#include #include "meshing.hpp" namespace netgen { extern const char * tetrules[]; // extern const char * tetrules2[]; extern const char * prismrules2[]; extern const char * pyramidrules[]; extern const char * pyramidrules2[]; extern double teterrpow; MESHING3_RESULT MeshVolume (MeshingParameters & mp, Mesh& mesh3d) { int i, oldne; PointIndex pi; int meshed; int cntsteps; Array connectednodes; if (&mesh3d.LocalHFunction() == NULL) mesh3d.CalcLocalH(); mesh3d.Compress(); // mesh3d.PrintMemInfo (cout); if (mp.checkoverlappingboundary) if (mesh3d.CheckOverlappingBoundary()) throw NgException ("Stop meshing since boundary mesh is overlapping"); int nonconsist = 0; for (int k = 1; k <= mesh3d.GetNDomains(); k++) { PrintMessage (3, "Check subdomain ", k, " / ", mesh3d.GetNDomains()); mesh3d.FindOpenElements(k); /* bool res = mesh3d.CheckOverlappingBoundary(); if (res) { PrintError ("Surface is overlapping !!"); nonconsist = 1; } */ bool res = (mesh3d.CheckConsistentBoundary() != 0); if (res) { PrintError ("Surface mesh not consistent"); nonconsist = 1; } } if (nonconsist) { PrintError ("Stop meshing since surface mesh not consistent"); throw NgException ("Stop meshing since surface mesh not consistent"); } double globmaxh = mp.maxh; for (int k = 1; k <= mesh3d.GetNDomains(); k++) { if (multithread.terminate) break; PrintMessage (2, ""); PrintMessage (1, "Meshing subdomain ", k, " of ", mesh3d.GetNDomains()); (*testout) << "Meshing subdomain " << k << endl; mp.maxh = min2 (globmaxh, mesh3d.MaxHDomain(k)); mesh3d.CalcSurfacesOfNode(); mesh3d.FindOpenElements(k); if (!mesh3d.GetNOpenElements()) continue; Box<3> domain_bbox( Box<3>::EMPTY_BOX ); for (SurfaceElementIndex sei = 0; sei < mesh3d.GetNSE(); sei++) { const Element2d & el = mesh3d[sei]; if (el.IsDeleted() ) continue; if (mesh3d.GetFaceDescriptor(el.GetIndex()).DomainIn() == k || mesh3d.GetFaceDescriptor(el.GetIndex()).DomainOut() == k) for (int j = 0; j < el.GetNP(); j++) domain_bbox.Add (mesh3d[el[j]]); } domain_bbox.Increase (0.01 * domain_bbox.Diam()); for (int qstep = 1; qstep <= 3; qstep++) { if (mesh3d.HasOpenQuads()) { string rulefile = ngdir; const char ** rulep = NULL; switch (qstep) { case 1: rulefile += "/rules/prisms2.rls"; rulep = prismrules2; break; case 2: // connect pyramid to triangle rulefile += "/rules/pyramids2.rls"; rulep = pyramidrules2; break; case 3: // connect to vis-a-vis point rulefile += "/rules/pyramids.rls"; rulep = pyramidrules; break; } // Meshing3 meshing(rulefile); Meshing3 meshing(rulep); MeshingParameters mpquad = mp; mpquad.giveuptol = 15; mpquad.baseelnp = 4; mpquad.starshapeclass = 1000; mpquad.check_impossible = qstep == 1; // for prisms only (air domain in trafo) for (pi = PointIndex::BASE; pi < mesh3d.GetNP()+PointIndex::BASE; pi++) meshing.AddPoint (mesh3d[pi], pi); mesh3d.GetIdentifications().GetPairs (0, connectednodes); for (i = 1; i <= connectednodes.Size(); i++) meshing.AddConnectedPair (connectednodes.Get(i)); for (i = 1; i <= mesh3d.GetNOpenElements(); i++) { Element2d hel = mesh3d.OpenElement(i); meshing.AddBoundaryElement (hel); } oldne = mesh3d.GetNE(); meshing.GenerateMesh (mesh3d, mpquad); for (i = oldne + 1; i <= mesh3d.GetNE(); i++) mesh3d.VolumeElement(i).SetIndex (k); (*testout) << "mesh has " << mesh3d.GetNE() << " prism/pyramid elements" << endl; mesh3d.FindOpenElements(k); } } if (mesh3d.HasOpenQuads()) { PrintSysError ("mesh has still open quads"); throw NgException ("Stop meshing since too many attempts"); // return MESHING3_GIVEUP; } if (mp.delaunay && mesh3d.GetNOpenElements()) { Meshing3 meshing((const char**)NULL); mesh3d.FindOpenElements(k); for (pi = PointIndex::BASE; pi < mesh3d.GetNP()+PointIndex::BASE; pi++) meshing.AddPoint (mesh3d[pi], pi); for (i = 1; i <= mesh3d.GetNOpenElements(); i++) meshing.AddBoundaryElement (mesh3d.OpenElement(i)); oldne = mesh3d.GetNE(); meshing.Delaunay (mesh3d, k, mp); for (i = oldne + 1; i <= mesh3d.GetNE(); i++) mesh3d.VolumeElement(i).SetIndex (k); PrintMessage (3, mesh3d.GetNP(), " points, ", mesh3d.GetNE(), " elements"); } cntsteps = 0; if (mesh3d.GetNOpenElements()) do { if (multithread.terminate) break; mesh3d.FindOpenElements(k); PrintMessage (5, mesh3d.GetNOpenElements(), " open faces"); cntsteps++; if (cntsteps > mp.maxoutersteps) throw NgException ("Stop meshing since too many attempts"); string rulefile = ngdir + "/tetra.rls"; PrintMessage (1, "start tetmeshing"); // Meshing3 meshing(rulefile); Meshing3 meshing(tetrules); Array glob2loc(mesh3d.GetNP()); glob2loc = -1; for (pi = PointIndex::BASE; pi < mesh3d.GetNP()+PointIndex::BASE; pi++) if (domain_bbox.IsIn (mesh3d[pi])) glob2loc[pi] = meshing.AddPoint (mesh3d[pi], pi); for (i = 1; i <= mesh3d.GetNOpenElements(); i++) { Element2d hel = mesh3d.OpenElement(i); for (int j = 0; j < hel.GetNP(); j++) hel[j] = glob2loc[hel[j]]; meshing.AddBoundaryElement (hel); // meshing.AddBoundaryElement (mesh3d.OpenElement(i)); } oldne = mesh3d.GetNE(); mp.giveuptol = 15 + 10 * cntsteps; mp.sloppy = 5; meshing.GenerateMesh (mesh3d, mp); for (ElementIndex ei = oldne; ei < mesh3d.GetNE(); ei++) mesh3d[ei].SetIndex (k); mesh3d.CalcSurfacesOfNode(); mesh3d.FindOpenElements(k); teterrpow = 2; if (mesh3d.GetNOpenElements() != 0) { meshed = 0; PrintMessage (5, mesh3d.GetNOpenElements(), " open faces found"); // mesh3d.Save ("tmp.vol"); MeshOptimize3d optmesh; const char * optstr = "mcmstmcmstmcmstmcm"; size_t j; for (j = 1; j <= strlen(optstr); j++) { mesh3d.CalcSurfacesOfNode(); mesh3d.FreeOpenElementsEnvironment(2); mesh3d.CalcSurfacesOfNode(); switch (optstr[j-1]) { case 'c': optmesh.CombineImprove(mesh3d, OPT_REST); break; case 