/*---------------------------------------------------------------------------*\ ========= | \\ / 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 cfx4ToFoam Description Converts a CFX 4 mesh to FOAM format \*---------------------------------------------------------------------------*/ #include "argList.H" #include "objectRegistry.H" #include "foamTime.H" #include "IFstream.H" #include "hexBlock.H" #include "polyMesh.H" #include "wallPolyPatch.H" #include "symmetryPolyPatch.H" #include "preservePatchTypes.H" #include "cellShape.H" #include "cellModeller.H" using namespace Foam; // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // // Main program: int main(int argc, char *argv[]) { argList::noParallel(); argList::validArgs.append("CFX geom file"); argList::validOptions.insert("scale", "scale factor"); argList args(argc, argv); if (!args.check()) { FatalError.exit(); } scalar scaleFactor = 1.0; args.optionReadIfPresent("scale", scaleFactor); # include "createTime.H" IFstream cfxFile(args.additionalArgs()[0]); // Read the cfx information using a fixed format reader. // Comments in the file are in C++ style, so the stream parser will remove // them with no intervention label nblock, npatch, nglue, nelem, npoint; cfxFile >> nblock >> npatch >> nglue >> nelem >> npoint; Info<< "Reading blocks" << endl; PtrList blocks(nblock); { word blockName; label nx, ny, nz; forAll (blocks, blockI) { cfxFile >> blockName; cfxFile >> nx >> ny >> nz; blocks.set(blockI, new hexBlock(nx, ny, nz)); } } Info<< "Reading patch definitions" << endl; wordList cfxPatchTypes(npatch); wordList cfxPatchNames(npatch); labelList patchMasterBlocks(npatch); labelList patchDirections(npatch); labelListList patchRanges(npatch); { label no, blkNo, patchLabel; forAll (cfxPatchTypes, patchI) { // Grab patch type and name cfxFile >> cfxPatchTypes[patchI] >> cfxPatchNames[patchI] >> no; // Grab patch range patchRanges[patchI].setSize(6); labelList& curRange = patchRanges[patchI]; forAll (curRange, rI) { cfxFile >> curRange[rI]; } // Grab patch direction and master block ID // Note: direc is the direction, from the cfx manual // 0 = solid (3-D patch), // 1 = high i, 2 = high j, 3 = high k // 4 = low i, 5 = low j, 6 = low k cfxFile >> patchDirections[patchI] >> blkNo >> patchLabel; patchMasterBlocks[patchI] = blkNo - 1; } } Info<< "Reading block glueing information" << endl; labelList glueMasterPatches(nglue, -1); labelList glueSlavePatches(nglue, -1); { label masterPatch, slavePatch; label dirIndex1, dirIndex2, dirIndex3, joinNumber; for (label glueI = 0; glueI < nglue; glueI++) { cfxFile >> masterPatch >> slavePatch; cfxFile >> dirIndex1 >> dirIndex2 >> dirIndex3 >> joinNumber; glueMasterPatches[glueI] = masterPatch - 1; glueSlavePatches[glueI] = slavePatch - 1; } } Info<< "Reading block points" << endl; forAll (blocks, blockI) { Info<< "block " << blockI << " is a "; blocks[blockI].readPoints(cfxFile); } Info<< "Calculating block offsets" << endl; labelList blockOffsets(nblock, -1); blockOffsets[0] = 0; label nMeshPoints = blocks[0].nBlockPoints(); label nMeshCells = blocks[0].nBlockCells(); for (label blockI = 1; blockI < nblock; blockI++) { nMeshPoints += blocks[blockI].nBlockPoints(); nMeshCells += blocks[blockI].nBlockCells(); blockOffsets[blockI] = blockOffsets[blockI - 1] + blocks[blockI - 1].nBlockPoints(); } Info<< "Assembling patches" << endl; faceListList rawPatches(npatch); forAll (rawPatches, patchI) { const word& patchType = cfxPatchTypes[patchI]; // reject volume patches if ( patchType == "POROUS" || patchType == "SOLID" || patchType == "SOLCON" || patchType == "USER3D" ) { patchMasterBlocks[patchI] = -1; rawPatches[patchI].setSize(0); } else { // read and create a 2-D patch rawPatches[patchI] = blocks[patchMasterBlocks[patchI]].patchFaces ( patchDirections[patchI], patchRanges[patchI] ); } } Info<< "Merging points "; labelList pointMergeList(nMeshPoints, -1); // In order to ensure robust merging, it is necessary to traverse // the patch glueing list until the pointMergeList stops changing. // // For efficiency, create merge pairs in the first pass labelListListList glueMergePairs(glueMasterPatches.size()); forAll (glueMasterPatches, glueI) { const label masterPatch = glueMasterPatches[glueI]; const label slavePatch = glueSlavePatches[glueI]; const label blockPlabel = patchMasterBlocks[masterPatch]; const label blockNlabel = patchMasterBlocks[slavePatch]; const pointField& blockPpoints = blocks[blockPlabel].points(); const pointField& blockNpoints = blocks[blockNlabel].points(); const faceList& blockPFaces = rawPatches[masterPatch]; const faceList& blockNFaces = rawPatches[slavePatch]; labelListList& curPairs = glueMergePairs[glueI]; curPairs.setSize(blockPFaces.size()); if (blockPFaces.size() != blockNFaces.size()) { FatalErrorIn(args.executable()) << "Inconsistent number of faces for glue pair " << glueI << " between blocks " << blockPlabel + 1 << " and " << blockNlabel + 1 << abort(FatalError); } // Calculate sqr of the merge tolerance as 1/10th of the min // sqr point to point distance on the block face. This is an // N^2 algorithm, sorry but I cannot quickly come up with // something better. scalar sqrMergeTol = GREAT; forAll (blockPFaces, blockPFaceLabel) { const labelList& blockPFacePoints = blockPFaces[blockPFaceLabel]; forAll (blockPFacePoints, blockPFacePointI) { forAll (blockPFacePoints, blockPFacePointI2) { if (blockPFacePointI != blockPFacePointI2) { sqrMergeTol = min ( sqrMergeTol, magSqr ( blockPpoints [blockPFacePoints[blockPFacePointI]] - blockPpoints [blockPFacePoints[blockPFacePointI2]] ) ); } } } } sqrMergeTol /= 10.0; register bool found = false; // N-squared point search over all points of all faces of // master block over all point of all faces of slave block forAll (blockPFaces, blockPFaceLabel) { const labelList& blockPFacePoints = blockPFaces[blockPFaceLabel]; labelList& cp = curPairs[blockPFaceLabel]; cp.setSize(blockPFacePoints.size()); forAll (blockPFacePoints, blockPFacePointI) { found = false; forAll (blockNFaces, blockNFaceLabel) { const labelList& blockNFacePoints = blockNFaces[blockNFaceLabel]; forAll (blockNFacePoints, blockNFacePointI) { if ( magSqr ( blockPpoints [blockPFacePoints[blockPFacePointI]] - blockNpoints [blockNFacePoints[blockNFacePointI]] ) < sqrMergeTol ) { // Found a new pair found = true; cp[blockPFacePointI] = blockNFacePoints[blockNFacePointI]; label PpointLabel = blockPFacePoints[blockPFacePointI] + blockOffsets[blockPlabel]; label NpointLabel = blockNFacePoints[blockNFacePointI] + blockOffsets[blockNlabel]; label minPN = min(PpointLabel, NpointLabel); if (pointMergeList[PpointLabel] != -1) { minPN = min(minPN, pointMergeList[PpointLabel]); } if (pointMergeList[NpointLabel] != -1) { minPN = min(minPN, pointMergeList[NpointLabel]); } pointMergeList[PpointLabel] = pointMergeList[NpointLabel] = minPN; break; } } if (found) break; } } } } register bool changedPointMerge = false; label nPasses = 0; do { changedPointMerge = false; nPasses++; forAll (glueMasterPatches, glueI) { const label masterPatch = glueMasterPatches[glueI]; const label slavePatch = glueSlavePatches[glueI]; const label blockPlabel = patchMasterBlocks[masterPatch]; const label blockNlabel = patchMasterBlocks[slavePatch]; const faceList& blockPFaces = rawPatches[masterPatch]; const labelListList& curPairs = glueMergePairs[glueI]; forAll (blockPFaces, blockPFaceLabel) { const labelList& blockPFacePoints = blockPFaces[blockPFaceLabel]; const labelList& cp = curPairs[blockPFaceLabel]; forAll (cp, blockPFacePointI) { label PpointLabel = blockPFacePoints[blockPFacePointI] + blockOffsets[blockPlabel]; label NpointLabel = cp[blockPFacePointI] + blockOffsets[blockNlabel]; if ( pointMergeList[PpointLabel] != pointMergeList[NpointLabel] ) { changedPointMerge = true; pointMergeList[PpointLabel] = pointMergeList[NpointLabel] = min ( pointMergeList[PpointLabel], pointMergeList[NpointLabel] ); } } } } Info<< "." << flush; } while (changedPointMerge && nPasses < 8); Info<< endl; if (changedPointMerge == true) { FatalErrorIn(args.executable()) << "Point merging failed after max number of passes." << abort(FatalError); } forAll (glueMasterPatches, glueI) { const label masterPatch = glueMasterPatches[glueI]; const label slavePatch = glueSlavePatches[glueI]; const label blockPlabel = patchMasterBlocks[masterPatch]; const label blockNlabel = patchMasterBlocks[slavePatch]; const faceList& blockPFaces = rawPatches[masterPatch]; const faceList& blockNFaces = rawPatches[slavePatch]; forAll (blockPFaces, blockPFaceLabel) { const labelList& blockPFacePoints = blockPFaces[blockPFaceLabel]; forAll (blockPFacePoints, blockPFacePointI) { label PpointLabel = blockPFacePoints[blockPFacePointI] + blockOffsets[blockPlabel]; if (pointMergeList[PpointLabel] == -1) { FatalErrorIn(args.executable()) << "Unable to merge point " << blockPFacePointI << " of face " << blockPFaceLabel << " of block " << blockPlabel << abort(FatalError); } } } forAll (blockNFaces, blockNFaceLabel) { const labelList& blockNFacePoints = blockNFaces[blockNFaceLabel]; forAll (blockNFacePoints, blockNFacePointI) { label NpointLabel = blockNFacePoints[blockNFacePointI] + blockOffsets[blockNlabel]; if (pointMergeList[NpointLabel] == -1) { FatalErrorIn(args.executable()) << "Unable to merge point " << blockNFacePointI << " of face " << blockNFaceLabel << " of block " << blockNlabel << abort(FatalError); } } } } // sort merge list to return new point label (in new shorter list) // given old point label label nNewPoints = 0; forAll (pointMergeList, pointLabel) { if (pointMergeList[pointLabel] > pointLabel) { FatalErrorIn(args.executable()) << "ouch" << abort(FatalError); } if ( (pointMergeList[pointLabel] == -1) || pointMergeList[pointLabel] == pointLabel ) { pointMergeList[pointLabel] = nNewPoints; nNewPoints++; } else { pointMergeList[pointLabel] = pointMergeList[pointMergeList[pointLabel]]; } } nMeshPoints = nNewPoints; Info<< "Creating points" << endl; pointField points(nMeshPoints); forAll (blocks, blockI) { const pointField& blockPoints = blocks[blockI].points(); forAll (blockPoints, blockPointLabel) { points [ pointMergeList [ blockPointLabel + blockOffsets[blockI] ] ] = blockPoints[blockPointLabel]; } } // Scale the points if (scaleFactor > 1.0 + SMALL || scaleFactor < 1.0 - SMALL) { points *= scaleFactor; } Info<< "Creating cells" << endl; cellShapeList cellShapes(nMeshCells); const cellModel& hex = *(cellModeller::lookup("hex")); label nCreatedCells = 0; forAll (blocks, blockI) { labelListList curBlockCells = blocks[blockI].blockCells(); forAll (curBlockCells, blockCellI) { labelList cellPoints(curBlockCells[blockCellI].size()); forAll (cellPoints, pointI) { cellPoints[pointI] = pointMergeList [ curBlockCells[blockCellI][pointI] + blockOffsets[blockI] ]; } cellShapes[nCreatedCells] = cellShape(hex, cellPoints); nCreatedCells++; } } Info<< "Creating boundary patches" << endl; faceListList