storing stored ascendantly tuple ids in \b this so that
9391 * this[*id] \b not in [\b vmin,\b vmax)
9393 * \param [in] vmin begin of range. This value is \b not included in range (excluded).
9394 * \param [in] vmax end of range. This value is included in range (included).
9395 * \return a newly allocated data array that the caller should deal with.
9397 * \sa DataArrayInt::getIdsInRange
9399 DataArrayInt *DataArrayInt::getIdsNotInRange(int vmin, int vmax) const
9402 if(getNumberOfComponents()!=1)
9403 throw INTERP_KERNEL::Exception("DataArrayInt::getIdsNotInRange : this must have exactly one component !");
9404 const int *cptr(getConstPointer());
9405 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
9406 int nbOfTuples(getNumberOfTuples());
9407 for(int i=0;i<nbOfTuples;i++,cptr++)
9408 if(*cptr<vmin || *cptr>=vmax)
9409 ret->pushBackSilent(i);
9414 * This method works only on data array with one component.
9415 * This method checks that all ids in \b this are in [ \b vmin, \b vmax ). If there is at least one element in \a this not in [ \b vmin, \b vmax ) an exception will be thrown.
9417 * \param [in] vmin begin of range. This value is included in range (included).
9418 * \param [in] vmax end of range. This value is \b not included in range (excluded).
9419 * \return if all ids in \a this are so that (*this)[i]==i for all i in [ 0, \c this->getNumberOfTuples() ). */
9420 bool DataArrayInt::checkAllIdsInRange(int vmin, int vmax) const
9423 if(getNumberOfComponents()!=1)
9424 throw INTERP_KERNEL::Exception("DataArrayInt::checkAllIdsInRange : this must have exactly one component !");
9425 int nbOfTuples=getNumberOfTuples();
9427 const int *cptr=getConstPointer();
9428 for(int i=0;i<nbOfTuples;i++,cptr++)
9430 if(*cptr>=vmin && *cptr<vmax)
9431 { ret=ret && *cptr==i; }
9434 std::ostringstream oss; oss << "DataArrayInt::checkAllIdsInRange : tuple #" << i << " has value " << *cptr << " should be in [" << vmin << "," << vmax << ") !";
9435 throw INTERP_KERNEL::Exception(oss.str().c_str());
9442 * Modify all elements of \a this array, so that
9443 * an element _x_ becomes <em> val % x </em>.
9444 * \warning If an exception is thrown because of presence of an element <= 0 in \a this
9445 * array, all elements processed before detection of the zero element remain
9447 * \param [in] val - the divident used to modify array elements.
9448 * \throw If \a this is not allocated.
9449 * \throw If there is an element equal to or less than 0 in \a this array.
9451 void DataArrayInt::applyRModulus(int val)
9454 int *ptr=getPointer();
9455 std::size_t nbOfElems=getNbOfElems();
9456 for(std::size_t i=0;i<nbOfElems;i++,ptr++)
9464 std::ostringstream oss; oss << "DataArrayInt::applyRModulus : presence of value <=0 in tuple #" << i/getNumberOfComponents() << " component #" << i%getNumberOfComponents();
9466 throw INTERP_KERNEL::Exception(oss.str().c_str());
9473 * Modify all elements of \a this array, so that
9474 * an element _x_ becomes <em> val ^ x </em>.
9475 * \param [in] val - the value used to apply pow on all array elements.
9476 * \throw If \a this is not allocated.
9477 * \throw If \a val < 0.
9479 void DataArrayInt::applyPow(int val)
9483 throw INTERP_KERNEL::Exception("DataArrayInt::applyPow : input pow in < 0 !");
9484 int *ptr=getPointer();
9485 std::size_t nbOfElems=getNbOfElems();
9488 std::fill(ptr,ptr+nbOfElems,1);
9491 for(std::size_t i=0;i<nbOfElems;i++,ptr++)
9494 for(int j=0;j<val;j++)
9502 * Modify all elements of \a this array, so that
9503 * an element _x_ becomes \f$ val ^ x \f$.
9504 * \param [in] val - the value used to apply pow on all array elements.
9505 * \throw If \a this is not allocated.
9506 * \throw If there is an element < 0 in \a this array.
9507 * \warning If an exception is thrown because of presence of 0 element in \a this
9508 * array, all elements processed before detection of the zero element remain
9511 void DataArrayInt::applyRPow(int val)
9514 int *ptr=getPointer();
9515 std::size_t nbOfElems=getNbOfElems();
9516 for(std::size_t i=0;i<nbOfElems;i++,ptr++)
9521 for(int j=0;j<*ptr;j++)
9527 std::ostringstream oss; oss << "DataArrayInt::applyRPow : presence of negative value in tuple #" << i/getNumberOfComponents() << " component #" << i%getNumberOfComponents();
9529 throw INTERP_KERNEL::Exception(oss.str().c_str());
9536 * Returns a new DataArrayInt by aggregating two given arrays, so that (1) the number
9537 * of components in the result array is a sum of the number of components of given arrays
9538 * and (2) the number of tuples in the result array is same as that of each of given
9539 * arrays. In other words the i-th tuple of result array includes all components of
9540 * i-th tuples of all given arrays.
9541 * Number of tuples in the given arrays must be the same.
9542 * \param [in] a1 - an array to include in the result array.
9543 * \param [in] a2 - another array to include in the result array.
9544 * \return DataArrayInt * - the new instance of DataArrayInt.
9545 * The caller is to delete this result array using decrRef() as it is no more
9547 * \throw If both \a a1 and \a a2 are NULL.
9548 * \throw If any given array is not allocated.
9549 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples()
9551 DataArrayInt *DataArrayInt::Meld(const DataArrayInt *a1, const DataArrayInt *a2)
9553 std::vector<const DataArrayInt *> arr(2);
9554 arr[0]=a1; arr[1]=a2;
9559 * Returns a new DataArrayInt by aggregating all given arrays, so that (1) the number
9560 * of components in the result array is a sum of the number of components of given arrays
9561 * and (2) the number of tuples in the result array is same as that of each of given
9562 * arrays. In other words the i-th tuple of result array includes all components of
9563 * i-th tuples of all given arrays.
9564 * Number of tuples in the given arrays must be the same.
9565 * \param [in] arr - a sequence of arrays to include in the result array.
9566 * \return DataArrayInt * - the new instance of DataArrayInt.
9567 * The caller is to delete this result array using decrRef() as it is no more
9569 * \throw If all arrays within \a arr are NULL.
9570 * \throw If any given array is not allocated.
9571 * \throw If getNumberOfTuples() of arrays within \a arr is different.
9573 DataArrayInt *DataArrayInt::Meld(const std::vector<const DataArrayInt *>& arr)
9575 std::vector<const DataArrayInt *> a;
9576 for(std::vector<const DataArrayInt *>::const_iterator it4=arr.begin();it4!=arr.end();it4++)
9580 throw INTERP_KERNEL::Exception("DataArrayInt::Meld : array must be NON empty !");
9581 std::vector<const DataArrayInt *>::const_iterator it;
9582 for(it=a.begin();it!=a.end();it++)
9583 (*it)->checkAllocated();
9585 int nbOfTuples=(*it)->getNumberOfTuples();
9586 std::vector<int> nbc(a.size());
9587 std::vector<const int *> pts(a.size());
9588 nbc[0]=(*it)->getNumberOfComponents();
9589 pts[0]=(*it++)->getConstPointer();
9590 for(int i=1;it!=a.end();it++,i++)
9592 if(nbOfTuples!=(*it)->getNumberOfTuples())
9593 throw INTERP_KERNEL::Exception("DataArrayInt::meld : mismatch of number of tuples !");
9594 nbc[i]=(*it)->getNumberOfComponents();
9595 pts[i]=(*it)->getConstPointer();
9597 int totalNbOfComp=std::accumulate(nbc.begin(),nbc.end(),0);
9598 DataArrayInt *ret=DataArrayInt::New();
9599 ret->alloc(nbOfTuples,totalNbOfComp);
9600 int *retPtr=ret->getPointer();
9601 for(int i=0;i<nbOfTuples;i++)
9602 for(int j=0;j<(int)a.size();j++)
9604 retPtr=std::copy(pts[j],pts[j]+nbc[j],retPtr);
9608 for(int i=0;i<(int)a.size();i++)
9609 for(int j=0;j<nbc[i];j++,k++)
9610 ret->setInfoOnComponent(k,a[i]->getInfoOnComponent(j));
9615 * Returns a new DataArrayInt which is a minimal partition of elements of \a groups.
9616 * The i-th item of the result array is an ID of a set of elements belonging to a
9617 * unique set of groups, which the i-th element is a part of. This set of elements
9618 * belonging to a unique set of groups is called \a family, so the result array contains
9619 * IDs of families each element belongs to.
9621 * \b Example: if we have two groups of elements: \a group1 [0,4] and \a group2 [ 0,1,2 ],
9622 * then there are 3 families:
9623 * - \a family1 (with ID 1) contains element [0] belonging to ( \a group1 + \a group2 ),
9624 * - \a family2 (with ID 2) contains elements [4] belonging to ( \a group1 ),
9625 * - \a family3 (with ID 3) contains element [1,2] belonging to ( \a group2 ), <br>
9626 * and the result array contains IDs of families [ 1,3,3,0,2 ]. <br> Note a family ID 0 which
9627 * stands for the element #3 which is in none of groups.
9629 * \param [in] groups - sequence of groups of element IDs.
9630 * \param [in] newNb - total number of elements; it must be more than max ID of element
9632 * \param [out] fidsOfGroups - IDs of families the elements of each group belong to.
9633 * \return DataArrayInt * - a new instance of DataArrayInt containing IDs of families
9634 * each element with ID from range [0, \a newNb ) belongs to. The caller is to
9635 * delete this array using decrRef() as it is no more needed.
9636 * \throw If any element ID in \a groups violates condition ( 0 <= ID < \a newNb ).
9638 DataArrayInt *DataArrayInt::MakePartition(const std::vector<const DataArrayInt *>& groups, int newNb, std::vector< std::vector<int> >& fidsOfGroups)
9640 std::vector<const DataArrayInt *> groups2;
9641 for(std::vector<const DataArrayInt *>::const_iterator it4=groups.begin();it4!=groups.end();it4++)
9643 groups2.push_back(*it4);
9644 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
9645 ret->alloc(newNb,1);
9646 int *retPtr=ret->getPointer();
9647 std::fill(retPtr,retPtr+newNb,0);
9649 for(std::vector<const DataArrayInt *>::const_iterator iter=groups2.begin();iter!=groups2.end();iter++)
9651 const int *ptr=(*iter)->getConstPointer();
9652 std::size_t nbOfElem=(*iter)->getNbOfElems();
9654 for(int j=0;j<sfid;j++)
9657 for(std::size_t i=0;i<nbOfElem;i++)
9659 if(ptr[i]>=0 && ptr[i]<newNb)
9661 if(retPtr[ptr[i]]==j)
9669 std::ostringstream oss; oss << "DataArrayInt::MakePartition : In group \"" << (*iter)->getName() << "\" in tuple #" << i << " value = " << ptr[i] << " ! Should be in [0," << newNb;
9671 throw INTERP_KERNEL::Exception(oss.str().c_str());
9678 fidsOfGroups.clear();
9679 fidsOfGroups.resize(groups2.size());
9681 for(std::vector<const DataArrayInt *>::const_iterator iter=groups2.begin();iter!=groups2.end();iter++,grId++)
9684 const int *ptr=(*iter)->getConstPointer();
9685 std::size_t nbOfElem=(*iter)->getNbOfElems();
9686 for(const int *p=ptr;p!=ptr+nbOfElem;p++)
9687 tmp.insert(retPtr[*p]);
9688 fidsOfGroups[grId].insert(fidsOfGroups[grId].end(),tmp.begin(),tmp.end());
9694 * Returns a new DataArrayInt which contains all elements of given one-dimensional
9695 * arrays. The result array does not contain any duplicates and its values
9696 * are sorted in ascending order.