'd': optmesh.SplitImprove(mesh3d, OPT_REST); break; case 's': optmesh.SwapImprove(mesh3d, OPT_REST); break; case 't': optmesh.SwapImprove2(mesh3d, OPT_REST); break; case 'm': mesh3d.ImproveMesh(OPT_REST); break; } } mesh3d.FindOpenElements(k); PrintMessage (3, "Call remove problem"); RemoveProblem (mesh3d, k); mesh3d.FindOpenElements(k); } else { meshed = 1; PrintMessage (1, "Success !"); } } while (!meshed); PrintMessage (1, mesh3d.GetNP(), " points, ", mesh3d.GetNE(), " elements"); } mp.maxh = globmaxh; MeshQuality3d (mesh3d); return MESHING3_OK; } /* MESHING3_RESULT MeshVolumeOld (MeshingParameters & mp, Mesh& mesh3d) { int i, k, oldne; int meshed; int cntsteps; PlotStatistics3d * pstat; if (globflags.GetNumFlag("silentflag", 1) <= 2) pstat = new XPlotStatistics3d; else pstat = new TerminalPlotStatistics3d; cntsteps = 0; do { cntsteps++; if (cntsteps > mp.maxoutersteps) { return MESHING3_OUTERSTEPSEXCEEDED; } int noldp = mesh3d.GetNP(); if ( (cntsteps == 1) && globflags.GetDefineFlag ("delaunay")) { cntsteps ++; mesh3d.CalcSurfacesOfNode(); for (k = 1; k <= mesh3d.GetNDomains(); k++) { Meshing3 meshing(NULL, pstat); mesh3d.FindOpenElements(k); for (i = 1; i <= noldp; i++) meshing.AddPoint (mesh3d.Point(i), i); for (i = 1; i <= mesh3d.GetNOpenElements(); i++) { if (mesh3d.OpenElement(i).GetIndex() == k) meshing.AddBoundaryElement (mesh3d.OpenElement(i)); } oldne = mesh3d.GetNE(); if (globflags.GetDefineFlag ("blockfill")) { if (!globflags.GetDefineFlag ("localh")) meshing.BlockFill (mesh3d, mp.h * globflags.GetNumFlag ("relblockfillh", 1)); else meshing.BlockFillLocalH (mesh3d); } MeshingParameters mpd; meshing.Delaunay (mesh3d, mpd); for (i = oldne + 1; i <= mesh3d.GetNE(); i++) mesh3d.VolumeElement(i).SetIndex (k); } } noldp = mesh3d.GetNP(); mesh3d.CalcSurfacesOfNode(); mesh3d.FindOpenElements(); for (k = 1; k <= mesh3d.GetNDomains(); k++) { Meshing3 meshing(globflags.GetStringFlag ("rules3d", NULL), pstat); Point3d pmin, pmax; mesh3d.GetBox (pmin, pmax, k); rot.SetCenter (Center (pmin, pmax)); for (i = 1; i <= noldp; i++) meshing.AddPoint (mesh3d.Point(i), i); for (i = 1; i <= mesh3d.GetNOpenElements(); i++) { if (mesh3d.OpenElement(i).GetIndex() == k) meshing.AddBoundaryElement (mesh3d.OpenElement(i)); } oldne = mesh3d.GetNE(); if ( (cntsteps == 1) && globflags.GetDefineFlag ("blockfill")) { if (!globflags.GetDefineFlag ("localh")) { meshing.BlockFill (mesh3d, mp.h * globflags.GetNumFlag ("relblockfillh", 1)); } else { meshing.BlockFillLocalH (mesh3d); } } mp.giveuptol = int(globflags.GetNumFlag ("giveuptol", 15)); meshing.GenerateMesh (mesh3d, mp); for (i = oldne + 1; i <= mesh3d.GetNE(); i++) mesh3d.VolumeElement(i).SetIndex (k); } mesh3d.CalcSurfacesOfNode(); mesh3d.FindOpenElements(); teterrpow = 2; if (mesh3d.GetNOpenElements() != 0) { meshed = 