-// Copyright (C) 2007-2013 CEA/DEN, EDF R&D
+// Copyright (C) 2007-2014 CEA/DEN, EDF R&D
//
// This library is free software; you can redistribute it and/or
// modify it under the terms of the GNU Lesser General Public
// License as published by the Free Software Foundation; either
-// version 2.1 of the License.
+// version 2.1 of the License, or (at your option) any later version.
//
// This library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
{
int meshInterpType=((int)_src_ft->getMesh()->getType()*16)+(int)_target_ft->getMesh()->getType();
switch(meshInterpType)
- {
+ {
case 90:
case 91:
case 165:
return prepareInterpKernelOnlyEE();
default:
throw INTERP_KERNEL::Exception("MEDCouplingRemapper::prepareInterpKernelOnly : Not managed type of meshes ! Dealt meshes type are : Unstructured<->Unstructured, Unstructured<->Cartesian, Cartesian<->Cartesian, Extruded<->Extruded !");
- }
+ }
}
int MEDCouplingRemapper::prepareNotInterpKernelOnly()
std::string srcm,trgm,method;
method=checkAndGiveInterpolationMethodStr(srcm,trgm);
switch(CheckInterpolationMethodManageableByNotOnlyInterpKernel(method))
- {
+ {
case 0:
return prepareNotInterpKernelOnlyGaussGauss();
default:
std::ostringstream oss; oss << "MEDCouplingRemapper::prepareNotInterpKernelOnly : INTERNAL ERROR ! the method \"" << method << "\" declared as managed bu not implemented !";
throw INTERP_KERNEL::Exception(oss.str().c_str());
}
- }
+ }
}
/*!
void MEDCouplingRemapper::setInterpolationMatrixPolicy(int newInterpMatPol)
{
switch(newInterpMatPol)
- {
+ {
case 0:
_interp_matrix_pol=IK_ONLY_PREFERED;
break;
break;
default:
throw INTERP_KERNEL::Exception("MEDCouplingRemapper::setInterpolationMatrixPolicy : invalid input integer value ! Should be in [0 (IK_PREFERED) , 1 (NOT_IK_PREFERED), 2 (IK_ONLY_FORCED), 3 (NOT_IK_ONLY_FORCED)] ! For information, the default is IK_PREFERED=0 !");
- }
+ }
}
int MEDCouplingRemapper::prepareInterpKernelOnlyUU()
const MEDCouplingPointSet *src_mesh=static_cast<const MEDCouplingPointSet *>(_src_ft->getMesh());
const MEDCouplingPointSet *target_mesh=static_cast<const MEDCouplingPointSet *>(_target_ft->getMesh());
std::string srcMeth,trgMeth;
- std::string method=checkAndGiveInterpolationMethodStr(srcMeth,trgMeth);
+ std::string method(checkAndGiveInterpolationMethodStr(srcMeth,trgMeth));
const int srcMeshDim=src_mesh->getMeshDimension();
int srcSpaceDim=-1;
if(srcMeshDim!=-1)
MEDCouplingNormalizedUnstructuredMesh<3,3> target_mesh_wrapper(target_mesh);
INTERP_KERNEL::Interpolation3D interpolation(*this);
std::vector<std::map<int,double> > matrixTmp;
- nbCols=interpolation.interpolateMeshes(target_mesh_wrapper,source_mesh_wrapper,matrixTmp,method);
+ std::string revMethod(BuildMethodFrom(trgMeth,srcMeth));
+ nbCols=interpolation.interpolateMeshes(target_mesh_wrapper,source_mesh_wrapper,matrixTmp,revMethod);
ReverseMatrix(matrixTmp,nbCols,_matrix);
nbCols=matrixTmp.size();
}
MEDCouplingNormalizedUnstructuredMesh<2,2> target_mesh_wrapper(target_mesh);
INTERP_KERNEL::Interpolation2D1D interpolation(*this);
std::vector<std::map<int,double> > matrixTmp;
- nbCols=interpolation.interpolateMeshes(target_mesh_wrapper,source_mesh_wrapper,matrixTmp,method);
