-// Copyright (C) 2007-2014 CEA/DEN, EDF R&D
+// Copyright (C) 2007-2015 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
%module MEDCoupling
+#ifdef WITH_DOCSTRINGS
+%include MEDCoupling_doc.i
+#endif
+
%include std_vector.i
%include std_string.i
#include "MEDCouplingUMesh.hxx"
#include "MEDCouplingExtrudedMesh.hxx"
#include "MEDCouplingCMesh.hxx"
+#include "MEDCouplingIMesh.hxx"
#include "MEDCouplingCurveLinearMesh.hxx"
#include "MEDCoupling1GTUMesh.hxx"
#include "MEDCouplingField.hxx"
#include "MEDCouplingFieldOverTime.hxx"
#include "MEDCouplingDefinitionTime.hxx"
#include "MEDCouplingFieldDiscretization.hxx"
+#include "MEDCouplingCartesianAMRMesh.hxx"
+#include "MEDCouplingAMRAttribute.hxx"
+#include "MEDCouplingMatrix.hxx"
+#include "MEDCouplingPartDefinition.hxx"
+#include "MEDCouplingSkyLineArray.hxx"
#include "MEDCouplingTypemaps.i"
#include "InterpKernelAutoPtr.hxx"
+#include "BoxSplittingOptions.hxx"
using namespace ParaMEDMEM;
using namespace INTERP_KERNEL;
}
//$$$$$$$$$$$$$$$$$$
+////////////////////
+%typemap(out) MEDCouplingCartesianAMRPatchGen*
+{
+ $result=convertCartesianAMRPatch($1,$owner);
+}
+//$$$$$$$$$$$$$$$$$$
+
+////////////////////
+%typemap(out) MEDCouplingCartesianAMRMeshGen*
+{
+ $result=convertCartesianAMRMesh($1,$owner);
+}
+//$$$$$$$$$$$$$$$$$$
+
+////////////////////
+%typemap(out) MEDCouplingDataForGodFather*
+{
+ $result=convertDataForGodFather($1,$owner);
+}
+//$$$$$$$$$$$$$$$$$$
////////////////////
%typemap(out) ParaMEDMEM::MEDCoupling1GTUMesh*
}
//$$$$$$$$$$$$$$$$$$
+////////////////////
+%typemap(out) ParaMEDMEM::PartDefinition*
+{
+ $result=convertPartDefinition($1,$owner);
+}
+
+%typemap(out) PartDefinition*
+{
+ $result=convertPartDefinition($1,$owner);
+}
+//$$$$$$$$$$$$$$$$$$
+
#ifdef WITH_NUMPY
%init %{ import_array(); %}
#endif
%newobject ParaMEDMEM::MEDCouplingPointSet::getCellIdsLyingOnNodes;
%newobject ParaMEDMEM::MEDCouplingPointSet::deepCpyConnectivityOnly;
%newobject ParaMEDMEM::MEDCouplingPointSet::getBoundingBoxForBBTree;
+%newobject ParaMEDMEM::MEDCouplingPointSet::computeFetchedNodeIds;
%newobject ParaMEDMEM::MEDCouplingPointSet::ComputeNbOfInteractionsWithSrcCells;
+%newobject ParaMEDMEM::MEDCouplingPointSet::computeDiameterField;
%newobject ParaMEDMEM::MEDCouplingPointSet::__getitem__;
%newobject ParaMEDMEM::MEDCouplingUMesh::New;
%newobject ParaMEDMEM::MEDCouplingUMesh::getNodalConnectivity;
%newobject ParaMEDMEM::MEDCouplingUMesh::ComputeSpreadZoneGradually;
%newobject ParaMEDMEM::MEDCouplingUMesh::ComputeSpreadZoneGraduallyFromSeed;
%newobject ParaMEDMEM::MEDCouplingUMesh::buildNewNumberingFromCommNodesFrmt;
+%newobject ParaMEDMEM::MEDCouplingUMesh::conformize2D;
+%newobject ParaMEDMEM::MEDCouplingUMesh::colinearize2D;
%newobject ParaMEDMEM::MEDCouplingUMesh::rearrange2ConsecutiveCellTypes;
%newobject ParaMEDMEM::MEDCouplingUMesh::sortCellsInMEDFileFrmt;
%newobject ParaMEDMEM::MEDCouplingUMesh::getRenumArrForMEDFileFrmt;
%newobject ParaMEDMEM::MEDCouplingUMesh::convertCellArrayPerGeoType;
-%newobject ParaMEDMEM::MEDCouplingUMesh::computeFetchedNodeIds;
%newobject ParaMEDMEM::MEDCouplingUMesh::getRenumArrForConsecutiveCellTypesSpec;
%newobject ParaMEDMEM::MEDCouplingUMesh::buildDirectionVectorField;
%newobject ParaMEDMEM::MEDCouplingUMesh::convertLinearCellsToQuadratic;
%newobject ParaMEDMEM::MEDCouplingUMesh::ComputeRangesFromTypeDistribution;
%newobject ParaMEDMEM::MEDCouplingUMesh::buildUnionOf2DMesh;
%newobject ParaMEDMEM::MEDCouplingUMesh::buildUnionOf3DMesh;
+%newobject ParaMEDMEM::MEDCouplingUMesh::generateGraph;
+%newobject ParaMEDMEM::MEDCouplingUMesh::orderConsecutiveCells1D;
%newobject ParaMEDMEM::MEDCouplingUMesh::getBoundingBoxForBBTreeFast;
%newobject ParaMEDMEM::MEDCouplingUMesh::getBoundingBoxForBBTree2DQuadratic;
+%newobject ParaMEDMEM::MEDCouplingUMesh::getBoundingBoxForBBTree1DQuadratic;
%newobject ParaMEDMEM::MEDCouplingUMeshCellByTypeEntry::__iter__;
%newobject ParaMEDMEM::MEDCouplingUMeshCellEntry::__iter__;
%newobject ParaMEDMEM::MEDCoupling1GTUMesh::New;
%newobject ParaMEDMEM::MEDCouplingExtrudedMesh::build3DUnstructuredMesh;
%newobject ParaMEDMEM::MEDCouplingStructuredMesh::buildStructuredSubPart;
%newobject ParaMEDMEM::MEDCouplingStructuredMesh::build1SGTUnstructured;
+%newobject ParaMEDMEM::MEDCouplingStructuredMesh::build1SGTSubLevelMesh;
%newobject ParaMEDMEM::MEDCouplingStructuredMesh::BuildExplicitIdsFrom;
+%newobject ParaMEDMEM::MEDCouplingStructuredMesh::ExtractFieldOfDoubleFrom;
%newobject ParaMEDMEM::MEDCouplingStructuredMesh::Build1GTNodalConnectivity;
+%newobject ParaMEDMEM::MEDCouplingStructuredMesh::Build1GTNodalConnectivityOfSubLevelMesh;
+%newobject ParaMEDMEM::MEDCouplingStructuredMesh::ComputeCornersGhost;
%newobject ParaMEDMEM::MEDCouplingCMesh::New;
%newobject ParaMEDMEM::MEDCouplingCMesh::clone;
%newobject ParaMEDMEM::MEDCouplingCMesh::getCoordsAt;
+%newobject ParaMEDMEM::MEDCouplingIMesh::New;
+%newobject ParaMEDMEM::MEDCouplingIMesh::asSingleCell;
+%newobject ParaMEDMEM::MEDCouplingIMesh::buildWithGhost;
+%newobject ParaMEDMEM::MEDCouplingIMesh::convertToCartesian;
%newobject ParaMEDMEM::MEDCouplingCurveLinearMesh::New;
%newobject ParaMEDMEM::MEDCouplingCurveLinearMesh::clone;
%newobject ParaMEDMEM::MEDCouplingCurveLinearMesh::getCoords;
%newobject ParaMEDMEM::MEDCouplingMultiFields::New;
%newobject ParaMEDMEM::MEDCouplingMultiFields::deepCpy;
%newobject ParaMEDMEM::MEDCouplingFieldOverTime::New;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRPatchGen::getMesh;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRPatchGen::__getitem__;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::deepCpy;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::buildUnstructured;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::extractGhostFrom;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::buildMeshFromPatchEnvelop;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::buildMeshOfDirectChildrenOnly;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::getImageMesh;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::getGodFather;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::getFather;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::getPatch;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::createCellFieldOnPatch;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::findPatchesInTheNeighborhoodOf;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::getPatchAtPosition;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::getMeshAtPosition;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMeshGen::__getitem__;
+%newobject ParaMEDMEM::MEDCouplingCartesianAMRMesh::New;
+%newobject ParaMEDMEM::MEDCouplingDataForGodFather::getMyGodFather;
+%newobject ParaMEDMEM::MEDCouplingAMRAttribute::New;
+%newobject ParaMEDMEM::MEDCouplingAMRAttribute::deepCpy;
+%newobject ParaMEDMEM::MEDCouplingAMRAttribute::deepCpyWithoutGodFather;
+%newobject ParaMEDMEM::MEDCouplingAMRAttribute::getFieldOn;
+%newobject ParaMEDMEM::MEDCouplingAMRAttribute::projectTo;
+%newobject ParaMEDMEM::MEDCouplingAMRAttribute::buildCellFieldOnRecurseWithoutOverlapWithoutGhost;
+%newobject ParaMEDMEM::MEDCouplingAMRAttribute::buildCellFieldOnWithGhost;
+%newobject ParaMEDMEM::MEDCouplingAMRAttribute::buildCellFieldOnWithoutGhost;
+%newobject ParaMEDMEM::DenseMatrix::New;
+%newobject ParaMEDMEM::DenseMatrix::deepCpy;
+%newobject ParaMEDMEM::DenseMatrix::shallowCpy;
+%newobject ParaMEDMEM::DenseMatrix::getData;
+%newobject ParaMEDMEM::DenseMatrix::matVecMult;
+%newobject ParaMEDMEM::DenseMatrix::MatVecMult;
+%newobject ParaMEDMEM::DenseMatrix::__add__;
+%newobject ParaMEDMEM::DenseMatrix::__sub__;
+%newobject ParaMEDMEM::DenseMatrix::__mul__;
+%newobject ParaMEDMEM::PartDefinition::New;
+%newobject ParaMEDMEM::PartDefinition::toDAI;
+%newobject ParaMEDMEM::PartDefinition::__add__;
+%newobject ParaMEDMEM::PartDefinition::composeWith;
+%newobject ParaMEDMEM::PartDefinition::tryToSimplify;
+%newobject ParaMEDMEM::DataArrayPartDefinition::New;
+%newobject ParaMEDMEM::SlicePartDefinition::New;
%feature("unref") MEDCouplingPointSet "$this->decrRef();"
%feature("unref") MEDCouplingMesh "$this->decrRef();"
%feature("unref") MEDCoupling1DGTUMesh "$this->decrRef();"
%feature("unref") MEDCouplingExtrudedMesh "$this->decrRef();"
%feature("unref") MEDCouplingCMesh "$this->decrRef();"
+%feature("unref") MEDCouplingIMesh "$this->decrRef();"
+%feature("unref") MEDCouplingCurveLinearMesh "$this->decrRef();"
%feature("unref") MEDCouplingField "$this->decrRef();"
%feature("unref") MEDCouplingFieldDiscretizationP0 "$this->decrRef();"
%feature("unref") MEDCouplingFieldDiscretizationP1 "$this->decrRef();"
%feature("unref") MEDCouplingMultiFields "$this->decrRef();"
%feature("unref") MEDCouplingFieldTemplate "$this->decrRef();"
%feature("unref") MEDCouplingMultiFields "$this->decrRef();"
+%feature("unref") MEDCouplingCartesianAMRMeshGen "$this->decrRef();"
+%feature("unref") MEDCouplingCartesianAMRMesh "$this->decrRef();"
+%feature("unref") MEDCouplingCartesianAMRMeshSub "$this->decrRef();"
+%feature("unref") MEDCouplingCartesianAMRPatchGen "$this->decrRef();"
+%feature("unref") MEDCouplingCartesianAMRPatchGF "$this->decrRef();"
+%feature("unref") MEDCouplingCartesianAMRPatch "$this->decrRef();"
+%feature("unref") MEDCouplingDataForGodFather "$this->decrRef();"
+%feature("unref") MEDCouplingAMRAttribute "$this->decrRef();"
+%feature("unref") DenseMatrix "$this->decrRef();"
+%feature("unref") PartDefinition "$this->decrRef();"
+%feature("unref") DataArrayPartDefinition "$this->decrRef();"
+%feature("unref") SlicePartDefinition "$this->decrRef();"
%rename(assign) *::operator=;
%ignore ParaMEDMEM::MEDCouplingGaussLocalization::pushTinySerializationIntInfo;
%include "MEDCouplingRefCountObject.i"
%include "MEDCouplingMemArray.i"
+namespace INTERP_KERNEL
+{
+ /*!
+ * \class BoxSplittingOptions
+ * Class defining the options for box splitting used for AMR algorithm like creation of patches following a criterion.