9697 * \param [in] arr - sequence of DataArrayInt's to unite.
9698 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
9699 * array using decrRef() as it is no more needed.
9700 * \throw If any \a arr[i] is not allocated.
9701 * \throw If \a arr[i]->getNumberOfComponents() != 1.
9703 DataArrayInt *DataArrayInt::BuildUnion(const std::vector<const DataArrayInt *>& arr)
9705 std::vector<const DataArrayInt *> a;
9706 for(std::vector<const DataArrayInt *>::const_iterator it4=arr.begin();it4!=arr.end();it4++)
9709 for(std::vector<const DataArrayInt *>::const_iterator it=a.begin();it!=a.end();it++)
9711 (*it)->checkAllocated();
9712 if((*it)->getNumberOfComponents()!=1)
9713 throw INTERP_KERNEL::Exception("DataArrayInt::BuildUnion : only single component allowed !");
9717 for(std::vector<const DataArrayInt *>::const_iterator it=a.begin();it!=a.end();it++)
9719 const int *pt=(*it)->getConstPointer();
9720 int nbOfTuples=(*it)->getNumberOfTuples();
9721 r.insert(pt,pt+nbOfTuples);
9723 DataArrayInt *ret=DataArrayInt::New();
9724 ret->alloc((int)r.size(),1);
9725 std::copy(r.begin(),r.end(),ret->getPointer());
9730 * Returns a new DataArrayInt which contains elements present in each of given one-dimensional
9731 * arrays. The result array does not contain any duplicates and its values
9732 * are sorted in ascending order.
9733 * \param [in] arr - sequence of DataArrayInt's to intersect.
9734 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
9735 * array using decrRef() as it is no more needed.
9736 * \throw If any \a arr[i] is not allocated.
9737 * \throw If \a arr[i]->getNumberOfComponents() != 1.
9739 DataArrayInt *DataArrayInt::BuildIntersection(const std::vector<const DataArrayInt *>& arr)
9741 std::vector<const DataArrayInt *> a;
9742 for(std::vector<const DataArrayInt *>::const_iterator it4=arr.begin();it4!=arr.end();it4++)
9745 for(std::vector<const DataArrayInt *>::const_iterator it=a.begin();it!=a.end();it++)
9747 (*it)->checkAllocated();
9748 if((*it)->getNumberOfComponents()!=1)
9749 throw INTERP_KERNEL::Exception("DataArrayInt::BuildIntersection : only single component allowed !");
9753 for(std::vector<const DataArrayInt *>::const_iterator it=a.begin();it!=a.end();it++)
9755 const int *pt=(*it)->getConstPointer();
9756 int nbOfTuples=(*it)->getNumberOfTuples();
9757 std::set<int> s1(pt,pt+nbOfTuples);
9761 std::set_intersection(r.begin(),r.end(),s1.begin(),s1.end(),inserter(r2,r2.end()));
9767 DataArrayInt *ret(DataArrayInt::New());
9768 ret->alloc((int)r.size(),1);
9769 std::copy(r.begin(),r.end(),ret->getPointer());
9774 namespace ParaMEDMEMImpl
9779 OpSwitchedOn(int *pt):_pt(pt),_cnt(0) { }
9780 void operator()(const bool& b) { if(b) *_pt++=_cnt; _cnt++; }
9789 OpSwitchedOff(int *pt):_pt(pt),_cnt(0) { }
9790 void operator()(const bool& b) { if(!b) *_pt++=_cnt; _cnt++; }
9799 * This method returns the list of ids in ascending mode so that v[id]==true.
9801 DataArrayInt *DataArrayInt::BuildListOfSwitchedOn(const std::vector<bool>& v)
9803 int sz((int)std::count(v.begin(),v.end(),true));
9804 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(sz,1);
9805 std::for_each(v.begin(),v.end(),ParaMEDMEMImpl::OpSwitchedOn(ret->getPointer()));
9810 * This method returns the list of ids in ascending mode so that v[id]==false.
9812 DataArrayInt *DataArrayInt::BuildListOfSwitchedOff(const std::vector<bool>& v)
9814 int sz((int)std::count(v.begin(),v.end(),false));
9815 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(sz,1);
9816 std::for_each(v.begin(),v.end(),ParaMEDMEMImpl::OpSwitchedOff(ret->getPointer()));
9821 * This method allows to put a vector of vector of integer into a more compact data stucture (skyline).
9822 * This method is not available into python because no available optimized data structure available to map std::vector< std::vector<int> >.
9824 * \param [in] v the input data structure to be translate into skyline format.
9825 * \param [out] data the first element of the skyline format. The user is expected to deal with newly allocated array.
9826 * \param [out] dataIndex the second element of the skyline format.
9828 void DataArrayInt::PutIntoToSkylineFrmt(const std::vector< std::vector<int> >& v, DataArrayInt *& data, DataArrayInt *& dataIndex)
9830 int sz((int)v.size());
9831 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret0(DataArrayInt::New()),ret1(DataArrayInt::New());
9832 ret1->alloc(sz+1,1);
9833 int *pt(ret1->getPointer()); *pt=0;
9834 for(int i=0;i<sz;i++,pt++)
9835 pt[1]=pt[0]+(int)v[i].size();
9836 ret0->alloc(ret1->back(),1);
9837 pt=ret0->getPointer();
9838 for(int i=0;i<sz;i++)
9839 pt=std::copy(v[i].begin(),v[i].end(),pt);
9840 data=ret0.retn(); dataIndex=ret1.retn();
9844 * Returns a new DataArrayInt which contains a complement of elements of \a this
9845 * one-dimensional array. I.e. the result array contains all elements from the range [0,
9846 * \a nbOfElement) not present in \a this array.
9847 * \param [in] nbOfElement - maximal size of the result array.
9848 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
9849 * array using decrRef() as it is no more needed.
9850 * \throw If \a this is not allocated.
9851 * \throw If \a this->getNumberOfComponents() != 1.
9852 * \throw If any element \a x of \a this array violates condition ( 0 <= \a x < \a
9855 DataArrayInt *DataArrayInt::buildComplement(int nbOfElement) const
9858 if(getNumberOfComponents()!=1)
9859 throw INTERP_KERNEL::Exception("DataArrayInt::buildComplement : only single component allowed !");
9860 std::vector<bool> tmp(nbOfElement);
9861 const int *pt=getConstPointer();
9862 int nbOfTuples=getNumberOfTuples();
9863 for(const int *w=pt;w!=pt+nbOfTuples;w++)
9864 if(*w>=0 && *w<nbOfElement)
9867 throw INTERP_KERNEL::Exception("DataArrayInt::buildComplement : an element is not in valid range : [0,nbOfElement) !");
9868 int nbOfRetVal=(int)std::count(tmp.begin(),tmp.end(),false);
9869 DataArrayInt *ret=DataArrayInt::New();
9870 ret->alloc(nbOfRetVal,1);
9872 int *retPtr=ret->getPointer();
9873 for(int i=0;i<nbOfElement;i++)
9880 * Returns a new DataArrayInt containing elements of \a this one-dimensional missing
9881 * from an \a other one-dimensional array.
9882 * \param [in] other - a DataArrayInt containing elements not to include in the result array.
9883 * \return DataArrayInt * - a new instance of DataArrayInt with one component. The
9884 * caller is to delete this array using decrRef() as it is no more needed.
9885 * \throw If \a other is NULL.
9886 * \throw If \a other is not allocated.
9887 * \throw If \a other->getNumberOfComponents() != 1.
9888 * \throw If \a this is not allocated.
9889 * \throw If \a this->getNumberOfComponents() != 1.
9890 * \sa DataArrayInt::buildSubstractionOptimized()
9892 DataArrayInt *DataArrayInt::buildSubstraction(const DataArrayInt *other) const
9895 throw INTERP_KERNEL::Exception("DataArrayInt::buildSubstraction : DataArrayInt pointer in input is NULL !");
9897 other->checkAllocated();
9898 if(getNumberOfComponents()!=1)
9899 throw INTERP_KERNEL::Exception("DataArrayInt::buildSubstraction : only single component allowed !");
9900 if(other->getNumberOfComponents()!=1)
9901 throw INTERP_KERNEL::Exception("DataArrayInt::buildSubstraction : only single component allowed for other type !");
9902 const int *pt=getConstPointer();
9903 int nbOfTuples=getNumberOfTuples();
9904 std::set<int> s1(pt,pt+nbOfTuples);
9905 pt=other->getConstPointer();
9906 nbOfTuples=other->getNumberOfTuples();
9907 std::set<int> s2(pt,pt+nbOfTuples);
9909 std::set_difference(s1.begin(),s1.end(),s2.begin(),s2.end(),std::back_insert_iterator< std::vector<int> >(r));
9910 DataArrayInt *ret=DataArrayInt::New();
9911 ret->alloc((int)r.size(),1);
9912 std::copy(r.begin(),r.end(),ret->getPointer());
9917 * \a this is expected to have one component and to be sorted ascendingly (as for \a other).
9918 * \a other is expected to be a part of \a this. If not DataArrayInt::buildSubstraction should be called instead.
9920 * \param [in] other an array with one component and expected to be sorted ascendingly.
9921 * \ret list of ids in \a this but not in \a other.
9922 * \sa DataArrayInt::buildSubstraction
9924 DataArrayInt *DataArrayInt::buildSubstractionOptimized(const DataArrayInt *other) const
9926 static const char *MSG="DataArrayInt::buildSubstractionOptimized : only single component allowed !";
9927 if(!other) throw INTERP_KERNEL::Exception("DataArrayInt::buildSubstractionOptimized : NULL input array !");
9928 checkAllocated(); other->checkAllocated();
9929 if(getNumberOfComponents()!=1) throw INTERP_KERNEL::Exception(MSG);
9930 if(other->getNumberOfComponents()!=1) throw INTERP_KERNEL::Exception(MSG);
9931 const int *pt1Bg(begin()),*pt1End(end()),*pt2Bg(other->begin()),*pt2End(other->end());
9932 const int *work1(pt1Bg),*work2(pt2Bg);
9933 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
9934 for(;work1!=pt1End;work1++)
9936 if(work2!=pt2End && *work1==*work2)
9939 ret->pushBackSilent(*work1);
9946 * Returns a new DataArrayInt which contains all elements of \a this and a given
9947 * one-dimensional arrays. The result array does not contain any duplicates
9948 * and its values are sorted in ascending order.
9949 * \param [in] other - an array to unite with \a this one.
9950 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
9951 * array using decrRef() as it is no more needed.
9952 * \throw If \a this or \a other is not allocated.
9953 * \throw If \a this->getNumberOfComponents() != 1.
9954 * \throw If \a other->getNumberOfComponents() != 1.
9956 DataArrayInt *DataArrayInt::buildUnion(const DataArrayInt *other) const
9958 std::vector<const DataArrayInt *>arrs(2);
9959 arrs[0]=this; arrs[1]=other;
9960 return BuildUnion(arrs);
9965 * Returns a new DataArrayInt which contains elements present in both \a this and a given
9966 * one-dimensional arrays. The result array does not contain any duplicates
9967 * and its values are sorted in ascending order.
9968 * \param [in] other - an array to intersect with \a this one.
9969 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
9970 * array using decrRef() as it is no more needed.
9971 * \throw If \a this or \a other is not allocated.
9972 * \throw If \a this->getNumberOfComponents() != 1.
9973 * \throw If \a other->getNumberOfComponents() != 1.
9975 DataArrayInt *DataArrayInt::buildIntersection(const DataArrayInt *other) const
9977 std::vector<const DataArrayInt *>arrs(2);
9978 arrs[0]=this; arrs[1]=other;
9979 return BuildIntersection(arrs);
9983 * This method can be applied on allocated with one component DataArrayInt instance.
