#include "MEDCouplingFieldDouble.hxx"
#include "MEDCouplingFieldTemplate.hxx"
+#include "MEDCouplingFieldT.txx"
+#include "MEDCouplingFieldInt.hxx"
#include "MEDCouplingUMesh.hxx"
#include "MEDCouplingTimeDiscretization.hxx"
#include "MEDCouplingFieldDiscretization.hxx"
using namespace MEDCoupling;
+template class MEDCouplingFieldT<double>;
/*!
* Creates a new MEDCouplingFieldDouble, of given spatial type and time discretization.
* Sets a time \a unit of \a this field. For more info, see \ref MEDCouplingFirstSteps3.
* \param [in] unit \a unit (string) in which time is measured.
*/
-void MEDCouplingFieldDouble::setTimeUnit(const std::string& unit)
-{
- _time_discr->setTimeUnit(unit);
-}
+//void MEDCouplingFieldDouble::setTimeUnit(const std::string& unit)
/*!
* Returns a time unit of \a this field.
* \return a string describing units in which time is measured.
*/
-std::string MEDCouplingFieldDouble::getTimeUnit() const
-{
- return _time_discr->getTimeUnit();
-}
+//std::string MEDCouplingFieldDouble::getTimeUnit() const
+
/*!
* This method if possible the time information (time unit, time iteration, time unit and time value) with its support
*/
void MEDCouplingFieldDouble::synchronizeTimeWithSupport()
{
- _time_discr->synchronizeTimeWith(_mesh);
+ timeDiscr()->synchronizeTimeWith(_mesh);
}
/*!
return new MEDCouplingFieldDouble(*this,recDeepCpy);
}
-/*!
- * Returns a new MEDCouplingFieldDouble which is a copy of \a this one. The data
- * of \a this field is copied either deep or shallow depending on \a recDeepCpy
- * parameter. But the underlying mesh is always deep copied.
- * Data that can be copied either deeply or shallow are:
- * - \ref MEDCouplingTemporalDisc "temporal discretization" data that holds array(s)
- * of field values,
- * - \ref MEDCouplingSpatialDisc "a spatial discretization".
- *
- * This method behaves exactly like clone() except that here the underlying **mesh is
- * always deeply duplicated**, whatever the value \a recDeepCpy parameter.
- * The result of \c cloneWithMesh(true) is exactly the same as that of deepCopy().
- * So the resulting field can not be used together with \a this one in the methods
- * like operator+(), operator*() etc. To avoid deep copying the underlying mesh,
- * the user can call clone().
- * \param [in] recDeepCpy - if \c true, the copy of the underlying data arrays is
- * deep, else all data arrays of \a this field are shared by the new field.
- * \return MEDCouplingFieldDouble * - a new instance of MEDCouplingFieldDouble. The
- * caller is to delete this field using decrRef() as it is no more needed.
- * \sa clone()
- */
-MEDCouplingFieldDouble *MEDCouplingFieldDouble::cloneWithMesh(bool recDeepCpy) const
-{
- MCAuto<MEDCouplingFieldDouble> ret=clone(recDeepCpy);
- if(_mesh)
- {
- MCAuto<MEDCouplingMesh> mCpy=_mesh->deepCopy();
- ret->setMesh(mCpy);
- }
- return ret.retn();
-}
-
/*!
* Returns a new MEDCouplingFieldDouble which is a deep copy of \a this one **including
* the mesh**.
*/
MEDCouplingFieldDouble *MEDCouplingFieldDouble::buildNewTimeReprFromThis(TypeOfTimeDiscretization td, bool deepCopy) const
{
- MEDCouplingTimeDiscretization *tdo=_time_discr->buildNewTimeReprFromThis(td,deepCopy);
+ MEDCouplingTimeDiscretization *tdo=timeDiscr()->buildNewTimeReprFromThis(td,deepCopy);
MCAuto<MEDCouplingFieldDiscretization> disc;
if(_type)
disc=_type->clone();
else
{
std::ostringstream oss; oss << "MEDCouplingFieldDouble::nodeToCellDiscretization : Cell id #" << i << " has been detected to have no nodes !";
- throw INTERP_KERNEL::Exception(oss.str().c_str());
+ throw INTERP_KERNEL::Exception(oss.str());
}
}
}
return ret.retn();
}
-/*!
- * Copies tiny info (component names, name and description) from an \a other field to
- * \a this one.
- * \warning The underlying mesh is not renamed (for safety reason).
- * \param [in] other - the field to copy the tiny info from.
- * \throw If \a this->getNumberOfComponents() != \a other->getNumberOfComponents()
- */
-void MEDCouplingFieldDouble::copyTinyStringsFrom(const MEDCouplingField *other)
-{
- MEDCouplingField::copyTinyStringsFrom(other);
- const MEDCouplingFieldDouble *otherC=dynamic_cast<const MEDCouplingFieldDouble *>(other);
- if(otherC)
- {
- _time_discr->copyTinyStringsFrom(*otherC->_time_discr);
- }
-}
-
-/*!
- * Copies only times, order and iteration from an \a other field to
- * \a this one. The underlying mesh is not impacted by this method.
- * Arrays are not impacted neither.
- * \param [in] other - the field to tiny attributes from.
- * \throw If \a this->getNumberOfComponents() != \a other->getNumberOfComponents()
- */
-void MEDCouplingFieldDouble::copyTinyAttrFrom(const MEDCouplingFieldDouble *other)
-{
- if(other)
- {
- _time_discr->copyTinyAttrFrom(*other->_time_discr);
- }
-}
-
-void MEDCouplingFieldDouble::copyAllTinyAttrFrom(const MEDCouplingFieldDouble *other)
-{
- copyTinyStringsFrom(other);
- copyTinyAttrFrom(other);
-}
-
-/*!
- * Returns a string describing \a this field. This string is outputted by \c print
- * Python command. The string includes info on
- * - name,
- * - description,
- * - \ref MEDCouplingSpatialDisc "spatial discretization",
- * - \ref MEDCouplingTemporalDisc "time discretization",
- * - \ref NatureOfField,
- * - components,
- * - mesh.
- *
- * \return std::string - the string describing \a this field.