+ */
+ class BoxSplittingOptions
+ {
+ public:
+ BoxSplittingOptions();
+ void init() throw(INTERP_KERNEL::Exception);
+ double getEfficiencyGoal() const throw(INTERP_KERNEL::Exception);
+ void setEfficiencyGoal(double efficiency) throw(INTERP_KERNEL::Exception);
+ double getEfficiencyThreshold() const throw(INTERP_KERNEL::Exception);
+ void setEfficiencyThreshold(double efficiencyThreshold) throw(INTERP_KERNEL::Exception);
+ int getMinimumPatchLength() const throw(INTERP_KERNEL::Exception);
+ void setMinimumPatchLength(int minPatchLength) throw(INTERP_KERNEL::Exception);
+ int getMaximumPatchLength() const throw(INTERP_KERNEL::Exception);
+ void setMaximumPatchLength(int maxPatchLength) throw(INTERP_KERNEL::Exception);
+ int getMaximumNbOfCellsInPatch() const throw(INTERP_KERNEL::Exception);
+ void setMaximumNbOfCellsInPatch(int maxNbCellsInPatch) throw(INTERP_KERNEL::Exception);
+ void copyOptions(const BoxSplittingOptions & other) throw(INTERP_KERNEL::Exception);
+ std::string printOptions() const throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ std::string __str__() const throw(INTERP_KERNEL::Exception)
+ {
+ return self->printOptions();
+ }
+ }
+ };
+}
+
namespace ParaMEDMEM
{
typedef enum
EXTRUDED = 8,
CURVE_LINEAR = 9,
SINGLE_STATIC_GEO_TYPE_UNSTRUCTURED = 10,
- SINGLE_DYNAMIC_GEO_TYPE_UNSTRUCTURED = 11
+ SINGLE_DYNAMIC_GEO_TYPE_UNSTRUCTURED = 11,
+ IMAGE_GRID = 12
} MEDCouplingMeshType;
class DataArrayInt;
virtual INTERP_KERNEL::NormalizedCellType getTypeOfCell(int cellId) const throw(INTERP_KERNEL::Exception);
virtual std::string simpleRepr() const throw(INTERP_KERNEL::Exception);
virtual std::string advancedRepr() const throw(INTERP_KERNEL::Exception);
- void writeVTK(const std::string& fileName, bool isBinary=true) const throw(INTERP_KERNEL::Exception);
+ std::string writeVTK(const std::string& fileName, bool isBinary=true) const throw(INTERP_KERNEL::Exception);
+ virtual std::string getVTKFileExtension() const;
+ std::string getVTKFileNameOf(const std::string& fileName) const;
// tools
virtual MEDCouplingFieldDouble *getMeasureField(bool isAbs) const throw(INTERP_KERNEL::Exception);
virtual MEDCouplingFieldDouble *getMeasureFieldOnNode(bool isAbs) const throw(INTERP_KERNEL::Exception);
virtual MEDCouplingMesh *mergeMyselfWith(const MEDCouplingMesh *other) const throw(INTERP_KERNEL::Exception);
virtual bool areCompatibleForMerge(const MEDCouplingMesh *other) const throw(INTERP_KERNEL::Exception);
virtual DataArrayInt *simplexize(int policy) throw(INTERP_KERNEL::Exception);
+ virtual void unserialization(const std::vector<double>& tinyInfoD, const std::vector<int>& tinyInfo, const DataArrayInt *a1, DataArrayDouble *a2, const std::vector<std::string>& littleStrings) throw(INTERP_KERNEL::Exception);
static MEDCouplingMesh *MergeMeshes(const MEDCouplingMesh *mesh1, const MEDCouplingMesh *mesh2) throw(INTERP_KERNEL::Exception);
static bool IsStaticGeometricType(INTERP_KERNEL::NormalizedCellType type) throw(INTERP_KERNEL::Exception);
static bool IsLinearGeometricType(INTERP_KERNEL::NormalizedCellType type) throw(INTERP_KERNEL::Exception);
PyList_SetItem(res,2,SWIG_From_int(tmp2));
return res;
}
-
+
int getCellContainingPoint(PyObject *p, double eps) const throw(INTERP_KERNEL::Exception)
{
double val;
PyList_SetItem(res,i,PyInt_FromLong(*iL));
return res;
}
+
+ virtual PyObject *getTinySerializationInformation() const throw(INTERP_KERNEL::Exception)
+ {
+ std::vector<double> a0;
+ std::vector<int> a1;
+ std::vector<std::string> a2;
+ self->getTinySerializationInformation(a0,a1,a2);
+ PyObject *ret(PyTuple_New(3));
+ PyTuple_SetItem(ret,0,convertDblArrToPyList2(a0));
+ PyTuple_SetItem(ret,1,convertIntArrToPyList2(a1));
+ int sz(a2.size());
+ PyObject *ret2(PyList_New(sz));
+ {
+ for(int i=0;i<sz;i++)
+ PyList_SetItem(ret2,i,PyString_FromString(a2[i].c_str()));
+ }
+ PyTuple_SetItem(ret,2,ret2);
+ return ret;
+ }
+
+ virtual PyObject *serialize() const throw(INTERP_KERNEL::Exception)
+ {
+ DataArrayInt *a0Tmp(0);
+ DataArrayDouble *a1Tmp(0);
+ self->serialize(a0Tmp,a1Tmp);
+ PyObject *ret(PyTuple_New(2));
+ PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(a0Tmp),SWIGTYPE_p_ParaMEDMEM__DataArrayInt, SWIG_POINTER_OWN | 0 ));
+ PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(a1Tmp),SWIGTYPE_p_ParaMEDMEM__DataArrayDouble, SWIG_POINTER_OWN | 0 ));
+ return ret;
+ }
+
+ void resizeForUnserialization(const std::vector<int>& tinyInfo, DataArrayInt *a1, DataArrayDouble *a2) const throw(INTERP_KERNEL::Exception)
+ {
+ std::vector<std::string> littleStrings;
+ self->resizeForUnserialization(tinyInfo,a1,a2,littleStrings);
+ }
+
+ PyObject *__getnewargs__() throw(INTERP_KERNEL::Exception)
+ {// put an empty dict in input to say to __new__ to call __init__...
+ PyObject *ret(PyTuple_New(1));
+ PyObject *ret0(PyDict_New());
+ PyTuple_SetItem(ret,0,ret0);
+ return ret;
+ }
+
+ PyObject *__getstate__() const throw(INTERP_KERNEL::Exception)
+ {
+ PyObject *ret0(ParaMEDMEM_MEDCouplingMesh_getTinySerializationInformation(self));
+ PyObject *ret1(ParaMEDMEM_MEDCouplingMesh_serialize(self));
+ PyObject *ret(PyTuple_New(2));
+ PyTuple_SetItem(ret,0,ret0);
+ PyTuple_SetItem(ret,1,ret1);
+ return ret;
+ }
+
+ void __setstate__(PyObject *inp) throw(INTERP_KERNEL::Exception)
+ {
+ static const char MSG[]="MEDCouplingMesh.__setstate__ : expected input is a tuple of size 2 !";
+ if(!PyTuple_Check(inp))
+ throw INTERP_KERNEL::Exception(MSG);
+ int sz(PyTuple_Size(inp));
+ if(sz!=2)
+ throw INTERP_KERNEL::Exception(MSG);
+ PyObject *elt0(PyTuple_GetItem(inp,0));
+ PyObject *elt1(PyTuple_GetItem(inp,1));
+ std::vector<double> a0;
+ std::vector<int> a1;
+ std::vector<std::string> a2;
+ DataArrayInt *b0(0);
+ DataArrayDouble *b1(0);
+ {
+ if(!PyTuple_Check(elt0) && PyTuple_Size(elt0)!=3)
+ throw INTERP_KERNEL::Exception(MSG);
+ PyObject *a0py(PyTuple_GetItem(elt0,0)),*a1py(PyTuple_GetItem(elt0,1)),*a2py(PyTuple_GetItem(elt0,2));
+ int tmp(-1);
+ fillArrayWithPyListDbl3(a0py,tmp,a0);
+ convertPyToNewIntArr3(a1py,a1);
+ fillStringVector(a2py,a2);
+ }
+ {
+ if(!PyTuple_Check(elt1) && PyTuple_Size(elt1)!=2)
+ throw INTERP_KERNEL::Exception(MSG);
+ PyObject *b0py(PyTuple_GetItem(elt1,0)),*b1py(PyTuple_GetItem(elt1,1));
+ void *argp(0);
+ int status(SWIG_ConvertPtr(b0py,&argp,SWIGTYPE_p_ParaMEDMEM__DataArrayInt,0|0));
+ if(!SWIG_IsOK(status))
+ throw INTERP_KERNEL::Exception(MSG);
+ b0=reinterpret_cast<DataArrayInt *>(argp);
+ status=SWIG_ConvertPtr(b1py,&argp,SWIGTYPE_p_ParaMEDMEM__DataArrayDouble,0|0);
+ if(!SWIG_IsOK(status))
+ throw INTERP_KERNEL::Exception(MSG);
+ b1=reinterpret_cast<DataArrayDouble *>(argp);
+ }
+ // useless here to call resizeForUnserialization because arrays are well resized.
+ self->unserialization(a0,a1,b0,b1,a2);
+ }
static MEDCouplingMesh *MergeMeshes(PyObject *li) throw(INTERP_KERNEL::Exception)
{
//
static bool AreAlmostEqual(const std::vector<double>& v1, const std::vector<double>& v2, double eps);
};
+
+ class MEDCouplingSkyLineArray
+ {
+ public:
+ MEDCouplingSkyLineArray();
+ MEDCouplingSkyLineArray( const MEDCouplingSkyLineArray &myArray );
+ MEDCouplingSkyLineArray( DataArrayInt* index, DataArrayInt* value );
+ MEDCouplingSkyLineArray( const std::vector<int>& index, const std::vector<int>& value );
+
+ void set( DataArrayInt* index, DataArrayInt* value );
+ int getNumberOf() const;
+ int getLength() const;
+ DataArrayInt* getIndexArray() const;
+ DataArrayInt* getValueArray() const;
+ %extend
+ {
+ std::string __str__() const throw(INTERP_KERNEL::Exception)
+ {
+ return self->simpleRepr();
+ }
+ }
+ };
}
%include "MEDCouplingFieldDiscretization.i"
static DataArrayDouble *MergeNodesArray(const MEDCouplingPointSet *m1, const MEDCouplingPointSet *m2) throw(INTERP_KERNEL::Exception);
static MEDCouplingPointSet *BuildInstanceFromMeshType(MEDCouplingMeshType type) throw(INTERP_KERNEL::Exception);
static DataArrayInt *ComputeNbOfInteractionsWithSrcCells(const MEDCouplingPointSet *srcMesh, const MEDCouplingPointSet *trgMesh, double eps) throw(INTERP_KERNEL::Exception);
+ virtual DataArrayInt *computeFetchedNodeIds() const throw(INTERP_KERNEL::Exception);
virtual int getNumberOfNodesInCell(int cellId) const throw(INTERP_KERNEL::Exception);
virtual MEDCouplingPointSet *buildBoundaryMesh(bool keepCoords) const throw(INTERP_KERNEL::Exception);
virtual DataArrayInt *getCellsInBoundingBox(const INTERP_KERNEL::DirectedBoundingBox& bbox, double eps) throw(INTERP_KERNEL::Exception);
virtual bool isEmptyMesh(const std::vector<int>& tinyInfo) const throw(INTERP_KERNEL::Exception);
virtual MEDCouplingPointSet *deepCpyConnectivityOnly() const throw(INTERP_KERNEL::Exception);
virtual DataArrayDouble *getBoundingBoxForBBTree(double arcDetEps=1e-12) const throw(INTERP_KERNEL::Exception);
+ virtual void renumberNodesWithOffsetInConn(int offset) throw(INTERP_KERNEL::Exception);
+ virtual bool areAllNodesFetched() const throw(INTERP_KERNEL::Exception);
+ virtual MEDCouplingFieldDouble *computeDiameterField() const throw(INTERP_KERNEL::Exception);
%extend
{
std::string __str__() const throw(INTERP_KERNEL::Exception)
std::string reprConnectivityOfThis() const throw(INTERP_KERNEL::Exception);
MEDCouplingUMesh *buildSetInstanceFromThis(int spaceDim) const throw(INTERP_KERNEL::Exception);
//tools
+ DataArrayInt *conformize2D(double eps) throw(INTERP_KERNEL::Exception);
+ DataArrayInt *colinearize2D(double eps) throw(INTERP_KERNEL::Exception);
void shiftNodeNumbersInConn(int delta) throw(INTERP_KERNEL::Exception);
std::vector<bool> getQuadraticStatus() const throw(INTERP_KERNEL::Exception);
DataArrayInt *findCellIdsOnBoundary() const throw(INTERP_KERNEL::Exception);
DataArrayInt *sortCellsInMEDFileFrmt() throw(INTERP_KERNEL::Exception);
DataArrayInt *getRenumArrForMEDFileFrmt() const throw(INTERP_KERNEL::Exception);
DataArrayInt *convertCellArrayPerGeoType(const DataArrayInt *da) const throw(INTERP_KERNEL::Exception);
- DataArrayInt *computeFetchedNodeIds() const throw(INTERP_KERNEL::Exception);
MEDCouplingUMesh *buildDescendingConnectivity(DataArrayInt *desc, DataArrayInt *descIndx, DataArrayInt *revDesc, DataArrayInt *revDescIndx) const throw(INTERP_KERNEL::Exception);
MEDCouplingUMesh *buildDescendingConnectivity2(DataArrayInt *desc, DataArrayInt *descIndx, DataArrayInt *revDesc, DataArrayInt *revDescIndx) const throw(INTERP_KERNEL::Exception);
MEDCouplingUMesh *explode3DMeshTo1D(DataArrayInt *desc, DataArrayInt *descIndx, DataArrayInt *revDesc, DataArrayInt *revDescIndx) const throw(INTERP_KERNEL::Exception);
DataArrayInt *convertNodalConnectivityToStaticGeoTypeMesh() const throw(INTERP_KERNEL::Exception);
DataArrayInt *buildUnionOf2DMesh() const throw(INTERP_KERNEL::Exception);
DataArrayInt *buildUnionOf3DMesh() const throw(INTERP_KERNEL::Exception);
+ MEDCouplingSkyLineArray *generateGraph() const throw(INTERP_KERNEL::Exception);
+ DataArrayInt *orderConsecutiveCells1D() const throw(INTERP_KERNEL::Exception);
DataArrayDouble *getBoundingBoxForBBTreeFast() const throw(INTERP_KERNEL::Exception);
DataArrayDouble *getBoundingBoxForBBTree2DQuadratic(double arcDetEps=1e-12) const throw(INTERP_KERNEL::Exception);
+ DataArrayDouble *getBoundingBoxForBBTree1DQuadratic(double arcDetEps=1e-12) const throw(INTERP_KERNEL::Exception);
+ void changeOrientationOfCells() throw(INTERP_KERNEL::Exception);
+ int split2DCells(const DataArrayInt *desc, const DataArrayInt *descI, const DataArrayInt *subNodesInSeg, const DataArrayInt *subNodesInSegI, const DataArrayInt *midOpt=0, const DataArrayInt *midOptI=0) throw(INTERP_KERNEL::Exception);