+ std::string revMethod(BuildMethodFrom(trgMeth,srcMeth));
+ nbCols=interpolation.interpolateMeshes(target_mesh_wrapper,source_mesh_wrapper,matrixTmp,revMethod);
ReverseMatrix(matrixTmp,nbCols,_matrix);
nbCols=matrixTmp.size();
INTERP_KERNEL::Interpolation2D1D::DuplicateFacesType duplicateFaces=interpolation.retrieveDuplicateFaces();
MEDCouplingNormalizedUnstructuredMesh<2,2> target_mesh_wrapper(target_mesh);
INTERP_KERNEL::Interpolation2D interpolation(*this);
std::vector<std::map<int,double> > matrixTmp;
- nbCols=interpolation.interpolateMeshes(target_mesh_wrapper,source_mesh_wrapper,matrixTmp,method);
+ std::string revMethod(BuildMethodFrom(trgMeth,srcMeth));
+ nbCols=interpolation.interpolateMeshes(target_mesh_wrapper,source_mesh_wrapper,matrixTmp,revMethod);
ReverseMatrix(matrixTmp,nbCols,_matrix);
nbCols=matrixTmp.size();
}
MEDCouplingNormalizedUnstructuredMesh<3,3> target_mesh_wrapper(target_mesh);
INTERP_KERNEL::Interpolation3D2D interpolation(*this);
std::vector<std::map<int,double> > matrixTmp;
- nbCols=interpolation.interpolateMeshes(target_mesh_wrapper,source_mesh_wrapper,matrixTmp,method);
+ std::string revMethod(BuildMethodFrom(trgMeth,srcMeth));
+ nbCols=interpolation.interpolateMeshes(target_mesh_wrapper,source_mesh_wrapper,matrixTmp,revMethod);
ReverseMatrix(matrixTmp,nbCols,_matrix);
nbCols=matrixTmp.size();
INTERP_KERNEL::Interpolation3D2D::DuplicateFacesType duplicateFaces=interpolation.retrieveDuplicateFaces();
throw INTERP_KERNEL::Exception("MEDCouplingRemapper::prepareInterpKernelOnlyUC : space dim of src unstructured should be equal to mesh dim of src unstructured and should be equal also equal to trg cartesian dimension !");
std::vector<std::map<int,double> > res;
switch(srcMeshDim)
- {
+ {
case 1:
{
MEDCouplingNormalizedCartesianMesh<1> targetWrapper(target_mesh);
}
default:
throw INTERP_KERNEL::Exception("MEDCouplingRemapper::prepareInterpKernelOnlyUC : only dimension 1 2 or 3 supported !");
- }
+ }
ReverseMatrix(res,target_mesh->getNumberOfCells(),_matrix);
nullifiedTinyCoeffInCrudeMatrixAbs(0.);
//
if(trgMeshDim!=trgSpceDim || trgMeshDim!=srcMeshDim)
throw INTERP_KERNEL::Exception("MEDCouplingRemapper::prepareInterpKernelOnlyCU : space dim of target unstructured should be equal to mesh dim of target unstructured and should be equal also equal to source cartesian dimension !");
switch(srcMeshDim)
- {
+ {
case 1:
{
MEDCouplingNormalizedCartesianMesh<1> sourceWrapper(src_mesh);
}
default:
throw INTERP_KERNEL::Exception("MEDCouplingRemapper::prepareInterpKernelOnlyCU : only dimension 1 2 or 3 supported !");
- }
+ }
nullifiedTinyCoeffInCrudeMatrixAbs(0.);
//
_deno_multiply.clear();
if(trgMeshDim!=srcMeshDim)
throw INTERP_KERNEL::Exception("MEDCouplingRemapper::prepareInterpKernelOnlyCC : dim of target cartesian should be equal to dim of source cartesian dimension !");
switch(srcMeshDim)
- {
+ {
case 1:
{
MEDCouplingNormalizedCartesianMesh<1> sourceWrapper(src_mesh);
}
default:
throw INTERP_KERNEL::Exception("MEDCouplingRemapper::prepareInterpKernelOnlyCC : only dimension 1 2 or 3 supported !");
- }
+ }
