-// Copyright (C) 2007-2013 CEA/DEN, EDF R&D
+// Copyright (C) 2007-2016 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
//
// See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
//
-// Author : Anthony Geay (CEA/DEN)
+// Author : Anthony Geay (EDF R&D)
#include "MEDCouplingFieldDiscretization.hxx"
#include "MEDCouplingCMesh.hxx"
#include "MEDCouplingUMesh.hxx"
#include "MEDCouplingFieldDouble.hxx"
-#include "MEDCouplingAutoRefCountObjectPtr.hxx"
+#include "MCAuto.hxx"
#include "CellModel.hxx"
#include "InterpolationUtils.hxx"
#include <algorithm>
#include <functional>
-using namespace ParaMEDMEM;
+using namespace MEDCoupling;
const double MEDCouplingFieldDiscretization::DFLT_PRECISION=1.e-12;
const TypeOfField MEDCouplingFieldDiscretizationKriging::TYPE=ON_NODES_KR;
// doc is here http://www.code-aster.org/V2/doc/default/fr/man_r/r3/r3.01.01.pdf
+const double MEDCouplingFieldDiscretizationGaussNE::FGP_POINT1[1]={0.};
const double MEDCouplingFieldDiscretizationGaussNE::FGP_SEG2[2]={1.,1.};
-const double MEDCouplingFieldDiscretizationGaussNE::FGP_SEG3[3]={0.5555555555555556,0.5555555555555556,0.8888888888888888};
+const double MEDCouplingFieldDiscretizationGaussNE::FGP_SEG3[3]={0.5555555555555556,0.8888888888888888,0.5555555555555556};
const double MEDCouplingFieldDiscretizationGaussNE::FGP_SEG4[4]={0.347854845137454,0.347854845137454,0.652145154862546,0.652145154862546};
const double MEDCouplingFieldDiscretizationGaussNE::FGP_TRI3[3]={0.16666666666666666,0.16666666666666666,0.16666666666666666};
const double MEDCouplingFieldDiscretizationGaussNE::FGP_TRI6[6]={0.0549758718227661,0.0549758718227661,0.0549758718227661,0.11169079483905,0.11169079483905,0.11169079483905};
const double MEDCouplingFieldDiscretizationGaussNE::FGP_TRI7[7]={0.062969590272413,0.062969590272413,0.062969590272413,0.066197076394253,0.066197076394253,0.066197076394253,0.1125};
const double MEDCouplingFieldDiscretizationGaussNE::FGP_QUAD4[4]={1.,1.,1.,1.};
+const double MEDCouplingFieldDiscretizationGaussNE::FGP_QUAD8[8]={1.,1.,1.,1.,1.,1.,1.,1.};
const double MEDCouplingFieldDiscretizationGaussNE::FGP_QUAD9[9]={0.30864197530864196,0.30864197530864196,0.30864197530864196,0.30864197530864196,0.49382716049382713,0.49382716049382713,0.49382716049382713,0.49382716049382713,0.7901234567901234};
const double MEDCouplingFieldDiscretizationGaussNE::FGP_TETRA4[4]={0.041666666666666664,0.041666666666666664,0.041666666666666664,0.041666666666666664};
+const double MEDCouplingFieldDiscretizationGaussNE::FGP_TETRA10[10]={1.,1.,1.,1.,1.,1.,1.,1.,1.,1.};//to check
const double MEDCouplingFieldDiscretizationGaussNE::FGP_PENTA6[6]={0.16666666666666666,0.16666666666666666,0.16666666666666666,0.16666666666666666,0.16666666666666666,0.16666666666666666};
+const double MEDCouplingFieldDiscretizationGaussNE::FGP_PENTA15[15]={1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.};//to check
const double MEDCouplingFieldDiscretizationGaussNE::FGP_HEXA8[8]={1.,1.,1.,1.,1.,1.,1.,1.};
-const double MEDCouplingFieldDiscretizationGaussNE::FGP_HEXA27[27]={0.1714677640603567,0.1714677640603567,0.1714677640603567,0.1714677640603567,0.1714677640603567,0.1714677640603567,0.1714677640603567,0.1714677640603567,0.27434842249657065,0.27434842249657065,0.27434842249657065,0.27434842249657065,0.27434842249657065,0.27434842249657065,0.27434842249657065,0.27434842249657065,0.27434842249657065,0.27434842249657065,0.27434842249657065,0.27434842249657065,0.43895747599451296,0.43895747599451296,0.43895747599451296,0.43895747599451296,0.43895747599451296,0.43895747599451296,0.7023319615912208};
+const double MEDCouplingFieldDiscretizationGaussNE::FGP_HEXA20[20]={1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.};
+const double MEDCouplingFieldDiscretizationGaussNE::FGP_HEXA27[27]={1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.};
const double MEDCouplingFieldDiscretizationGaussNE::FGP_PYRA5[5]={0.13333333333333333,0.13333333333333333,0.13333333333333333,0.13333333333333333,0.13333333333333333};
+const double MEDCouplingFieldDiscretizationGaussNE::FGP_PYRA13[13]={1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.,1.};//to check
const double MEDCouplingFieldDiscretizationGaussNE::REF_SEG2[2]={-1.,1.};
-const double MEDCouplingFieldDiscretizationGaussNE::REF_SEG3[3]={-1.,0.,1.};
+const double MEDCouplingFieldDiscretizationGaussNE::REF_SEG3[3]={-1.,1.,0.};
const double MEDCouplingFieldDiscretizationGaussNE::REF_SEG4[4]={-1.,1.,-0.3333333333333333,0.3333333333333333};
const double MEDCouplingFieldDiscretizationGaussNE::REF_TRI3[6]={0.,0.,1.,0.,0.,1.};
const double MEDCouplingFieldDiscretizationGaussNE::REF_TRI6[12]={0.,0.,1.,0.,0.,1.,0.5,0.,0.5,0.5,0.,0.5};
const double MEDCouplingFieldDiscretizationGaussNE::REF_PENTA15[45]={-1.,1.,0.,-1.,0.,1.,-1.,0.,0.,1.,1.,0.,1.,0.,1.,1.,0.,0.,-1.,0.5,0.5,-1.,0.,0.5,-1.,0.5,0.,0.,1.,0.,0.,0.,1.,0.,0.,0.,1.,0.5,0.5,1.,0.,0.5,1.,0.5,0.};
const double MEDCouplingFieldDiscretizationGaussNE::REF_HEXA8[24]={-1.,-1.,-1.,1.,-1.,-1.,1.,1.,-1.,-1.,1.,-1.,-1.,-1.,1.,1.,-1.,1.,1.,1.,1.,-1.,1.,1.};
const double MEDCouplingFieldDiscretizationGaussNE::REF_HEXA20[60]={-1.,-1.,-1.,1.,-1.,-1.,1.,1.,-1.,-1.,1.,-1.,-1.,-1.,1.,1.,-1.,1.,1.,1.,1.,-1.,1.,1.,0.,-1.,-1.,1.,0.,-1.,0.,1.,-1.,-1.,0.,-1.,-1.,-1.,0.,1.,-1.,0.,1.,1.,0.,-1.,1.,0.,0.,-1.,1.,1.,0.,1.,0.,1.,1.,-1.,0.,1.};
-const double MEDCouplingFieldDiscretizationGaussNE::REF_HEXA27[81]={-1.,-1.,-1.,1.,-1.,-1.,1.,1.,-1.,-1.,1.,-1.,-1.,-1.,1.,1.,-1.,1.,1.,1.,1.,-1.,1.,1.,0.,-1.,-1.,1.,0.,-1.,0.,1.,-1.,-1.,0.,-1.,-1.,-1.,0.,1.,-1.,0.,1.,1.,0.,-1.,1.,0.,0.,-1.,1.,1.,0.,1.,0.,1.,1.,-1.,0.,1.,0.,0.,-1.,0.,-1.,0.,1.,0.,0.,0.,1.,0.,-1.,0.,0.,0.,0.,1.,0.,0.,0.};
+const double MEDCouplingFieldDiscretizationGaussNE::REF_HEXA27[81]={-1.,-1.,-1.,-1.,1.,-1.,1.,1.,-1.,1.,-1.,-1.,-1.,-1.,1.,-1.,1.,1.,1.,1.,1.,1.,-1.,1.,-1.,0.,-1.,0.,1.,-1.,1.,0.,-1.,0.,-1.,-1.,-1.,0.,1.,0.,1.,1.,1.,0.,1.,0.,-1.,1.,-1.,-1.,0.,-1.,1.,0.,1.,1.,0.,1.,-1.,0.,0.,0.,-1.,-1.,0.,0.,0.,1.,0.,1.,0.,0.,0.,-1.,0.,0.,0.,1.,0.,0.,0.};
const double MEDCouplingFieldDiscretizationGaussNE::REF_PYRA5[15]={1.,0.,0.,0.,1.,0.,-1.,0.,0.,0.,-1.,0.,0.,0.,1.};
-const double MEDCouplingFieldDiscretizationGaussNE::REF_PYRA13[39]={1.,0.,0.,0.,1.,0.,-1.,0.,0.,0.,-1.,0.,0.,0.,1.,0.5,0.5,0.,-0.5,0.5,0.,-0.5,-0.5,0.,0.5,-0.5,0.,0.5,0.,0.5,0.,0.5,0.5,-0.5,0.,0.5,0.,-0.5,0.5};
+const double MEDCouplingFieldDiscretizationGaussNE::REF_PYRA13[39]={1.,0.,0.,0.,-1.,0.,-1.,0.,0.,0.,1.,0.,0.,0.,1.,0.5,-0.5,0.,-0.5,-0.5,0.,-0.5,0.5,0.,0.5,0.5,0.,0.5,0.,0.5,0.,-0.5,0.5,-0.5,0.,0.5,0.,0.5,0.5};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_SEG2[2]={0.577350269189626,-0.577350269189626};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_SEG3[3]={-0.774596669241,0.,0.774596669241};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_SEG4[4]={0.339981043584856,-0.339981043584856,0.861136311594053,-0.861136311594053};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_TRI3[6]={0.16666666666666667,0.16666666666666667,0.6666666666666667,0.16666666666666667,0.16666666666666667,0.6666666666666667};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_TRI6[12]={0.091576213509771,0.091576213509771,0.816847572980458,0.091576213509771,0.091576213509771,0.816847572980458,0.445948490915965,0.10810301816807,0.445948490915965,0.445948490915965,0.10810301816807,0.445948490915965};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_TRI7[14]={0.3333333333333333,0.3333333333333333,0.470142064105115,0.470142064105115,0.05971587178977,0.470142064105115,0.470142064105115,0.05971587178977,0.101286507323456,0.101286507323456,0.797426985353088,0.101286507323456,0.101286507323456,0.797426985353088};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_QUAD4[8]={-0.774596669241483,-0.774596669241483,0.774596669241483,-0.774596669241483,0.774596669241483,0.774596669241483,-0.774596669241483,0.774596669241483};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_QUAD8[16]={-0.774596669241483,-0.774596669241483,0.774596669241483,-0.774596669241483,0.774596669241483,0.774596669241483,-0.774596669241483,0.774596669241483,0.,-0.774596669241483,0.774596669241483,0.,0.,0.774596669241483,-0.774596669241483,0.};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_QUAD9[18]={-0.774596669241483,-0.774596669241483,0.774596669241483,-0.774596669241483,0.774596669241483,0.774596669241483,-0.774596669241483,0.774596669241483,0.,-0.774596669241483,0.774596669241483,0.,0.,0.774596669241483,-0.774596669241483,0.,0.,0.};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_TETRA4[12]={0.1381966011250105,0.1381966011250105,0.1381966011250105,0.1381966011250105,0.1381966011250105,0.5854101966249685,0.1381966011250105,0.5854101966249685,0.1381966011250105,0.5854101966249685,0.1381966011250105,0.1381966011250105};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_TETRA10[30]={0.,1.,0.,0.,0.,1.,0.,0.,0.,1.,0.,0.,0.,0.5,0.5,0.,0.,0.5,0.,0.5,0.,0.5,0.5,0.,0.5,0.,0.5,0.5,0.,0.};//to check
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_PENTA6[18]={-0.5773502691896258,0.5,0.5,-0.5773502691896258,0.,0.5,-0.5773502691896258,0.5,0.,0.5773502691896258,0.5,0.5,0.5773502691896258,0.,0.5,0.5773502691896258,0.5,0.};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_PENTA15[45]={-1.,1.,0.,-1.,0.,1.,-1.,0.,0.,1.,1.,0.,1.,0.,1.,1.,0.,0.,-1.,0.5,0.5,-1.,0.,0.5,-1.,0.5,0.,0.,1.,0.,0.,0.,1.,0.,0.,0.,1.,0.5,0.5,1.,0.,0.5,1.,0.5,0.};//to check
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_HEXA8[24]={-0.5773502691896258,-0.5773502691896258,-0.5773502691896258,-0.5773502691896258,-0.5773502691896258,0.5773502691896258,-0.5773502691896258,0.5773502691896258,-0.5773502691896258,-0.5773502691896258,0.5773502691896258,0.5773502691896258,0.5773502691896258,-0.5773502691896258,-0.5773502691896258,0.5773502691896258,-0.5773502691896258,0.5773502691896258,0.5773502691896258,0.5773502691896258,-0.5773502691896258,0.5773502691896258,0.5773502691896258,0.5773502691896258};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_HEXA20[60]={-1.,-1.,-1.,1.,-1.,-1.,1.,1.,-1.,-1.,1.,-1.,-1.,-1.,1.,1.,-1.,1.,1.,1.,1.,-1.,1.,1.,0.,-1.,-1.,1.,0.,-1.,0.,1.,-1.,-1.,0.,-1.,-1.,-1.,0.,1.,-1.,0.,1.,1.,0.,-1.,1.,0.,0.,-1.,1.,1.,0.,1.,0.,1.,1.,-1.,0.,1.};//to check
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_HEXA27[81]={-1.,-1.,-1.,-1.,1.,-1.,1.,1.,-1.,1.,-1.,-1.,-1.,-1.,1.,-1.,1.,1.,1.,1.,1.,1.,-1.,1.,-1.,0.,-1.,0.,1.,-1.,1.,0.,-1.,0.,-1.,-1.,-1.,0.,1.,0.,1.,1.,1.,0.,1.,0.,-1.,1.,-1.,-1.,0.,-1.,1.,0.,1.,1.,0.,1.,-1.,0.,0.,0.,-1.,-1.,0.,0.,0.,1.,0.,1.,0.,0.,0.,-1.,0.,0.,0.,1.,0.,0.,0.};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_PYRA5[15]={0.5,0.,0.1531754163448146,0.,0.5,0.1531754163448146,-0.5,0.,0.1531754163448146,0.,-0.5,0.1531754163448146,0.,0.,0.6372983346207416};
+const double MEDCouplingFieldDiscretizationGaussNE::LOC_PYRA13[39]={1.,0.,0.,0.,-1.,0.,-1.,0.,0.,0.,1.,0.,0.,0.,0.999999999999,0.5,-0.5,0.,-0.5,-0.5,0.,-0.5,0.5,0.,0.5,0.5,0.,0.5,0.,0.5,0.,-0.5,0.5,-0.5,0.,0.5,0.,0.5,0.5};//to check 0.99999... to avoid nan ! on node #4 of PYRA13
MEDCouplingFieldDiscretization::MEDCouplingFieldDiscretization():_precision(DFLT_PRECISION)
{
MEDCouplingFieldDiscretization *MEDCouplingFieldDiscretization::New(TypeOfField type)
{
switch(type)
- {
+ {
case MEDCouplingFieldDiscretizationP0::TYPE:
return new MEDCouplingFieldDiscretizationP0;
case MEDCouplingFieldDiscretizationP1::TYPE:
case MEDCouplingFieldDiscretizationKriging::TYPE:
return new MEDCouplingFieldDiscretizationKriging;
default:
- throw INTERP_KERNEL::Exception("Choosen discretization is not implemented yet.");
- }
+ throw INTERP_KERNEL::Exception("Chosen discretization is not implemented yet.");
+ }
}
-TypeOfField MEDCouplingFieldDiscretization::GetTypeOfFieldFromStringRepr(const char *repr) throw(INTERP_KERNEL::Exception)
+TypeOfField MEDCouplingFieldDiscretization::GetTypeOfFieldFromStringRepr(const std::string& repr)
{
- std::string reprCpp(repr);
- if(reprCpp==MEDCouplingFieldDiscretizationP0::REPR)
+ if(repr==MEDCouplingFieldDiscretizationP0::REPR)
return MEDCouplingFieldDiscretizationP0::TYPE;
- if(reprCpp==MEDCouplingFieldDiscretizationP1::REPR)
+ if(repr==MEDCouplingFieldDiscretizationP1::REPR)
return MEDCouplingFieldDiscretizationP1::TYPE;
- if(reprCpp==MEDCouplingFieldDiscretizationGauss::REPR)
+ if(repr==MEDCouplingFieldDiscretizationGauss::REPR)
return MEDCouplingFieldDiscretizationGauss::TYPE;
- if(reprCpp==MEDCouplingFieldDiscretizationGaussNE::REPR)
+ if(repr==MEDCouplingFieldDiscretizationGaussNE::REPR)
return MEDCouplingFieldDiscretizationGaussNE::TYPE;
- if(reprCpp==MEDCouplingFieldDiscretizationKriging::REPR)
+ if(repr==MEDCouplingFieldDiscretizationKriging::REPR)
return MEDCouplingFieldDiscretizationKriging::TYPE;
throw INTERP_KERNEL::Exception("Representation does not match with any field discretization !");
}
+std::string MEDCouplingFieldDiscretization::GetTypeOfFieldRepr(TypeOfField type)
+{
+ if(type==MEDCouplingFieldDiscretizationP0::TYPE)
+ return MEDCouplingFieldDiscretizationP0::REPR;
+ if(type==MEDCouplingFieldDiscretizationP1::TYPE)
+ return MEDCouplingFieldDiscretizationP1::REPR;
+ if(type==MEDCouplingFieldDiscretizationGauss::TYPE)
+ return MEDCouplingFieldDiscretizationGauss::REPR;
+ if(type==MEDCouplingFieldDiscretizationGaussNE::TYPE)
+ return MEDCouplingFieldDiscretizationGaussNE::REPR;
+ if(type==MEDCouplingFieldDiscretizationKriging::TYPE)
+ return MEDCouplingFieldDiscretizationKriging::REPR;
+ throw INTERP_KERNEL::Exception("GetTypeOfFieldRepr : Representation does not match with any field discretization !");
+}
+
bool MEDCouplingFieldDiscretization::isEqual(const MEDCouplingFieldDiscretization *other, double eps) const
{
std::string reason;
* This method is an alias of MEDCouplingFieldDiscretization::clone. It is only here for coherency with all the remaining of MEDCoupling.