static MEDCouplingUMesh *Build0DMeshFromCoords(DataArrayDouble *da) throw(INTERP_KERNEL::Exception);
static MEDCouplingUMesh *MergeUMeshes(const MEDCouplingUMesh *mesh1, const MEDCouplingUMesh *mesh2) throw(INTERP_KERNEL::Exception);
static MEDCouplingUMesh *MergeUMeshesOnSameCoords(const MEDCouplingUMesh *mesh1, const MEDCouplingUMesh *mesh2) throw(INTERP_KERNEL::Exception);
{
return MEDCouplingUMesh::New(meshName,meshDim);
}
-
+
+ // serialization
+ static PyObject *___new___(PyObject *cls, PyObject *args) throw(INTERP_KERNEL::Exception)
+ {
+ return NewMethWrapCallInitOnlyIfEmptyDictInInput(cls,args,"MEDCouplingUMesh");
+ }
+
std::string __str__() const throw(INTERP_KERNEL::Exception)
{
return self->simpleRepr();
arrIndxIn->checkAllocated();
if(arrIndxIn->getNumberOfComponents()!=1)
throw INTERP_KERNEL::Exception("ExtractFromIndexedArrays2 (wrap) : number of components of last argument must be equal to one !");
- if(PySlice_GetIndices(sliC,arrIndxIn->getNumberOfTuples(),&strt,&stp,&step)!=0)
- throw INTERP_KERNEL::Exception("ExtractFromIndexedArrays2 (wrap) : Invalid slice regarding nb of elements !");
+ GetIndicesOfSlice(sliC,arrIndxIn->getNumberOfTuples(),&strt,&stp,&step,"ExtractFromIndexedArrays2 (wrap) : Invalid slice regarding nb of elements !");
DataArrayInt *arrOut=0,*arrIndexOut=0;
MEDCouplingUMesh::ExtractFromIndexedArrays2(strt,stp,step,arrIn,arrIndxIn,arrOut,arrIndexOut);
PyObject *ret=PyTuple_New(2);
return ret;
}
+ PyObject *computeNeighborsOfNodes() const throw(INTERP_KERNEL::Exception)
+ {
+ DataArrayInt *neighbors=0,*neighborsIdx=0;
+ self->computeNeighborsOfNodes(neighbors,neighborsIdx);
+ PyObject *ret=PyTuple_New(2);
+ PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(neighbors),SWIGTYPE_p_ParaMEDMEM__DataArrayInt, SWIG_POINTER_OWN | 0 ));
+ PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(neighborsIdx),SWIGTYPE_p_ParaMEDMEM__DataArrayInt, SWIG_POINTER_OWN | 0 ));
+ return ret;
+ }
+
static PyObject *ComputeNeighborsOfCellsAdv(const DataArrayInt *desc, const DataArrayInt *descI, const DataArrayInt *revDesc, const DataArrayInt *revDescI) throw(INTERP_KERNEL::Exception)
{
DataArrayInt *neighbors=0,*neighborsIdx=0;
return ret;
}
+ static PyObject *Intersect2DMeshWith1DLine(const MEDCouplingUMesh *mesh2D, const MEDCouplingUMesh *mesh1D, double eps) throw(INTERP_KERNEL::Exception)
+ {
+ MEDCouplingUMesh *splitMesh2D(0),*splitMesh1D(0);
+ DataArrayInt *cellIdInMesh2D(0),*cellIdInMesh1D(0);
+ MEDCouplingUMesh::Intersect2DMeshWith1DLine(mesh2D,mesh1D,eps,splitMesh2D,splitMesh1D,cellIdInMesh2D,cellIdInMesh1D);
+ PyObject *ret(PyTuple_New(4));
+ PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(splitMesh2D),SWIGTYPE_p_ParaMEDMEM__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 ));
+ PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(splitMesh1D),SWIGTYPE_p_ParaMEDMEM__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 ));
+ PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(cellIdInMesh2D),SWIGTYPE_p_ParaMEDMEM__DataArrayInt, SWIG_POINTER_OWN | 0 ));
+ PyTuple_SetItem(ret,3,SWIG_NewPointerObj(SWIG_as_voidptr(cellIdInMesh1D),SWIGTYPE_p_ParaMEDMEM__DataArrayInt, SWIG_POINTER_OWN | 0 ));
+ return ret;
+ }
+
PyObject *buildSlice3D(PyObject *origin, PyObject *vec, double eps) const throw(INTERP_KERNEL::Exception)
{
int spaceDim=self->getSpaceDimension();
{
return MEDCouplingExtrudedMesh::New(mesh3D,mesh2D,cell2DId);
}
+
+ MEDCouplingExtrudedMesh()
+ {
+ return MEDCouplingExtrudedMesh::New();
+ }
+
+ static PyObject *___new___(PyObject *cls, PyObject *args) throw(INTERP_KERNEL::Exception)
+ {
+ return NewMethWrapCallInitOnlyIfEmptyDictInInput(cls,args,"MEDCouplingExtrudedMesh");
+ }
std::string __str__() const throw(INTERP_KERNEL::Exception)
{
DataArrayInt *sortHexa8EachOther() throw(INTERP_KERNEL::Exception);
%extend
{
+ MEDCoupling1SGTUMesh()
+ {
+ return MEDCoupling1SGTUMesh::New();
+ }
+
MEDCoupling1SGTUMesh(const std::string& name, INTERP_KERNEL::NormalizedCellType type) throw(INTERP_KERNEL::Exception)
{
return MEDCoupling1SGTUMesh::New(name,type);
return MEDCoupling1SGTUMesh::New(m);
}
+ static PyObject *___new___(PyObject *cls, PyObject *args) throw(INTERP_KERNEL::Exception)
+ {
+ return NewMethWrapCallInitOnlyIfEmptyDictInInput(cls,args,"MEDCoupling1SGTUMesh");
+ }
+
std::string __str__() const throw(INTERP_KERNEL::Exception)
{
return self->simpleRepr();
return oss.str();
}
+ PyObject *structurizeMe(double eps=1e-12) const throw(INTERP_KERNEL::Exception)
+ {
+ DataArrayInt *cellPerm(0),*nodePerm(0);
+ MEDCouplingCMesh *retCpp(self->structurizeMe(cellPerm,nodePerm,eps));
+ PyObject *ret(PyTuple_New(3));
+ PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(retCpp),SWIGTYPE_p_ParaMEDMEM__MEDCouplingCMesh, SWIG_POINTER_OWN | 0 ));
+ PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(cellPerm),SWIGTYPE_p_ParaMEDMEM__DataArrayInt, SWIG_POINTER_OWN | 0 ));
+ PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(nodePerm),SWIGTYPE_p_ParaMEDMEM__DataArrayInt, SWIG_POINTER_OWN | 0 ));
+ return ret;
+ }
+
static MEDCoupling1SGTUMesh *Merge1SGTUMeshes(PyObject *li) throw(INTERP_KERNEL::Exception)
{
std::vector<const ParaMEDMEM::MEDCoupling1SGTUMesh *> tmp;
bool isPacked() const throw(INTERP_KERNEL::Exception);
%extend
{
+ MEDCoupling1DGTUMesh()
+ {
+ return MEDCoupling1DGTUMesh::New();
+ }
MEDCoupling1DGTUMesh(const std::string& name, INTERP_KERNEL::NormalizedCellType type) throw(INTERP_KERNEL::Exception)
{
return MEDCoupling1DGTUMesh::New(name,type);
return MEDCoupling1DGTUMesh::New(m);
}
+ static PyObject *___new___(PyObject *cls, PyObject *args) throw(INTERP_KERNEL::Exception)
+ {
+ return NewMethWrapCallInitOnlyIfEmptyDictInInput(cls,args,"MEDCoupling1DGTUMesh");
+ }
+
std::string __str__() const throw(INTERP_KERNEL::Exception)
{
return self->simpleRepr();
public:
int getCellIdFromPos(int i, int j, int k) const throw(INTERP_KERNEL::Exception);
int getNodeIdFromPos(int i, int j, int k) const throw(INTERP_KERNEL::Exception);
+ int getNumberOfCellsOfSubLevelMesh() const throw(INTERP_KERNEL::Exception);
+ int getSpaceDimensionOnNodeStruct() const throw(INTERP_KERNEL::Exception);
+ double computeSquareness() const throw(INTERP_KERNEL::Exception);
virtual std::vector<int> getNodeGridStructure() const throw(INTERP_KERNEL::Exception);
std::vector<int> getCellGridStructure() const throw(INTERP_KERNEL::Exception);
MEDCoupling1SGTUMesh *build1SGTUnstructured() const throw(INTERP_KERNEL::Exception);
+ std::vector<int> getLocationFromCellId(int cellId) const throw(INTERP_KERNEL::Exception);
+ std::vector<int> getLocationFromNodeId(int cellId) const throw(INTERP_KERNEL::Exception);
static INTERP_KERNEL::NormalizedCellType GetGeoTypeGivenMeshDimension(int meshDim) throw(INTERP_KERNEL::Exception);
+ MEDCoupling1SGTUMesh *build1SGTSubLevelMesh() const throw(INTERP_KERNEL::Exception);
+ static int DeduceNumberOfGivenStructure(const std::vector<int>& st) throw(INTERP_KERNEL::Exception);
+ static DataArrayInt *ComputeCornersGhost(const std::vector<int>& st, int ghostLev) throw(INTERP_KERNEL::Exception);
+ static std::vector<int> GetSplitVectFromStruct(const std::vector<int>& strct) throw(INTERP_KERNEL::Exception);
%extend
{
virtual MEDCouplingStructuredMesh *buildStructuredSubPart(PyObject *cellPart) const throw(INTERP_KERNEL::Exception)
static DataArrayInt *BuildExplicitIdsFrom(PyObject *st, PyObject *part) throw(INTERP_KERNEL::Exception)
{
- int tmpp1=-1,tmpp2=-1;
- std::vector<int> tmp=fillArrayWithPyListInt2(part,tmpp1,tmpp2);
std::vector< std::pair<int,int> > inp;
- if(tmpp2==2)
- {
- inp.resize(tmpp1);
- for(int i=0;i<tmpp1;i++)
- { inp[i].first=tmp[2*i]; inp[i].second=tmp[2*i+1]; }
- }
- else if(tmpp2==1)
- {
- if(tmpp1%2!=0)
- throw INTERP_KERNEL::Exception("Wrap of MEDCouplingStructuredMesh.BuildExplicitIdsFrom : invalid input size ! Must be even size !");
- inp.resize(tmpp1/2);
- for(int i=0;i<tmpp1/2;i++)
- { inp[i].first=tmp[2*i]; inp[i].second=tmp[2*i+1]; }
- }
- else
- throw INTERP_KERNEL::Exception("Wrap of MEDCouplingStructuredMesh.BuildExplicitIdsFrom : invalid input size !");
+ convertPyToVectorPairInt(part,inp);
//
int szArr,sw,iTypppArr;
std::vector<int> stdvecTyyppArr;
return MEDCouplingStructuredMesh::BuildExplicitIdsFrom(tmp5,inp);
}
+ static void MultiplyPartOf(const std::vector<int>& st, PyObject *part, double factor, DataArrayDouble *da) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(part,inp);
+ MEDCouplingStructuredMesh::MultiplyPartOf(st,inp,factor,da);
+ }
+
+ static void MultiplyPartOfByGhost(const std::vector<int>& st, PyObject *part, int ghostSize, double factor, DataArrayDouble *da) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(part,inp);
+ MEDCouplingStructuredMesh::MultiplyPartOfByGhost(st,inp,ghostSize,factor,da);
+ }
+
+ static PyObject *PutInGhostFormat(int ghostSize, const std::vector<int>& st, PyObject *part) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(part,inp);
+ std::vector<int> stWithGhost;
+ std::vector< std::pair<int,int> > partWithGhost;
+ MEDCouplingStructuredMesh::PutInGhostFormat(ghostSize,st,inp,stWithGhost,partWithGhost);
+ PyObject *ret(PyTuple_New(2));
+ PyTuple_SetItem(ret,0,convertIntArrToPyList2(stWithGhost));
+ PyTuple_SetItem(ret,1,convertFromVectorPairInt(partWithGhost));
+ return ret;
+ }
+
+ static DataArrayDouble *ExtractFieldOfDoubleFrom(const std::vector<int>& st, const DataArrayDouble *fieldOfDbl, PyObject *partCompactFormat) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(partCompactFormat,inp);
+ return MEDCouplingStructuredMesh::ExtractFieldOfDoubleFrom(st,fieldOfDbl,inp);
+ }
+
+ static void AssignPartOfFieldOfDoubleUsing(const std::vector<int>& st, DataArrayDouble *fieldOfDbl, PyObject *partCompactFormat, const DataArrayDouble *other) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(partCompactFormat,inp);
+ MEDCouplingStructuredMesh::AssignPartOfFieldOfDoubleUsing(st,fieldOfDbl,inp,other);
+ }
+
+ static int DeduceNumberOfGivenRangeInCompactFrmt(PyObject *part) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(part,inp);
+ return MEDCouplingStructuredMesh::DeduceNumberOfGivenRangeInCompactFrmt(inp);
+ }
+
static DataArrayInt *Build1GTNodalConnectivity(PyObject *li) throw(INTERP_KERNEL::Exception)
{
int szArr,sw,iTypppArr;
return MEDCouplingStructuredMesh::Build1GTNodalConnectivity(tmp,tmp+szArr);
}
+ static DataArrayInt *Build1GTNodalConnectivityOfSubLevelMesh(PyObject *li) throw(INTERP_KERNEL::Exception)
+ {
+ int szArr,sw,iTypppArr;
+ std::vector<int> stdvecTyyppArr;
+ const int *tmp(convertObjToPossibleCpp1_Safe(li,sw,szArr,iTypppArr,stdvecTyyppArr));
+ return MEDCouplingStructuredMesh::Build1GTNodalConnectivityOfSubLevelMesh(tmp,tmp+szArr);
+ }
+
+ static std::vector<int> GetDimensionsFromCompactFrmt(PyObject *partCompactFormat) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(partCompactFormat,inp);
+ return MEDCouplingStructuredMesh::GetDimensionsFromCompactFrmt(inp);
+ }
+
+ static PyObject *GetCompactFrmtFromDimensions(const std::vector<int>& dims) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > ret(MEDCouplingStructuredMesh::GetCompactFrmtFromDimensions(dims));
+ PyObject *retPy=PyList_New(ret.size());
+ for(std::size_t i=0;i<ret.size();i++)
+ {
+ PyObject *tmp=PyTuple_New(2);
+ PyTuple_SetItem(tmp,0,PyInt_FromLong(ret[i].first));
+ PyTuple_SetItem(tmp,1,PyInt_FromLong(ret[i].second));
+ PyList_SetItem(retPy,i,tmp);
+ }
+ return retPy;
+ }
+
+ static PyObject *IntersectRanges(PyObject *r1, PyObject *r2) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > r1Cpp,r2Cpp;