- */
-std::string MEDCouplingFieldDouble::simpleRepr() const
-{
- std::ostringstream ret;
- ret << "FieldDouble with name : \"" << getName() << "\"\n";
- ret << "Description of field is : \"" << getDescription() << "\"\n";
- if(_type)
- { ret << "FieldDouble space discretization is : " << _type->getStringRepr() << "\n"; }
- else
- { ret << "FieldDouble has no spatial discretization !\n"; }
- if(_time_discr)
- { ret << "FieldDouble time discretization is : " << _time_discr->getStringRepr() << "\n"; }
- else
- { ret << "FieldDouble has no time discretization !\n"; }
- ret << "FieldDouble nature of field is : \"" << MEDCouplingNatureOfField::GetReprNoThrow(_nature) << "\"\n";
- if(getArray())
- {
- if(getArray()->isAllocated())
- {
- int nbOfCompo=getArray()->getNumberOfComponents();
- ret << "FieldDouble default array has " << nbOfCompo << " components and " << getArray()->getNumberOfTuples() << " tuples.\n";
- ret << "FieldDouble default array has following info on components : ";
- for(int i=0;i<nbOfCompo;i++)
- ret << "\"" << getArray()->getInfoOnComponent(i) << "\" ";
- ret << "\n";
- }
- else
- {
- ret << "Array set but not allocated !\n";
- }
- }
- if(_mesh)
- ret << "Mesh support information :\n__________________________\n" << _mesh->simpleRepr();
- else
- ret << "Mesh support information : No mesh set !\n";
- return ret.str();
-}
-
/*!
* Returns a string describing \a this field. The string includes info on
* - name,
{ ret << "FieldDouble space discretization is : " << _type->getStringRepr() << "\n"; }
else
{ ret << "FieldDouble has no space discretization set !\n"; }
- if(_time_discr)
- { ret << "FieldDouble time discretization is : " << _time_discr->getStringRepr() << "\n"; }
+ if(timeDiscr())
+ { ret << "FieldDouble time discretization is : " << timeDiscr()->getStringRepr() << "\n"; }
else
{ ret << "FieldDouble has no time discretization set !\n"; }
if(getArray())
else
ret << "Mesh support information : No mesh set !\n";
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
int arrayId=0;
for(std::vector<DataArrayDouble *>::const_iterator iter=arrays.begin();iter!=arrays.end();iter++,arrayId++)
{
return MEDCouplingFieldDouble::WriteVTK(fileName,fs,isBinary);
}
-bool MEDCouplingFieldDouble::isEqualIfNotWhy(const MEDCouplingField *other, double meshPrec, double valsPrec, std::string& reason) const
-{
- if(!other)
- throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::isEqualIfNotWhy : other instance is NULL !");
- const MEDCouplingFieldDouble *otherC=dynamic_cast<const MEDCouplingFieldDouble *>(other);
- if(!otherC)
- {
- reason="field given in input is not castable in MEDCouplingFieldDouble !";
- return false;
- }
- if(!MEDCouplingField::isEqualIfNotWhy(other,meshPrec,valsPrec,reason))
- return false;
- if(!_time_discr->isEqualIfNotWhy(otherC->_time_discr,valsPrec,reason))
- {
- reason.insert(0,"In FieldDouble time discretizations differ :");
- return false;
- }
- return true;
-}
-
-/*!
- * Checks equality of \a this and \a other field. Only numeric data is considered,
- * i.e. names, description etc are not compared.
- * \param [in] other - the field to compare with.
- * \param [in] meshPrec - a precision used to compare node coordinates of meshes.
- * \param [in] valsPrec - a precision used to compare data arrays of the two fields.
- * \return bool - \c true if the two fields are equal, \c false else.
- * \throw If \a other == NULL.
- * \throw If the spatial discretization of \a this field is NULL.
- */
-bool MEDCouplingFieldDouble::isEqualWithoutConsideringStr(const MEDCouplingField *other, double meshPrec, double valsPrec) const
-{
- const MEDCouplingFieldDouble *otherC=dynamic_cast<const MEDCouplingFieldDouble *>(other);
- if(!otherC)
- return false;
- if(!MEDCouplingField::isEqualWithoutConsideringStr(other,meshPrec,valsPrec))
- return false;
- if(!_time_discr->isEqualWithoutConsideringStr(otherC->_time_discr,valsPrec))
- return false;
- return true;
-}
-
/*!
* This method states if \a this and 'other' are compatibles each other before performing any treatment.
* This method is good for methods like : mergeFields.
{
if(!MEDCouplingField::areCompatibleForMerge(other))
return false;
- const MEDCouplingFieldDouble *otherC=dynamic_cast<const MEDCouplingFieldDouble *>(other);
+ const MEDCouplingFieldDouble *otherC(dynamic_cast<const MEDCouplingFieldDouble *>(other));
if(!otherC)
return false;
- if(!_time_discr->areCompatible(otherC->_time_discr))
- return false;
- return true;
-}
-
-/*!
- * This method is more strict than MEDCouplingField::areCompatibleForMerge method.
- * This method is used for operation on fields to operate a first check before attempting operation.
- */
-bool MEDCouplingFieldDouble::areStrictlyCompatible(const MEDCouplingField *other) const
-{
- std::string tmp;
- if(!MEDCouplingField::areStrictlyCompatible(other))
- return false;
- const MEDCouplingFieldDouble *otherC=dynamic_cast<const MEDCouplingFieldDouble *>(other);
- if(!otherC)
- return false;
- if(!_time_discr->areStrictlyCompatible(otherC->_time_discr,tmp))
- return false;
- return true;
-}
-
-/*!
- * Method with same principle than MEDCouplingFieldDouble::areStrictlyCompatibleForMulDiv method except that
- * number of components between \a this and 'other' can be different here (for operator*).
- */
-bool MEDCouplingFieldDouble::areCompatibleForMul(const MEDCouplingField *other) const
-{
- if(!MEDCouplingField::areStrictlyCompatibleForMulDiv(other))
- return false;
- const MEDCouplingFieldDouble *otherC=dynamic_cast<const MEDCouplingFieldDouble *>(other);
- if(!otherC)
- return false;
- if(!_time_discr->areStrictlyCompatibleForMul(otherC->_time_discr))
- return false;
- return true;
-}
-
-/*!
- * Method with same principle than MEDCouplingFieldDouble::areStrictlyCompatibleForMulDiv method except that
- * number of components between \a this and 'other' can be different here (for operator/).