9984 * This method is typically relevant for sorted arrays. All consecutive duplicated items in \a this will appear only once in returned DataArrayInt instance.
9985 * Example : if \a this contains [1,2,2,3,3,3,3,4,5,5,7,7,7,19] the returned array will contain [1,2,3,4,5,7,19]
9987 * \return a newly allocated array that contain the result of the unique operation applied on \a this.
9988 * \throw if \a this is not allocated or if \a this has not exactly one component.
9990 DataArrayInt *DataArrayInt::buildUnique() const
9993 if(getNumberOfComponents()!=1)
9994 throw INTERP_KERNEL::Exception("DataArrayInt::buildUnique : only single component allowed !");
9995 int nbOfTuples=getNumberOfTuples();
9996 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> tmp=deepCpy();
9997 int *data=tmp->getPointer();
9998 int *last=std::unique(data,data+nbOfTuples);
9999 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
10000 ret->alloc(std::distance(data,last),1);
10001 std::copy(data,last,ret->getPointer());
10006 * Returns a new DataArrayInt which contains size of every of groups described by \a this
10007 * "index" array. Such "index" array is returned for example by
10008 * \ref ParaMEDMEM::MEDCouplingUMesh::buildDescendingConnectivity
10009 * "MEDCouplingUMesh::buildDescendingConnectivity" and
10010 * \ref ParaMEDMEM::MEDCouplingUMesh::getNodalConnectivityIndex
10011 * "MEDCouplingUMesh::getNodalConnectivityIndex" etc.
10012 * This method preforms the reverse operation of DataArrayInt::computeOffsets2.
10013 * \return DataArrayInt * - a new instance of DataArrayInt, whose number of tuples
10014 * equals to \a this->getNumberOfComponents() - 1, and number of components is 1.
10015 * The caller is to delete this array using decrRef() as it is no more needed.
10016 * \throw If \a this is not allocated.
10017 * \throw If \a this->getNumberOfComponents() != 1.
10018 * \throw If \a this->getNumberOfTuples() < 2.
10021 * - this contains [1,3,6,7,7,9,15]
10022 * - result array contains [2,3,1,0,2,6],
10023 * where 2 = 3 - 1, 3 = 6 - 3, 1 = 7 - 6 etc.
10025 * \sa DataArrayInt::computeOffsets2
10027 DataArrayInt *DataArrayInt::deltaShiftIndex() const
10030 if(getNumberOfComponents()!=1)
10031 throw INTERP_KERNEL::Exception("DataArrayInt::deltaShiftIndex : only single component allowed !");
10032 int nbOfTuples=getNumberOfTuples();
10034 throw INTERP_KERNEL::Exception("DataArrayInt::deltaShiftIndex : 1 tuple at least must be present in 'this' !");
10035 const int *ptr=getConstPointer();
10036 DataArrayInt *ret=DataArrayInt::New();
10037 ret->alloc(nbOfTuples-1,1);
10038 int *out=ret->getPointer();
10039 std::transform(ptr+1,ptr+nbOfTuples,ptr,out,std::minus<int>());
10044 * Modifies \a this one-dimensional array so that value of each element \a x
10045 * of \a this array (\a a) is computed as \f$ x_i = \sum_{j=0}^{i-1} a[ j ] \f$.
10046 * Or: for each i>0 new[i]=new[i-1]+old[i-1] for i==0 new[i]=0. Number of tuples
10047 * and components remains the same.<br>
10048 * This method is useful for allToAllV in MPI with contiguous policy. This method
10049 * differs from computeOffsets2() in that the number of tuples is \b not changed by
10051 * \throw If \a this is not allocated.
10052 * \throw If \a this->getNumberOfComponents() != 1.
10055 * - Before \a this contains [3,5,1,2,0,8]
10056 * - After \a this contains [0,3,8,9,11,11]<br>
10057 * Note that the last element 19 = 11 + 8 is missing because size of \a this
10058 * array is retained and thus there is no space to store the last element.
10060 void DataArrayInt::computeOffsets()
10063 if(getNumberOfComponents()!=1)
10064 throw INTERP_KERNEL::Exception("DataArrayInt::computeOffsets : only single component allowed !");
10065 int nbOfTuples=getNumberOfTuples();
10068 int *work=getPointer();
10071 for(int i=1;i<nbOfTuples;i++)
10074 work[i]=work[i-1]+tmp;
10082 * Modifies \a this one-dimensional array so that value of each element \a x
10083 * of \a this array (\a a) is computed as \f$ x_i = \sum_{j=0}^{i-1} a[ j ] \f$.
10084 * Or: for each i>0 new[i]=new[i-1]+old[i-1] for i==0 new[i]=0. Number
10085 * components remains the same and number of tuples is inceamented by one.<br>
10086 * This method is useful for allToAllV in MPI with contiguous policy. This method
10087 * differs from computeOffsets() in that the number of tuples is changed by this one.
10088 * This method preforms the reverse operation of DataArrayInt::deltaShiftIndex.
10089 * \throw If \a this is not allocated.
10090 * \throw If \a this->getNumberOfComponents() != 1.
10093 * - Before \a this contains [3,5,1,2,0,8]
10094 * - After \a this contains [0,3,8,9,11,11,19]<br>
10095 * \sa DataArrayInt::deltaShiftIndex
10097 void DataArrayInt::computeOffsets2()
10100 if(getNumberOfComponents()!=1)
10101 throw INTERP_KERNEL::Exception("DataArrayInt::computeOffsets2 : only single component allowed !");
10102 int nbOfTuples=getNumberOfTuples();
10103 int *ret=(int *)malloc((nbOfTuples+1)*sizeof(int));
10106 const int *work=getConstPointer();
10108 for(int i=0;i<nbOfTuples;i++)
10109 ret[i+1]=work[i]+ret[i];
10110 useArray(ret,true,C_DEALLOC,nbOfTuples+1,1);
10115 * Returns two new DataArrayInt instances whose contents is computed from that of \a this and \a listOfIds arrays as follows.
10116 * \a this is expected to be an offset format ( as returned by DataArrayInt::computeOffsets2 ) that is to say with one component
10117 * and ** sorted strictly increasingly **. \a listOfIds is expected to be sorted ascendingly (not strictly needed for \a listOfIds).
10118 * This methods searches in \a this, considered as a set of contiguous \c this->getNumberOfComponents() ranges, all ids in \a listOfIds
10119 * filling completely one of the ranges in \a this.
10121 * \param [in] listOfIds a list of ids that has to be sorted ascendingly.
10122 * \param [out] rangeIdsFetched the range ids fetched
10123 * \param [out] idsInInputListThatFetch contains the list of ids in \a listOfIds that are \b fully included in a range in \a this. So
10124 * \a idsInInputListThatFetch is a part of input \a listOfIds.
10126 * \sa DataArrayInt::computeOffsets2
10129 * - \a this : [0,3,7,9,15,18]
10130 * - \a listOfIds contains [0,1,2,3,7,8,15,16,17]
10131 * - \a rangeIdsFetched result array: [0,2,4]
10132 * - \a idsInInputListThatFetch result array: [0,1,2,7,8,15,16,17]
10133 * In this example id 3 in input \a listOfIds is alone so it do not appear in output \a idsInInputListThatFetch.
10136 void DataArrayInt::searchRangesInListOfIds(const DataArrayInt *listOfIds, DataArrayInt *& rangeIdsFetched, DataArrayInt *& idsInInputListThatFetch) const
10139 throw INTERP_KERNEL::Exception("DataArrayInt::searchRangesInListOfIds : input list of ids is null !");
10140 listOfIds->checkAllocated(); checkAllocated();
10141 if(listOfIds->getNumberOfComponents()!=1)
10142 throw INTERP_KERNEL::Exception("DataArrayInt::searchRangesInListOfIds : input list of ids must have exactly one component !");
10143 if(getNumberOfComponents()!=1)
10144 throw INTERP_KERNEL::Exception("DataArrayInt::searchRangesInListOfIds : this must have exactly one component !");
10145 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret0=DataArrayInt::New(); ret0->alloc(0,1);
10146 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret1=DataArrayInt::New(); ret1->alloc(0,1);
10147 const int *tupEnd(listOfIds->end()),*offBg(begin()),*offEnd(end()-1);
10148 const int *tupPtr(listOfIds->begin()),*offPtr(offBg);
10149 while(tupPtr!=tupEnd && offPtr!=offEnd)
10151 if(*tupPtr==*offPtr)
10154 while(i<offPtr[1] && *tupPtr==i && tupPtr!=tupEnd) { i++; tupPtr++; }
10157 ret0->pushBackSilent((int)std::distance(offBg,offPtr));
10158 ret1->pushBackValsSilent(tupPtr-(offPtr[1]-offPtr[0]),tupPtr);
10163 { if(*tupPtr<*offPtr) tupPtr++; else offPtr++; }
10165 rangeIdsFetched=ret0.retn();
10166 idsInInputListThatFetch=ret1.retn();
10170 * Returns a new DataArrayInt whose contents is computed from that of \a this and \a
10171 * offsets arrays as follows. \a offsets is a one-dimensional array considered as an
10172 * "index" array of a "iota" array, thus, whose each element gives an index of a group
10173 * beginning within the "iota" array. And \a this is a one-dimensional array
10174 * considered as a selector of groups described by \a offsets to include into the result array.
10175 * \throw If \a offsets is NULL.
10176 * \throw If \a offsets is not allocated.
10177 * \throw If \a offsets->getNumberOfComponents() != 1.
10178 * \throw If \a offsets is not monotonically increasing.
10179 * \throw If \a this is not allocated.
10180 * \throw If \a this->getNumberOfComponents() != 1.
10181 * \throw If any element of \a this is not a valid index for \a offsets array.
10184 * - \a this: [0,2,3]
10185 * - \a offsets: [0,3,6,10,14,20]
10186 * - result array: [0,1,2,6,7,8,9,10,11,12,13] == <br>
10187 * \c range(0,3) + \c range(6,10) + \c range(10,14) ==<br>
10188 * \c range( \a offsets[ \a this[0] ], offsets[ \a this[0]+1 ]) +
10189 * \c range( \a offsets[ \a this[1] ], offsets[ \a this[1]+1 ]) +
10190 * \c range( \a offsets[ \a this[2] ], offsets[ \a this[2]+1 ])
10192 DataArrayInt *DataArrayInt::buildExplicitArrByRanges(const DataArrayInt *offsets) const
10195 throw INTERP_KERNEL::Exception("DataArrayInt::buildExplicitArrByRanges : DataArrayInt pointer in input is NULL !");
10197 if(getNumberOfComponents()!=1)
10198 throw INTERP_KERNEL::Exception("DataArrayInt::buildExplicitArrByRanges : only single component allowed !");
10199 offsets->checkAllocated();
10200 if(offsets->getNumberOfComponents()!=1)
10201 throw INTERP_KERNEL::Exception("DataArrayInt::buildExplicitArrByRanges : input array should have only single component !");
10202 int othNbTuples=offsets->getNumberOfTuples()-1;
10203 int nbOfTuples=getNumberOfTuples();
10204 int retNbOftuples=0;
10205 const int *work=getConstPointer();
10206 const int *offPtr=offsets->getConstPointer();
10207 for(int i=0;i<nbOfTuples;i++)
10210 if(val>=0 && val<othNbTuples)
10212 int delta=offPtr[val+1]-offPtr[val];
10214 retNbOftuples+=delta;
10217 std::ostringstream oss; oss << "DataArrayInt::buildExplicitArrByRanges : Tuple #" << val << " of offset array has a delta < 0 !";
10218 throw INTERP_KERNEL::Exception(oss.str().c_str());
10223 std::ostringstream oss; oss << "DataArrayInt::buildExplicitArrByRanges : Tuple #" << i << " in this contains " << val;
10224 oss << " whereas offsets array is of size " << othNbTuples+1 << " !";
10225 throw INTERP_KERNEL::Exception(oss.str().c_str());
10228 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
10229 ret->alloc(retNbOftuples,1);
10230 int *retPtr=ret->getPointer();
10231 for(int i=0;i<nbOfTuples;i++)
10234 int start=offPtr[val];
10235 int off=offPtr[val+1]-start;
10236 for(int j=0;j<off;j++,retPtr++)
10243 * Returns a new DataArrayInt whose contents is computed using \a this that must be a
10244 * scaled array (monotonically increasing).
