// Copyright (C) 2017 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, 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 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU // Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public // License along with this library; if not, write to the Free Software // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA // // See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com // // Author : Anthony Geay (EDF R&D) #ifdef WITH_DOCSTRINGS %include MEDCoupling_doc.i #endif %include std_vector.i %include std_string.i %{ #include "MEDCouplingMemArray.hxx" #include "MEDCouplingUMesh.hxx" #include "MEDCouplingMappedExtrudedMesh.hxx" #include "MEDCouplingCMesh.hxx" #include "MEDCouplingIMesh.hxx" #include "MEDCouplingMap.txx" #include "MEDCouplingCurveLinearMesh.hxx" #include "MEDCoupling1GTUMesh.hxx" #include "MEDCouplingField.hxx" #include "MEDCouplingFieldDouble.hxx" #include "MEDCouplingFieldInt.hxx" #include "MEDCouplingFieldFloat.hxx" #include "MEDCouplingFieldTemplate.hxx" #include "MEDCouplingGaussLocalization.hxx" #include "MCAuto.hxx" #include "MEDCouplingMultiFields.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 MEDCoupling; using namespace INTERP_KERNEL; %} %template(ivec) std::vector; %template(dvec) std::vector; %template(svec) std::vector; //////////////////// %typemap(out) MEDCoupling::MEDCouplingMesh* { $result=convertMesh($1,$owner); } %typemap(out) MEDCouplingMesh* { $result=convertMesh($1,$owner); } //$$$$$$$$$$$$$$$$$$ //////////////////// %typemap(out) MEDCoupling::MEDCouplingPointSet* { $result=convertMesh($1,$owner); } %typemap(out) MEDCouplingPointSet* { $result=convertMesh($1,$owner); } //$$$$$$$$$$$$$$$$$$ //////////////////// %typemap(out) MEDCouplingCartesianAMRPatchGen* { $result=convertCartesianAMRPatch($1,$owner); } //$$$$$$$$$$$$$$$$$$ //////////////////// %typemap(out) MEDCouplingCartesianAMRMeshGen* { $result=convertCartesianAMRMesh($1,$owner); } //$$$$$$$$$$$$$$$$$$ //////////////////// %typemap(out) MEDCouplingDataForGodFather* { $result=convertDataForGodFather($1,$owner); } //$$$$$$$$$$$$$$$$$$ //////////////////// %typemap(out) MEDCoupling::MEDCoupling1GTUMesh* { $result=convertMesh($1,$owner); } %typemap(out) MEDCoupling1GTUMesh* { $result=convertMesh($1,$owner); } //$$$$$$$$$$$$$$$$$$ //////////////////// %typemap(out) MEDCoupling::MEDCouplingStructuredMesh* { $result=convertMesh($1,$owner); } %typemap(out) MEDCouplingStructuredMesh* { $result=convertMesh($1,$owner); } //$$$$$$$$$$$$$$$$$$ //////////////////// %typemap(out) MEDCoupling::MEDCouplingFieldDiscretization* { $result=convertFieldDiscretization($1,$owner); } %typemap(out) MEDCouplingFieldDiscretization* { $result=convertFieldDiscretization($1,$owner); } //$$$$$$$$$$$$$$$$$$ //////////////////// %typemap(out) MEDCoupling::MEDCouplingField* { $result=convertField($1,$owner); } %typemap(out) MEDCouplingField* { $result=convertField($1,$owner); } //$$$$$$$$$$$$$$$$$$ //////////////////// %typemap(out) MEDCoupling::MEDCouplingMultiFields* { $result=convertMultiFields($1,$owner); } %typemap(out) MEDCouplingMultiFields* { $result=convertMultiFields($1,$owner); } //$$$$$$$$$$$$$$$$$$ //////////////////// %typemap(out) MEDCoupling::PartDefinition* { $result=convertPartDefinition($1,$owner); } %typemap(out) PartDefinition* { $result=convertPartDefinition($1,$owner); } //$$$$$$$$$$$$$$$$$$ #ifdef WITH_NUMPY %init %{ import_array(); %} #endif %init %{ initializeMe(); %} %feature("autodoc", "1"); %feature("docstring"); %newobject MEDCoupling::MEDCouplingField::buildMeasureField; %newobject MEDCoupling::MEDCouplingField::getLocalizationOfDiscr; %newobject MEDCoupling::MEDCouplingField::computeTupleIdsToSelectFromCellIds; %newobject MEDCoupling::MEDCouplingFieldDouble::New; %newobject MEDCoupling::MEDCouplingFieldDouble::getArray; %newobject MEDCoupling::MEDCouplingFieldDouble::getEndArray; %newobject MEDCoupling::MEDCouplingFieldDouble::MergeFields; %newobject MEDCoupling::MEDCouplingFieldDouble::MeldFields; %newobject MEDCoupling::MEDCouplingFieldDouble::convertToIntField; %newobject MEDCoupling::MEDCouplingFieldDouble::convertToFloatField; %newobject MEDCoupling::MEDCouplingFieldDouble::doublyContractedProduct; %newobject MEDCoupling::MEDCouplingFieldDouble::determinant; %newobject MEDCoupling::MEDCouplingFieldDouble::eigenValues; %newobject MEDCoupling::MEDCouplingFieldDouble::eigenVectors; %newobject MEDCoupling::MEDCouplingFieldDouble::inverse; %newobject MEDCoupling::MEDCouplingFieldDouble::trace; %newobject MEDCoupling::MEDCouplingFieldDouble::deviator; %newobject MEDCoupling::MEDCouplingFieldDouble::magnitude; %newobject MEDCoupling::MEDCouplingFieldDouble::maxPerTuple; %newobject MEDCoupling::MEDCouplingFieldDouble::keepSelectedComponents; %newobject MEDCoupling::MEDCouplingFieldDouble::extractSlice3D; %newobject MEDCoupling::MEDCouplingFieldDouble::DotFields; %newobject MEDCoupling::MEDCouplingFieldDouble::dot; %newobject MEDCoupling::MEDCouplingFieldDouble::CrossProductFields; %newobject MEDCoupling::MEDCouplingFieldDouble::crossProduct; %newobject MEDCoupling::MEDCouplingFieldDouble::MaxFields; %newobject MEDCoupling::MEDCouplingFieldDouble::max; %newobject MEDCoupling::MEDCouplingFieldDouble::MinFields; %newobject MEDCoupling::MEDCouplingFieldDouble::AddFields; %newobject MEDCoupling::MEDCouplingFieldDouble::SubstractFields; %newobject MEDCoupling::MEDCouplingFieldDouble::MultiplyFields; %newobject MEDCoupling::MEDCouplingFieldDouble::DivideFields; %newobject MEDCoupling::MEDCouplingFieldDouble::min; %newobject MEDCoupling::MEDCouplingFieldDouble::negate; %newobject MEDCoupling::MEDCouplingFieldDouble::findIdsInRange; %newobject MEDCoupling::MEDCouplingFieldDouble::buildSubPart; %newobject MEDCoupling::MEDCouplingFieldDouble::buildSubPartRange; %newobject MEDCoupling::MEDCouplingFieldDouble::voronoize; %newobject MEDCoupling::MEDCouplingFieldDouble::convertQuadraticCellsToLinear; %newobject MEDCoupling::MEDCouplingFieldDouble::__getitem__; %newobject MEDCoupling::MEDCouplingFieldDouble::__neg__; %newobject MEDCoupling::MEDCouplingFieldDouble::__add__; %newobject MEDCoupling::MEDCouplingFieldDouble::__sub__; %newobject MEDCoupling::MEDCouplingFieldDouble::__mul__; %newobject MEDCoupling::MEDCouplingFieldDouble::__div__; %newobject MEDCoupling::MEDCouplingFieldDouble::__pow__; %newobject MEDCoupling::MEDCouplingFieldDouble::__radd__; %newobject MEDCoupling::MEDCouplingFieldDouble::__rsub__; %newobject MEDCoupling::MEDCouplingFieldDouble::__rmul__; %newobject MEDCoupling::MEDCouplingFieldDouble::__rdiv__; %newobject MEDCoupling::MEDCouplingFieldDouble::clone; %newobject MEDCoupling::MEDCouplingFieldDouble::cloneWithMesh; %newobject MEDCoupling::MEDCouplingFieldDouble::deepCopy; %newobject MEDCoupling::MEDCouplingFieldDouble::buildNewTimeReprFromThis; %newobject MEDCoupling::MEDCouplingFieldDouble::nodeToCellDiscretization; %newobject MEDCoupling::MEDCouplingFieldDouble::cellToNodeDiscretization; %newobject MEDCoupling::MEDCouplingFieldDouble::getValueOnMulti; %newobject MEDCoupling::MEDCouplingFieldDouble::computeVectorFieldCyl; %newobject MEDCoupling::MEDCouplingFieldInt::New; %newobject MEDCoupling::MEDCouplingFieldInt::convertToDblField; %newobject MEDCoupling::MEDCouplingFieldInt::getArray; %newobject MEDCoupling::MEDCouplingFieldInt::deepCopy; %newobject MEDCoupling::MEDCouplingFieldInt::clone; %newobject MEDCoupling::MEDCouplingFieldInt::cloneWithMesh; %newobject MEDCoupling::MEDCouplingFieldInt::buildSubPart; %newobject MEDCoupling::MEDCouplingFieldInt::buildSubPartRange; %newobject MEDCoupling::MEDCouplingFieldInt::__getitem__; %newobject MEDCoupling::MEDCouplingFieldFloat::New; %newobject MEDCoupling::MEDCouplingFieldFloat::convertToDblField; %newobject MEDCoupling::MEDCouplingFieldFloat::getArray; %newobject MEDCoupling::MEDCouplingFieldFloat::deepCopy; %newobject MEDCoupling::MEDCouplingFieldFloat::clone; %newobject MEDCoupling::MEDCouplingFieldFloat::cloneWithMesh; %newobject MEDCoupling::MEDCouplingFieldFloat::buildSubPart; %newobject MEDCoupling::MEDCouplingFieldFloat::buildSubPartRange; %newobject MEDCoupling::MEDCouplingFieldFloat::__getitem__; %newobject MEDCoupling::MEDCouplingFieldTemplate::New; %newobject MEDCoupling::MEDCouplingMesh::deepCopy; %newobject MEDCoupling::MEDCouplingMesh::clone; %newobject MEDCoupling::MEDCouplingMesh::checkDeepEquivalOnSameNodesWith; %newobject MEDCoupling::MEDCouplingMesh::checkTypeConsistencyAndContig; %newobject MEDCoupling::MEDCouplingMesh::computeNbOfNodesPerCell; %newobject MEDCoupling::MEDCouplingMesh::computeNbOfFacesPerCell; %newobject MEDCoupling::MEDCouplingMesh::computeEffectiveNbOfNodesPerCell; %newobject MEDCoupling::MEDCouplingMesh::buildPartRange; %newobject MEDCoupling::MEDCouplingMesh::giveCellsWithType; %newobject MEDCoupling::MEDCouplingMesh::getCoordinatesAndOwner; %newobject MEDCoupling::MEDCouplingMesh::computeCellCenterOfMass; %newobject MEDCoupling::MEDCouplingMesh::computeIsoBarycenterOfNodesPerCell; %newobject MEDCoupling::MEDCouplingMesh::buildOrthogonalField; %newobject MEDCoupling::MEDCouplingMesh::getCellIdsFullyIncludedInNodeIds; %newobject MEDCoupling::MEDCouplingMesh::mergeMyselfWith; %newobject MEDCoupling::MEDCouplingMesh::fillFromAnalytic; %newobject MEDCoupling::MEDCouplingMesh::fillFromAnalyticCompo; %newobject MEDCoupling::MEDCouplingMesh::fillFromAnalyticNamedCompo; %newobject MEDCoupling::MEDCouplingMesh::getMeasureField; %newobject MEDCoupling::MEDCouplingMesh::simplexize; %newobject MEDCoupling::MEDCouplingMesh::buildUnstructured; %newobject MEDCoupling::MEDCouplingMesh::MergeMeshes; %newobject MEDCoupling::MEDCouplingMesh::getDirectAccessOfCoordsArrIfInStructure; %newobject MEDCoupling::MEDCouplingPointSet::zipCoordsTraducer; %newobject MEDCoupling::MEDCouplingPointSet::getCellsInBoundingBox; %newobject MEDCoupling::MEDCouplingPointSet::findBoundaryNodes; %newobject MEDCoupling::MEDCouplingPointSet::buildBoundaryMesh; %newobject MEDCoupling::MEDCouplingPointSet::MergeNodesArray; %newobject MEDCoupling::MEDCouplingPointSet::buildPartOfMySelfSlice; %newobject MEDCoupling::MEDCouplingPointSet::BuildInstanceFromMeshType; %newobject MEDCoupling::MEDCouplingPointSet::zipConnectivityTraducer; %newobject MEDCoupling::MEDCouplingPointSet::mergeMyselfWithOnSameCoords; %newobject MEDCoupling::MEDCouplingPointSet::fillCellIdsToKeepFromNodeIds; %newobject MEDCoupling::MEDCouplingPointSet::getCellIdsLyingOnNodes; %newobject MEDCoupling::MEDCouplingPointSet::deepCopyConnectivityOnly; %newobject MEDCoupling::MEDCouplingPointSet::getBoundingBoxForBBTree; %newobject MEDCoupling::MEDCouplingPointSet::computeFetchedNodeIds; %newobject MEDCoupling::MEDCouplingPointSet::ComputeNbOfInteractionsWithSrcCells; %newobject MEDCoupling::MEDCouplingPointSet::computeDiameterField; %newobject MEDCoupling::MEDCouplingPointSet::__getitem__; %newobject MEDCoupling::MEDCouplingUMesh::New; %newobject MEDCoupling::MEDCouplingUMesh::getNodalConnectivity; %newobject MEDCoupling::MEDCouplingUMesh::getNodalConnectivityIndex; %newobject MEDCoupling::MEDCouplingUMesh::__iter__; %newobject MEDCoupling::MEDCouplingUMesh::cellsByType; %newobject MEDCoupling::MEDCouplingUMesh::buildDescendingConnectivity; %newobject MEDCoupling::MEDCouplingUMesh::buildDescendingConnectivity2; %newobject MEDCoupling::MEDCouplingUMesh::explode3DMeshTo1D; %newobject MEDCoupling::MEDCouplingUMesh::explodeMeshIntoMicroEdges; %newobject MEDCoupling::MEDCouplingUMesh::buildExtrudedMesh; %newobject MEDCoupling::MEDCouplingUMesh::buildSpreadZonesWithPoly; %newobject MEDCoupling::MEDCouplingUMesh::MergeUMeshes; %newobject MEDCoupling::MEDCouplingUMesh::MergeUMeshesOnSameCoords; %newobject MEDCoupling::MEDCouplingUMesh::ComputeSpreadZoneGradually; %newobject MEDCoupling::MEDCouplingUMesh::ComputeSpreadZoneGraduallyFromSeed; %newobject MEDCoupling::MEDCouplingUMesh::buildNewNumberingFromCommNodesFrmt; %newobject MEDCoupling::MEDCouplingUMesh::conformize2D; %newobject MEDCoupling::MEDCouplingUMesh::conformize3D; %newobject MEDCoupling::MEDCouplingUMesh::colinearize2D; %newobject MEDCoupling::MEDCouplingUMesh::colinearizeKeepingConform2D; %newobject MEDCoupling::MEDCouplingUMesh::rearrange2ConsecutiveCellTypes; %newobject MEDCoupling::MEDCouplingUMesh::sortCellsInMEDFileFrmt; %newobject MEDCoupling::MEDCouplingUMesh::getRenumArrForMEDFileFrmt; %newobject MEDCoupling::MEDCouplingUMesh::convertCellArrayPerGeoType; %newobject MEDCoupling::MEDCouplingUMesh::getRenumArrForConsecutiveCellTypesSpec; %newobject MEDCoupling::MEDCouplingUMesh::buildDirectionVectorField; %newobject MEDCoupling::MEDCouplingUMesh::convertLinearCellsToQuadratic; %newobject MEDCoupling::MEDCouplingUMesh::getEdgeRatioField; %newobject MEDCoupling::MEDCouplingUMesh::getAspectRatioField; %newobject MEDCoupling::MEDCouplingUMesh::getWarpField; %newobject MEDCoupling::MEDCouplingUMesh::getSkewField; %newobject MEDCoupling::MEDCouplingUMesh::getPartBarycenterAndOwner; %newobject MEDCoupling::MEDCouplingUMesh::computePlaneEquationOf3DFaces; %newobject MEDCoupling::MEDCouplingUMesh::getPartMeasureField; %newobject MEDCoupling::MEDCouplingUMesh::buildPartOrthogonalField; %newobject MEDCoupling::MEDCouplingUMesh::keepCellIdsByType; %newobject MEDCoupling::MEDCouplingUMesh::Build0DMeshFromCoords; %newobject MEDCoupling::MEDCouplingUMesh::Build1DMeshFromCoords; %newobject MEDCoupling::MEDCouplingUMesh::findAndCorrectBadOriented3DExtrudedCells; %newobject MEDCoupling::MEDCouplingUMesh::findAndCorrectBadOriented3DCells; %newobject MEDCoupling::MEDCouplingUMesh::convertIntoSingleGeoTypeMesh; %newobject MEDCoupling::MEDCouplingUMesh::convertNodalConnectivityToStaticGeoTypeMesh; %newobject MEDCoupling::MEDCouplingUMesh::findCellIdsOnBoundary; %newobject MEDCoupling::MEDCouplingUMesh::computeSkin; %newobject MEDCoupling::MEDCouplingUMesh::buildSetInstanceFromThis; %newobject MEDCoupling::MEDCouplingUMesh::getCellIdsCrossingPlane; %newobject MEDCoupling::MEDCouplingUMesh::convexEnvelop2D; %newobject MEDCoupling::MEDCouplingUMesh::ComputeRangesFromTypeDistribution; %newobject MEDCoupling::MEDCouplingUMesh::buildUnionOf2DMesh; %newobject MEDCoupling::MEDCouplingUMesh::buildUnionOf3DMesh; %newobject MEDCoupling::MEDCouplingUMesh::generateGraph; %newobject MEDCoupling::MEDCouplingUMesh::orderConsecutiveCells1D; %newobject MEDCoupling::MEDCouplingUMesh::clipSingle3DCellByPlane; %newobject MEDCoupling::MEDCouplingUMesh::getBoundingBoxForBBTreeFast; %newobject MEDCoupling::MEDCouplingUMesh::getBoundingBoxForBBTree2DQuadratic; %newobject MEDCoupling::MEDCouplingUMesh::getBoundingBoxForBBTree1DQuadratic; %newobject MEDCoupling::MEDCouplingUMesh::convertDegeneratedCellsAndRemoveFlatOnes; %newobject MEDCoupling::MEDCouplingUMeshCellByTypeEntry::__iter__; %newobject MEDCoupling::MEDCouplingUMeshCellEntry::__iter__; %newobject MEDCoupling::MEDCoupling1GTUMesh::New; %newobject MEDCoupling::MEDCoupling1GTUMesh::getNodalConnectivity; %newobject MEDCoupling::MEDCoupling1GTUMesh::AggregateOnSameCoordsToUMesh; %newobject MEDCoupling::MEDCoupling1SGTUMesh::New; %newobject MEDCoupling::MEDCoupling1SGTUMesh::buildSetInstanceFromThis; %newobject MEDCoupling::MEDCoupling1SGTUMesh::computeDualMesh; %newobject MEDCoupling::MEDCoupling1SGTUMesh::explodeEachHexa8To6Quad4; %newobject MEDCoupling::MEDCoupling1SGTUMesh::sortHexa8EachOther; %newobject MEDCoupling::MEDCoupling1SGTUMesh::Merge1SGTUMeshes; %newobject MEDCoupling::MEDCoupling1SGTUMesh::Merge1SGTUMeshesOnSameCoords; %newobject MEDCoupling::MEDCoupling1DGTUMesh::New; %newobject MEDCoupling::MEDCoupling1DGTUMesh::getNodalConnectivityIndex; %newobject MEDCoupling::MEDCoupling1DGTUMesh::buildSetInstanceFromThis; %newobject MEDCoupling::MEDCoupling1DGTUMesh::Merge1DGTUMeshes; %newobject MEDCoupling::MEDCoupling1DGTUMesh::Merge1DGTUMeshesOnSameCoords; %newobject MEDCoupling::MEDCouplingMappedExtrudedMesh::New; %newobject MEDCoupling::MEDCouplingMappedExtrudedMesh::build3DUnstructuredMesh; %newobject MEDCoupling::MEDCouplingStructuredMesh::buildStructuredSubPart; %newobject MEDCoupling::MEDCouplingStructuredMesh::build1SGTUnstructured; %newobject MEDCoupling::MEDCouplingStructuredMesh::build1SGTSubLevelMesh; %newobject MEDCoupling::MEDCouplingStructuredMesh::BuildExplicitIdsFrom; %newobject MEDCoupling::MEDCouplingStructuredMesh::ExtractFieldOfDoubleFrom; %newobject MEDCoupling::MEDCouplingStructuredMesh::Build1GTNodalConnectivity; %newobject MEDCoupling::MEDCouplingStructuredMesh::Build1GTNodalConnectivityOfSubLevelMesh; %newobject MEDCoupling::MEDCouplingStructuredMesh::ComputeCornersGhost; %newobject MEDCoupling::MEDCouplingCMesh::New; %newobject MEDCoupling::MEDCouplingCMesh::getCoordsAt; %newobject MEDCoupling::MEDCouplingCMesh::buildCurveLinear; %newobject MEDCoupling::MEDCouplingIMesh::New; %newobject MEDCoupling::MEDCouplingIMesh::asSingleCell; %newobject MEDCoupling::MEDCouplingIMesh::buildWithGhost; %newobject MEDCoupling::MEDCouplingIMesh::convertToCartesian; %newobject MEDCoupling::MEDCouplingCurveLinearMesh::New; %newobject MEDCoupling::MEDCouplingCurveLinearMesh::getCoords; %newobject MEDCoupling::MEDCouplingMultiFields::New; %newobject MEDCoupling::MEDCouplingMultiFields::deepCopy; %newobject MEDCoupling::MEDCouplingFieldOverTime::New; %newobject MEDCoupling::MEDCouplingCartesianAMRPatchGen::getMesh; %newobject MEDCoupling::MEDCouplingCartesianAMRPatchGen::__getitem__; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::deepCopy; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::buildUnstructured; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::extractGhostFrom; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::buildMeshFromPatchEnvelop; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::buildMeshOfDirectChildrenOnly; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::getImageMesh; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::getGodFather; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::getFather; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::getPatch; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::createCellFieldOnPatch; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::findPatchesInTheNeighborhoodOf; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::getPatchAtPosition; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::getMeshAtPosition; %newobject MEDCoupling::MEDCouplingCartesianAMRMeshGen::__getitem__; %newobject MEDCoupling::MEDCouplingCartesianAMRMesh::New; %newobject MEDCoupling::MEDCouplingDataForGodFather::getMyGodFather; %newobject MEDCoupling::MEDCouplingAMRAttribute::New; %newobject MEDCoupling::MEDCouplingAMRAttribute::deepCopy; %newobject MEDCoupling::MEDCouplingAMRAttribute::deepCpyWithoutGodFather; %newobject MEDCoupling::MEDCouplingAMRAttribute::getFieldOn; %newobject MEDCoupling::MEDCouplingAMRAttribute::projectTo; %newobject MEDCoupling::MEDCouplingAMRAttribute::buildCellFieldOnRecurseWithoutOverlapWithoutGhost; %newobject MEDCoupling::MEDCouplingAMRAttribute::buildCellFieldOnWithGhost; %newobject MEDCoupling::MEDCouplingAMRAttribute::buildCellFieldOnWithoutGhost; %newobject MEDCoupling::DenseMatrix::New; %newobject MEDCoupling::DenseMatrix::deepCopy; %newobject MEDCoupling::DenseMatrix::shallowCpy; %newobject MEDCoupling::DenseMatrix::getData; %newobject MEDCoupling::DenseMatrix::matVecMult; %newobject MEDCoupling::DenseMatrix::MatVecMult; %newobject MEDCoupling::DenseMatrix::__add__; %newobject MEDCoupling::DenseMatrix::__sub__; %newobject MEDCoupling::DenseMatrix::__mul__; %newobject MEDCoupling::MEDCouplingGaussLocalization::localizePtsInRefCooForEachCell; %newobject MEDCoupling::MEDCouplingGaussLocalization::buildRefCell; %newobject MEDCoupling::MEDCouplingSkyLineArray::BuildFromPolyhedronConn; %newobject MEDCoupling::MEDCouplingSkyLineArray::getSuperIndexArray; %newobject MEDCoupling::MEDCouplingSkyLineArray::getIndexArray; %newobject MEDCoupling::MEDCouplingSkyLineArray::getValuesArray; %feature("unref") MEDCouplingPointSet "$this->decrRef();" %feature("unref") MEDCouplingMesh "$this->decrRef();" %feature("unref") MEDCouplingUMesh "$this->decrRef();" %feature("unref") MEDCoupling1GTUMesh "$this->decrRef();" %feature("unref") MEDCoupling1SGTUMesh "$this->decrRef();" %feature("unref") MEDCoupling1DGTUMesh "$this->decrRef();" %feature("unref") MEDCouplingMappedExtrudedMesh "$this->decrRef();" %feature("unref") MEDCouplingCMesh "$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 "$this->decrRef();" %feature("unref") MEDCouplingFieldDiscretizationGauss "$this->decrRef();" %feature("unref") MEDCouplingFieldDiscretizationGaussNE "$this->decrRef();" %feature("unref") MEDCouplingFieldDiscretizationKriging "$this->decrRef();" %feature("unref") MEDCouplingFieldDouble "$this->decrRef();" %feature("unref") MEDCouplingFieldFloat "$this->decrRef();" %feature("unref") MEDCouplingFieldInt "$this->decrRef();" %feature("unref") MEDCouplingMultiFields "$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 "$this->decrRef();" %feature("unref") MEDCouplingSkyLineArray "$this->decrRef();" %rename(assign) *::operator=; %ignore MEDCoupling::MEDCouplingGaussLocalization::pushTinySerializationIntInfo; %ignore MEDCoupling::MEDCouplingGaussLocalization::pushTinySerializationDblInfo; %ignore MEDCoupling::MEDCouplingGaussLocalization::fillWithValues; %ignore MEDCoupling::MEDCouplingGaussLocalization::buildNewInstanceFromTinyInfo; %nodefaultctor; %rename (InterpKernelException) INTERP_KERNEL::Exception; %include "MEDCouplingRefCountObject.i" %include "MEDCouplingMemArray.i" %{ void initializeMe() {// AGY : here initialization of C++ traits in MEDCouplingDataArrayTypemaps.i for code factorization. Awful, I know, but no other solutions. SWIGTITraits::TI=SWIGTYPE_p_MEDCoupling__DataArrayDouble; SWIGTITraits::TI=SWIGTYPE_p_MEDCoupling__DataArrayFloat; SWIGTITraits::TI=SWIGTYPE_p_MEDCoupling__DataArrayInt; SWIGTITraits::TI_TUPLE=SWIGTYPE_p_MEDCoupling__DataArrayDoubleTuple; SWIGTITraits::TI_TUPLE=SWIGTYPE_p_MEDCoupling__DataArrayFloatTuple; SWIGTITraits::TI_TUPLE=SWIGTYPE_p_MEDCoupling__DataArrayIntTuple; } %} 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 MEDCoupling { typedef enum { ON_CELLS = 0, ON_NODES = 1, ON_GAUSS_PT = 2, ON_GAUSS_NE = 3, ON_NODES_KR = 4 } TypeOfField; typedef enum { NO_TIME = 4, ONE_TIME = 5, LINEAR_TIME = 6, CONST_ON_TIME_INTERVAL = 7 } TypeOfTimeDiscretization; typedef enum { UNSTRUCTURED = 5, CARTESIAN = 7, EXTRUDED = 8, CURVE_LINEAR = 9, SINGLE_STATIC_GEO_TYPE_UNSTRUCTURED = 10, SINGLE_DYNAMIC_GEO_TYPE_UNSTRUCTURED = 11, IMAGE_GRID = 12 } MEDCouplingMeshType; class DataArrayInt; class DataArrayDouble; class MEDCouplingUMesh; class MEDCouplingCMesh; class MEDCouplingFieldDouble; %extend RefCountObject { std::string