- */
-bool MEDCouplingFieldDouble::areCompatibleForDiv(const MEDCouplingField *other) const
-{
- if(!MEDCouplingField::areStrictlyCompatibleForMulDiv(other))
- return false;
- const MEDCouplingFieldDouble *otherC=dynamic_cast<const MEDCouplingFieldDouble *>(other);
- if(!otherC)
- return false;
- if(!_time_discr->areStrictlyCompatibleForDiv(otherC->_time_discr))
+ if(!timeDiscr()->areCompatible(otherC->timeDiscr()))
return false;
return true;
}
{
if(!MEDCouplingField::areStrictlyCompatible(other))
return false;
- if(!_time_discr->areCompatibleForMeld(other->_time_discr))
+ if(!timeDiscr()->areCompatibleForMeld(other->timeDiscr()))
return false;
return true;
}
//
_type->renumberCells(old2NewBg,check);
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
std::vector<DataArray *> arrays2(arrays.size()); std::copy(arrays.begin(),arrays.end(),arrays2.begin());
_type->renumberArraysForCell(_mesh,arrays2,old2NewBg,check);
//
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("Expecting a spatial discretization to be able to operate a renumbering !");
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
for(std::vector<DataArrayDouble *>::const_iterator iter=arrays.begin();iter!=arrays.end();iter++)
if(*iter)
_type->renumberValuesOnNodes(eps,old2NewBg,newNbOfNodes,*iter);
ret->setDiscretization(MCAuto<MEDCouplingFieldDiscretization>(disc->clonePart(partBg,partEnd)));
ret->setMesh(m);
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
std::vector<DataArrayDouble *> arrs;
std::vector< MCAuto<DataArrayDouble> > arrsSafe;
const int *arrSelBg=arrSelect->begin();
arr=(*iter)->selectByTupleIdSafe(arrSelBg,arrSelEnd);
arrs.push_back(arr); arrsSafe.push_back(arr);
}
- ret->_time_discr->setArrays(arrs,0);
+ ret->timeDiscr()->setArrays(arrs,0);
return ret.retn();
}
ret->setDiscretization(MCAuto<MEDCouplingFieldDiscretization>(disc->clonePartRange(begin,end,step)));
ret->setMesh(m);
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
std::vector<DataArrayDouble *> arrs;
std::vector< MCAuto<DataArrayDouble> > arrsSafe;
for(std::vector<DataArrayDouble *>::const_iterator iter=arrays.begin();iter!=arrays.end();iter++)
}
arrs.push_back(arr); arrsSafe.push_back(arr);
}
- ret->_time_discr->setArrays(arrs,0);
+ ret->timeDiscr()->setArrays(arrs,0);
return ret.retn();
}
-/*!
- * Returns a type of \ref MEDCouplingTemporalDisc "time discretization" of \a this field.
- * \return MEDCoupling::TypeOfTimeDiscretization - an enum item describing the time
- * discretization type.
- */
-TypeOfTimeDiscretization MEDCouplingFieldDouble::getTimeDiscretization() const
+MEDCouplingFieldInt *MEDCouplingFieldDouble::convertToIntField() const
{
- return _time_discr->getEnum();
+ MCAuto<MEDCouplingFieldTemplate> tmp(MEDCouplingFieldTemplate::New(*this));
+ int t1,t2;
+ double t0(getTime(t1,t2));
+ MCAuto<MEDCouplingFieldInt> ret(MEDCouplingFieldInt::New(*tmp,getTimeDiscretization()));
+ ret->setTime(t0,t1,t2);
+ if(getArray())
+ {
+ MCAuto<DataArrayInt> arr(getArray()->convertToIntArr());
+ ret->setArray(arr);
+ }
+ return ret.retn();
}
-MEDCouplingFieldDouble::MEDCouplingFieldDouble(TypeOfField type, TypeOfTimeDiscretization td):MEDCouplingField(type),
- _time_discr(MEDCouplingTimeDiscretization::New(td))
+MEDCouplingFieldDouble::MEDCouplingFieldDouble(TypeOfField type, TypeOfTimeDiscretization td):MEDCouplingFieldT<double>(type,MEDCouplingTimeDiscretization::New(td))
{
}
/*!
* ** WARINING : This method do not deeply copy neither mesh nor spatial discretization. Only a shallow copy (reference) is done for mesh and spatial discretization ! **
*/
-MEDCouplingFieldDouble::MEDCouplingFieldDouble(const MEDCouplingFieldTemplate& ft, TypeOfTimeDiscretization td):MEDCouplingField(ft,false),
- _time_discr(MEDCouplingTimeDiscretization::New(td))
+MEDCouplingFieldDouble::MEDCouplingFieldDouble(const MEDCouplingFieldTemplate& ft, TypeOfTimeDiscretization td):MEDCouplingFieldT<double>(ft,MEDCouplingTimeDiscretization::New(td),false)
{
}
-MEDCouplingFieldDouble::MEDCouplingFieldDouble(const MEDCouplingFieldDouble& other, bool deepCopy):MEDCouplingField(other,deepCopy),
- _time_discr(other._time_discr->performCopyOrIncrRef(deepCopy))
+MEDCouplingFieldDouble::MEDCouplingFieldDouble(const MEDCouplingFieldDouble& other, bool deepCopy):MEDCouplingFieldT<double>(other,deepCopy)
{
}
-MEDCouplingFieldDouble::MEDCouplingFieldDouble(NatureOfField n, MEDCouplingTimeDiscretization *td, MEDCouplingFieldDiscretization *type):MEDCouplingField(type,n),_time_discr(td)
+MEDCouplingFieldDouble::MEDCouplingFieldDouble(NatureOfField n, MEDCouplingTimeDiscretization *td, MEDCouplingFieldDiscretization *type):MEDCouplingFieldT<double>(type,n,td)
{
}
-MEDCouplingFieldDouble::~MEDCouplingFieldDouble()
-{
- delete _time_discr;
-}
-
-/*!
- * Checks if \a this field is correctly defined, else an exception is thrown.
- * \throw If the mesh is not set.
- * \throw If the data array is not set.
- * \throw If the spatial discretization of \a this field is NULL.
- * \throw If \a this->getTimeTolerance() < 0.
- * \throw If the temporal discretization data is incorrect.
- * \throw If mesh data does not correspond to field data.
- */
-void MEDCouplingFieldDouble::checkConsistencyLight() const
-{
- MEDCouplingField::checkConsistencyLight();
- _time_discr->checkConsistencyLight();
- _type->checkCoherencyBetween(_mesh,getArray());
-}
-
/*!
* Accumulate values of a given component of \a this field.
* \param [in] compId - the index of the component of interest.