10245 from that of \a this and \a
10246 * offsets arrays as follows. \a offsets is a one-dimensional array considered as an
10247 * "index" array of a "iota" array, thus, whose each element gives an index of a group
10248 * beginning within the "iota" array. And \a this is a one-dimensional array
10249 * considered as a selector of groups described by \a offsets to include into the result array.
10250 * \throw If \a is NULL.
10251 * \throw If \a this is not allocated.
10252 * \throw If \a this->getNumberOfComponents() != 1.
10253 * \throw If \a this->getNumberOfTuples() == 0.
10254 * \throw If \a this is not monotonically increasing.
10255 * \throw If any element of ids in ( \a bg \a stop \a step ) points outside the scale in \a this.
10258 * - \a bg , \a stop and \a step : (0,5,2)
10259 * - \a this: [0,3,6,10,14,20]
10260 * - result array: [0,0,0, 2,2,2,2, 4,4,4,4,4,4] == <br>
10262 DataArrayInt *DataArrayInt::buildExplicitArrOfSliceOnScaledArr(int bg, int stop, int step) const
10265 throw INTERP_KERNEL::Exception("DataArrayInt::buildExplicitArrOfSliceOnScaledArr : not allocated array !");
10266 if(getNumberOfComponents()!=1)
10267 throw INTERP_KERNEL::Exception("DataArrayInt::buildExplicitArrOfSliceOnScaledArr : number of components is expected to be equal to one !");
10268 int nbOfTuples(getNumberOfTuples());
10270 throw INTERP_KERNEL::Exception("DataArrayInt::buildExplicitArrOfSliceOnScaledArr : number of tuples must be != 0 !");
10271 const int *ids(begin());
10272 int nbOfEltsInSlc(GetNumberOfItemGivenBESRelative(bg,stop,step,"DataArrayInt::buildExplicitArrOfSliceOnScaledArr")),sz(0),pos(bg);
10273 for(int i=0;i<nbOfEltsInSlc;i++,pos+=step)
10275 if(pos>=0 && pos<nbOfTuples-1)
10277 int delta(ids[pos+1]-ids[pos]);
10281 std::ostringstream oss; oss << "DataArrayInt::buildExplicitArrOfSliceOnScaledArr : At pos #" << i << " of input slice, value is " << pos << " and at this pos this is not monotonically increasing !";
10282 throw INTERP_KERNEL::Exception(oss.str().c_str());
10287 std::ostringstream oss; oss << "DataArrayInt::buildExplicitArrOfSliceOnScaledArr : At pos #" << i << " of input slice, value is " << pos << " should be in [0," << nbOfTuples-1 << ") !";
10288 throw INTERP_KERNEL::Exception(oss.str().c_str());
10291 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(sz,1);
10292 int *retPtr(ret->getPointer());
10294 for(int i=0;i<nbOfEltsInSlc;i++,pos+=step)
10296 int delta(ids[pos+1]-ids[pos]);
10297 for(int j=0;j<delta;j++,retPtr++)
10304 * Given in input ranges \a ranges, it returns a newly allocated DataArrayInt instance having one component and the same number of tuples than \a this.
10305 * For each tuple at place **i** in \a this it tells which is the first range in \a ranges that contains value \c this->getIJ(i,0) and put the result
10306 * in tuple **i** of returned DataArrayInt.
10307 * If ranges overlapped (in theory it should not) this method do not detect it and always returns the first range.
10309 * For example if \a this contains : [1,24,7,8,10,17] and \a ranges contains [(0,3),(3,8),(8,15),(15,22),(22,30)]
10310 * The return DataArrayInt will contain : **[0,4,1,2,2,3]**
10312 * \param [in] ranges typically come from output of MEDCouplingUMesh::ComputeRangesFromTypeDistribution. Each range is specified like this : 1st component is
10313 * for lower value included and 2nd component is the upper value of corresponding range **excluded**.
10314 * \throw If offsets is a null pointer or does not have 2 components or if \a this is not allocated or \a this do not have exactly one component. To finish an exception
10315 * is thrown if no ranges in \a ranges contains value in \a this.
10317 * \sa DataArrayInt::findIdInRangeForEachTuple
10319 DataArrayInt *DataArrayInt::findRangeIdForEachTuple(const DataArrayInt *ranges) const
10322 throw INTERP_KERNEL::Exception("DataArrayInt::findRangeIdForEachTuple : null input pointer !");
10323 if(ranges->getNumberOfComponents()!=2)
10324 throw INTERP_KERNEL::Exception("DataArrayInt::findRangeIdForEachTuple : input DataArrayInt instance should have 2 components !");
10326 if(getNumberOfComponents()!=1)
10327 throw INTERP_KERNEL::Exception("DataArrayInt::findRangeIdForEachTuple : this should have only one component !");
10328 int nbTuples=getNumberOfTuples();
10329 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New(); ret->alloc(nbTuples,1);
10330 int nbOfRanges=ranges->getNumberOfTuples();
10331 const int *rangesPtr=ranges->getConstPointer();
10332 int *retPtr=ret->getPointer();
10333 const int *inPtr=getConstPointer();
10334 for(int i=0;i<nbTuples;i++,retPtr++)
10338 for(int j=0;j<nbOfRanges && !found;j++)
10339 if(val>=rangesPtr[2*j] && val<rangesPtr[2*j+1])
10340 { *retPtr=j; found=true; }
10345 std::ostringstream oss; oss << "DataArrayInt::findRangeIdForEachTuple : tuple #" << i << " not found by any ranges !";
10346 throw INTERP_KERNEL::Exception(oss.str().c_str());
10353 * Given in input ranges \a ranges, it returns a newly allocated DataArrayInt instance having one component and the same number of tuples than \a this.
10354 * For each tuple at place **i** in \a this it tells which is the sub position of the first range in \a ranges that contains value \c this->getIJ(i,0) and put the result
10355 * in tuple **i** of returned DataArrayInt.
10356 * If ranges overlapped (in theory it should not) this method do not detect it and always returns the sub position of the first range.
10358 * For example if \a this contains : [1,24,7,8,10,17] and \a ranges contains [(0,3),(3,8),(8,15),(15,22),(22,30)]
10359 * The return DataArrayInt will contain : **[1,2,4,0,2,2]**
10360 * This method is often called in pair with DataArrayInt::findRangeIdForEachTuple method.
10362 * \param [in] ranges typically come from output of MEDCouplingUMesh::ComputeRangesFromTypeDistribution. Each range is specified like this : 1st component is
10363 * for lower value included and 2nd component is the upper value of corresponding range **excluded**.
10364 * \throw If offsets is a null pointer or does not have 2 components or if \a this is not allocated or \a this do not have exactly one component. To finish an exception
10365 * is thrown if no ranges in \a ranges contains value in \a this.
10366 * \sa DataArrayInt::findRangeIdForEachTuple
10368 DataArrayInt *DataArrayInt::findIdInRangeForEachTuple(const DataArrayInt *ranges) const
10371 throw INTERP_KERNEL::Exception("DataArrayInt::findIdInRangeForEachTuple : null input pointer !");
10372 if(ranges->getNumberOfComponents()!=2)
10373 throw INTERP_KERNEL::Exception("DataArrayInt::findIdInRangeForEachTuple : input DataArrayInt instance should have 2 components !");
10375 if(getNumberOfComponents()!=1)
10376 throw INTERP_KERNEL::Exception("DataArrayInt::findIdInRangeForEachTuple : this should have only one component !");
10377 int nbTuples=getNumberOfTuples();
10378 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New(); ret->alloc(nbTuples,1);
10379 int nbOfRanges=ranges->getNumberOfTuples();
10380 const int *rangesPtr=ranges->getConstPointer();
10381 int *retPtr=ret->getPointer();
10382 const int *inPtr=getConstPointer();
10383 for(int i=0;i<nbTuples;i++,retPtr++)
10387 for(int j=0;j<nbOfRanges && !found;j++)
10388 if(val>=rangesPtr[2*j] && val<rangesPtr[2*j+1])
10389 { *retPtr=val-rangesPtr[2*j]; found=true; }
10394 std::ostringstream oss; oss << "DataArrayInt::findIdInRangeForEachTuple : tuple #" << i << " not found by any ranges !";
10395 throw INTERP_KERNEL::Exception(oss.str().c_str());
10402 * \b WARNING this method is a \b non \a const \b method. This method works tuple by tuple. Each tuple is expected to be pairs (number of components must be equal to 2).
10403 * This method rearrange each pair in \a this so that, tuple with id \b tid will be after the call \c this->getIJ(tid,0)==this->getIJ(tid-1,1) and \c this->getIJ(tid,1)==this->getIJ(tid+1,0).
10404 * If it is impossible to reach such condition an exception will be thrown ! \b WARNING In case of throw \a this can be partially modified !
10405 * If this method has correctly worked, \a this will be able to be considered as a linked list.
10406 * This method does nothing if number of tuples is lower of equal to 1.
10408 * This method is useful for users having an unstructured mesh having only SEG2 to rearrange internaly the connectibity without any coordinates consideration.
10410 * \sa MEDCouplingUMesh::orderConsecutiveCells1D
10412 void DataArrayInt::sortEachPairToMakeALinkedList()
10415 if(getNumberOfComponents()!=2)
10416 throw INTERP_KERNEL::Exception("DataArrayInt::sortEachPairToMakeALinkedList : Only works on DataArrayInt instance with nb of components equal to 2 !");
10417 int nbOfTuples(getNumberOfTuples());
10420 int *conn(getPointer());
10421 for(int i=1;i<nbOfTuples;i++,conn+=2)
10425 if(conn[2]==conn[3])
10427 std::ostringstream oss; oss << "DataArrayInt::sortEachPairToMakeALinkedList : In the tuple #" << i << " presence of a pair filled with same ids !";
10428 throw INTERP_KERNEL::Exception(oss.str().c_str());
10430 if(conn[2]!=conn[1] && conn[3]==conn[1] && conn[2]!=conn[0])
10431 std::swap(conn[2],conn[3]);
10432 //not(conn[2]==conn[1] && conn[3]!=conn[1] && conn[3]!=conn[0])
10433 if(conn[2]!=conn[1] || conn[3]==conn[1] || conn[3]==conn[0])
10435 std::ostringstream oss; oss << "DataArrayInt::sortEachPairToMakeALinkedList : In the tuple #" << i << " something is invalid !";
10436 throw INTERP_KERNEL::Exception(oss.str().c_str());
10441 if(conn[0]==conn[1] || conn[2]==conn[3])
10442 throw INTERP_KERNEL::Exception("DataArrayInt::sortEachPairToMakeALinkedList : In the 2 first tuples presence of a pair filled with same ids !");
10445 s.insert(conn,conn+4);
10447 throw INTERP_KERNEL::Exception("DataArrayInt::sortEachPairToMakeALinkedList : This can't be considered as a linked list regarding 2 first tuples !");
10448 if(std::count(conn,conn+4,conn[0])==2)
10453 if(conn[2]==conn[0])
10454 { tmp[3]=conn[3]; }
10457 std::copy(tmp,tmp+4,conn);
10465 * \param [in] nbTimes specifies the nb of times each tuples in \a this will be duplicated contiguouly in returned DataArrayInt instance.
10466 * \a nbTimes should be at least equal to 1.