* \sa MEDCouplingFieldDiscretization::clone.
*/
-MEDCouplingFieldDiscretization *MEDCouplingFieldDiscretization::deepCpy() const
+MEDCouplingFieldDiscretization *MEDCouplingFieldDiscretization::deepCopy() const
{
return clone();
}
{
}
-std::size_t MEDCouplingFieldDiscretization::getHeapMemorySize() const
+std::size_t MEDCouplingFieldDiscretization::getHeapMemorySizeWithoutChildren() const
{
return 0;
}
+std::vector<const BigMemoryObject *> MEDCouplingFieldDiscretization::getDirectChildrenWithNull() const
+{
+ return std::vector<const BigMemoryObject *>();
+}
+
/*!
* Computes normL1 of DataArrayDouble instance arr.
* @param res output parameter expected to be of size arr->getNumberOfComponents();
* @throw when the field discretization fails on getMeasure fields (gauss points for example)
*/
-void MEDCouplingFieldDiscretization::normL1(const MEDCouplingMesh *mesh, const DataArrayDouble *arr, double *res) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretization::normL1(const MEDCouplingMesh *mesh, const DataArrayDouble *arr, double *res) const
{
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> vol=getMeasureField(mesh,true);
+ MCAuto<MEDCouplingFieldDouble> vol=getMeasureField(mesh,true);
int nbOfCompo=arr->getNumberOfComponents();
int nbOfElems=getNumberOfTuples(mesh);
std::fill(res,res+nbOfCompo,0.);
* @param res output parameter expected to be of size arr->getNumberOfComponents();
* @throw when the field discretization fails on getMeasure fields (gauss points for example)
*/
-void MEDCouplingFieldDiscretization::normL2(const MEDCouplingMesh *mesh, const DataArrayDouble *arr, double *res) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretization::normL2(const MEDCouplingMesh *mesh, const DataArrayDouble *arr, double *res) const
{
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> vol=getMeasureField(mesh,true);
+ MCAuto<MEDCouplingFieldDouble> vol=getMeasureField(mesh,true);
int nbOfCompo=arr->getNumberOfComponents();
int nbOfElems=getNumberOfTuples(mesh);
std::fill(res,res+nbOfCompo,0.);
* @param res output parameter expected to be of size arr->getNumberOfComponents();
* @throw when the field discretization fails on getMeasure fields (gauss points for example)
*/
-void MEDCouplingFieldDiscretization::integral(const MEDCouplingMesh *mesh, const DataArrayDouble *arr, bool isWAbs, double *res) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretization::integral(const MEDCouplingMesh *mesh, const DataArrayDouble *arr, bool isWAbs, double *res) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretization::integral : mesh is NULL !");
if(!arr)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretization::integral : input array is NULL !");
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> vol=getMeasureField(mesh,isWAbs);
- int nbOfCompo=arr->getNumberOfComponents();
- int nbOfElems=getNumberOfTuples(mesh);
+ MCAuto<MEDCouplingFieldDouble> vol=getMeasureField(mesh,isWAbs);
+ std::size_t nbOfCompo(arr->getNumberOfComponents()),nbOfElems(getNumberOfTuples(mesh));
if(nbOfElems!=arr->getNumberOfTuples())
{
std::ostringstream oss; oss << "MEDCouplingFieldDiscretization::integral : field is not correct ! number of tuples in array is " << arr->getNumberOfTuples();
throw INTERP_KERNEL::Exception(oss.str().c_str());
}
std::fill(res,res+nbOfCompo,0.);
- const double *arrPtr=arr->getConstPointer();
- const double *volPtr=vol->getArray()->getConstPointer();
+ const double *arrPtr(arr->begin()),*volPtr(vol->getArray()->begin());
INTERP_KERNEL::AutoPtr<double> tmp=new double[nbOfCompo];
- for (int i=0;i<nbOfElems;i++)
+ for(std::size_t i=0;i<nbOfElems;i++)
{
std::transform(arrPtr+i*nbOfCompo,arrPtr+(i+1)*nbOfCompo,(double *)tmp,std::bind2nd(std::multiplies<double>(),volPtr[i]));
std::transform((double *)tmp,(double *)tmp+nbOfCompo,res,res,std::plus<double>());
*/
MEDCouplingMesh *MEDCouplingFieldDiscretization::buildSubMeshDataRange(const MEDCouplingMesh *mesh, int beginCellIds, int endCellIds, int stepCellIds, int& beginOut, int& endOut, int& stepOut, DataArrayInt *&di) const
{
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> da=DataArrayInt::Range(beginCellIds,endCellIds,stepCellIds);
+ MCAuto<DataArrayInt> da=DataArrayInt::Range(beginCellIds,endCellIds,stepCellIds);
return buildSubMeshData(mesh,da->begin(),da->end(),di);
}
arr=0;
}
+/*!
+ * Empty : Not a bug
+ */
+void MEDCouplingFieldDiscretization::checkForUnserialization(const std::vector<int>& tinyInfo, const DataArrayInt *arr)
+{
+}
+
/*!
* Empty : Not a bug
*/
/*!
* This method is typically the first step of renumbering. The implementation is empty it is not a bug only gauss is impacted
- * virtualy by this method.
+ * virtually by this method.
*/
-void MEDCouplingFieldDiscretization::renumberCells(const int *old2NewBg, bool check) throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretization::renumberCells(const int *old2NewBg, bool check)
{
}
-double MEDCouplingFieldDiscretization::getIJK(const MEDCouplingMesh *mesh, const DataArrayDouble *da,
- int cellId, int nodeIdInCell, int compoId) const throw(INTERP_KERNEL::Exception)
+double MEDCouplingFieldDiscretization::getIJK(const MEDCouplingMesh *mesh, const DataArrayDouble *da, int cellId, int nodeIdInCell, int compoId) const
{
throw INTERP_KERNEL::Exception("getIJK Invalid ! only for GaussPoint and GaussNE discretizations !");
}
void MEDCouplingFieldDiscretization::setGaussLocalizationOnType(const MEDCouplingMesh *m, INTERP_KERNEL::NormalizedCellType type, const std::vector<double>& refCoo,
- const std::vector<double>& gsCoo, const std::vector<double>& wg) throw(INTERP_KERNEL::Exception)
+ const std::vector<double>& gsCoo, const std::vector<double>& wg)
{
throw INTERP_KERNEL::Exception("Invalid method for the corresponding field discretization : available only for GaussPoint discretization !");
}
void MEDCouplingFieldDiscretization::setGaussLocalizationOnCells(const MEDCouplingMesh *m, const int *begin, const int *end, const std::vector<double>& refCoo,
- const std::vector<double>& gsCoo, const std::vector<double>& wg) throw(INTERP_KERNEL::Exception)
+ const std::vector<double>& gsCoo, const std::vector<double>& wg)
{
throw INTERP_KERNEL::Exception("Invalid method for the corresponding field discretization : available only for GaussPoint discretization !");
}
-void MEDCouplingFieldDiscretization::clearGaussLocalizations() throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretization::clearGaussLocalizations()
{
throw INTERP_KERNEL::Exception("Invalid method for the corresponding field discretization : available only for GaussPoint discretization !");
}
-MEDCouplingGaussLocalization& MEDCouplingFieldDiscretization::getGaussLocalization(int locId) throw(INTERP_KERNEL::Exception)
+MEDCouplingGaussLocalization& MEDCouplingFieldDiscretization::getGaussLocalization(int locId)
{
throw INTERP_KERNEL::Exception("Invalid method for the corresponding field discretization : available only for GaussPoint discretization !");
}
-const MEDCouplingGaussLocalization& MEDCouplingFieldDiscretization::getGaussLocalization(int locId) const throw(INTERP_KERNEL::Exception)
+const MEDCouplingGaussLocalization& MEDCouplingFieldDiscretization::getGaussLocalization(int locId) const
{
throw INTERP_KERNEL::Exception("Invalid method for the corresponding field discretization : available only for GaussPoint discretization !");
}
-int MEDCouplingFieldDiscretization::getNbOfGaussLocalization() const throw(INTERP_KERNEL::Exception)
+int MEDCouplingFieldDiscretization::getNbOfGaussLocalization() const
{
throw INTERP_KERNEL::Exception("Invalid method for the corresponding field discretization : available only for GaussPoint discretization !");
}
-int MEDCouplingFieldDiscretization::getGaussLocalizationIdOfOneCell(int cellId) const throw(INTERP_KERNEL::Exception)
+int MEDCouplingFieldDiscretization::getGaussLocalizationIdOfOneCell(int cellId) const
{
throw INTERP_KERNEL::Exception("Invalid method for the corresponding field discretization : available only for GaussPoint discretization !");
}
-int MEDCouplingFieldDiscretization::getGaussLocalizationIdOfOneType(INTERP_KERNEL::NormalizedCellType type) const throw(INTERP_KERNEL::Exception)
+int MEDCouplingFieldDiscretization::getGaussLocalizationIdOfOneType(INTERP_KERNEL::NormalizedCellType type) const
{
throw INTERP_KERNEL::Exception("Invalid method for the corresponding field discretization : available only for GaussPoint discretization !");
}
-std::set<int> MEDCouplingFieldDiscretization::getGaussLocalizationIdsOfOneType(INTERP_KERNEL::NormalizedCellType type) const throw(INTERP_KERNEL::Exception)
+std::set<int> MEDCouplingFieldDiscretization::getGaussLocalizationIdsOfOneType(INTERP_KERNEL::NormalizedCellType type) const
{
throw INTERP_KERNEL::Exception("Invalid method for the corresponding field discretization : available only for GaussPoint discretization !");
}
-void MEDCouplingFieldDiscretization::getCellIdsHavingGaussLocalization(int locId, std::vector<int>& cellIds) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretization::getCellIdsHavingGaussLocalization(int locId, std::vector<int>& cellIds) const
{
throw INTERP_KERNEL::Exception("Invalid method for the corresponding field discretization : available only for GaussPoint discretization !");
}
-void MEDCouplingFieldDiscretization::RenumberEntitiesFromO2NArr(double eps, const int *old2NewPtr, int newNbOfEntity, DataArrayDouble *arr, const char *msg)
+void MEDCouplingFieldDiscretization::RenumberEntitiesFromO2NArr(double eps, const int *old2NewPtr, int newNbOfEntity, DataArrayDouble *arr, const std::string& msg)
{
if(!arr)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretization::RenumberEntitiesFromO2NArr : input array is NULL !");
int oldNbOfElems=arr->getNumberOfTuples();
int nbOfComp=arr->getNumberOfComponents();
int newNbOfTuples=newNbOfEntity;
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arrCpy=arr->deepCpy();
+ MCAuto<DataArrayDouble> arrCpy=arr->deepCopy();
const double *ptSrc=arrCpy->getConstPointer();
arr->reAlloc(newNbOfTuples);
double *ptToFill=arr->getPointer();
if(newNb>=0)//if newNb<0 the node is considered as out.
{
if(std::find_if(ptToFill+newNb*nbOfComp,ptToFill+(newNb+1)*nbOfComp,std::bind2nd(std::not_equal_to<double>(),std::numeric_limits<double>::max()))
- ==ptToFill+(newNb+1)*nbOfComp)
+ ==ptToFill+(newNb+1)*nbOfComp)
std::copy(ptSrc+i*nbOfComp,ptSrc+(i+1)*nbOfComp,ptToFill+newNb*nbOfComp);
else
{
}
}
-void MEDCouplingFieldDiscretization::RenumberEntitiesFromN2OArr(const int *new2OldPtr, int new2OldSz, DataArrayDouble *arr, const char *msg)
+void MEDCouplingFieldDiscretization::RenumberEntitiesFromN2OArr(const int *new2OldPtr, int new2OldSz, DataArrayDouble *arr, const std::string& msg)
{
int nbOfComp=arr->getNumberOfComponents();
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arrCpy=arr->deepCpy();
+ MCAuto<DataArrayDouble> arrCpy=arr->deepCopy();
const double *ptSrc=arrCpy->getConstPointer();
arr->reAlloc(new2OldSz);
double *ptToFill=arr->getPointer();
}
/*!
