ifstream kivaFile(kivaFileName.c_str()); if (!kivaFile.good()) { FatalErrorIn(args.executable()) << "Cannot open file " << kivaFileName << exit(FatalError); } Info << "Reading kiva grid from file " << kivaFileName << endl; char title[120]; kivaFile.getline(title, 120, '\n'); label nPoints, nCells, nRegs; kivaFile >> nCells >> nPoints >> nRegs; pointField points(nPoints); label i4; labelList idface(nPoints), fv(nPoints); for(label i=0; i> i4 >> points[i].x() >> points[i].y() >> points[i].z() >> ffv; if (kivaVersion == kiva3v) { kivaFile >> idface[i]; } // Convert from KIVA cgs units to SI points[i] *= 0.01; fv[i] = label(ffv); } labelList i1tab(nPoints), i3tab(nPoints), i8tab(nPoints), idreg(nPoints), f(nPoints), bcl(nPoints), bcf(nPoints), bcb(nPoints); label nBfaces = 0; for(label i=0; i> i1 >> i3 >> i4 >> i8 >> ff >> fbcl >> fbcf >> fbcb >> idreg[i]; // Correct indices to start from 0 i1tab[i] = i1 - 1; i3tab[i] = i3 - 1; i8tab[i] = i8 - 1; // Convert scalar indices into hexLabels f[i] = label(ff); bcl[i] = label(fbcl); bcf[i] = label(fbcf); bcb[i] = label(fbcb); if (bcl[i] > 0 && bcl[i] != 4) nBfaces++; if (bcf[i] > 0 && bcf[i] != 4) nBfaces++; if (bcb[i] > 0 && bcb[i] != 4) nBfaces++; } label mTable; kivaFile >> mTable; if (mTable == 0) { FatalErrorIn(args.executable()) << "mTable == 0. This is not supported." " kivaToFoam needs complete neighbour information" << exit(FatalError); } labelList imtab(nPoints), jmtab(nPoints), kmtab(nPoints); for(label i=0; i> i4 >> im >> jm >> km; // Correct indices to start from 0 imtab[i] = im - 1; jmtab[i] = jm - 1; kmtab[i] = km - 1; } Info << "Finished reading KIVA file" << endl; cellShapeList cellShapes(nPoints); labelList cellZoning(nPoints, -1); const cellModel& hex = *(cellModeller::lookup("hex")); labelList hexLabels(8); label activeCells = 0; // Create and set the collocated point collapse map labelList pointMap(nPoints); forAll (pointMap, i) { pointMap[i] = i; } // Initialise all cells to hex and search and set map for collocated points for(label i=0; i 0.0) { hexLabels[0] = i; hexLabels[1] = i1tab[i]; hexLabels[2] = i3tab[i1tab[i]]; hexLabels[3] = i3tab[i]; hexLabels[4] = i8tab[i]; hexLabels[5] = i1tab[i8tab[i]]; hexLabels[6] = i3tab[i1tab[i8tab[i]]]; hexLabels[7] = i3tab[i8tab[i]]; cellShapes[activeCells] = cellShape(hex, hexLabels); edgeList edges = cellShapes[activeCells].edges(); forAll (edges, ei) { if (edges[ei].mag(points) < SMALL) { label start = pointMap[edges[ei].start()]; while (start != pointMap[start]) { start = pointMap[start]; } label end = pointMap[edges[ei].end()]; while (end != pointMap[end]) { end = pointMap[end]; } label minLabel = min(start, end); pointMap[start] = pointMap[end] = minLabel; } } // Grab the cell zoning info cellZoning[activeCells] = idreg[i]; activeCells++; } } // Contract list of cells to the active ones cellShapes.setSize(activeCells); cellZoning.setSize(activeCells); // Map collocated points to refer to the same point and collapse cell shape // to the corresponding hex-degenerate. forAll (cellShapes, celli) { cellShape& cs = cellShapes[celli]; forAll (cs, i) { cs[i] = pointMap[cs[i]]; } cs.collapse(); } label bcIDs[11] = {-1, 0, 2, 4, -1, 5, -1, 6, 7, 8, 9}; const label nBCs = 12; const word* kivaPatchTypes[nBCs] = { &wallPolyPatch::typeName, &wallPolyPatch::typeName, &wallPolyPatch::typeName, &wallPolyPatch::typeName, &symmetryPolyPatch::typeName, &wedgePolyPatch::typeName, &polyPatch::typeName, &polyPatch::typeName, &polyPatch::typeName, &polyPatch::typeName, &symmetryPolyPatch::typeName, &cyclicPolyPatch::typeName }; enum patchTypeNames { PISTON, VALVE, LINER, CYLINDERHEAD, AXIS, WEDGE, INFLOW, OUTFLOW, PRESIN, PRESOUT, SYMMETRYPLANE, CYCLIC }; const char* kivaPatchNames[nBCs] = { "piston", "valve", "liner", "cylinderHead", "axis", "wedge", "inflow", "outflow", "presin", "presout", "symmetryPlane", "cyclic" }; List > pFaces[nBCs]; face quadFace(4); face triFace(3); for(label i=0; i 0) { // left label bci = bcl[i]; if (bci != 4) { quadFace[0] = i3tab[i]; quadFace[1] = i; quadFace[2] = i8tab[i]; quadFace[3] = i3tab[i8tab[i]]; # include "checkPatch.H" } // right bci = bcl[i1tab[i]]; if (bci != 4) { quadFace[0] = i1tab[i]; quadFace[1] = i3tab[i1tab[i]]; quadFace[2] = i8tab[i3tab[i1tab[i]]]; quadFace[3] = i8tab[i1tab[i]]; # include "checkPatch.H" } // front bci = bcf[i]; if (bci != 4) { quadFace[0] = i; quadFace[1] = i1tab[i]; quadFace[2] = i8tab[i1tab[i]]; quadFace[3] = i8tab[i]; # include "checkPatch.H" } // derriere (back) bci = bcf[i3tab[i]]; if (bci != 4) { quadFace[0] = i3tab[i]; quadFace[1] = i8tab[i3tab[i]]; quadFace[2] = i8tab[i1tab[i3tab[i]]]; quadFace[3] = i1tab[i3tab[i]]; # include "checkPatch.H" } // bottom bci = bcb[i]; if (bci != 4) { quadFace[0] = i; quadFace[1] = i3tab[i]; quadFace[2] = i1tab[i3tab[i]]; quadFace[3] = i1tab[i]; # include "checkPatch.H" } // top bci = bcb[i8tab[i]]; if (bci != 4) { quadFace[0] = i8tab[i]; quadFace[1] = i1tab[i8tab[i]]; quadFace[2] = i3tab[i1tab[i8tab[i]]]; quadFace[3] = i3tab[i8tab[i]]; # include "checkPatch.H" } } } // Tranfer liner faces that are above the minimum cylinder-head z height // into the cylinder-head region if ( pFaces[LINER].size() && pFaces[LINER][0].size() && pFaces[CYLINDERHEAD].size() && pFaces[CYLINDERHEAD][0].size() ) { scalar minz = GREAT; for ( SLList::iterator iter = pFaces[CYLINDERHEAD][0].begin(); iter != pFaces[CYLINDERHEAD][0].end(); ++iter ) { const face& pf = iter(); forAll (pf, pfi) { minz = min(minz, points[pf[pfi]].z()); } } minz += SMALL; SLList newLinerFaces; for ( SLList::iterator iter = pFaces[LINER][0].begin(); iter != pFaces[LINER][0].end(); ++iter ) { const face& pf = iter(); scalar minfz = GREAT; forAll (pf, pfi) { minfz = min(minfz, points[pf[pfi]].z()); } if (minfz > minz) { pFaces[CYLINDERHEAD][0].append(pf); } else { newLinerFaces.append(pf); } } if (pFaces[LINER][0].size() != newLinerFaces.size()) { Info<< "Transfered " << pFaces[LINER][0].size() - newLinerFaces.size() << " faces from liner region to cylinder head" << endl; pFaces[LINER][0] = newLinerFaces; } SLList newCylinderHeadFaces; for ( SLList::iterator