+ convertPyToVectorPairInt(r1,r1Cpp);
+ convertPyToVectorPairInt(r2,r2Cpp);
+ std::vector< std::pair<int,int> > ret(MEDCouplingStructuredMesh::IntersectRanges(r1Cpp,r2Cpp));
+ PyObject *retPy=PyList_New(ret.size());
+ for(std::size_t i=0;i<ret.size();i++)
+ {
+ PyObject *tmp=PyTuple_New(2);
+ PyTuple_SetItem(tmp,0,PyInt_FromLong(ret[i].first));
+ PyTuple_SetItem(tmp,1,PyInt_FromLong(ret[i].second));
+ PyList_SetItem(retPy,i,tmp);
+ }
+ return retPy;
+ }
+
+ static bool AreRangesIntersect(PyObject *r1, PyObject *r2)
+ {
+ std::vector< std::pair<int,int> > r1Cpp,r2Cpp;
+ convertPyToVectorPairInt(r1,r1Cpp);
+ convertPyToVectorPairInt(r2,r2Cpp);
+ return MEDCouplingStructuredMesh::AreRangesIntersect(r1Cpp,r2Cpp);
+ }
+
static PyObject *IsPartStructured(PyObject *li, PyObject *st) throw(INTERP_KERNEL::Exception)
{
int szArr,sw,iTypppArr;
PyTuple_SetItem(ret,1,ret1Py);
return ret;
}
+
+ static PyObject *ChangeReferenceFromGlobalOfCompactFrmt(PyObject *bigInAbs, PyObject *partOfBigInAbs, bool check=true) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > param0,param1,ret;
+ convertPyToVectorPairInt(bigInAbs,param0);
+ convertPyToVectorPairInt(partOfBigInAbs,param1);
+ MEDCouplingStructuredMesh::ChangeReferenceFromGlobalOfCompactFrmt(param0,param1,ret,check);
+ PyObject *retPy(PyList_New(ret.size()));
+ for(std::size_t i=0;i<ret.size();i++)
+ {
+ PyObject *tmp(PyTuple_New(2));
+ PyTuple_SetItem(tmp,0,PyInt_FromLong(ret[i].first));
+ PyTuple_SetItem(tmp,1,PyInt_FromLong(ret[i].second));
+ PyList_SetItem(retPy,i,tmp);
+ }
+ return retPy;
+ }
+
+ static PyObject *TranslateCompactFrmt(PyObject *part, const std::vector<int>& translation) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > param0;
+ convertPyToVectorPairInt(part,param0);
+ std::vector< std::pair<int,int> > ret(MEDCouplingStructuredMesh::TranslateCompactFrmt(param0,translation));
+ PyObject *retPy(PyList_New(ret.size()));
+ for(std::size_t i=0;i<ret.size();i++)
+ {
+ PyObject *tmp(PyTuple_New(2));
+ PyTuple_SetItem(tmp,0,PyInt_FromLong(ret[i].first));
+ PyTuple_SetItem(tmp,1,PyInt_FromLong(ret[i].second));
+ PyList_SetItem(retPy,i,tmp);
+ }
+ return retPy;
+ }
+
+ static std::vector<int> FindTranslationFrom(PyObject *startingFrom, PyObject *goingTo) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > param0,param1;
+ convertPyToVectorPairInt(startingFrom,param0);
+ convertPyToVectorPairInt(goingTo,param1);
+ return MEDCouplingStructuredMesh::FindTranslationFrom(param0,param1);
+ }
+
+ static PyObject *ChangeReferenceToGlobalOfCompactFrmt(PyObject *bigInAbs, PyObject *partOfBigRelativeToBig, bool check=true) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > param0,param1,ret;
+ convertPyToVectorPairInt(bigInAbs,param0);
+ convertPyToVectorPairInt(partOfBigRelativeToBig,param1);
+ MEDCouplingStructuredMesh::ChangeReferenceToGlobalOfCompactFrmt(param0,param1,ret,check);
+ PyObject *retPy(PyList_New(ret.size()));
+ for(std::size_t i=0;i<ret.size();i++)
+ {
+ PyObject *tmp(PyTuple_New(2));
+ PyTuple_SetItem(tmp,0,PyInt_FromLong(ret[i].first));
+ PyTuple_SetItem(tmp,1,PyInt_FromLong(ret[i].second));
+ PyList_SetItem(retPy,i,tmp);
+ }
+ return retPy;
+ }
}
};
class MEDCouplingCMesh : public ParaMEDMEM::MEDCouplingStructuredMesh
{
public:
- static MEDCouplingCMesh *New();
- static MEDCouplingCMesh *New(const std::string& meshName);
+ static MEDCouplingCMesh *New() throw(INTERP_KERNEL::Exception);
+ static MEDCouplingCMesh *New(const std::string& meshName) throw(INTERP_KERNEL::Exception);
MEDCouplingCMesh *clone(bool recDeepCpy) const;
void setCoords(const DataArrayDouble *coordsX,
const DataArrayDouble *coordsY=0,
const DataArrayDouble *coordsZ=0) throw(INTERP_KERNEL::Exception);
void setCoordsAt(int i, const DataArrayDouble *arr) throw(INTERP_KERNEL::Exception);
%extend {
- MEDCouplingCMesh()
+ MEDCouplingCMesh() throw(INTERP_KERNEL::Exception)
{
return MEDCouplingCMesh::New();
}
- MEDCouplingCMesh(const std::string& meshName)
+ MEDCouplingCMesh(const std::string& meshName) throw(INTERP_KERNEL::Exception)
{
return MEDCouplingCMesh::New(meshName);
}
+ // serialization
+ static PyObject *___new___(PyObject *cls, PyObject *args) throw(INTERP_KERNEL::Exception)
+ {
+ return NewMethWrapCallInitOnlyIfEmptyDictInInput(cls,args,"MEDCouplingCMesh");
+ }
std::string __str__() const throw(INTERP_KERNEL::Exception)
{
return self->simpleRepr();
class MEDCouplingCurveLinearMesh : public ParaMEDMEM::MEDCouplingStructuredMesh
{
public:
- static MEDCouplingCurveLinearMesh *New();
- static MEDCouplingCurveLinearMesh *New(const std::string& meshName);
+ static MEDCouplingCurveLinearMesh *New() throw(INTERP_KERNEL::Exception);
+ static MEDCouplingCurveLinearMesh *New(const std::string& meshName) throw(INTERP_KERNEL::Exception);
MEDCouplingCurveLinearMesh *clone(bool recDeepCpy) const;
void setCoords(const DataArrayDouble *coords) throw(INTERP_KERNEL::Exception);
%extend {
- MEDCouplingCurveLinearMesh()
+ MEDCouplingCurveLinearMesh() throw(INTERP_KERNEL::Exception)
{
return MEDCouplingCurveLinearMesh::New();
}
- MEDCouplingCurveLinearMesh(const std::string& meshName)
+ MEDCouplingCurveLinearMesh(const std::string& meshName) throw(INTERP_KERNEL::Exception)
{
return MEDCouplingCurveLinearMesh::New(meshName);
}
+ static PyObject *___new___(PyObject *cls, PyObject *args) throw(INTERP_KERNEL::Exception)
+ {
+ return NewMethWrapCallInitOnlyIfEmptyDictInInput(cls,args,"MEDCouplingCurveLinearMesh");
+ }
std::string __str__() const throw(INTERP_KERNEL::Exception)
{
return self->simpleRepr();
};
//== MEDCouplingCurveLinearMesh End
-}
-namespace ParaMEDMEM
-{
- class MEDCouplingField : public ParaMEDMEM::RefCountObject, public ParaMEDMEM::TimeLabel
+ //== MEDCouplingIMesh
+
+ class MEDCouplingIMesh : public ParaMEDMEM::MEDCouplingStructuredMesh
{
public:
- virtual void checkCoherency() const throw(INTERP_KERNEL::Exception);
- virtual bool areCompatibleForMerge(const MEDCouplingField *other) const throw(INTERP_KERNEL::Exception);
- virtual bool isEqual(const MEDCouplingField *other, double meshPrec, double valsPrec) const throw(INTERP_KERNEL::Exception);
- virtual bool isEqualWithoutConsideringStr(const MEDCouplingField *other, double meshPrec, double valsPrec) const throw(INTERP_KERNEL::Exception);
- virtual void copyTinyStringsFrom(const MEDCouplingField *other) throw(INTERP_KERNEL::Exception);
- void setMesh(const ParaMEDMEM::MEDCouplingMesh *mesh) throw(INTERP_KERNEL::Exception);
- void setName(const char *name) throw(INTERP_KERNEL::Exception);
- std::string getDescription() const throw(INTERP_KERNEL::Exception);
- void setDescription(const char *desc) throw(INTERP_KERNEL::Exception);
- std::string getName() const throw(INTERP_KERNEL::Exception);
- TypeOfField getTypeOfField() const throw(INTERP_KERNEL::Exception);
- NatureOfField getNature() const throw(INTERP_KERNEL::Exception);
- virtual void setNature(NatureOfField nat) throw(INTERP_KERNEL::Exception);
- DataArrayDouble *getLocalizationOfDiscr() const throw(INTERP_KERNEL::Exception);
- MEDCouplingFieldDouble *buildMeasureField(bool isAbs) const throw(INTERP_KERNEL::Exception);
- int getNumberOfTuplesExpected() const throw(INTERP_KERNEL::Exception);
- int getNumberOfMeshPlacesExpected() const throw(INTERP_KERNEL::Exception);
- void setGaussLocalizationOnType(INTERP_KERNEL::NormalizedCellType type, const std::vector<double>& refCoo,
- const std::vector<double>& gsCoo, const std::vector<double>& wg) throw(INTERP_KERNEL::Exception);
- void clearGaussLocalizations() throw(INTERP_KERNEL::Exception);
- MEDCouplingGaussLocalization& getGaussLocalization(int locId) throw(INTERP_KERNEL::Exception);
- int getNbOfGaussLocalization() const throw(INTERP_KERNEL::Exception);
- int getGaussLocalizationIdOfOneCell(int cellId) const throw(INTERP_KERNEL::Exception);
- const MEDCouplingGaussLocalization& getGaussLocalization(int locId) const throw(INTERP_KERNEL::Exception);
- int getGaussLocalizationIdOfOneType(INTERP_KERNEL::NormalizedCellType type) const throw(INTERP_KERNEL::Exception);
- void setDiscretization(MEDCouplingFieldDiscretization *newDisc);
- %extend {
- PyObject *getMesh() const throw(INTERP_KERNEL::Exception)
+ static MEDCouplingIMesh *New() throw(INTERP_KERNEL::Exception);
+ //
+ void setSpaceDimension(int spaceDim) throw(INTERP_KERNEL::Exception);
+ std::vector<int> getNodeStruct() const throw(INTERP_KERNEL::Exception);
+ std::vector<double> getOrigin() const throw(INTERP_KERNEL::Exception);
+ std::vector<double> getDXYZ() const throw(INTERP_KERNEL::Exception);
+ void setAxisUnit(const std::string& unitName) throw(INTERP_KERNEL::Exception);
+ std::string getAxisUnit() const throw(INTERP_KERNEL::Exception);
+ double getMeasureOfAnyCell() const throw(INTERP_KERNEL::Exception);
+ MEDCouplingCMesh *convertToCartesian() const throw(INTERP_KERNEL::Exception);
+ void refineWithFactor(const std::vector<int>& factors) throw(INTERP_KERNEL::Exception);
+ MEDCouplingIMesh *asSingleCell() const throw(INTERP_KERNEL::Exception);
+ MEDCouplingIMesh *buildWithGhost(int ghostLev) const throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ MEDCouplingIMesh()
{
- MEDCouplingMesh *ret1=const_cast<MEDCouplingMesh *>(self->getMesh());
- if(ret1)
- ret1->incrRef();
- return convertMesh(ret1,SWIG_POINTER_OWN | 0 );
+ return MEDCouplingIMesh::New();
+ }
+ static MEDCouplingIMesh *New(const std::string& meshName, int spaceDim, PyObject *nodeStrct, PyObject *origin, PyObject *dxyz) throw(INTERP_KERNEL::Exception)
+ {
+ static const char msg0[]="MEDCouplingIMesh::New : error on 'origin' parameter !";
+ static const char msg1[]="MEDCouplingIMesh::New : error on 'dxyz' parameter !";
+ const int *nodeStrctPtr(0);
+ const double *originPtr(0),*dxyzPtr(0);
+ int sw,sz,val0;
+ std::vector<int> bb0;
+ nodeStrctPtr=convertObjToPossibleCpp1_Safe(nodeStrct,sw,sz,val0,bb0);
+ //
+ double val,val2;
+ std::vector<double> bb,bb2;
+ int sz1,sz2;
+ originPtr=convertObjToPossibleCpp5_SingleCompo(origin,sw,val,bb,msg0,false,sz1);
+ dxyzPtr=convertObjToPossibleCpp5_SingleCompo(dxyz,sw,val2,bb2,msg1,false,sz2);
+ //
+ return MEDCouplingIMesh::New(meshName,spaceDim,nodeStrctPtr,nodeStrctPtr+sz,originPtr,originPtr+sz1,dxyzPtr,dxyzPtr+sz2);
}
- PyObject *getDiscretization() throw(INTERP_KERNEL::Exception)
+ MEDCouplingIMesh(const std::string& meshName, int spaceDim, PyObject *nodeStrct, PyObject *origin, PyObject *dxyz) throw(INTERP_KERNEL::Exception)
{
- MEDCouplingFieldDiscretization *ret=self->getDiscretization();
- if(ret)
- ret->incrRef();
- return convertFieldDiscretization(ret,SWIG_POINTER_OWN | 0 );
+ return ParaMEDMEM_MEDCouplingIMesh_New__SWIG_1(meshName,spaceDim,nodeStrct,origin,dxyz);
}
- PyObject *getGaussLocalizationIdsOfOneType(INTERP_KERNEL::NormalizedCellType type) const throw(INTERP_KERNEL::Exception)
+ static PyObject *___new___(PyObject *cls, PyObject *args) throw(INTERP_KERNEL::Exception)
{
- std::set<int> ret=self->getGaussLocalizationIdsOfOneType(type);
- return convertIntArrToPyList3(ret);
+ return NewMethWrapCallInitOnlyIfEmptyDictInInput(cls,args,"MEDCouplingIMesh");
}
- PyObject *isEqualIfNotWhy(const MEDCouplingField *other, double meshPrec, double valsPrec) const throw(INTERP_KERNEL::Exception)
+ void setNodeStruct(PyObject *nodeStrct) throw(INTERP_KERNEL::Exception)
{
- std::string ret1;
- bool ret0=self->isEqualIfNotWhy(other,meshPrec,valsPrec,ret1);
+ int sw,sz,val0;
+ std::vector<int> bb0;
+ const int *nodeStrctPtr(convertObjToPossibleCpp1_Safe(nodeStrct,sw,sz,val0,bb0));
+ self->setNodeStruct(nodeStrctPtr,nodeStrctPtr+sz);