getHiddenCppPointer() const { std::ostringstream oss; oss << "C++ Pointer address is : " << self; return oss.str(); } } %extend MEDCouplingGaussLocalization { std::string __str__() const throw(INTERP_KERNEL::Exception) { return self->getStringRepr(); } std::string __repr__() const throw(INTERP_KERNEL::Exception) { std::ostringstream oss; oss << "MEDCouplingGaussLocalization C++ instance at " << self << "." << std::endl; oss << self->getStringRepr(); return oss.str(); } } //== MEDCouplingMesh class MEDCouplingMesh : public RefCountObject, public TimeLabel { public: void setName(const std::string& name); std::string getName() const; void setDescription(const std::string& descr); std::string getDescription() const; void setTime(double val, int iteration, int order); void setTimeUnit(const std::string& unit); std::string getTimeUnit() const; virtual MEDCouplingMeshType getType() const throw(INTERP_KERNEL::Exception); bool isStructured() const throw(INTERP_KERNEL::Exception); virtual MEDCouplingMesh *deepCopy() const throw(INTERP_KERNEL::Exception); virtual MEDCouplingMesh *clone(bool recDeepCpy) const throw(INTERP_KERNEL::Exception); virtual bool isEqual(const MEDCouplingMesh *other, double prec) const throw(INTERP_KERNEL::Exception); virtual bool isEqualWithoutConsideringStr(const MEDCouplingMesh *other, double prec) const throw(INTERP_KERNEL::Exception); virtual void checkFastEquivalWith(const MEDCouplingMesh *other, double prec) const throw(INTERP_KERNEL::Exception); virtual void copyTinyStringsFrom(const MEDCouplingMesh *other) throw(INTERP_KERNEL::Exception); virtual void copyTinyInfoFrom(const MEDCouplingMesh *other) throw(INTERP_KERNEL::Exception); virtual void checkConsistencyLight() const throw(INTERP_KERNEL::Exception); virtual void checkConsistency(double eps=1e-12) const throw(INTERP_KERNEL::Exception); virtual int getNumberOfCells() const throw(INTERP_KERNEL::Exception); virtual int getNumberOfNodes() const throw(INTERP_KERNEL::Exception); virtual int getSpaceDimension() const throw(INTERP_KERNEL::Exception); virtual int getMeshDimension() const throw(INTERP_KERNEL::Exception); virtual DataArrayDouble *getCoordinatesAndOwner() const throw(INTERP_KERNEL::Exception); virtual DataArrayDouble *computeCellCenterOfMass() const throw(INTERP_KERNEL::Exception); virtual DataArrayDouble *computeIsoBarycenterOfNodesPerCell() const throw(INTERP_KERNEL::Exception); virtual DataArrayInt *giveCellsWithType(INTERP_KERNEL::NormalizedCellType type) const throw(INTERP_KERNEL::Exception); virtual DataArrayInt *computeNbOfNodesPerCell() const throw(INTERP_KERNEL::Exception); virtual DataArrayInt *computeNbOfFacesPerCell() const throw(INTERP_KERNEL::Exception); virtual DataArrayInt *computeEffectiveNbOfNodesPerCell() const throw(INTERP_KERNEL::Exception); virtual MEDCouplingMesh *buildPartRange(int beginCellIds, int endCellIds, int stepCellIds) const throw(INTERP_KERNEL::Exception); virtual int getNumberOfCellsWithType(INTERP_KERNEL::NormalizedCellType type) const throw(INTERP_KERNEL::Exception); 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); 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 MEDCouplingFieldDouble *fillFromAnalytic(TypeOfField t, int nbOfComp, const std::string& func) const throw(INTERP_KERNEL::Exception); virtual MEDCouplingFieldDouble *fillFromAnalyticCompo(TypeOfField t, int nbOfComp, const std::string& func) const throw(INTERP_KERNEL::Exception); virtual MEDCouplingFieldDouble *fillFromAnalyticNamedCompo(TypeOfField t, int nbOfComp, const std::vector& varsOrder, const std::string& func) const throw(INTERP_KERNEL::Exception); virtual MEDCouplingFieldDouble *buildOrthogonalField() const throw(INTERP_KERNEL::Exception); virtual MEDCouplingUMesh *buildUnstructured() 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& tinyInfoD, const std::vector& tinyInfo, const DataArrayInt *a1, DataArrayDouble *a2, const std::vector& 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); static INTERP_KERNEL::NormalizedCellType GetCorrespondingPolyType(INTERP_KERNEL::NormalizedCellType type) throw(INTERP_KERNEL::Exception); static int GetNumberOfNodesOfGeometricType(INTERP_KERNEL::NormalizedCellType type) throw(INTERP_KERNEL::Exception); static int GetDimensionOfGeometricType(INTERP_KERNEL::NormalizedCellType type) throw(INTERP_KERNEL::Exception); static const char *GetReprOfGeometricType(INTERP_KERNEL::NormalizedCellType type) throw(INTERP_KERNEL::Exception); %extend { std::string __str__() const throw(INTERP_KERNEL::Exception) { return self->simpleRepr(); } PyObject *getTime() throw(INTERP_KERNEL::Exception) { int tmp1,tmp2; double tmp0=self->getTime(tmp1,tmp2); PyObject *res = PyList_New(3); PyList_SetItem(res,0,SWIG_From_double(tmp0)); PyList_SetItem(res,1,SWIG_From_int(tmp1)); PyList_SetItem(res,2,SWIG_From_int(tmp2)); return res; } DataArrayDouble *getDirectAccessOfCoordsArrIfInStructure() const throw(INTERP_KERNEL::Exception) { const DataArrayDouble *ret(self->getDirectAccessOfCoordsArrIfInStructure()); DataArrayDouble *ret2(const_cast(ret)); if(ret2) ret2->incrRef(); return ret2; } int getCellContainingPoint(PyObject *p, double eps) const throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int spaceDim=self->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingMesh::getCellContainingPoint : "; const double *pos=convertObjToPossibleCpp5_Safe(p,sw,val,a,aa,bb,msg,1,spaceDim,true); return self->getCellContainingPoint(pos,eps); } PyObject *getCellsContainingPoints(PyObject *p, int nbOfPoints, double eps) const throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int spaceDim=self->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingMesh::getCellsContainingPoint : "; const double *pos=convertObjToPossibleCpp5_Safe(p,sw,val,a,aa,bb,msg,nbOfPoints,spaceDim,true); MCAuto elts,eltsIndex; self->getCellsContainingPoints(pos,nbOfPoints,eps,elts,eltsIndex); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(elts.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(eltsIndex.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *getCellsContainingPointsLinearPartOnlyOnNonDynType(PyObject *p, int nbOfPoints, double eps) const throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int spaceDim=self->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingMesh::getCellsContainingPointsLinearPartOnlyOnNonDynType : "; const double *pos=convertObjToPossibleCpp5_Safe(p,sw,val,a,aa,bb,msg,nbOfPoints,spaceDim,true); MCAuto elts,eltsIndex; self->getCellsContainingPointsLinearPartOnlyOnNonDynType(pos,nbOfPoints,eps,elts,eltsIndex); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(elts.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(eltsIndex.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *getCellsContainingPoints(PyObject *p, double eps) const throw(INTERP_KERNEL::Exception) { auto getCellsContainingPointsFunc=[self](const double *a, int b,double c, MCAuto& d, MCAuto& e) { self->getCellsContainingPoints(a,b,c,d,e); }; return Mesh_getCellsContainingPointsLike(p,eps,self,getCellsContainingPointsFunc); } PyObject *getCellsContainingPointsLinearPartOnlyOnNonDynType(PyObject *p, double eps) const throw(INTERP_KERNEL::Exception) { auto getCellsContainingPointsFunc=[self](const double *a, int b,double c, MCAuto& d, MCAuto& e) { self->getCellsContainingPointsLinearPartOnlyOnNonDynType(a,b,c,d,e); }; return Mesh_getCellsContainingPointsLike(p,eps,self,getCellsContainingPointsFunc); } PyObject *getCellsContainingPoint(PyObject *p, double eps) const throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int spaceDim=self->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingUMesh::getCellsContainingPoint : "; const double *pos=convertObjToPossibleCpp5_Safe(p,sw,val,a,aa,bb,msg,1,spaceDim,true); std::vector elts; self->getCellsContainingPoint(pos,eps,elts); DataArrayInt *ret=DataArrayInt::New(); ret->alloc((int)elts.size(),1); std::copy(elts.begin(),elts.end(),ret->getPointer()); return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); } virtual PyObject *getReverseNodalConnectivity() const throw(INTERP_KERNEL::Exception) { MCAuto d0=DataArrayInt::New(); MCAuto d1=DataArrayInt::New(); self->getReverseNodalConnectivity(d0,d1); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(d0.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(d1.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } void renumberCells(PyObject *li, bool check=true) throw(INTERP_KERNEL::Exception) { int sw,sz(-1); int v0; std::vector v1; const int *ids(convertIntStarLikePyObjToCppIntStar(li,sw,sz,v0,v1)); self->renumberCells(ids,check); } PyObject *checkGeoEquivalWith(const MEDCouplingMesh *other, int levOfCheck, double prec) const throw(INTERP_KERNEL::Exception) { DataArrayInt *cellCor, *nodeCor; self->checkGeoEquivalWith(other,levOfCheck,prec,cellCor,nodeCor); PyObject *res = PyList_New(2); PyList_SetItem(res,0,SWIG_NewPointerObj(SWIG_as_voidptr(cellCor),SWIGTYPE_p_MEDCoupling__DataArrayInt, cellCor?SWIG_POINTER_OWN | 0:0 )); PyList_SetItem(res,1,SWIG_NewPointerObj(SWIG_as_voidptr(nodeCor),SWIGTYPE_p_MEDCoupling__DataArrayInt, nodeCor?SWIG_POINTER_OWN | 0:0 )); return res; } PyObject *checkDeepEquivalWith(const MEDCouplingMesh *other, int cellCompPol, double prec) const throw(INTERP_KERNEL::Exception) { DataArrayInt *cellCor=0,*nodeCor=0; self->checkDeepEquivalWith(other,cellCompPol,prec,cellCor,nodeCor); PyObject *res = PyList_New(2); PyList_SetItem(res,0,SWIG_NewPointerObj(SWIG_as_voidptr(cellCor),SWIGTYPE_p_MEDCoupling__DataArrayInt, cellCor?SWIG_POINTER_OWN | 0:0 )); PyList_SetItem(res,1,SWIG_NewPointerObj(SWIG_as_voidptr(nodeCor),SWIGTYPE_p_MEDCoupling__DataArrayInt, nodeCor?SWIG_POINTER_OWN | 0:0 )); return res; } DataArrayInt *checkDeepEquivalOnSameNodesWith(const MEDCouplingMesh *other, int cellCompPol, double prec) const throw(INTERP_KERNEL::Exception) { DataArrayInt *cellCor=0; self->checkDeepEquivalOnSameNodesWith(other,cellCompPol,prec,cellCor); return cellCor; } DataArrayInt *getCellIdsFullyIncludedInNodeIds(PyObject *li) const throw(INTERP_KERNEL::Exception) { void *da=0; int res1=SWIG_ConvertPtr(li,&da,SWIGTYPE_p_MEDCoupling__DataArrayInt, 0 | 0 ); if (!SWIG_IsOK(res1)) { int size; INTERP_KERNEL::AutoPtr tmp=convertPyToNewIntArr2(li,&size); return self->getCellIdsFullyIncludedInNodeIds(tmp,((const int *)tmp)+size); } else { DataArrayInt *da2=reinterpret_cast< DataArrayInt * >(da); if(!da2) throw INTERP_KERNEL::Exception("Not null DataArrayInt instance expected !"); da2->checkAllocated(); return self->getCellIdsFullyIncludedInNodeIds(da2->getConstPointer(),da2->getConstPointer()+da2->getNbOfElems()); } } PyObject *getNodeIdsOfCell(int cellId) const throw(INTERP_KERNEL::Exception) { std::vector conn; self->getNodeIdsOfCell(cellId,conn); return convertIntArrToPyList2(conn); } PyObject *getCoordinatesOfNode(int nodeId) const throw(INTERP_KERNEL::Exception) { std::vector coo; self->getCoordinatesOfNode(nodeId,coo); return convertDblArrToPyList2(coo); } void scale(PyObject *point, double factor) throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int spaceDim=self->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingPointSet::scale : "; const double *pointPtr=convertObjToPossibleCpp5_Safe(point,sw,val,a,aa,bb,msg,1,spaceDim,true); self->scale(pointPtr,factor); } PyObject *getBoundingBox() const throw(INTERP_KERNEL::Exception) { int spaceDim=self->getSpaceDimension(); INTERP_KERNEL::AutoPtr tmp=new double[2*spaceDim]; self->getBoundingBox(tmp); PyObject *ret=convertDblArrToPyListOfTuple(tmp,2,spaceDim); return ret; } PyObject *isEqualIfNotWhy(const MEDCouplingMesh *other, double prec) const throw(INTERP_KERNEL::Exception) { std::string ret1; bool ret0=self->isEqualIfNotWhy(other,prec,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; } PyObject *buildPart(PyObject *li) const throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); MEDCouplingMesh *ret=self->buildPart(tmp,tmp+szArr); if(sw==3)//DataArrayInt { void *argp; SWIG_ConvertPtr(li,&argp,SWIGTYPE_p_MEDCoupling__DataArrayInt,0|0); DataArrayInt *argpt=reinterpret_cast< MEDCoupling::DataArrayInt * >(argp); std::string name=argpt->getName(); if(!name.empty()) ret->setName(name.c_str()); } return convertMesh(ret, SWIG_POINTER_OWN | 0 ); } PyObject *buildPartAndReduceNodes(PyObject *li) const throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; DataArrayInt *arr=0; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); MEDCouplingMesh *ret=self->buildPartAndReduceNodes(tmp,tmp+szArr,arr); if(sw==3)//DataArrayInt { void *argp; SWIG_ConvertPtr(li,&argp,SWIGTYPE_p_MEDCoupling__DataArrayInt,0|0); DataArrayInt *argpt=reinterpret_cast< MEDCoupling::DataArrayInt * >(argp); std::string name=argpt->getName(); if(!name.empty()) ret->setName(name.c_str()); } // PyObject *res = PyList_New(2); PyObject *obj0=convertMesh(ret, SWIG_POINTER_OWN | 0 ); PyObject *obj1=SWIG_NewPointerObj(SWIG_as_voidptr(arr),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); PyList_SetItem(res,0,obj0); PyList_SetItem(res,1,obj1); return res; } PyObject *buildPartRangeAndReduceNodes(int beginCellIds, int endCellIds, int stepCellIds) const throw(INTERP_KERNEL::Exception) { int a,b,c; DataArrayInt *arr=0; MEDCouplingMesh *ret=self->buildPartRangeAndReduceNodes(beginCellIds,endCellIds,stepCellIds,a,b,c,arr); PyObject *res = PyTuple_New(2); PyObject *obj0=convertMesh(ret, SWIG_POINTER_OWN | 0 ); PyObject *obj1=0; if(arr) obj1=SWIG_NewPointerObj(SWIG_as_voidptr(arr),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); else obj1=PySlice_New(PyInt_FromLong(a),PyInt_FromLong(b),PyInt_FromLong(b)); PyTuple_SetItem(res,0,obj0); PyTuple_SetItem(res,1,obj1); return res; } PyObject *getDistributionOfTypes() const throw(INTERP_KERNEL::Exception) { std::vector vals=self->getDistributionOfTypes(); if(vals.size()%3!=0) throw INTERP_KERNEL::Exception("Internal Error detected in wrap python ! code returned by MEDCouplingMesh::getDistributionOfTypes is not so that %3==0 !"); PyObject *ret=PyList_New((int)vals.size()/3); for(int j=0;j<(int)vals.size()/3;j++) { PyObject *ret1=PyList_New(3); PyList_SetItem(ret1,0,SWIG_From_int(vals[3*j])); PyList_SetItem(ret1,1,SWIG_From_int(vals[3*j+1])); PyList_SetItem(ret1,2,SWIG_From_int(vals[3*j+2])); PyList_SetItem(ret,j,ret1); } return ret; } DataArrayInt *checkTypeConsistencyAndContig(PyObject *li, PyObject *li2) const throw(INTERP_KERNEL::Exception) { std::vector code; std::vector idsPerType; convertFromPyObjVectorOfObj(li2,SWIGTYPE_p_MEDCoupling__DataArrayInt,"DataArrayInt",idsPerType); convertPyToNewIntArr4(li,1,3,code); return self->checkTypeConsistencyAndContig(code,idsPerType); } PyObject *splitProfilePerType(const DataArrayInt *profile, bool smartPflKiller=true) const throw(INTERP_KERNEL::Exception) { std::vector code; std::vector idsInPflPerType; std::vector idsPerType; self->splitProfilePerType(profile,code,idsInPflPerType,idsPerType,smartPflKiller); PyObject *ret=PyTuple_New(3); // if(code.size()%3!=0) throw INTERP_KERNEL::Exception("Internal Error detected in wrap python ! code returned by MEDCouplingMesh::splitProfilePerType is not so that %3==0 !"); PyObject *ret0=PyList_New((int)code.size()/3); for(int j=0;j<(int)code.size()/3;j++) { PyObject *ret00=PyList_New(3); PyList_SetItem(ret00,0,SWIG_From_int(code[3*j])); PyList_SetItem(ret00,1,SWIG_From_int(code[3*j+1])); PyList_SetItem(ret00,2,SWIG_From_int(code[3*j+2])); PyList_SetItem(ret0,j,ret00); } PyTuple_SetItem(ret,0,ret0); // PyObject *ret1=PyList_New(idsInPflPerType.size()); for(std::size_t j=0;j bb; int sw; int spaceDim=self->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingPointSet::translate : "; const double *vectorPtr=convertObjToPossibleCpp5_Safe(vector,sw,val,a,aa,bb,msg,1,spaceDim,true); self->translate(vectorPtr); } void rotate(PyObject *center, double alpha) throw(INTERP_KERNEL::Exception) { const char msg[]="Python wrap of MEDCouplingPointSet::rotate : "; double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int spaceDim=self->getSpaceDimension(); const double *centerPtr=convertObjToPossibleCpp5_Safe(center,sw,val,a,aa,bb,msg,1,spaceDim,true); self->rotate(centerPtr,0,alpha); } void rotate(PyObject *center, PyObject *vector, double alpha) throw(INTERP_KERNEL::Exception) { const char msg[]="Python wrap of MEDCouplingPointSet::rotate : "; double val,val2; DataArrayDouble *a,*a2; DataArrayDoubleTuple *aa,*aa2; std::vector bb,bb2; int sw; int spaceDim=self->getSpaceDimension(); const double *centerPtr=convertObjToPossibleCpp5_Safe(center,sw,val,a,aa,bb,msg,1,spaceDim,true); const double *vectorPtr=convertObjToPossibleCpp5_Safe(vector,sw,val2,a2,aa2,bb2,msg,1,spaceDim,false);//vectorPtr can be null in case of space dim 2 self->rotate(centerPtr,vectorPtr,alpha); } PyObject *getAllGeoTypes() const throw(INTERP_KERNEL::Exception) { std::set result=self->getAllGeoTypes(); std::set::const_iterator iL=result.begin(); PyObject *res=PyList_New(result.size()); for(int i=0;iL!=result.end(); i++, iL++) PyList_SetItem(res,i,PyInt_FromLong(*iL)); return res; } virtual PyObject *getTinySerializationInformation() const throw(INTERP_KERNEL::Exception) { std::vector a0; std::vector a1; std::vector 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;iserialize(a0Tmp,a1Tmp); PyObject *ret(PyTuple_New(2)); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(a0Tmp),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(a1Tmp),SWIGTYPE_p_MEDCoupling__DataArrayDouble, SWIG_POINTER_OWN | 0 )); return ret; } void resizeForUnserialization(const std::vector& tinyInfo, DataArrayInt *a1, DataArrayDouble *a2) const throw(INTERP_KERNEL::Exception) { std::vector littleStrings; self->resizeForUnserialization(tinyInfo,a1,a2,littleStrings); } PyObject *__getstate__() const throw(INTERP_KERNEL::Exception) { PyObject *ret0(MEDCoupling_MEDCouplingMesh_getTinySerializationInformation(self)); PyObject *ret1(MEDCoupling_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 a0; std::vector a1; std::vector 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_MEDCoupling__DataArrayInt,0|0)); if(!SWIG_IsOK(status)) throw INTERP_KERNEL::Exception(MSG); b0=reinterpret_cast(argp); status=SWIG_ConvertPtr(b1py,&argp,SWIGTYPE_p_MEDCoupling__DataArrayDouble,0|0); if(!SWIG_IsOK(status)) throw INTERP_KERNEL::Exception(MSG); b1=reinterpret_cast(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) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCouplingMesh,"MEDCouplingMesh",tmp); return MEDCouplingMesh::MergeMeshes(tmp); } } }; } //== MEDCouplingMesh End %include "NormalizedGeometricTypes" %include "MEDCouplingNatureOfFieldEnum" // namespace MEDCoupling { class MEDCouplingNatureOfField { public: static const char *GetRepr(NatureOfField nat) throw(INTERP_KERNEL::Exception); static std::string GetReprNoThrow(NatureOfField nat); static std::string GetAllPossibilitiesStr(); }; } // the MEDCouplingTimeDiscretization classes are not swigged : in case the file can help // include "MEDCouplingTimeDiscretization.i" namespace MEDCoupling { class MEDCouplingGaussLocalization { public: MEDCouplingGaussLocalization(INTERP_KERNEL::NormalizedCellType type, const std::vector& refCoo, const std::vector& gsCoo, const std::vector& w) throw(INTERP_KERNEL::Exception); MEDCouplingGaussLocalization(INTERP_KERNEL::NormalizedCellType typ) throw(INTERP_KERNEL::Exception); INTERP_KERNEL::NormalizedCellType getType() const throw(INTERP_KERNEL::Exception); void setType(INTERP_KERNEL::NormalizedCellType typ) throw(INTERP_KERNEL::Exception); int getNumberOfGaussPt() const throw(INTERP_KERNEL::Exception); int getDimension() const throw(INTERP_KERNEL::Exception); int getNumberOfPtsInRefCell() const throw(INTERP_KERNEL::Exception); std::string getStringRepr() const throw(INTERP_KERNEL::Exception); void checkConsistencyLight() const throw(INTERP_KERNEL::Exception); bool isEqual(const MEDCouplingGaussLocalization& other, double eps) const throw(INTERP_KERNEL::Exception); // const std::vector& getRefCoords() const throw(INTERP_KERNEL::Exception); double getRefCoord(int ptIdInCell, int comp) const throw(INTERP_KERNEL::Exception); const std::vector& getGaussCoords() const throw(INTERP_KERNEL::Exception); double getGaussCoord(int gaussPtIdInCell, int comp) const throw(INTERP_KERNEL::Exception); const std::vector& getWeights() const throw(INTERP_KERNEL::Exception); double getWeight(int gaussPtIdInCell, double newVal) const throw(INTERP_KERNEL::Exception); void setRefCoord(int ptIdInCell, int comp, double newVal) throw(INTERP_KERNEL::Exception); void setGaussCoord(int gaussPtIdInCell, int comp, double newVal) throw(INTERP_KERNEL::Exception); void setWeight(int gaussPtIdInCell, double newVal) throw(INTERP_KERNEL::Exception); void setRefCoords(const std::vector& refCoo) throw(INTERP_KERNEL::Exception); void setGaussCoords(const std::vector& gsCoo) throw(INTERP_KERNEL::Exception); void setWeights(const std::vector& w) throw(INTERP_KERNEL::Exception); // static bool AreAlmostEqual(const std::vector& v1, const std::vector& v2, double eps); // %extend { DataArrayDouble *localizePtsInRefCooForEachCell(const DataArrayDouble *ptsInRefCoo, const MEDCouplingUMesh *mesh) const throw(INTERP_KERNEL::Exception) { MCAuto ret(self->localizePtsInRefCooForEachCell(ptsInRefCoo,mesh)); return ret.retn(); } MEDCouplingUMesh *buildRefCell() const throw(INTERP_KERNEL::Exception) { MCAuto ret(self->buildRefCell()); return ret.retn(); } } }; class MEDCouplingSkyLineArray { public: static MEDCouplingSkyLineArray *BuildFromPolyhedronConn( const DataArrayInt* c, const DataArrayInt* cI ) throw(INTERP_KERNEL::Exception); void set( DataArrayInt* index, DataArrayInt* value ); void set3( DataArrayInt* superIndex, DataArrayInt* index, DataArrayInt* value ); int getSuperNumberOf() const; int getNumberOf() const; int getLength() const; void deletePack(const int i, const int j) throw(INTERP_KERNEL::Exception); void deleteSimplePack(const int i) throw(INTERP_KERNEL::Exception); void deleteSimplePacks(const DataArrayInt* idx) throw(INTERP_KERNEL::Exception); %extend { MEDCouplingSkyLineArray() throw(INTERP_KERNEL::Exception) { return MEDCouplingSkyLineArray::New(); } MEDCouplingSkyLineArray( const std::vector& index, const std::vector& value) throw(INTERP_KERNEL::Exception) { return MEDCouplingSkyLineArray::New(index, value); } MEDCouplingSkyLineArray( DataArrayInt* index, DataArrayInt* value ) throw(INTERP_KERNEL::Exception) { return MEDCouplingSkyLineArray::New(index, value); } MEDCouplingSkyLineArray( const MEDCouplingSkyLineArray & other ) throw(INTERP_KERNEL::Exception) { return MEDCouplingSkyLineArray::New(other); } std::string __str__() const throw(INTERP_KERNEL::Exception) { return self->simpleRepr(); } DataArrayInt *getSuperIndexArray() const { DataArrayInt *ret(self->getSuperIndexArray()); if(ret) ret->incrRef(); return ret; } DataArrayInt *getIndexArray() const { DataArrayInt *ret(self->getIndexArray()); if(ret) ret->incrRef(); return ret; } DataArrayInt *getValuesArray() const { DataArrayInt *ret(self->getValuesArray()); if(ret) ret->incrRef(); return ret; } PyObject *getSimplePackSafe(int absolutePackId) const throw(INTERP_KERNEL::Exception) { std::vector ret; self->getSimplePackSafe(absolutePackId,ret); return convertIntArrToPyList2(ret); } PyObject *findPackIds(PyObject *superPackIndices, PyObject *pack) const throw(INTERP_KERNEL::Exception) { std::vector vpack, vspIdx, out; convertPyToNewIntArr3(superPackIndices,vspIdx); convertPyToNewIntArr3(pack,vpack); self->findPackIds(vspIdx, vpack.data(), vpack.data()+vpack.size(), out); return convertIntArrToPyList2(out); } void pushBackPack(const int i, PyObject *pack) throw(INTERP_KERNEL::Exception) { std::vector vpack; convertPyToNewIntArr3(pack,vpack); self->pushBackPack(i,vpack.data(), vpack.data()+vpack.size()); } void replaceSimplePack(const int idx, PyObject *pack) throw(INTERP_KERNEL::Exception) { std::vector vpack; convertPyToNewIntArr3(pack,vpack); self->replaceSimplePack(idx, vpack.data(), vpack.data()+vpack.size()); } void replaceSimplePacks(const DataArrayInt* idx, PyObject *listePacks) throw(INTERP_KERNEL::Exception) { std::vector packs; convertFromPyObjVectorOfObj(listePacks,SWIGTYPE_p_MEDCoupling__DataArrayInt,"DataArrayInt",packs); self->replaceSimplePacks(idx, packs); } void replacePack(const int superIdx, const int idx, PyObject *pack) throw(INTERP_KERNEL::Exception) { std::vector vpack; convertPyToNewIntArr3(pack,vpack); self->replacePack(superIdx, idx, vpack.data(), vpack.data()+vpack.size()); } PyObject *convertToPolyhedronConn() const throw(INTERP_KERNEL::Exception) { MCAuto d0=DataArrayInt::New(); MCAuto d1=DataArrayInt::New(); self->convertToPolyhedronConn(d0,d1); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(d0.