double MEDCouplingFieldDouble::getMaxValue() const
{
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
double ret=-std::numeric_limits<double>::max();
bool isExistingArr=false;
for(std::vector<DataArrayDouble *>::const_iterator iter=arrays.begin();iter!=arrays.end();iter++)
double MEDCouplingFieldDouble::getMaxValue2(DataArrayInt*& tupleIds) const
{
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
double ret=-std::numeric_limits<double>::max();
bool isExistingArr=false;
tupleIds=0;
double MEDCouplingFieldDouble::getMinValue() const
{
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
double ret=std::numeric_limits<double>::max();
bool isExistingArr=false;
for(std::vector<DataArrayDouble *>::const_iterator iter=arrays.begin();iter!=arrays.end();iter++)
double MEDCouplingFieldDouble::getMinValue2(DataArrayInt*& tupleIds) const
{
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
double ret=-std::numeric_limits<double>::max();
bool isExistingArr=false;
tupleIds=0;
if(compId<0 || compId>=nbComps)
{
std::ostringstream oss; oss << "MEDCouplingFieldDouble::getWeightedAverageValue : Invalid compId specified : No such nb of components ! Should be in [0," << nbComps << ") !";
- throw INTERP_KERNEL::Exception(oss.str().c_str());
+ throw INTERP_KERNEL::Exception(oss.str());
}
INTERP_KERNEL::AutoPtr<double> res=new double[nbComps];
getWeightedAverageValue(res,isWAbs);
if(compId<0 || compId>=nbComps)
{
std::ostringstream oss; oss << "MEDCouplingFieldDouble::normL1 : Invalid compId specified : No such nb of components ! Should be in [0," << nbComps << ") !";
- throw INTERP_KERNEL::Exception(oss.str().c_str());
+ throw INTERP_KERNEL::Exception(oss.str());
}
INTERP_KERNEL::AutoPtr<double> res=new double[nbComps];
_type->normL1(_mesh,getArray(),res);
if(compId<0 || compId>=nbComps)
{
std::ostringstream oss; oss << "MEDCouplingFieldDouble::normL2 : Invalid compId specified : No such nb of components ! Should be in [0," << nbComps << ") !";
- throw INTERP_KERNEL::Exception(oss.str().c_str());
+ throw INTERP_KERNEL::Exception(oss.str());
}
INTERP_KERNEL::AutoPtr<double> res=new double[nbComps];
_type->normL2(_mesh,getArray(),res);
if(compId<0 || compId>=nbComps)
{
std::ostringstream oss; oss << "MEDCouplingFieldDouble::integral : Invalid compId specified : No such nb of components ! Should be in [0," << nbComps << ") !";
- throw INTERP_KERNEL::Exception(oss.str().c_str());
+ throw INTERP_KERNEL::Exception(oss.str());
}
INTERP_KERNEL::AutoPtr<double> res=new double[nbComps];
_type->integral(_mesh,getArray(),isWAbs,res);
*/
void MEDCouplingFieldDouble::getValueOnPos(int i, int j, int k, double *res) const
{
- const DataArrayDouble *arr=_time_discr->getArray();
+ const DataArrayDouble *arr=timeDiscr()->getArray();
if(!_mesh)
throw INTERP_KERNEL::Exception("No mesh underlying this field to perform getValueOnPos");
if(!((const MEDCouplingFieldDiscretization *)_type))
*/
void MEDCouplingFieldDouble::getValueOn(const double *spaceLoc, double *res) const
{
- const DataArrayDouble *arr=_time_discr->getArray();
+ const DataArrayDouble *arr=timeDiscr()->getArray();
if(!_mesh)
throw INTERP_KERNEL::Exception("No mesh underlying this field to perform getValueOn");
if(!((const MEDCouplingFieldDiscretization *)_type))
*/
DataArrayDouble *MEDCouplingFieldDouble::getValueOnMulti(const double *spaceLoc, int nbOfPoints) const
{
- const DataArrayDouble *arr=_time_discr->getArray();
+ const DataArrayDouble *arr=timeDiscr()->getArray();
if(!_mesh)
throw INTERP_KERNEL::Exception("No mesh underlying this field to perform getValueOnMulti");
if(!((const MEDCouplingFieldDiscretization *)_type))
*/
void MEDCouplingFieldDouble::getValueOn(const double *spaceLoc, double time, double *res) const
{
- std::vector< const DataArrayDouble *> arrs=_time_discr->getArraysForTime(time);
+ std::vector< const DataArrayDouble *> arrs=timeDiscr()->getArraysForTime(time);
if(!_mesh)
throw INTERP_KERNEL::Exception("No mesh underlying this field to perform getValueOn");
if(!((const MEDCouplingFieldDiscretization *)_type))
res2.resize(sz+(*iter)->getNumberOfComponents());
_type->getValueOn(*iter,_mesh,spaceLoc,&res2[sz]);
}
- _time_discr->getValueForTime(time,res2,res);
+ timeDiscr()->getValueForTime(time,res2,res);
}
/*!
*/
void MEDCouplingFieldDouble::applyLin(double a, double b, int compoId)
{
- _time_discr->applyLin(a,b,compoId);
+ timeDiscr()->applyLin(a,b,compoId);
}
/*!
*/
void MEDCouplingFieldDouble::applyLin(double a, double b)
{
- _time_discr->applyLin(a,b);
+ timeDiscr()->applyLin(a,b);
}
/*!
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform operator = !");
int nbOfTuple=_type->getNumberOfTuples(_mesh);
- _time_discr->setOrCreateUniformValueOnAllComponents(nbOfTuple,value);
+ timeDiscr()->setOrCreateUniformValueOnAllComponents(nbOfTuple,value);
return *this;
}
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform fillFromAnalytic !");
MCAuto<DataArrayDouble> loc=_type->getLocalizationOfDiscValues(_mesh);
- _time_discr->fillFromAnalytic(loc,nbOfComp,func);
+ timeDiscr()->fillFromAnalytic(loc,nbOfComp,func);
}
/*!
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform fillFromAnalytic !");
MCAuto<DataArrayDouble> loc=_type->getLocalizationOfDiscValues(_mesh);
- _time_discr->fillFromAnalytic(loc,nbOfComp,func);
+ timeDiscr()->fillFromAnalytic(loc,nbOfComp,func);
}
/*!
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform fillFromAnalyticCompo !");
MCAuto<DataArrayDouble> loc=_type->getLocalizationOfDiscValues(_mesh);
- _time_discr->fillFromAnalyticCompo(loc,nbOfComp,func);
+ timeDiscr()->fillFromAnalyticCompo(loc,nbOfComp,func);
}
/*!
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform fillFromAnalyticNamedCompo !");
MCAuto<DataArrayDouble> loc=_type->getLocalizationOfDiscValues(_mesh);
- _time_discr->fillFromAnalyticNamedCompo(loc,nbOfComp,varsOrder,func);
+ timeDiscr()->fillFromAnalyticNamedCompo(loc,nbOfComp,varsOrder,func);
}
/*!
*/
void MEDCouplingFieldDouble::applyFunc(int nbOfComp, FunctionToEvaluate func)
{
- _time_discr->applyFunc(nbOfComp,func);
+ timeDiscr()->applyFunc(nbOfComp,func);
}
/*!
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform applyFunc !");
int nbOfTuple=_type->getNumberOfTuples(_mesh);
- _time_discr->setUniformValue(nbOfTuple,nbOfComp,val);
+ timeDiscr()->setUniformValue(nbOfTuple,nbOfComp,val);
}
/*!
*/
void MEDCouplingFieldDouble::applyFunc(int nbOfComp, const std::string& func)
{
- _time_discr->applyFunc(nbOfComp,func);
+ timeDiscr()->applyFunc(nbOfComp,func);
}
*/
void MEDCouplingFieldDouble::applyFuncCompo(int nbOfComp, const std::string& func)
{
- _time_discr->applyFuncCompo(nbOfComp,func);
+ timeDiscr()->applyFuncCompo(nbOfComp,func);
}
/*!
