/*---------------------------------------------------------------------------*\ ========= | \\ / 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 . Description Write out the FOAM mesh in Version 3.0 Fieldview-UNS format (binary). See Fieldview Release 9 Reference Manual - Appendix D (Unstructured Data Format) Borrows various from uns/write_binary_uns.c from FieldView dist. \*---------------------------------------------------------------------------*/ #include "argList.H" #include "timeSelector.H" #include "volFields.H" #include "surfaceFields.H" #include "pointFields.H" #include "scalarIOField.H" #include "volPointInterpolation.H" #include "wallFvPatch.H" #include "symmetryFvPatch.H" #include "CloudTemplate.H" #include "passiveParticle.H" #include "IOobjectList.H" #include "boolList.H" #include "stringList.H" #include "cellModeller.H" #include "floatScalar.H" #include "calcFaceAddressing.H" #include "writeFunctions.H" #include "fieldviewTopology.H" #include #include "fv_reader_tags.h" extern "C" { unsigned int fv_encode_elem_header(int elem_type, int wall_info[]); } using namespace Foam; typedef Field floatField; static HashTable FieldviewNames; static word getFieldViewName(const word& foamName) { if (FieldviewNames.found(foamName)) { return FieldviewNames[foamName]; } else { return foamName; } } static void printNames(const wordList& names, Ostream& os) { forAll(names, fieldI) { Info<< " " << names[fieldI] << '/' << getFieldViewName(names[fieldI]); } } // Count number of vertices used by celli static label countVerts(const primitiveMesh& mesh, const label celli) { const cell& cll = mesh.cells()[celli]; // Count number of vertices used labelHashSet usedVerts(10*cll.size()); forAll(cll, cellFacei) { const face& f = mesh.faces()[cll[cellFacei]]; forAll(f, fp) { if (!usedVerts.found(f[fp])) { usedVerts.insert(f[fp]); } } } return usedVerts.toc().size(); } static void writeFaceData ( const polyMesh& mesh, const fieldviewTopology& topo, const label patchI, const scalarField& patchField, const bool writePolyFaces, std::ofstream& fvFile ) { const polyPatch& pp = mesh.boundaryMesh()[patchI]; // Start off with dummy value. if (writePolyFaces) { floatField fField(topo.nPolyFaces()[patchI], 0.0); // Fill selected faces with field values label polyFaceI = 0; forAll(patchField, faceI) { if (pp[faceI].size() > 4) { fField[polyFaceI++] = float(patchField[faceI]); } } fvFile.write ( reinterpret_cast(fField.begin()), fField.size()*sizeof(float) ); } else { floatField fField(pp.size() - topo.nPolyFaces()[patchI], 0.0); // Fill selected faces with field values label quadFaceI = 0; forAll(patchField, faceI) { if (pp[faceI].size() <= 4) { fField[quadFaceI++] = float(patchField[faceI]); } } fvFile.write ( reinterpret_cast(fField.begin()), fField.size()*sizeof(float) ); } } // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // // Main program: int main(int argc, char *argv[]) { argList::noParallel(); argList::validOptions.insert("noWall", ""); timeSelector::addOptions(true, false); # include "setRootCase.H" # include "createTime.H" instantList timeDirs = timeSelector::select0(runTime, args); # include "createMesh.H" // Initialize name mapping table