- * This method is simply called by MEDCouplingFieldDiscretization::deepCpy. It performs the deep copy of \a this.
+ * This method is simply called by MEDCouplingFieldDiscretization::deepCopy. It performs the deep copy of \a this.
*
- * \sa MEDCouplingFieldDiscretization::deepCpy.
+ * \sa MEDCouplingFieldDiscretization::deepCopy.
*/
MEDCouplingFieldDiscretization *MEDCouplingFieldDiscretizationP0::clone() const
{
return ret;
}
-int MEDCouplingFieldDiscretizationP0::getNumberOfTuples(const MEDCouplingMesh *mesh) const throw(INTERP_KERNEL::Exception)
+int MEDCouplingFieldDiscretizationP0::getNumberOfTuples(const MEDCouplingMesh *mesh) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP0::getNumberOfTuples : NULL input mesh !");
return mesh->getNumberOfCells();
}
+/*!
+ * This method returns the number of tuples regarding exclusively the input code \b without \b using \b a \b mesh \b in \b input.
+ * The input code coherency is also checked regarding spatial discretization of \a this.
+ * If an incoherency is detected, an exception will be thrown. If the input code is coherent, the number of tuples expected is returned.
+ * The number of tuples expected is equal to those to have a valid field lying on \a this and having a mesh fitting perfectly the input code (geometric type distribution).
+ */
+int MEDCouplingFieldDiscretizationP0::getNumberOfTuplesExpectedRegardingCode(const std::vector<int>& code, const std::vector<const DataArrayInt *>& idsPerType) const
+{
+ if(code.size()%3!=0)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP0::getNumberOfTuplesExpectedRegardingCode : invalid input code !");
+ int nbOfSplit=(int)idsPerType.size();
+ int nbOfTypes=(int)code.size()/3;
+ int ret=0;
+ for(int i=0;i<nbOfTypes;i++)
+ {
+ int nbOfEltInChunk=code[3*i+1];
+ if(nbOfEltInChunk<0)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP0::getNumberOfTuplesExpectedRegardingCode : invalid input code ! presence of negative value in a type !");
+ int pos=code[3*i+2];
+ if(pos!=-1)
+ {
+ if(pos<0 || pos>=nbOfSplit)
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationP0::getNumberOfTuplesExpectedRegardingCode : input code points to pos " << pos << " in typeid " << i << " ! Should be in [0," << nbOfSplit << ") !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ const DataArrayInt *ids(idsPerType[pos]);
+ if(!ids || !ids->isAllocated() || ids->getNumberOfComponents()!=1 || (int)ids->getNumberOfTuples()!=nbOfEltInChunk || ids->getMinValueInArray()<0)
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationP0::getNumberOfTuplesExpectedRegardingCode : input pfl chunck at pos " << pos << " should have " << i << " tuples and one component and with ids all >=0 !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ }
+ ret+=nbOfEltInChunk;
+ }
+ return ret;
+}
+
int MEDCouplingFieldDiscretizationP0::getNumberOfMeshPlaces(const MEDCouplingMesh *mesh) const
{
if(!mesh)
}
void MEDCouplingFieldDiscretizationP0::renumberArraysForCell(const MEDCouplingMesh *mesh, const std::vector<DataArray *>& arrays,
- const int *old2NewBg, bool check) throw(INTERP_KERNEL::Exception)
+ const int *old2NewBg, bool check)
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP0::renumberArraysForCell : NULL input mesh !");
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP0::getLocalizationOfDiscValues : NULL input mesh !");
- return mesh->getBarycenterAndOwner();
+ return mesh->computeCellCenterOfMass();
}
void MEDCouplingFieldDiscretizationP0::computeMeshRestrictionFromTupleIds(const MEDCouplingMesh *mesh, const int *tupleIdsBg, const int *tupleIdsEnd,
- DataArrayInt *&cellRestriction, DataArrayInt *&trueTupleRestriction) const throw(INTERP_KERNEL::Exception)
+ DataArrayInt *&cellRestriction, DataArrayInt *&trueTupleRestriction) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP0::computeMeshRestrictionFromTupleIds : NULL input mesh !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> tmp=DataArrayInt::New();
+ MCAuto<DataArrayInt> tmp=DataArrayInt::New();
tmp->alloc((int)std::distance(tupleIdsBg,tupleIdsEnd),1);
std::copy(tupleIdsBg,tupleIdsEnd,tmp->getPointer());
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> tmp2(tmp->deepCpy());
+ MCAuto<DataArrayInt> tmp2(tmp->deepCopy());
cellRestriction=tmp.retn();
trueTupleRestriction=tmp2.retn();
}
-void MEDCouplingFieldDiscretizationP0::reprQuickOverview(std::ostream& stream) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationP0::reprQuickOverview(std::ostream& stream) const
{
stream << "P0 spatial discretization.";
}
-void MEDCouplingFieldDiscretizationP0::checkCompatibilityWithNature(NatureOfField nat) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationP0::checkCompatibilityWithNature(NatureOfField nat) const
{
}
-void MEDCouplingFieldDiscretizationP0::checkCoherencyBetween(const MEDCouplingMesh *mesh, const DataArray *da) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationP0::checkCoherencyBetween(const MEDCouplingMesh *mesh, const DataArray *da) const
{
if(!mesh || !da)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP0::checkCoherencyBetween : NULL input mesh or DataArray !");
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP0::getValueOnMulti : NULL input mesh !");
- std::vector<int> elts,eltsIndex;
- mesh->getCellsContainingPoints(loc,nbOfPoints,_precision,elts,eltsIndex);
+ MCAuto<DataArrayInt> eltsArr,eltsIndexArr;
+ mesh->getCellsContainingPoints(loc,nbOfPoints,_precision,eltsArr,eltsIndexArr);
+ const int *elts(eltsArr->begin()),*eltsIndex(eltsIndexArr->begin());
int spaceDim=mesh->getSpaceDimension();
int nbOfComponents=arr->getNumberOfComponents();
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
+ MCAuto<DataArrayDouble> ret=DataArrayDouble::New();
ret->alloc(nbOfPoints,nbOfComponents);
double *ptToFill=ret->getPointer();
for(int i=0;i<nbOfPoints;i++,ptToFill+=nbOfComponents)
*/
DataArrayInt *MEDCouplingFieldDiscretizationP0::computeTupleIdsToSelectFromCellIds(const MEDCouplingMesh *mesh, const int *startCellIds, const int *endCellIds) const
{
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
+ MCAuto<DataArrayInt> ret=DataArrayInt::New();
ret->alloc((int)std::distance(startCellIds,endCellIds),1);
std::copy(startCellIds,endCellIds,ret->getPointer());
return ret.retn();
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP0::buildSubMeshData : NULL input mesh !");
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> ret=mesh->buildPart(start,end);
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> diSafe=DataArrayInt::New();
+ MCAuto<MEDCouplingMesh> ret=mesh->buildPart(start,end);
+ MCAuto<DataArrayInt> diSafe=DataArrayInt::New();
diSafe->alloc((int)std::distance(start,end),1);
std::copy(start,end,diSafe->getPointer());
di=diSafe.retn();
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP0::buildSubMeshDataRange : NULL input mesh !");
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> ret=mesh->buildPartRange(beginCellIds,endCellIds,stepCellIds);
+ MCAuto<MEDCouplingMesh> ret=mesh->buildPartRange(beginCellIds,endCellIds,stepCellIds);
di=0; beginOut=beginCellIds; endOut=endCellIds; stepOut=stepCellIds;
return ret.retn();
}
-int MEDCouplingFieldDiscretizationOnNodes::getNumberOfTuples(const MEDCouplingMesh *mesh) const throw(INTERP_KERNEL::Exception)
+int MEDCouplingFieldDiscretizationOnNodes::getNumberOfTuples(const MEDCouplingMesh *mesh) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationNodes::getNumberOfTuples : NULL input mesh !");
return mesh->getNumberOfNodes();
}
+/*!
+ * This method returns the number of tuples regarding exclusively the input code \b without \b using \b a \b mesh \b in \b input.
+ * The input code coherency is also checked regarding spatial discretization of \a this.
+ * If an incoherency is detected, an exception will be thrown. If the input code is coherent, the number of tuples expected is returned.
+ * The number of tuples expected is equal to those to have a valid field lying on \a this and having a mesh fitting perfectly the input code (geometric type distribution).
+ */
+int MEDCouplingFieldDiscretizationOnNodes::getNumberOfTuplesExpectedRegardingCode(const std::vector<int>& code, const std::vector<const DataArrayInt *>& idsPerType) const
+{
+ if(code.size()%3!=0)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationOnNodes::getNumberOfTuplesExpectedRegardingCode : invalid input code !");
+ int nbOfSplit=(int)idsPerType.size();
+ int nbOfTypes=(int)code.size()/3;
+ int ret=0;
+ for(int i=0;i<nbOfTypes;i++)
+ {
+ int nbOfEltInChunk=code[3*i+1];
+ if(nbOfEltInChunk<0)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationOnNodes::getNumberOfTuplesExpectedRegardingCode : invalid input code ! presence of negative value in a type !");
+ int pos=code[3*i+2];
+ if(pos!=-1)
+ {
+ if(pos<0 || pos>=nbOfSplit)
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationOnNodes::getNumberOfTuplesExpectedRegardingCode : input code points to pos " << pos << " in typeid " << i << " ! Should be in [0," << nbOfSplit << ") !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ const DataArrayInt *ids(idsPerType[pos]);
+ if(!ids || !ids->isAllocated() || ids->getNumberOfComponents()!=1 || (int)ids->getNumberOfTuples()!=nbOfEltInChunk || ids->getMinValueInArray()<0)
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationOnNodes::getNumberOfTuplesExpectedRegardingCode : input pfl chunck at pos " << pos << " should have " << i << " tuples and one component and with ids all >=0 !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ }
+ ret+=nbOfEltInChunk;
+ }
+ return ret;
+}
+
int MEDCouplingFieldDiscretizationOnNodes::getNumberOfMeshPlaces(const MEDCouplingMesh *mesh) const
{
if(!mesh)
* Nothing to do here.
*/
void MEDCouplingFieldDiscretizationOnNodes::renumberArraysForCell(const MEDCouplingMesh *, const std::vector<DataArray *>& arrays,
- const int *old2NewBg, bool check) throw(INTERP_KERNEL::Exception)
+ const int *old2NewBg, bool check)
{
}
}
void MEDCouplingFieldDiscretizationOnNodes::computeMeshRestrictionFromTupleIds(const MEDCouplingMesh *mesh, const int *tupleIdsBg, const int *tupleIdsEnd,
- DataArrayInt *&cellRestriction, DataArrayInt *&trueTupleRestriction) const throw(INTERP_KERNEL::Exception)
+ DataArrayInt *&cellRestriction, DataArrayInt *&trueTupleRestriction) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationOnNodes::computeMeshRestrictionFromTupleIds : NULL input mesh !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret1=mesh->getCellIdsFullyIncludedInNodeIds(tupleIdsBg,tupleIdsEnd);
+ MCAuto<DataArrayInt> ret1=mesh->getCellIdsFullyIncludedInNodeIds(tupleIdsBg,tupleIdsEnd);
const MEDCouplingUMesh *meshc=dynamic_cast<const MEDCouplingUMesh *>(mesh);
if(!meshc)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationOnNodes::computeMeshRestrictionFromTupleIds : trying to subpart field on nodes by node ids ! Your mesh has to be unstructured !");
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingUMesh> meshPart=static_cast<MEDCouplingUMesh *>(meshc->buildPartOfMySelf(ret1->begin(),ret1->end(),true));
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret2=meshPart->computeFetchedNodeIds();
+ MCAuto<MEDCouplingUMesh> meshPart=static_cast<MEDCouplingUMesh *>(meshc->buildPartOfMySelf(ret1->begin(),ret1->end(),true));
+ MCAuto<DataArrayInt> ret2=meshPart->computeFetchedNodeIds();
cellRestriction=ret1.retn();
trueTupleRestriction=ret2.retn();
}
-void MEDCouplingFieldDiscretizationOnNodes::checkCoherencyBetween(const MEDCouplingMesh *mesh, const DataArray *da) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationOnNodes::checkCoherencyBetween(const MEDCouplingMesh *mesh, const DataArray *da) const
{
if(!mesh || !da)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationNodes::checkCoherencyBetween : NULL input mesh or DataArray !");
- if(mesh->getNumberOfNodes()!=da->getNumberOfTuples())
+ if(mesh->getNumberOfNodes()!=(int)da->getNumberOfTuples())
{
std::ostringstream message;
message << "Field on nodes invalid because there are " << mesh->getNumberOfNodes();
/*!
* This method returns a submesh of 'mesh' instance constituting cell ids contained in array defined as an interval [start;end).
-* @param di is an array returned that specifies entity ids (here nodes ids) in mesh 'mesh' of entity in returned submesh.
+ * @param di is an array returned that specifies entity ids (here nodes ids) in mesh 'mesh' of entity in returned submesh.
* Example : The first node id of returned mesh has the (*di)[0] id in 'mesh'
*/
MEDCouplingMesh *MEDCouplingFieldDiscretizationOnNodes::buildSubMeshData(const MEDCouplingMesh *mesh, const int *start, const int *end, DataArrayInt *&di) const
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationNodes::buildSubMeshData : NULL input mesh !");
DataArrayInt *diTmp=0;
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> ret=mesh->buildPartAndReduceNodes(start,end,diTmp);
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> diTmpSafe(diTmp);
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> di2=diTmpSafe->invertArrayO2N2N2O(ret->getNumberOfNodes());
+ MCAuto<MEDCouplingMesh> ret=mesh->buildPartAndReduceNodes(start,end,diTmp);
+ MCAuto<DataArrayInt> diTmpSafe(diTmp);
+ MCAuto<DataArrayInt> di2=diTmpSafe->invertArrayO2N2N2O(ret->getNumberOfNodes());
di=di2.retn();
return ret.retn();
}
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationOnNodes::buildSubMeshDataRange : NULL input mesh !");
DataArrayInt *diTmp=0;
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> ret=mesh->buildPartRangeAndReduceNodes(beginCellIds,endCellIds,stepCellIds,beginOut,endOut,stepOut,diTmp);
+ MCAuto<MEDCouplingMesh> ret=mesh->buildPartRangeAndReduceNodes(beginCellIds,endCellIds,stepCellIds,beginOut,endOut,stepOut,diTmp);
if(diTmp)
{
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> diTmpSafe(diTmp);
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> di2=diTmpSafe->invertArrayO2N2N2O(ret->getNumberOfNodes());
+ MCAuto<DataArrayInt> diTmpSafe(diTmp);
+ MCAuto<DataArrayInt> di2=diTmpSafe->invertArrayO2N2N2O(ret->getNumberOfNodes());
di=di2.retn();
}
return ret.retn();
/*!
* This method returns a tuple ids selection from cell ids selection [start;end).
- * This method is called by MEDCouplingFieldDiscretizationP0::buildSubMeshData to return parameter \b di.
+ * This method is called by MEDCouplingFieldDiscretizationOnNodes::buildSubMeshData to return parameter \b di.
* Here for P1 only nodes fetched by submesh of mesh[startCellIds:endCellIds) is returned !
*
* \return a newly allocated array containing ids to select into the DataArrayDouble of the field.