+ }
+
+ void setOrigin(PyObject *origin) throw(INTERP_KERNEL::Exception)
+ {
+ static const char msg[]="MEDCouplingIMesh::setOrigin : invalid input 'origin' parameter ! integer, float, list/tuple of float, DataArrayDouble or DataArrayDoubleTuple supported !";
+ double val;
+ DataArrayDouble *a;
+ DataArrayDoubleTuple *aa;
+ std::vector<double> bb;
+ int sw,nbTuples;
+ const double *originPtr(convertObjToPossibleCpp5_SingleCompo(origin,sw,val,bb,msg,false,nbTuples));
+ self->setOrigin(originPtr,originPtr+nbTuples);
+ }
+
+ void setDXYZ(PyObject *dxyz) throw(INTERP_KERNEL::Exception)
+ {
+ static const char msg[]="MEDCouplingIMesh::setDXYZ : invalid input 'dxyz' parameter ! integer, float, list/tuple of float, DataArrayDouble or DataArrayDoubleTuple supported !";
+ double val;
+ DataArrayDouble *a;
+ DataArrayDoubleTuple *aa;
+ std::vector<double> bb;
+ int sw,nbTuples;
+ const double *originPtr(convertObjToPossibleCpp5_SingleCompo(dxyz,sw,val,bb,msg,false,nbTuples));
+ self->setDXYZ(originPtr,originPtr+nbTuples);
+ }
+
+ static void CondenseFineToCoarse(const std::vector<int>& coarseSt, const DataArrayDouble *fineDA, PyObject *fineLocInCoarse, const std::vector<int>& facts, DataArrayDouble *coarseDA) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(fineLocInCoarse,inp);
+ MEDCouplingIMesh::CondenseFineToCoarse(coarseSt,fineDA,inp,facts,coarseDA);
+ }
+
+ static void CondenseFineToCoarseGhost(const std::vector<int>& coarseSt, const DataArrayDouble *fineDA, PyObject *fineLocInCoarse, const std::vector<int>& facts, DataArrayDouble *coarseDA, int ghostSize) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(fineLocInCoarse,inp);
+ MEDCouplingIMesh::CondenseFineToCoarseGhost(coarseSt,fineDA,inp,facts,coarseDA,ghostSize);
+ }
+
+ static void SpreadCoarseToFine(const DataArrayDouble *coarseDA, const std::vector<int>& coarseSt, DataArrayDouble *fineDA, PyObject *fineLocInCoarse, const std::vector<int>& facts) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(fineLocInCoarse,inp);
+ MEDCouplingIMesh::SpreadCoarseToFine(coarseDA,coarseSt,fineDA,inp,facts);
+ }
+
+ static void SpreadCoarseToFineGhost(const DataArrayDouble *coarseDA, const std::vector<int>& coarseSt, DataArrayDouble *fineDA, PyObject *fineLocInCoarse, const std::vector<int>& facts, int ghostSize) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(fineLocInCoarse,inp);
+ MEDCouplingIMesh::SpreadCoarseToFineGhost(coarseDA,coarseSt,fineDA,inp,facts,ghostSize);
+ }
+
+ static void SpreadCoarseToFineGhostZone(const DataArrayDouble *coarseDA, const std::vector<int>& coarseSt, DataArrayDouble *fineDA, PyObject *fineLocInCoarse, const std::vector<int>& facts, int ghostSize) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(fineLocInCoarse,inp);
+ MEDCouplingIMesh::SpreadCoarseToFineGhostZone(coarseDA,coarseSt,fineDA,inp,facts,ghostSize);
+ }
+
+ std::string __str__() const throw(INTERP_KERNEL::Exception)
+ {
+ return self->simpleRepr();
+ }
+ std::string __repr__() const throw(INTERP_KERNEL::Exception)
+ {
+ std::ostringstream oss;
+ self->reprQuickOverview(oss);
+ return oss.str();
+ }
+ }
+ };
+
+ //== MEDCouplingIMesh End
+
+}
+
+namespace ParaMEDMEM
+{
+ class MEDCouplingField : public ParaMEDMEM::RefCountObject, public ParaMEDMEM::TimeLabel
+ {
+ public:
+ virtual void checkCoherency() const throw(INTERP_KERNEL::Exception);
+ virtual bool areCompatibleForMerge(const MEDCouplingField *other) const throw(INTERP_KERNEL::Exception);
+ virtual bool isEqual(const MEDCouplingField *other, double meshPrec, double valsPrec) const throw(INTERP_KERNEL::Exception);
+ virtual bool isEqualWithoutConsideringStr(const MEDCouplingField *other, double meshPrec, double valsPrec) const throw(INTERP_KERNEL::Exception);
+ virtual void copyTinyStringsFrom(const MEDCouplingField *other) throw(INTERP_KERNEL::Exception);
+ void setMesh(const ParaMEDMEM::MEDCouplingMesh *mesh) throw(INTERP_KERNEL::Exception);
+ void setName(const char *name) throw(INTERP_KERNEL::Exception);
+ std::string getDescription() const throw(INTERP_KERNEL::Exception);
+ void setDescription(const char *desc) throw(INTERP_KERNEL::Exception);
+ std::string getName() const throw(INTERP_KERNEL::Exception);
+ TypeOfField getTypeOfField() const throw(INTERP_KERNEL::Exception);
+ NatureOfField getNature() const throw(INTERP_KERNEL::Exception);
+ virtual void setNature(NatureOfField nat) throw(INTERP_KERNEL::Exception);
+ DataArrayDouble *getLocalizationOfDiscr() const throw(INTERP_KERNEL::Exception);
+ MEDCouplingFieldDouble *buildMeasureField(bool isAbs) const throw(INTERP_KERNEL::Exception);
+ int getNumberOfTuplesExpected() const throw(INTERP_KERNEL::Exception);
+ int getNumberOfMeshPlacesExpected() const throw(INTERP_KERNEL::Exception);
+ void setGaussLocalizationOnType(INTERP_KERNEL::NormalizedCellType type, const std::vector<double>& refCoo,
+ const std::vector<double>& gsCoo, const std::vector<double>& wg) throw(INTERP_KERNEL::Exception);
+ void clearGaussLocalizations() throw(INTERP_KERNEL::Exception);
+ MEDCouplingGaussLocalization& getGaussLocalization(int locId) throw(INTERP_KERNEL::Exception);
+ int getNbOfGaussLocalization() const throw(INTERP_KERNEL::Exception);
+ int getGaussLocalizationIdOfOneCell(int cellId) const throw(INTERP_KERNEL::Exception);
+ const MEDCouplingGaussLocalization& getGaussLocalization(int locId) const throw(INTERP_KERNEL::Exception);
+ int getGaussLocalizationIdOfOneType(INTERP_KERNEL::NormalizedCellType type) const throw(INTERP_KERNEL::Exception);
+ void setDiscretization(MEDCouplingFieldDiscretization *newDisc);
+ %extend {
+ PyObject *getMesh() const throw(INTERP_KERNEL::Exception)
+ {
+ MEDCouplingMesh *ret1=const_cast<MEDCouplingMesh *>(self->getMesh());
+ if(ret1)
+ ret1->incrRef();
+ return convertMesh(ret1,SWIG_POINTER_OWN | 0 );
+ }
+
+ PyObject *getDiscretization() throw(INTERP_KERNEL::Exception)
+ {
+ MEDCouplingFieldDiscretization *ret=self->getDiscretization();
+ if(ret)
+ ret->incrRef();
+ return convertFieldDiscretization(ret,SWIG_POINTER_OWN | 0 );
+ }
+
+ PyObject *getGaussLocalizationIdsOfOneType(INTERP_KERNEL::NormalizedCellType type) const throw(INTERP_KERNEL::Exception)
+ {
+ std::set<int> ret=self->getGaussLocalizationIdsOfOneType(type);
+ return convertIntArrToPyList3(ret);
+ }
+
+ PyObject *isEqualIfNotWhy(const MEDCouplingField *other, double meshPrec, double valsPrec) const throw(INTERP_KERNEL::Exception)
+ {
+ std::string ret1;
+ bool ret0=self->isEqualIfNotWhy(other,meshPrec,valsPrec,ret1);
PyObject *ret=PyTuple_New(2);
PyObject *ret0Py=ret0?Py_True:Py_False;
Py_XINCREF(ret0Py);
void copyAllTinyAttrFrom(const MEDCouplingFieldDouble *other) throw(INTERP_KERNEL::Exception);
std::string simpleRepr() const throw(INTERP_KERNEL::Exception);
std::string advancedRepr() const throw(INTERP_KERNEL::Exception);
- void writeVTK(const std::string& fileName, bool isBinary=true) const throw(INTERP_KERNEL::Exception);
+ std::string writeVTK(const std::string& fileName, bool isBinary=true) const throw(INTERP_KERNEL::Exception);
MEDCouplingFieldDouble *clone(bool recDeepCpy) const;
MEDCouplingFieldDouble *cloneWithMesh(bool recDeepCpy) const;
MEDCouplingFieldDouble *deepCpy() const;
void setStartTime(double val, int iteration, int order) throw(INTERP_KERNEL::Exception);
void setEndTime(double val, int iteration, int order) throw(INTERP_KERNEL::Exception);
void applyLin(double a, double b, int compoId) throw(INTERP_KERNEL::Exception);
+ void applyLin(double a, double b) throw(INTERP_KERNEL::Exception);
int getNumberOfComponents() const throw(INTERP_KERNEL::Exception);
int getNumberOfTuples() const throw(INTERP_KERNEL::Exception);
int getNumberOfValues() const throw(INTERP_KERNEL::Exception);
case 1:
{
std::vector<int> v2(1,singleVal);
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> aarr=static_cast<DataArrayDouble *>(ret0Arr->keepSelectedComponents(v2));
+ MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> aarr(ret0Arr->keepSelectedComponents(v2));
ret0->setArray(aarr);
return ret0.retn();
}
case 2:
{
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> aarr=static_cast<DataArrayDouble *>(ret0Arr->keepSelectedComponents(multiVal));
+ MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> aarr(ret0Arr->keepSelectedComponents(multiVal));
ret0->setArray(aarr);
return ret0.retn();
}
std::vector<int> v2(nbOfComp);
for(int i=0;i<nbOfComp;i++)
v2[i]=slic.first+i*slic.second.second;
- MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> aarr=static_cast<DataArrayDouble *>(ret0Arr->keepSelectedComponents(v2));
+ MEDCouplingAutoRefCountObjectPtr<DataArrayDouble> aarr(ret0Arr->keepSelectedComponents(v2));
ret0->setArray(aarr);
return ret0.retn();
}
return MEDCouplingFieldDouble::MergeFields(tmp);
}
- static void WriteVTK(const char *fileName, PyObject *li, bool isBinary=true) throw(INTERP_KERNEL::Exception)
+ static std::string WriteVTK(const char *fileName, PyObject *li, bool isBinary=true) throw(INTERP_KERNEL::Exception)
{
std::vector<const MEDCouplingFieldDouble *> tmp;
convertFromPyObjVectorOfObj<const ParaMEDMEM::MEDCouplingFieldDouble *>(li,SWIGTYPE_p_ParaMEDMEM__MEDCouplingFieldDouble,"MEDCouplingFieldDouble",tmp);
- MEDCouplingFieldDouble::WriteVTK(fileName,tmp,isBinary);
+ return MEDCouplingFieldDouble::WriteVTK(fileName,tmp,isBinary);
+ }
+
+ PyObject *getTinySerializationInformation() const throw(INTERP_KERNEL::Exception)
+ {
+ std::vector<double> a0;
+ std::vector<int> a1;
+ std::vector<std::string> a2;
+ self->getTinySerializationDbleInformation(a0);
+ self->getTinySerializationIntInformation(a1);
+ self->getTinySerializationStrInformation(a2);
+ //
+ PyObject *ret(PyTuple_New(3));
+ PyTuple_SetItem(ret,0,convertDblArrToPyList2(a0));
+ PyTuple_SetItem(ret,1,convertIntArrToPyList2(a1));
+ int sz(a2.size());
+ PyObject *ret2(PyList_New(sz));
+ {
+ for(int i=0;i<sz;i++)
+ PyList_SetItem(ret2,i,PyString_FromString(a2[i].c_str()));
+ }
+ PyTuple_SetItem(ret,2,ret2);
+ return ret;
+ }
+
+ PyObject *serialize() const throw(INTERP_KERNEL::Exception)
+ {
+ DataArrayInt *ret0(0);
+ std::vector<DataArrayDouble *> ret1;
+ self->serialize(ret0,ret1);
+ if(ret0)
+ ret0->incrRef();
+ std::size_t sz(ret1.size());
+ PyObject *ret(PyTuple_New(2));
+ PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_ParaMEDMEM__DataArrayInt, SWIG_POINTER_OWN | 0 ));
+ PyObject *ret1Py(PyList_New(sz));
+ for(std::size_t i=0;i<sz;i++)
+ {
+ if(ret1[i])
+ ret1[i]->incrRef();
+ PyList_SetItem(ret1Py,i,SWIG_NewPointerObj(SWIG_as_voidptr(ret1[i]),SWIGTYPE_p_ParaMEDMEM__DataArrayDouble, SWIG_POINTER_OWN | 0 ));
+ }
+ PyTuple_SetItem(ret,1,ret1Py);
+ return ret;
+ }
+
+ static PyObject *___new___(PyObject *cls, PyObject *args) throw(INTERP_KERNEL::Exception)
+ {
+ static const char MSG[]="MEDCouplingFieldDouble.__new__ : the args in input is expected to be a tuple !";
+ if(!PyTuple_Check(args))
+ throw INTERP_KERNEL::Exception(MSG);
+ PyObject *builtinsd(PyEval_GetBuiltins());//borrowed
+ PyObject *obj(PyDict_GetItemString(builtinsd,"object"));//borrowed
+ PyObject *selfMeth(PyObject_GetAttrString(obj,"__new__"));
+ //
+ PyObject *tmp0(PyTuple_New(1));
+ PyTuple_SetItem(tmp0,0,cls); Py_XINCREF(cls);
+ PyObject *instance(PyObject_CallObject(selfMeth,tmp0));
+ Py_DECREF(tmp0);
+ Py_DECREF(selfMeth);
+ if(PyTuple_Size(args)==2 && PyDict_Check(PyTuple_GetItem(args,1)) && PyDict_Size(PyTuple_GetItem(args,1))==1 )
+ {// NOT general case. only true if in unpickeling context ! call __init__. Because for all other cases, __init__ is called right after __new__ !