boundary(npatch); wordList patchNames(npatch); wordList patchTypes(npatch); word defaultFacesName = "defaultFaces"; word defaultFacesType = wallPolyPatch::typeName; label nCreatedPatches = 0; forAll (rawPatches, patchI) { if (rawPatches[patchI].size() && cfxPatchTypes[patchI] != "BLKBDY") { // Check if this name has been already created label existingPatch = -1; for (label oldPatchI = 0; oldPatchI < nCreatedPatches; oldPatchI++) { if (patchNames[oldPatchI] == cfxPatchNames[patchI]) { existingPatch = oldPatchI; break; } } const faceList& curRawPatch = rawPatches[patchI]; label curBlock = patchMasterBlocks[patchI]; if (existingPatch >= 0) { Info<< "CFX patch " << patchI << ", of type " << cfxPatchTypes[patchI] << ", name " << cfxPatchNames[patchI] << " already exists as FOAM patch " << existingPatch << ". Adding faces." << endl; faceList& renumberedPatch = boundary[existingPatch]; label oldSize = renumberedPatch.size(); renumberedPatch.setSize(oldSize + curRawPatch.size()); forAll (curRawPatch, faceI) { const face& oldFace = curRawPatch[faceI]; face& newFace = renumberedPatch[oldSize + faceI]; newFace.setSize(oldFace.size()); forAll (oldFace, pointI) { newFace[pointI] = pointMergeList [ oldFace[pointI] + blockOffsets[curBlock] ]; } } } else { // Real patch to be created faceList& renumberedPatch = boundary[nCreatedPatches]; renumberedPatch.setSize(curRawPatch.size()); forAll (curRawPatch, faceI) { const face& oldFace = curRawPatch[faceI]; face& newFace = renumberedPatch[faceI]; newFace.setSize(oldFace.size()); forAll (oldFace, pointI) { newFace[pointI] = pointMergeList [ oldFace[pointI] + blockOffsets[curBlock] ]; } } Info<< "CFX patch " << patchI << ", of type " << cfxPatchTypes[patchI] << ", name " << cfxPatchNames[patchI] << " converted into FOAM patch " << nCreatedPatches << " type "; if (cfxPatchTypes[patchI] == "WALL") { Info<< "wall." << endl; patchTypes[nCreatedPatches] = wallPolyPatch::typeName; patchNames[nCreatedPatches] = cfxPatchNames[patchI]; nCreatedPatches++; } else if (cfxPatchTypes[patchI] == "SYMMET") { Info<< "symmetryPlane." << endl; patchTypes[nCreatedPatches] = symmetryPolyPatch::typeName; patchNames[nCreatedPatches] = cfxPatchNames[patchI]; nCreatedPatches++; } else if ( cfxPatchTypes[patchI] == "INLET" || cfxPatchTypes[patchI] == "OUTLET" || cfxPatchTypes[patchI] == "PRESS" || cfxPatchTypes[patchI] == "CNDBDY" || cfxPatchTypes[patchI] == "USER2D" ) { Info<< "generic." << endl; patchTypes[nCreatedPatches] = polyPatch::typeName; patchNames[nCreatedPatches] = cfxPatchNames[patchI]; nCreatedPatches++; } else { FatalErrorIn(args.executable()) << "Unrecognised CFX patch type " << cfxPatchTypes[patchI] << abort(FatalError); } } } } boundary.setSize(nCreatedPatches); patchTypes.setSize(nCreatedPatches); patchNames.setSize(nCreatedPatches); PtrList patchDicts; preservePatchTypes ( runTime, runTime.constant(), polyMesh::meshSubDir, patchNames, patchDicts, defaultFacesName, defaultFacesType ); // Add information to dictionary forAll (patchNames, patchI) { if (!patchDicts.set(patchI)) { patchDicts.set(patchI, new dictionary()); } // Add but not overwrite patchDicts[patchI].add("type", patchTypes[patchI], false); } polyMesh pShapeMesh ( IOobject ( polyMesh::defaultRegion, runTime.constant(), runTime ), xferMove(points), cellShapes, boundary, patchNames, patchDicts, defaultFacesName, defaultFacesType ); // Set the precision of the points data to 10 IOstream::defaultPrecision(max(10u, IOstream::defaultPrecision())); Info<< "Writing polyMesh" << endl; pShapeMesh.write(); Info<< "End\n" << endl; return 0; } // ************************************************************************* //