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP1::computeTupleIdsToSelectFromCellIds : NULL input mesh !");
- const MEDCouplingAutoRefCountObjectPtr<MEDCouplingUMesh> umesh=mesh->buildUnstructured();
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingUMesh> umesh2=static_cast<MEDCouplingUMesh *>(umesh->buildPartOfMySelf(startCellIds,endCellIds,true));
+ const MCAuto<MEDCouplingUMesh> umesh=mesh->buildUnstructured();
+ MCAuto<MEDCouplingUMesh> umesh2=static_cast<MEDCouplingUMesh *>(umesh->buildPartOfMySelf(startCellIds,endCellIds,true));
return umesh2->computeFetchedNodeIds();
}
}
/*!
- * This method is simply called by MEDCouplingFieldDiscretization::deepCpy. It performs the deep copy of \a this.
+ * This method is simply called by MEDCouplingFieldDiscretization::deepCopy. It performs the deep copy of \a this.
*
- * \sa MEDCouplingFieldDiscretization::deepCpy.
+ * \sa MEDCouplingFieldDiscretization::deepCopy.
*/
MEDCouplingFieldDiscretization *MEDCouplingFieldDiscretizationP1::clone() const
{
return ret;
}
-void MEDCouplingFieldDiscretizationP1::checkCompatibilityWithNature(NatureOfField nat) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationP1::checkCompatibilityWithNature(NatureOfField nat) const
{
- if(nat!=ConservativeVolumic)
- throw INTERP_KERNEL::Exception("Invalid nature for P1 field : expected ConservativeVolumic !");
+ if(nat!=IntensiveMaximum)
+ throw INTERP_KERNEL::Exception("Invalid nature for P1 field : expected IntensiveMaximum !");
}
MEDCouplingFieldDouble *MEDCouplingFieldDiscretizationP1::getMeasureField(const MEDCouplingMesh *mesh, bool isAbs) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationP1::getValueOnMulti : NULL input mesh !");
- std::vector<int> elts,eltsIndex;
- mesh->getCellsContainingPoints(loc,nbOfPoints,_precision,elts,eltsIndex);
+ MCAuto<DataArrayInt> eltsArr,eltsIndexArr;
+ mesh->getCellsContainingPoints(loc,nbOfPoints,_precision,eltsArr,eltsIndexArr);
+ const int *elts(eltsArr->begin()),*eltsIndex(eltsIndexArr->begin());
int spaceDim=mesh->getSpaceDimension();
int nbOfComponents=arr->getNumberOfComponents();
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
+ MCAuto<DataArrayDouble> ret=DataArrayDouble::New();
ret->alloc(nbOfPoints,nbOfComponents);
double *ptToFill=ret->getPointer();
for(int i=0;i<nbOfPoints;i++)
return ret.retn();
}
-void MEDCouplingFieldDiscretizationP1::reprQuickOverview(std::ostream& stream) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationP1::reprQuickOverview(std::ostream& stream) const
{
stream << "P1 spatial discretization.";
}
}
/*!
- * This constructor deep copies ParaMEDMEM::DataArrayInt instance from other (if any).
+ * This constructor deep copies MEDCoupling::DataArrayInt instance from other (if any).
*/
MEDCouplingFieldDiscretizationPerCell::MEDCouplingFieldDiscretizationPerCell(const MEDCouplingFieldDiscretizationPerCell& other, const int *startCellIds, const int *endCellIds):_discr_per_cell(0)
{
if(arr)
{
if(startCellIds==0 && endCellIds==0)
- _discr_per_cell=arr->deepCpy();
+ _discr_per_cell=arr->deepCopy();
else
_discr_per_cell=arr->selectByTupleIdSafe(startCellIds,endCellIds);
}
DataArrayInt *arr=other._discr_per_cell;
if(arr)
{
- _discr_per_cell=arr->selectByTupleId2(beginCellIds,endCellIds,stepCellIds);
+ _discr_per_cell=arr->selectByTupleIdSafeSlice(beginCellIds,endCellIds,stepCellIds);
}
}
updateTimeWith(*_discr_per_cell);
}
-std::size_t MEDCouplingFieldDiscretizationPerCell::getHeapMemorySize() const
+std::size_t MEDCouplingFieldDiscretizationPerCell::getHeapMemorySizeWithoutChildren() const
{
- std::size_t ret=0;
- if(_discr_per_cell)
- ret+=_discr_per_cell->getHeapMemorySize();
+ std::size_t ret(MEDCouplingFieldDiscretization::getHeapMemorySizeWithoutChildren());
+ return ret;
+}
+
+std::vector<const BigMemoryObject *> MEDCouplingFieldDiscretizationPerCell::getDirectChildrenWithNull() const
+{
+ std::vector<const BigMemoryObject *> ret(MEDCouplingFieldDiscretization::getDirectChildrenWithNull());
+ ret.push_back(_discr_per_cell);
return ret;
}
-void MEDCouplingFieldDiscretizationPerCell::checkCoherencyBetween(const MEDCouplingMesh *mesh, const DataArray *da) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationPerCell::checkCoherencyBetween(const MEDCouplingMesh *mesh, const DataArray *da) const
{
if(!_discr_per_cell)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationPerCell has no discretization per cell !");
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationPerCell::checkCoherencyBetween : NULL input mesh or DataArray !");
- int nbOfTuples=_discr_per_cell->getNumberOfTuples();
+ std::size_t nbOfTuples(_discr_per_cell->getNumberOfTuples());
if(nbOfTuples!=mesh->getNumberOfCells())
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationPerCell has a discretization per cell but it's not matching the underlying mesh !");
}
/*!
* This method is typically the first step of renumbering. The impact on _discr_per_cell is necessary here.
- * virtualy by this method.
+ * virtually by this method.
*/
-void MEDCouplingFieldDiscretizationPerCell::renumberCells(const int *old2NewBg, bool check) throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationPerCell::renumberCells(const int *old2NewBg, bool check)
{
int nbCells=_discr_per_cell->getNumberOfTuples();
const int *array=old2NewBg;
}
}
-void MEDCouplingFieldDiscretizationPerCell::checkNoOrphanCells() const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationPerCell::checkNoOrphanCells() const
{
if(!_discr_per_cell)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationPerCell::checkNoOrphanCells : no discretization defined !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> test=_discr_per_cell->getIdsEqual(DFT_INVALID_LOCID_VALUE);
+ MCAuto<DataArrayInt> test=_discr_per_cell->findIdsEqual(DFT_INVALID_LOCID_VALUE);
if(test->getNumberOfTuples()!=0)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationPerCell::checkNoOrphanCells : presence of orphan cells !");
}
*
* If no descretization is set in 'this' and exception will be thrown.
*/
-std::vector<DataArrayInt *> MEDCouplingFieldDiscretizationPerCell::splitIntoSingleGaussDicrPerCellType(std::vector<int>& locIds) const throw(INTERP_KERNEL::Exception)
+std::vector<DataArrayInt *> MEDCouplingFieldDiscretizationPerCell::splitIntoSingleGaussDicrPerCellType(std::vector<int>& locIds) const
{
if(!_discr_per_cell)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationPerCell::splitIntoSingleGaussDicrPerCellType : no descretization set !");
return _discr_per_cell;
}
-void MEDCouplingFieldDiscretizationPerCell::setArrayOfDiscIds(const DataArrayInt *adids) throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationPerCell::setArrayOfDiscIds(const DataArrayInt *adids)
{
if(adids!=_discr_per_cell)
{
}
/*!
- * This method is simply called by MEDCouplingFieldDiscretization::deepCpy. It performs the deep copy of \a this.
+ * This method is simply called by MEDCouplingFieldDiscretization::deepCopy. It performs the deep copy of \a this.
*
- * \sa MEDCouplingFieldDiscretization::deepCpy.
+ * \sa MEDCouplingFieldDiscretization::deepCopy.
*/
MEDCouplingFieldDiscretization *MEDCouplingFieldDiscretizationGauss::clone() const
{
return oss.str();
}
-std::size_t MEDCouplingFieldDiscretizationGauss::getHeapMemorySize() const
+std::size_t MEDCouplingFieldDiscretizationGauss::getHeapMemorySizeWithoutChildren() const
{
- std::size_t ret=_loc.capacity()*sizeof(MEDCouplingGaussLocalization);
+ std::size_t ret(MEDCouplingFieldDiscretizationPerCell::getHeapMemorySizeWithoutChildren());
+ ret+=_loc.capacity()*sizeof(MEDCouplingGaussLocalization);
for(std::vector<MEDCouplingGaussLocalization>::const_iterator it=_loc.begin();it!=_loc.end();it++)
- ret+=(*it).getHeapMemorySize();
- return MEDCouplingFieldDiscretizationPerCell::getHeapMemorySize()+ret;
+ ret+=(*it).getMemorySize();
+ return ret;
}
const char *MEDCouplingFieldDiscretizationGauss::getRepr() const
return REPR;
}
-int MEDCouplingFieldDiscretizationGauss::getNumberOfTuples(const MEDCouplingMesh *) const throw(INTERP_KERNEL::Exception)
+/*!
+ * This method returns the number of tuples regarding exclusively the input code \b without \b using \b a \b mesh \b in \b input.
+ * The input code coherency is also checked regarding spatial discretization of \a this.
+ * If an incoherency is detected, an exception will be thrown. If the input code is coherent, the number of tuples expected is returned.
+ * The number of tuples expected is equal to those to have a valid field lying on \a this and having a mesh fitting perfectly the input code (geometric type distribution).
+ */
+int MEDCouplingFieldDiscretizationGauss::getNumberOfTuplesExpectedRegardingCode(const std::vector<int>& code, const std::vector<const DataArrayInt *>& idsPerType) const
+{
+ if(!_discr_per_cell || !_discr_per_cell->isAllocated() || _discr_per_cell->getNumberOfComponents()!=1)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::getNumberOfTuplesExpectedRegardingCode");
+ if(code.size()%3!=0)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::getNumberOfTuplesExpectedRegardingCode : invalid input code !");
+ int nbOfSplit=(int)idsPerType.size();
+ int nbOfTypes=(int)code.size()/3;
+ std::size_t ret(0);
+ for(int i=0;i<nbOfTypes;i++)
+ {
+ int nbOfEltInChunk=code[3*i+1];
+ if(nbOfEltInChunk<0)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::getNumberOfTuplesExpectedRegardingCode : invalid input code ! presence of negative value in a type !");
+ int pos=code[3*i+2];
+ if(pos!=-1)
+ {
+ if(pos<0 || pos>=nbOfSplit)
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationGauss::getNumberOfTuplesExpectedRegardingCode : input code points to pos " << pos << " in typeid " << i << " ! Should be in [0," << nbOfSplit << ") !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ const DataArrayInt *ids(idsPerType[pos]);
+ if(!ids || !ids->isAllocated() || ids->getNumberOfComponents()!=1 || (int)ids->getNumberOfTuples()!=nbOfEltInChunk || ids->getMinValueInArray()<0)
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationGauss::getNumberOfTuplesExpectedRegardingCode : input pfl chunck at pos " << pos << " should have " << i << " tuples and one component and with ids all >=0 !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ }
+ ret+=nbOfEltInChunk;
+ }
+ if(ret!=_discr_per_cell->getNumberOfTuples())
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationGauss::getNumberOfTuplesExpectedRegardingCode : input code points to " << ret << " cells whereas discretization percell array lgth is " << _discr_per_cell->getNumberOfTuples() << " !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ return getNumberOfTuples(0);//0 is not an error ! It is to be sure that input mesh is not used
+}
+
+int MEDCouplingFieldDiscretizationGauss::getNumberOfTuples(const MEDCouplingMesh *) const
{
int ret=0;
if (_discr_per_cell == 0)
throw INTERP_KERNEL::Exception("Discretization is not initialized!");
const int *dcPtr=_discr_per_cell->getConstPointer();
int nbOfTuples=_discr_per_cell->getNumberOfTuples();
+ int maxSz=(int)_loc.size();
for(const int *w=dcPtr;w!=dcPtr+nbOfTuples;w++)
- ret+=_loc[*w].getNumberOfGaussPt();
+ {
+ if(*w>=0 && *w<maxSz)
+ ret+=_loc[*w].getNumberOfGaussPt();
+ else
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationGauss::getNumberOfTuples : At cell #" << std::distance(dcPtr,w) << " localization id is " << *w << " should be in [0," << maxSz << ") !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ }
return ret;
}
/*!
* This method is redevelopped for performance reasons, but it is equivalent to a call to MEDCouplingFieldDiscretizationGauss::buildNbOfGaussPointPerCellField
- * and a call to DataArrayDouble::computeOffsets2 on the returned array.
+ * and a call to DataArrayDouble::computeOffsetsFull on the returned array.
*/
DataArrayInt *MEDCouplingFieldDiscretizationGauss::getOffsetArr(const MEDCouplingMesh *mesh) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::getOffsetArr : NULL input mesh !");
- int nbOfTuples=mesh->getNumberOfCells();
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
+ std::size_t nbOfTuples(mesh->getNumberOfCells());
+ MCAuto<DataArrayInt> ret=DataArrayInt::New();
ret->alloc(nbOfTuples+1,1);
- int *retPtr=ret->getPointer();
- const int *start=_discr_per_cell->getConstPointer();
+ int *retPtr(ret->getPointer());
+ const int *start(_discr_per_cell->begin());
if(_discr_per_cell->getNumberOfTuples()!=nbOfTuples)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::getOffsetArr : mismatch between the mesh and the discretization ids array length !");
int maxPossible=(int)_loc.size();
retPtr[0]=0;
- for(int i=0;i<nbOfTuples;i++,start++)
+ for(std::size_t i=0;i<nbOfTuples;i++,start++)
{
if(*start>=0 && *start<maxPossible)
retPtr[i+1]=retPtr[i]+_loc[*start].getNumberOfGaussPt();
}
void MEDCouplingFieldDiscretizationGauss::renumberArraysForCell(const MEDCouplingMesh *mesh, const std::vector<DataArray *>& arrays,
- const int *old2NewBg, bool check) throw(INTERP_KERNEL::Exception)
+ const int *old2NewBg, bool check)
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::renumberArraysForCell : NULL input mesh !");
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::getLocalizationOfDiscValues : NULL input mesh !");
checkNoOrphanCells();
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingUMesh> umesh=mesh->buildUnstructured();//in general do nothing
+ MCAuto<MEDCouplingUMesh> umesh=mesh->buildUnstructured();//in general do nothing
int nbOfTuples=getNumberOfTuples(mesh);
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
+ MCAuto<DataArrayDouble> ret=DataArrayDouble::New();
int spaceDim=mesh->getSpaceDimension();
ret->alloc(nbOfTuples,spaceDim);
std::vector< int > locIds;
std::vector<DataArrayInt *> parts=splitIntoSingleGaussDicrPerCellType(locIds);
- std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > parts2(parts.size());
+ std::vector< MCAuto<DataArrayInt> > parts2(parts.size());
std::copy(parts.begin(),parts.end(),parts2.begin());
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> offsets=buildNbOfGaussPointPerCellField();
+ MCAuto<DataArrayInt> offsets=buildNbOfGaussPointPerCellField();
offsets->computeOffsets();
const int *ptrOffsets=offsets->getConstPointer();
const double *coords=umesh->getCoords()->getConstPointer();
{
INTERP_KERNEL::GaussCoords calculator;
//
- const MEDCouplingGaussLocalization& cli=_loc[locIds[i]];//curLocInfo
- INTERP_KERNEL::NormalizedCellType typ=cli.getType();
- const std::vector<double>& wg=cli.getWeights();
+ const MEDCouplingGaussLocalization& cli(_loc[locIds[i]]);//curLocInfo
+ INTERP_KERNEL::NormalizedCellType typ(cli.getType());
+ const std::vector<double>& wg(cli.getWeights());
calculator.addGaussInfo(typ,INTERP_KERNEL::CellModel::GetCellModel(typ).getDimension(),
- &cli.getGaussCoords()[0],(int)wg.size(),&cli.getRefCoords()[0],
- INTERP_KERNEL::CellModel::GetCellModel(typ).getNumberOfNodes());
+ &cli.getGaussCoords()[0],(int)wg.size(),&cli.getRefCoords()[0],
+ INTERP_KERNEL::CellModel::GetCellModel(typ).getNumberOfNodes());
//
- int nbt=parts2[i]->getNumberOfTuples();
- for(const int *w=parts2[i]->getConstPointer();w!=parts2[i]->getConstPointer()+nbt;w++)
+ for(const int *w=parts2[i]->begin();w!=parts2[i]->end();w++)
calculator.calculateCoords(cli.getType(),coords,spaceDim,conn+connI[*w]+1,valsToFill+spaceDim*(ptrOffsets[*w]));
}
ret->copyStringInfoFrom(*umesh->getCoords());
}
void MEDCouplingFieldDiscretizationGauss::computeMeshRestrictionFromTupleIds(const MEDCouplingMesh *mesh, const int *tupleIdsBg, const int *tupleIdsEnd,
- DataArrayInt *&cellRestriction, DataArrayInt *&trueTupleRestriction) const throw(INTERP_KERNEL::Exception)
+ DataArrayInt *&cellRestriction, DataArrayInt *&trueTupleRestriction) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::computeMeshRestrictionFromTupleIds : NULL input mesh !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> tmp=DataArrayInt::New(); tmp->alloc((int)std::distance(tupleIdsBg,tupleIdsEnd),1);
+ MCAuto<DataArrayInt> tmp=DataArrayInt::New(); tmp->alloc((int)std::distance(tupleIdsBg,tupleIdsEnd),1);
std::copy(tupleIdsBg,tupleIdsEnd,tmp->getPointer());
tmp->sort(true);
tmp=tmp->buildUnique();
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> nbOfNodesPerCell=buildNbOfGaussPointPerCellField();
- nbOfNodesPerCell->computeOffsets2();
- nbOfNodesPerCell->searchRangesInListOfIds(tmp,cellRestriction,trueTupleRestriction);
+ MCAuto<DataArrayInt> nbOfNodesPerCell=buildNbOfGaussPointPerCellField();
+ nbOfNodesPerCell->computeOffsetsFull();
+ nbOfNodesPerCell->findIdsRangesInListOfIds(tmp,cellRestriction,trueTupleRestriction);
}
/*!