0; (*mycout) << "Open elements found, old" << endl; const char * optstr = "mcmcmcmcm"; int j; for (j = 1; j <= strlen(optstr); j++) switch (optstr[j-1]) { case 'c': mesh3d.CombineImprove(); break; case 'd': mesh3d.SplitImprove(); break; case 's': mesh3d.SwapImprove(); break; case 'm': mesh3d.ImproveMesh(2); break; } (*mycout) << "Call remove" << endl; RemoveProblem (mesh3d); (*mycout) << "Problem removed" << endl; } else meshed = 1; } while (!meshed); MeshQuality3d (mesh3d); return MESHING3_OK; } */ /* MESHING3_RESULT MeshMixedVolume(MeshingParameters & mp, Mesh& mesh3d) { int i, j; MESHING3_RESULT res; Point3d pmin, pmax; mp.giveuptol = 10; mp.baseelnp = 4; mp.starshapeclass = 100; // TerminalPlotStatistics3d pstat; Meshing3 meshing1("pyramids.rls"); for (i = 1; i <= mesh3d.GetNP(); i++) meshing1.AddPoint (mesh3d.Point(i), i); mesh3d.FindOpenElements(); for (i = 1; i <= mesh3d.GetNOpenElements(); i++) if (mesh3d.OpenElement(i).GetIndex() == 1) meshing1.AddBoundaryElement (mesh3d.OpenElement(i)); res = meshing1.GenerateMesh (mesh3d, mp); mesh3d.GetBox (pmin, pmax); PrintMessage (1, "Mesh pyramids, res = ", res); if (res) exit (1); for (i = 1; i <= mesh3d.GetNE(); i++) mesh3d.VolumeElement(i).SetIndex (1); // do delaunay mp.baseelnp = 0; mp.starshapeclass = 5; Meshing3 meshing2(NULL); for (i = 1; i <= mesh3d.GetNP(); i++) meshing2.AddPoint (mesh3d.Point(i), i); mesh3d.FindOpenElements(); for (i = 1; i <= mesh3d.GetNOpenElements(); i++) if (mesh3d.OpenElement(i).GetIndex() == 1) meshing2.AddBoundaryElement (mesh3d.OpenElement(i)); MeshingParameters mpd; meshing2.Delaunay (mesh3d, mpd); for (i = 1; i <= mesh3d.GetNE(); i++) mesh3d.VolumeElement(i).SetIndex (1); mp.baseelnp = 0; mp.giveuptol = 10; for (int trials = 1; trials <= 50; trials++) { if (multithread.terminate) return MESHING3_TERMINATE; Meshing3 meshing3("tetra.rls"); for (i = 1; i <= mesh3d.GetNP(); i++) meshing3.AddPoint (mesh3d.Point(i), i); mesh3d.FindOpenElements(); for (i = 1; i <= mesh3d.GetNOpenElements(); i++) if (mesh3d.OpenElement(i).GetIndex() == 1) meshing3.AddBoundaryElement (mesh3d.OpenElement(i)); if (trials > 1) CheckSurfaceMesh2 (mesh3d); res = meshing3.GenerateMesh (mesh3d, mp); for (i = 1; i <= mesh3d.GetNE(); i++) mesh3d.VolumeElement(i).SetIndex (1); if (res == 0) break; for (i = 1; i <= mesh3d.GetNE(); i++) { const Element & el = mesh3d.VolumeElement(i); if (el.GetNP() != 4) { for (j = 1; j <= el.GetNP(); j++) mesh3d.AddLockedPoint (el.PNum(j)); } } mesh3d.CalcSurfacesOfNode(); mesh3d.FindOpenElements(); MeshOptimize3d optmesh; teterrpow = 2; const char * optstr = "mcmcmcmcm"; for (j = 1; j <= strlen(optstr); j++) switch (optstr[j-1]) { case 'c': optmesh.CombineImprove(mesh3d, OPT_REST); break; case 'd': optmesh.SplitImprove(mesh3d); break; case 's': optmesh.SwapImprove(mesh3d); break; case 