10467 * \return a newly allocated DataArrayInt having one component and number of tuples equal to \a nbTimes * \c this->getNumberOfTuples.
10468 * \throw if \a this is not allocated or if \a this has not number of components set to one or if \a nbTimes is lower than 1.
10470 DataArrayInt *DataArrayInt::duplicateEachTupleNTimes(int nbTimes) const
10473 if(getNumberOfComponents()!=1)
10474 throw INTERP_KERNEL::Exception("DataArrayInt::duplicateEachTupleNTimes : this should have only one component !");
10476 throw INTERP_KERNEL::Exception("DataArrayInt::duplicateEachTupleNTimes : nb times should be >= 1 !");
10477 int nbTuples=getNumberOfTuples();
10478 const int *inPtr=getConstPointer();
10479 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New(); ret->alloc(nbTimes*nbTuples,1);
10480 int *retPtr=ret->getPointer();
10481 for(int i=0;i<nbTuples;i++,inPtr++)
10484 for(int j=0;j<nbTimes;j++,retPtr++)
10487 ret->copyStringInfoFrom(*this);
10492 * This method returns all different values found in \a this. This method throws if \a this has not been allocated.
10493 * But the number of components can be different from one.
10494 * \return a newly allocated array (that should be dealt by the caller) containing different values in \a this.
10496 DataArrayInt *DataArrayInt::getDifferentValues() const
10500 ret.insert(begin(),end());
10501 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret2=DataArrayInt::New(); ret2->alloc((int)ret.size(),1);
10502 std::copy(ret.begin(),ret.end(),ret2->getPointer());
10503 return ret2.retn();
10507 * This method is a refinement of DataArrayInt::getDifferentValues because it returns not only different values in \a this but also, for each of
10508 * them it tells which tuple id have this id.
10509 * This method works only on arrays with one component (if it is not the case call DataArrayInt::rearrange(1) ).
10510 * This method returns two arrays having same size.
10511 * The instances of DataArrayInt in the returned vector have be specially allocated and computed by this method. Each of them should be dealt by the caller of this method.
10512 * Example : if this is equal to [1,0,1,2,0,2,2,-3,2] -> differentIds=[-3,0,1,2] and returned array will be equal to [[7],[1,4],[0,2],[3,5,6,8]]
10514 std::vector<DataArrayInt *> DataArrayInt::partitionByDifferentValues(std::vector<int>& differentIds) const
10517 if(getNumberOfComponents()!=1)
10518 throw INTERP_KERNEL::Exception("DataArrayInt::partitionByDifferentValues : this should have only one component !");
10520 std::map<int,int> m,m2,m3;
10521 for(const int *w=begin();w!=end();w++)
10523 differentIds.resize(m.size());
10524 std::vector<DataArrayInt *> ret(m.size());
10525 std::vector<int *> retPtr(m.size());
10526 for(std::map<int,int>::const_iterator it=m.begin();it!=m.end();it++,id++)
10528 m2[(*it).first]=id;
10529 ret[id]=DataArrayInt::New();
10530 ret[id]->alloc((*it).second,1);
10531 retPtr[id]=ret[id]->getPointer();
10532 differentIds[id]=(*it).first;
10535 for(const int *w=begin();w!=end();w++,id++)
10537 retPtr[m2[*w]][m3[*w]++]=id;
10543 * This method split ids in [0, \c this->getNumberOfTuples() ) using \a this array as a field of weight (>=0 each).
10544 * The aim of this method is to return a set of \a nbOfSlices chunk of contiguous ids as balanced as possible.
10546 * \param [in] nbOfSlices - number of slices expected.
10547 * \return - a vector having a size equal to \a nbOfSlices giving the start (included) and the stop (excluded) of each chunks.
10549 * \sa DataArray::GetSlice
10550 * \throw If \a this is not allocated or not with exactly one component.
10551 * \throw If an element in \a this if < 0.
10553 std::vector< std::pair<int,int> > DataArrayInt::splitInBalancedSlices(int nbOfSlices) const
10555 if(!isAllocated() || getNumberOfComponents()!=1)
10556 throw INTERP_KERNEL::Exception("DataArrayInt::splitInBalancedSlices : this array should have number of components equal to one and must be allocated !");
10558 throw INTERP_KERNEL::Exception("DataArrayInt::splitInBalancedSlices : number of slices must be >= 1 !");
10559 int sum(accumulate(0)),nbOfTuples(getNumberOfTuples());
10560 int sumPerSlc(sum/nbOfSlices),pos(0);
10561 const int *w(begin());
10562 std::vector< std::pair<int,int> > ret(nbOfSlices);
10563 for(int i=0;i<nbOfSlices;i++)
10565 std::pair<int,int> p(pos,-1);
10567 while(locSum<sumPerSlc && pos<nbOfTuples) { pos++; locSum+=*w++; }
10568 if(i!=nbOfSlices-1)
10571 p.second=nbOfTuples;
10578 * Returns a new DataArrayInt that is a sum of two given arrays. There are 3
10580 * 1. The arrays have same number of tuples and components. Then each value of
10581 * the result array (_a_) is a sum of the corresponding values of \a a1 and \a a2,
10582 * i.e.: _a_ [ i, j ] = _a1_ [ i, j ] + _a2_ [ i, j ].
10583 * 2. The arrays have same number of tuples and one array, say _a2_, has one
10585 * _a_ [ i, j ] = _a1_ [ i, j ] + _a2_ [ i, 0 ].
10586 * 3. The arrays have same number of components and one array, say _a2_, has one
10588 * _a_ [ i, j ] = _a1_ [ i, j ] + _a2_ [ 0, j ].
10590 * Info on components is copied either from the first array (in the first case) or from
10591 * the array with maximal number of elements (getNbOfElems()).
10592 * \param [in] a1 - an array to sum up.
10593 * \param [in] a2 - another array to sum up.
10594 * \return DataArrayInt * - the new instance of DataArrayInt.
10595 * The caller is to delete this result array using decrRef() as it is no more
10597 * \throw If either \a a1 or \a a2 is NULL.
10598 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples() and
10599 * \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents() and
10600 * none of them has number of tuples or components equal to 1.
10602 DataArrayInt *DataArrayInt::Add(const DataArrayInt *a1, const DataArrayInt *a2)
10605 throw INTERP_KERNEL::Exception("DataArrayInt::Add : input DataArrayInt instance is NULL !");
10606 int nbOfTuple=a1->getNumberOfTuples();
10607 int nbOfTuple2=a2->getNumberOfTuples();
10608 int nbOfComp=a1->getNumberOfComponents();
10609 int nbOfComp2=a2->getNumberOfComponents();
10610 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=0;
10611 if(nbOfTuple==nbOfTuple2)
10613 if(nbOfComp==nbOfComp2)
10615 ret=DataArrayInt::New();
10616 ret->alloc(nbOfTuple,nbOfComp);
10617 std::transform(a1->begin(),a1->end(),a2->begin(),ret->getPointer(),std::plus<int>());
10618 ret->copyStringInfoFrom(*a1);
10622 int nbOfCompMin,nbOfCompMax;
10623 const DataArrayInt *aMin, *aMax;
10624 if(nbOfComp>nbOfComp2)
10626 nbOfCompMin=nbOfComp2; nbOfCompMax=nbOfComp;
10631 nbOfCompMin=nbOfComp; nbOfCompMax=nbOfComp2;
10636 ret=DataArrayInt::New();
10637 ret->alloc(nbOfTuple,nbOfCompMax);
10638 const int *aMinPtr=aMin->getConstPointer();
10639 const int *aMaxPtr=aMax->getConstPointer();
10640 int *res=ret->getPointer();
10641 for(int i=0;i<nbOfTuple;i++)
10642 res=std::transform(aMaxPtr+i*nbOfCompMax,aMaxPtr+(i+1)*nbOfCompMax,res,std::bind2nd(std::plus<int>(),aMinPtr[i]));
10643 ret->copyStringInfoFrom(*aMax);
10646 throw INTERP_KERNEL::Exception("Nb of components mismatch for array Add !");
10649 else if((nbOfTuple==1 && nbOfTuple2>1) || (nbOfTuple>1 && nbOfTuple2==1))
10651 if(nbOfComp==nbOfComp2)
10653 int nbOfTupleMax=std::max(nbOfTuple,nbOfTuple2);
10654 const DataArrayInt *aMin=nbOfTuple>nbOfTuple2?a2:a1;
10655 const DataArrayInt *aMax=nbOfTuple>nbOfTuple2?a1:a2;
10656 const int *aMinPtr=aMin->getConstPointer(),*aMaxPtr=aMax->getConstPointer();
10657 ret=DataArrayInt::New();
10658 ret->alloc(nbOfTupleMax,nbOfComp);
10659 int *res=ret->getPointer();
10660 for(int i=0;i<nbOfTupleMax;i++)
10661 res=std::transform(aMaxPtr+i*nbOfComp,aMaxPtr+(i+1)*nbOfComp,aMinPtr,res,std::plus<int>());
10662 ret->copyStringInfoFrom(*aMax);
10665 throw INTERP_KERNEL::Exception("Nb of components mismatch for array Add !");
10668 throw INTERP_KERNEL::Exception("Nb of tuples mismatch for array Add !");
10673 * Adds values of another DataArrayInt to values of \a this one. There are 3
10675 * 1. The arrays have same number of tuples and components. Then each value of
10676 * \a other array is added to the corresponding value of \a this array, i.e.:
10677 * _a_ [ i, j ] += _other_ [ i, j ].
10678 * 2. The arrays have same number of tuples and \a other array has one component. Then
10679 * _a_ [ i, j ] += _other_ [ i, 0 ].
10680 * 3. The arrays have same number of components and \a other array has one tuple. Then
10681 * _a_ [ i, j ] += _a2_ [ 0, j ].
10683 * \param [in] other - an array to add to \a this one.
10684 * \throw If \a other is NULL.
10685 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples() and
10686 * \a this->getNumberOfComponents() != \a other->getNumberOfComponents() and
10687 * \a other has number of both tuples and components not equal to 1.
10689 void DataArrayInt::addEqual(const DataArrayInt *other)
10692 throw INTERP_KERNEL::Exception("DataArrayInt::addEqual : input DataArrayInt instance is NULL !");
10693 const char *msg="Nb of tuples mismatch for DataArrayInt::addEqual !";
10694 checkAllocated(); other->checkAllocated();
10695 int nbOfTuple=getNumberOfTuples();
10696 int nbOfTuple2=other->getNumberOfTuples();
10697 int nbOfComp=getNumberOfComponents();
10698 int nbOfComp2=other->getNumberOfComponents();
10699 if(nbOfTuple==nbOfTuple2)
10701 if(nbOfComp==nbOfComp2)
10703 std::transform(begin(),end(),other->begin(),getPointer(),std::plus<int>());
10705 else if(nbOfComp2==1)
10707 int *ptr=getPointer();
10708 const int *ptrc=other->getConstPointer();
10709 for(int i=0;i<nbOfTuple;i++)
10710 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptr+i*nbOfComp,std::bind2nd(std::plus<int>(),*ptrc++));
10713 throw INTERP_KERNEL::Exception(msg);
10715 else if(nbOfTuple2==1)
10717 if(nbOfComp2==nbOfComp)
10719 int *ptr=getPointer();
10720 const int *ptrc=other->getConstPointer();
10721 for(int i=0;i<nbOfTuple;i++)
10722 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptrc,ptr+i*nbOfComp,std::plus<int>());
10725 throw INTERP_KERNEL::Exception(msg);
10728 throw INTERP_KERNEL::Exception(msg);
10733 * Returns a new DataArrayInt that is a subtraction of two given arrays. There are 3
10735 * 1. The arrays have same number of tuples and components. Then each value of
10736 * the result array (_a_) is a subtraction of the corresponding values of \a a1 and
10737 * \a a2, i.e.: _a_ [ i, j ] = _a1_ [ i, j ] - _a2_ [ i, j ].