*/
void MEDCouplingFieldDouble::applyFuncNamedCompo(int nbOfComp, const std::vector<std::string>& varsOrder, const std::string& func)
{
- _time_discr->applyFuncNamedCompo(nbOfComp,varsOrder,func);
+ timeDiscr()->applyFuncNamedCompo(nbOfComp,varsOrder,func);
}
/*!
*/
void MEDCouplingFieldDouble::applyFunc(const std::string& func)
{
- _time_discr->applyFunc(func);
+ timeDiscr()->applyFunc(func);
}
/*!
*/
void MEDCouplingFieldDouble::applyFuncFast32(const std::string& func)
{
- _time_discr->applyFuncFast32(func);
+ timeDiscr()->applyFuncFast32(func);
}
/*!
*/
void MEDCouplingFieldDouble::applyFuncFast64(const std::string& func)
{
- _time_discr->applyFuncFast64(func);
+ timeDiscr()->applyFuncFast64(func);
}
/*!
void MEDCouplingFieldDouble::updateTime() const
{
MEDCouplingField::updateTime();
- updateTimeWith(*_time_discr);
+ updateTimeWith(*timeDiscr());
}
std::size_t MEDCouplingFieldDouble::getHeapMemorySizeWithoutChildren() const
std::vector<const BigMemoryObject *> MEDCouplingFieldDouble::getDirectChildrenWithNull() const
{
std::vector<const BigMemoryObject *> ret(MEDCouplingField::getDirectChildrenWithNull());
- if(_time_discr)
+ if(timeDiscr())
{
- std::vector<const BigMemoryObject *> ret2(_time_discr->getDirectChildrenWithNull());
+ std::vector<const BigMemoryObject *> ret2(timeDiscr()->getDirectChildrenWithNull());
ret.insert(ret.end(),ret2.begin(),ret2.end());
}
return ret;
}
-/*!
- * Sets \ref NatureOfField.
- * \param [in] nat - an item of enum MEDCoupling::NatureOfField.
- */
-void MEDCouplingFieldDouble::setNature(NatureOfField nat)
-{
- MEDCouplingField::setNature(nat);
- if(_type)
- _type->checkCompatibilityWithNature(nat);
-}
-
-/*!
- * This method synchronizes time information (time, iteration, order, time unit) regarding the information in \c this->_mesh.
- * \throw If no mesh is set in this. Or if \a this is not compatible with time setting (typically NO_TIME)
- */
-void MEDCouplingFieldDouble::synchronizeTimeWithMesh()
-{
- if(!_mesh)
- throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::synchronizeTimeWithMesh : no mesh set in this !");
- int it=-1,ordr=-1;
- double val=_mesh->getTime(it,ordr);
- std::string timeUnit(_mesh->getTimeUnit());
- setTime(val,it,ordr);
- setTimeUnit(timeUnit);
-}
-
/*!
* Returns a value of \a this field of type either
* \ref MEDCoupling::ON_GAUSS_PT "ON_GAUSS_PT" or
* \ref MEDCouplingSpatialDisc "spatial discretization" of \a this field
* (see getNumberOfTuples()), but this size is not checked here.
*/
-void MEDCouplingFieldDouble::setArray(DataArrayDouble *array)
-{
- _time_discr->setArray(array,this);
-}
+//void MEDCouplingFieldDouble::setArray(DataArrayDouble *array)
/*!
* Sets the data array holding values corresponding to an end of a time interval
* \ref MEDCouplingSpatialDisc "spatial discretization" of \a this field
* (see getNumberOfTuples()), but this size is not checked here.
*/
-void MEDCouplingFieldDouble::setEndArray(DataArrayDouble *array)
-{
- _time_discr->setEndArray(array,this);
-}
+//void MEDCouplingFieldDouble::setEndArray(DataArrayDouble *array)
/*!
* Sets all data arrays needed to define the field values.
* \throw If number of arrays in \a arrs does not correspond to type of
* \ref MEDCouplingTemporalDisc "temporal discretization" of \a this field.
*/
-void MEDCouplingFieldDouble::setArrays(const std::vector<DataArrayDouble *>& arrs)
-{
- _time_discr->setArrays(arrs,this);
-}
+//void MEDCouplingFieldDouble::setArrays(const std::vector<DataArrayDouble *>& arrs)
void MEDCouplingFieldDouble::getTinySerializationStrInformation(std::vector<std::string>& tinyInfo) const
{
tinyInfo.clear();
- _time_discr->getTinySerializationStrInformation(tinyInfo);
+ timeDiscr()->getTinySerializationStrInformation(tinyInfo);
tinyInfo.push_back(_name);
tinyInfo.push_back(_desc);
tinyInfo.push_back(getTimeUnit());
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform getTinySerializationIntInformation !");
tinyInfo.clear();
tinyInfo.push_back((int)_type->getEnum());
- tinyInfo.push_back((int)_time_discr->getEnum());
+ tinyInfo.push_back((int)timeDiscr()->getEnum());
tinyInfo.push_back((int)_nature);
- _time_discr->getTinySerializationIntInformation(tinyInfo);
+ timeDiscr()->getTinySerializationIntInformation(tinyInfo);
std::vector<int> tinyInfo2;
_type->getTinySerializationIntInformation(tinyInfo2);
tinyInfo.insert(tinyInfo.end(),tinyInfo2.begin(),tinyInfo2.end());
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform getTinySerializationDbleInformation !");
tinyInfo.clear();
- _time_discr->getTinySerializationDbleInformation(tinyInfo);
+ timeDiscr()->getTinySerializationDbleInformation(tinyInfo);
std::vector<double> tinyInfo2;
_type->getTinySerializationDbleInformation(tinyInfo2);
tinyInfo.insert(tinyInfo.end(),tinyInfo2.begin(),tinyInfo2.end());
tinyInfoITmp.pop_back();
std::vector<int> tinyInfoITmp2(tinyInfoITmp.begin(),tinyInfoITmp.end()-sz);
std::vector<int> tinyInfoI2(tinyInfoITmp2.begin()+3,tinyInfoITmp2.end());
- _time_discr->resizeForUnserialization(tinyInfoI2,arrays);
+ timeDiscr()->resizeForUnserialization(tinyInfoI2,arrays);
std::vector<int> tinyInfoITmp3(tinyInfoITmp.end()-sz,tinyInfoITmp.end());
_type->resizeForUnserialization(tinyInfoITmp3,dataInt);
}
tinyInfoITmp.pop_back();
std::vector<int> tinyInfoITmp2(tinyInfoITmp.begin(),tinyInfoITmp.end()-sz);
std::vector<int> tinyInfoI2(tinyInfoITmp2.begin()+3,tinyInfoITmp2.end());
- _time_discr->checkForUnserialization(tinyInfoI2,arrays);
+ timeDiscr()->checkForUnserialization(tinyInfoI2,arrays);
std::vector<int> tinyInfoITmp3(tinyInfoITmp.end()-sz,tinyInfoITmp.end());
_type->checkForUnserialization(tinyInfoITmp3,dataInt);
}
std::vector<double> tmp1(tmp.begin(),tmp.end()-sz);
std::vector<double> tmp2(tmp.end()-sz,tmp.end());
//
- _time_discr->finishUnserialization(tinyInfoI2,tmp1,tinyInfoS);
+ timeDiscr()->finishUnserialization(tinyInfoI2,tmp1,tinyInfoS);
_nature=(NatureOfField)tinyInfoI[2];
_type->finishUnserialization(tmp2);
int nbOfElemS=(int)tinyInfoS.size();
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform serialize !");
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
_type->getSerializationIntArray(dataInt);
}
if(!ret)//no nodes have been merged.