* Empty : not a bug
*/
-void MEDCouplingFieldDiscretizationGauss::checkCompatibilityWithNature(NatureOfField nat) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGauss::checkCompatibilityWithNature(NatureOfField nat) const
{
}
else
_discr_per_cell=0;
arr=_discr_per_cell;
- int nbOfLoc=tinyInfo[1];
- _loc.clear();
- int dim=tinyInfo[2];
- int delta=-1;
- if(nbOfLoc>0)
- delta=((int)tinyInfo.size()-3)/nbOfLoc;
- for(int i=0;i<nbOfLoc;i++)
+ commonUnserialization(tinyInfo);
+}
+
+void MEDCouplingFieldDiscretizationGauss::checkForUnserialization(const std::vector<int>& tinyInfo, const DataArrayInt *arr)
+{
+ static const char MSG[]="MEDCouplingFieldDiscretizationGauss::checkForUnserialization : expect to have one not null DataArrayInt !";
+ int val=tinyInfo[0];
+ if(val>=0)
{
- std::vector<int> tmp(tinyInfo.begin()+3+i*delta,tinyInfo.begin()+3+(i+1)*delta);
- MEDCouplingGaussLocalization elt=MEDCouplingGaussLocalization::BuildNewInstanceFromTinyInfo(dim,tmp);
- _loc.push_back(elt);
+ if(!arr)
+ throw INTERP_KERNEL::Exception(MSG);
+ arr->checkNbOfTuplesAndComp(val,1,MSG);
+ _discr_per_cell=const_cast<DataArrayInt *>(arr);
+ _discr_per_cell->incrRef();
}
+ else
+ _discr_per_cell=0;
+ commonUnserialization(tinyInfo);
}
void MEDCouplingFieldDiscretizationGauss::finishUnserialization(const std::vector<double>& tinyInfo)
delete [] tmp;
}
-double MEDCouplingFieldDiscretizationGauss::getIJK(const MEDCouplingMesh *mesh, const DataArrayDouble *da,
- int cellId, int nodeIdInCell, int compoId) const throw(INTERP_KERNEL::Exception)
+double MEDCouplingFieldDiscretizationGauss::getIJK(const MEDCouplingMesh *mesh, const DataArrayDouble *da, int cellId, int nodeIdInCell, int compoId) const
{
int offset=getOffsetOfCell(cellId);
return da->getIJ(offset+nodeIdInCell,compoId);
}
-void MEDCouplingFieldDiscretizationGauss::checkCoherencyBetween(const MEDCouplingMesh *mesh, const DataArray *da) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGauss::checkCoherencyBetween(const MEDCouplingMesh *mesh, const DataArray *da) const
{
if(!mesh || !da)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::checkCoherencyBetween : NULL input mesh or DataArray !");
MEDCouplingFieldDiscretizationPerCell::checkCoherencyBetween(mesh,da);
for(std::vector<MEDCouplingGaussLocalization>::const_iterator iter=_loc.begin();iter!=_loc.end();iter++)
- (*iter).checkCoherency();
+ (*iter).checkConsistencyLight();
int nbOfDesc=(int)_loc.size();
int nbOfCells=mesh->getNumberOfCells();
const int *dc=_discr_per_cell->getConstPointer();
{
if(dc[i]>=nbOfDesc)
{
- std::ostringstream oss; oss << "Cell # " << i << " of mesh \"" << mesh->getName() << "\" has an undefined gauss location ! Should never happend !";
+ std::ostringstream oss; oss << "Cell # " << i << " of mesh \"" << mesh->getName() << "\" has an undefined gauss location ! Should never happened !";
throw INTERP_KERNEL::Exception(oss.str().c_str());
}
if(dc[i]<0)
throw INTERP_KERNEL::Exception(oss.str().c_str());
}
}
- int nbOfTuples=getNumberOfTuples(mesh);
+ std::size_t nbOfTuples(getNumberOfTuples(mesh));
if(nbOfTuples!=da->getNumberOfTuples())
{
- std::ostringstream oss; oss << "Invalid number of tuples in the array : expecting " << nbOfTuples << " !";
+ std::ostringstream oss; oss << "Invalid number of tuples in the array : expecting " << nbOfTuples << " having " << da->getNumberOfTuples() << " !";
throw INTERP_KERNEL::Exception(oss.str().c_str());
}
}
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::getMeasureField : mesh instance specified is NULL !");
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> vol=mesh->getMeasureField(isAbs);
+ MCAuto<MEDCouplingFieldDouble> vol=mesh->getMeasureField(isAbs);
const double *volPtr=vol->getArray()->begin();
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=MEDCouplingFieldDouble::New(ON_GAUSS_PT);
+ MCAuto<MEDCouplingFieldDouble> ret=MEDCouplingFieldDouble::New(ON_GAUSS_PT);
ret->setMesh(mesh);
ret->setDiscretization(const_cast<MEDCouplingFieldDiscretizationGauss *>(this));
if(!_discr_per_cell)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::getMeasureField : no discr per cell array defined but with nb of components different from 1 !");
if(_discr_per_cell->getNumberOfTuples()!=vol->getNumberOfTuples())
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::getMeasureField : no discr per cell array defined but mismatch between nb of cells of mesh and size of spatial disr array !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> offset=getOffsetArr(mesh);
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arr=DataArrayDouble::New(); arr->alloc(getNumberOfTuples(mesh),1);
+ MCAuto<DataArrayInt> offset=getOffsetArr(mesh);
+ MCAuto<DataArrayDouble> arr=DataArrayDouble::New(); arr->alloc(getNumberOfTuples(mesh),1);
ret->setArray(arr);
double *arrPtr=arr->getPointer();
const int *offsetPtr=offset->getConstPointer();
int maxGaussLoc=(int)_loc.size();
std::vector<int> locIds;
std::vector<DataArrayInt *> ids=splitIntoSingleGaussDicrPerCellType(locIds);
- std::vector< MEDCouplingAutoRefCountObjectPtr<DataArrayInt> > ids2(ids.size()); std::copy(ids.begin(),ids.end(),ids2.begin());
+ std::vector< MCAuto<DataArrayInt> > ids2(ids.size()); std::copy(ids.begin(),ids.end(),ids2.begin());
for(std::size_t i=0;i<locIds.size();i++)
{
const DataArrayInt *curIds=ids[i];
void MEDCouplingFieldDiscretizationGauss::getValueOnPos(const DataArrayDouble *arr, const MEDCouplingMesh *mesh, int i, int j, int k, double *res) const
{
- throw INTERP_KERNEL::Exception("getValueOnPos(i,j,k) : Not applyable for Gauss points !");
+ throw INTERP_KERNEL::Exception("getValueOnPos(i,j,k) : Not applicable for Gauss points !");
}
DataArrayDouble *MEDCouplingFieldDiscretizationGauss::getValueOnMulti(const DataArrayDouble *arr, const MEDCouplingMesh *mesh, const double *loc, int nbOfPoints) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::buildSubMeshData : NULL input mesh !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> diSafe=computeTupleIdsToSelectFromCellIds(mesh,start,end);
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> ret=mesh->buildPart(start,end);
+ MCAuto<DataArrayInt> diSafe=computeTupleIdsToSelectFromCellIds(mesh,start,end);
+ MCAuto<MEDCouplingMesh> ret=mesh->buildPart(start,end);
di=diSafe.retn();
return ret.retn();
}
else
{ std::ostringstream oss; oss << msg << i << " is detected as orphan !"; throw INTERP_KERNEL::Exception(oss.str().c_str()); }
}
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> ret=mesh->buildPartRange(beginCellIds,endCellIds,stepCellIds);
+ MCAuto<MEDCouplingMesh> ret=mesh->buildPartRange(beginCellIds,endCellIds,stepCellIds);
return ret.retn();
}
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::computeTupleIdsToSelectFromCellIds : null mesh !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> nbOfNodesPerCell=buildNbOfGaussPointPerCellField();//check of _discr_per_cell not NULL pointer
- int nbOfCells=mesh->getNumberOfCells();
+ MCAuto<DataArrayInt> nbOfNodesPerCell=buildNbOfGaussPointPerCellField();//check of _discr_per_cell not NULL pointer
+ std::size_t nbOfCells(mesh->getNumberOfCells());
if(_discr_per_cell->getNumberOfTuples()!=nbOfCells)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::computeTupleIdsToSelectFromCellIds : mismatch of nb of tuples of cell ids array and number of cells !");
- nbOfNodesPerCell->computeOffsets2();
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> sel=DataArrayInt::New(); sel->useArray(startCellIds,false,CPP_DEALLOC,(int)std::distance(startCellIds,endCellIds),1);
+ nbOfNodesPerCell->computeOffsetsFull();
+ MCAuto<DataArrayInt> sel=DataArrayInt::New(); sel->useArray(startCellIds,false,CPP_DEALLOC,(int)std::distance(startCellIds,endCellIds),1);
return sel->buildExplicitArrByRanges(nbOfNodesPerCell);
}
}
void MEDCouplingFieldDiscretizationGauss::setGaussLocalizationOnType(const MEDCouplingMesh *mesh, INTERP_KERNEL::NormalizedCellType type, const std::vector<double>& refCoo,
- const std::vector<double>& gsCoo, const std::vector<double>& wg) throw(INTERP_KERNEL::Exception)
+ const std::vector<double>& gsCoo, const std::vector<double>& wg)
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::setGaussLocalizationOnType : NULL input mesh !");
}
void MEDCouplingFieldDiscretizationGauss::setGaussLocalizationOnCells(const MEDCouplingMesh *mesh, const int *begin, const int *end, const std::vector<double>& refCoo,
- const std::vector<double>& gsCoo, const std::vector<double>& wg) throw(INTERP_KERNEL::Exception)
+ const std::vector<double>& gsCoo, const std::vector<double>& wg)
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::setGaussLocalizationOnCells : NULL input mesh !");
zipGaussLocalizations();
}
-void MEDCouplingFieldDiscretizationGauss::clearGaussLocalizations() throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGauss::clearGaussLocalizations()
{
if(_discr_per_cell)
{
_loc.clear();
}
-void MEDCouplingFieldDiscretizationGauss::setGaussLocalization(int locId, const MEDCouplingGaussLocalization& loc) throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGauss::setGaussLocalization(int locId, const MEDCouplingGaussLocalization& loc)
{
if(locId<0)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::setGaussLocalization : localization id has to be >=0 !");
_loc[locId]=loc;
}
-void MEDCouplingFieldDiscretizationGauss::resizeLocalizationVector(int newSz) throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGauss::resizeLocalizationVector(int newSz)
{
if(newSz<0)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::resizeLocalizationVector : new size has to be >=0 !");
_loc.resize(newSz,gLoc);
}
-MEDCouplingGaussLocalization& MEDCouplingFieldDiscretizationGauss::getGaussLocalization(int locId) throw(INTERP_KERNEL::Exception)
+MEDCouplingGaussLocalization& MEDCouplingFieldDiscretizationGauss::getGaussLocalization(int locId)
{
checkLocalizationId(locId);
return _loc[locId];
}
-int MEDCouplingFieldDiscretizationGauss::getNbOfGaussLocalization() const throw(INTERP_KERNEL::Exception)
+int MEDCouplingFieldDiscretizationGauss::getNbOfGaussLocalization() const
{
return (int)_loc.size();
}
-int MEDCouplingFieldDiscretizationGauss::getGaussLocalizationIdOfOneCell(int cellId) const throw(INTERP_KERNEL::Exception)
+int MEDCouplingFieldDiscretizationGauss::getGaussLocalizationIdOfOneCell(int cellId) const
{
if(!_discr_per_cell)
throw INTERP_KERNEL::Exception("No Gauss localization still set !");
return locId;
}
-int MEDCouplingFieldDiscretizationGauss::getGaussLocalizationIdOfOneType(INTERP_KERNEL::NormalizedCellType type) const throw(INTERP_KERNEL::Exception)
+int MEDCouplingFieldDiscretizationGauss::getGaussLocalizationIdOfOneType(INTERP_KERNEL::NormalizedCellType type) const
{
std::set<int> ret=getGaussLocalizationIdsOfOneType(type);
if(ret.empty())
return *ret.begin();
}
-std::set<int> MEDCouplingFieldDiscretizationGauss::getGaussLocalizationIdsOfOneType(INTERP_KERNEL::NormalizedCellType type) const throw(INTERP_KERNEL::Exception)
+std::set<int> MEDCouplingFieldDiscretizationGauss::getGaussLocalizationIdsOfOneType(INTERP_KERNEL::NormalizedCellType type) const
{
if(!_discr_per_cell)
throw INTERP_KERNEL::Exception("No Gauss localization still set !");
return ret;
}
-void MEDCouplingFieldDiscretizationGauss::getCellIdsHavingGaussLocalization(int locId, std::vector<int>& cellIds) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGauss::getCellIdsHavingGaussLocalization(int locId, std::vector<int>& cellIds) const
{
if(locId<0 || locId>=(int)_loc.size())
throw INTERP_KERNEL::Exception("Invalid locId given : must be in range [0:getNbOfGaussLocalization()) !");
cellIds.push_back(i);
}
-const MEDCouplingGaussLocalization& MEDCouplingFieldDiscretizationGauss::getGaussLocalization(int locId) const throw(INTERP_KERNEL::Exception)
+const MEDCouplingGaussLocalization& MEDCouplingFieldDiscretizationGauss::getGaussLocalization(int locId) const
{
checkLocalizationId(locId);
return _loc[locId];
}
-void MEDCouplingFieldDiscretizationGauss::checkLocalizationId(int locId) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGauss::checkLocalizationId(int locId) const
{
if(locId<0 || locId>=(int)_loc.size())
throw INTERP_KERNEL::Exception("Invalid locId given : must be in range [0:getNbOfGaussLocalization()) !");
}
-int MEDCouplingFieldDiscretizationGauss::getOffsetOfCell(int cellId) const throw(INTERP_KERNEL::Exception)
+int MEDCouplingFieldDiscretizationGauss::getOffsetOfCell(int cellId) const
{
int ret=0;
const int *start=_discr_per_cell->getConstPointer();
* This method returns a newly created array with number of tuples equals to '_discr_per_cell->getNumberOfTuples' and number of components equal to 1.