iter = pFaces[CYLINDERHEAD][0].begin(); iter != pFaces[CYLINDERHEAD][0].end(); ++iter ) { const face& pf = iter(); scalar minfz = GREAT; forAll (pf, pfi) { minfz = min(minfz, points[pf[pfi]].z()); } if (minfz < zHeadMin) { pFaces[LINER][0].append(pf); } else { newCylinderHeadFaces.append(pf); } } if (pFaces[CYLINDERHEAD][0].size() != newCylinderHeadFaces.size()) { Info<< "Transfered faces from cylinder-head region to linder" << endl; pFaces[CYLINDERHEAD][0] = newCylinderHeadFaces; } } // Count the number of non-zero sized patches label nPatches = 0; for (int bci=0; bci::iterator iterf = pFaces[WEDGE][0].begin(); SLList::iterator iterb = pFaces[WEDGE][1].begin(); for ( ; iterf != pFaces[WEDGE][0].end(), iterb != pFaces[WEDGE][1].end(); ++iterf, ++iterb ) { for (direction d=0; d<4; d++) { points[iterf()[d]].y() = -tanTheta*points[iterf()[d]].x(); points[iterb()[d]].y() = tanTheta*points[iterb()[d]].x(); } } } else { pFaces[CYCLIC].setSize(1); pFaces[CYCLIC][0] = pFaces[WEDGE][0]; for ( SLList::iterator iterb = pFaces[WEDGE][1].begin(); iterb != pFaces[WEDGE][1].end(); ++iterb ) { pFaces[CYCLIC][0].append(iterb()); } pFaces[WEDGE].clear(); nPatches--; } } // Build the patches faceListList boundary(nPatches); wordList patchNames(nPatches); wordList patchTypes(nPatches); word defaultFacesName = "defaultFaces"; word defaultFacesType = emptyPolyPatch::typeName; wordList patchPhysicalTypes(nPatches); label nAddedPatches = 0; for (int bci=0; bci 1) { patchNames[nAddedPatches] += name(rgi+1); } boundary[nAddedPatches] = pFaces[bci][rgi]; nAddedPatches++; } } } // Remove unused points and update cell and face labels accordingly labelList pointLabels(nPoints, -1); // Scan cells for used points forAll (cellShapes, celli) { forAll (cellShapes[celli], i) { pointLabels[cellShapes[celli][i]] = 1; } } // Create addressing for used points and pack points array label newPointi = 0; forAll (pointLabels, pointi) { if (pointLabels[pointi] != -1) { pointLabels[pointi] = newPointi; points[newPointi++] = points[pointi]; } } points.setSize(newPointi); // Reset cell point labels forAll (cellShapes, celli) { cellShape& cs = cellShapes[celli]; forAll (cs, i) { cs[i] = pointLabels[cs[i]]; } } // Reset boundary-face point labels forAll (boundary, patchi) { forAll (boundary[patchi], facei) { face& f = boundary[patchi][facei]; forAll (f, i) { f[i] = pointLabels[f[i]]; } } } preservePatchTypes ( runTime, runTime.constant(), polyMesh::defaultRegion, patchNames, patchTypes, defaultFacesName, defaultFacesType, patchPhysicalTypes ); // Build the mesh and write it out polyMesh pShapeMesh ( IOobject ( polyMesh::defaultRegion, runTime.constant(), runTime ), xferMove(points), cellShapes, boundary, patchNames, patchTypes, defaultFacesName, defaultFacesType, patchPhysicalTypes ); Info << "Writing polyMesh" << endl; pShapeMesh.write(); fileName czPath ( runTime.path()/runTime.constant()/polyMesh::defaultRegion/"cellZoning" ); Info << "Writing cell zoning info to file: " << czPath << endl; OFstream cz(czPath); cz << cellZoning << endl;