return ret;
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
for(std::vector<DataArrayDouble *>::const_iterator iter=arrays.begin();iter!=arrays.end();iter++)
if(*iter)
_type->renumberValuesOnNodes(epsOnVals,arr->getConstPointer(),meshC2->getNumberOfNodes(),*iter);
if(!ret)//no nodes have been merged.
return ret;
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
for(std::vector<DataArrayDouble *>::const_iterator iter=arrays.begin();iter!=arrays.end();iter++)
if(*iter)
_type->renumberValuesOnNodes(epsOnVals,arr->getConstPointer(),meshC2->getNumberOfNodes(),*iter);
if(meshC2->getNumberOfNodes()!=oldNbOfNodes)
{
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
for(std::vector<DataArrayDouble *>::const_iterator iter=arrays.begin();iter!=arrays.end();iter++)
if(*iter)
_type->renumberValuesOnNodes(epsOnVals,arr->getConstPointer(),meshC2->getNumberOfNodes(),*iter);
if(meshC2->getNumberOfCells()!=oldNbOfCells)
{
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
for(std::vector<DataArrayDouble *>::const_iterator iter=arrays.begin();iter!=arrays.end();iter++)
if(*iter)
_type->renumberValuesOnCells(epsOnVals,meshC,arr->getConstPointer(),meshC2->getNumberOfCells(),*iter);
ret->setMesh(mesh2);
MCAuto<DataArrayInt> tupleIds=computeTupleIdsToSelectFromCellIds(cellIds->begin(),cellIds->end());
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
int i=0;
std::vector<DataArrayDouble *> newArr(arrays.size());
std::vector< MCAuto<DataArrayDouble> > newArr2(arrays.size());
if(oldNbOfCells==newNbOfCells)
return false;
std::vector<DataArrayDouble *> arrays;
- _time_discr->getArrays(arrays);
+ timeDiscr()->getArrays(arrays);
for(std::vector<DataArrayDouble *>::const_iterator iter=arrays.begin();iter!=arrays.end();iter++)
if(*iter)
_type->renumberValuesOnCellsR(_mesh,arr->getConstPointer(),arr->getNbOfElems(),*iter);
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform doublyContractedProduct !");
- MEDCouplingTimeDiscretization *td=_time_discr->doublyContractedProduct();
- td->copyTinyAttrFrom(*_time_discr);
+ MEDCouplingTimeDiscretization *td=timeDiscr()->doublyContractedProduct();
+ td->copyTinyAttrFrom(*timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(getNature(),td,_type->clone());
ret->setName("DoublyContractedProduct");
ret->setMesh(getMesh());
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform determinant !");
- MEDCouplingTimeDiscretization *td=_time_discr->determinant();
- td->copyTinyAttrFrom(*_time_discr);
+ MEDCouplingTimeDiscretization *td=timeDiscr()->determinant();
+ td->copyTinyAttrFrom(*timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(getNature(),td,_type->clone());
ret->setName("Determinant");
ret->setMesh(getMesh());
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform eigenValues !");
- MEDCouplingTimeDiscretization *td=_time_discr->eigenValues();
- td->copyTinyAttrFrom(*_time_discr);
+ MEDCouplingTimeDiscretization *td=timeDiscr()->eigenValues();
+ td->copyTinyAttrFrom(*timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(getNature(),td,_type->clone());
ret->setName("EigenValues");
ret->setMesh(getMesh());
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform eigenVectors !");
- MEDCouplingTimeDiscretization *td=_time_discr->eigenVectors();
- td->copyTinyAttrFrom(*_time_discr);
+ MEDCouplingTimeDiscretization *td=timeDiscr()->eigenVectors();
+ td->copyTinyAttrFrom(*timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(getNature(),td,_type->clone());
ret->setName("EigenVectors");
ret->setMesh(getMesh());
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform inverse !");
- MEDCouplingTimeDiscretization *td=_time_discr->inverse();
- td->copyTinyAttrFrom(*_time_discr);
+ MEDCouplingTimeDiscretization *td=timeDiscr()->inverse();
+ td->copyTinyAttrFrom(*timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(getNature(),td,_type->clone());
ret->setName("Inversion");
ret->setMesh(getMesh());
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform trace !");
- MEDCouplingTimeDiscretization *td=_time_discr->trace();
- td->copyTinyAttrFrom(*_time_discr);
+ MEDCouplingTimeDiscretization *td=timeDiscr()->trace();
+ td->copyTinyAttrFrom(*timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(getNature(),td,_type->clone());
ret->setName("Trace");
ret->setMesh(getMesh());
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform deviator !");
- MEDCouplingTimeDiscretization *td=_time_discr->deviator();
- td->copyTinyAttrFrom(*_time_discr);
+ MEDCouplingTimeDiscretization *td=timeDiscr()->deviator();
+ td->copyTinyAttrFrom(*timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(getNature(),td,_type->clone());
ret->setName("Deviator");
ret->setMesh(getMesh());
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform magnitude !");
- MEDCouplingTimeDiscretization *td=_time_discr->magnitude();
- td->copyTinyAttrFrom(*_time_discr);
+ MEDCouplingTimeDiscretization *td=timeDiscr()->magnitude();
+ td->copyTinyAttrFrom(*timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(getNature(),td,_type->clone());
ret->setName("Magnitude");
ret->setMesh(getMesh());
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform maxPerTuple !");
- MEDCouplingTimeDiscretization *td=_time_discr->maxPerTuple();
- td->copyTinyAttrFrom(*_time_discr);
+ MEDCouplingTimeDiscretization *td=timeDiscr()->maxPerTuple();
+ td->copyTinyAttrFrom(*timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(getNature(),td,_type->clone());
std::ostringstream oss;
oss << "Max_" << getName();
*/
void MEDCouplingFieldDouble::changeNbOfComponents(int newNbOfComp, double dftValue)
{
- _time_discr->changeNbOfComponents(newNbOfComp,dftValue);
+ timeDiscr()->changeNbOfComponents(newNbOfComp,dftValue);
}
/*!