+ PyObject *initMeth(PyObject_GetAttrString(instance,"__init__"));
+ ////
+ PyObject *a(PyInt_FromLong(0));
+ PyObject *uniqueElt(PyDict_GetItem(PyTuple_GetItem(args,1),a));
+ Py_DECREF(a);
+ if(!uniqueElt)
+ throw INTERP_KERNEL::Exception(MSG);
+ if(!PyTuple_Check(uniqueElt) || PyTuple_Size(uniqueElt)!=2)
+ throw INTERP_KERNEL::Exception(MSG);
+ PyObject *tmp2(PyObject_CallObject(initMeth,uniqueElt));
+ Py_XDECREF(tmp2);
+ ////
+ Py_DECREF(initMeth);
+ }
+ return instance;
+ }
+
+ PyObject *__getnewargs__() throw(INTERP_KERNEL::Exception)
+ {// put an empty dict in input to say to __new__ to call __init__...
+ self->checkCoherency();
+ PyObject *ret(PyTuple_New(1));
+ PyObject *ret0(PyDict_New());
+ {
+ PyObject *a(PyInt_FromLong(0)),*b(PyInt_FromLong(self->getTypeOfField())),*c(PyInt_FromLong(self->getTimeDiscretization()));
+ PyObject *d(PyTuple_New(2)); PyTuple_SetItem(d,0,b); PyTuple_SetItem(d,1,c);
+ PyDict_SetItem(ret0,a,d);
+ Py_DECREF(a); Py_DECREF(d);
+ }
+ PyTuple_SetItem(ret,0,ret0);
+ return ret;
+ }
+
+ PyObject *__getstate__() const throw(INTERP_KERNEL::Exception)
+ {
+ self->checkCoherency();
+ PyObject *ret0(ParaMEDMEM_MEDCouplingFieldDouble_getTinySerializationInformation(self));
+ PyObject *ret1(ParaMEDMEM_MEDCouplingFieldDouble_serialize(self));
+ const MEDCouplingMesh *mesh(self->getMesh());
+ if(mesh)
+ mesh->incrRef();
+ PyObject *ret(PyTuple_New(3));
+ PyTuple_SetItem(ret,0,ret0);
+ PyTuple_SetItem(ret,1,ret1);
+ PyTuple_SetItem(ret,2,convertMesh(const_cast<MEDCouplingMesh *>(mesh),SWIG_POINTER_OWN | 0 ));
+ return ret;
+ }
+
+ void __setstate__(PyObject *inp) throw(INTERP_KERNEL::Exception)
+ {
+ static const char MSG[]="MEDCouplingFieldDouble.__setstate__ : expected input is a tuple of size 3 !";
+ if(!PyTuple_Check(inp))
+ throw INTERP_KERNEL::Exception(MSG);
+ int sz(PyTuple_Size(inp));
+ if(sz!=3)
+ throw INTERP_KERNEL::Exception(MSG);
+ // mesh
+ PyObject *elt2(PyTuple_GetItem(inp,2));
+ void *argp=0;
+ int status(SWIG_ConvertPtr(elt2,&argp,SWIGTYPE_p_ParaMEDMEM__MEDCouplingMesh,0|0));
+ if(!SWIG_IsOK(status))
+ throw INTERP_KERNEL::Exception(MSG);
+ self->setMesh(reinterpret_cast< const MEDCouplingUMesh * >(argp));
+ //
+ PyObject *elt0(PyTuple_GetItem(inp,0));
+ PyObject *elt1(PyTuple_GetItem(inp,1));
+ std::vector<double> a0;
+ std::vector<int> a1;
+ std::vector<std::string> a2;
+ DataArrayInt *b0(0);
+ std::vector<DataArrayDouble *>b1;
+ {
+ if(!PyTuple_Check(elt0) && PyTuple_Size(elt0)!=3)
+ throw INTERP_KERNEL::Exception(MSG);
+ PyObject *a0py(PyTuple_GetItem(elt0,0)),*a1py(PyTuple_GetItem(elt0,1)),*a2py(PyTuple_GetItem(elt0,2));
+ int tmp(-1);
+ fillArrayWithPyListDbl3(a0py,tmp,a0);
+ convertPyToNewIntArr3(a1py,a1);
+ fillStringVector(a2py,a2);
+ }
+ {
+ if(!PyTuple_Check(elt1) && PyTuple_Size(elt1)!=2)
+ throw INTERP_KERNEL::Exception(MSG);
+ PyObject *b0py(PyTuple_GetItem(elt1,0)),*b1py(PyTuple_GetItem(elt1,1));
+ void *argp(0);
+ int status(SWIG_ConvertPtr(b0py,&argp,SWIGTYPE_p_ParaMEDMEM__DataArrayInt,0|0));
+ if(!SWIG_IsOK(status))
+ throw INTERP_KERNEL::Exception(MSG);
+ b0=reinterpret_cast<DataArrayInt *>(argp);
+ convertFromPyObjVectorOfObj<ParaMEDMEM::DataArrayDouble *>(b1py,SWIGTYPE_p_ParaMEDMEM__DataArrayDouble,"DataArrayDouble",b1);
+ }
+ self->checkForUnserialization(a1,b0,b1);
+ // useless here to call resizeForUnserialization because arrays are well resized.
+ self->finishUnserialization(a1,a0,a2);
}
}
};
}
}
};
+
+ class MEDCouplingCartesianAMRMesh;
+
+ class MEDCouplingCartesianAMRPatchGen : public RefCountObject
+ {
+ public:
+ int getNumberOfCellsRecursiveWithOverlap() const throw(INTERP_KERNEL::Exception);
+ int getNumberOfCellsRecursiveWithoutOverlap() const throw(INTERP_KERNEL::Exception);
+ int getMaxNumberOfLevelsRelativeToThis() const throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ MEDCouplingCartesianAMRMeshGen *getMesh() const throw(INTERP_KERNEL::Exception)
+ {
+ MEDCouplingCartesianAMRMeshGen *ret(const_cast<MEDCouplingCartesianAMRMeshGen *>(self->getMesh()));
+ if(ret)
+ ret->incrRef();
+ return ret;
+ }
+ }
+ };
+
+ class MEDCouplingCartesianAMRPatch : public MEDCouplingCartesianAMRPatchGen
+ {
+ public:
+ int getNumberOfOverlapedCellsForFather() const throw(INTERP_KERNEL::Exception);
+ bool isInMyNeighborhood(const MEDCouplingCartesianAMRPatch *other, int ghostLev) const throw(INTERP_KERNEL::Exception);
+ std::vector<int> computeCellGridSt() const throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ PyObject *getBLTRRange() const throw(INTERP_KERNEL::Exception)
+ {
+ const std::vector< std::pair<int,int> >& ret(self->getBLTRRange());
+ return convertFromVectorPairInt(ret);
+ }
+
+ PyObject *getBLTRRangeRelativeToGF() const throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > ret(self->getBLTRRangeRelativeToGF());
+ return convertFromVectorPairInt(ret);
+ }
+
+ void addPatch(PyObject *bottomLeftTopRight, const std::vector<int>& factors) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(bottomLeftTopRight,inp);
+ self->addPatch(inp,factors);
+ }
+
+ MEDCouplingCartesianAMRPatch *__getitem__(int patchId) const throw(INTERP_KERNEL::Exception)
+ {
+ const MEDCouplingCartesianAMRMeshGen *mesh(self->getMesh());
+ if(!mesh)
+ throw INTERP_KERNEL::Exception("wrap MEDCouplingCartesianAMRPatchGen.__getitem__ : no underlying mesh !");
+ if(patchId==mesh->getNumberOfPatches())
+ {
+ std::ostringstream oss;
+ oss << "Requesting for patchId " << patchId << " having only " << mesh->getNumberOfPatches() << " patches !";
+ PyErr_SetString(PyExc_StopIteration,oss.str().c_str());
+ return 0;
+ }
+ MEDCouplingCartesianAMRPatch *ret(const_cast<MEDCouplingCartesianAMRPatch *>(mesh->getPatch(patchId)));
+ if(ret)
+ ret->incrRef();
+ return ret;
+ }
+
+ void __delitem__(int patchId) throw(INTERP_KERNEL::Exception)
+ {
+ MEDCouplingCartesianAMRMeshGen *mesh(const_cast<MEDCouplingCartesianAMRMeshGen *>(self->getMesh()));
+ if(!mesh)
+ throw INTERP_KERNEL::Exception("wrap MEDCouplingCartesianAMRPatch.__delitem__ : no underlying mesh !");
+ mesh->removePatch(patchId);
+ }
+
+ int __len__() const throw(INTERP_KERNEL::Exception)
+ {
+ const MEDCouplingCartesianAMRMeshGen *mesh(self->getMesh());
+ if(!mesh)
+ throw INTERP_KERNEL::Exception("wrap MEDCouplingCartesianAMRPatch.__len__ : no underlying mesh !");
+ return mesh->getNumberOfPatches();
+ }
+ }
+ };
+
+ class MEDCouplingCartesianAMRPatchGF : public MEDCouplingCartesianAMRPatchGen
+ {
+ };
+
+ class MEDCouplingCartesianAMRMeshGen : public RefCountObject, public TimeLabel
+ {
+ public:
+ int getAbsoluteLevel() const throw(INTERP_KERNEL::Exception);
+ int getAbsoluteLevelRelativeTo(const MEDCouplingCartesianAMRMeshGen *ref) const throw(INTERP_KERNEL::Exception);
+ std::vector<int> getPositionRelativeTo(const MEDCouplingCartesianAMRMeshGen *ref) const throw(INTERP_KERNEL::Exception);
+ int getSpaceDimension() const throw(INTERP_KERNEL::Exception);
+ const std::vector<int>& getFactors() const throw(INTERP_KERNEL::Exception);
+ void setFactors(const std::vector<int>& newFactors) throw(INTERP_KERNEL::Exception);
+ int getMaxNumberOfLevelsRelativeToThis() const throw(INTERP_KERNEL::Exception);
+ int getNumberOfCellsAtCurrentLevel() const throw(INTERP_KERNEL::Exception);
+ int getNumberOfCellsAtCurrentLevelGhost(int ghostLev) const throw(INTERP_KERNEL::Exception);
+ int getNumberOfCellsRecursiveWithOverlap() const throw(INTERP_KERNEL::Exception);
+ int getNumberOfCellsRecursiveWithoutOverlap() const throw(INTERP_KERNEL::Exception);
+ bool isPatchInNeighborhoodOf(int patchId1, int patchId2, int ghostLev) const throw(INTERP_KERNEL::Exception);
+ virtual void detachFromFather() throw(INTERP_KERNEL::Exception);
+ //
+ int getNumberOfPatches() const throw(INTERP_KERNEL::Exception);
+ int getPatchIdFromChildMesh(const MEDCouplingCartesianAMRMeshGen *mesh) const throw(INTERP_KERNEL::Exception);
+ MEDCouplingUMesh *buildUnstructured() const throw(INTERP_KERNEL::Exception);
+ DataArrayDouble *extractGhostFrom(int ghostSz, const DataArrayDouble *arr) const throw(INTERP_KERNEL::Exception);
+ std::vector<int> getPatchIdsInTheNeighborhoodOf(int patchId, int ghostLev) const throw(INTERP_KERNEL::Exception);
+ MEDCoupling1SGTUMesh *buildMeshFromPatchEnvelop() const throw(INTERP_KERNEL::Exception);
+ MEDCoupling1SGTUMesh *buildMeshOfDirectChildrenOnly() const throw(INTERP_KERNEL::Exception);
+ void removeAllPatches() throw(INTERP_KERNEL::Exception);
+ void removePatch(int patchId) throw(INTERP_KERNEL::Exception);
+ void createPatchesFromCriterion(const INTERP_KERNEL::BoxSplittingOptions& bso, const DataArrayByte *criterion, const std::vector<int>& factors) throw(INTERP_KERNEL::Exception);
+ void createPatchesFromCriterion(const INTERP_KERNEL::BoxSplittingOptions& bso, const DataArrayDouble *criterion, const std::vector<int>& factors, double eps) throw(INTERP_KERNEL::Exception);
+ DataArrayDouble *createCellFieldOnPatch(int patchId, const DataArrayDouble *cellFieldOnThis) const throw(INTERP_KERNEL::Exception);
+ void fillCellFieldOnPatch(int patchId, const DataArrayDouble *cellFieldOnThis, DataArrayDouble *cellFieldOnPatch, bool isConservative=true) const throw(INTERP_KERNEL::Exception);
+ void fillCellFieldOnPatchGhost(int patchId, const DataArrayDouble *cellFieldOnThis, DataArrayDouble *cellFieldOnPatch, int ghostLev, bool isConservative=true) const throw(INTERP_KERNEL::Exception);
+ void fillCellFieldOnPatchOnlyOnGhostZone(int patchId, const DataArrayDouble *cellFieldOnThis, DataArrayDouble *cellFieldOnPatch, int ghostLev) const throw(INTERP_KERNEL::Exception);