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(d1.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } } }; } %include "MEDCouplingFieldDiscretization.i" //== MEDCouplingPointSet namespace MEDCoupling { class MEDCouplingPointSet : public MEDCoupling::MEDCouplingMesh { public: void setCoords(const DataArrayDouble *coords) throw(INTERP_KERNEL::Exception); DataArrayDouble *getCoordinatesAndOwner() const throw(INTERP_KERNEL::Exception); bool areCoordsEqual(const MEDCouplingPointSet& other, double prec) const throw(INTERP_KERNEL::Exception); void zipCoords() throw(INTERP_KERNEL::Exception); double getCaracteristicDimension() const throw(INTERP_KERNEL::Exception); void recenterForMaxPrecision(double eps) throw(INTERP_KERNEL::Exception); void changeSpaceDimension(int newSpaceDim, double dftVal=0.) throw(INTERP_KERNEL::Exception); void tryToShareSameCoords(const MEDCouplingPointSet& other, double epsilon) throw(INTERP_KERNEL::Exception); virtual void shallowCopyConnectivityFrom(const MEDCouplingPointSet *other) throw(INTERP_KERNEL::Exception); virtual MEDCouplingPointSet *buildPartOfMySelfSlice(int start, int end, int step) const throw(INTERP_KERNEL::Exception); virtual void tryToShareSameCoordsPermute(const MEDCouplingPointSet& other, double epsilon) throw(INTERP_KERNEL::Exception); 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 DataArrayInt *zipCoordsTraducer() throw(INTERP_KERNEL::Exception); virtual DataArrayInt *findBoundaryNodes() const; virtual DataArrayInt *zipConnectivityTraducer(int compType, int startCellId=0) throw(INTERP_KERNEL::Exception); virtual MEDCouplingPointSet *mergeMyselfWithOnSameCoords(const MEDCouplingPointSet *other) const throw(INTERP_KERNEL::Exception); virtual void checkFullyDefined() const throw(INTERP_KERNEL::Exception); virtual bool isEmptyMesh(const std::vector& tinyInfo) const throw(INTERP_KERNEL::Exception); virtual MEDCouplingPointSet *deepCopyConnectivityOnly() 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); virtual void invertOrientationOfAllCells() throw(INTERP_KERNEL::Exception); %extend { std::string __str__() const throw(INTERP_KERNEL::Exception) { return self->simpleRepr(); } PyObject *buildNewNumberingFromCommonNodesFormat(const DataArrayInt *comm, const DataArrayInt *commIndex) const throw(INTERP_KERNEL::Exception) { int newNbOfNodes; DataArrayInt *ret0=self->buildNewNumberingFromCommonNodesFormat(comm,commIndex,newNbOfNodes); PyObject *res = PyList_New(2); PyList_SetItem(res,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyList_SetItem(res,1,SWIG_From_int(newNbOfNodes)); return res; } PyObject *findCommonNodes(double prec, int limitTupleId=-1) const throw(INTERP_KERNEL::Exception) { DataArrayInt *comm, *commIndex; self->findCommonNodes(prec,limitTupleId,comm,commIndex); PyObject *res = PyList_New(2); PyList_SetItem(res,0,SWIG_NewPointerObj(SWIG_as_voidptr(comm),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyList_SetItem(res,1,SWIG_NewPointerObj(SWIG_as_voidptr(commIndex),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return res; } PyObject *getCoords() throw(INTERP_KERNEL::Exception) { DataArrayDouble *ret1=self->getCoords(); if (ret1) ret1->incrRef(); return SWIG_NewPointerObj((void*)ret1,SWIGTYPE_p_MEDCoupling__DataArrayDouble,SWIG_POINTER_OWN | 0); } PyObject *buildPartOfMySelf(PyObject *li, bool keepCoords=true) const throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); MEDCouplingPointSet *ret=self->buildPartOfMySelf(tmp,tmp+szArr,keepCoords); if(sw==3)//DataArrayInt { void *argp; SWIG_ConvertPtr(li,&argp,SWIGTYPE_p_MEDCoupling__DataArrayInt,0|0); DataArrayInt *argpt=reinterpret_cast< MEDCoupling::DataArrayInt * >(argp); std::string name=argpt->getName(); if(!name.empty()) ret->setName(name.c_str()); } return convertMesh(ret, SWIG_POINTER_OWN | 0 ); } PyObject *buildPartOfMySelfNode(PyObject *li, bool fullyIn) const throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); MEDCouplingPointSet *ret=self->buildPartOfMySelfNode(tmp,tmp+szArr,fullyIn); if(sw==3)//DataArrayInt { void *argp; SWIG_ConvertPtr(li,&argp,SWIGTYPE_p_MEDCoupling__DataArrayInt,0|0); DataArrayInt *argpt=reinterpret_cast< MEDCoupling::DataArrayInt * >(argp); std::string name=argpt->getName(); if(!name.empty()) ret->setName(name.c_str()); } return convertMesh(ret, SWIG_POINTER_OWN | 0 ); } virtual PyObject *buildPartOfMySelfKeepCoords(PyObject *li) const throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); MEDCouplingPointSet *ret=self->buildPartOfMySelfKeepCoords(tmp,tmp+szArr); if(sw==3)//DataArrayInt { void *argp; SWIG_ConvertPtr(li,&argp,SWIGTYPE_p_MEDCoupling__DataArrayInt,0|0); DataArrayInt *argpt=reinterpret_cast< MEDCoupling::DataArrayInt * >(argp); std::string name=argpt->getName(); if(!name.empty()) ret->setName(name.c_str()); } return convertMesh(ret, SWIG_POINTER_OWN | 0 ); } virtual PyObject *buildPartOfMySelfKeepCoordsSlice(int start, int end, int step) const throw(INTERP_KERNEL::Exception) { MEDCouplingPointSet *ret=self->buildPartOfMySelfKeepCoordsSlice(start,end,step); return convertMesh(ret, SWIG_POINTER_OWN | 0 ); } PyObject *buildFacePartOfMySelfNode(PyObject *li, bool fullyIn) const throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); MEDCouplingPointSet *ret=self->buildFacePartOfMySelfNode(tmp,tmp+szArr,fullyIn); if(sw==3)//DataArrayInt { void *argp; SWIG_ConvertPtr(li,&argp,SWIGTYPE_p_MEDCoupling__DataArrayInt,0|0); DataArrayInt *argpt=reinterpret_cast< MEDCoupling::DataArrayInt * >(argp); std::string name=argpt->getName(); if(!name.empty()) ret->setName(name.c_str()); } return convertMesh(ret, SWIG_POINTER_OWN | 0 ); } void renumberNodes(PyObject *li, int newNbOfNodes) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); self->renumberNodes(tmp,newNbOfNodes); } void renumberNodesCenter(PyObject *li, int newNbOfNodes) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); self->renumberNodesCenter(tmp,newNbOfNodes); } PyObject *findNodesOnLine(PyObject *pt, PyObject *vec, double eps) const throw(INTERP_KERNEL::Exception) { int spaceDim=self->getSpaceDimension(); double val,val2; DataArrayDouble *a,*a2; DataArrayDoubleTuple *aa,*aa2; std::vector bb,bb2; int sw; const char msg[]="Python wrap of MEDCouplingPointSet::findNodesOnLine : 1st parameter for point."; const char msg2[]="Python wrap of MEDCouplingPointSet::findNodesOnLine : 2nd parameter for vector."; const double *p=convertObjToPossibleCpp5_Safe(pt,sw,val,a,aa,bb,msg,1,spaceDim,true); const double *v=convertObjToPossibleCpp5_Safe(vec,sw,val2,a2,aa2,bb2,msg2,1,spaceDim,true); std::vector nodes; self->findNodesOnLine(p,v,eps,nodes); DataArrayInt *ret=DataArrayInt::New(); ret->alloc((int)nodes.size(),1); std::copy(nodes.begin(),nodes.end(),ret->getPointer()); return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); } PyObject *findNodesOnPlane(PyObject *pt, PyObject *vec, double eps) const throw(INTERP_KERNEL::Exception) { int spaceDim=self->getSpaceDimension(); double val,val2; DataArrayDouble *a,*a2; DataArrayDoubleTuple *aa,*aa2; std::vector bb,bb2; int sw; const char msg[]="Python wrap of MEDCouplingPointSet::findNodesOnPlane : 1st parameter for point."; const char msg2[]="Python wrap of MEDCouplingPointSet::findNodesOnPlane : 2nd parameter for vector."; const double *p=convertObjToPossibleCpp5_Safe(pt,sw,val,a,aa,bb,msg,1,spaceDim,true); const double *v=convertObjToPossibleCpp5_Safe(vec,sw,val2,a2,aa2,bb2,msg2,1,spaceDim,true); std::vector nodes; self->findNodesOnPlane(p,v,eps,nodes); DataArrayInt *ret=DataArrayInt::New(); ret->alloc((int)nodes.size(),1); std::copy(nodes.begin(),nodes.end(),ret->getPointer()); return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); } PyObject *getNodeIdsNearPoint(PyObject *pt, double eps) const throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int spaceDim=self->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingPointSet::getNodeIdsNearPoint : "; const double *pos=convertObjToPossibleCpp5_Safe(pt,sw,val,a,aa,bb,msg,1,spaceDim,true); DataArrayInt *ret=self->getNodeIdsNearPoint(pos,eps); return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); } PyObject *getNodeIdsNearPoints(PyObject *pt, int nbOfPoints, double eps) const throw(INTERP_KERNEL::Exception) { DataArrayInt *c=0,*cI=0; // double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int spaceDim=self->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingPointSet::getNodeIdsNearPoints : "; const double *pos=convertObjToPossibleCpp5_Safe(pt,sw,val,a,aa,bb,msg,nbOfPoints,spaceDim,true); self->getNodeIdsNearPoints(pos,nbOfPoints,eps,c,cI); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(c),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(cI),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *getNodeIdsNearPoints(PyObject *pt, double eps) const throw(INTERP_KERNEL::Exception) { DataArrayInt *c=0,*cI=0; int spaceDim=self->getSpaceDimension(); double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int nbOfTuples=-1; const double *ptPtr=convertObjToPossibleCpp5_Safe2(pt,sw,val,a,aa,bb,"Python wrap of MEDCouplingUMesh::getNodeIdsNearPoints",spaceDim,true,nbOfTuples); self->getNodeIdsNearPoints(ptPtr,nbOfTuples,eps,c,cI); // PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(c),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(cI),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *getCellsInBoundingBox(PyObject *bbox, double eps) const throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int spaceDim=self->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingPointSet::getCellsInBoundingBox : "; const double *tmp=convertObjToPossibleCpp5_Safe(bbox,sw,val,a,aa,bb,msg,spaceDim,2,true); // DataArrayInt *elems=self->getCellsInBoundingBox(tmp,eps); return SWIG_NewPointerObj(SWIG_as_voidptr(elems),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); } void duplicateNodesInCoords(PyObject *li) throw(INTERP_KERNEL::Exception) { int sw; int singleVal; std::vector multiVal; std::pair > slic; MEDCoupling::DataArrayInt *daIntTyypp=0; convertIntStarOrSliceLikePyObjToCpp(li,self->getNumberOfNodes(),sw,singleVal,multiVal,slic,daIntTyypp); switch(sw) { case 1: return self->duplicateNodesInCoords(&singleVal,&singleVal+1); case 2: return self->duplicateNodesInCoords(&multiVal[0],&multiVal[0]+multiVal.size()); case 4: return self->duplicateNodesInCoords(daIntTyypp->begin(),daIntTyypp->end()); default: throw INTERP_KERNEL::Exception("MEDCouplingPointSet::duplicateNodesInCoords : unrecognized type entered, expected list of int, tuple of int or DataArrayInt !"); } } virtual PyObject *findCommonCells(int compType, int startCellId=0) const throw(INTERP_KERNEL::Exception) { DataArrayInt *v0(nullptr),*v1(nullptr); self->findCommonCells(compType,startCellId,v0,v1); PyObject *res = PyList_New(2); PyList_SetItem(res,0,SWIG_NewPointerObj(SWIG_as_voidptr(v0),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyList_SetItem(res,1,SWIG_NewPointerObj(SWIG_as_voidptr(v1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return res; } virtual void renumberNodesInConn(PyObject *li) throw(INTERP_KERNEL::Exception) { void *da(nullptr); { int res1(SWIG_ConvertPtr(li,&da,SWIGTYPE_p_MEDCoupling__MapII, 0 | 0 )); if(SWIG_IsOK(res1)) { MapII *da2(reinterpret_cast(da)); self->renumberNodesInConn(da2->data()); return ; } } int res1(SWIG_ConvertPtr(li,&da,SWIGTYPE_p_MEDCoupling__DataArrayInt, 0 | 0 )); if (!SWIG_IsOK(res1)) { int size; INTERP_KERNEL::AutoPtr tmp=convertPyToNewIntArr2(li,&size); self->renumberNodesInConn(tmp); } else { DataArrayInt *da2(reinterpret_cast< DataArrayInt * >(da)); if(!da2) throw INTERP_KERNEL::Exception("Not null DataArrayInt instance expected !"); da2->checkAllocated(); self->renumberNodesInConn(da2->getConstPointer()); } } virtual PyObject *getNodeIdsInUse() const throw(INTERP_KERNEL::Exception) { int ret1=-1; DataArrayInt *ret0=self->getNodeIdsInUse(ret1); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,PyInt_FromLong(ret1)); return ret; } virtual DataArrayInt *fillCellIdsToKeepFromNodeIds(PyObject *li, bool fullyIn) const { DataArrayInt *ret(nullptr); // int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); self->fillCellIdsToKeepFromNodeIds(tmp,tmp+szArr,fullyIn,ret); return ret; } virtual PyObject *mergeNodes(double precision) throw(INTERP_KERNEL::Exception) { bool ret1; int ret2; DataArrayInt *ret0=self->mergeNodes(precision,ret1,ret2); PyObject *res = PyList_New(3); PyList_SetItem(res,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyList_SetItem(res,1,SWIG_From_bool(ret1)); PyList_SetItem(res,2,SWIG_From_int(ret2)); return res; } virtual PyObject *mergeNodesCenter(double precision) throw(INTERP_KERNEL::Exception) { bool ret1; int ret2; DataArrayInt *ret0=self->mergeNodesCenter(precision,ret1,ret2); PyObject *res = PyList_New(3); PyList_SetItem(res,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyList_SetItem(res,1,SWIG_From_bool(ret1)); PyList_SetItem(res,2,SWIG_From_int(ret2)); return res; } DataArrayInt *getCellIdsLyingOnNodes(PyObject *li, bool fullyIn) const throw(INTERP_KERNEL::Exception) { void *da=0; int res1=SWIG_ConvertPtr(li,&da,SWIGTYPE_p_MEDCoupling__DataArrayInt, 0 | 0 ); if (!SWIG_IsOK(res1)) { int size; INTERP_KERNEL::AutoPtr tmp=convertPyToNewIntArr2(li,&size); return self->getCellIdsLyingOnNodes(tmp,((const int *)tmp)+size,fullyIn); } else { DataArrayInt *da2=reinterpret_cast< DataArrayInt * >(da); if(!da2) throw INTERP_KERNEL::Exception("Not null DataArrayInt instance expected !"); da2->checkAllocated(); return self->getCellIdsLyingOnNodes(da2->getConstPointer(),da2->getConstPointer()+da2->getNbOfElems(),fullyIn); } } MEDCouplingPointSet *__getitem__(PyObject *listOrDataArrI) throw(INTERP_KERNEL::Exception) { int sw; int singleVal; std::vector multiVal; std::pair > slic; MEDCoupling::DataArrayInt *daIntTyypp=0; int nbc=self->getNumberOfCells(); convertIntStarOrSliceLikePyObjToCpp(listOrDataArrI,nbc,sw,singleVal,multiVal,slic,daIntTyypp); switch(sw) { case 1: { if(singleVal>=nbc) { std::ostringstream oss; oss << "Requesting for cell id " << singleVal << " having only " << nbc << " cells !"; throw INTERP_KERNEL::Exception(oss.str().c_str()); } if(singleVal>=0) return self->buildPartOfMySelf(&singleVal,&singleVal+1,true); else { if(nbc+singleVal>0) { int tmp=nbc+singleVal; return self->buildPartOfMySelf(&tmp,&tmp+1,true); } else { std::ostringstream oss; oss << "Requesting for cell id " << singleVal << " having only " << nbc << " cells !"; throw INTERP_KERNEL::Exception(oss.str().c_str()); } } } case 2: { return static_cast(self->buildPartOfMySelf(&multiVal[0],&multiVal[0]+multiVal.size(),true)); } case 3: { return self->buildPartOfMySelfSlice(slic.first,slic.second.first,slic.second.second,true); } case 4: { if(!daIntTyypp) throw INTERP_KERNEL::Exception("MEDCouplingUMesh::__getitem__ : null instance has been given in input !"); daIntTyypp->checkAllocated(); return self->buildPartOfMySelf(daIntTyypp->begin(),daIntTyypp->end(),true); } default: throw INTERP_KERNEL::Exception("MEDCouplingUMesh::__getitem__ : unrecognized type in input ! Possibilities are : int, list or tuple of int DataArrayInt instance !"); } } static void Rotate2DAlg(PyObject *center, double angle, int nbNodes, PyObject *coords) throw(INTERP_KERNEL::Exception) { int sz; INTERP_KERNEL::AutoCPtr c=convertPyToNewDblArr2(center,&sz); INTERP_KERNEL::AutoCPtr coo=convertPyToNewDblArr2(coords,&sz); MEDCoupling::DataArrayDouble::Rotate2DAlg(c,angle,nbNodes,coo,coo); for(int i=0;i c=convertPyToNewDblArr2(center,&sz); int sw,nbNodes=0; double val0; MEDCoupling::DataArrayDouble *val1=0; MEDCoupling::DataArrayDoubleTuple *val2=0; std::vector val3; const double *coo=convertObjToPossibleCpp5_Safe2(coords,sw,val0,val1,val2,val3, "Rotate2DAlg",2,true,nbNodes); if(sw!=2 && sw!=3) throw INTERP_KERNEL::Exception("Invalid call to MEDCouplingPointSet::Rotate2DAlg : try another overload method !"); MEDCoupling::DataArrayDouble::Rotate2DAlg(c,angle,nbNodes,coo,const_cast(coo)); } static void Rotate3DAlg(PyObject *center, PyObject *vect, double angle, int nbNodes, PyObject *coords) throw(INTERP_KERNEL::Exception) { int sz,sz2; INTERP_KERNEL::AutoCPtr c=convertPyToNewDblArr2(center,&sz); INTERP_KERNEL::AutoCPtr coo=convertPyToNewDblArr2(coords,&sz); INTERP_KERNEL::AutoCPtr v=convertPyToNewDblArr2(vect,&sz2); MEDCoupling::DataArrayDouble::Rotate3DAlg(c,v,angle,nbNodes,coo,coo); for(int i=0;i c=convertPyToNewDblArr2(center,&sz); int sw,nbNodes=0; double val0; MEDCoupling::DataArrayDouble *val1=0; MEDCoupling::DataArrayDoubleTuple *val2=0; std::vector val3; const double *coo=convertObjToPossibleCpp5_Safe2(coords,sw,val0,val1,val2,val3, "Rotate3DAlg",3,true,nbNodes); if(sw!=2 && sw!=3) throw INTERP_KERNEL::Exception("Invalid call to MEDCouplingPointSet::Rotate3DAlg : try another overload method !"); INTERP_KERNEL::AutoCPtr v=convertPyToNewDblArr2(vect,&sz2); MEDCoupling::DataArrayDouble::Rotate3DAlg(c,v,angle,nbNodes,coo,const_cast(coo)); } } }; //== MEDCouplingPointSet End class MEDCouplingUMeshCell { public: INTERP_KERNEL::NormalizedCellType getType() const; %extend { std::string __str__() const throw(INTERP_KERNEL::Exception) { return self->repr(); } PyObject *getAllConn() const throw(INTERP_KERNEL::Exception) { int ret2; const int *r=self->getAllConn(ret2); PyObject *ret=PyTuple_New(ret2); for(int i=0;inextt(); if(ret) return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__MEDCouplingUMeshCell,0|0); else { PyErr_SetString(PyExc_StopIteration,"No more data."); return 0; } } } }; class MEDCouplingUMeshCellByTypeIterator { public: ~MEDCouplingUMeshCellByTypeIterator(); %extend { PyObject *next() { MEDCouplingUMeshCellEntry *ret=self->nextt(); if(ret) return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__MEDCouplingUMeshCellEntry,SWIG_POINTER_OWN | 0); else { PyErr_SetString(PyExc_StopIteration,"No more data."); return 0; } } } }; class MEDCouplingUMeshCellByTypeEntry { public: ~MEDCouplingUMeshCellByTypeEntry(); %extend { MEDCouplingUMeshCellByTypeIterator *__iter__() { return self->iterator(); } } }; class MEDCouplingUMeshCellEntry { public: INTERP_KERNEL::NormalizedCellType getType() const; int getNumberOfElems() const; %extend { MEDCouplingUMeshCellIterator *__iter__() { return self->iterator(); } } }; //== MEDCouplingUMesh class MEDCouplingUMesh : public MEDCoupling::MEDCouplingPointSet { public: static MEDCouplingUMesh *New() throw(INTERP_KERNEL::Exception); static MEDCouplingUMesh *New(const char *meshName, int meshDim) throw(INTERP_KERNEL::Exception); void checkConsistencyLight() const throw(INTERP_KERNEL::Exception); void setMeshDimension(int meshDim) throw(INTERP_KERNEL::Exception); void allocateCells(int nbOfCells=0) throw(INTERP_KERNEL::Exception); void finishInsertingCells() throw(INTERP_KERNEL::Exception); MEDCouplingUMeshCellByTypeEntry *cellsByType() throw(INTERP_KERNEL::Exception); void setConnectivity(DataArrayInt *conn, DataArrayInt *connIndex, bool isComputingTypes=true) throw(INTERP_KERNEL::Exception); INTERP_KERNEL::NormalizedCellType getTypeOfCell(int cellId) const throw(INTERP_KERNEL::Exception); void setPartOfMySelfSlice(int start, int end, int step, const MEDCouplingUMesh& otherOnSameCoordsThanThis) throw(INTERP_KERNEL::Exception); int getNodalConnectivityArrayLen() const throw(INTERP_KERNEL::Exception); void computeTypes() 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 *conformize3D(double eps) throw(INTERP_KERNEL::Exception); DataArrayInt *colinearize2D(double eps) throw(INTERP_KERNEL::Exception); DataArrayInt *colinearizeKeepingConform2D(double eps) throw(INTERP_KERNEL::Exception); void shiftNodeNumbersInConn(int delta) throw(INTERP_KERNEL::Exception); std::vector getQuadraticStatus() const throw(INTERP_KERNEL::Exception); DataArrayInt *findCellIdsOnBoundary() const throw(INTERP_KERNEL::Exception); MEDCouplingUMesh *computeSkin() const throw(INTERP_KERNEL::Exception); bool checkConsecutiveCellTypes() const throw(INTERP_KERNEL::Exception); bool checkConsecutiveCellTypesForMEDFileFrmt() const throw(INTERP_KERNEL::Exception); DataArrayInt *rearrange2ConsecutiveCellTypes() 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); 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); MEDCouplingUMesh *explodeMeshIntoMicroEdges(DataArrayInt *desc, DataArrayInt *descIndx, DataArrayInt *revDesc, DataArrayInt *revDescIndx) const throw(INTERP_KERNEL::Exception); void orientCorrectlyPolyhedrons() throw(INTERP_KERNEL::Exception); bool isPresenceOfQuadratic() const throw(INTERP_KERNEL::Exception); bool isFullyQuadratic() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *buildDirectionVectorField() const throw(INTERP_KERNEL::Exception); bool isContiguous1D() const throw(INTERP_KERNEL::Exception); void tessellate2D(double eps) throw(INTERP_KERNEL::Exception); void convertQuadraticCellsToLinear() throw(INTERP_KERNEL::Exception); DataArrayInt *convertLinearCellsToQuadratic(int conversionType=0) throw(INTERP_KERNEL::Exception); void convertDegeneratedCells() throw(INTERP_KERNEL::Exception); DataArrayInt *convertDegeneratedCellsAndRemoveFlatOnes() throw(INTERP_KERNEL::Exception); bool removeDegenerated1DCells() throw(INTERP_KERNEL::Exception); bool areOnlySimplexCells() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *getEdgeRatioField() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *getAspectRatioField() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *getWarpField() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *getSkewField() const throw(INTERP_KERNEL::Exception); DataArrayDouble *computePlaneEquationOf3DFaces() const throw(INTERP_KERNEL::Exception); DataArrayInt *convexEnvelop2D() throw(INTERP_KERNEL::Exception); std::string cppRepr() const throw(INTERP_KERNEL::Exception); DataArrayInt *findAndCorrectBadOriented3DExtrudedCells() throw(INTERP_KERNEL::Exception); DataArrayInt *findAndCorrectBadOriented3DCells() throw(INTERP_KERNEL::Exception); MEDCoupling::MEDCoupling1GTUMesh *convertIntoSingleGeoTypeMesh() const throw(INTERP_KERNEL::Exception); MEDCouplingSkyLineArray *generateGraph() 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); 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); static DataArrayInt *ComputeSpreadZoneGradually(const DataArrayInt *arrIn, const DataArrayInt *arrIndxIn) throw(INTERP_KERNEL::Exception); static DataArrayInt *ComputeRangesFromTypeDistribution(const std::vector& code) throw(INTERP_KERNEL::Exception); %extend { MEDCouplingUMesh() throw(INTERP_KERNEL::Exception) { return MEDCouplingUMesh::New(); } MEDCouplingUMesh(const char *meshName, int meshDim) throw(INTERP_KERNEL::Exception) { return MEDCouplingUMesh::New(meshName,meshDim); } 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(); } MEDCouplingUMeshCellIterator *__iter__() throw(INTERP_KERNEL::Exception) { return self->cellIterator(); } static MEDCouplingUMesh *Build1DMeshFromCoords(DataArrayDouble *da) throw(INTERP_KERNEL::Exception) { MCAuto ret(MEDCouplingUMesh::Build1DMeshFromCoords(da)); return ret.retn(); } PyObject *getAllGeoTypesSorted() const throw(INTERP_KERNEL::Exception) { std::vector result=self->getAllGeoTypesSorted(); std::vector::const_iterator iL=result.begin(); PyObject *res=PyList_New(result.size()); for(int i=0;iL!