/*---------------------------------------------------------------------------*\ ========= | \\ / F ield | foam-extend: Open Source CFD \\ / O peration | Version: 3.2 \\ / 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 . Application mapFields Description Maps volume fields from one mesh to another, reading and interpolating all fields present in the time directory of both cases. Parallel and non-parallel cases are handled without the need to reconstruct them first. \*---------------------------------------------------------------------------*/ #include "fvCFD.H" #include "meshToMesh.H" #include "MapVolFields.H" #include "MapConsistentVolFields.H" #include "UnMapped.H" #include "processorFvPatch.H" #include "mapLagrangian.H" // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // void mapConsistentMesh ( const fvMesh& meshSource, const fvMesh& meshTarget ) { // Create the interpolation scheme meshToMesh meshToMeshInterp(meshSource, meshTarget); Info<< nl << "Consistently creating and mapping fields for time " << meshSource.time().timeName() << nl << endl; { // Search for list of objects for this time IOobjectList objects(meshSource, meshSource.time().timeName()); // Map volFields // ~~~~~~~~~~~~~ MapConsistentVolFields(objects, meshToMeshInterp); MapConsistentVolFields(objects, meshToMeshInterp); MapConsistentVolFields(objects, meshToMeshInterp); MapConsistentVolFields(objects, meshToMeshInterp); MapConsistentVolFields(objects, meshToMeshInterp); } { // Search for list of target objects for this time IOobjectList objects(meshTarget, meshTarget.time().timeName()); // Mark surfaceFields as unmapped // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ UnMapped(objects); UnMapped(objects); UnMapped(objects); UnMapped(objects); UnMapped(objects); // Mark pointFields as unmapped // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ UnMapped(objects); UnMapped(objects); UnMapped(objects); UnMapped(objects); UnMapped(objects); } mapLagrangian(meshToMeshInterp); } void mapSubMesh ( const fvMesh& meshSource, const fvMesh& meshTarget, const HashTable& patchMap, const wordList& cuttingPatches ) { // Create the interpolation scheme meshToMesh meshToMeshInterp ( meshSource, meshTarget, patchMap, cuttingPatches ); Info<< nl << "Mapping fields for time " << meshSource.time().timeName() << nl << endl; { // Search for list of source objects for this time IOobjectList objects(meshSource, meshSource.time().timeName()); // Map volFields // ~~~~~~~~~~~~~ MapVolFields(objects, meshToMeshInterp); MapVolFields(objects, meshToMeshInterp); MapVolFields(objects, meshToMeshInterp); MapVolFields(objects, meshToMeshInterp); MapVolFields(objects, meshToMeshInterp); } { // Search for list of target objects for this time IOobjectList objects(meshTarget, meshTarget.time().timeName()); // Mark surfaceFields as unmapped // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ UnMapped(objects); UnMapped(objects); UnMapped(objects); UnMapped(objects); UnMapped(objects); // Mark pointFields as unmapped // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ UnMapped(objects); UnMapped(objects); UnMapped(objects); UnMapped(objects); UnMapped(objects); } mapLagrangian(meshToMeshInterp); } void mapConsistentSubMesh ( const fvMesh& meshSource, const fvMesh& meshTarget ) { HashTable patchMap; HashTable cuttingPatchTable; forAll(meshTarget.boundary(), patchi) { if (!isA(meshTarget.boundary()[patchi])) { patchMap.insert ( meshTarget.boundary()[patchi].name(), meshTarget.boundary()[patchi].name() ); } else { cuttingPatchTable.insert ( meshTarget.boundaryMesh()[patchi].name(), -1 ); } } mapSubMesh(meshSource, meshTarget, patchMap, cuttingPatchTable.toc()); } wordList addProcessorPatches ( const fvMesh& meshTarget, const wordList& cuttingPatches ) { // Add the processor patches to the cutting list HashTable cuttingPatchTable; forAll (cuttingPatches, i) { cuttingPatchTable.insert(cuttingPatches[i], i); } forAll (meshTarget.boundary(), patchi) { if (isA(meshTarget.boundary()[patchi])) { if ( !cuttingPatchTable.found ( meshTarget.boundaryMesh()[patchi].name() ) ) { cuttingPatchTable.insert ( meshTarget.boundaryMesh()[patchi].name(), -1 ); } } } return cuttingPatchTable.toc(); } // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // int main(int argc, char *argv[]) { #include "setRoots.H" #include "createTimes.H" HashTable patchMap; wordList cuttingPatches; if (!consistent) { IOdictionary mapFieldsDict ( IOobject ( "mapFieldsDict", runTimeTarget.system(), runTimeTarget, IOobject::MUST_READ, IOobject::NO_WRITE, false ) ); mapFieldsDict.lookup("patchMap") >> patchMap; mapFieldsDict.lookup("cuttingPatches") >> cuttingPatches; } if (parallelSource && !parallelTarget) { IOdictionary decompositionDict ( IOobject ( "decomposeParDict", runTimeSource.system(), runTimeSource, IOobject::MUST_READ, IOobject::NO_WRITE ) ); int nProcs(readInt(decompositionDict.lookup("numberOfSubdomains"))); Info<< "Create target mesh\n" << endl; fvMesh meshTarget ( IOobject ( fvMesh::defaultRegion, runTimeTarget.timeName(), runTimeTarget ) ); Info<< "Target mesh size: " << meshTarget.nCells() << endl; for (int procI=0; procI bbsTarget(nProcsTarget); List bbsTargetSet(nProcsTarget, false); for (int procISource=0; procISource