+ void fillCellFieldOnPatchOnlyOnGhostZoneWith(int ghostLev, const MEDCouplingCartesianAMRPatch *patchToBeModified, const MEDCouplingCartesianAMRPatch *neighborPatch, DataArrayDouble *cellFieldOnPatch, const DataArrayDouble *cellFieldNeighbor) const;
+ void fillCellFieldComingFromPatch(int patchId, const DataArrayDouble *cellFieldOnPatch, DataArrayDouble *cellFieldOnThis, bool isConservative=true) const throw(INTERP_KERNEL::Exception);
+ void fillCellFieldComingFromPatchGhost(int patchId, const DataArrayDouble *cellFieldOnPatch, DataArrayDouble *cellFieldOnThis, int ghostLev, bool isConservative=true) const throw(INTERP_KERNEL::Exception);
+ DataArrayInt *findPatchesInTheNeighborhoodOf(int patchId, int ghostLev) const throw(INTERP_KERNEL::Exception);
+ std::string buildPythonDumpOfThis() const throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ void addPatch(PyObject *bottomLeftTopRight, const std::vector<int>& factors) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<int,int> > inp;
+ convertPyToVectorPairInt(bottomLeftTopRight,inp);
+ self->addPatch(inp,factors);
+ }
+
+ PyObject *getPatches() const throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< const MEDCouplingCartesianAMRPatch *> ps(self->getPatches());
+ int sz(ps.size());
+ PyObject *ret = PyList_New(sz);
+ for(int i=0;i<sz;i++)
+ {
+ MEDCouplingCartesianAMRPatch *elt(const_cast<MEDCouplingCartesianAMRPatch *>(ps[i]));
+ if(elt)
+ elt->incrRef();
+ PyList_SetItem(ret,i,convertCartesianAMRPatch(elt, SWIG_POINTER_OWN | 0 ));
+ }
+ return ret;
+ }
+
+ // agy : don't know why typemap fails here ??? let it in the extend section
+ PyObject *deepCpy(MEDCouplingCartesianAMRMeshGen *father) const throw(INTERP_KERNEL::Exception)
+ {
+ return convertCartesianAMRMesh(self->deepCpy(father), SWIG_POINTER_OWN | 0 );
+ }
+
+ MEDCouplingCartesianAMRPatch *getPatchAtPosition(const std::vector<int>& pos) const throw(INTERP_KERNEL::Exception)
+ {
+ const MEDCouplingCartesianAMRPatch *ret(self->getPatchAtPosition(pos));
+ MEDCouplingCartesianAMRPatch *ret2(const_cast<MEDCouplingCartesianAMRPatch *>(ret));
+ if(ret2)
+ ret2->incrRef();
+ return ret2;
+ }
+
+ MEDCouplingCartesianAMRMeshGen *getMeshAtPosition(const std::vector<int>& pos) const throw(INTERP_KERNEL::Exception)
+ {
+ const MEDCouplingCartesianAMRMeshGen *ret(self->getMeshAtPosition(pos));
+ MEDCouplingCartesianAMRMeshGen *ret2(const_cast<MEDCouplingCartesianAMRMeshGen *>(ret));
+ if(ret2)
+ ret2->incrRef();
+ return ret2;
+ }
+
+ virtual PyObject *positionRelativeToGodFather() const throw(INTERP_KERNEL::Exception)
+ {
+ std::vector<int> out1;
+ std::vector< std::pair<int,int> > out0(self->positionRelativeToGodFather(out1));
+ PyObject *ret(PyTuple_New(2));
+ PyTuple_SetItem(ret,0,convertFromVectorPairInt(out0));
+ PyTuple_SetItem(ret,1,convertIntArrToPyList2(out1));
+ return ret;
+ }
+
+ virtual PyObject *retrieveGridsAt(int absoluteLev) const throw(INTERP_KERNEL::Exception)
+ {
+ std::vector<MEDCouplingCartesianAMRPatchGen *> ps(self->retrieveGridsAt(absoluteLev));
+ int sz(ps.size());
+ PyObject *ret = PyList_New(sz);
+ for(int i=0;i<sz;i++)
+ PyList_SetItem(ret,i,convertCartesianAMRPatch(ps[i], SWIG_POINTER_OWN | 0 ));
+ return ret;
+ }
+
+ MEDCouplingFieldDouble *buildCellFieldOnRecurseWithoutOverlapWithoutGhost(int ghostSz, PyObject *recurseArrs) const
+ {
+ std::vector<const DataArrayDouble *> inp;
+ convertFromPyObjVectorOfObj<const ParaMEDMEM::DataArrayDouble *>(recurseArrs,SWIGTYPE_p_ParaMEDMEM__DataArrayDouble,"DataArrayDouble",inp);
+ return self->buildCellFieldOnRecurseWithoutOverlapWithoutGhost(ghostSz,inp);
+ }
+
+ virtual MEDCouplingCartesianAMRMeshGen *getFather() const throw(INTERP_KERNEL::Exception)
+ {
+ MEDCouplingCartesianAMRMeshGen *ret(const_cast<MEDCouplingCartesianAMRMeshGen *>(self->getFather()));
+ if(ret)
+ ret->incrRef();
+ return ret;
+ }
+
+ virtual MEDCouplingCartesianAMRMeshGen *getGodFather() const throw(INTERP_KERNEL::Exception)
+ {
+ MEDCouplingCartesianAMRMeshGen *ret(const_cast<MEDCouplingCartesianAMRMeshGen *>(self->getGodFather()));
+ if(ret)
+ ret->incrRef();
+ return ret;
+ }
+
+ MEDCouplingCartesianAMRPatch *getPatch(int patchId) const throw(INTERP_KERNEL::Exception)
+ {
+ MEDCouplingCartesianAMRPatch *ret(const_cast<MEDCouplingCartesianAMRPatch *>(self->getPatch(patchId)));
+ if(ret)
+ ret->incrRef();
+ return ret;
+ }
+
+ MEDCouplingIMesh *getImageMesh() const throw(INTERP_KERNEL::Exception)
+ {
+ const MEDCouplingIMesh *ret(self->getImageMesh());
+ if(ret)
+ ret->incrRef();
+ return const_cast<MEDCouplingIMesh *>(ret);
+ }
+
+ MEDCouplingCartesianAMRPatch *__getitem__(int patchId) const throw(INTERP_KERNEL::Exception)
+ {
+ if(patchId==self->getNumberOfPatches())
+ {
+ std::ostringstream oss;
+ oss << "Requesting for patchId " << patchId << " having only " << self->getNumberOfPatches() << " patches !";
+ PyErr_SetString(PyExc_StopIteration,oss.str().c_str());
+ return 0;
+ }
+ MEDCouplingCartesianAMRPatch *ret(const_cast<MEDCouplingCartesianAMRPatch *>(self->getPatch(patchId)));
+ if(ret)
+ ret->incrRef();
+ return ret;
+ }
+
+ void fillCellFieldOnPatchGhostAdv(int patchId, const DataArrayDouble *cellFieldOnThis, int ghostLev, PyObject *arrsOnPatches, bool isConservative=true) const throw(INTERP_KERNEL::Exception)
+ {
+ std::vector<const ParaMEDMEM::DataArrayDouble *> arrsOnPatches2;
+ convertFromPyObjVectorOfObj<const ParaMEDMEM::DataArrayDouble *>(arrsOnPatches,SWIGTYPE_p_ParaMEDMEM__DataArrayDouble,"DataArrayDouble",arrsOnPatches2);
+ self->fillCellFieldOnPatchGhostAdv(patchId,cellFieldOnThis,ghostLev,arrsOnPatches2,isConservative);
+ }
+
+ void fillCellFieldOnPatchOnlyGhostAdv(int patchId, int ghostLev, PyObject *arrsOnPatches) const
+ {
+ std::vector<const ParaMEDMEM::DataArrayDouble *> arrsOnPatches2;
+ convertFromPyObjVectorOfObj<const ParaMEDMEM::DataArrayDouble *>(arrsOnPatches,SWIGTYPE_p_ParaMEDMEM__DataArrayDouble,"DataArrayDouble",arrsOnPatches2);
+ self->fillCellFieldOnPatchOnlyGhostAdv(patchId,ghostLev,arrsOnPatches2);
+ }
+
+ void __delitem__(int patchId) throw(INTERP_KERNEL::Exception)
+ {
+ self->removePatch(patchId);
+ }
+
+ int __len__() const throw(INTERP_KERNEL::Exception)
+ {
+ return self->getNumberOfPatches();
+ }
+ }
+ };
+
+ class MEDCouplingCartesianAMRMeshSub : public MEDCouplingCartesianAMRMeshGen
+ {
+ };
+
+ class MEDCouplingCartesianAMRMesh : public MEDCouplingCartesianAMRMeshGen
+ {
+ public:
+ static MEDCouplingCartesianAMRMesh *New(MEDCouplingIMesh *mesh) throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ static MEDCouplingCartesianAMRMesh *New(const std::string& meshName, int spaceDim, PyObject *nodeStrct, PyObject *origin, PyObject *dxyz) throw(INTERP_KERNEL::Exception)
+ {
+ static const char msg0[]="MEDCouplingCartesianAMRMesh::New : error on 'origin' parameter !";
+ static const char msg1[]="MEDCouplingCartesianAMRMesh::New : error on 'dxyz' parameter !";
+ const int *nodeStrctPtr(0);
+ const double *originPtr(0),*dxyzPtr(0);
+ int sw,sz,val0;
+ std::vector<int> bb0;
+ nodeStrctPtr=convertObjToPossibleCpp1_Safe(nodeStrct,sw,sz,val0,bb0);
+ //
+ double val,val2;
+ std::vector<double> bb,bb2;
+ int sz1,sz2;
+ originPtr=convertObjToPossibleCpp5_SingleCompo(origin,sw,val,bb,msg0,false,sz1);
+ dxyzPtr=convertObjToPossibleCpp5_SingleCompo(dxyz,sw,val2,bb2,msg1,false,sz2);
+ //
+ return MEDCouplingCartesianAMRMesh::New(meshName,spaceDim,nodeStrctPtr,nodeStrctPtr+sz,originPtr,originPtr+sz1,dxyzPtr,dxyzPtr+sz2);
+ }
+
+ void createPatchesFromCriterionML(PyObject *bso, const DataArrayDouble *criterion, PyObject *factors, double eps) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector<const INTERP_KERNEL::BoxSplittingOptions *> inp0;
+ convertFromPyObjVectorOfObj<const INTERP_KERNEL::BoxSplittingOptions *>(bso,SWIGTYPE_p_INTERP_KERNEL__BoxSplittingOptions,"BoxSplittingOptions",inp0);
+ std::vector< std::vector<int> > inp2;
+ convertPyToVectorOfVectorOfInt(factors,inp2);
+ self->createPatchesFromCriterionML(inp0,criterion,inp2,eps);
+ }
+
+ MEDCouplingCartesianAMRMesh(const std::string& meshName, int spaceDim, PyObject *nodeStrct, PyObject *origin, PyObject *dxyz) throw(INTERP_KERNEL::Exception)
+ {
+ return ParaMEDMEM_MEDCouplingCartesianAMRMesh_New__SWIG_1(meshName,spaceDim,nodeStrct,origin,dxyz);
+ }
+
+ MEDCouplingCartesianAMRMesh(MEDCouplingIMesh *mesh) throw(INTERP_KERNEL::Exception)
+ {
+ return MEDCouplingCartesianAMRMesh::New(mesh);
+ }
+ }
+ };
+
+ class MEDCouplingDataForGodFather : public RefCountObject
+ {
+ public:
+ virtual void synchronizeFineToCoarse() throw(INTERP_KERNEL::Exception);
+ virtual void synchronizeFineToCoarseBetween(int fromLev, int toLev) throw(INTERP_KERNEL::Exception);
+ virtual void synchronizeCoarseToFine() throw(INTERP_KERNEL::Exception);
+ virtual void synchronizeCoarseToFineBetween(int fromLev, int toLev) throw(INTERP_KERNEL::Exception);
+ virtual void synchronizeAllGhostZones() throw(INTERP_KERNEL::Exception);
+ virtual void synchronizeAllGhostZonesOfDirectChidrenOf(const MEDCouplingCartesianAMRMeshGen *mesh) throw(INTERP_KERNEL::Exception);
+ virtual void synchronizeAllGhostZonesAtASpecifiedLevel(int level) throw(INTERP_KERNEL::Exception);
+ virtual void synchronizeAllGhostZonesAtASpecifiedLevelUsingOnlyFather(int level) throw(INTERP_KERNEL::Exception);
+ virtual void alloc() throw(INTERP_KERNEL::Exception);
+ virtual void dealloc() throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ MEDCouplingCartesianAMRMesh *getMyGodFather() throw(INTERP_KERNEL::Exception)
+ {
+ MEDCouplingCartesianAMRMesh *ret(self->getMyGodFather());
+ if(ret)
+ ret->incrRef();
+ return ret;
+ }
+ }
+ };
+
+ class MEDCouplingAMRAttribute : public MEDCouplingDataForGodFather, public TimeLabel
+ {
+ public:
+ int getNumberOfLevels() const throw(INTERP_KERNEL::Exception);