FieldviewNames.insert("alpha", "aalpha"); FieldviewNames.insert("Alpha", "AAlpha"); FieldviewNames.insert("fsmach", "ffsmach"); FieldviewNames.insert("FSMach", "FFSMach"); FieldviewNames.insert("re", "rre"); FieldviewNames.insert("Re", "RRe"); FieldviewNames.insert("time", "ttime"); FieldviewNames.insert("Time", "TTime"); FieldviewNames.insert("pi", "ppi"); FieldviewNames.insert("PI", "PPI"); FieldviewNames.insert("x", "xx"); FieldviewNames.insert("X", "XX"); FieldviewNames.insert("y", "yy"); FieldviewNames.insert("Y", "YY"); FieldviewNames.insert("z", "zz"); FieldviewNames.insert("Z", "ZZ"); FieldviewNames.insert("rcyl", "rrcyl"); FieldviewNames.insert("Rcyl", "RRcyl"); FieldviewNames.insert("theta", "ttheta"); FieldviewNames.insert("Theta", "TTheta"); FieldviewNames.insert("rsphere", "rrsphere"); FieldviewNames.insert("Rsphere", "RRsphere"); FieldviewNames.insert("k", "kk"); FieldviewNames.insert("K", "KK"); // Scan for all available fields, in all timesteps // volScalarNames : all scalar fields // volVectorNames : ,, vector ,, // surfScalarNames : surface fields // surfVectorNames : ,, // sprayScalarNames: spray fields // sprayVectorNames: ,, # include "getFieldNames.H" bool hasLagrangian = false; if (sprayScalarNames.size() || sprayVectorNames.size()) { hasLagrangian = true; } Info<< "All fields: Foam/Fieldview" << endl; Info<< " volScalar :"; printNames(volScalarNames, Info); Info<< endl; Info<< " volVector :"; printNames(volVectorNames, Info); Info<< endl; Info<< " surfScalar :"; printNames(surfScalarNames, Info); Info<< endl; Info<< " surfVector :"; printNames(surfVectorNames, Info); Info<< endl; Info<< " sprayScalar :"; printNames(sprayScalarNames, Info); Info<< endl; Info<< " sprayVector :"; printNames(sprayVectorNames, Info); Info<< endl; // // Start writing // // make a directory called FieldView in the case fileName fvPath(runTime.path()/"Fieldview"); if (isDir(fvPath)) { rmDir(fvPath); } mkDir(fvPath); fileName fvParticleFileName(fvPath/runTime.caseName() + ".fvp"); if (hasLagrangian) { Info<< "Opening particle file " << fvParticleFileName << endl; } std::ofstream fvParticleFile(fvParticleFileName.c_str()); // Write spray file header if (hasLagrangian) { # include "writeSprayHeader.H" } // Current mesh. Start off from unloaded mesh. autoPtr topoPtr(NULL); label fieldViewTime = 0; forAll(timeDirs, timeI) { runTime.setTime(timeDirs[timeI], timeI); Info<< "Time: " << runTime.timeName() << endl; fvMesh::readUpdateState state = mesh.readUpdate(); if ( timeI == 0 || state == fvMesh::TOPO_CHANGE || state == fvMesh::TOPO_PATCH_CHANGE ) { // Mesh topo changed. Update Fieldview topo. topoPtr.reset ( new fieldviewTopology ( mesh, !args.optionFound("noWall") ) ); Info<< " Mesh read:" << endl << " tet : " << topoPtr().nTet() << endl << " hex : " << topoPtr().nHex() << endl << " prism : " << topoPtr().nPrism() << endl << " pyr : " << topoPtr().nPyr() << endl << " poly : " << topoPtr().nPoly() << endl << endl; } else if (state == fvMesh::POINTS_MOVED) { // points exists for time step, let's read them Info<< " Points file detected - updating points" << endl; } const fieldviewTopology& topo = topoPtr(); // // Create file and write header // fileName fvFileName ( fvPath/runTime.caseName() + "_" + Foam::name(timeI) + ".uns" ); Info<< " file:" << fvFileName.c_str() << endl; std::ofstream fvFile(fvFileName.c_str()); //Info<< "Writing header ..." << endl; // Output the