* The i_th tuple in returned array is the number of gauss point if the corresponding cell.
*/
-DataArrayInt *MEDCouplingFieldDiscretizationGauss::buildNbOfGaussPointPerCellField() const throw(INTERP_KERNEL::Exception)
+DataArrayInt *MEDCouplingFieldDiscretizationGauss::buildNbOfGaussPointPerCellField() const
{
if(!_discr_per_cell)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGauss::buildNbOfGaussPointPerCellField : no discretization array set !");
int nbOfTuples=_discr_per_cell->getNumberOfTuples();
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ret=DataArrayInt::New();
+ MCAuto<DataArrayInt> ret=DataArrayInt::New();
const int *w=_discr_per_cell->begin();
ret->alloc(nbOfTuples,1);
int *valsToFill=ret->getPointer();
return ret.retn();
}
-void MEDCouplingFieldDiscretizationGauss::reprQuickOverview(std::ostream& stream) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGauss::reprQuickOverview(std::ostream& stream) const
{
stream << "Gauss points spatial discretization.";
}
std::vector<MEDCouplingGaussLocalization> tmpLoc;
for(int i=0;i<(int)_loc.size();i++)
if(tmp[i]!=-2)
- tmpLoc.push_back(_loc[tmp[i]]);
+ tmpLoc.push_back(_loc[i]);
_loc=tmpLoc;
}
+void MEDCouplingFieldDiscretizationGauss::commonUnserialization(const std::vector<int>& tinyInfo)
+{
+ int nbOfLoc=tinyInfo[1];
+ _loc.clear();
+ int dim=tinyInfo[2];
+ int delta=-1;
+ if(nbOfLoc>0)
+ delta=((int)tinyInfo.size()-3)/nbOfLoc;
+ for(int i=0;i<nbOfLoc;i++)
+ {
+ std::vector<int> tmp(tinyInfo.begin()+3+i*delta,tinyInfo.begin()+3+(i+1)*delta);
+ MEDCouplingGaussLocalization elt=MEDCouplingGaussLocalization::BuildNewInstanceFromTinyInfo(dim,tmp);
+ _loc.push_back(elt);
+ }
+}
+
MEDCouplingFieldDiscretizationGaussNE::MEDCouplingFieldDiscretizationGaussNE()
{
}
}
/*!
- * This method is simply called by MEDCouplingFieldDiscretization::deepCpy. It performs the deep copy of \a this.
+ * This method is simply called by MEDCouplingFieldDiscretization::deepCopy. It performs the deep copy of \a this.
*
- * \sa MEDCouplingFieldDiscretization::deepCpy.
+ * \sa MEDCouplingFieldDiscretization::deepCopy.
*/
MEDCouplingFieldDiscretization *MEDCouplingFieldDiscretizationGaussNE::clone() const
{
return ret;
}
-int MEDCouplingFieldDiscretizationGaussNE::getNumberOfTuples(const MEDCouplingMesh *mesh) const throw(INTERP_KERNEL::Exception)
+/*!
+ * This method returns the number of tuples regarding exclusively the input code \b without \b using \b a \b mesh \b in \b input.
+ * The input code coherency is also checked regarding spatial discretization of \a this.
+ * If an incoherency is detected, an exception will be thrown. If the input code is coherent, the number of tuples expected is returned.
+ * The number of tuples expected is equal to those to have a valid field lying on \a this and having a mesh fitting perfectly the input code (geometric type distribution).
+ */
+int MEDCouplingFieldDiscretizationGaussNE::getNumberOfTuplesExpectedRegardingCode(const std::vector<int>& code, const std::vector<const DataArrayInt *>& idsPerType) const
+{
+ if(code.size()%3!=0)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::getNumberOfTuplesExpectedRegardingCode : invalid input code !");
+ int nbOfSplit=(int)idsPerType.size();
+ int nbOfTypes=(int)code.size()/3;
+ int ret(0);
+ for(int i=0;i<nbOfTypes;i++)
+ {
+ const INTERP_KERNEL::CellModel& cm(INTERP_KERNEL::CellModel::GetCellModel((INTERP_KERNEL::NormalizedCellType)code[3*i]));
+ if(cm.isDynamic())
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationGaussNE::getNumberOfTuplesExpectedRegardingCode : At pos #" << i << " the geometric type " << cm.getRepr() << " is dynamic ! There are not managed by GAUSS_NE field discretization !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ int nbOfEltInChunk=code[3*i+1];
+ if(nbOfEltInChunk<0)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::getNumberOfTuplesExpectedRegardingCode : invalid input code ! presence of negative value in a type !");
+ int pos=code[3*i+2];
+ if(pos!=-1)
+ {
+ if(pos<0 || pos>=nbOfSplit)
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationGaussNE::getNumberOfTuplesExpectedRegardingCode : input code points to pos " << pos << " in typeid " << i << " ! Should be in [0," << nbOfSplit << ") !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ const DataArrayInt *ids(idsPerType[pos]);
+ if(!ids || !ids->isAllocated() || ids->getNumberOfComponents()!=1 || (int)ids->getNumberOfTuples()!=nbOfEltInChunk || ids->getMinValueInArray()<0)
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationGaussNE::getNumberOfTuplesExpectedRegardingCode : input pfl chunck at pos " << pos << " should have " << i << " tuples and one component and with ids all >=0 !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ }
+ ret+=nbOfEltInChunk*(int)cm.getNumberOfNodes();
+ }
+ return ret;
+}
+
+int MEDCouplingFieldDiscretizationGaussNE::getNumberOfTuples(const MEDCouplingMesh *mesh) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::getNumberOfTuples : NULL input mesh !");
}
void MEDCouplingFieldDiscretizationGaussNE::renumberArraysForCell(const MEDCouplingMesh *mesh, const std::vector<DataArray *>& arrays,
- const int *old2NewBg, bool check) throw(INTERP_KERNEL::Exception)
+ const int *old2NewBg, bool check)
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::renumberArraysForCell : NULL input mesh !");
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::getLocalizationOfDiscValues : NULL input mesh !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingUMesh> umesh=mesh->buildUnstructured();//in general do nothing
+ MCAuto<DataArrayDouble> ret=DataArrayDouble::New();
+ MCAuto<MEDCouplingUMesh> umesh=mesh->buildUnstructured();//in general do nothing
int nbOfTuples=getNumberOfTuples(umesh);
int spaceDim=mesh->getSpaceDimension();
ret->alloc(nbOfTuples,spaceDim);
/*!
* Reimplemented from MEDCouplingFieldDiscretization::integral for performance reason. The default implementation is valid too for GAUSS_NE spatial discretization.
*/
-void MEDCouplingFieldDiscretizationGaussNE::integral(const MEDCouplingMesh *mesh, const DataArrayDouble *arr, bool isWAbs, double *res) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGaussNE::integral(const MEDCouplingMesh *mesh, const DataArrayDouble *arr, bool isWAbs, double *res) const
{
if(!mesh || !arr)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::integral : input mesh or array is null !");
int nbOfCompo=arr->getNumberOfComponents();
std::fill(res,res+nbOfCompo,0.);
//
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> vol=mesh->getMeasureField(isWAbs);
+ MCAuto<MEDCouplingFieldDouble> vol=mesh->getMeasureField(isWAbs);
std::set<INTERP_KERNEL::NormalizedCellType> types=mesh->getAllGeoTypes();
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> nbOfNodesPerCell=mesh->computeNbOfNodesPerCell();
- nbOfNodesPerCell->computeOffsets2();
+ MCAuto<DataArrayInt> nbOfNodesPerCell=mesh->computeNbOfNodesPerCell();
+ nbOfNodesPerCell->computeOffsetsFull();
const double *arrPtr=arr->begin(),*volPtr=vol->getArray()->begin();
for(std::set<INTERP_KERNEL::NormalizedCellType>::const_iterator it=types.begin();it!=types.end();it++)
{
INTERP_KERNEL::AutoPtr<double> wArr2=new double[wArrSz];
double sum=std::accumulate(wArr,wArr+wArrSz,0.);
std::transform(wArr,wArr+wArrSz,(double *)wArr2,std::bind2nd(std::multiplies<double>(),1./sum));
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ids=mesh->giveCellsWithType(*it);
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ids2=ids->buildExplicitArrByRanges(nbOfNodesPerCell);
+ MCAuto<DataArrayInt> ids=mesh->giveCellsWithType(*it);
+ MCAuto<DataArrayInt> ids2=ids->buildExplicitArrByRanges(nbOfNodesPerCell);
const int *ptIds2=ids2->begin(),*ptIds=ids->begin();
int nbOfCellsWithCurGeoType=ids->getNumberOfTuples();
for(int i=0;i<nbOfCellsWithCurGeoType;i++,ptIds++,ptIds2+=wArrSz)
}
}
-const double *MEDCouplingFieldDiscretizationGaussNE::GetWeightArrayFromGeometricType(INTERP_KERNEL::NormalizedCellType geoType, std::size_t& lgth) throw(INTERP_KERNEL::Exception)
+const double *MEDCouplingFieldDiscretizationGaussNE::GetWeightArrayFromGeometricType(INTERP_KERNEL::NormalizedCellType geoType, std::size_t& lgth)
{
switch(geoType)
- {
+ {
+ case INTERP_KERNEL::NORM_POINT1:
+ lgth=(int)sizeof(FGP_POINT1)/sizeof(double);
+ return FGP_POINT1;
case INTERP_KERNEL::NORM_SEG2:
lgth=(int)sizeof(FGP_SEG2)/sizeof(double);
return FGP_SEG2;
case INTERP_KERNEL::NORM_QUAD4:
lgth=(int)sizeof(FGP_QUAD4)/sizeof(double);
return FGP_QUAD4;
+ case INTERP_KERNEL::NORM_QUAD8:
+ lgth=(int)sizeof(FGP_QUAD8)/sizeof(double);
+ return FGP_QUAD8;
case INTERP_KERNEL::NORM_QUAD9:
lgth=(int)sizeof(FGP_QUAD9)/sizeof(double);
return FGP_QUAD9;
case INTERP_KERNEL::NORM_TETRA4:
lgth=(int)sizeof(FGP_TETRA4)/sizeof(double);
return FGP_TETRA4;
+ case INTERP_KERNEL::NORM_TETRA10:
+ lgth=(int)sizeof(FGP_TETRA10)/sizeof(double);
+ return FGP_TETRA10;
case INTERP_KERNEL::NORM_PENTA6:
lgth=(int)sizeof(FGP_PENTA6)/sizeof(double);
return FGP_PENTA6;
+ case INTERP_KERNEL::NORM_PENTA15:
+ lgth=(int)sizeof(FGP_PENTA15)/sizeof(double);
+ return FGP_PENTA15;
case INTERP_KERNEL::NORM_HEXA8:
lgth=(int)sizeof(FGP_HEXA8)/sizeof(double);
return FGP_HEXA8;
+ case INTERP_KERNEL::NORM_HEXA20:
+ lgth=(int)sizeof(FGP_HEXA20)/sizeof(double);
+ return FGP_HEXA20;
case INTERP_KERNEL::NORM_HEXA27:
lgth=(int)sizeof(FGP_HEXA27)/sizeof(double);
return FGP_HEXA27;
case INTERP_KERNEL::NORM_PYRA5:
lgth=(int)sizeof(FGP_PYRA5)/sizeof(double);
return FGP_PYRA5;
+ case INTERP_KERNEL::NORM_PYRA13:
+ lgth=(int)sizeof(FGP_PYRA13)/sizeof(double);
+ return FGP_PYRA13;
default:
- throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::GetWeightArrayFromGeometricType : only SEG[2,3,4], TRI[3,6,7], QUAD[4,9], TETRA4, PENTA6, HEXA[8,27], PYRA5 supported !");
- }
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::GetWeightArrayFromGeometricType : only SEG[2,3,4], TRI[3,6,7], QUAD[4,9], TETRA[4,10], PENTA[6,15], HEXA[8,20,27], PYRA[5,13] supported !");
+ }
}
-const double *MEDCouplingFieldDiscretizationGaussNE::GetRefCoordsFromGeometricType(INTERP_KERNEL::NormalizedCellType geoType, std::size_t& lgth) throw(INTERP_KERNEL::Exception)
+const double *MEDCouplingFieldDiscretizationGaussNE::GetRefCoordsFromGeometricType(INTERP_KERNEL::NormalizedCellType geoType, std::size_t& lgth)
{
switch(geoType)
- {
+ {
+ case INTERP_KERNEL::NORM_POINT1:
+ lgth=0;
+ return 0;
case INTERP_KERNEL::NORM_SEG2:
lgth=(int)sizeof(REF_SEG2)/sizeof(double);
return REF_SEG2;
return REF_PYRA13;
default:
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::GetRefCoordsFromGeometricType : only SEG[2,3,4], TRI[3,6,7], QUAD[4,8,9], TETRA[4,10], PENTA[6,15], HEXA[8,20,27], PYRA[5,13] supported !");
- }
+ }
+}
+
+const double *MEDCouplingFieldDiscretizationGaussNE::GetLocsFromGeometricType(INTERP_KERNEL::NormalizedCellType geoType, std::size_t& lgth)
+{
+ switch(geoType)
+ {
+ case INTERP_KERNEL::NORM_POINT1:
+ {
+ lgth=0;
+ return 0;
+ }
+ case INTERP_KERNEL::NORM_SEG2:
+ {
+ lgth=(int)sizeof(LOC_SEG2)/sizeof(double);
+ return LOC_SEG2;
+ }
+ case INTERP_KERNEL::NORM_SEG3:
+ {
+ lgth=(int)sizeof(LOC_SEG3)/sizeof(double);
+ return LOC_SEG3;
+ }
+ case INTERP_KERNEL::NORM_SEG4:
+ {
+ lgth=(int)sizeof(LOC_SEG4)/sizeof(double);
+ return LOC_SEG4;
+ }
+ case INTERP_KERNEL::NORM_TRI3:
+ {
+ lgth=(int)sizeof(LOC_TRI3)/sizeof(double);
+ return LOC_TRI3;
+ }
+ case INTERP_KERNEL::NORM_TRI6:
+ {
+ lgth=(int)sizeof(LOC_TRI6)/sizeof(double);
+ return LOC_TRI6;
+ }
+ case INTERP_KERNEL::NORM_TRI7:
+ {
+ lgth=(int)sizeof(LOC_TRI7)/sizeof(double);
+ return LOC_TRI7;