=result.end(); i++, iL++) PyList_SetItem(res,i,PyInt_FromLong(*iL)); return res; } void setPartOfMySelf(PyObject *li, const MEDCouplingUMesh& otherOnSameCoordsThanThis) throw(INTERP_KERNEL::Exception) { int sw; int singleVal; std::vector multiVal; std::pair > slic; MEDCoupling::DataArrayInt *daIntTyypp=0; int nbc=self->getNumberOfCells(); convertIntStarOrSliceLikePyObjToCpp(li,nbc,sw,singleVal,multiVal,slic,daIntTyypp); switch(sw) { case 1: { if(singleVal>=nbc) { std::ostringstream oss; oss << "Requesting for cell id " << singleVal << " having only " << nbc << " cells !"; throw INTERP_KERNEL::Exception(oss.str().c_str()); } if(singleVal>=0) { self->setPartOfMySelf(&singleVal,&singleVal+1,otherOnSameCoordsThanThis); break; } else { if(nbc+singleVal>0) { int tmp=nbc+singleVal; self->setPartOfMySelf(&tmp,&tmp+1,otherOnSameCoordsThanThis); break; } else { std::ostringstream oss; oss << "Requesting for cell id " << singleVal << " having only " << nbc << " cells !"; throw INTERP_KERNEL::Exception(oss.str().c_str()); } } } case 2: { self->setPartOfMySelf(&multiVal[0],&multiVal[0]+multiVal.size(),otherOnSameCoordsThanThis); break; } case 4: { if(!daIntTyypp) throw INTERP_KERNEL::Exception("MEDCouplingUMesh::setPartOfMySelf : null instance has been given in input !"); daIntTyypp->checkAllocated(); self->setPartOfMySelf(daIntTyypp->begin(),daIntTyypp->end(),otherOnSameCoordsThanThis); break; } default: throw INTERP_KERNEL::Exception("MEDCouplingUMesh::setPartOfMySelf : unrecognized type in input ! Possibilities are : int, list or tuple of int DataArrayInt instance !"); } } void __setitem__(PyObject *li, const MEDCouplingUMesh& otherOnSameCoordsThanThis) throw(INTERP_KERNEL::Exception) { int sw; int singleVal; std::vector multiVal; std::pair > slic; MEDCoupling::DataArrayInt *daIntTyypp=0; int nbc=self->getNumberOfCells(); convertIntStarOrSliceLikePyObjToCpp(li,nbc,sw,singleVal,multiVal,slic,daIntTyypp); switch(sw) { case 1: { if(singleVal>=nbc) { std::ostringstream oss; oss << "Requesting for cell id " << singleVal << " having only " << nbc << " cells !"; throw INTERP_KERNEL::Exception(oss.str().c_str()); } if(singleVal>=0) { self->setPartOfMySelf(&singleVal,&singleVal+1,otherOnSameCoordsThanThis); break; } else { if(nbc+singleVal>0) { int tmp=nbc+singleVal; self->setPartOfMySelf(&tmp,&tmp+1,otherOnSameCoordsThanThis); break; } else { std::ostringstream oss; oss << "Requesting for cell id " << singleVal << " having only " << nbc << " cells !"; throw INTERP_KERNEL::Exception(oss.str().c_str()); } } } case 2: { self->setPartOfMySelf(&multiVal[0],&multiVal[0]+multiVal.size(),otherOnSameCoordsThanThis); break; } case 3: { self->setPartOfMySelfSlice(slic.first,slic.second.first,slic.second.second,otherOnSameCoordsThanThis); break; } case 4: { if(!daIntTyypp) throw INTERP_KERNEL::Exception("MEDCouplingUMesh::__setitem__ : null instance has been given in input !"); daIntTyypp->checkAllocated(); self->setPartOfMySelf(daIntTyypp->begin(),daIntTyypp->end(),otherOnSameCoordsThanThis); break; } default: throw INTERP_KERNEL::Exception("MEDCouplingUMesh::__setitem__ : unrecognized type in input ! Possibilities are : int, list or tuple of int, slice, DataArrayInt instance !"); } } void insertNextCell(INTERP_KERNEL::NormalizedCellType type, int size, PyObject *li) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); if(size>szArr) { std::ostringstream oss; oss << "Wrap of MEDCouplingUMesh::insertNextCell : request of connectivity with length " << size << " whereas the length of input is " << szArr << " !"; throw INTERP_KERNEL::Exception(oss.str().c_str()); } self->insertNextCell(type,size,tmp); } void insertNextCell(INTERP_KERNEL::NormalizedCellType type, PyObject *li) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); self->insertNextCell(type,szArr,tmp); } DataArrayInt *getNodalConnectivity() throw(INTERP_KERNEL::Exception) { DataArrayInt *ret=self->getNodalConnectivity(); if(ret) ret->incrRef(); return ret; } DataArrayInt *getNodalConnectivityIndex() throw(INTERP_KERNEL::Exception) { DataArrayInt *ret=self->getNodalConnectivityIndex(); if(ret) ret->incrRef(); return ret; } static PyObject *ComputeSpreadZoneGraduallyFromSeed(PyObject *seed, const DataArrayInt *arrIn, const DataArrayInt *arrIndxIn, int nbOfDepthPeeling=-1) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *seedPtr=convertIntStarLikePyObjToCppIntStar(seed,sw,szArr,iTypppArr,stdvecTyyppArr); int nbOfDepthPeelingPerformed=0; DataArrayInt *ret0=MEDCouplingUMesh::ComputeSpreadZoneGraduallyFromSeed(seedPtr,seedPtr+szArr,arrIn,arrIndxIn,nbOfDepthPeeling,nbOfDepthPeelingPerformed); PyObject *res=PyTuple_New(2); PyTuple_SetItem(res,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(res,1,PyInt_FromLong(nbOfDepthPeelingPerformed)); return res; } static PyObject *FindCommonCellsAlg(int compType, int startCellId, const DataArrayInt *nodal, const DataArrayInt *nodalI, const DataArrayInt *revNodal, const DataArrayInt *revNodalI) throw(INTERP_KERNEL::Exception) { DataArrayInt *v0=0,*v1=0; MEDCouplingUMesh::FindCommonCellsAlg(compType,startCellId,nodal,nodalI,revNodal,revNodalI,v0,v1); PyObject *res = PyList_New(2); PyList_SetItem(res,0,SWIG_NewPointerObj(SWIG_as_voidptr(v0),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyList_SetItem(res,1,SWIG_NewPointerObj(SWIG_as_voidptr(v1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return res; } PyObject *distanceToPoint(PyObject *point) const throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int nbOfCompo=self->getSpaceDimension(); const double *pt=convertObjToPossibleCpp5_Safe(point,sw,val,a,aa,bb,"Python wrap of MEDCouplingUMesh::distanceToPoint",1,nbOfCompo,true); // int cellId=-1; double ret0=self->distanceToPoint(pt,pt+nbOfCompo,cellId); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,PyFloat_FromDouble(ret0)); PyTuple_SetItem(ret,1,PyInt_FromLong(cellId)); return ret; } PyObject *distanceToPoints(const DataArrayDouble *pts) const throw(INTERP_KERNEL::Exception) { DataArrayInt *ret1=0; DataArrayDouble *ret0=self->distanceToPoints(pts,ret1); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__DataArrayDouble, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(ret1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *tetrahedrize(int policy) throw(INTERP_KERNEL::Exception) { int ret2(-1); DataArrayInt *ret1(0); MEDCoupling1SGTUMesh *ret0(self->tetrahedrize(policy,ret1,ret2)); PyObject *ret=PyTuple_New(3); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__MEDCoupling1SGTUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(ret1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,PyInt_FromLong(ret2)); return ret; } PyObject *checkButterflyCells(double eps=1e-12) throw(INTERP_KERNEL::Exception) { std::vector cells; self->checkButterflyCells(cells,eps); DataArrayInt *ret=DataArrayInt::New(); ret->alloc((int)cells.size(),1); std::copy(cells.begin(),cells.end(),ret->getPointer()); return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); } PyObject *splitByType() const throw(INTERP_KERNEL::Exception) { std::vector ms=self->splitByType(); int sz=ms.size(); PyObject *ret = PyList_New(sz); for(int i=0;i retCpp=self->partitionBySpreadZone(); int sz=retCpp.size(); PyObject *ret=PyList_New(sz); for(int i=0;i retCpp(MEDCouplingUMesh::PartitionBySpreadZone(arrIn,arrIndxIn)); int sz=retCpp.size(); PyObject *ret=PyList_New(sz); for(int i=0;i tmp=convertPyToNewIntArr2(ids,&size); MEDCouplingUMesh *ret=self->keepSpecifiedCells(type,tmp,tmp+size); return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 ); } bool checkConsecutiveCellTypesAndOrder(PyObject *li) const throw(INTERP_KERNEL::Exception) { int sz; INTERP_KERNEL::AutoPtr order=(INTERP_KERNEL::NormalizedCellType *)convertPyToNewIntArr2(li,&sz); bool ret=self->checkConsecutiveCellTypesAndOrder(order,order+sz); return ret; } DataArrayInt *getRenumArrForConsecutiveCellTypesSpec(PyObject *li) const throw(INTERP_KERNEL::Exception) { int sz; INTERP_KERNEL::AutoPtr order=(INTERP_KERNEL::NormalizedCellType *)convertPyToNewIntArr2(li,&sz); DataArrayInt *ret=self->getRenumArrForConsecutiveCellTypesSpec(order,(INTERP_KERNEL::NormalizedCellType *)order+sz); return ret; } PyObject *findNodesToDuplicate(const MEDCouplingUMesh& otherDimM1OnSameCoords) const throw(INTERP_KERNEL::Exception) { DataArrayInt *tmp0=0,*tmp1=0,*tmp2=0; self->findNodesToDuplicate(otherDimM1OnSameCoords,tmp0,tmp1,tmp2); PyObject *ret=PyTuple_New(3); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(tmp0),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(tmp1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(tmp2),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *findCellIdsLyingOn(const MEDCouplingUMesh& otherDimM1OnSameCoords) const throw(INTERP_KERNEL::Exception) { DataArrayInt *tmp0=0,*tmp1=0; self->findCellIdsLyingOn(otherDimM1OnSameCoords,tmp0,tmp1); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(tmp0),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(tmp1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } void duplicateNodes(PyObject *li) throw(INTERP_KERNEL::Exception) { int sw; int singleVal; std::vector multiVal; std::pair > slic; MEDCoupling::DataArrayInt *daIntTyypp=0; convertIntStarOrSliceLikePyObjToCpp(li,self->getNumberOfNodes(),sw,singleVal,multiVal,slic,daIntTyypp); switch(sw) { case 1: return self->duplicateNodes(&singleVal,&singleVal+1); case 2: return self->duplicateNodes(&multiVal[0],&multiVal[0]+multiVal.size()); case 4: return self->duplicateNodes(daIntTyypp->begin(),daIntTyypp->end()); default: throw INTERP_KERNEL::Exception("MEDCouplingUMesh::duplicateNodes : unrecognized type entered, expected list of int, tuple of int or DataArrayInt !"); } } void duplicateNodesInConn(PyObject *li, int offset) throw(INTERP_KERNEL::Exception) { int sw; int singleVal; std::vector multiVal; std::pair > slic; MEDCoupling::DataArrayInt *daIntTyypp=0; convertIntStarOrSliceLikePyObjToCpp(li,self->getNumberOfNodes(),sw,singleVal,multiVal,slic,daIntTyypp); switch(sw) { case 1: return self->duplicateNodesInConn(&singleVal,&singleVal+1,offset); case 2: return self->duplicateNodesInConn(&multiVal[0],&multiVal[0]+multiVal.size(),offset); case 4: return self->duplicateNodesInConn(daIntTyypp->begin(),daIntTyypp->end(),offset); default: throw INTERP_KERNEL::Exception("MEDCouplingUMesh::duplicateNodesInConn : unrecognized type entered, expected list of int, tuple of int or DataArrayInt !"); } } void attractSeg3MidPtsAroundNodes(double ratio, PyObject *nodeIds) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *nodeIdsPtr(convertIntStarLikePyObjToCppIntStar(nodeIds,sw,szArr,iTypppArr,stdvecTyyppArr)); self->attractSeg3MidPtsAroundNodes(ratio,nodeIdsPtr,nodeIdsPtr+szArr); } PyObject *getLevArrPerCellTypes(PyObject *li) const throw(INTERP_KERNEL::Exception) { int sz; INTERP_KERNEL::AutoPtr order=(INTERP_KERNEL::NormalizedCellType *)convertPyToNewIntArr2(li,&sz); DataArrayInt *tmp0,*tmp1=0; tmp0=self->getLevArrPerCellTypes(order,(INTERP_KERNEL::NormalizedCellType *)order+sz,tmp1); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(tmp0),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(tmp1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *convertNodalConnectivityToDynamicGeoTypeMesh() const throw(INTERP_KERNEL::Exception) { DataArrayInt *ret0=0,*ret1=0; self->convertNodalConnectivityToDynamicGeoTypeMesh(ret0,ret1); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(ret1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } static PyObject *AggregateSortedByTypeMeshesOnSameCoords(PyObject *ms) throw(INTERP_KERNEL::Exception) { std::vector meshes; convertFromPyObjVectorOfObj(ms,SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh,"MEDCouplingUMesh",meshes); DataArrayInt *ret1=0,*ret2=0; MEDCouplingUMesh *ret0=MEDCouplingUMesh::AggregateSortedByTypeMeshesOnSameCoords(meshes,ret1,ret2); PyObject *ret=PyTuple_New(3); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(ret1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(ret2),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } static PyObject *MergeUMeshesOnSameCoords(PyObject *ms) throw(INTERP_KERNEL::Exception) { std::vector meshes; convertFromPyObjVectorOfObj(ms,SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh,"MEDCouplingUMesh",meshes); MEDCouplingUMesh *ret=MEDCouplingUMesh::MergeUMeshesOnSameCoords(meshes); return convertMesh(ret, SWIG_POINTER_OWN | 0 ); } static PyObject *FuseUMeshesOnSameCoords(PyObject *ms, int compType) throw(INTERP_KERNEL::Exception) { int sz; std::vector meshes; convertFromPyObjVectorOfObj(ms,SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh,"MEDCouplingUMesh",meshes); std::vector corr; MEDCouplingUMesh *um=MEDCouplingUMesh::FuseUMeshesOnSameCoords(meshes,compType,corr); sz=corr.size(); PyObject *ret1=PyList_New(sz); for(int i=0;i meshes; convertFromPyObjVectorOfObj(ms,SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh,"MEDCouplingUMesh",meshes); MEDCouplingUMesh::PutUMeshesOnSameAggregatedCoords(meshes); } static void MergeNodesOnUMeshesSharingSameCoords(PyObject *ms, double eps) throw(INTERP_KERNEL::Exception) { std::vector meshes; convertFromPyObjVectorOfObj(ms,SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh,"MEDCouplingUMesh",meshes); MEDCouplingUMesh::MergeNodesOnUMeshesSharingSameCoords(meshes,eps); } static bool RemoveIdsFromIndexedArrays(PyObject *li, DataArrayInt *arr, DataArrayInt *arrIndx, int offsetForRemoval=0) throw(INTERP_KERNEL::Exception) { int sw; int singleVal; std::vector multiVal; std::pair > slic; MEDCoupling::DataArrayInt *daIntTyypp=0; if(!arrIndx) throw INTERP_KERNEL::Exception("MEDCouplingUMesh::RemoveIdsFromIndexedArrays : null pointer as arrIndex !"); convertIntStarOrSliceLikePyObjToCpp(li,arrIndx->getNumberOfTuples()-1,sw,singleVal,multiVal,slic,daIntTyypp); switch(sw) { case 1: return MEDCouplingUMesh::RemoveIdsFromIndexedArrays(&singleVal,&singleVal+1,arr,arrIndx,offsetForRemoval); case 2: return MEDCouplingUMesh::RemoveIdsFromIndexedArrays(&multiVal[0],&multiVal[0]+multiVal.size(),arr,arrIndx,offsetForRemoval); case 4: return MEDCouplingUMesh::RemoveIdsFromIndexedArrays(daIntTyypp->begin(),daIntTyypp->end(),arr,arrIndx,offsetForRemoval); default: throw INTERP_KERNEL::Exception("MEDCouplingUMesh::RemoveIdsFromIndexedArrays : unrecognized type entered, expected list of int, tuple of int or DataArrayInt !"); } } static PyObject *ExtractFromIndexedArrays(PyObject *li, const DataArrayInt *arrIn, const DataArrayInt *arrIndxIn) throw(INTERP_KERNEL::Exception) { DataArrayInt *arrOut=0,*arrIndexOut=0; int sw; int singleVal; std::vector multiVal; std::pair > slic; MEDCoupling::DataArrayInt *daIntTyypp=0; if(!arrIndxIn) throw INTERP_KERNEL::Exception("MEDCouplingUMesh::ExtractFromIndexedArrays : null pointer as arrIndxIn !"); convertIntStarOrSliceLikePyObjToCpp(li,arrIndxIn->getNumberOfTuples()-1,sw,singleVal,multiVal,slic,daIntTyypp); switch(sw) { case 1: { MEDCouplingUMesh::ExtractFromIndexedArrays(&singleVal,&singleVal+1,arrIn,arrIndxIn,arrOut,arrIndexOut); break; } case 2: { MEDCouplingUMesh::ExtractFromIndexedArrays(&multiVal[0],&multiVal[0]+multiVal.size(),arrIn,arrIndxIn,arrOut,arrIndexOut); break; } case 4: { MEDCouplingUMesh::ExtractFromIndexedArrays(daIntTyypp->begin(),daIntTyypp->end(),arrIn,arrIndxIn,arrOut,arrIndexOut); break; } default: throw INTERP_KERNEL::Exception("MEDCouplingUMesh::ExtractFromIndexedArrays : unrecognized type entered, expected list of int, tuple of int or DataArrayInt !"); } PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(arrOut),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(arrIndexOut),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } static PyObject *ExtractFromIndexedArraysSlice(int strt, int stp, int step, const DataArrayInt *arrIn, const DataArrayInt *arrIndxIn) throw(INTERP_KERNEL::Exception) { DataArrayInt *arrOut=0,*arrIndexOut=0; MEDCouplingUMesh::ExtractFromIndexedArraysSlice(strt,stp,step,arrIn,arrIndxIn,arrOut,arrIndexOut); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(arrOut),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(arrIndexOut),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } static PyObject *ExtractFromIndexedArraysSlice(PyObject *slic, const DataArrayInt *arrIn, const DataArrayInt *arrIndxIn) throw(INTERP_KERNEL::Exception) { if(!PySlice_Check(slic)) throw INTERP_KERNEL::Exception("ExtractFromIndexedArraysSlice (wrap) : the first param is not a pyslice !"); Py_ssize_t strt=2,stp=2,step=2; if(!arrIndxIn) throw INTERP_KERNEL::Exception("ExtractFromIndexedArraysSlice (wrap) : last array is null !"); arrIndxIn->checkAllocated(); if(arrIndxIn->getNumberOfComponents()!=1) throw INTERP_KERNEL::Exception("ExtractFromIndexedArraysSlice (wrap) : number of components of last argument must be equal to one !"); GetIndicesOfSlice(slic,arrIndxIn->getNumberOfTuples(),&strt,&stp,&step,"ExtractFromIndexedArraysSlice (wrap) : Invalid slice regarding nb of elements !"); DataArrayInt *arrOut=0,*arrIndexOut=0; MEDCouplingUMesh::ExtractFromIndexedArraysSlice(strt,stp,step,arrIn,arrIndxIn,arrOut,arrIndexOut); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(arrOut),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(arrIndexOut),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } static PyObject *SetPartOfIndexedArrays(PyObject *li, const DataArrayInt *arrIn, const DataArrayInt *arrIndxIn, const DataArrayInt *srcArr, const DataArrayInt *srcArrIndex) throw(INTERP_KERNEL::Exception) { DataArrayInt *arrOut=0,*arrIndexOut=0; int sw; int singleVal; std::vector multiVal; std::pair > slic; MEDCoupling::DataArrayInt *daIntTyypp=0; if(!arrIndxIn) throw INTERP_KERNEL::Exception("MEDCouplingUMesh::SetPartOfIndexedArrays : null pointer as arrIndex !"); convertIntStarOrSliceLikePyObjToCpp(li,arrIndxIn->getNumberOfTuples()-1,sw,singleVal,multiVal,slic,daIntTyypp); switch(sw) { case 1: { MEDCouplingUMesh::SetPartOfIndexedArrays(&singleVal,&singleVal+1,arrIn,arrIndxIn,srcArr,srcArrIndex,arrOut,arrIndexOut); break; } case 2: { MEDCouplingUMesh::SetPartOfIndexedArrays(&multiVal[0],&multiVal[0]+multiVal.size(),arrIn,arrIndxIn,srcArr,srcArrIndex,arrOut,arrIndexOut); break; } case 4: { MEDCouplingUMesh::SetPartOfIndexedArrays(daIntTyypp->begin(),daIntTyypp->end(),arrIn,arrIndxIn,srcArr,srcArrIndex,arrOut,arrIndexOut); break; } default: throw INTERP_KERNEL::Exception("MEDCouplingUMesh::SetPartOfIndexedArrays : unrecognized type entered, expected list of int, tuple of int or DataArrayInt !"); } PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(arrOut),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(arrIndexOut),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } static void SetPartOfIndexedArraysSameIdx(PyObject *li, DataArrayInt *arrIn, const DataArrayInt *arrIndxIn, const DataArrayInt *srcArr, const DataArrayInt *srcArrIndex) throw(INTERP_KERNEL::Exception) { int sw; int singleVal; std::vector multiVal; std::pair > slic; MEDCoupling::DataArrayInt *daIntTyypp=0; if(!arrIndxIn) throw INTERP_KERNEL::Exception("MEDCouplingUMesh::SetPartOfIndexedArraysSameIdx : null pointer as arrIndex !"); convertIntStarOrSliceLikePyObjToCpp(li,arrIndxIn->getNumberOfTuples()-1,sw,singleVal,multiVal,slic,daIntTyypp); switch(sw) { case 1: { MEDCouplingUMesh::SetPartOfIndexedArraysSameIdx(&singleVal,&singleVal+1,arrIn,arrIndxIn,srcArr,srcArrIndex); break; } case 2: { MEDCouplingUMesh::SetPartOfIndexedArraysSameIdx(&multiVal[0],&multiVal[0]+multiVal.size(),arrIn,arrIndxIn,srcArr,srcArrIndex); break; } case 4: { MEDCouplingUMesh::SetPartOfIndexedArraysSameIdx(daIntTyypp->begin(),daIntTyypp->end(),arrIn,arrIndxIn,srcArr,srcArrIndex); break; } default: throw INTERP_KERNEL::Exception("MEDCouplingUMesh::SetPartOfIndexedArraysSameIdx : unrecognized type entered, expected list of int, tuple of int or DataArrayInt !"); } } PyObject *are2DCellsNotCorrectlyOriented(PyObject *vec, bool polyOnly) const throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int spaceDim=self->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingUMesh::are2DCellsNotCorrectlyOriented : "; const double *v=convertObjToPossibleCpp5_Safe(vec,sw,val,a,aa,bb,msg,1,spaceDim,true); // std::vector cells; self->are2DCellsNotCorrectlyOriented(v,polyOnly,cells); DataArrayInt *ret=DataArrayInt::New(); ret->alloc((int)cells.size(),1); std::copy(cells.begin(),cells.end(),ret->getPointer()); return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); } void orientCorrectly2DCells(PyObject *vec, bool polyOnly) throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; int spaceDim=self->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingUMesh::orientCorrectly2DCells : "; const double *v=convertObjToPossibleCpp5_Safe(vec,sw,val,a,aa,bb,msg,1,spaceDim,true); self->orientCorrectly2DCells(v,polyOnly); } PyObject *arePolyhedronsNotCorrectlyOriented() const throw(INTERP_KERNEL::Exception) { std::vector cells; self->arePolyhedronsNotCorrectlyOriented(cells); DataArrayInt *ret=DataArrayInt::New(); ret->alloc((int)cells.size(),1); std::copy(cells.begin(),cells.end(),ret->getPointer()); return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); } PyObject *getFastAveragePlaneOfThis() const throw(INTERP_KERNEL::Exception) { double vec[3]; double pos[3]; self->getFastAveragePlaneOfThis(vec,pos); double vals[6]; std::copy(vec,vec+3,vals); std::copy(pos,pos+3,vals+3); return convertDblArrToPyListOfTuple(vals,3,2); } static MEDCouplingUMesh *MergeUMeshes(PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh,"MEDCouplingUMesh",tmp); return MEDCouplingUMesh::MergeUMeshes(tmp); } PyObject *areCellsIncludedIn(const MEDCouplingUMesh *other, int compType) const throw(INTERP_KERNEL::Exception) { DataArrayInt *ret1; bool ret0=self->areCellsIncludedIn(other,compType,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,SWIG_NewPointerObj(SWIG_as_voidptr(ret1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *areCellsIncludedInPolicy7(const MEDCouplingUMesh *other) const throw(INTERP_KERNEL::Exception) { DataArrayInt *ret1; bool ret0=self->areCellsIncludedInPolicy7(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,SWIG_NewPointerObj(SWIG_as_voidptr(ret1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *explode3DMeshTo1D() const throw(INTERP_KERNEL::Exception) { MCAuto d0=DataArrayInt::New(); MCAuto d1=DataArrayInt::New(); MCAuto d2=DataArrayInt::New(); MCAuto d3=DataArrayInt::New(); MEDCouplingUMesh *m=self->explode3DMeshTo1D(d0,d1,d2,d3); PyObject *ret=PyTuple_New(5); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(m),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(d0.