'm': mesh3d.ImproveMesh(); break; } RemoveProblem (mesh3d); } PrintMessage (1, "Meshing tets, res = ", res); if (res) { mesh3d.FindOpenElements(); PrintSysError (1, "Open elemetns: ", mesh3d.GetNOpenElements()); exit (1); } for (i = 1; i <= mesh3d.GetNE(); i++) { const Element & el = mesh3d.VolumeElement(i); if (el.GetNP() != 4) { for (j = 1; j <= el.GetNP(); j++) mesh3d.AddLockedPoint (el.PNum(j)); } } mesh3d.CalcSurfacesOfNode(); mesh3d.FindOpenElements(); MeshOptimize3d optmesh; teterrpow = 2; const char * optstr = "mcmcmcmcm"; for (j = 1; j <= strlen(optstr); j++) switch (optstr[j-1]) { case 'c': optmesh.CombineImprove(mesh3d, OPT_REST); break; case 'd': optmesh.SplitImprove(mesh3d); break; case 's': optmesh.SwapImprove(mesh3d); break; case 'm': mesh3d.ImproveMesh(); break; } return MESHING3_OK; } */ MESHING3_RESULT OptimizeVolume (MeshingParameters & mp, Mesh & mesh3d) // const CSGeometry * geometry) { int i; PrintMessage (1, "Volume Optimization"); /* if (!mesh3d.PureTetMesh()) return MESHING3_OK; */ // (*mycout) << "optstring = " << mp.optimize3d << endl; /* const char * optstr = globflags.GetStringFlag ("optimize3d", "cmh"); int optsteps = int (globflags.GetNumFlag ("optsteps3d", 2)); */ mesh3d.CalcSurfacesOfNode(); for (i = 1; i <= mp.optsteps3d; i++) { if (multithread.terminate) break; MeshOptimize3d optmesh; teterrpow = mp.opterrpow; for (size_t j = 1; j <= strlen(mp.optimize3d); j++) { if (multithread.terminate) break; switch (mp.optimize3d[j-1]) { case 'c': optmesh.CombineImprove(mesh3d, OPT_REST); break; case 'd': optmesh.SplitImprove(mesh3d); break; case 's': optmesh.SwapImprove(mesh3d); break; // case 'u': optmesh.SwapImproveSurface(mesh3d); break; case 't': optmesh.SwapImprove2(mesh3d); break; #ifdef SOLIDGEOM case 'm': mesh3d.ImproveMesh(*geometry); break; case 'M': mesh3d.ImproveMesh(*geometry); break; #else case 'm': mesh3d.ImproveMesh(); break; case 'M': mesh3d.ImproveMesh(); break; #endif case 'j': mesh3d.ImproveMeshJacobian(); break; } } mesh3d.mglevels = 1; MeshQuality3d (mesh3d); } return MESHING3_OK; } void RemoveIllegalElements (Mesh & mesh3d) { int it = 10; int nillegal, oldn; PrintMessage (1, "Remove Illegal Elements"); // return, if non-pure tet-mesh /* if (!mesh3d.PureTetMesh()) return; */ mesh3d.CalcSurfacesOfNode(); nillegal = mesh3d.MarkIllegalElements(); MeshOptimize3d optmesh; while (nillegal && (it--) > 0) { if (multithread.terminate) break; PrintMessage (5, nillegal, " illegal tets"); optmesh.SplitImprove (mesh3d, OPT_LEGAL); mesh3d.MarkIllegalElements(); // test optmesh.SwapImprove (mesh3d, OPT_LEGAL); mesh3d.MarkIllegalElements(); // test optmesh.SwapImprove2 (mesh3d, OPT_LEGAL); oldn = nillegal; nillegal = mesh3d.MarkIllegalElements(); if (oldn != nillegal) it = 10; } PrintMessage (5, nillegal, " illegal tets"); } }