+ }
+ case INTERP_KERNEL::NORM_QUAD4:
+ {
+ lgth=(int)sizeof(LOC_QUAD4)/sizeof(double);
+ return LOC_QUAD4;
+ }
+ case INTERP_KERNEL::NORM_QUAD8:
+ {
+ lgth=(int)sizeof(LOC_QUAD8)/sizeof(double);
+ return LOC_QUAD8;
+ }
+ case INTERP_KERNEL::NORM_QUAD9:
+ {
+ lgth=(int)sizeof(LOC_QUAD9)/sizeof(double);
+ return LOC_QUAD9;
+ }
+ case INTERP_KERNEL::NORM_TETRA4:
+ {
+ lgth=(int)sizeof(LOC_TETRA4)/sizeof(double);
+ return LOC_TETRA4;
+ }
+ case INTERP_KERNEL::NORM_TETRA10:
+ {
+ lgth=(int)sizeof(LOC_TETRA10)/sizeof(double);
+ return LOC_TETRA10;
+ }
+ case INTERP_KERNEL::NORM_PENTA6:
+ {
+ lgth=(int)sizeof(LOC_PENTA6)/sizeof(double);
+ return LOC_PENTA6;
+ }
+ case INTERP_KERNEL::NORM_PENTA15:
+ {
+ lgth=(int)sizeof(LOC_PENTA15)/sizeof(double);
+ return LOC_PENTA15;
+ }
+ case INTERP_KERNEL::NORM_HEXA8:
+ {
+ lgth=(int)sizeof(LOC_HEXA8)/sizeof(double);
+ return LOC_HEXA8;
+ }
+ case INTERP_KERNEL::NORM_HEXA20:
+ {
+ lgth=(int)sizeof(LOC_HEXA20)/sizeof(double);
+ return LOC_HEXA20;
+ }
+ case INTERP_KERNEL::NORM_HEXA27:
+ {
+ lgth=(int)sizeof(LOC_HEXA27)/sizeof(double);
+ return LOC_HEXA27;
+ }
+ case INTERP_KERNEL::NORM_PYRA5:
+ {
+ lgth=(int)sizeof(LOC_PYRA5)/sizeof(double);
+ return LOC_PYRA5;
+ }
+ case INTERP_KERNEL::NORM_PYRA13:
+ {
+ lgth=(int)sizeof(LOC_PYRA13)/sizeof(double);
+ return LOC_PYRA13;
+ }
+ default:
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::GetLocsFromGeometricType : only SEG[2,3,4], TRI[3,6,7], QUAD[4,8,9], TETRA[4,10], PENTA[6,15], HEXA[8,20,27], PYRA[5,13] supported !");
+ }
}
void MEDCouplingFieldDiscretizationGaussNE::computeMeshRestrictionFromTupleIds(const MEDCouplingMesh *mesh, const int *tupleIdsBg, const int *tupleIdsEnd,
- DataArrayInt *&cellRestriction, DataArrayInt *&trueTupleRestriction) const throw(INTERP_KERNEL::Exception)
+ DataArrayInt *&cellRestriction, DataArrayInt *&trueTupleRestriction) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::computeMeshRestrictionFromTupleIds : NULL input mesh !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> tmp=DataArrayInt::New(); tmp->alloc((int)std::distance(tupleIdsBg,tupleIdsEnd),1);
+ MCAuto<DataArrayInt> tmp=DataArrayInt::New(); tmp->alloc((int)std::distance(tupleIdsBg,tupleIdsEnd),1);
std::copy(tupleIdsBg,tupleIdsEnd,tmp->getPointer());
tmp->sort(true);
tmp=tmp->buildUnique();
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> nbOfNodesPerCell=mesh->computeNbOfNodesPerCell();
- nbOfNodesPerCell->computeOffsets2();
- nbOfNodesPerCell->searchRangesInListOfIds(tmp,cellRestriction,trueTupleRestriction);
+ MCAuto<DataArrayInt> nbOfNodesPerCell=mesh->computeNbOfNodesPerCell();
+ nbOfNodesPerCell->computeOffsetsFull();
+ nbOfNodesPerCell->findIdsRangesInListOfIds(tmp,cellRestriction,trueTupleRestriction);
}
-void MEDCouplingFieldDiscretizationGaussNE::checkCompatibilityWithNature(NatureOfField nat) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGaussNE::checkCompatibilityWithNature(NatureOfField nat) const
{
}
-double MEDCouplingFieldDiscretizationGaussNE::getIJK(const MEDCouplingMesh *mesh, const DataArrayDouble *da,
- int cellId, int nodeIdInCell, int compoId) const throw(INTERP_KERNEL::Exception)
+double MEDCouplingFieldDiscretizationGaussNE::getIJK(const MEDCouplingMesh *mesh, const DataArrayDouble *da, int cellId, int nodeIdInCell, int compoId) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::getIJK : NULL input mesh !");
return da->getIJ(offset+nodeIdInCell,compoId);
}
-void MEDCouplingFieldDiscretizationGaussNE::checkCoherencyBetween(const MEDCouplingMesh *mesh, const DataArray *da) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGaussNE::checkCoherencyBetween(const MEDCouplingMesh *mesh, const DataArray *da) const
{
- int nbOfTuples=getNumberOfTuples(mesh);
+ std::size_t nbOfTuples(getNumberOfTuples(mesh));
if(nbOfTuples!=da->getNumberOfTuples())
{
std::ostringstream oss; oss << "Invalid number of tuples in the array : expecting " << nbOfTuples << " !";
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::getMeasureField : mesh instance specified is NULL !");
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> vol=mesh->getMeasureField(isAbs);
+ MCAuto<MEDCouplingFieldDouble> vol=mesh->getMeasureField(isAbs);
const double *volPtr=vol->getArray()->begin();
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingFieldDouble> ret=MEDCouplingFieldDouble::New(ON_GAUSS_NE);
+ MCAuto<MEDCouplingFieldDouble> ret=MEDCouplingFieldDouble::New(ON_GAUSS_NE);
ret->setMesh(mesh);
//
std::set<INTERP_KERNEL::NormalizedCellType> types=mesh->getAllGeoTypes();
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> nbOfNodesPerCell=mesh->computeNbOfNodesPerCell();
+ MCAuto<DataArrayInt> nbOfNodesPerCell=mesh->computeNbOfNodesPerCell();
int nbTuples=nbOfNodesPerCell->accumulate(0);
- nbOfNodesPerCell->computeOffsets2();
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arr=DataArrayDouble::New(); arr->alloc(nbTuples,1);
+ nbOfNodesPerCell->computeOffsetsFull();
+ MCAuto<DataArrayDouble> arr=DataArrayDouble::New(); arr->alloc(nbTuples,1);
ret->setArray(arr);
double *arrPtr=arr->getPointer();
for(std::set<INTERP_KERNEL::NormalizedCellType>::const_iterator it=types.begin();it!=types.end();it++)
INTERP_KERNEL::AutoPtr<double> wArr2=new double[wArrSz];
double sum=std::accumulate(wArr,wArr+wArrSz,0.);
std::transform(wArr,wArr+wArrSz,(double *)wArr2,std::bind2nd(std::multiplies<double>(),1./sum));
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ids=mesh->giveCellsWithType(*it);
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> ids2=ids->buildExplicitArrByRanges(nbOfNodesPerCell);
+ MCAuto<DataArrayInt> ids=mesh->giveCellsWithType(*it);
+ MCAuto<DataArrayInt> ids2=ids->buildExplicitArrByRanges(nbOfNodesPerCell);
const int *ptIds2=ids2->begin(),*ptIds=ids->begin();
int nbOfCellsWithCurGeoType=ids->getNumberOfTuples();
for(int i=0;i<nbOfCellsWithCurGeoType;i++,ptIds++)
void MEDCouplingFieldDiscretizationGaussNE::getValueOnPos(const DataArrayDouble *arr, const MEDCouplingMesh *mesh, int i, int j, int k, double *res) const
{
- throw INTERP_KERNEL::Exception("getValueOnPos(i,j,k) : Not applyable for Gauss points !");
+ throw INTERP_KERNEL::Exception("getValueOnPos(i,j,k) : Not applicable for Gauss points !");
}
DataArrayDouble *MEDCouplingFieldDiscretizationGaussNE::getValueOnMulti(const DataArrayDouble *arr, const MEDCouplingMesh *mesh, const double *loc, int nbOfPoints) const
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::buildSubMeshData : NULL input mesh !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> diSafe=computeTupleIdsToSelectFromCellIds(mesh,start,end);
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> ret=mesh->buildPart(start,end);
+ MCAuto<DataArrayInt> diSafe=computeTupleIdsToSelectFromCellIds(mesh,start,end);
+ MCAuto<MEDCouplingMesh> ret=mesh->buildPart(start,end);
di=diSafe.retn();
return ret.retn();
}
if(i>=endCellIds)
break;
}
- MEDCouplingAutoRefCountObjectPtr<MEDCouplingMesh> ret=mesh->buildPartRange(beginCellIds,endCellIds,stepCellIds);
+ MCAuto<MEDCouplingMesh> ret=mesh->buildPartRange(beginCellIds,endCellIds,stepCellIds);
return ret.retn();
}
{
if(!mesh)
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationGaussNE::computeTupleIdsToSelectFromCellIds : null mesh !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> nbOfNodesPerCell=mesh->computeNbOfNodesPerCell();
- nbOfNodesPerCell->computeOffsets2();
- MEDCouplingAutoRefCountObjectPtr<DataArrayInt> sel=DataArrayInt::New(); sel->useArray(startCellIds,false,CPP_DEALLOC,(int)std::distance(startCellIds,endCellIds),1);
+ MCAuto<DataArrayInt> nbOfNodesPerCell=mesh->computeNbOfNodesPerCell();
+ nbOfNodesPerCell->computeOffsetsFull();
+ MCAuto<DataArrayInt> sel=DataArrayInt::New(); sel->useArray(startCellIds,false,CPP_DEALLOC,(int)std::distance(startCellIds,endCellIds),1);
return sel->buildExplicitArrByRanges(nbOfNodesPerCell);
}
throw INTERP_KERNEL::Exception("Not implemented yet !");
}
-void MEDCouplingFieldDiscretizationGaussNE::reprQuickOverview(std::ostream& stream) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationGaussNE::reprQuickOverview(std::ostream& stream) const
{
stream << "Gauss points on nodes per element spatial discretization.";
}
}
/*!
- * This method is simply called by MEDCouplingFieldDiscretization::deepCpy. It performs the deep copy of \a this.
+ * This method is simply called by MEDCouplingFieldDiscretization::deepCopy. It performs the deep copy of \a this.
*
- * \sa MEDCouplingFieldDiscretization::deepCpy.
+ * \sa MEDCouplingFieldDiscretization::deepCopy.
*/
MEDCouplingFieldDiscretization *MEDCouplingFieldDiscretizationKriging::clone() const
{
return std::string(REPR);
}
-void MEDCouplingFieldDiscretizationKriging::checkCompatibilityWithNature(NatureOfField nat) const throw(INTERP_KERNEL::Exception)
+void MEDCouplingFieldDiscretizationKriging::checkCompatibilityWithNature(NatureOfField nat) const
{
- if(nat!=ConservativeVolumic)
- throw INTERP_KERNEL::Exception("Invalid nature for Kriging field : expected ConservativeVolumic !");
+ if(nat!=IntensiveMaximum)
+ throw INTERP_KERNEL::Exception("Invalid nature for Kriging field : expected IntensiveMaximum !");
}
bool MEDCouplingFieldDiscretizationKriging::isEqualIfNotWhy(const MEDCouplingFieldDiscretization *other, double eps, std::string& reason) const
void MEDCouplingFieldDiscretizationKriging::getValueOn(const DataArrayDouble *arr, const MEDCouplingMesh *mesh, const double *loc, double *res) const
{
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> res2=MEDCouplingFieldDiscretizationKriging::getValueOnMulti(arr,mesh,loc,1);
+ MCAuto<DataArrayDouble> res2=MEDCouplingFieldDiscretizationKriging::getValueOnMulti(arr,mesh,loc,1);
std::copy(res2->begin(),res2->end(),res);
}
DataArrayDouble *MEDCouplingFieldDiscretizationKriging::getValueOnMulti(const DataArrayDouble *arr, const MEDCouplingMesh *mesh, const double *loc, int nbOfTargetPoints) const
{
- if(!mesh)
- throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::getValueOnMulti : NULL input mesh !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> coords=getLocalizationOfDiscValues(mesh);
- int nbOfPts=coords->getNumberOfTuples();
- int dimension=coords->getNumberOfComponents();
- //
- int delta=0;
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> KnewiK=computeVectorOfCoefficients(mesh,arr,delta);
+ if(!arr || !arr->isAllocated())
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::getValueOnMulti : input array is null or not allocated !");
+ std::size_t nbOfRows(getNumberOfMeshPlaces(mesh));
+ if(arr->getNumberOfTuples()!=nbOfRows)
+ {
+ std::ostringstream oss; oss << "MEDCouplingFieldDiscretizationKriging::getValueOnMulti : input array does not have correct number of tuples ! Excepted " << nbOfRows << " having " << arr->getNumberOfTuples() << " !";
+ throw INTERP_KERNEL::Exception(oss.str().c_str());
+ }
+ int nbCols(-1),nbCompo(arr->getNumberOfComponents());
+ MCAuto<DataArrayDouble> m(computeEvaluationMatrixOnGivenPts(mesh,loc,nbOfTargetPoints,nbCols));
+ MCAuto<DataArrayDouble> ret(DataArrayDouble::New());
+ ret->alloc(nbOfTargetPoints,nbCompo);
+ INTERP_KERNEL::matrixProduct(m->begin(),nbOfTargetPoints,nbCols,arr->begin(),nbOfRows,nbCompo,ret->getPointer());
+ return ret.retn();
+}
+
+void MEDCouplingFieldDiscretizationKriging::reprQuickOverview(std::ostream& stream) const
+{
+ stream << "Kriging spatial discretization.";
+}
+
+/*!
+ * Returns the matrix of size nbRows = \a nbOfTargetPoints and \a nbCols = \a nbCols. This matrix is useful if
+ *
+ * \return the new result matrix to be deallocated by the caller.