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(d1.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,3,SWIG_NewPointerObj(SWIG_as_voidptr(d2.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,4,SWIG_NewPointerObj(SWIG_as_voidptr(d3.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *explodeIntoEdges() const throw(INTERP_KERNEL::Exception) { MCAuto desc,descIndex,revDesc,revDescIndx; MCAuto m(self->explodeIntoEdges(desc,descIndex,revDesc,revDescIndx)); PyObject *ret=PyTuple_New(5); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(m.retn()),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(desc.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(descIndex.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,3,SWIG_NewPointerObj(SWIG_as_voidptr(revDesc.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,4,SWIG_NewPointerObj(SWIG_as_voidptr(revDescIndx.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *explodeMeshIntoMicroEdges() const throw(INTERP_KERNEL::Exception) { MCAuto d0=DataArrayInt::New(); MCAuto d1=DataArrayInt::New(); MCAuto d2=DataArrayInt::New(); MCAuto d3=DataArrayInt::New(); MEDCouplingUMesh *m=self->explodeMeshIntoMicroEdges(d0,d1,d2,d3); PyObject *ret=PyTuple_New(5); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(m),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(d0.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(d1.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,3,SWIG_NewPointerObj(SWIG_as_voidptr(d2.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,4,SWIG_NewPointerObj(SWIG_as_voidptr(d3.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *buildDescendingConnectivity() const throw(INTERP_KERNEL::Exception) { MCAuto d0=DataArrayInt::New(); MCAuto d1=DataArrayInt::New(); MCAuto d2=DataArrayInt::New(); MCAuto d3=DataArrayInt::New(); MEDCouplingUMesh *m=self->buildDescendingConnectivity(d0,d1,d2,d3); PyObject *ret=PyTuple_New(5); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(m),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(d0.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(d1.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,3,SWIG_NewPointerObj(SWIG_as_voidptr(d2.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,4,SWIG_NewPointerObj(SWIG_as_voidptr(d3.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *buildDescendingConnectivity2() const throw(INTERP_KERNEL::Exception) { MCAuto d0=DataArrayInt::New(); MCAuto d1=DataArrayInt::New(); MCAuto d2=DataArrayInt::New(); MCAuto d3=DataArrayInt::New(); MEDCouplingUMesh *m=self->buildDescendingConnectivity2(d0,d1,d2,d3); PyObject *ret=PyTuple_New(5); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(m),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(d0.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(d1.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,3,SWIG_NewPointerObj(SWIG_as_voidptr(d2.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,4,SWIG_NewPointerObj(SWIG_as_voidptr(d3.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *computeNeighborsOfCells() const throw(INTERP_KERNEL::Exception) { DataArrayInt *neighbors=0,*neighborsIdx=0; self->computeNeighborsOfCells(neighbors,neighborsIdx); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(neighbors),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(neighborsIdx),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); 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_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(neighborsIdx),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *computeEnlargedNeighborsOfNodes() const throw(INTERP_KERNEL::Exception) { MCAuto neighbors,neighborsIdx; self->computeEnlargedNeighborsOfNodes(neighbors,neighborsIdx); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(neighbors.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(neighborsIdx.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *computeCellNeighborhoodFromNodesOne(const DataArrayInt *nodeNeigh, const DataArrayInt *nodeNeighI) const throw(INTERP_KERNEL::Exception) { MCAuto cellNeigh,cellNeighIndex; self->computeCellNeighborhoodFromNodesOne(nodeNeigh,nodeNeighI,cellNeigh,cellNeighIndex); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(cellNeigh.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(cellNeighIndex.retn()),SWIGTYPE_p_MEDCoupling__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; MEDCouplingUMesh::ComputeNeighborsOfCellsAdv(desc,descI,revDesc,revDescI,neighbors,neighborsIdx); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(neighbors),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(neighborsIdx),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *emulateMEDMEMBDC(const MEDCouplingUMesh *nM1LevMesh) { MCAuto d0=DataArrayInt::New(); MCAuto d1=DataArrayInt::New(); DataArrayInt *d2,*d3,*d4,*dd5; MEDCouplingUMesh *mOut=self->emulateMEDMEMBDC(nM1LevMesh,d0,d1,d2,d3,d4,dd5); PyObject *ret=PyTuple_New(7); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(mOut),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(d0.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(d1.retn()),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,3,SWIG_NewPointerObj(SWIG_as_voidptr(d2),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,4,SWIG_NewPointerObj(SWIG_as_voidptr(d3),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,5,SWIG_NewPointerObj(SWIG_as_voidptr(d4),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,6,SWIG_NewPointerObj(SWIG_as_voidptr(dd5),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } DataArrayDouble *getPartBarycenterAndOwner(DataArrayInt *da) const throw(INTERP_KERNEL::Exception) { if(!da) throw INTERP_KERNEL::Exception("Not null DataArrayInt instance expected !"); da->checkAllocated(); return self->getPartBarycenterAndOwner(da->getConstPointer(),da->getConstPointer()+da->getNbOfElems()); } DataArrayDouble *getPartMeasureField(bool isAbs, DataArrayInt *da) const throw(INTERP_KERNEL::Exception) { if(!da) throw INTERP_KERNEL::Exception("Not null DataArrayInt instance expected !"); da->checkAllocated(); return self->getPartMeasureField(isAbs,da->getConstPointer(),da->getConstPointer()+da->getNbOfElems()); } MEDCouplingFieldDouble *buildPartOrthogonalField(DataArrayInt *da) const throw(INTERP_KERNEL::Exception) { if(!da) throw INTERP_KERNEL::Exception("Not null DataArrayInt instance expected !"); da->checkAllocated(); return self->buildPartOrthogonalField(da->getConstPointer(),da->getConstPointer()+da->getNbOfElems()); } PyObject *getTypesOfPart(DataArrayInt *da) const throw(INTERP_KERNEL::Exception) { if(!da) throw INTERP_KERNEL::Exception("Not null DataArrayInt instance expected !"); da->checkAllocated(); std::set result=self->getTypesOfPart(da->getConstPointer(),da->getConstPointer()+da->getNbOfElems()); std::set::const_iterator iL=result.begin(); PyObject *res = PyList_New(result.size()); for (int i=0;iL!=result.end(); i++, iL++) PyList_SetItem(res,i,PyInt_FromLong(*iL)); return res; } DataArrayInt *keepCellIdsByType(INTERP_KERNEL::NormalizedCellType type, DataArrayInt *da) const throw(INTERP_KERNEL::Exception) { if(!da) throw INTERP_KERNEL::Exception("Not null DataArrayInt instance expected !"); da->checkAllocated(); DataArrayInt *ret=self->keepCellIdsByType(type,da->getConstPointer(),da->getConstPointer()+da->getNbOfElems()); ret->setName(da->getName().c_str()); return ret; } static PyObject *Intersect2DMeshes(const MEDCouplingUMesh *m1, const MEDCouplingUMesh *m2, double eps) throw(INTERP_KERNEL::Exception) { DataArrayInt *cellNb1=0,*cellNb2=0; MEDCouplingUMesh *mret=MEDCouplingUMesh::Intersect2DMeshes(m1,m2,eps,cellNb1,cellNb2); PyObject *ret=PyTuple_New(3); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(mret),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(cellNb1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(cellNb2),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 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_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(splitMesh1D),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(cellIdInMesh2D),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,3,SWIG_NewPointerObj(SWIG_as_voidptr(cellIdInMesh1D),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *buildSlice3D(PyObject *origin, PyObject *vec, double eps) const throw(INTERP_KERNEL::Exception) { int spaceDim=self->getSpaceDimension(); if(spaceDim!=3) throw INTERP_KERNEL::Exception("Python wrap of MEDCouplingUMesh::buildSlice3D : works only for spaceDim 3 !"); double val,val2; DataArrayDouble *a,*a2; DataArrayDoubleTuple *aa,*aa2; std::vector bb,bb2; int sw; const char msg[]="Python wrap of MEDCouplingUMesh::buildSlice3D : 1st parameter for origin."; const char msg2[]="Python wrap of MEDCouplingUMesh::buildSlice3D : 2nd parameter for vector."; const double *orig=convertObjToPossibleCpp5_Safe(origin,sw,val,a,aa,bb,msg,1,spaceDim,true); const double *vect=convertObjToPossibleCpp5_Safe(vec,sw,val2,a2,aa2,bb2,msg2,1,spaceDim,true); // DataArrayInt *cellIds=0; MEDCouplingUMesh *ret0=self->buildSlice3D(orig,vect,eps,cellIds); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(cellIds),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *buildSlice3DSurf(PyObject *origin, PyObject *vec, double eps) const throw(INTERP_KERNEL::Exception) { int spaceDim=self->getSpaceDimension(); if(spaceDim!=3) throw INTERP_KERNEL::Exception("Python wrap of MEDCouplingUMesh::buildSlice3DSurf : works only for spaceDim 3 !"); double val,val2; DataArrayDouble *a,*a2; DataArrayDoubleTuple *aa,*aa2; std::vector bb,bb2; int sw; const char msg[]="Python wrap of MEDCouplingUMesh::buildSlice3DSurf : 1st parameter for origin."; const char msg2[]="Python wrap of MEDCouplingUMesh::buildSlice3DSurf : 2nd parameter for vector."; const double *orig=convertObjToPossibleCpp5_Safe(origin,sw,val,a,aa,bb,msg,1,spaceDim,true); const double *vect=convertObjToPossibleCpp5_Safe(vec,sw,val2,a2,aa2,bb2,msg2,1,spaceDim,true); // DataArrayInt *cellIds=0; MEDCouplingUMesh *ret0=self->buildSlice3DSurf(orig,vect,eps,cellIds); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(cellIds),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } MEDCouplingUMesh *clipSingle3DCellByPlane(PyObject *origin, PyObject *vec, double eps) const throw(INTERP_KERNEL::Exception) { double val,val2; DataArrayDouble *a,*a2; DataArrayDoubleTuple *aa,*aa2; std::vector bb,bb2; int sw; const char msg[]="Python wrap of MEDCouplingUMesh::clipSingle3DCellByPlane : 1st parameter for origin."; const char msg2[]="Python wrap of MEDCouplingUMesh::clipSingle3DCellByPlane : 2nd parameter for vector."; const double *orig=convertObjToPossibleCpp5_Safe(origin,sw,val,a,aa,bb,msg,1,3,true); const double *vect=convertObjToPossibleCpp5_Safe(vec,sw,val2,a2,aa2,bb2,msg2,1,3,true); MCAuto ret(self->clipSingle3DCellByPlane(orig,vect,eps)); return ret.retn(); } DataArrayInt *getCellIdsCrossingPlane(PyObject *origin, PyObject *vec, double eps) const throw(INTERP_KERNEL::Exception) { int spaceDim=self->getSpaceDimension(); if(spaceDim!=3) throw INTERP_KERNEL::Exception("Python wrap of MEDCouplingUMesh::getCellIdsCrossingPlane : works only for spaceDim 3 !"); double val,val2; DataArrayDouble *a,*a2; DataArrayDoubleTuple *aa,*aa2; std::vector bb,bb2; int sw; const char msg[]="Python wrap of MEDCouplingUMesh::getCellIdsCrossingPlane : 1st parameter for origin."; const char msg2[]="Python wrap of MEDCouplingUMesh::getCellIdsCrossingPlane : 2nd parameter for vector."; const double *orig=convertObjToPossibleCpp5_Safe(origin,sw,val,a,aa,bb,msg,1,spaceDim,true); const double *vect=convertObjToPossibleCpp5_Safe(vec,sw,val2,a2,aa2,bb2,msg2,1,spaceDim,true); return self->getCellIdsCrossingPlane(orig,vect,eps); } void convertToPolyTypes(PyObject *li) throw(INTERP_KERNEL::Exception) { int sw; int pos1; std::vector pos2; DataArrayInt *pos3=0; DataArrayIntTuple *pos4=0; convertIntStarLikePyObjToCpp(li,sw,pos1,pos2,pos3,pos4); switch(sw) { case 1: { self->convertToPolyTypes(&pos1,&pos1+1); return; } case 2: { if(pos2.empty()) return; self->convertToPolyTypes(&pos2[0],&pos2[0]+pos2.size()); return ; } case 3: { self->convertToPolyTypes(pos3->begin(),pos3->end()); return ; } default: throw INTERP_KERNEL::Exception("MEDCouplingUMesh::convertToPolyTypes : unexpected input array type recognized !"); } } } void convertAllToPoly(); void convertExtrudedPolyhedra() throw(INTERP_KERNEL::Exception); bool unPolyze() throw(INTERP_KERNEL::Exception); void simplifyPolyhedra(double eps) throw(INTERP_KERNEL::Exception); MEDCouplingUMesh *buildSpreadZonesWithPoly() const throw(INTERP_KERNEL::Exception); MEDCouplingUMesh *buildExtrudedMesh(const MEDCouplingUMesh *mesh1D, int policy) throw(INTERP_KERNEL::Exception); }; //== MEDCouplingUMesh End //== MEDCouplingMappedExtrudedMesh class MEDCouplingMappedExtrudedMesh : public MEDCoupling::MEDCouplingMesh { public: static MEDCouplingMappedExtrudedMesh *New(const MEDCouplingUMesh *mesh3D, const MEDCouplingUMesh *mesh2D, int cell2DId) throw(INTERP_KERNEL::Exception); static MEDCouplingMappedExtrudedMesh *New(const MEDCouplingCMesh *mesh3D) throw(INTERP_KERNEL::Exception); MEDCouplingUMesh *build3DUnstructuredMesh() const throw(INTERP_KERNEL::Exception); int get2DCellIdForExtrusion() const; %extend { MEDCouplingMappedExtrudedMesh(const MEDCouplingUMesh *mesh3D, const MEDCouplingUMesh *mesh2D, int cell2DId) throw(INTERP_KERNEL::Exception) { return MEDCouplingMappedExtrudedMesh::New(mesh3D,mesh2D,cell2DId); } MEDCouplingMappedExtrudedMesh(const MEDCouplingCMesh *mesh3D) throw(INTERP_KERNEL::Exception) { return MEDCouplingMappedExtrudedMesh::New(mesh3D); } MEDCouplingMappedExtrudedMesh() { return MEDCouplingMappedExtrudedMesh::New(); } 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(); } PyObject *getMesh2D() const throw(INTERP_KERNEL::Exception) { MEDCouplingUMesh *ret=self->getMesh2D(); if(ret) ret->incrRef(); return convertMesh(ret, SWIG_POINTER_OWN | 0 ); } PyObject *getMesh1D() const throw(INTERP_KERNEL::Exception) { MEDCouplingUMesh *ret=self->getMesh1D(); if(ret) ret->incrRef(); return convertMesh(ret, SWIG_POINTER_OWN | 0 ); } PyObject *getMesh3DIds() const throw(INTERP_KERNEL::Exception) { DataArrayInt *ret=self->getMesh3DIds(); if(ret) ret->incrRef(); return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); } } }; //== MEDCouplingMappedExtrudedMesh End class MEDCoupling1GTUMesh : public MEDCoupling::MEDCouplingPointSet { public: static MEDCoupling1GTUMesh *New(const std::string& name, INTERP_KERNEL::NormalizedCellType type) throw(INTERP_KERNEL::Exception); static MEDCoupling1GTUMesh *New(const MEDCouplingUMesh *m) throw(INTERP_KERNEL::Exception); INTERP_KERNEL::NormalizedCellType getCellModelEnum() const throw(INTERP_KERNEL::Exception); int getNodalConnectivityLength() const throw(INTERP_KERNEL::Exception); virtual void allocateCells(int nbOfCells=0) throw(INTERP_KERNEL::Exception); virtual void checkConsistencyOfConnectivity() const throw(INTERP_KERNEL::Exception); %extend { virtual void insertNextCell(PyObject *li) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); self->insertNextCell(tmp,tmp+szArr); } virtual DataArrayInt *getNodalConnectivity() const throw(INTERP_KERNEL::Exception) { DataArrayInt *ret=self->getNodalConnectivity(); if(ret) ret->incrRef(); return ret; } static MEDCouplingUMesh *AggregateOnSameCoordsToUMesh(PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector< const MEDCoupling1GTUMesh *> parts; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCoupling1GTUMesh,"MEDCoupling1GTUMesh",parts); return MEDCoupling1GTUMesh::AggregateOnSameCoordsToUMesh(parts); } } }; //== MEDCoupling1SGTUMesh class MEDCoupling1SGTUMesh : public MEDCoupling::MEDCoupling1GTUMesh { public: static MEDCoupling1SGTUMesh *New(const std::string& name, INTERP_KERNEL::NormalizedCellType type) throw(INTERP_KERNEL::Exception); static MEDCoupling1SGTUMesh *New(const MEDCouplingUMesh *m) throw(INTERP_KERNEL::Exception); void setNodalConnectivity(DataArrayInt *nodalConn) throw(INTERP_KERNEL::Exception); int getNumberOfNodesPerCell() const throw(INTERP_KERNEL::Exception); static MEDCoupling1SGTUMesh *Merge1SGTUMeshes(const MEDCoupling1SGTUMesh *mesh1, const MEDCoupling1SGTUMesh *mesh2) throw(INTERP_KERNEL::Exception); MEDCoupling1SGTUMesh *buildSetInstanceFromThis(int spaceDim) const throw(INTERP_KERNEL::Exception); MEDCoupling1GTUMesh *computeDualMesh() const throw(INTERP_KERNEL::Exception); MEDCoupling1SGTUMesh *explodeEachHexa8To6Quad4() 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); } MEDCoupling1SGTUMesh(const MEDCouplingUMesh *m) throw(INTERP_KERNEL::Exception) { return MEDCoupling1SGTUMesh::New(m); } 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(); } 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_MEDCoupling__MEDCouplingCMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(cellPerm),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(nodePerm),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } static MEDCoupling1SGTUMesh *Merge1SGTUMeshes(PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCoupling1SGTUMesh,"MEDCoupling1SGTUMesh",tmp); return MEDCoupling1SGTUMesh::Merge1SGTUMeshes(tmp); } static MEDCoupling1SGTUMesh *Merge1SGTUMeshesOnSameCoords(PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCoupling1SGTUMesh,"MEDCoupling1SGTUMesh",tmp); return MEDCoupling1SGTUMesh::Merge1SGTUMeshesOnSameCoords(tmp); } } }; //== MEDCoupling1SGTUMesh End //== MEDCoupling1DGTUMesh class MEDCoupling1DGTUMesh : public MEDCoupling::MEDCoupling1GTUMesh { public: static MEDCoupling1DGTUMesh *New(const std::string& name, INTERP_KERNEL::NormalizedCellType type) throw(INTERP_KERNEL::Exception); static MEDCoupling1DGTUMesh *New(const MEDCouplingUMesh *m) throw(INTERP_KERNEL::Exception); void setNodalConnectivity(DataArrayInt *nodalConn, DataArrayInt *nodalConnIndex) throw(INTERP_KERNEL::Exception); MEDCoupling1DGTUMesh *buildSetInstanceFromThis(int spaceDim) const throw(INTERP_KERNEL::Exception); 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); } MEDCoupling1DGTUMesh(const MEDCouplingUMesh *m) throw(INTERP_KERNEL::Exception) { return MEDCoupling1DGTUMesh::New(m); } 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(); } DataArrayInt *getNodalConnectivityIndex() const throw(INTERP_KERNEL::Exception) { DataArrayInt *ret=self->getNodalConnectivityIndex(); if(ret) ret->incrRef(); return ret; } PyObject *retrievePackedNodalConnectivity() const throw(INTERP_KERNEL::Exception) { DataArrayInt *ret1=0,*ret2=0; bool ret0=self->retrievePackedNodalConnectivity(ret1,ret2); PyObject *ret0Py=ret0?Py_True:Py_False; Py_XINCREF(ret0Py); PyObject *ret=PyTuple_New(3); PyTuple_SetItem(ret,0,ret0Py); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(ret1),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,2,SWIG_NewPointerObj(SWIG_as_voidptr(ret2),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *copyWithNodalConnectivityPacked() const throw(INTERP_KERNEL::Exception) { bool ret1; MEDCoupling1DGTUMesh *ret0=self->copyWithNodalConnectivityPacked(ret1); PyObject *ret=PyTuple_New(2); PyObject *ret1Py=ret1?Py_True:Py_False; Py_XINCREF(ret1Py); PyTuple_SetItem(ret,0,SWIG_NewPointerObj(SWIG_as_voidptr(ret0),SWIGTYPE_p_MEDCoupling__MEDCoupling1DGTUMesh, SWIG_POINTER_OWN | 0 )); PyTuple_SetItem(ret,1,ret1Py); return ret; } static MEDCoupling1DGTUMesh *Merge1DGTUMeshes(PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCoupling1DGTUMesh,"MEDCoupling1DGTUMesh",tmp); return MEDCoupling1DGTUMesh::Merge1DGTUMeshes(tmp); } static MEDCoupling1DGTUMesh *Merge1DGTUMeshesOnSameCoords(PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCoupling1DGTUMesh,"MEDCoupling1DGTUMesh",tmp); return MEDCoupling1DGTUMesh::Merge1DGTUMeshesOnSameCoords(tmp); } static DataArrayInt *AggregateNodalConnAndShiftNodeIds(PyObject *li, const std::vector& offsetInNodeIdsPerElt) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__DataArrayInt,"DataArrayInt",tmp); return MEDCoupling1DGTUMesh::AggregateNodalConnAndShiftNodeIds(tmp,offsetInNodeIdsPerElt); } } }; //== MEDCoupling1DGTUMeshEnd class MEDCouplingStructuredMesh : public MEDCoupling::MEDCouplingMesh { 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 getNodeGridStructure() const throw(INTERP_KERNEL::Exception); std::vector getCellGridStructure() const