10738 * 2. The arrays have same number of tuples and one array, say _a2_, has one
10740 * _a_ [ i, j ] = _a1_ [ i, j ] - _a2_ [ i, 0 ].
10741 * 3. The arrays have same number of components and one array, say _a2_, has one
10743 * _a_ [ i, j ] = _a1_ [ i, j ] - _a2_ [ 0, j ].
10745 * Info on components is copied either from the first array (in the first case) or from
10746 * the array with maximal number of elements (getNbOfElems()).
10747 * \param [in] a1 - an array to subtract from.
10748 * \param [in] a2 - an array to subtract.
10749 * \return DataArrayInt * - the new instance of DataArrayInt.
10750 * The caller is to delete this result array using decrRef() as it is no more
10752 * \throw If either \a a1 or \a a2 is NULL.
10753 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples() and
10754 * \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents() and
10755 * none of them has number of tuples or components equal to 1.
10757 DataArrayInt *DataArrayInt::Substract(const DataArrayInt *a1, const DataArrayInt *a2)
10760 throw INTERP_KERNEL::Exception("DataArrayInt::Substract : input DataArrayInt instance is NULL !");
10761 int nbOfTuple1=a1->getNumberOfTuples();
10762 int nbOfTuple2=a2->getNumberOfTuples();
10763 int nbOfComp1=a1->getNumberOfComponents();
10764 int nbOfComp2=a2->getNumberOfComponents();
10765 if(nbOfTuple2==nbOfTuple1)
10767 if(nbOfComp1==nbOfComp2)
10769 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
10770 ret->alloc(nbOfTuple2,nbOfComp1);
10771 std::transform(a1->begin(),a1->end(),a2->begin(),ret->getPointer(),std::minus<int>());
10772 ret->copyStringInfoFrom(*a1);
10775 else if(nbOfComp2==1)
10777 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
10778 ret->alloc(nbOfTuple1,nbOfComp1);
10779 const int *a2Ptr=a2->getConstPointer();
10780 const int *a1Ptr=a1->getConstPointer();
10781 int *res=ret->getPointer();
10782 for(int i=0;i<nbOfTuple1;i++)
10783 res=std::transform(a1Ptr+i*nbOfComp1,a1Ptr+(i+1)*nbOfComp1,res,std::bind2nd(std::minus<int>(),a2Ptr[i]));
10784 ret->copyStringInfoFrom(*a1);
10789 a1->checkNbOfComps(nbOfComp2,"Nb of components mismatch for array Substract !");
10793 else if(nbOfTuple2==1)
10795 a1->checkNbOfComps(nbOfComp2,"Nb of components mismatch for array Substract !");
10796 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
10797 ret->alloc(nbOfTuple1,nbOfComp1);
10798 const int *a1ptr=a1->getConstPointer(),*a2ptr=a2->getConstPointer();
10799 int *pt=ret->getPointer();
10800 for(int i=0;i<nbOfTuple1;i++)
10801 pt=std::transform(a1ptr+i*nbOfComp1,a1ptr+(i+1)*nbOfComp1,a2ptr,pt,std::minus<int>());
10802 ret->copyStringInfoFrom(*a1);
10807 a1->checkNbOfTuples(nbOfTuple2,"Nb of tuples mismatch for array Substract !");//will always throw an exception
10813 * Subtract values of another DataArrayInt from values of \a this one. There are 3
10815 * 1. The arrays have same number of tuples and components. Then each value of
10816 * \a other array is subtracted from the corresponding value of \a this array, i.e.:
10817 * _a_ [ i, j ] -= _other_ [ i, j ].
10818 * 2. The arrays have same number of tuples and \a other array has one component. Then
10819 * _a_ [ i, j ] -= _other_ [ i, 0 ].
10820 * 3. The arrays have same number of components and \a other array has one tuple. Then
10821 * _a_ [ i, j ] -= _a2_ [ 0, j ].
10823 * \param [in] other - an array to subtract from \a this one.
10824 * \throw If \a other is NULL.
10825 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples() and
10826 * \a this->getNumberOfComponents() != \a other->getNumberOfComponents() and
10827 * \a other has number of both tuples and components not equal to 1.
10829 void DataArrayInt::substractEqual(const DataArrayInt *other)
10832 throw INTERP_KERNEL::Exception("DataArrayInt::substractEqual : input DataArrayInt instance is NULL !");
10833 const char *msg="Nb of tuples mismatch for DataArrayInt::substractEqual !";
10834 checkAllocated(); other->checkAllocated();
10835 int nbOfTuple=getNumberOfTuples();
10836 int nbOfTuple2=other->getNumberOfTuples();
10837 int nbOfComp=getNumberOfComponents();
10838 int nbOfComp2=other->getNumberOfComponents();
10839 if(nbOfTuple==nbOfTuple2)
10841 if(nbOfComp==nbOfComp2)
10843 std::transform(begin(),end(),other->begin(),getPointer(),std::minus<int>());
10845 else if(nbOfComp2==1)
10847 int *ptr=getPointer();
10848 const int *ptrc=other->getConstPointer();
10849 for(int i=0;i<nbOfTuple;i++)
10850 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptr+i*nbOfComp,std::bind2nd(std::minus<int>(),*ptrc++));
10853 throw INTERP_KERNEL::Exception(msg);
10855 else if(nbOfTuple2==1)
10857 int *ptr=getPointer();
10858 const int *ptrc=other->getConstPointer();
10859 for(int i=0;i<nbOfTuple;i++)
10860 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptrc,ptr+i*nbOfComp,std::minus<int>());
10863 throw INTERP_KERNEL::Exception(msg);
10868 * Returns a new DataArrayInt that is a product of two given arrays. There are 3
10870 * 1. The arrays have same number of tuples and components. Then each value of
10871 * the result array (_a_) is a product of the corresponding values of \a a1 and
10872 * \a a2, i.e.: _a_ [ i, j ] = _a1_ [ i, j ] * _a2_ [ i, j ].
10873 * 2. The arrays have same number of tuples and one array, say _a2_, has one
10875 * _a_ [ i, j ] = _a1_ [ i, j ] * _a2_ [ i, 0 ].
10876 * 3. The arrays have same number of components and one array, say _a2_, has one
10878 * _a_ [ i, j ] = _a1_ [ i, j ] * _a2_ [ 0, j ].
10880 * Info on components is copied either from the first array (in the first case) or from
10881 * the array with maximal number of elements (getNbOfElems()).
10882 * \param [in] a1 - a factor array.
10883 * \param [in] a2 - another factor array.
10884 * \return DataArrayInt * - the new instance of DataArrayInt.
10885 * The caller is to delete this result array using decrRef() as it is no more
10887 * \throw If either \a a1 or \a a2 is NULL.
10888 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples() and
10889 * \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents() and
10890 * none of them has number of tuples or components equal to 1.
10892 DataArrayInt *DataArrayInt::Multiply(const DataArrayInt *a1, const DataArrayInt *a2)
10895 throw INTERP_KERNEL::Exception("DataArrayInt::Multiply : input DataArrayInt instance is NULL !");
10896 int nbOfTuple=a1->getNumberOfTuples();
10897 int nbOfTuple2=a2->getNumberOfTuples();
10898 int nbOfComp=a1->getNumberOfComponents();
10899 int nbOfComp2=a2->getNumberOfComponents();
10900 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=0;
10901 if(nbOfTuple==nbOfTuple2)
10903 if(nbOfComp==nbOfComp2)
10905 ret=DataArrayInt::New();
10906 ret->alloc(nbOfTuple,nbOfComp);
10907 std::transform(a1->begin(),a1->end(),a2->begin(),ret->getPointer(),std::multiplies<int>());
10908 ret->copyStringInfoFrom(*a1);
10912 int nbOfCompMin,nbOfCompMax;
10913 const DataArrayInt *aMin, *aMax;
10914 if(nbOfComp>nbOfComp2)
10916 nbOfCompMin=nbOfComp2; nbOfCompMax=nbOfComp;
10921 nbOfCompMin=nbOfComp; nbOfCompMax=nbOfComp2;
10926 ret=DataArrayInt::New();
10927 ret->alloc(nbOfTuple,nbOfCompMax);
10928 const int *aMinPtr=aMin->getConstPointer();
10929 const int *aMaxPtr=aMax->getConstPointer();
10930 int *res=ret->getPointer();
10931 for(int i=0;i<nbOfTuple;i++)
10932 res=std::transform(aMaxPtr+i*nbOfCompMax,aMaxPtr+(i+1)*nbOfCompMax,res,std::bind2nd(std::multiplies<int>(),aMinPtr[i]));
10933 ret->copyStringInfoFrom(*aMax);
10936 throw INTERP_KERNEL::Exception("Nb of components mismatch for array Multiply !");
10939 else if((nbOfTuple==1 && nbOfTuple2>1) || (nbOfTuple>1 && nbOfTuple2==1))
10941 if(nbOfComp==nbOfComp2)
10943 int nbOfTupleMax=std::max(nbOfTuple,nbOfTuple2);
10944 const DataArrayInt *aMin=nbOfTuple>nbOfTuple2?a2:a1;
10945 const DataArrayInt *aMax=nbOfTuple>nbOfTuple2?a1:a2;
10946 const int *aMinPtr=aMin->getConstPointer(),*aMaxPtr=aMax->getConstPointer();
10947 ret=DataArrayInt::New();
10948 ret->alloc(nbOfTupleMax,nbOfComp);
10949 int *res=ret->getPointer();
10950 for(int i=0;i<nbOfTupleMax;i++)
10951 res=std::transform(aMaxPtr+i*nbOfComp,aMaxPtr+(i+1)*nbOfComp,aMinPtr,res,std::multiplies<int>());
10952 ret->copyStringInfoFrom(*aMax);
10955 throw INTERP_KERNEL::Exception("Nb of components mismatch for array Multiply !");
10958 throw INTERP_KERNEL::Exception("Nb of tuples mismatch for array Multiply !");
10964 * Multiply values of another DataArrayInt to values of \a this one. There are 3
10966 * 1. The arrays have same number of tuples and components. Then each value of
10967 * \a other array is multiplied to the corresponding value of \a this array, i.e.:
10968 * _a_ [ i, j ] *= _other_ [ i, j ].
10969 * 2. The arrays have same number of tuples and \a other array has one component. Then
10970 * _a_ [ i, j ] *= _other_ [ i, 0 ].
10971 * 3. The arrays have same number of components and \a other array has one tuple. Then
10972 * _a_ [ i, j ] *= _a2_ [ 0, j ].
10974 * \param [in] other - an array to multiply to \a this one.
10975 * \throw If \a other is NULL.
10976 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples() and
10977 * \a this->getNumberOfComponents() != \a other->getNumberOfComponents() and
10978 * \a other has number of both tuples and components not equal to 1.
10980 void DataArrayInt::multiplyEqual(const DataArrayInt *other)
10983 throw INTERP_KERNEL::Exception("DataArrayInt::multiplyEqual : input DataArrayInt instance is NULL !");
10984 const char *msg="Nb of tuples mismatch for DataArrayInt::multiplyEqual !";
10985 checkAllocated(); other->checkAllocated();
10986 int nbOfTuple=getNumberOfTuples();
10987 int nbOfTuple2=other->getNumberOfTuples();
10988 int nbOfComp=getNumberOfComponents();
10989 int nbOfComp2=other->getNumberOfComponents();
10990 if(nbOfTuple==nbOfTuple2)
10992 if(nbOfComp==nbOfComp2)
10994 std::transform(begin(),end(),other->begin(),getPointer(),std::multiplies<int>());
10996 else if(nbOfComp2==1)
10998 int *ptr=getPointer();
10999 const int *ptrc=other->getConstPointer();
11000 for(int i=0;i<nbOfTuple;i++)
11001 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptr+i*nbOfComp,std::bind2nd(std::multiplies<int>(),*ptrc++));
11004 throw INTERP_KERNEL::Exception(msg);
11006 else if(nbOfTuple2==1)
11008 if(nbOfComp2==nbOfComp)
11010 int *ptr=getPointer();
11011 const int *ptrc=other->getConstPointer();
11012 for(int i=0;i<nbOfTuple;i++)
11013 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptrc,ptr+i*nbOfComp,std::multiplies<int>());
11016 throw INTERP_KERNEL::Exception(msg);
11019 throw INTERP_KERNEL::Exception(msg);
11025 * Returns a new DataArrayInt that is a division of two given arrays. There are 3
11027 * 1. The arrays have same number of tuples and components. Then each value of
11028 * the result array (_a_) is a division of the corresponding values of \a a1 and
11029 * \a a2, i.e.: _a_ [ i, j ] = _a1_ [ i, j ] / _a2_ [ i, j ].