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform keepSelectedComponents !");
- MEDCouplingTimeDiscretization *td=_time_discr->keepSelectedComponents(compoIds);
- td->copyTinyAttrFrom(*_time_discr);
+ MEDCouplingTimeDiscretization *td=timeDiscr()->keepSelectedComponents(compoIds);
+ td->copyTinyAttrFrom(*timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(getNature(),td,_type->clone());
ret->setName(getName());
ret->setMesh(getMesh());
*/
void MEDCouplingFieldDouble::setSelectedComponents(const MEDCouplingFieldDouble *f, const std::vector<int>& compoIds)
{
- _time_discr->setSelectedComponents(f->_time_discr,compoIds);
+ timeDiscr()->setSelectedComponents(f->timeDiscr(),compoIds);
}
/*!
*/
void MEDCouplingFieldDouble::sortPerTuple(bool asc)
{
- _time_discr->sortPerTuple(asc);
+ timeDiscr()->sortPerTuple(asc);
}
/*!
if(!f1->areCompatibleForMerge(f2))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply MergeFields on them ! Check support mesh, field nature, and spatial and time discretisation.");
const MEDCouplingMesh *m1(f1->getMesh()),*m2(f2->getMesh());
- if(!f1->_time_discr)
+ if(!f1->timeDiscr())
throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::MergeFields : no time discr of f1 !");
if(!f1->_type)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::MergeFields : no spatial discr of f1 !");
- MEDCouplingTimeDiscretization *td=f1->_time_discr->aggregate(f2->_time_discr);
- td->copyTinyAttrFrom(*f1->_time_discr);
+ MEDCouplingTimeDiscretization *td=f1->timeDiscr()->aggregate(f2->timeDiscr());
+ td->copyTinyAttrFrom(*f1->timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(f1->getNature(),td,f1->_type->clone());
ret->setName(f1->getName());
ret->setDescription(f1->getDescription());
{ ms[i]=a[i]->getMesh()->buildUnstructured(); ms2[i]=ms[i]; }
else
{ ms[i]=0; ms2[i]=0; }
- tds[i]=a[i]->_time_discr;
+ tds[i]=a[i]->timeDiscr();
}
MEDCouplingTimeDiscretization *td=tds[0]->aggregate(tds);
- td->copyTinyAttrFrom(*(a[0]->_time_discr));
+ td->copyTinyAttrFrom(*(a[0]->timeDiscr()));
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(a[0]->getNature(),td,a[0]->_type->clone());
ret->setName(a[0]->getName());
ret->setDescription(a[0]->getDescription());
{
if(!f1->areCompatibleForMeld(f2))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply MeldFields on them ! Check support mesh, field nature, and spatial and time discretisation.");
- MEDCouplingTimeDiscretization *td=f1->_time_discr->meld(f2->_time_discr);
- td->copyTinyAttrFrom(*f1->_time_discr);
+ MEDCouplingTimeDiscretization *td=f1->timeDiscr()->meld(f2->timeDiscr());
+ td->copyTinyAttrFrom(*f1->timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(f1->getNature(),td,f1->_type->clone());
ret->setMesh(f1->getMesh());
return ret.retn();
throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::DotFields : input field is NULL !");
if(!f1->areStrictlyCompatibleForMulDiv(f2))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply DotFields on them! Check support mesh, and spatial and time discretisation.");
- MEDCouplingTimeDiscretization *td=f1->_time_discr->dot(f2->_time_discr);
- td->copyTinyAttrFrom(*f1->_time_discr);
+ MEDCouplingTimeDiscretization *td=f1->timeDiscr()->dot(f2->timeDiscr());
+ td->copyTinyAttrFrom(*f1->timeDiscr());
MEDCouplingFieldDouble *ret=new MEDCouplingFieldDouble(NoNature,td,f1->_type->clone());
ret->setMesh(f1->getMesh());
return ret;
throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::CrossProductFields : input field is NULL !");
if(!f1->areStrictlyCompatibleForMulDiv(f2))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply CrossProductFields on them! Check support mesh, and spatial and time discretisation.");
- MEDCouplingTimeDiscretization *td=f1->_time_discr->crossProduct(f2->_time_discr);
- td->copyTinyAttrFrom(*f1->_time_discr);
+ MEDCouplingTimeDiscretization *td=f1->timeDiscr()->crossProduct(f2->timeDiscr());
+ td->copyTinyAttrFrom(*f1->timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(NoNature,td,f1->_type->clone());
ret->setMesh(f1->getMesh());
return ret.retn();
throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::MaxFields : input field is NULL !");
if(!f1->areStrictlyCompatible(f2))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply MaxFields on them! Check support mesh, field nature, and spatial and time discretisation.");
- MEDCouplingTimeDiscretization *td=f1->_time_discr->max(f2->_time_discr);
- td->copyTinyAttrFrom(*f1->_time_discr);
+ MEDCouplingTimeDiscretization *td=f1->timeDiscr()->max(f2->timeDiscr());
+ td->copyTinyAttrFrom(*f1->timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(f1->getNature(),td,f1->_type->clone());
ret->setMesh(f1->getMesh());
return ret.retn();
throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::MinFields : input field is NULL !");
if(!f1->areStrictlyCompatible(f2))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply MinFields on them! Check support mesh, field nature, and spatial and time discretisation.");
- MEDCouplingTimeDiscretization *td=f1->_time_discr->min(f2->_time_discr);
- td->copyTinyAttrFrom(*f1->_time_discr);
+ MEDCouplingTimeDiscretization *td=f1->timeDiscr()->min(f2->timeDiscr());
+ td->copyTinyAttrFrom(*f1->timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(f1->getNature(),td,f1->_type->clone());
ret->setMesh(f1->getMesh());
return ret.retn();
{
if(!((const MEDCouplingFieldDiscretization *)_type))
throw INTERP_KERNEL::Exception("No spatial discretization underlying this field to perform negate !");
- MEDCouplingTimeDiscretization *td=_time_discr->negate();
- td->copyTinyAttrFrom(*_time_discr);
+ MEDCouplingTimeDiscretization *td=timeDiscr()->negate();
+ td->copyTinyAttrFrom(*timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(getNature(),td,_type->clone());
ret->setMesh(getMesh());
return ret.retn();
throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::AddFields : input field is NULL !");
if(!f1->areStrictlyCompatible(f2))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply AddFields on them! Check support mesh, field nature, and spatial and time discretisation.");
- MEDCouplingTimeDiscretization *td=f1->_time_discr->add(f2->_time_discr);
- td->copyTinyAttrFrom(*f1->_time_discr);
+ MEDCouplingTimeDiscretization *td=f1->timeDiscr()->add(f2->timeDiscr());