throw(INTERP_KERNEL::Exception); MEDCoupling1SGTUMesh *build1SGTUnstructured() const throw(INTERP_KERNEL::Exception); std::vector getLocationFromCellId(int cellId) const throw(INTERP_KERNEL::Exception); std::vector 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& st) throw(INTERP_KERNEL::Exception); static DataArrayInt *ComputeCornersGhost(const std::vector& st, int ghostLev) throw(INTERP_KERNEL::Exception); static std::vector GetSplitVectFromStruct(const std::vector& strct) throw(INTERP_KERNEL::Exception); %extend { virtual MEDCouplingStructuredMesh *buildStructuredSubPart(PyObject *cellPart) const throw(INTERP_KERNEL::Exception) { int tmpp1=-1,tmpp2=-1; std::vector tmp=fillArrayWithPyListInt2(cellPart,tmpp1,tmpp2); std::vector< std::pair > inp; if(tmpp2==2) { inp.resize(tmpp1); for(int i=0;ibuildStructuredSubPart(inp); } static DataArrayInt *BuildExplicitIdsFrom(PyObject *st, PyObject *part) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(part,inp); // int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp4=convertIntStarLikePyObjToCppIntStar(st,sw,szArr,iTypppArr,stdvecTyyppArr); std::vector tmp5(tmp4,tmp4+szArr); // return MEDCouplingStructuredMesh::BuildExplicitIdsFrom(tmp5,inp); } static void MultiplyPartOf(const std::vector& st, PyObject *part, double factor, DataArrayDouble *da) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(part,inp); MEDCouplingStructuredMesh::MultiplyPartOf(st,inp,factor,da); } static void MultiplyPartOfByGhost(const std::vector& st, PyObject *part, int ghostSize, double factor, DataArrayDouble *da) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(part,inp); MEDCouplingStructuredMesh::MultiplyPartOfByGhost(st,inp,ghostSize,factor,da); } static PyObject *PutInGhostFormat(int ghostSize, const std::vector& st, PyObject *part) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(part,inp); std::vector stWithGhost; std::vector< std::pair > 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& st, const DataArrayDouble *fieldOfDbl, PyObject *partCompactFormat) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(partCompactFormat,inp); return MEDCouplingStructuredMesh::ExtractFieldOfDoubleFrom(st,fieldOfDbl,inp); } static void AssignPartOfFieldOfDoubleUsing(const std::vector& st, DataArrayDouble *fieldOfDbl, PyObject *partCompactFormat, const DataArrayDouble *other) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(partCompactFormat,inp); MEDCouplingStructuredMesh::AssignPartOfFieldOfDoubleUsing(st,fieldOfDbl,inp,other); } static int DeduceNumberOfGivenRangeInCompactFrmt(PyObject *part) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(part,inp); return MEDCouplingStructuredMesh::DeduceNumberOfGivenRangeInCompactFrmt(inp); } static DataArrayInt *Build1GTNodalConnectivity(PyObject *li) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); return MEDCouplingStructuredMesh::Build1GTNodalConnectivity(tmp,tmp+szArr); } static DataArrayInt *Build1GTNodalConnectivityOfSubLevelMesh(PyObject *li) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp(convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr)); return MEDCouplingStructuredMesh::Build1GTNodalConnectivityOfSubLevelMesh(tmp,tmp+szArr); } static std::vector GetDimensionsFromCompactFrmt(PyObject *partCompactFormat) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(partCompactFormat,inp); return MEDCouplingStructuredMesh::GetDimensionsFromCompactFrmt(inp); } static PyObject *GetCompactFrmtFromDimensions(const std::vector& dims) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > ret(MEDCouplingStructuredMesh::GetCompactFrmtFromDimensions(dims)); PyObject *retPy=PyList_New(ret.size()); for(std::size_t i=0;i > r1Cpp,r2Cpp; convertPyToVectorPairInt(r1,r1Cpp); convertPyToVectorPairInt(r2,r2Cpp); std::vector< std::pair > ret(MEDCouplingStructuredMesh::IntersectRanges(r1Cpp,r2Cpp)); PyObject *retPy=PyList_New(ret.size()); for(std::size_t i=0;i > 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; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); int szArr2,sw2,iTypppArr2; std::vector stdvecTyyppArr2; const int *tmp2=convertIntStarLikePyObjToCppIntStar(st,sw2,szArr2,iTypppArr2,stdvecTyyppArr2); std::vector tmp3(tmp2,tmp2+szArr2); std::vector< std::pair > partCompactFormat; bool ret0=MEDCouplingStructuredMesh::IsPartStructured(tmp,tmp+szArr,tmp3,partCompactFormat); PyObject *ret=PyTuple_New(2); PyObject *ret0Py=ret0?Py_True:Py_False; Py_XINCREF(ret0Py); PyTuple_SetItem(ret,0,ret0Py); PyObject *ret1Py=PyList_New(partCompactFormat.size()); for(std::size_t i=0;i > 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& translation) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > param0; convertPyToVectorPairInt(part,param0); std::vector< std::pair > ret(MEDCouplingStructuredMesh::TranslateCompactFrmt(param0,translation)); PyObject *retPy(PyList_New(ret.size())); for(std::size_t i=0;i FindTranslationFrom(PyObject *startingFrom, PyObject *goingTo) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > 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 > 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;isimpleRepr(); } std::string __repr__() const throw(INTERP_KERNEL::Exception) { std::ostringstream oss; self->reprQuickOverview(oss); return oss.str(); } DataArrayDouble *getCoordsAt(int i) throw(INTERP_KERNEL::Exception) { DataArrayDouble *ret=self->getCoordsAt(i); if(ret) ret->incrRef(); return ret; } } }; //== MEDCouplingCMesh End //== MEDCouplingCurveLinearMesh class MEDCouplingCurveLinearMesh : public MEDCoupling::MEDCouplingStructuredMesh { public: static MEDCouplingCurveLinearMesh *New() throw(INTERP_KERNEL::Exception); static MEDCouplingCurveLinearMesh *New(const std::string& meshName) throw(INTERP_KERNEL::Exception); void setCoords(const DataArrayDouble *coords) throw(INTERP_KERNEL::Exception); %extend { MEDCouplingCurveLinearMesh() throw(INTERP_KERNEL::Exception) { return MEDCouplingCurveLinearMesh::New(); } MEDCouplingCurveLinearMesh(const std::string& meshName) throw(INTERP_KERNEL::Exception) { return MEDCouplingCurveLinearMesh::New(meshName); } 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(); } DataArrayDouble *getCoords() throw(INTERP_KERNEL::Exception) { DataArrayDouble *ret=self->getCoords(); if(ret) ret->incrRef(); return ret; } void setNodeGridStructure(PyObject *gridStruct) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(gridStruct,sw,szArr,iTypppArr,stdvecTyyppArr); self->setNodeGridStructure(tmp,tmp+szArr); } } }; //== MEDCouplingCurveLinearMesh End //== MEDCouplingIMesh class MEDCouplingIMesh : public MEDCoupling::MEDCouplingStructuredMesh { public: static MEDCouplingIMesh *New() throw(INTERP_KERNEL::Exception); // void setSpaceDimension(int spaceDim) throw(INTERP_KERNEL::Exception); std::vector getNodeStruct() const throw(INTERP_KERNEL::Exception); std::vector getOrigin() const throw(INTERP_KERNEL::Exception); std::vector 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& factors) throw(INTERP_KERNEL::Exception); MEDCouplingIMesh *asSingleCell() const throw(INTERP_KERNEL::Exception); MEDCouplingIMesh *buildWithGhost(int ghostLev) const throw(INTERP_KERNEL::Exception); %extend { MEDCouplingIMesh() { 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 bb0; nodeStrctPtr=convertIntStarLikePyObjToCppIntStar(nodeStrct,sw,sz,val0,bb0); // double val,val2; std::vector 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); } MEDCouplingIMesh(const std::string& meshName, int spaceDim, PyObject *nodeStrct, PyObject *origin, PyObject *dxyz) throw(INTERP_KERNEL::Exception) { return MEDCoupling_MEDCouplingIMesh_New__SWIG_1(meshName,spaceDim,nodeStrct,origin,dxyz); } void setNodeStruct(PyObject *nodeStrct) throw(INTERP_KERNEL::Exception) { int sw,sz,val0; std::vector bb0; const int *nodeStrctPtr(convertIntStarLikePyObjToCppIntStar(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 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 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& coarseSt, const DataArrayDouble *fineDA, PyObject *fineLocInCoarse, const std::vector& facts, DataArrayDouble *coarseDA) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(fineLocInCoarse,inp); MEDCouplingIMesh::CondenseFineToCoarse(coarseSt,fineDA,inp,facts,coarseDA); } static void CondenseFineToCoarseGhost(const std::vector& coarseSt, const DataArrayDouble *fineDA, PyObject *fineLocInCoarse, const std::vector& facts, DataArrayDouble *coarseDA, int ghostSize) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(fineLocInCoarse,inp); MEDCouplingIMesh::CondenseFineToCoarseGhost(coarseSt,fineDA,inp,facts,coarseDA,ghostSize); } static void SpreadCoarseToFine(const DataArrayDouble *coarseDA, const std::vector& coarseSt, DataArrayDouble *fineDA, PyObject *fineLocInCoarse, const std::vector& facts) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(fineLocInCoarse,inp); MEDCouplingIMesh::SpreadCoarseToFine(coarseDA,coarseSt,fineDA,inp,facts); } static void SpreadCoarseToFineGhost(const DataArrayDouble *coarseDA, const std::vector& coarseSt, DataArrayDouble *fineDA, PyObject *fineLocInCoarse, const std::vector& facts, int ghostSize) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > inp; convertPyToVectorPairInt(fineLocInCoarse,inp); MEDCouplingIMesh::SpreadCoarseToFineGhost(coarseDA,coarseSt,fineDA,inp,facts,ghostSize); } static void SpreadCoarseToFineGhostZone(const DataArrayDouble *coarseDA, const std::vector& coarseSt, DataArrayDouble *fineDA, PyObject *fineLocInCoarse, const std::vector& facts, int ghostSize) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > 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 MEDCoupling { class MEDCouplingField : public MEDCoupling::RefCountObject, public MEDCoupling::TimeLabel { public: virtual void checkConsistencyLight() const throw(INTERP_KERNEL::Exception); virtual bool areCompatibleForMerge(const MEDCouplingField *other) const throw(INTERP_KERNEL::Exception); virtual void copyTinyStringsFrom(const MEDCouplingField *other) throw(INTERP_KERNEL::Exception); void setMesh(const MEDCoupling::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& refCoo, const std::vector& gsCoo, const std::vector& 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(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 ret=self->getGaussLocalizationIdsOfOneType(type); return convertIntArrToPyList3(ret); } PyObject *buildSubMeshData(PyObject *li) const throw(INTERP_KERNEL::Exception) { DataArrayInt *ret1=0; MEDCouplingMesh *ret0=0; void *da=0; int res1=SWIG_ConvertPtr(li,&da,SWIGTYPE_p_MEDCoupling__DataArrayInt, 0 | 0 ); if (!SWIG_IsOK(res1)) { int size; INTERP_KERNEL::AutoPtr tmp=convertPyToNewIntArr2(li,&size); ret0=self->buildSubMeshData(tmp,tmp+size,ret1); } else { DataArrayInt *da2=reinterpret_cast< DataArrayInt * >(da); if(!da2) throw INTERP_KERNEL::Exception("Not null DataArrayInt instance expected !"); da2->checkAllocated(); ret0=self->buildSubMeshData(da2->getConstPointer(),da2->getConstPointer()+da2->getNbOfElems(),ret1); } PyObject *res = PyList_New(2); PyList_SetItem(res,0,convertMesh(ret0, SWIG_POINTER_OWN | 0 )); PyList_SetItem(res,1,SWIG_NewPointerObj((void*)ret1,SWIGTYPE_p_MEDCoupling__DataArrayInt,SWIG_POINTER_OWN | 0)); return res; } PyObject *buildSubMeshDataRange(int begin, int end, int step) const throw(INTERP_KERNEL::Exception) { DataArrayInt *ret1=0; int bb,ee,ss; MEDCouplingMesh *ret0=self->buildSubMeshDataRange(begin,end,step,bb,ee,ss,ret1); PyObject *res=PyTuple_New(2); PyTuple_SetItem(res,0,convertMesh(ret0, SWIG_POINTER_OWN | 0 )); if(ret1) PyTuple_SetItem(res,1,SWIG_NewPointerObj((void*)ret1,SWIGTYPE_p_MEDCoupling__DataArrayInt,SWIG_POINTER_OWN | 0)); else { PyObject *res1=PySlice_New(PyInt_FromLong(bb),PyInt_FromLong(ee),PyInt_FromLong(ss)); PyTuple_SetItem(res,1,res1); } return res; } DataArrayInt *computeTupleIdsToSelectFromCellIds(PyObject *cellIds) const { int sw,sz(-1); int v0; std::vector v1; const int *cellIdsBg(convertIntStarLikePyObjToCppIntStar(cellIds,sw,sz,v0,v1)); return self->computeTupleIdsToSelectFromCellIds(cellIdsBg,cellIdsBg+sz); } void setGaussLocalizationOnCells(PyObject *li, const std::vector& refCoo, const std::vector& gsCoo, const std::vector& wg) throw(INTERP_KERNEL::Exception) { void *da=0; int res1=SWIG_ConvertPtr(li,&da,SWIGTYPE_p_MEDCoupling__DataArrayInt, 0 | 0 ); if (!SWIG_IsOK(res1)) { int size; INTERP_KERNEL::AutoPtr tmp=convertPyToNewIntArr2(li,&size); self->setGaussLocalizationOnCells(tmp,((int *)tmp)+size,refCoo,gsCoo,wg); } else { DataArrayInt *da2=reinterpret_cast< DataArrayInt * >(da); if(!da2) throw INTERP_KERNEL::Exception("Not null DataArrayInt instance expected !"); da2->checkAllocated(); self->setGaussLocalizationOnCells(da2->getConstPointer(),da2->getConstPointer()+da2->getNbOfElems(),refCoo,gsCoo,wg); } } PyObject *getCellIdsHavingGaussLocalization(int locId) const throw(INTERP_KERNEL::Exception) { std::vector tmp; self->getCellIdsHavingGaussLocalization(locId,tmp); DataArrayInt *ret=DataArrayInt::New(); ret->alloc((int)tmp.size(),1); std::copy(tmp.begin(),tmp.end(),ret->getPointer()); return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 ); } int getNumberOfTuplesExpectedRegardingCode(PyObject *code, PyObject *idsPerType) const throw(INTERP_KERNEL::Exception) { std::vector inp0; convertPyToNewIntArr4(code,1,3,inp0); std::vector inp1; convertFromPyObjVectorOfObj(idsPerType,SWIGTYPE_p_MEDCoupling__DataArrayInt,"DataArrayInt",inp1); return self->getNumberOfTuplesExpectedRegardingCode(inp0,inp1); } } }; class MEDCouplingFieldTemplate : public MEDCoupling::MEDCouplingField { public: static MEDCouplingFieldTemplate *New(const MEDCouplingFieldDouble& f) throw(INTERP_KERNEL::Exception); static MEDCouplingFieldTemplate *New(const MEDCouplingFieldFloat& f) throw(INTERP_KERNEL::Exception); static MEDCouplingFieldTemplate *New(const MEDCouplingFieldInt& f) throw(INTERP_KERNEL::Exception); static MEDCouplingFieldTemplate *New(TypeOfField type); std::string simpleRepr() const throw(INTERP_KERNEL::Exception); std::string advancedRepr() const throw(INTERP_KERNEL::Exception); bool isEqual(const MEDCouplingFieldTemplate *other, double meshPrec) const throw(INTERP_KERNEL::Exception); bool isEqualWithoutConsideringStr(const MEDCouplingFieldTemplate *other, double meshPrec) const throw(INTERP_KERNEL::Exception); %extend { MEDCouplingFieldTemplate(const MEDCouplingFieldDouble& f) throw(INTERP_KERNEL::Exception) { return MEDCouplingFieldTemplate::New(f); } MEDCouplingFieldTemplate(const MEDCouplingFieldFloat& f) throw(INTERP_KERNEL::Exception) { return MEDCouplingFieldTemplate::New(f); } MEDCouplingFieldTemplate(const MEDCouplingFieldInt& f) throw(INTERP_KERNEL::Exception) { return MEDCouplingFieldTemplate::New(f); } MEDCouplingFieldTemplate(TypeOfField type) throw(INTERP_KERNEL::Exception) { return MEDCouplingFieldTemplate::New(type); } 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(); } PyObject *isEqualIfNotWhy(const MEDCouplingFieldTemplate *other, double meshPrec) const throw(INTERP_KERNEL::Exception) { std::string ret1; bool ret0=self->isEqualIfNotWhy(other,meshPrec,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; } } }; template class MEDCouplingFieldT : public MEDCoupling::MEDCouplingField { public: TypeOfTimeDiscretization getTimeDiscretization() const throw(INTERP_KERNEL::Exception); protected: MEDCouplingFieldT(); ~MEDCouplingFieldT(); }; %template(MEDCouplingFieldTdouble) MEDCoupling::MEDCouplingFieldT; %template(MEDCouplingFieldTfloat) MEDCoupling::MEDCouplingFieldT; %template(MEDCouplingFieldTint) MEDCoupling::MEDCouplingFieldT; class MEDCouplingFieldInt; class MEDCouplingFieldFloat; class MEDCouplingFieldDouble : public MEDCouplingFieldT { public: static MEDCouplingFieldDouble *New(TypeOfField type, TypeOfTimeDiscretization td=ONE_TIME); static MEDCouplingFieldDouble *New(const MEDCouplingFieldTemplate& ft, TypeOfTimeDiscretization td=ONE_TIME); bool isEqual(const MEDCouplingFieldDouble *other, double meshPrec, double valsPrec) const throw(INTERP_KERNEL::Exception); bool isEqualWithoutConsideringStr(const MEDCouplingFieldDouble *other, double meshPrec, double valsPrec) const throw(INTERP_KERNEL::Exception); void setTimeUnit(const std::string& unit); std::string getTimeUnit() const; void synchronizeTimeWithSupport() throw(INTERP_KERNEL::Exception); void copyTinyAttrFrom(const MEDCouplingFieldDouble *other) throw(INTERP_KERNEL::Exception); 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); std::string writeVTK(const std::string& fileName, bool isBinary=true) const throw(INTERP_KERNEL::Exception); MEDCouplingFieldInt *convertToIntField() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldFloat *convertToFloatField() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *clone(bool recDeepCpy) const; MEDCouplingFieldDouble *cloneWithMesh(bool recDeepCpy) const; MEDCouplingFieldDouble *deepCopy() const; MEDCouplingFieldDouble *buildNewTimeReprFromThis(TypeOfTimeDiscretization td, bool deepCopy) const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *nodeToCellDiscretization() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *cellToNodeDiscretization() const throw(INTERP_KERNEL::Exception); double getIJ(int tupleId, int compoId) const throw(INTERP_KERNEL::Exception); double getIJK(int cellId, int nodeIdInCell, int compoId) const throw(INTERP_KERNEL::Exception); void synchronizeTimeWithMesh() throw(INTERP_KERNEL::Exception); void setArray(DataArrayDouble *array) throw(INTERP_KERNEL::Exception); void setEndArray(DataArrayDouble *array) throw(INTERP_KERNEL::Exception); void setTime(double val, int iteration, int order) throw(INTERP_KERNEL::Exception); 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); void setTimeTolerance(double val) throw(INTERP_KERNEL::Exception); double getTimeTolerance() const throw(INTERP_KERNEL::Exception); void setIteration(int it) throw(INTERP_KERNEL::Exception); void setEndIteration(int it) throw(INTERP_KERNEL::Exception); void setOrder(int order) throw(INTERP_KERNEL::Exception); void setEndOrder(int order) throw(INTERP_KERNEL::Exception); void setTimeValue(double val) throw(INTERP_KERNEL::Exception); void setEndTimeValue(double val) throw(INTERP_KERNEL::Exception); void changeUnderlyingMesh(const MEDCouplingMesh *other, int levOfCheck, double precOnMesh, double eps=1e-15) throw(INTERP_KERNEL::Exception); void substractInPlaceDM(const MEDCouplingFieldDouble *f, int levOfCheck, double precOnMesh, double eps=1e-15) throw(INTERP_KERNEL::Exception); bool mergeNodes(double eps, double epsOnVals=1e-15) throw(INTERP_KERNEL::Exception); bool mergeNodesCenter(double eps, double epsOnVals=1e-15) throw(INTERP_KERNEL::Exception); bool zipCoords(double epsOnVals=1e-15) throw(INTERP_KERNEL::Exception); bool zipConnectivity(int compType,double epsOnVals=1e-15) throw(INTERP_KERNEL::Exception); bool simplexize(int policy) throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *doublyContractedProduct() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *determinant() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *eigenValues() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *eigenVectors() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *inverse() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *trace() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *deviator() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *magnitude() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *maxPerTuple() const throw(INTERP_KERNEL::Exception); void changeNbOfComponents(int newNbOfComp, double dftValue=0.) throw(INTERP_KERNEL::Exception); void sortPerTuple(bool asc) throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble &operator=(double value) throw(INTERP_KERNEL::Exception); void fillFromAnalytic(int nbOfComp, const std::string& func) throw(INTERP_KERNEL::Exception); void fillFromAnalyticCompo(int nbOfComp, const std::string& func) throw(INTERP_KERNEL::Exception); void fillFromAnalyticNamedCompo(int nbOfComp, const std::vector& varsOrder, const std::string& func) throw(INTERP_KERNEL::Exception); void applyFunc(int nbOfComp, const std::string& func) throw(INTERP_KERNEL::Exception); void applyFuncCompo(int nbOfComp, const std::string& func) throw(INTERP_KERNEL::Exception); void applyFuncNamedCompo(int nbOfComp, const std::vector& varsOrder, const std::string& func) throw(INTERP_KERNEL::Exception); void applyFunc(int nbOfComp, double val) throw(INTERP_KERNEL::Exception); void applyFunc(const std::string& func) throw(INTERP_KERNEL::Exception); void applyFuncFast32(const std::string& func) throw(INTERP_KERNEL::Exception); void applyFuncFast64(const std::string& func) throw(INTERP_KERNEL::Exception); double accumulate(int compId) const throw(INTERP_KERNEL::Exception); double getMaxValue() const throw(INTERP_KERNEL::Exception); double getMinValue() const throw(INTERP_KERNEL::Exception); double getAverageValue() const throw(INTERP_KERNEL::Exception); double norm2() const throw(INTERP_KERNEL::Exception); //do not put a default value to isWAbs because confusion in python with overloaded getWeightedAverageValue method double getWeightedAverageValue(int compId, bool isWAbs) const throw(INTERP_KERNEL::Exception); double integral(int compId, bool isWAbs) const throw(INTERP_KERNEL::Exception); double normL1(int compId) const throw(INTERP_KERNEL::Exception); double normL2(int compId) const throw(INTERP_KERNEL::Exception); double normMax(int compId) const throw(INTERP_KERNEL::Exception); DataArrayInt *findIdsInRange(double vmin, double vmax) const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *buildSubPartRange(int begin, int end, int step) const throw(INTERP_KERNEL::Exception); static MEDCouplingFieldDouble *MergeFields(const MEDCouplingFieldDouble *f1, const MEDCouplingFieldDouble *f2) throw(INTERP_KERNEL::Exception); static MEDCouplingFieldDouble *MeldFields(const MEDCouplingFieldDouble *f1, const MEDCouplingFieldDouble *f2) throw(INTERP_KERNEL::Exception); static MEDCouplingFieldDouble *DotFields(const MEDCouplingFieldDouble *f1, const MEDCouplingFieldDouble *f2) throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *dot(const MEDCouplingFieldDouble& other) const throw(INTERP_KERNEL::Exception); static MEDCouplingFieldDouble *CrossProductFields(const MEDCouplingFieldDouble *f1, const MEDCouplingFieldDouble *f2) throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *crossProduct(const MEDCouplingFieldDouble& other) const throw(INTERP_KERNEL::Exception); static MEDCouplingFieldDouble *MaxFields(const MEDCouplingFieldDouble *f1, const MEDCouplingFieldDouble *f2) throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *max(const MEDCouplingFieldDouble& other) const throw(INTERP_KERNEL::Exception); static MEDCouplingFieldDouble *MinFields(const MEDCouplingFieldDouble *f1, const MEDCouplingFieldDouble *f2) throw(INTERP_KERNEL::Exception); static MEDCouplingFieldDouble *AddFields(const MEDCouplingFieldDouble *f1, const MEDCouplingFieldDouble *f2) throw(INTERP_KERNEL::Exception); static MEDCouplingFieldDouble *SubstractFields(const MEDCouplingFieldDouble *f1, const MEDCouplingFieldDouble *f2) throw(INTERP_KERNEL::Exception); static MEDCouplingFieldDouble *MultiplyFields(const MEDCouplingFieldDouble *f1, const MEDCouplingFieldDouble *f2) throw(INTERP_KERNEL::Exception); static MEDCouplingFieldDouble *DivideFields(const MEDCouplingFieldDouble *f1, const MEDCouplingFieldDouble *f2) throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *min(const MEDCouplingFieldDouble& other) const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *negate() const throw(INTERP_KERNEL::Exception); %extend { MEDCouplingFieldDouble(TypeOfField type, TypeOfTimeDiscretization td=ONE_TIME) { return MEDCouplingFieldDouble::New(type,td); } MEDCouplingFieldDouble(const MEDCouplingFieldTemplate& ft, TypeOfTimeDiscretization td=ONE_TIME) { return MEDCouplingFieldDouble::New(ft,td); } 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(); } PyObject *isEqualIfNotWhy(const MEDCouplingFieldDouble *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); PyTuple_SetItem(ret,0,ret0Py); PyTuple_SetItem(ret,1,PyString_FromString(ret1.c_str())); return ret; } MEDCouplingFieldDouble *voronoize(double eps) const throw(INTERP_KERNEL::Exception) { MCAuto ret(self->voronoize(eps)); return ret.retn(); } MEDCouplingFieldDouble *convertQuadraticCellsToLinear() const throw(INTERP_KERNEL::Exception) { MCAuto ret(self->convertQuadraticCellsToLinear()); return ret.retn(); } MEDCouplingFieldDouble *computeVectorFieldCyl(PyObject *center, PyObject *vector) const { const char msg[]="Python wrap of MEDCouplingFieldDouble::computeVectorFieldCyl : "; double val,val2; DataArrayDouble *a,*a2; DataArrayDoubleTuple *aa,*aa2; std::vector bb,bb2; int sw; const double *centerPtr=convertObjToPossibleCpp5_Safe(center,sw,val,a,aa,bb,msg,1,3,true); const double *vectorPtr=convertObjToPossibleCpp5_Safe(vector,sw,val2,a2,aa2,bb2,msg,1,3,true); return self->computeVectorFieldCyl(centerPtr,vectorPtr); } DataArrayDouble *getArray() throw(INTERP_KERNEL::Exception) { DataArrayDouble *ret=self->getArray(); if(ret) ret->incrRef(); return ret; } PyObject *getArrays() const throw(INTERP_KERNEL::Exception) { std::vector arrs=self->getArrays(); for(std::vector::iterator it=arrs.begin();it!