+ */
+DataArrayDouble *MEDCouplingFieldDiscretizationKriging::computeEvaluationMatrixOnGivenPts(const MEDCouplingMesh *mesh, const double *loc, int nbOfTargetPoints, int& nbCols) const
+{
+ int isDrift(-1),nbRows(-1);
+ MCAuto<DataArrayDouble> matrixInv(computeInverseMatrix(mesh,isDrift,nbRows));
//
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> locArr=DataArrayDouble::New();
+ MCAuto<DataArrayDouble> coords=getLocalizationOfDiscValues(mesh);
+ int nbOfPts(coords->getNumberOfTuples()),dimension(coords->getNumberOfComponents());
+ MCAuto<DataArrayDouble> locArr=DataArrayDouble::New();
locArr->useArray(loc,false,CPP_DEALLOC,nbOfTargetPoints,dimension);
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> matrix2=coords->buildEuclidianDistanceDenseMatrixWith(locArr);
- operateOnDenseMatrix(mesh->getSpaceDimension(),nbOfPts*nbOfTargetPoints,matrix2->getPointer());
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> matrix3=DataArrayDouble::New();
- matrix3->alloc((nbOfPts+delta)*nbOfTargetPoints,1);
+ nbCols=nbOfPts;
+ //
+ MCAuto<DataArrayDouble> matrix2=coords->buildEuclidianDistanceDenseMatrixWith(locArr);
+ operateOnDenseMatrix(mesh->getSpaceDimension(),nbOfTargetPoints*nbOfPts,matrix2->getPointer());
+ //
+ MCAuto<DataArrayDouble> matrix3=DataArrayDouble::New();
+ matrix3->alloc(nbOfTargetPoints*nbRows,1);
double *work=matrix3->getPointer();
- const double *workCst=matrix2->getConstPointer();
- const double *workCst2=loc;
- for(int i=0;i<nbOfTargetPoints;i++,workCst+=nbOfPts,workCst2+=delta-1)
+ const double *workCst(matrix2->begin()),*workCst2(loc);
+ for(int i=0;i<nbOfTargetPoints;i++,workCst+=nbOfPts,workCst2+=isDrift-1)
{
for(int j=0;j<nbOfPts;j++)
- work[j*nbOfTargetPoints+i]=workCst[j];
- work[nbOfPts*nbOfTargetPoints+i]=1.0;
- for(int j=0;j<delta-1;j++)
- work[(nbOfPts+1+j)*nbOfTargetPoints+i]=workCst2[j];
+ work[i*nbRows+j]=workCst[j];
+ work[i*nbRows+nbOfPts]=1.0;
+ for(int j=0;j<isDrift-1;j++)
+ work[i*nbRows+(nbOfPts+1+j)]=workCst2[j];
}
- //
- int nbOfCompo=arr->getNumberOfComponents();
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
- ret->alloc(nbOfTargetPoints,nbOfCompo);
- INTERP_KERNEL::matrixProduct(KnewiK->getConstPointer(),1,nbOfPts+delta,matrix3->getConstPointer(),nbOfPts+delta,nbOfTargetPoints*nbOfCompo,ret->getPointer());
- return ret.retn();
+ MCAuto<DataArrayDouble> ret(DataArrayDouble::New());
+ ret->alloc(nbOfTargetPoints,nbRows);
+ INTERP_KERNEL::matrixProduct(matrix3->begin(),nbOfTargetPoints,nbRows,matrixInv->begin(),nbRows,nbRows,ret->getPointer());
+ MCAuto<DataArrayDouble> ret2(DataArrayDouble::New());
+ ret2->alloc(nbOfTargetPoints*nbOfPts,1);
+ workCst=ret->begin(); work=ret2->getPointer();
+ for(int i=0;i<nbOfTargetPoints;i++,workCst+=nbRows)
+ work=std::copy(workCst,workCst+nbOfPts,work);
+ return ret2.retn();
}
-void MEDCouplingFieldDiscretizationKriging::reprQuickOverview(std::ostream& stream) const throw(INTERP_KERNEL::Exception)
+/*!
+ * This method returns the square matrix of size \a matSz that is the inverse of the kriging matrix. The returned matrix can returned all the coeffs of kriging
+ * when multiplied by the vector of values attached to each point.
+ *
+ * \param [out] isDrift return if drift coefficients are present in the returned vector of coefficients. If different from 0 there is presence of drift coefficients.
+ * \param [out] matSz the size of returned square matrix
+ * \return the new result matrix to be deallocated by the caller.
+ * \sa computeMatrix
+ */
+DataArrayDouble *MEDCouplingFieldDiscretizationKriging::computeInverseMatrix(const MEDCouplingMesh *mesh, int& isDrift, int& matSz) const
{
- stream << "Kriging spatial discretization.";
+ MCAuto<DataArrayDouble> matrixWithDrift(computeMatrix(mesh,isDrift,matSz));
+ MCAuto<DataArrayDouble> matrixInv(DataArrayDouble::New());
+ matrixInv->alloc(matSz*matSz,1);
+ INTERP_KERNEL::inverseMatrix(matrixWithDrift->getConstPointer(),matSz,matrixInv->getPointer());
+ return matrixInv.retn();
+}
+
+/*!
+ * This method computes the kriging matrix.
+ * \return the new result matrix to be deallocated by the caller.
+ * \sa computeInverseMatrix
+ */
+DataArrayDouble *MEDCouplingFieldDiscretizationKriging::computeMatrix(const MEDCouplingMesh *mesh, int& isDrift, int& matSz) const
+{
+ if(!mesh)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::computeMatrix : NULL input mesh !");
+ MCAuto<DataArrayDouble> coords(getLocalizationOfDiscValues(mesh));
+ int nbOfPts(coords->getNumberOfTuples());
+ MCAuto<DataArrayDouble> matrix(coords->buildEuclidianDistanceDenseMatrix());
+ operateOnDenseMatrix(mesh->getSpaceDimension(),nbOfPts*nbOfPts,matrix->getPointer());
+ // Drift
+ MCAuto<DataArrayDouble> matrixWithDrift(performDrift(matrix,coords,isDrift));
+ matSz=nbOfPts+isDrift;
+ return matrixWithDrift.retn();
}
/*!
*
* \param [in] mesh is the sources of nodes on which kriging will be done regarding the parameters and the value of \c this->getSpaceDimension()
* \param [in] arr input field DataArrayDouble whose number of tuples must be equal to the number of nodes in \a mesh
- * \param [out] isDrift return if drift coefficients are present in the returned vector of coefficients, and if. If different from 0 there is presence of drift coefficients.
+ * \param [out] isDrift return if drift coefficients are present in the returned vector of coefficients. If different from 0 there is presence of drift coefficients.
* Whatever the value of \a isDrift the number of tuples of returned DataArrayDouble will be equal to \c arr->getNumberOfTuples() + \a isDrift.
* \return a newly allocated array containing coefficients including or not drift coefficient at the end depending the value of \a isDrift parameter.
*/
DataArrayDouble *MEDCouplingFieldDiscretizationKriging::computeVectorOfCoefficients(const MEDCouplingMesh *mesh, const DataArrayDouble *arr, int& isDrift) const
{
- if(!mesh)
- throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::computeVectorOfCoefficients : NULL input mesh !");
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> coords=getLocalizationOfDiscValues(mesh);
- int nbOfPts=coords->getNumberOfTuples();
- //int dimension=coords->getNumberOfComponents();
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> matrix=coords->buildEuclidianDistanceDenseMatrix();
- operateOnDenseMatrix(mesh->getSpaceDimension(),nbOfPts*nbOfPts,matrix->getPointer());
- // Drift
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> matrixWithDrift=performDrift(matrix,coords,isDrift);
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> matrixInv=DataArrayDouble::New();
- matrixInv->alloc((nbOfPts+isDrift)*(nbOfPts+isDrift),1);
- INTERP_KERNEL::inverseMatrix(matrixWithDrift->getConstPointer(),nbOfPts+isDrift,matrixInv->getPointer());
- //
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> KnewiK=DataArrayDouble::New();
- KnewiK->alloc((nbOfPts+isDrift)*1,1);
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arr2=DataArrayDouble::New();
- arr2->alloc((nbOfPts+isDrift)*1,1);
- double *work=std::copy(arr->begin(),arr->end(),arr2->getPointer());
- std::fill(work,work+isDrift,0.);
- INTERP_KERNEL::matrixProduct(matrixInv->getConstPointer(),nbOfPts+isDrift,nbOfPts+isDrift,arr2->getConstPointer(),nbOfPts+isDrift,1,KnewiK->getPointer());
+ int nbRows(-1);
+ MCAuto<DataArrayDouble> matrixInv(computeInverseMatrix(mesh,isDrift,nbRows));
+ MCAuto<DataArrayDouble> KnewiK(DataArrayDouble::New());
+ KnewiK->alloc(nbRows*1,1);
+ MCAuto<DataArrayDouble> arr2(PerformDriftOfVec(arr,isDrift));
+ INTERP_KERNEL::matrixProduct(matrixInv->getConstPointer(),nbRows,nbRows,arr2->getConstPointer(),arr2->getNumberOfTuples(),1,KnewiK->getPointer());
return KnewiK.retn();
}
void MEDCouplingFieldDiscretizationKriging::operateOnDenseMatrix(int spaceDimension, int nbOfElems, double *matrixPtr) const
{
switch(spaceDimension)
- {
+ {
case 1:
{
- for(int i=0;i<nbOfElems;i++)
- {
- double val=matrixPtr[i];
- matrixPtr[i]=val*val*val;
- }
+ OperateOnDenseMatrixH3(nbOfElems,matrixPtr);
+ break;
+ }
+ case 2:
+ {
+ OperateOnDenseMatrixH2Ln(nbOfElems,matrixPtr);
+ break;
+ }
+ case 3:
+ {
+ //nothing here : it is not a bug g(h)=h with spaceDim 3.
break;
}
default:
- throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::operateOnDenseMatrix : only dimension 1 implemented !");
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::operateOnDenseMatrix : only dimension 1, 2 and 3 implemented !");
+ }
+}
+
+void MEDCouplingFieldDiscretizationKriging::OperateOnDenseMatrixH3(int nbOfElems, double *matrixPtr)
+{
+ for(int i=0;i<nbOfElems;i++)
+ {
+ double val=matrixPtr[i];
+ matrixPtr[i]=val*val*val;
+ }
+}
+
+void MEDCouplingFieldDiscretizationKriging::OperateOnDenseMatrixH2Ln(int nbOfElems, double *matrixPtr)
+{
+ for(int i=0;i<nbOfElems;i++)
+ {
+ double val=matrixPtr[i];
+ if(val!=0.)
+ matrixPtr[i]=val*val*log(val);
}
}
+/*!
+ * Performs a drift to the rectangular input matrix \a matr.
+ * This method generate a dense matrix starting from an input dense matrix \a matr and input array \a arr.
+ * \param [in] matr The rectangular dense matrix (with only one component). The number of rows of \a matr must be equal to the number of tuples of \a arr
+ * \param [in] arr The array of coords to be appended in the input dense matrix \a matr. Typically arr is an array of coordinates.
+ * \param [out] delta the delta of number of columns between returned dense matrix and input dense matrix \a matr. \a delta is equal to number of components of \a arr + 1.
+ * \sa performDrift
+ */
+DataArrayDouble *MEDCouplingFieldDiscretizationKriging::PerformDriftRect(const DataArrayDouble *matr, const DataArrayDouble *arr, int& delta)
+{
+ if(!matr || !matr->isAllocated() || matr->getNumberOfComponents()!=1)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::PerformDriftRect : invalid input dense matrix ! Must be allocated not NULL and with exactly one component !");
+ if(!arr || !arr->isAllocated())
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::PerformDriftRect : invalid input array of coordiantes ! Must be allocated and not NULL !");
+ int spaceDimension(arr->getNumberOfComponents()),nbOfPts(arr->getNumberOfTuples()),nbOfEltInMatrx(matr->getNumberOfTuples());
+ delta=spaceDimension+1;
+ int nbOfCols(nbOfEltInMatrx/nbOfPts);
+ if(nbOfEltInMatrx%nbOfPts!=0)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::PerformDriftRect : size of input dense matrix and input arrays mismatch ! NbOfElems in matrix % nb of tuples in array must be equal to 0 !");
+ MCAuto<DataArrayDouble> ret(DataArrayDouble::New()); ret->alloc(nbOfPts*(nbOfCols+delta));
+ double *retPtr(ret->getPointer());
+ const double *mPtr(matr->begin()),*aPtr(arr->begin());
+ for(int i=0;i<nbOfPts;i++,aPtr+=spaceDimension,mPtr+=nbOfCols)
+ {
+ retPtr=std::copy(mPtr,mPtr+nbOfCols,retPtr);
+ *retPtr++=1.;
+ retPtr=std::copy(aPtr,aPtr+spaceDimension,retPtr);
+ }
+ return ret.retn();
+}
+
+/*!
+ * \return a newly allocated array having \a isDrift more tuples than \a arr.
+ * \sa computeVectorOfCoefficients
+ */
+DataArrayDouble *MEDCouplingFieldDiscretizationKriging::PerformDriftOfVec(const DataArrayDouble *arr, int isDrift)
+{
+ if(!arr || !arr->isAllocated() || arr->getNumberOfComponents()!=1)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::PerformDriftOfVec : input array must be not NULL allocated and with one component !");
+ if(isDrift<0)
+ throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::PerformDriftOfVec : isDrift parameter must be >=0 !");
+ MCAuto<DataArrayDouble> arr2(DataArrayDouble::New());
+ arr2->alloc((arr->getNumberOfTuples()+isDrift)*1,1);
+ double *work(std::copy(arr->begin(),arr->end(),arr2->getPointer()));
+ std::fill(work,work+isDrift,0.);
+ return arr2.retn();
+}
+
/*!
* Starting from a square matrix \a matr, this method returns a newly allocated dense square matrix whose \a matr is included in returned matrix
* in the top left corner, and in the remaining returned matrix the parameters to take into account about the kriging drift.
* \param [in] matr input matrix whose drift part will be added
* \param [out] delta the difference between the size of the output matrix and the input matrix \a matr.
* \return a newly allocated matrix bigger than input matrix \a matr.
+ * \sa MEDCouplingFieldDiscretizationKriging::PerformDriftRect
*/
DataArrayDouble *MEDCouplingFieldDiscretizationKriging::performDrift(const DataArrayDouble *matr, const DataArrayDouble *arr, int& delta) const
{
- int spaceDimension=arr->getNumberOfComponents();
+ std::size_t spaceDimension(arr->getNumberOfComponents());
delta=spaceDimension+1;
- int szOfMatrix=arr->getNumberOfTuples();
+ std::size_t szOfMatrix(arr->getNumberOfTuples());
if(szOfMatrix*szOfMatrix!=matr->getNumberOfTuples())
throw INTERP_KERNEL::Exception("MEDCouplingFieldDiscretizationKriging::performDrift : invalid size");
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> ret=DataArrayDouble::New();
+ MCAuto<DataArrayDouble> ret=DataArrayDouble::New();
ret->alloc((szOfMatrix+delta)*(szOfMatrix+delta),1);
const double *srcWork=matr->getConstPointer();
const double *srcWork2=arr->getConstPointer();
double *destWork=ret->getPointer();
- for(int i=0;i<szOfMatrix;i++)
+ for(std::size_t i=0;i<szOfMatrix;i++)
{
destWork=std::copy(srcWork,srcWork+szOfMatrix,destWork);
srcWork+=szOfMatrix;
}
std::fill(destWork,destWork+szOfMatrix,1.); destWork+=szOfMatrix;
std::fill(destWork,destWork+spaceDimension+1,0.); destWork+=spaceDimension+1;
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> arrNoI=arr->toNoInterlace();
+ MCAuto<DataArrayDouble> arrNoI=arr->toNoInterlace();
srcWork2=arrNoI->getConstPointer();
- for(int i=0;i<spaceDimension;i++)
+ for(std::size_t i=0;i<spaceDimension;i++)
{
destWork=std::copy(srcWork2,srcWork2+szOfMatrix,destWork);
srcWork2+=szOfMatrix;
std::fill(destWork,destWork+spaceDimension+1,0.);
- destWork+=spaceDimension;
+ destWork+=spaceDimension+1;
}
//
return ret.retn();