magic number. writeInt(fvFile, FV_MAGIC); // Output file header and version number. writeStr80(fvFile, "FIELDVIEW"); // This version of the FIELDVIEW unstructured file is "3.0". // This is written as two integers. writeInt(fvFile, 3); writeInt(fvFile, 0); // File type code. Grid and results. writeInt(fvFile, FV_COMBINED_FILE); // Reserved field, always zero writeInt(fvFile, 0); // Output constants for time, fsmach, alpha and re. float fBuf[4]; fBuf[0] = runTime.value(); fBuf[1] = 0.0; fBuf[2] = 0.0; fBuf[3] = 1.0; fvFile.write(reinterpret_cast(fBuf), 4*sizeof(float)); // Output the number of grids writeInt(fvFile, 1); // // Boundary table // //Info<< "Writing boundary table ..." << endl; // num patches writeInt(fvFile, mesh.boundary().size()); forAll (mesh.boundary(), patchI) { const fvPatch& currPatch = mesh.boundary()[patchI]; writeInt(fvFile, 1); // data present writeInt(fvFile, 1); // normals ok // name writeStr80(fvFile, currPatch.name().c_str()); } // // Create fields: // volFieldPtrs : List of ptrs to all volScalar/Vector fields // (null if field not present at current time) // volFieldNames : FieldView compatible names of volFields // surfFieldPtrs : same for surfaceScalar/Vector // surfFieldNames # include "createFields.H" // // Write Variables table // //Info<< "Writing variables table ..." << endl; writeInt(fvFile, volFieldNames.size()); forAll(volFieldNames, fieldI) { if (volFieldPtrs[fieldI] == NULL) { Info<< " dummy field for " << volFieldNames[fieldI].c_str() << endl; } writeStr80(fvFile, volFieldNames[fieldI].c_str()); } // // Write Boundary Variables table = vol + surface fields // //Info<< "Writing boundary variables table ..." << endl; writeInt ( fvFile, volFieldNames.size() + surfFieldNames.size() ); forAll(volFieldNames, fieldI) { writeStr80(fvFile, volFieldNames[fieldI].c_str()); } forAll(surfFieldNames, fieldI) { if (surfFieldPtrs[fieldI] == NULL) { Info<< " dummy surface field for " << surfFieldNames[fieldI].c_str() << endl; } writeStr80(fvFile, surfFieldNames[fieldI].c_str()); } // Output grid data. // // Nodes // //Info<< "Writing points ..." << endl; const pointField& points = mesh.points(); label nPoints = points.size(); writeInt(fvFile, FV_NODES); writeInt(fvFile, nPoints); for (direction cmpt=0; cmpt(fField.begin()), fField.size()*sizeof(float) ); } // // Boundary Faces - regular // //Info<< "Writing regular boundary faces ..." << endl; forAll(mesh.boundary(), patchI) { label nQuadFaces = topo.quadFaceLabels()[patchI].size()/4; if (nQuadFaces != 0) { writeInt(fvFile, FV_FACES); writeInt(fvFile, patchI + 1); // patch number writeInt(fvFile, nQuadFaces); // number of faces in patch fvFile.write ( reinterpret_cast (topo.quadFaceLabels()[patchI].begin()), nQuadFaces*4*sizeof(int) ); } } // // Boundary Faces - arbitrary polygon // //Info<< "Write polygonal boundary faces ..." << endl; forAll(mesh.boundary(), patchI) { if (topo.nPolyFaces()[patchI] > 0) { writeInt(fvFile, FV_ARB_POLY_FACES); writeInt(fvFile, patchI + 1); // number of arb faces in patch writeInt(fvFile, topo.nPolyFaces()[patchI]); const polyPatch& patchFaces = mesh.boundary()[patchI].patch(); forAll(patchFaces, faceI) { const face& f = patchFaces[faceI]; if (f.size() > 4) { writeInt(fvFile, f.size()); forAll(f, fp) { writeInt(fvFile, f[fp] + 1); } } } } } // // Write