/*---------------------------------------------------------------------------*\ ========= | \\ / F ield | foam-extend: Open Source CFD \\ / O peration | Version: 4.1 \\ / A nd | Web: http://www.foam-extend.org \\/ M anipulation | For copyright notice see file Copyright ------------------------------------------------------------------------------- License This file is part of foam-extend. foam-extend is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. foam-extend 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 General Public License for more details. You should have received a copy of the GNU General Public License along with foam-extend. If not, see . InClass vtkPVFoam \*---------------------------------------------------------------------------*/ #ifndef vtkPVFoamVolFields_H #define vtkPVFoamVolFields_H // Foam includes #include "emptyFvPatchField.H" #include "wallPolyPatch.H" #include "faceSet.H" #include "volPointInterpolation.H" #include "vtkPVFoamFaceField.H" #include "vtkPVFoamPatchField.H" #include "vtkFoamTupleRemap.H" // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // template void Foam::vtkPVFoam::convertVolFields ( const fvMesh& mesh, const PtrList >& ppInterpList, const IOobjectList& objects, vtkMultiBlockDataSet* output ) { const polyBoundaryMesh& patches = mesh.boundaryMesh(); forAllConstIter(IOobjectList, objects, iter) { // restrict to GeometricField if ( iter()->headerClassName() != GeometricField::typeName ) { continue; } // Load field GeometricField tf ( *iter(), mesh ); // Interpolated field (demand driven) autoPtr > ptfPtr; // Convert activated internalMesh regions convertVolFieldBlock ( tf, ptfPtr, output, partInfoVolume_, regionPolyDecomp_ ); // Convert activated cellZones convertVolFieldBlock ( tf, ptfPtr, output, partInfoCellZones_, zonePolyDecomp_ ); // Convert activated cellSets convertVolFieldBlock ( tf, ptfPtr, output, partInfoCellSets_, csetPolyDecomp_ ); // // Convert patches - if activated // // The name for the interpolated patch point field must be consistent // with the interpolated volume point field. // This could be done better. const word pointFldName = "volPointInterpolate(" + tf.name() + ')'; for ( int partId = partInfoPatches_.start(); partId < partInfoPatches_.end(); ++partId ) { const word patchName = getPartName(partId); const label datasetNo = partDataset_[partId]; const label patchId = patches.findPatchID(patchName); if (!partStatus_[partId] || datasetNo < 0 || patchId < 0) { continue; } const fvPatchField& ptf = tf.boundaryField()[patchId]; if ( isType >(ptf) || ( reader_->GetExtrapolatePatches() && !polyPatch::constraintType(patches[patchId].type()) ) ) { fvPatch p(ptf.patch().patch(), tf.mesh().boundary()); tmp > tpptf ( fvPatchField(p, tf).patchInternalField() ); convertPatchField ( tf.name(), tpptf(), output, partInfoPatches_, datasetNo ); convertPatchPointField ( pointFldName, ppInterpList[patchId].faceToPointInterpolate(tpptf)(), output, partInfoPatches_, datasetNo ); } else { convertPatchField ( tf.name(), ptf, output, partInfoPatches_, datasetNo ); convertPatchPointField ( pointFldName, ppInterpList[patchId].faceToPointInterpolate(ptf)(), output, partInfoPatches_, datasetNo ); } } // // Convert face zones - if activated // for ( int partId = partInfoFaceZones_.start(); partId < partInfoFaceZones_.end(); ++partId ) { const word zoneName = getPartName(partId); const label datasetNo = partDataset_[partId]; if (!partStatus_[partId] || datasetNo < 0) { continue; } const faceZoneMesh& zMesh = mesh.faceZones(); const label zoneId = zMesh.findZoneID(zoneName); if (zoneId < 0) { continue; } convertFaceField ( tf, output, partInfoFaceZones_, datasetNo, mesh, zMesh[zoneId] ); // TODO: points } // // Convert face sets - if activated // for ( int partId = partInfoFaceSets_.start(); partId < partInfoFaceSets_.end(); ++partId ) { const word selectName = getPartName(partId); const label datasetNo = partDataset_[partId]; if (!partStatus_[partId] || datasetNo < 0) { continue; } const faceSet fSet(mesh, selectName); convertFaceField ( tf, output, partInfoFaceSets_, datasetNo, mesh, fSet ); // TODO: points } } } template void Foam::vtkPVFoam::convertVolFieldBlock ( const GeometricField& tf, autoPtr >& ptfPtr, vtkMultiBlockDataSet* output, const partInfo& selector, const List& decompLst ) { for (int partId = selector.start(); partId < selector.end(); ++partId) { const label datasetNo = partDataset_[partId]; if (datasetNo >= 0 && partStatus_[partId]) { convertVolField ( tf, output, selector, datasetNo, decompLst[datasetNo] ); if (!ptfPtr.valid()) { if (debug) { Info<< "convertVolFieldBlock interpolating:" << tf.name() << endl; } ptfPtr.reset ( volPointInterpolation::New(tf.mesh()).interpolate(tf).ptr() ); } convertPointField ( ptfPtr(), tf, output, selector, datasetNo, decompLst[datasetNo] ); } } } template void Foam::vtkPVFoam::convertVolField ( const GeometricField& tf, vtkMultiBlockDataSet* output, const partInfo& selector, const label datasetNo, const polyDecomp& decompInfo ) { const label nComp = pTraits::nComponents; const labelList& superCells = decompInfo.superCells(); vtkFloatArray* celldata = vtkFloatArray::New(); celldata->SetNumberOfTuples(superCells.size()); celldata->SetNumberOfComponents(nComp); celldata->Allocate(nComp*superCells.size()); celldata->SetName(tf.name().c_str()); if (debug) { Info<< "convert volField: " << tf.name() << " size = " << tf.size() << " nComp=" << nComp << " nTuples = " << superCells.size() << endl; } float vec[nComp]; forAll(superCells, i) { const Type& t = tf[superCells[i]]; for (direction d=0; d(vec); celldata->InsertTuple(i, vec); } vtkUnstructuredGrid::SafeDownCast ( GetDataSetFromBlock(output, selector, datasetNo) ) ->GetCellData() ->AddArray(celldata); celldata->Delete(); } // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // #endif // ************************************************************************* //