11030 * 2. The arrays have same number of tuples and one array, say _a2_, has one
11032 * _a_ [ i, j ] = _a1_ [ i, j ] / _a2_ [ i, 0 ].
11033 * 3. The arrays have same number of components and one array, say _a2_, has one
11035 * _a_ [ i, j ] = _a1_ [ i, j ] / _a2_ [ 0, j ].
11037 * Info on components is copied either from the first array (in the first case) or from
11038 * the array with maximal number of elements (getNbOfElems()).
11039 * \warning No check of division by zero is performed!
11040 * \param [in] a1 - a numerator array.
11041 * \param [in] a2 - a denominator array.
11042 * \return DataArrayInt * - the new instance of DataArrayInt.
11043 * The caller is to delete this result array using decrRef() as it is no more
11045 * \throw If either \a a1 or \a a2 is NULL.
11046 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples() and
11047 * \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents() and
11048 * none of them has number of tuples or components equal to 1.
11050 DataArrayInt *DataArrayInt::Divide(const DataArrayInt *a1, const DataArrayInt *a2)
11053 throw INTERP_KERNEL::Exception("DataArrayInt::Divide : input DataArrayInt instance is NULL !");
11054 int nbOfTuple1=a1->getNumberOfTuples();
11055 int nbOfTuple2=a2->getNumberOfTuples();
11056 int nbOfComp1=a1->getNumberOfComponents();
11057 int nbOfComp2=a2->getNumberOfComponents();
11058 if(nbOfTuple2==nbOfTuple1)
11060 if(nbOfComp1==nbOfComp2)
11062 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
11063 ret->alloc(nbOfTuple2,nbOfComp1);
11064 std::transform(a1->begin(),a1->end(),a2->begin(),ret->getPointer(),std::divides<int>());
11065 ret->copyStringInfoFrom(*a1);
11068 else if(nbOfComp2==1)
11070 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
11071 ret->alloc(nbOfTuple1,nbOfComp1);
11072 const int *a2Ptr=a2->getConstPointer();
11073 const int *a1Ptr=a1->getConstPointer();
11074 int *res=ret->getPointer();
11075 for(int i=0;i<nbOfTuple1;i++)
11076 res=std::transform(a1Ptr+i*nbOfComp1,a1Ptr+(i+1)*nbOfComp1,res,std::bind2nd(std::divides<int>(),a2Ptr[i]));
11077 ret->copyStringInfoFrom(*a1);
11082 a1->checkNbOfComps(nbOfComp2,"Nb of components mismatch for array Divide !");
11086 else if(nbOfTuple2==1)
11088 a1->checkNbOfComps(nbOfComp2,"Nb of components mismatch for array Divide !");
11089 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
11090 ret->alloc(nbOfTuple1,nbOfComp1);
11091 const int *a1ptr=a1->getConstPointer(),*a2ptr=a2->getConstPointer();
11092 int *pt=ret->getPointer();
11093 for(int i=0;i<nbOfTuple1;i++)
11094 pt=std::transform(a1ptr+i*nbOfComp1,a1ptr+(i+1)*nbOfComp1,a2ptr,pt,std::divides<int>());
11095 ret->copyStringInfoFrom(*a1);
11100 a1->checkNbOfTuples(nbOfTuple2,"Nb of tuples mismatch for array Divide !");//will always throw an exception
11106 * Divide values of \a this array by values of another DataArrayInt. There are 3
11108 * 1. The arrays have same number of tuples and components. Then each value of
11109 * \a this array is divided by the corresponding value of \a other one, i.e.:
11110 * _a_ [ i, j ] /= _other_ [ i, j ].
11111 * 2. The arrays have same number of tuples and \a other array has one component. Then
11112 * _a_ [ i, j ] /= _other_ [ i, 0 ].
11113 * 3. The arrays have same number of components and \a other array has one tuple. Then
11114 * _a_ [ i, j ] /= _a2_ [ 0, j ].
11116 * \warning No check of division by zero is performed!
11117 * \param [in] other - an array to divide \a this one by.
11118 * \throw If \a other is NULL.
11119 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples() and
11120 * \a this->getNumberOfComponents() != \a other->getNumberOfComponents() and
11121 * \a other has number of both tuples and components not equal to 1.
11123 void DataArrayInt::divideEqual(const DataArrayInt *other)
11126 throw INTERP_KERNEL::Exception("DataArrayInt::divideEqual : input DataArrayInt instance is NULL !");
11127 const char *msg="Nb of tuples mismatch for DataArrayInt::divideEqual !";
11128 checkAllocated(); other->checkAllocated();
11129 int nbOfTuple=getNumberOfTuples();
11130 int nbOfTuple2=other->getNumberOfTuples();
11131 int nbOfComp=getNumberOfComponents();
11132 int nbOfComp2=other->getNumberOfComponents();
11133 if(nbOfTuple==nbOfTuple2)
11135 if(nbOfComp==nbOfComp2)
11137 std::transform(begin(),end(),other->begin(),getPointer(),std::divides<int>());
11139 else if(nbOfComp2==1)
11141 int *ptr=getPointer();
11142 const int *ptrc=other->getConstPointer();
11143 for(int i=0;i<nbOfTuple;i++)
11144 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptr+i*nbOfComp,std::bind2nd(std::divides<int>(),*ptrc++));
11147 throw INTERP_KERNEL::Exception(msg);
11149 else if(nbOfTuple2==1)
11151 if(nbOfComp2==nbOfComp)
11153 int *ptr=getPointer();
11154 const int *ptrc=other->getConstPointer();
11155 for(int i=0;i<nbOfTuple;i++)
11156 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptrc,ptr+i*nbOfComp,std::divides<int>());
11159 throw INTERP_KERNEL::Exception(msg);
11162 throw INTERP_KERNEL::Exception(msg);
11168 * Returns a new DataArrayInt that is a modulus of two given arrays. There are 3
11170 * 1. The arrays have same number of tuples and components. Then each value of
11171 * the result array (_a_) is a division of the corresponding values of \a a1 and
11172 * \a a2, i.e.: _a_ [ i, j ] = _a1_ [ i, j ] % _a2_ [ i, j ].
11173 * 2. The arrays have same number of tuples and one array, say _a2_, has one
11175 * _a_ [ i, j ] = _a1_ [ i, j ] % _a2_ [ i, 0 ].
11176 * 3. The arrays have same number of components and one array, say _a2_, has one
11178 * _a_ [ i, j ] = _a1_ [ i, j ] % _a2_ [ 0, j ].
11180 * Info on components is copied either from the first array (in the first case) or from
11181 * the array with maximal number of elements (getNbOfElems()).
11182 * \warning No check of division by zero is performed!
11183 * \param [in] a1 - a dividend array.
11184 * \param [in] a2 - a divisor array.
11185 * \return DataArrayInt * - the new instance of DataArrayInt.
11186 * The caller is to delete this result array using decrRef() as it is no more
11188 * \throw If either \a a1 or \a a2 is NULL.
11189 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples() and
11190 * \a a1->getNumberOfComponents() != \a a2->getNumberOfComponents() and
11191 * none of them has number of tuples or components equal to 1.
11193 DataArrayInt *DataArrayInt::Modulus(const DataArrayInt *a1, const DataArrayInt *a2)
11196 throw INTERP_KERNEL::Exception("DataArrayInt::Modulus : input DataArrayInt instance is NULL !");
11197 int nbOfTuple1=a1->getNumberOfTuples();
11198 int nbOfTuple2=a2->getNumberOfTuples();
11199 int nbOfComp1=a1->getNumberOfComponents();
11200 int nbOfComp2=a2->getNumberOfComponents();
11201 if(nbOfTuple2==nbOfTuple1)
11203 if(nbOfComp1==nbOfComp2)
11205 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
11206 ret->alloc(nbOfTuple2,nbOfComp1);
11207 std::transform(a1->begin(),a1->end(),a2->begin(),ret->getPointer(),std::modulus<int>());
11208 ret->copyStringInfoFrom(*a1);
11211 else if(nbOfComp2==1)
11213 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
11214 ret->alloc(nbOfTuple1,nbOfComp1);
11215 const int *a2Ptr=a2->getConstPointer();
11216 const int *a1Ptr=a1->getConstPointer();
11217 int *res=ret->getPointer();
11218 for(int i=0;i<nbOfTuple1;i++)
11219 res=std::transform(a1Ptr+i*nbOfComp1,a1Ptr+(i+1)*nbOfComp1,res,std::bind2nd(std::modulus<int>(),a2Ptr[i]));
11220 ret->copyStringInfoFrom(*a1);
11225 a1->checkNbOfComps(nbOfComp2,"Nb of components mismatch for array Modulus !");
11229 else if(nbOfTuple2==1)
11231 a1->checkNbOfComps(nbOfComp2,"Nb of components mismatch for array Modulus !");
11232 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
11233 ret->alloc(nbOfTuple1,nbOfComp1);
11234 const int *a1ptr=a1->getConstPointer(),*a2ptr=a2->getConstPointer();
11235 int *pt=ret->getPointer();
11236 for(int i=0;i<nbOfTuple1;i++)
11237 pt=std::transform(a1ptr+i*nbOfComp1,a1ptr+(i+1)*nbOfComp1,a2ptr,pt,std::modulus<int>());
11238 ret->copyStringInfoFrom(*a1);
11243 a1->checkNbOfTuples(nbOfTuple2,"Nb of tuples mismatch for array Modulus !");//will always throw an exception
11249 * Modify \a this array so that each value becomes a modulus of division of this value by
11250 * a value of another DataArrayInt. There are 3 valid cases.
11251 * 1. The arrays have same number of tuples and components. Then each value of
11252 * \a this array is divided by the corresponding value of \a other one, i.e.:
11253 * _a_ [ i, j ] %= _other_ [ i, j ].
11254 * 2. The arrays have same number of tuples and \a other array has one component. Then
11255 * _a_ [ i, j ] %= _other_ [ i, 0 ].
11256 * 3. The arrays have same number of components and \a other array has one tuple. Then
11257 * _a_ [ i, j ] %= _a2_ [ 0, j ].
11259 * \warning No check of division by zero is performed!
11260 * \param [in] other - a divisor array.
11261 * \throw If \a other is NULL.
11262 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples() and
11263 * \a this->getNumberOfComponents() != \a other->getNumberOfComponents() and
11264 * \a other has number of both tuples and components not equal to 1.