regular topology // //Info<< "Writing regular elements ..." << endl; writeInt(fvFile, FV_ELEMENTS); writeInt(fvFile, topo.nTet()); writeInt(fvFile, topo.nHex()); writeInt(fvFile, topo.nPrism()); writeInt(fvFile, topo.nPyr()); fvFile.write ( reinterpret_cast(topo.tetLabels().begin()), topo.nTet()*(1+4)*sizeof(int) ); fvFile.write ( reinterpret_cast(topo.hexLabels().begin()), topo.nHex()*(1+8)*sizeof(int) ); fvFile.write ( reinterpret_cast(topo.prismLabels().begin()), topo.nPrism()*(1+6)*sizeof(int) ); fvFile.write ( reinterpret_cast(topo.pyrLabels().begin()), topo.nPyr()*(1+5)*sizeof(int) ); // // Write arbitrary polyhedra // //Info<< "Writing polyhedral elements ..." << endl; const cellShapeList& cellShapes = mesh.cellShapes(); const cellModel& unknown = *(cellModeller::lookup("unknown")); if (topo.nPoly() > 0) { writeInt(fvFile, FV_ARB_POLY_ELEMENTS); writeInt(fvFile, topo.nPoly()); forAll(cellShapes, celli) { if (cellShapes[celli].model() == unknown) { const cell& cll = mesh.cells()[celli]; // number of faces writeInt(fvFile, cll.size()); // number of vertices used (no cell centre) writeInt(fvFile, countVerts(mesh, celli)); // cell centre node id writeInt(fvFile, -1); forAll(cll, cellFacei) { label faceI = cll[cellFacei]; const face& f = mesh.faces()[faceI]; // Not a wall for now writeInt(fvFile, NOT_A_WALL); writeInt(fvFile, f.size()); if (mesh.faceOwner()[faceI] == celli) { forAll(f, fp) { writeInt(fvFile, f[fp]+1); } } else { for (label fp = f.size()-1; fp >= 0; fp--) { writeInt(fvFile, f[fp]+1); } } // Number of hanging nodes writeInt(fvFile, 0); } } } } // // Variables data // //Info<< "Writing variables data ..." << endl; volPointInterpolation pInterp(mesh); writeInt(fvFile, FV_VARIABLES); forAll(volFieldPtrs, fieldI) { if (volFieldPtrs[fieldI] != NULL) { const volScalarField& vField = *volFieldPtrs[fieldI]; // Interpolate to points pointScalarField psf(pInterp.interpolate(vField)); floatField fField(nPoints); for (label pointi = 0; pointi(fField.begin()), fField.size()*sizeof(float) ); } else { // Create dummy field floatField dummyField(nPoints, 0.0); fvFile.write ( reinterpret_cast(dummyField.begin()), dummyField.size()*sizeof(float) ); } } // // Boundary variables data // 1. volFields // 2. surfFields //Info<< "Writing regular boundary elements data ..." << endl; writeInt(fvFile, FV_BNDRY_VARS); forAll(volFieldPtrs, fieldI) { if (volFieldPtrs[fieldI] != NULL) { const volScalarField& vsf = *volFieldPtrs[fieldI]; forAll (mesh.boundary(), patchI) { writeFaceData ( mesh, topo, patchI, vsf.boundaryField()[patchI], false, fvFile ); } } else { forAll (mesh.boundaryMesh(), patchI) { // Dummy value. floatField fField ( mesh.boundaryMesh()[patchI].size() - topo.nPolyFaces()[patchI], 0.0 ); fvFile.write ( reinterpret_cast(fField.begin()), fField.size()*sizeof(float) ); } } } // surfFields forAll(surfFieldPtrs, fieldI) { if (surfFieldPtrs[fieldI] != NULL) { const surfaceScalarField& ssf = *surfFieldPtrs[fieldI]; forAll (mesh.boundary(), patchI) { writeFaceData ( mesh, topo, patchI, ssf.boundaryField()[patchI], false, fvFile ); } } else { forAll (mesh.boundaryMesh(), patchI) { // Dummy value. floatField fField ( mesh.boundaryMesh()[patchI].size() - topo.nPolyFaces()[patchI], 0.0 ); fvFile.write ( reinterpret_cast(fField.begin()), fField.size()*sizeof(float) ); } } } // // Polygonal