+ td->copyTinyAttrFrom(*f1->timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(f1->getNature(),td,f1->_type->clone());
ret->setMesh(f1->getMesh());
return ret.retn();
{
if(!areStrictlyCompatible(&other))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply += on them! Check support mesh, field nature, and spatial and time discretisation.");
- _time_discr->addEqual(other._time_discr);
+ timeDiscr()->addEqual(other.timeDiscr());
return *this;
}
throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::SubstractFields : input field is NULL !");
if(!f1->areStrictlyCompatible(f2))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply SubstractFields on them! Check support mesh, field nature, and spatial and time discretisation.");
- MEDCouplingTimeDiscretization *td=f1->_time_discr->substract(f2->_time_discr);
- td->copyTinyAttrFrom(*f1->_time_discr);
+ MEDCouplingTimeDiscretization *td=f1->timeDiscr()->substract(f2->timeDiscr());
+ td->copyTinyAttrFrom(*f1->timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(f1->getNature(),td,f1->_type->clone());
ret->setMesh(f1->getMesh());
return ret.retn();
{
if(!areStrictlyCompatible(&other))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply -= on them! Check support mesh, field nature, and spatial and time discretisation.");
- _time_discr->substractEqual(other._time_discr);
+ timeDiscr()->substractEqual(other.timeDiscr());
return *this;
}
throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::MultiplyFields : input field is NULL !");
if(!f1->areCompatibleForMul(f2))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply MultiplyFields on them! Check support mesh, and spatial and time discretisation.");
- MEDCouplingTimeDiscretization *td=f1->_time_discr->multiply(f2->_time_discr);
- td->copyTinyAttrFrom(*f1->_time_discr);
+ MEDCouplingTimeDiscretization *td=f1->timeDiscr()->multiply(f2->timeDiscr());
+ td->copyTinyAttrFrom(*f1->timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(NoNature,td,f1->_type->clone());
ret->setMesh(f1->getMesh());
return ret.retn();
{
if(!areCompatibleForMul(&other))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply *= on them! Check support mesh, and spatial and time discretisation.");
- _time_discr->multiplyEqual(other._time_discr);
+ timeDiscr()->multiplyEqual(other.timeDiscr());
_nature = NoNature;
return *this;
}
throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::DivideFields : input field is NULL !");
if(!f1->areCompatibleForDiv(f2))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply DivideFields on them! Check support mesh, and spatial and time discretisation.");
- MEDCouplingTimeDiscretization *td=f1->_time_discr->divide(f2->_time_discr);
- td->copyTinyAttrFrom(*f1->_time_discr);
+ MEDCouplingTimeDiscretization *td=f1->timeDiscr()->divide(f2->timeDiscr());
+ td->copyTinyAttrFrom(*f1->timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(NoNature,td,f1->_type->clone());
ret->setMesh(f1->getMesh());
return ret.retn();
{
if(!areCompatibleForDiv(&other))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply /= on them! Check support mesh, and spatial and time discretisation.");
- _time_discr->divideEqual(other._time_discr);
+ timeDiscr()->divideEqual(other.timeDiscr());
_nature = NoNature;
return *this;
}
throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble::PowFields : input field is NULL !");
if(!f1->areCompatibleForMul(f2))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply PowFields on them! Check support mesh, and spatial and time discretisation.");
- MEDCouplingTimeDiscretization *td=f1->_time_discr->pow(f2->_time_discr);
- td->copyTinyAttrFrom(*f1->_time_discr);
+ MEDCouplingTimeDiscretization *td=f1->timeDiscr()->pow(f2->timeDiscr());
+ td->copyTinyAttrFrom(*f1->timeDiscr());
MCAuto<MEDCouplingFieldDouble> ret=new MEDCouplingFieldDouble(NoNature,td,f1->_type->clone());
ret->setMesh(f1->getMesh());
return ret.retn();
{
if(!areCompatibleForDiv(&other))
throw INTERP_KERNEL::Exception("Fields are not compatible. Unable to apply ^= on them! Check support mesh, and spatial and time discretisation.");
- _time_discr->powEqual(other._time_discr);
+ timeDiscr()->powEqual(other.timeDiscr());
_nature = NoNature;
return *this;
}
if(name.empty())
{
std::ostringstream oss; oss << "MEDCouplingFieldDouble::WriteVTK : Field in pos #" << i << " has no name !";
- throw INTERP_KERNEL::Exception(oss.str().c_str());
+ throw INTERP_KERNEL::Exception(oss.str());
}
TypeOfField typ=cur->getTypeOfField();
if(typ==ON_CELLS)
return ret;
}
-void MEDCouplingFieldDouble::reprQuickOverview(std::ostream& stream) const
-{
- stream << "MEDCouplingFieldDouble C++ instance at " << this << ". Name : \"" << _name << "\"." << std::endl;
- const char *nat=0;
- try
- {
- nat=MEDCouplingNatureOfField::GetRepr(_nature);
- stream << "Nature of field : " << nat << ".\n";
- }
- catch(INTERP_KERNEL::Exception& /*e*/)
- { }
- const MEDCouplingFieldDiscretization *fd(_type);
- if(!fd)
- stream << "No spatial discretization set !";
- else
- fd->reprQuickOverview(stream);
- stream << std::endl;
- if(!_mesh)
- stream << "\nNo mesh support defined !";
- else
- {
- std::ostringstream oss;
- _mesh->reprQuickOverview(oss);
- std::string tmp(oss.str());
- stream << "\nMesh info : " << tmp.substr(0,tmp.find('\n'));
- }
- if(_time_discr)
- {
- const DataArrayDouble *arr=_time_discr->getArray();
- if(arr)
- {
- stream << "\n\nArray info : ";
- arr->reprQuickOverview(stream);
- }
- else
- {
- stream << "\n\nNo data array set !";
- }
- }
+MEDCouplingTimeDiscretization *MEDCouplingFieldDouble::timeDiscr()
+{
+ MEDCouplingTimeDiscretizationTemplate<double> *ret(_time_discr);
+ if(!ret)
+ return 0;
+ MEDCouplingTimeDiscretization *retc(dynamic_cast<MEDCouplingTimeDiscretization *>(ret));
+ if(!retc)
+ throw INTERP_KERNEL::Exception("Field Double Null invalid type of time discr !");
+ return retc;
+}
+
+const MEDCouplingTimeDiscretization *MEDCouplingFieldDouble::timeDiscr() const
+{
+ const MEDCouplingTimeDiscretizationTemplate<double> *ret(_time_discr);
+ if(!ret)
+ return 0;
+ const MEDCouplingTimeDiscretization *retc(dynamic_cast<const MEDCouplingTimeDiscretization *>(ret));
+ if(!retc)
+ throw INTERP_KERNEL::Exception("Field Double Null invalid type of time discr !");
+ return retc;
}