11266 void DataArrayInt::modulusEqual(const DataArrayInt *other)
11269 throw INTERP_KERNEL::Exception("DataArrayInt::modulusEqual : input DataArrayInt instance is NULL !");
11270 const char *msg="Nb of tuples mismatch for DataArrayInt::modulusEqual !";
11271 checkAllocated(); other->checkAllocated();
11272 int nbOfTuple=getNumberOfTuples();
11273 int nbOfTuple2=other->getNumberOfTuples();
11274 int nbOfComp=getNumberOfComponents();
11275 int nbOfComp2=other->getNumberOfComponents();
11276 if(nbOfTuple==nbOfTuple2)
11278 if(nbOfComp==nbOfComp2)
11280 std::transform(begin(),end(),other->begin(),getPointer(),std::modulus<int>());
11282 else if(nbOfComp2==1)
11284 if(nbOfComp2==nbOfComp)
11286 int *ptr=getPointer();
11287 const int *ptrc=other->getConstPointer();
11288 for(int i=0;i<nbOfTuple;i++)
11289 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptr+i*nbOfComp,std::bind2nd(std::modulus<int>(),*ptrc++));
11292 throw INTERP_KERNEL::Exception(msg);
11295 throw INTERP_KERNEL::Exception(msg);
11297 else if(nbOfTuple2==1)
11299 int *ptr=getPointer();
11300 const int *ptrc=other->getConstPointer();
11301 for(int i=0;i<nbOfTuple;i++)
11302 std::transform(ptr+i*nbOfComp,ptr+(i+1)*nbOfComp,ptrc,ptr+i*nbOfComp,std::modulus<int>());
11305 throw INTERP_KERNEL::Exception(msg);
11310 * Returns a new DataArrayInt that is the result of pow of two given arrays. There are 3
11313 * \param [in] a1 - an array to pow up.
11314 * \param [in] a2 - another array to sum up.
11315 * \return DataArrayInt * - the new instance of DataArrayInt.
11316 * The caller is to delete this result array using decrRef() as it is no more
11318 * \throw If either \a a1 or \a a2 is NULL.
11319 * \throw If \a a1->getNumberOfTuples() != \a a2->getNumberOfTuples()
11320 * \throw If \a a1->getNumberOfComponents() != 1 or \a a2->getNumberOfComponents() != 1.
11321 * \throw If there is a negative value in \a a2.
11323 DataArrayInt *DataArrayInt::Pow(const DataArrayInt *a1, const DataArrayInt *a2)
11326 throw INTERP_KERNEL::Exception("DataArrayInt::Pow : at least one of input instances is null !");
11327 int nbOfTuple=a1->getNumberOfTuples();
11328 int nbOfTuple2=a2->getNumberOfTuples();
11329 int nbOfComp=a1->getNumberOfComponents();
11330 int nbOfComp2=a2->getNumberOfComponents();
11331 if(nbOfTuple!=nbOfTuple2)
11332 throw INTERP_KERNEL::Exception("DataArrayInt::Pow : number of tuples mismatches !");
11333 if(nbOfComp!=1 || nbOfComp2!=1)
11334 throw INTERP_KERNEL::Exception("DataArrayInt::Pow : number of components of both arrays must be equal to 1 !");
11335 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New(); ret->alloc(nbOfTuple,1);
11336 const int *ptr1(a1->begin()),*ptr2(a2->begin());
11337 int *ptr=ret->getPointer();
11338 for(int i=0;i<nbOfTuple;i++,ptr1++,ptr2++,ptr++)
11343 for(int j=0;j<*ptr2;j++)
11349 std::ostringstream oss; oss << "DataArrayInt::Pow : on tuple #" << i << " of a2 value is < 0 (" << *ptr2 << ") !";
11350 throw INTERP_KERNEL::Exception(oss.str().c_str());
11357 * Apply pow on values of another DataArrayInt to values of \a this one.
11359 * \param [in] other - an array to pow to \a this one.
11360 * \throw If \a other is NULL.
11361 * \throw If \a this->getNumberOfTuples() != \a other->getNumberOfTuples()
11362 * \throw If \a this->getNumberOfComponents() != 1 or \a other->getNumberOfComponents() != 1
11363 * \throw If there is a negative value in \a other.
11365 void DataArrayInt::powEqual(const DataArrayInt *other)
11368 throw INTERP_KERNEL::Exception("DataArrayInt::powEqual : input instance is null !");
11369 int nbOfTuple=getNumberOfTuples();
11370 int nbOfTuple2=other->getNumberOfTuples();
11371 int nbOfComp=getNumberOfComponents();
11372 int nbOfComp2=other->getNumberOfComponents();
11373 if(nbOfTuple!=nbOfTuple2)
11374 throw INTERP_KERNEL::Exception("DataArrayInt::powEqual : number of tuples mismatches !");
11375 if(nbOfComp!=1 || nbOfComp2!=1)
11376 throw INTERP_KERNEL::Exception("DataArrayInt::powEqual : number of components of both arrays must be equal to 1 !");
11377 int *ptr=getPointer();
11378 const int *ptrc=other->begin();
11379 for(int i=0;i<nbOfTuple;i++,ptrc++,ptr++)
11384 for(int j=0;j<*ptrc;j++)
11390 std::ostringstream oss; oss << "DataArrayInt::powEqual : on tuple #" << i << " of other value is < 0 (" << *ptrc << ") !";
11391 throw INTERP_KERNEL::Exception(oss.str().c_str());
11398 * Returns a C array which is a renumbering map in "Old to New" mode for the input array.
11399 * This map, if applied to \a start array, would make it sorted. For example, if
11400 * \a start array contents are [9,10,0,6,4,11,3,7] then the contents of the result array is
11401 * [5,6,0,3,2,7,1,4].
11402 * \param [in] start - pointer to the first element of the array for which the
11403 * permutation map is computed.
11404 * \param [in] end - pointer specifying the end of the array \a start, so that
11405 * the last value of \a start is \a end[ -1 ].
11406 * \return int * - the result permutation array that the caller is to delete as it is no
11408 * \throw If there are equal values in the input array.
11410 int *DataArrayInt::CheckAndPreparePermutation(const int *start, const int *end)
11412 std::size_t sz=std::distance(start,end);
11413 int *ret=(int *)malloc(sz*sizeof(int));
11414 int *work=new int[sz];
11415 std::copy(start,end,work);
11416 std::sort(work,work+sz);
11417 if(std::unique(work,work+sz)!=work+sz)
11421 throw INTERP_KERNEL::Exception("Some elements are equals in the specified array !");
11423 std::map<int,int> m;
11424 for(int *workPt=work;workPt!=work+sz;workPt++)
11425 m[*workPt]=(int)std::distance(work,workPt);
11427 for(const int *iter=start;iter!=end;iter++,iter2++)
11434 * Returns a new DataArrayInt containing an arithmetic progression
11435 * that is equal to the sequence returned by Python \c range(\a begin,\a end,\a step )
11437 * \param [in] begin - the start value of the result sequence.
11438 * \param [in] end - limiting value, so that every value of the result array is less than
11440 * \param [in] step - specifies the increment or decrement.
11441 * \return DataArrayInt * - a new instance of DataArrayInt. The caller is to delete this
11442 * array using decrRef() as it is no more needed.
11443 * \throw If \a step == 0.
11444 * \throw If \a end < \a begin && \a step > 0.
11445 * \throw If \a end > \a begin && \a step < 0.
11447 DataArrayInt *DataArrayInt::Range(int begin, int end, int step)
11449 int nbOfTuples=GetNumberOfItemGivenBESRelative(begin,end,step,"DataArrayInt::Range");
11450 MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
11451 ret->alloc(nbOfTuples,1);
11452 int *ptr=ret->getPointer();
11455 for(int i=begin;i<end;i+=step,ptr++)
11460 for(int i=begin;i>end;i+=step,ptr++)
11467 * Useless method for end user. Only for MPI/Corba/File serialsation for multi arrays class.
11470 void DataArrayInt::getTinySerializationIntInformation(std::vector<int>& tinyInfo) const
11472 tinyInfo.resize(2);
11475 tinyInfo[0]=getNumberOfTuples();
11476 tinyInfo[1]=getNumberOfComponents();
11486 * Useless method for end user. Only for MPI/Corba/File serialsation for multi arrays class.
11489 void DataArrayInt::getTinySerializationStrInformation(std::vector<std::string>& tinyInfo) const
11493 int nbOfCompo=getNumberOfComponents();
11494 tinyInfo.resize(nbOfCompo+1);
11495 tinyInfo[0]=getName();
11496 for(int i=0;i<nbOfCompo;i++)
11497 tinyInfo[i+1]=getInfoOnComponent(i);
11501 tinyInfo.resize(1);
11502 tinyInfo[0]=getName();
11507 * Useless method for end user. Only for MPI/Corba/File serialsation for multi arrays class.
11508 * This method returns if a feeding is needed.
11510 bool DataArrayInt::resizeForUnserialization(const std::vector<int>& tinyInfoI)
11512 int nbOfTuple=tinyInfoI[0];
11513 int nbOfComp=tinyInfoI[1];
11514 if(nbOfTuple!=-1 || nbOfComp!=-1)
11516 alloc(nbOfTuple,nbOfComp);
11523 * Useless method for end user. Only for MPI/Corba/File serialsation for multi arrays class.
11524 * This method returns if a feeding is needed.
11526 void DataArrayInt::finishUnserialization(const std::vector<int>& tinyInfoI, const std::vector<std::string>& tinyInfoS)
11528 setName(tinyInfoS[0]);
11531 int nbOfCompo=tinyInfoI[1];
11532 for(int i=0;i<nbOfCompo;i++)
11533 setInfoOnComponent(i,tinyInfoS[i+1]);
11537 DataArrayIntIterator::DataArrayIntIterator(DataArrayInt *da):_da(da),_pt(0),_tuple_id(0),_nb_comp(0),_nb_tuple(0)
11542 if(_da->isAllocated())
11544 _nb_comp=da->getNumberOfComponents();
11545 _nb_tuple=da->getNumberOfTuples();
11546 _pt=da->getPointer();
11551 DataArrayIntIterator::~DataArrayIntIterator()
11557 DataArrayIntTuple *DataArrayIntIterator::nextt()
11559 if(_tuple_id<_nb_tuple)
11562 DataArrayIntTuple *ret=new DataArrayIntTuple(_pt,_nb_comp);
11570 DataArrayIntTuple::DataArrayIntTuple(int *pt, int nbOfComp):_pt(pt),_nb_of_compo(nbOfComp)
11574 std::string DataArrayIntTuple::repr() const
11576 std::ostringstream oss; oss << "(";
11577 for(int i=0;i<_nb_of_compo-1;i++)
11578 oss << _pt[i] << ", ";
11579 oss << _pt[_nb_of_compo-1] << ")";
11583 int DataArrayIntTuple::intValue() const
11585 if(_nb_of_compo==1)
11587 throw INTERP_KERNEL::Exception("DataArrayIntTuple::intValue : DataArrayIntTuple instance has not exactly 1 component -> Not possible to convert it into an integer !");
11591 * This method returns a newly allocated instance the caller should dealed with by a ParaMEDMEM::DataArrayInt::decrRef.
11592 * This method performs \b no copy of data. The content is only referenced using ParaMEDMEM::DataArrayInt::useArray with ownership set to \b false.
11593 * This method throws an INTERP_KERNEL::Exception is it is impossible to match sizes of \b this that is too say \b nbOfCompo=this->_nb_of_elem and \bnbOfTuples==1 or
11594 * \b nbOfCompo=1 and \bnbOfTuples==this->_nb_of_elem.
11596 DataArrayInt *DataArrayIntTuple::buildDAInt(int nbOfTuples, int nbOfCompo) const
11598 if((_nb_of_compo==nbOfCompo && nbOfTuples==1) || (_nb_of_compo==nbOfTuples && nbOfCompo==1))
11600 DataArrayInt *ret=DataArrayInt::New();
11601 ret->useExternalArrayWithRWAccess(_pt,nbOfTuples,nbOfCompo);
11606 std::ostringstream oss; oss << "DataArrayIntTuple::buildDAInt : unable to build a requested DataArrayInt instance with nbofTuple=" << nbOfTuples << " and nbOfCompo=" << nbOfCompo;
11607 oss << ".\nBecause the number of elements in this is " << _nb_of_compo << " !";
11608 throw INTERP_KERNEL::Exception(oss.str().c_str());