=arrs.end();it++) if(*it) (*it)->incrRef(); int sz=arrs.size(); PyObject *ret=PyTuple_New(sz); for(int i=0;i tmp; convertFromPyObjVectorOfObj(ls,SWIGTYPE_p_MEDCoupling__DataArrayDouble,"DataArrayDouble",tmp); int sz=tmp.size(); std::vector arrs(sz); for(int i=0;i(tmp[i]); self->setArrays(arrs); } DataArrayDouble *getEndArray() throw(INTERP_KERNEL::Exception) { DataArrayDouble *ret=self->getEndArray(); if(ret) ret->incrRef(); return ret; } PyObject *getValueOn(PyObject *sl) const throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; const MEDCouplingMesh *mesh=self->getMesh(); if(!mesh) throw INTERP_KERNEL::Exception("Python wrap of MEDCouplingFieldDouble::getValueOn : no underlying mesh !"); int spaceDim=mesh->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingFieldDouble::getValueOn : "; const double *spaceLoc=convertObjToPossibleCpp5_Safe(sl,sw,val,a,aa,bb,msg,1,spaceDim,true); // int sz=self->getNumberOfComponents(); INTERP_KERNEL::AutoPtr res=new double[sz]; self->getValueOn(spaceLoc,res); return convertDblArrToPyList(res,sz); } PyObject *getValueOnPos(int i, int j, int k) const throw(INTERP_KERNEL::Exception) { int sz=self->getNumberOfComponents(); INTERP_KERNEL::AutoPtr res=new double[sz]; self->getValueOnPos(i,j,k,res); return convertDblArrToPyList(res,sz); } DataArrayDouble *getValueOnMulti(PyObject *locs) const throw(INTERP_KERNEL::Exception) { const MEDCouplingMesh *mesh(self->getMesh()); if(!mesh) throw INTERP_KERNEL::Exception("Python wrap MEDCouplingFieldDouble::getValueOnMulti : lying on a null mesh !"); // int sw,nbPts; double v0; MEDCoupling::DataArrayDouble *v1(0); MEDCoupling::DataArrayDoubleTuple *v2(0); std::vector v3; const double *inp=convertObjToPossibleCpp5_Safe2(locs,sw,v0,v1,v2,v3,"wrap of MEDCouplingFieldDouble::getValueOnMulti", mesh->getSpaceDimension(),true,nbPts); return self->getValueOnMulti(inp,nbPts); } PyObject *getValueOn(PyObject *sl, double time) const throw(INTERP_KERNEL::Exception) { double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; const MEDCouplingMesh *mesh=self->getMesh(); if(!mesh) throw INTERP_KERNEL::Exception("Python wrap of MEDCouplingFieldDouble::getValueOn : no underlying mesh !"); int spaceDim=mesh->getSpaceDimension(); const char msg[]="Python wrap of MEDCouplingFieldDouble::getValueOn : "; const double *spaceLoc=convertObjToPossibleCpp5_Safe(sl,sw,val,a,aa,bb,msg,1,spaceDim,true); // // int sz=self->getNumberOfComponents(); INTERP_KERNEL::AutoPtr res=new double[sz]; self->getValueOn(spaceLoc,time,res); return convertDblArrToPyList(res,sz); } void setValues(PyObject *li, PyObject *nbOfTuples=0, PyObject *nbOfComp=0) throw(INTERP_KERNEL::Exception) { if(self->getArray()!=0) MEDCoupling_DataArrayDouble_setValues__SWIG_0(self->getArray(),li,nbOfTuples,nbOfComp); else { MCAuto arr=DataArrayDouble::New(); MEDCoupling_DataArrayDouble_setValues__SWIG_0(arr,li,nbOfTuples,nbOfComp); self->setArray(arr); } } PyObject *getTime() throw(INTERP_KERNEL::Exception) { int tmp1,tmp2; double tmp0=self->getTime(tmp1,tmp2); PyObject *res = PyList_New(3); PyList_SetItem(res,0,SWIG_From_double(tmp0)); PyList_SetItem(res,1,SWIG_From_int(tmp1)); PyList_SetItem(res,2,SWIG_From_int(tmp2)); return res; } PyObject *getStartTime() throw(INTERP_KERNEL::Exception) { int tmp1,tmp2; double tmp0=self->getStartTime(tmp1,tmp2); PyObject *res = PyList_New(3); PyList_SetItem(res,0,SWIG_From_double(tmp0)); PyList_SetItem(res,1,SWIG_From_int(tmp1)); PyList_SetItem(res,2,SWIG_From_int(tmp2)); return res; } PyObject *getEndTime() throw(INTERP_KERNEL::Exception) { int tmp1,tmp2; double tmp0=self->getEndTime(tmp1,tmp2); PyObject *res = PyList_New(3); PyList_SetItem(res,0,SWIG_From_double(tmp0)); PyList_SetItem(res,1,SWIG_From_int(tmp1)); PyList_SetItem(res,2,SWIG_From_int(tmp2)); return res; } PyObject *accumulate() const throw(INTERP_KERNEL::Exception) { int sz=self->getNumberOfComponents(); INTERP_KERNEL::AutoPtr tmp=new double[sz]; self->accumulate(tmp); return convertDblArrToPyList(tmp,sz); } PyObject *integral(bool isWAbs) const throw(INTERP_KERNEL::Exception) { int sz=self->getNumberOfComponents(); INTERP_KERNEL::AutoPtr tmp=new double[sz]; self->integral(isWAbs,tmp); return convertDblArrToPyList(tmp,sz); } PyObject *getWeightedAverageValue(bool isWAbs=true) const throw(INTERP_KERNEL::Exception) { int sz=self->getNumberOfComponents(); INTERP_KERNEL::AutoPtr tmp=new double[sz]; self->getWeightedAverageValue(tmp,isWAbs); return convertDblArrToPyList(tmp,sz); } PyObject *normL1() const throw(INTERP_KERNEL::Exception) { int sz=self->getNumberOfComponents(); INTERP_KERNEL::AutoPtr tmp=new double[sz]; self->normL1(tmp); return convertDblArrToPyList(tmp,sz); } PyObject *normL2() const throw(INTERP_KERNEL::Exception) { int sz=self->getNumberOfComponents(); INTERP_KERNEL::AutoPtr tmp=new double[sz]; self->normL2(tmp); return convertDblArrToPyList(tmp,sz); } PyObject *normMax() const throw(INTERP_KERNEL::Exception) { int sz=self->getNumberOfComponents(); INTERP_KERNEL::AutoPtr tmp=new double[sz]; self->normMax(tmp); return convertDblArrToPyList(tmp,sz); } void renumberCells(PyObject *li, bool check=true) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); self->renumberCells(tmp,check); } void renumberCellsWithoutMesh(PyObject *li, bool check=true) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); self->renumberCellsWithoutMesh(tmp,check); } void renumberNodes(PyObject *li, double eps=1e-15) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); self->renumberNodes(tmp,eps); } void renumberNodesWithoutMesh(PyObject *li, int newNbOfNodes, double eps=1e-15) throw(INTERP_KERNEL::Exception) { int szArr,sw,iTypppArr; std::vector stdvecTyyppArr; const int *tmp=convertIntStarLikePyObjToCppIntStar(li,sw,szArr,iTypppArr,stdvecTyyppArr); self->renumberNodesWithoutMesh(tmp,newNbOfNodes,eps); } MEDCouplingFieldDouble *buildSubPart(PyObject *li) const throw(INTERP_KERNEL::Exception) { return fieldT_buildSubPart(self,li); } MEDCouplingFieldDouble *__getitem__(PyObject *li) const throw(INTERP_KERNEL::Exception) { return fieldT__getitem__(self,li); } PyObject *getMaxValue2() const throw(INTERP_KERNEL::Exception) { DataArrayInt *tmp; double r1=self->getMaxValue2(tmp); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,PyFloat_FromDouble(r1)); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(tmp),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } PyObject *getMinValue2() const throw(INTERP_KERNEL::Exception) { DataArrayInt *tmp; double r1=self->getMinValue2(tmp); PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,PyFloat_FromDouble(r1)); PyTuple_SetItem(ret,1,SWIG_NewPointerObj(SWIG_as_voidptr(tmp),SWIGTYPE_p_MEDCoupling__DataArrayInt, SWIG_POINTER_OWN | 0 )); return ret; } MEDCouplingFieldDouble *keepSelectedComponents(PyObject *li) const throw(INTERP_KERNEL::Exception) { std::vector tmp; convertPyToNewIntArr3(li,tmp); return self->keepSelectedComponents(tmp); } void setSelectedComponents(const MEDCouplingFieldDouble *f, PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertPyToNewIntArr3(li,tmp); self->setSelectedComponents(f,tmp); } MEDCouplingFieldDouble *extractSlice3D(PyObject *origin, PyObject *vec, double eps) const throw(INTERP_KERNEL::Exception) { double val,val2; DataArrayDouble *a,*a2; DataArrayDoubleTuple *aa,*aa2; std::vector bb,bb2; int sw; int spaceDim=3; const char msg[]="Python wrap of MEDCouplingFieldDouble::extractSlice3D : 1st parameter for origin."; const char msg2[]="Python wrap of MEDCouplingFieldDouble::extractSlice3D : 2nd parameter for vector."; const double *orig=convertObjToPossibleCpp5_Safe(origin,sw,val,a,aa,bb,msg,1,spaceDim,true); const double *vect=convertObjToPossibleCpp5_Safe(vec,sw,val2,a2,aa2,bb2,msg2,1,spaceDim,true); // return self->extractSlice3D(orig,vect,eps); } MEDCouplingFieldDouble *__add__(PyObject *obj) throw(INTERP_KERNEL::Exception) { return MEDCoupling_MEDCouplingFieldDouble___add__Impl(self,obj); } MEDCouplingFieldDouble *__radd__(PyObject *obj) throw(INTERP_KERNEL::Exception) { return MEDCoupling_MEDCouplingFieldDouble___radd__Impl(self,obj); } MEDCouplingFieldDouble *__sub__(PyObject *obj) throw(INTERP_KERNEL::Exception) { const char msg[]="Unexpected situation in MEDCouplingFieldDouble.__sub__ ! Expecting a not null MEDCouplingFieldDouble or DataArrayDouble or DataArrayDoubleTuple instance, or a list of double, or a double."; const char msg2[]="in MEDCouplingFieldDouble.__sub__ : self field has no Array of values set !"; void *argp; // if(SWIG_IsOK(SWIG_ConvertPtr(obj,&argp,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,0|0))) { MEDCouplingFieldDouble *other=reinterpret_cast< MEDCoupling::MEDCouplingFieldDouble * >(argp); if(other) return (*self)-(*other); else throw INTERP_KERNEL::Exception(msg); } // double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; convertDoubleStarLikePyObjToCpp_2(obj,sw,val,a,aa,bb); switch(sw) { case 1: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto ret=self->getArray()->deepCopy(); ret->applyLin(1.,-val); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } case 2: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto ret=DataArrayDouble::Substract(self->getArray(),a); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } case 3: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto aaa=aa->buildDADouble(1,self->getNumberOfComponents()); MCAuto ret=DataArrayDouble::Substract(self->getArray(),aaa); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } case 4: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto aaa=DataArrayDouble::New(); aaa->useArray(&bb[0],false,CPP_DEALLOC,1,(int)bb.size()); MCAuto ret=DataArrayDouble::Substract(self->getArray(),aaa); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } default: { throw INTERP_KERNEL::Exception(msg); } } } MEDCouplingFieldDouble *__rsub__(PyObject *obj) throw(INTERP_KERNEL::Exception) { return MEDCoupling_MEDCouplingFieldDouble___rsub__Impl(self,obj); } MEDCouplingFieldDouble *__mul__(PyObject *obj) throw(INTERP_KERNEL::Exception) { return MEDCoupling_MEDCouplingFieldDouble___mul__Impl(self,obj); } MEDCouplingFieldDouble *__rmul__(PyObject *obj) throw(INTERP_KERNEL::Exception) { return MEDCoupling_MEDCouplingFieldDouble___rmul__Impl(self,obj); } MEDCouplingFieldDouble *__div__(PyObject *obj) throw(INTERP_KERNEL::Exception) { const char msg[]="Unexpected situation in MEDCouplingFieldDouble.__div__ ! Expecting a not null MEDCouplingFieldDouble or DataArrayDouble or DataArrayDoubleTuple instance, or a list of double, or a double."; const char msg2[]="in MEDCouplingFieldDouble.__div__ : self field has no Array of values set !"; void *argp; // if(SWIG_IsOK(SWIG_ConvertPtr(obj,&argp,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,0|0))) { MEDCouplingFieldDouble *other=reinterpret_cast< MEDCoupling::MEDCouplingFieldDouble * >(argp); if(other) return (*self)/(*other); else throw INTERP_KERNEL::Exception(msg); } // double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; convertDoubleStarLikePyObjToCpp_2(obj,sw,val,a,aa,bb); switch(sw) { case 1: { if(val==0.) throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble.__div__ : trying to divide by zero !"); if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto ret=self->getArray()->deepCopy(); ret->applyLin(1./val,0); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } case 2: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto ret=DataArrayDouble::Divide(self->getArray(),a); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } case 3: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto aaa=aa->buildDADouble(1,self->getNumberOfComponents()); MCAuto ret=DataArrayDouble::Divide(self->getArray(),aaa); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } case 4: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto aaa=DataArrayDouble::New(); aaa->useArray(&bb[0],false,CPP_DEALLOC,1,(int)bb.size()); MCAuto ret=DataArrayDouble::Divide(self->getArray(),aaa); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } default: { throw INTERP_KERNEL::Exception(msg); } } } MEDCouplingFieldDouble *__rdiv__(PyObject *obj) throw(INTERP_KERNEL::Exception) { return MEDCoupling_MEDCouplingFieldDouble___rdiv__Impl(self,obj); } MEDCouplingFieldDouble *__pow__(PyObject *obj) throw(INTERP_KERNEL::Exception) { const char msg[]="Unexpected situation in MEDCouplingFieldDouble.__pow__ ! Expecting a not null MEDCouplingFieldDouble or DataArrayDouble or DataArrayDoubleTuple instance, or a list of double, or a double."; const char msg2[]="in MEDCouplingFieldDouble.__pow__ : self field has no Array of values set !"; void *argp; // if(SWIG_IsOK(SWIG_ConvertPtr(obj,&argp,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,0|0))) { MEDCouplingFieldDouble *other=reinterpret_cast< MEDCoupling::MEDCouplingFieldDouble * >(argp); if(other) return (*self)^(*other); else throw INTERP_KERNEL::Exception(msg); } // double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; convertDoubleStarLikePyObjToCpp_2(obj,sw,val,a,aa,bb); switch(sw) { case 1: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto ret=self->getArray()->deepCopy(); ret->applyPow(val); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } case 2: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto ret=DataArrayDouble::Pow(self->getArray(),a); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } case 3: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto aaa=aa->buildDADouble(1,self->getNumberOfComponents()); MCAuto ret=DataArrayDouble::Pow(self->getArray(),aaa); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } case 4: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto aaa=DataArrayDouble::New(); aaa->useArray(&bb[0],false,CPP_DEALLOC,1,(int)bb.size()); MCAuto ret=DataArrayDouble::Pow(self->getArray(),aaa); MCAuto ret2=self->clone(false); ret2->setArray(ret); return ret2.retn(); } default: { throw INTERP_KERNEL::Exception(msg); } } } MEDCouplingFieldDouble *__neg__() const throw(INTERP_KERNEL::Exception) { return self->negate(); } PyObject *___iadd___(PyObject *trueSelf, PyObject *obj) throw(INTERP_KERNEL::Exception) { const char msg[]="Unexpected situation in MEDCouplingFieldDouble.__iadd__ ! Expecting a not null MEDCouplingFieldDouble or DataArrayDouble or DataArrayDoubleTuple instance, or a list of double, or a double."; const char msg2[]="in MEDCouplingFieldDouble.__iadd__ : self field has no Array of values set !"; void *argp; // if(SWIG_IsOK(SWIG_ConvertPtr(obj,&argp,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,0|0))) { MEDCouplingFieldDouble *other=reinterpret_cast< MEDCoupling::MEDCouplingFieldDouble * >(argp); if(other) { *self+=*other; Py_XINCREF(trueSelf); return trueSelf; } else throw INTERP_KERNEL::Exception(msg); } // double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; convertDoubleStarLikePyObjToCpp_2(obj,sw,val,a,aa,bb); switch(sw) { case 1: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); self->getArray()->applyLin(1.,val); Py_XINCREF(trueSelf); return trueSelf; } case 2: { MCAuto ret2=self->clone(false); ret2->setArray(a); *self+=*ret2; Py_XINCREF(trueSelf); return trueSelf; } case 3: { MCAuto aaa=aa->buildDADouble(1,self->getNumberOfComponents()); MCAuto ret2=self->clone(false); ret2->setArray(aaa); *self+=*ret2; Py_XINCREF(trueSelf); return trueSelf; } case 4: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto aaa=DataArrayDouble::New(); aaa->useArray(&bb[0],false,CPP_DEALLOC,1,(int)bb.size()); self->getArray()->addEqual(aaa); Py_XINCREF(trueSelf); return trueSelf; } default: { throw INTERP_KERNEL::Exception(msg); } } } PyObject *___isub___(PyObject *trueSelf, PyObject *obj) throw(INTERP_KERNEL::Exception) { const char msg[]="Unexpected situation in MEDCouplingFieldDouble.__isub__ ! Expecting a not null MEDCouplingFieldDouble or DataArrayDouble or DataArrayDoubleTuple instance, or a list of double, or a double."; const char msg2[]="in MEDCouplingFieldDouble.__isub__ : self field has no Array of values set !"; void *argp; // if(SWIG_IsOK(SWIG_ConvertPtr(obj,&argp,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,0|0))) { MEDCouplingFieldDouble *other=reinterpret_cast< MEDCoupling::MEDCouplingFieldDouble * >(argp); if(other) { *self-=*other; Py_XINCREF(trueSelf); return trueSelf; } else throw INTERP_KERNEL::Exception(msg); } // double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; convertDoubleStarLikePyObjToCpp_2(obj,sw,val,a,aa,bb); switch(sw) { case 1: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); self->getArray()->applyLin(1.,-val); Py_XINCREF(trueSelf); return trueSelf; } case 2: { MCAuto ret2=self->clone(false); ret2->setArray(a); *self-=*ret2; Py_XINCREF(trueSelf); return trueSelf; } case 3: { MCAuto aaa=aa->buildDADouble(1,self->getNumberOfComponents()); MCAuto ret2=self->clone(false); ret2->setArray(aaa); *self-=*ret2; Py_XINCREF(trueSelf); return trueSelf; } case 4: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto aaa=DataArrayDouble::New(); aaa->useArray(&bb[0],false,CPP_DEALLOC,1,(int)bb.size()); self->getArray()->substractEqual(aaa); Py_XINCREF(trueSelf); return trueSelf; } default: { throw INTERP_KERNEL::Exception(msg); } } } PyObject *___imul___(PyObject *trueSelf, PyObject *obj) throw(INTERP_KERNEL::Exception) { const char msg[]="Unexpected situation in MEDCouplingFieldDouble.__imul__ ! Expecting a not null MEDCouplingFieldDouble or DataArrayDouble or DataArrayDoubleTuple instance, or a list of double, or a double."; const char msg2[]="in MEDCouplingFieldDouble.__imul__ : self field has no Array of values set !"; void *argp; // if(SWIG_IsOK(SWIG_ConvertPtr(obj,&argp,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,0|0))) { MEDCouplingFieldDouble *other=reinterpret_cast< MEDCoupling::MEDCouplingFieldDouble * >(argp); if(other) { *self*=*other; Py_XINCREF(trueSelf); return trueSelf; } else throw INTERP_KERNEL::Exception(msg); } // double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; convertDoubleStarLikePyObjToCpp_2(obj,sw,val,a,aa,bb); switch(sw) { case 1: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); self->getArray()->applyLin(val,0); Py_XINCREF(trueSelf); return trueSelf; } case 2: { MCAuto ret2=self->clone(false); ret2->setArray(a); *self*=*ret2; Py_XINCREF(trueSelf); return trueSelf; } case 3: { MCAuto aaa=aa->buildDADouble(1,self->getNumberOfComponents()); MCAuto ret2=self->clone(false); ret2->setArray(aaa); *self*=*ret2; Py_XINCREF(trueSelf); return trueSelf; } case 4: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto aaa=DataArrayDouble::New(); aaa->useArray(&bb[0],false,CPP_DEALLOC,1,(int)bb.size()); self->getArray()->multiplyEqual(aaa); Py_XINCREF(trueSelf); return trueSelf; } default: { throw INTERP_KERNEL::Exception(msg); } } } PyObject *___idiv___(PyObject *trueSelf, PyObject *obj) throw(INTERP_KERNEL::Exception) { const char msg[]="Unexpected situation in MEDCouplingFieldDouble.__idiv__ ! Expecting a not null MEDCouplingFieldDouble or DataArrayDouble or DataArrayDoubleTuple instance, or a list of double, or a double."; const char msg2[]="in MEDCouplingFieldDouble.__idiv__ : self field has no Array of values set !"; void *argp; // if(SWIG_IsOK(SWIG_ConvertPtr(obj,&argp,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,0|0))) { MEDCouplingFieldDouble *other=reinterpret_cast< MEDCoupling::MEDCouplingFieldDouble * >(argp); if(other) { *self/=*other; Py_XINCREF(trueSelf); return trueSelf; } else throw INTERP_KERNEL::Exception(msg); } // double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; convertDoubleStarLikePyObjToCpp_2(obj,sw,val,a,aa,bb); switch(sw) { case 1: { if(val==0.) throw INTERP_KERNEL::Exception("MEDCouplingFieldDouble.__idiv__ : trying to divide by zero !"); if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); self->getArray()->applyLin(1./val,0); Py_XINCREF(trueSelf); return trueSelf; } case 2: { MCAuto ret2=self->clone(false); ret2->setArray(a); *self/=*ret2; Py_XINCREF(trueSelf); return trueSelf; } case 3: { MCAuto aaa=aa->buildDADouble(1,self->getNumberOfComponents()); MCAuto ret2=self->clone(false); ret2->setArray(aaa); *self/=*ret2; Py_XINCREF(trueSelf); return trueSelf; } case 4: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto aaa=DataArrayDouble::New(); aaa->useArray(&bb[0],false,CPP_DEALLOC,1,(int)bb.size()); self->getArray()->divideEqual(aaa); Py_XINCREF(trueSelf); return trueSelf; } default: { throw INTERP_KERNEL::Exception(msg); } } } PyObject *___ipow___(PyObject *trueSelf, PyObject *obj) throw(INTERP_KERNEL::Exception) { const char msg[]="Unexpected situation in MEDCouplingFieldDouble.