faces boundary data // 1. volFields // 2. surfFields //Info<< "Writing polygonal boundary elements data ..." << endl; writeInt(fvFile, FV_ARB_POLY_BNDRY_VARS); forAll(volFieldPtrs, fieldI) { if (volFieldPtrs[fieldI] != NULL) { const volScalarField& vsf = *volFieldPtrs[fieldI]; // All non-empty patches forAll (mesh.boundary(), patchI) { writeFaceData ( mesh, topo, patchI, vsf.boundaryField()[patchI], true, fvFile ); } } else { forAll (mesh.boundary(), patchI) { // Dummy value. floatField fField(topo.nPolyFaces()[patchI], 0.0); fvFile.write ( reinterpret_cast(fField.begin()), fField.size()*sizeof(float) ); } } } // surfFields forAll(surfFieldPtrs, fieldI) { if (surfFieldPtrs[fieldI] != NULL) { const surfaceScalarField& ssf = *surfFieldPtrs[fieldI]; // All non-empty patches forAll(mesh.boundary(), patchI) { writeFaceData ( mesh, topo, patchI, ssf.boundaryField()[patchI], true, fvFile ); } } else { forAll (mesh.boundaryMesh(), patchI) { // Dummy value. floatField fField ( mesh.boundaryMesh()[patchI].size() - topo.nPolyFaces()[patchI], 0.0 ); fvFile.write ( reinterpret_cast(fField.begin()), fField.size()*sizeof(float) ); } } } // // Cleanup volume and surface fields // forAll(volFieldPtrs, fieldI) { delete volFieldPtrs[fieldI]; } forAll(surfFieldPtrs, fieldI) { delete surfFieldPtrs[fieldI]; } // // Spray // if (hasLagrangian) { // Read/create fields: // sprayScalarFieldPtrs: List of ptrs to lagrangian scalfields // sprayVectorFieldPtrs: ,, vec ,, # include "createSprayFields.H" // Write time header // Time index (FieldView: has to start from 1) writeInt(fvParticleFile, fieldViewTime + 1); // Time value writeFloat(fvParticleFile, runTime.value()); // Read particles Cloud parcels(mesh); // Num particles writeInt(fvParticleFile, parcels.size()); Info<< " Writing " << parcels.size() << " particles." << endl; // // Output data parcelwise // label parcelNo = 0; for ( Cloud::iterator elmnt = parcels.begin(); elmnt != parcels.end(); ++elmnt, parcelNo++ ) { writeInt(fvParticleFile, parcelNo+1); writeFloat(fvParticleFile, elmnt().position().x()); writeFloat(fvParticleFile, elmnt().position().y()); writeFloat(fvParticleFile, elmnt().position().z()); forAll(sprayScalarFieldPtrs, fieldI) { if (sprayScalarFieldPtrs[fieldI] != NULL) { const IOField& sprayField = *sprayScalarFieldPtrs[fieldI]; writeFloat ( fvParticleFile, sprayField[parcelNo] ); } else { writeFloat(fvParticleFile, 0.0); } } forAll(sprayVectorFieldPtrs, fieldI) { if (sprayVectorFieldPtrs[fieldI] != NULL) { const IOField& sprayVectorField = *sprayVectorFieldPtrs[fieldI]; const vector& val = sprayVectorField[parcelNo]; writeFloat(fvParticleFile, val.x()); writeFloat(fvParticleFile, val.y()); writeFloat(fvParticleFile, val.z()); } else { writeFloat(fvParticleFile, 0.0); writeFloat(fvParticleFile, 0.0); writeFloat(fvParticleFile, 0.0); } } } // increment fieldView particle time fieldViewTime++; // // Cleanup spray fields // forAll(sprayScalarFieldPtrs, fieldI) { delete sprayScalarFieldPtrs[fieldI]; } forAll(sprayVectorFieldPtrs, fieldI) { delete sprayVectorFieldPtrs[fieldI]; } } // end of hasLagrangian } if (!hasLagrangian) { rm(fvParticleFileName); } Info << "End\n" << endl; return 0; } // ************************************************************************* //