+ MEDCouplingAMRAttribute *deepCpy() const throw(INTERP_KERNEL::Exception);
+ MEDCouplingAMRAttribute *deepCpyWithoutGodFather() const throw(INTERP_KERNEL::Exception);
+ MEDCouplingFieldDouble *buildCellFieldOnRecurseWithoutOverlapWithoutGhost(MEDCouplingCartesianAMRMeshGen *mesh, const std::string& fieldName) const throw(INTERP_KERNEL::Exception);
+ MEDCouplingFieldDouble *buildCellFieldOnWithGhost(MEDCouplingCartesianAMRMeshGen *mesh, const std::string& fieldName) const throw(INTERP_KERNEL::Exception);
+ MEDCouplingFieldDouble *buildCellFieldOnWithoutGhost(MEDCouplingCartesianAMRMeshGen *mesh, const std::string& fieldName) const throw(INTERP_KERNEL::Exception);
+ bool changeGodFather(MEDCouplingCartesianAMRMesh *gf) throw(INTERP_KERNEL::Exception);
+ MEDCouplingAMRAttribute *projectTo(MEDCouplingCartesianAMRMesh *targetGF) const throw(INTERP_KERNEL::Exception);
+ std::string writeVTHB(const std::string& fileName) const throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ static MEDCouplingAMRAttribute *New(MEDCouplingCartesianAMRMesh *gf, PyObject *fieldNames, int ghostLev) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::pair<std::string,int> > fieldNamesCpp0;
+ std::vector< std::pair<std::string, std::vector<std::string> > > fieldNamesCpp1;
+ MEDCouplingAMRAttribute *ret(0);
+ try
+ {
+ convertPyToVectorPairStringInt(fieldNames,fieldNamesCpp0);
+ ret=MEDCouplingAMRAttribute::New(gf,fieldNamesCpp0,ghostLev);
+ }
+ catch(INTERP_KERNEL::Exception&)
+ {
+ convertPyToVectorPairStringVecString(fieldNames,fieldNamesCpp1);
+ ret=MEDCouplingAMRAttribute::New(gf,fieldNamesCpp1,ghostLev);
+ }
+ return ret;
+ }
+
+ MEDCouplingAMRAttribute(MEDCouplingCartesianAMRMesh *gf, PyObject *fieldNames, int ghostLev) throw(INTERP_KERNEL::Exception)
+ {
+ return ParaMEDMEM_MEDCouplingAMRAttribute_New(gf,fieldNames,ghostLev);
+ }
+
+ DataArrayDouble *getFieldOn(MEDCouplingCartesianAMRMeshGen *mesh, const std::string& fieldName) const throw(INTERP_KERNEL::Exception)
+ {
+ const DataArrayDouble *ret(self->getFieldOn(mesh,fieldName));
+ DataArrayDouble *ret2(const_cast<DataArrayDouble *>(ret));
+ if(ret2)
+ ret2->incrRef();
+ return ret2;
+ }
+
+ void spillInfoOnComponents(PyObject *compNames) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector< std::vector<std::string> > compNamesCpp;
+ convertPyToVectorOfVectorOfString(compNames,compNamesCpp);
+ self->spillInfoOnComponents(compNamesCpp);
+ }
+
+ void spillNatures(PyObject *nfs) throw(INTERP_KERNEL::Exception)
+ {
+ std::vector<int> inp0;
+ if(!fillIntVector(nfs,inp0))
+ throw INTERP_KERNEL::Exception("wrap of MEDCouplingAMRAttribute::spillNatures : vector of NatureOfField enum expected !");
+ std::size_t sz(inp0.size());
+ std::vector<NatureOfField> inp00(sz);
+ for(std::size_t i=0;i<sz;i++)
+ inp00[i]=(NatureOfField)inp0[i];
+ self->spillNatures(inp00);
+ }
+
+ PyObject *retrieveFieldsOn(MEDCouplingCartesianAMRMeshGen *mesh) const throw(INTERP_KERNEL::Exception)
+ {
+ std::vector<DataArrayDouble *> ret(self->retrieveFieldsOn(mesh));
+ int sz((int)ret.size());
+ PyObject *retPy(PyList_New(sz));
+ for(int i=0;i<sz;i++)
+ PyList_SetItem(retPy,i,SWIG_NewPointerObj(SWIG_as_voidptr(ret[i]),SWIGTYPE_p_ParaMEDMEM__DataArrayDouble, SWIG_POINTER_OWN | 0 ));
+ return retPy;
+ }
+ }
+ };
+
+ class DenseMatrix : public RefCountObject, public TimeLabel
+ {
+ public:
+ static DenseMatrix *New(int nbRows, int nbCols) throw(INTERP_KERNEL::Exception);
+ static DenseMatrix *New(DataArrayDouble *array, int nbRows, int nbCols) throw(INTERP_KERNEL::Exception);
+ DenseMatrix *deepCpy() const throw(INTERP_KERNEL::Exception);
+ DenseMatrix *shallowCpy() const throw(INTERP_KERNEL::Exception);
+ //
+ int getNumberOfRows() const throw(INTERP_KERNEL::Exception);
+ int getNumberOfCols() const throw(INTERP_KERNEL::Exception);
+ int getNbOfElems() const throw(INTERP_KERNEL::Exception);
+ void reBuild(DataArrayDouble *array, int nbRows=-1, int nbCols=-1) throw(INTERP_KERNEL::Exception);
+ void reShape(int nbRows, int nbCols) throw(INTERP_KERNEL::Exception);
+ void transpose() throw(INTERP_KERNEL::Exception);
+ //
+ bool isEqual(const DenseMatrix& other, double eps) const throw(INTERP_KERNEL::Exception);
+ DataArrayDouble *matVecMult(const DataArrayDouble *vec) const throw(INTERP_KERNEL::Exception);
+ static DataArrayDouble *MatVecMult(const DenseMatrix *mat, const DataArrayDouble *vec) throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ DenseMatrix(int nbRows, int nbCols) throw(INTERP_KERNEL::Exception)
+ {
+ return DenseMatrix::New(nbRows,nbCols);
+ }
+
+ DenseMatrix(DataArrayDouble *array, int nbRows, int nbCols) throw(INTERP_KERNEL::Exception)
+ {
+ return DenseMatrix::New(array,nbRows,nbCols);
+ }
+
+ PyObject *isEqualIfNotWhy(const DenseMatrix& other, double eps) const throw(INTERP_KERNEL::Exception)
+ {
+ std::string ret1;
+ bool ret0=self->isEqualIfNotWhy(other,eps,ret1);
+ PyObject *ret=PyTuple_New(2);
+ PyObject *ret0Py=ret0?Py_True:Py_False;
+ Py_XINCREF(ret0Py);
+ PyTuple_SetItem(ret,0,ret0Py);
+ PyTuple_SetItem(ret,1,PyString_FromString(ret1.c_str()));
+ return ret;
+ }
+
+ DataArrayDouble *getData() throw(INTERP_KERNEL::Exception)
+ {
+ DataArrayDouble *ret(self->getData());
+ if(ret)
+ ret->incrRef();
+ return ret;
+ }
+
+ DenseMatrix *__add__(const DenseMatrix *other) throw(INTERP_KERNEL::Exception)
+ {
+ return ParaMEDMEM::DenseMatrix::Add(self,other);
+ }
+
+ DenseMatrix *__sub__(const DenseMatrix *other) throw(INTERP_KERNEL::Exception)
+ {
+ return ParaMEDMEM::DenseMatrix::Substract(self,other);
+ }
+
+ DenseMatrix *__mul__(const DenseMatrix *other) throw(INTERP_KERNEL::Exception)
+ {
+ return ParaMEDMEM::DenseMatrix::Multiply(self,other);
+ }
+
+ DenseMatrix *__mul__(const DataArrayDouble *other) throw(INTERP_KERNEL::Exception)
+ {
+ return ParaMEDMEM::DenseMatrix::Multiply(self,other);
+ }
+
+ PyObject *___iadd___(PyObject *trueSelf, const DenseMatrix *other) throw(INTERP_KERNEL::Exception)
+ {
+ self->addEqual(other);
+ Py_XINCREF(trueSelf);
+ return trueSelf;
+ }
+
+ PyObject *___isub___(PyObject *trueSelf, const DenseMatrix *other) throw(INTERP_KERNEL::Exception)
+ {
+ self->substractEqual(other);
+ Py_XINCREF(trueSelf);
+ return trueSelf;
+ }
+#ifdef WITH_NUMPY
+ PyObject *toNumPyMatrix() throw(INTERP_KERNEL::Exception) // not const. It is not a bug !
+ {
+ PyObject *obj(ToNumPyArrayUnderground<DataArrayDouble,double>(self->getData(),NPY_DOUBLE,"DataArrayDouble",self->getNumberOfRows(),self->getNumberOfCols()));
+ return obj;
+ }
+#endif
+ }
+ };
+
+ class PartDefinition : public RefCountObject, public TimeLabel
+ {
+ public:
+ static PartDefinition *New(int start, int stop, int step) throw(INTERP_KERNEL::Exception);
+ static PartDefinition *New(DataArrayInt *listOfIds) throw(INTERP_KERNEL::Exception);
+ virtual DataArrayInt *toDAI() const throw(INTERP_KERNEL::Exception);
+ virtual int getNumberOfElems() const throw(INTERP_KERNEL::Exception);
+ virtual std::string getRepr() const throw(INTERP_KERNEL::Exception);
+ virtual PartDefinition *composeWith(const PartDefinition *other) const throw(INTERP_KERNEL::Exception);
+ virtual void checkCoherency() const throw(INTERP_KERNEL::Exception);
+ virtual PartDefinition *tryToSimplify() const throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ virtual PartDefinition *__add__(const PartDefinition& other) const throw(INTERP_KERNEL::Exception)
+ {
+ return (*self)+other;
+ }
+
+ virtual PyObject *isEqual(const PartDefinition *other) const throw(INTERP_KERNEL::Exception)
+ {
+ std::string ret1;
+ bool ret0(self->isEqual(other,ret1));
+ PyObject *ret=PyTuple_New(2);
+ PyObject *ret0Py=ret0?Py_True:Py_False;
+ Py_XINCREF(ret0Py);
+ PyTuple_SetItem(ret,0,ret0Py);
+ PyTuple_SetItem(ret,1,PyString_FromString(ret1.c_str()));
+ return ret;
+ }
+
+ virtual PyObject *deepCpy() const throw(INTERP_KERNEL::Exception)
+ {
+ return convertPartDefinition(self->deepCpy(),SWIG_POINTER_OWN | 0);
+ }
+ }
+ protected:
+ virtual ~PartDefinition();
+ };
+
+ class DataArrayPartDefinition : public PartDefinition
+ {
+ public:
+ static DataArrayPartDefinition *New(DataArrayInt *listOfIds) throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ DataArrayPartDefinition(DataArrayInt *listOfIds) throw(INTERP_KERNEL::Exception)
+ {
+ return DataArrayPartDefinition::New(listOfIds);
+ }
+
+ std::string __str__() const throw(INTERP_KERNEL::Exception)
+ {
+ return self->getRepr();
+ }
+
+ std::string __repr__() const throw(INTERP_KERNEL::Exception)
+ {
+ std::ostringstream oss; oss << "DataArrayPartDefinition C++ instance at " << self << "." << std::endl;
+ oss << self->getRepr();
+ return oss.str();
+ }
+ }
+ protected:
+ virtual ~DataArrayPartDefinition();
+ };
+
+ class SlicePartDefinition : public PartDefinition
+ {
+ public:
+ static SlicePartDefinition *New(int start, int stop, int step) throw(INTERP_KERNEL::Exception);
+ int getEffectiveStop() const throw(INTERP_KERNEL::Exception);
+ %extend
+ {
+ SlicePartDefinition(int start, int stop, int step) throw(INTERP_KERNEL::Exception)
+ {
+ return SlicePartDefinition::New(start,stop,step);
+ }
+
+ PyObject *getSlice() const throw(INTERP_KERNEL::Exception)
+ {
+ int a,b,c;
+ self->getSlice(a,b,c);
+ return PySlice_New(PyInt_FromLong(a),PyInt_FromLong(b),PyInt_FromLong(c));
+ }
+
+ std::string __str__() const throw(INTERP_KERNEL::Exception)
+ {
+ return self->getRepr();
+ }
+
+ std::string __repr__() const throw(INTERP_KERNEL::Exception)
+ {
+ std::ostringstream oss; oss << "SlicePartDefinition C++ instance at " << self << "." << std::endl;
+ oss << self->getRepr();
+ return oss.str();
+ }
+ }
+ protected:
+ virtual ~SlicePartDefinition();
+ };
}
%pythoncode %{