__ipow__ ! Expecting a not null MEDCouplingFieldDouble or DataArrayDouble or DataArrayDoubleTuple instance, or a list of double, or a double."; const char msg2[]="in MEDCouplingFieldDouble.__ipow__ : self field has no Array of values set !"; void *argp; // if(SWIG_IsOK(SWIG_ConvertPtr(obj,&argp,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,0|0))) { MEDCouplingFieldDouble *other=reinterpret_cast< MEDCoupling::MEDCouplingFieldDouble * >(argp); if(other) { *self^=*other; Py_XINCREF(trueSelf); return trueSelf; } else throw INTERP_KERNEL::Exception(msg); } // double val; DataArrayDouble *a; DataArrayDoubleTuple *aa; std::vector bb; int sw; convertDoubleStarLikePyObjToCpp_2(obj,sw,val,a,aa,bb); switch(sw) { case 1: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); self->getArray()->applyPow(val); Py_XINCREF(trueSelf); return trueSelf; } case 2: { MCAuto ret2=self->clone(false); ret2->setArray(a); *self^=*ret2; Py_XINCREF(trueSelf); return trueSelf; } case 3: { MCAuto aaa=aa->buildDADouble(1,self->getNumberOfComponents()); MCAuto ret2=self->clone(false); ret2->setArray(aaa); *self^=*ret2; Py_XINCREF(trueSelf); return trueSelf; } case 4: { if(!self->getArray()) throw INTERP_KERNEL::Exception(msg2); MCAuto aaa=DataArrayDouble::New(); aaa->useArray(&bb[0],false,CPP_DEALLOC,1,(int)bb.size()); self->getArray()->powEqual(aaa); Py_XINCREF(trueSelf); return trueSelf; } default: { throw INTERP_KERNEL::Exception(msg); } } } static MEDCouplingFieldDouble *MergeFields(PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,"MEDCouplingFieldDouble",tmp); return MEDCouplingFieldDouble::MergeFields(tmp); } static std::string WriteVTK(const char *fileName, PyObject *li, bool isBinary=true) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,"MEDCouplingFieldDouble",tmp); return MEDCouplingFieldDouble::WriteVTK(fileName,tmp,isBinary); } PyObject *getTinySerializationInformation() const throw(INTERP_KERNEL::Exception) { return field_getTinySerializationInformation(self); } PyObject *serialize() const throw(INTERP_KERNEL::Exception) { return field_serialize(self); } PyObject *__getstate__() const throw(INTERP_KERNEL::Exception) { return field__getstate__(self,MEDCoupling_MEDCouplingFieldDouble_getTinySerializationInformation,MEDCoupling_MEDCouplingFieldDouble_serialize); } void __setstate__(PyObject *inp) throw(INTERP_KERNEL::Exception) { field__setstate__(self,inp); } } }; class MEDCouplingMultiFields : public RefCountObject, public TimeLabel { public: int getNumberOfFields() const; MEDCouplingMultiFields *deepCopy() const; virtual std::string simpleRepr() const throw(INTERP_KERNEL::Exception); virtual std::string advancedRepr() const throw(INTERP_KERNEL::Exception); virtual bool isEqual(const MEDCouplingMultiFields *other, double meshPrec, double valsPrec) const; virtual bool isEqualWithoutConsideringStr(const MEDCouplingMultiFields *other, double meshPrec, double valsPrec) const; virtual void checkConsistencyLight() const throw(INTERP_KERNEL::Exception); %extend { std::string __str__() const throw(INTERP_KERNEL::Exception) { return self->simpleRepr(); } static MEDCouplingMultiFields *New(PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,"MEDCouplingFieldDouble",tmp); int sz=tmp.size(); std::vector fs(sz); for(int i=0;i(tmp[i]); return MEDCouplingMultiFields::New(fs); } MEDCouplingMultiFields(PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,"MEDCouplingFieldDouble",tmp); int sz=tmp.size(); std::vector fs(sz); for(int i=0;i(tmp[i]); return MEDCouplingMultiFields::New(fs); } PyObject *getFields() const { std::vector fields=self->getFields(); int sz=fields.size(); PyObject *res = PyList_New(sz); for(int i=0;iincrRef(); PyList_SetItem(res,i,SWIG_NewPointerObj(SWIG_as_voidptr(fields[i]),SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble, SWIG_POINTER_OWN | 0 )); } else { PyList_SetItem(res,i,SWIG_NewPointerObj(SWIG_as_voidptr(0),SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble, 0 )); } } return res; } PyObject *getFieldAtPos(int id) const throw(INTERP_KERNEL::Exception) { const MEDCouplingFieldDouble *ret=self->getFieldAtPos(id); if(ret) { ret->incrRef(); return SWIG_NewPointerObj(SWIG_as_voidptr(ret),SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble, SWIG_POINTER_OWN | 0 ); } else return SWIG_NewPointerObj(SWIG_as_voidptr(0),SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble, 0 ); } PyObject *getMeshes() const throw(INTERP_KERNEL::Exception) { std::vector ms=self->getMeshes(); int sz=ms.size(); PyObject *res = PyList_New(sz); for(int i=0;iincrRef(); PyList_SetItem(res,i,convertMesh(ms[i], SWIG_POINTER_OWN | 0 )); } else { PyList_SetItem(res,i,SWIG_NewPointerObj(SWIG_as_voidptr(0),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, 0 )); } } return res; } PyObject *getDifferentMeshes() const throw(INTERP_KERNEL::Exception) { std::vector refs; std::vector ms=self->getDifferentMeshes(refs); int sz=ms.size(); PyObject *res = PyList_New(sz); for(int i=0;iincrRef(); PyList_SetItem(res,i,convertMesh(ms[i], SWIG_POINTER_OWN | 0 )); } else { PyList_SetItem(res,i,SWIG_NewPointerObj(SWIG_as_voidptr(0),SWIGTYPE_p_MEDCoupling__MEDCouplingUMesh, 0 )); } } // PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,res); PyTuple_SetItem(ret,1,convertIntArrToPyList2(refs)); return ret; } PyObject *getArrays() const throw(INTERP_KERNEL::Exception) { std::vector ms=self->getArrays(); int sz=ms.size(); PyObject *res = PyList_New(sz); for(int i=0;iincrRef(); PyList_SetItem(res,i,SWIG_NewPointerObj(SWIG_as_voidptr(ms[i]),SWIGTYPE_p_MEDCoupling__DataArrayDouble, SWIG_POINTER_OWN | 0 )); } else { PyList_SetItem(res,i,SWIG_NewPointerObj(SWIG_as_voidptr(0),SWIGTYPE_p_MEDCoupling__DataArrayDouble, 0 )); } } return res; } PyObject *getDifferentArrays() const throw(INTERP_KERNEL::Exception) { std::vector< std::vector > refs; std::vector ms=self->getDifferentArrays(refs); int sz=ms.size(); PyObject *res = PyList_New(sz); PyObject *res2 = PyList_New(sz); for(int i=0;iincrRef(); PyList_SetItem(res,i,SWIG_NewPointerObj(SWIG_as_voidptr(ms[i]),SWIGTYPE_p_MEDCoupling__DataArrayDouble, SWIG_POINTER_OWN | 0 )); } else { PyList_SetItem(res,i,SWIG_NewPointerObj(SWIG_as_voidptr(0),SWIGTYPE_p_MEDCoupling__DataArrayDouble, 0 )); } PyList_SetItem(res2,i,convertIntArrToPyList2(refs[i])); } // PyObject *ret=PyTuple_New(2); PyTuple_SetItem(ret,0,res); PyTuple_SetItem(ret,1,res2); return ret; } } }; class MEDCouplingFieldInt : public MEDCouplingFieldT { public: static MEDCouplingFieldInt *New(TypeOfField type, TypeOfTimeDiscretization td=ONE_TIME); static MEDCouplingFieldInt *New(const MEDCouplingFieldTemplate& ft, TypeOfTimeDiscretization td=ONE_TIME); bool isEqual(const MEDCouplingFieldInt *other, double meshPrec, int valsPrec) const throw(INTERP_KERNEL::Exception); bool isEqualWithoutConsideringStr(const MEDCouplingFieldInt *other, double meshPrec, int valsPrec) const throw(INTERP_KERNEL::Exception); void setTimeUnit(const std::string& unit) throw(INTERP_KERNEL::Exception); std::string getTimeUnit() const throw(INTERP_KERNEL::Exception); void setTime(double val, int iteration, int order) throw(INTERP_KERNEL::Exception); void setArray(DataArrayInt *array) throw(INTERP_KERNEL::Exception); MEDCouplingFieldInt *deepCopy() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldInt *clone(bool recDeepCpy) const throw(INTERP_KERNEL::Exception); MEDCouplingFieldInt *cloneWithMesh(bool recDeepCpy) const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *convertToDblField() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldInt *buildSubPartRange(int begin, int end, int step) const throw(INTERP_KERNEL::Exception); %extend { MEDCouplingFieldInt(TypeOfField type, TypeOfTimeDiscretization td=ONE_TIME) { return MEDCouplingFieldInt::New(type,td); } MEDCouplingFieldInt(const MEDCouplingFieldTemplate& ft, TypeOfTimeDiscretization td=ONE_TIME) { return MEDCouplingFieldInt::New(ft,td); } PyObject *isEqualIfNotWhy(const MEDCouplingFieldInt *other, double meshPrec, int 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); PyTuple_SetItem(ret,0,ret0Py); PyTuple_SetItem(ret,1,PyString_FromString(ret1.c_str())); return ret; } 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(); } MEDCouplingFieldInt *buildSubPart(PyObject *li) const throw(INTERP_KERNEL::Exception) { return fieldT_buildSubPart(self,li); } MEDCouplingFieldInt *__getitem__(PyObject *li) const throw(INTERP_KERNEL::Exception) { return fieldT__getitem__(self,li); } DataArrayInt *getArray() throw(INTERP_KERNEL::Exception) { DataArrayInt *ret=self->getArray(); if(ret) ret->incrRef(); return ret; } PyObject *getTime() throw(INTERP_KERNEL::Exception) { int tmp1,tmp2; double tmp0=self->getTime(tmp1,tmp2); PyObject *res = PyList_New(3); PyList_SetItem(res,0,SWIG_From_double(tmp0)); PyList_SetItem(res,1,SWIG_From_int(tmp1)); PyList_SetItem(res,2,SWIG_From_int(tmp2)); return res; } PyObject *getTinySerializationInformation() const throw(INTERP_KERNEL::Exception) { return field_getTinySerializationInformation(self); } PyObject *serialize() const throw(INTERP_KERNEL::Exception) { return field_serialize(self); } PyObject *__getstate__() const throw(INTERP_KERNEL::Exception) { return field__getstate__(self,MEDCoupling_MEDCouplingFieldInt_getTinySerializationInformation,MEDCoupling_MEDCouplingFieldInt_serialize); } void __setstate__(PyObject *inp) throw(INTERP_KERNEL::Exception) { field__setstate__(self,inp); } } }; class MEDCouplingFieldFloat : public MEDCouplingFieldT { public: static MEDCouplingFieldFloat *New(TypeOfField type, TypeOfTimeDiscretization td=ONE_TIME); static MEDCouplingFieldFloat *New(const MEDCouplingFieldTemplate& ft, TypeOfTimeDiscretization td=ONE_TIME); bool isEqual(const MEDCouplingFieldFloat *other, double meshPrec, float valsPrec) const throw(INTERP_KERNEL::Exception); bool isEqualWithoutConsideringStr(const MEDCouplingFieldFloat *other, double meshPrec, float valsPrec) const throw(INTERP_KERNEL::Exception); void setTimeUnit(const std::string& unit) throw(INTERP_KERNEL::Exception); std::string getTimeUnit() const throw(INTERP_KERNEL::Exception); void setTime(double val, int iteration, int order) throw(INTERP_KERNEL::Exception); void setArray(DataArrayFloat *array) throw(INTERP_KERNEL::Exception); MEDCouplingFieldFloat *deepCopy() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldFloat *clone(bool recDeepCpy) const throw(INTERP_KERNEL::Exception); MEDCouplingFieldFloat *cloneWithMesh(bool recDeepCpy) const throw(INTERP_KERNEL::Exception); MEDCouplingFieldDouble *convertToDblField() const throw(INTERP_KERNEL::Exception); MEDCouplingFieldFloat *buildSubPartRange(int begin, int end, int step) const throw(INTERP_KERNEL::Exception); %extend { MEDCouplingFieldFloat(TypeOfField type, TypeOfTimeDiscretization td=ONE_TIME) { return MEDCouplingFieldFloat::New(type,td); } MEDCouplingFieldFloat(const MEDCouplingFieldTemplate& ft, TypeOfTimeDiscretization td=ONE_TIME) { return MEDCouplingFieldFloat::New(ft,td); } PyObject *isEqualIfNotWhy(const MEDCouplingFieldFloat *other, double meshPrec, float 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); PyTuple_SetItem(ret,0,ret0Py); PyTuple_SetItem(ret,1,PyString_FromString(ret1.c_str())); return ret; } 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(); } MEDCouplingFieldFloat *buildSubPart(PyObject *li) const throw(INTERP_KERNEL::Exception) { return fieldT_buildSubPart(self,li); } MEDCouplingFieldFloat *__getitem__(PyObject *li) const throw(INTERP_KERNEL::Exception) { return fieldT__getitem__(self,li); } DataArrayFloat *getArray() throw(INTERP_KERNEL::Exception) { DataArrayFloat *ret=self->getArray(); if(ret) ret->incrRef(); return ret; } PyObject *getTime() throw(INTERP_KERNEL::Exception) { int tmp1,tmp2; double tmp0=self->getTime(tmp1,tmp2); PyObject *res = PyList_New(3); PyList_SetItem(res,0,SWIG_From_double(tmp0)); PyList_SetItem(res,1,SWIG_From_int(tmp1)); PyList_SetItem(res,2,SWIG_From_int(tmp2)); return res; } PyObject *getTinySerializationInformation() const throw(INTERP_KERNEL::Exception) { return field_getTinySerializationInformation(self); } PyObject *serialize() const throw(INTERP_KERNEL::Exception) { return field_serialize(self); } PyObject *__getstate__() const throw(INTERP_KERNEL::Exception) { return field__getstate__(self,MEDCoupling_MEDCouplingFieldFloat_getTinySerializationInformation,MEDCoupling_MEDCouplingFieldFloat_serialize); } void __setstate__(PyObject *inp) throw(INTERP_KERNEL::Exception) { field__setstate__(self,inp); } } }; class MEDCouplingDefinitionTime { public: MEDCouplingDefinitionTime(); void assign(const MEDCouplingDefinitionTime& other); bool isEqual(const MEDCouplingDefinitionTime& other) const; double getTimeResolution() const; std::vector getHotSpotsTime() const; %extend { std::string __str__() const throw(INTERP_KERNEL::Exception) { std::ostringstream oss; self->appendRepr(oss); return oss.str(); } PyObject *getIdsOnTimeRight(double tm) const throw(INTERP_KERNEL::Exception) { int meshId,arrId,arrIdInField,fieldId; self->getIdsOnTimeRight(tm,meshId,arrId,arrIdInField,fieldId); PyObject *res=PyList_New(4); PyList_SetItem(res,0,PyInt_FromLong(meshId)); PyList_SetItem(res,1,PyInt_FromLong(arrId)); PyList_SetItem(res,2,PyInt_FromLong(arrIdInField)); PyList_SetItem(res,3,PyInt_FromLong(fieldId)); return res; } PyObject *getIdsOnTimeLeft(double tm) const throw(INTERP_KERNEL::Exception) { int meshId,arrId,arrIdInField,fieldId; self->getIdsOnTimeLeft(tm,meshId,arrId,arrIdInField,fieldId); PyObject *res=PyList_New(4); PyList_SetItem(res,0,PyInt_FromLong(meshId)); PyList_SetItem(res,1,PyInt_FromLong(arrId)); PyList_SetItem(res,2,PyInt_FromLong(arrIdInField)); PyList_SetItem(res,3,PyInt_FromLong(fieldId)); return res; } } }; class MEDCouplingFieldOverTime : public MEDCouplingMultiFields { public: double getTimeTolerance() const throw(INTERP_KERNEL::Exception); MEDCouplingDefinitionTime getDefinitionTimeZone() const; %extend { MEDCouplingFieldOverTime(PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,"MEDCouplingFieldDouble",tmp); int sz=tmp.size(); std::vector fs(sz); for(int i=0;i(tmp[i]); return MEDCouplingFieldOverTime::New(fs); } std::string __str__() const throw(INTERP_KERNEL::Exception) { return self->simpleRepr(); } static MEDCouplingFieldOverTime *New(PyObject *li) throw(INTERP_KERNEL::Exception) { std::vector tmp; convertFromPyObjVectorOfObj(li,SWIGTYPE_p_MEDCoupling__MEDCouplingFieldDouble,"MEDCouplingFieldDouble",tmp); int sz=tmp.size(); std::vector fs(sz); for(int i=0;i(tmp[i]); return MEDCouplingFieldOverTime::New(fs); } } }; 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(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 computeCellGridSt() const throw(INTERP_KERNEL::Exception); %extend { PyObject *getBLTRRange() const throw(INTERP_KERNEL::Exception) { const std::vector< std::pair >& ret(self->getBLTRRange()); return convertFromVectorPairInt(ret); } PyObject *getBLTRRangeRelativeToGF() const throw(INTERP_KERNEL::Exception) { std::vector< std::pair > ret(self->getBLTRRangeRelativeToGF()); return convertFromVectorPairInt(ret); } void addPatch(PyObject *bottomLeftTopRight, const std::vector& factors) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > 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(mesh->getPatch(patchId))); if(ret) ret->incrRef(); return ret; } void __delitem__(int patchId) throw(INTERP_KERNEL::Exception) { MEDCouplingCartesianAMRMeshGen *mesh(const_cast(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 getPositionRelativeTo(const MEDCouplingCartesianAMRMeshGen *ref) const throw(INTERP_KERNEL::Exception); int getSpaceDimension() const throw(INTERP_KERNEL::Exception); const std::vector& getFactors() const throw(INTERP_KERNEL::Exception); void setFactors(const std::vector& 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 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& factors) throw(INTERP_KERNEL::Exception); void createPatchesFromCriterion(const INTERP_KERNEL::BoxSplittingOptions& bso, const DataArrayDouble *criterion, const std::vector& 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& factors) throw(INTERP_KERNEL::Exception) { std::vector< std::pair > 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(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 *deepCopy(MEDCouplingCartesianAMRMeshGen *father) const throw(INTERP_KERNEL::Exception) { return convertCartesianAMRMesh(self->deepCopy(father), SWIG_POINTER_OWN | 0 ); } MEDCouplingCartesianAMRPatch *getPatchAtPosition(const std::vector& pos) const throw(INTERP_KERNEL::Exception) { const MEDCouplingCartesianAMRPatch *ret(self->getPatchAtPosition(pos)); MEDCouplingCartesianAMRPatch *ret2(const_cast(ret)); if(ret2) ret2->incrRef(); return ret2; } MEDCouplingCartesianAMRMeshGen *getMeshAtPosition(const std::vector& pos) const throw(INTERP_KERNEL::Exception) { const MEDCouplingCartesianAMRMeshGen *ret(self->getMeshAtPosition(pos)); MEDCouplingCartesianAMRMeshGen *ret2(const_cast(ret)); if(ret2) ret2->incrRef(); return ret2; } virtual PyObject *positionRelativeToGodFather() const throw(INTERP_KERNEL::Exception) { std::vector out1; std::vector< std::pair > 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 ps(self->retrieveGridsAt(absoluteLev)); int sz(ps.size()); PyObject *ret = PyList_New(sz); for(int i=0;i inp; convertFromPyObjVectorOfObj(recurseArrs,SWIGTYPE_p_MEDCoupling__DataArrayDouble,"DataArrayDouble",inp); return self->buildCellFieldOnRecurseWithoutOverlapWithoutGhost(ghostSz,inp); } virtual MEDCouplingCartesianAMRMeshGen *getFather() const throw(INTERP_KERNEL::Exception) { MEDCouplingCartesianAMRMeshGen *ret(const_cast(self->getFather())); if(ret) ret->incrRef(); return ret; } virtual MEDCouplingCartesianAMRMeshGen *getGodFather() const throw(INTERP_KERNEL::Exception) { MEDCouplingCartesianAMRMeshGen *ret(const_cast(self->getGodFather())); if(ret) ret->incrRef(); return ret; } MEDCouplingCartesianAMRPatch *getPatch(int patchId) const throw(INTERP_KERNEL::Exception) { MEDCouplingCartesianAMRPatch *ret(const_cast(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(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(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 arrsOnPatches2; convertFromPyObjVectorOfObj(arrsOnPatches,SWIGTYPE_p_MEDCoupling__DataArrayDouble,"DataArrayDouble",arrsOnPatches2); self->fillCellFieldOnPatchGhostAdv(patchId,cellFieldOnThis,ghostLev,arrsOnPatches2,isConservative); } void fillCellFieldOnPatchOnlyGhostAdv(int patchId, int ghostLev, PyObject *arrsOnPatches) const { std::vector arrsOnPatches2; convertFromPyObjVectorOfObj(arrsOnPatches,SWIGTYPE_p_MEDCoupling__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 bb0; nodeStrctPtr=convertIntStarLikePyObjToCppIntStar(nodeStrct,sw,sz,val0,bb0); // double val,val2; std::vector 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 inp0; convertFromPyObjVectorOfObj(bso,SWIGTYPE_p_INTERP_KERNEL__BoxSplittingOptions,"BoxSplittingOptions",inp0); std::vector< std::vector > 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 MEDCoupling_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 *deepCopy() 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 > fieldNamesCpp0; std::vector< std::pair > > 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 MEDCoupling_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(ret)); if(ret2) ret2->incrRef(); return ret2; } void spillInfoOnComponents(PyObject *compNames) throw(INTERP_KERNEL::Exception) { std::vector< std::vector > compNamesCpp; convertPyToVectorOfVectorOfString(compNames,compNamesCpp); self->spillInfoOnComponents(compNamesCpp); } void spillNatures(PyObject *nfs) throw(INTERP_KERNEL::Exception) { std::vector 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 inp00(sz); for(std::size_t i=0;ispillNatures(inp00); } PyObject *retrieveFieldsOn(MEDCouplingCartesianAMRMeshGen *mesh) const throw(INTERP_KERNEL::Exception) { std::vector ret(self->retrieveFieldsOn(mesh)); int sz((int)ret.size()); PyObject *retPy(PyList_New(sz)); for(int i=0;iisEqualIfNotWhy(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 MEDCoupling::DenseMatrix::Add(self,other); } DenseMatrix *__sub__(const DenseMatrix *other) throw(INTERP_KERNEL::Exception) { return MEDCoupling::DenseMatrix::Substract(self,other); } DenseMatrix *__mul__(const DenseMatrix *other) throw(INTERP_KERNEL::Exception) { return MEDCoupling::DenseMatrix::Multiply(self,other); } DenseMatrix *__mul__(const DataArrayDouble *other) throw(INTERP_KERNEL::Exception) { return MEDCoupling::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(self->getData(),NPY_DOUBLE,"DataArrayDouble",self->getNumberOfRows(),self->getNumberOfCols())); return obj; } #endif } }; } %pythoncode %{ def MEDCouplingUMeshReduce(self): return MEDCouplingStdReduceFunct,(MEDCouplingUMesh,((),(self.__getstate__()),)) def MEDCouplingCMeshReduce(self): return MEDCouplingStdReduceFunct,(MEDCouplingCMesh,((),(self.__getstate__()),)) def MEDCouplingIMeshReduce(self): return MEDCouplingStdReduceFunct,(MEDCouplingIMesh,((),(self.__getstate__()),)) def MEDCouplingMappedExtrudedMeshReduce(self): return MEDCouplingStdReduceFunct,(MEDCouplingMappedExtrudedMesh,((),(self.__getstate__()),)) def MEDCouplingCurveLinearMeshReduce(self): return MEDCouplingStdReduceFunct,(MEDCouplingCurveLinearMesh,((),(self.__getstate__()),)) def MEDCoupling1SGTUMeshReduce(self): return MEDCouplingStdReduceFunct,(MEDCoupling1SGTUMesh,((),(self.__getstate__()),)) def MEDCoupling1DGTUMeshReduce(self): return MEDCouplingStdReduceFunct,(MEDCoupling1DGTUMesh,((),(self.__getstate__()),)) def MEDCouplingFieldDoubleReduce(self): self.checkConsistencyLight() d=(self.getTypeOfField(),self.getTimeDiscretization()) return MEDCouplingStdReduceFunct,(MEDCouplingFieldDouble,(d,(self.__getstate__()),)) def MEDCouplingFieldIntReduce(self): self.checkConsistencyLight() d=(self.getTypeOfField(),self.getTimeDiscretization()) return MEDCouplingStdReduceFunct,(MEDCouplingFieldInt,(d,(self.__getstate__()),)) def MEDCouplingFieldFloatReduce(self): self.checkConsistencyLight() d=(self.getTypeOfField(),self.getTimeDiscretization()) return MEDCouplingStdReduceFunct,(MEDCouplingFieldFloat,(d,(self.__getstate__()),)) %} %pythoncode %{ import os __filename=os.environ.get('PYTHONSTARTUP') if __filename and os.path.isfile(__filename): exec(open(__filename).read()) pass %}