nullifiedTinyCoeffInCrudeMatrixAbs(0.);
//
_deno_multiply.clear();
int MEDCouplingRemapper::prepareNotInterpKernelOnlyGaussGauss()
{
if(getIntersectionType()!=INTERP_KERNEL::PointLocator)
- throw INTERP_KERNEL::Exception("MEDCouplingRemapper::prepareNotInterpKernelOnlyGaussGauss : The intersection type is not supported ! Only PointLocator is supported for Gauss->Gauss interpolation ! Please invoke setIntersectionType(PointLocator) on the MEDCouplingRemapper instance !");
+ throw INTERP_KERNEL::Exception("MEDCouplingRemapper::prepareNotInterpKernelOnlyGaussGauss : The intersection type is not supported ! Only PointLocator is supported for Gauss->Gauss interpolation ! Please invoke setIntersectionType(PointLocator) on the MEDCouplingRemapper instance !");
MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> trgLoc=_target_ft->getLocalizationOfDiscr();
const double *trgLocPtr=trgLoc->begin();
int trgSpaceDim=trgLoc->getNumberOfComponents();
std::string srcm,trgm,method;
method=checkAndGiveInterpolationMethodStr(srcm,trgm);
switch(_interp_matrix_pol)
- {
+ {
case IK_ONLY_PREFERED:
{
try
- {
+ {
std::string tmp1,tmp2;
INTERP_KERNEL::Interpolation<INTERP_KERNEL::Interpolation3D>::CheckAndSplitInterpolationMethod(method,tmp1,tmp2);
return true;
- }
+ }
catch(INTERP_KERNEL::Exception& /*e*/)
- {
+ {
return false;
- }
+ }
}
case NOT_IK_ONLY_PREFERED:
{
try
- {
+ {
CheckInterpolationMethodManageableByNotOnlyInterpKernel(method);
return false;
- }
+ }
catch(INTERP_KERNEL::Exception& /*e*/)
- {
+ {
return true;
- }
+ }
}
case IK_ONLY_FORCED:
return true;
return false;
default:
throw INTERP_KERNEL::Exception("MEDCouplingRemapper::isInterpKernelOnlyOrNotOnly : internal error ! The interpolation matrix policy is not managed ! Try to change it using MEDCouplingRemapper::setInterpolationMatrixPolicy !");
- }
+ }
}
void MEDCouplingRemapper::updateTime() const
throw INTERP_KERNEL::Exception("MEDCouplingRemapper::checkAndGiveInterpolationMethodStr : it appears that no all field templates have their mesh set !");
srcMeth=_src_ft->getDiscretization()->getRepr();
trgMeth=_target_ft->getDiscretization()->getRepr();
- std::string method(srcMeth); method+=trgMeth;
+ return BuildMethodFrom(srcMeth,trgMeth);
+}
+
+std::string MEDCouplingRemapper::BuildMethodFrom(const std::string& meth1, const std::string& meth2)
+{
+ std::string method(meth1); method+=meth2;
return method;
}
if(nat==NoNature)
return computeDenoFromScratch(nat,srcField,trgField);
else if(nat!=_nature_of_deno)
- return computeDenoFromScratch(nat,srcField,trgField);
+ return computeDenoFromScratch(nat,srcField,trgField);
else if(nat==_nature_of_deno && _time_deno_update!=getTimeOfThis())
return computeDenoFromScratch(nat,srcField,trgField);
}
_nature_of_deno=nat;
_time_deno_update=getTimeOfThis();
switch(_nature_of_deno)
- {
+ {
case ConservativeVolumic:
{
ComputeRowSumAndColSum(_matrix,_deno_multiply,_deno_reverse_multiply);
}
case NoNature:
throw INTERP_KERNEL::Exception("No nature specified ! Select one !");
- }
+ }
}
void MEDCouplingRemapper::computeProduct(const double *inputPointer, int inputNbOfCompo, bool isDftVal, double dftValue, double *resPointer)