#include #include "meshing.hpp" #include "debugging.hpp" namespace netgen { extern const char * tetrules[]; // extern const char * tetrules2[]; extern const char * prismrules2[]; extern const char * pyramidrules[]; extern const char * pyramidrules2[]; extern const char * hexrules[]; struct MeshingData { int domain; // mesh for one domain (contains all adjacent surface elments) unique_ptr mesh; // maps from local (domain) mesh to global mesh Array pmap; // Array connected_pairs; MeshingParameters mp; unique_ptr meshing; }; // extract surface meshes belonging to individual domains Array DivideMesh(Mesh & mesh, const MeshingParameters & mp) { static Timer timer("DivideMesh"); RegionTimer rt(timer); Array ret; auto num_domains = mesh.GetNDomains(); if(num_domains==1 || mp.only3D_domain_nr) { ret.SetSize(1); // no need to divide mesh, just fill in meshing data ret[0].domain = 1; if(mp.only3D_domain_nr) ret[0].domain = mp.only3D_domain_nr; ret[0].mesh.reset(&mesh); // careful, this unique_ptr must not delete &mesh! (it will be released in MergeMeshes after meshing) ret[0].mp = mp; return ret; } ret.SetSize(num_domains); Array> ipmap; ipmap.SetSize(num_domains); auto dim = mesh.GetDimension(); auto num_points = mesh.GetNP(); auto num_facedescriptors = mesh.GetNFD(); for(auto i : Range(ret)) { auto & md = ret[i]; md.domain = i+1; md.mp = mp; md.mp.maxh = min2 (mp.maxh, mesh.MaxHDomain(md.domain)); ret[i].mesh = make_unique(); auto & m = *ret[i].mesh; m.SetLocalH(mesh.GetLocalH()); ipmap[i].SetSize(num_points); ipmap[i] = PointIndex::INVALID; m.SetDimension( mesh.GetDimension() ); m.SetGeometry( mesh.GetGeometry() ); for(auto i : Range(1, num_facedescriptors+1)) m.AddFaceDescriptor( mesh.GetFaceDescriptor(i) ); } // mark used points for each domain, add surface elements (with wrong point numbers) to domain mesh for(const auto & sel : mesh.SurfaceElements()) { const auto & fd = mesh.GetFaceDescriptor(sel.GetIndex()); int dom_in = fd.DomainIn(); int dom_out = fd.DomainOut(); for( auto dom : {dom_in, dom_out} ) { if(dom==0) continue; auto & sels = ret[dom-1].mesh->SurfaceElements(); for(auto pi : sel.PNums()) ipmap[dom-1][pi] = 1; sels.Append(sel); } } // mark locked/fixed points for each domain TODO: domain bounding box to add only relevant points? for(auto pi : mesh.LockedPoints()) for(auto i : Range(ret)) ipmap[i][pi] = 1; // add used points to domain mesh, build point mapping for(auto i : Range(ret)) { auto & m = *ret[i].mesh; auto & pmap = ret[i].pmap; for(auto pi : Range(ipmap[i])) if(ipmap[i][pi]) { auto pi_new = m.AddPoint( mesh[pi] ); ipmap[i][pi] = pi_new; pmap.Append( pi ); } } // add segmetns for(auto i : Range(ret)) { auto & imap = ipmap[i]; auto & m = *ret[i].mesh; for(auto seg : mesh.LineSegments()) if(imap[seg[0]].IsValid() && imap[seg[1]].IsValid()) { seg[0] = imap[seg[0]]; seg[1] = imap[seg[1]]; m.AddSegment(seg); } } auto & identifications = mesh.GetIdentifications(); for(auto i : Range(ret)) { auto & m = *ret[i].mesh; auto & imap = ipmap[i]; auto nmax = identifications.GetMaxNr (); auto & m_ident = m.GetIdentifications(); for (auto & sel : m.SurfaceElements()) for(auto & pi : sel.PNums()) pi = imap[pi]; for(auto n : Range(1,nmax+1)) { NgArray pairs; identifications.GetPairs(n, pairs); for(auto pair : pairs) { auto pi0 = imap[pair[0]]; auto pi1 = imap[pair[1]]; if(!pi0.IsValid() || !pi1.IsValid()) continue; if(pi1 connectednodes; for (int nr = 1; nr <= mesh.GetIdentifications().GetMaxNr(); nr++) if (mesh.GetIdentifications().GetType(nr) != Identifications::PERIODIC) { mesh.GetIdentifications().GetPairs (nr, connectednodes); for (auto pair : connectednodes) meshing.AddConnectedPair (pair); } // for (auto pair : md.connected_pairs) // meshing.AddConnectedPair (pair); for (int i = 1; i <= mesh.GetNOpenElements(); i++) { Element2d hel = mesh.OpenElement(i); meshing.AddBoundaryElement (hel); } oldne = mesh.GetNE(); meshing.GenerateMesh (mesh, mpquad); for (int i = oldne + 1; i <= mesh.GetNE(); i++) mesh.VolumeElement(i).SetIndex (domain); (*testout) << "mesh has " << mesh.GetNE() << " prism/pyramid elements" << endl; mesh.FindOpenElements(domain); } } if (mesh.HasOpenQuads()) { PrintSysError ("mesh has still open quads"); throw NgException ("Stop meshing since too many attempts"); // return MESHING3_GIVEUP; } } void MeshDomain( MeshingData & md) { auto & mesh = *md.mesh; auto domain = md.domain; MeshingParameters & mp = md.mp; mesh.CalcSurfacesOfNode(); mesh.FindOpenElements(md.domain); md.meshing = make_unique(nullptr); for (PointIndex pi : mesh.Points().Range()) md.meshing->AddPoint (mesh[pi], pi); for (int i = 1; i <= mesh.GetNOpenElements(); i++) md.meshing->AddBoundaryElement (mesh.OpenElement(i)); if (mp.delaunay && mesh.GetNOpenElements()) { int oldne = mesh.GetNE(); md.meshing->Delaunay (mesh, domain, mp); for (int i = oldne + 1; i <= mesh.GetNE(); i++) mesh.VolumeElement(i).SetIndex (domain); PrintMessage (3, mesh.GetNP(), " points, ", mesh.GetNE(), " elements"); } Box<3> domain_bbox( Box<3>::EMPTY_BOX ); for (auto & sel : mesh.SurfaceElements()) { if (sel.IsDeleted() ) continue; for (auto pi : sel.PNums()) domain_bbox.Add (mesh[pi]); } domain_bbox.Increase (0.01 * domain_bbox.Diam()); mesh.FindOpenElements(domain); int cntsteps = 0; int meshed; if (mesh.GetNOpenElements()) do { if (multithread.terminate) break; mesh.FindOpenElements(domain); PrintMessage (5, mesh.GetNOpenElements(), " open faces"); GetOpenElements( mesh, domain )->Save("open_"+ToString(cntsteps)+".vol"); cntsteps++; if (cntsteps > mp.maxoutersteps) throw NgException ("Stop meshing since too many attempts"); PrintMessage (1, "start tetmeshing"); Meshing3 meshing(tetrules); Array glob2loc(mesh.GetNP()); glob2loc = PointIndex::INVALID; for (PointIndex pi : mesh.Points().Range()) if (domain_bbox.IsIn (mesh[pi])) glob2loc[pi] = meshing.AddPoint (mesh[pi], pi); for (auto sel : mesh.OpenElements() ) { for(auto & pi : sel.PNums()) pi = glob2loc[pi]; meshing.AddBoundaryElement (sel); } int oldne = mesh.GetNE(); mp.giveuptol = 15 + 10 * cntsteps; mp.sloppy = 5; meshing.GenerateMesh (mesh, mp); for (ElementIndex ei = oldne; ei < mesh.GetNE(); ei++) mesh[ei].SetIndex (domain); mesh.CalcSurfacesOfNode(); mesh.FindOpenElements(domain); // teterrpow = 2; if (mesh.GetNOpenElements() != 0) { meshed = 0; PrintMessage (5, mesh.GetNOpenElements(), " open faces found"); MeshOptimize3d optmesh(mp); const char * optstr = "mcmstmcmstmcmstmcm"; for (size_t j = 1; j <= strlen(optstr); j++) { mesh.CalcSurfacesOfNode(); mesh.FreeOpenElementsEnvironment(2); mesh.CalcSurfacesOfNode(); switch (optstr[j-1]) { case 'c': optmesh.CombineImprove(mesh, OPT_REST); break; case 'd': optmesh.SplitImprove(mesh, OPT_REST); break; case 's': optmesh.SwapImprove(mesh, OPT_REST); break; case 't': optmesh.SwapImprove2(mesh, OPT_REST); break; case 'm': mesh.ImproveMesh(mp, OPT_REST); break; } } mesh.FindOpenElements(); PrintMessage (3, "Call remove problem"); // mesh.Save("before_remove.vol"); RemoveProblem (mesh, domain); // mesh.Save("after_remove.vol"); mesh.FindOpenElements(); } else { meshed = 1; PrintMessage (1, "Success !"); } } while (!meshed); { PrintMessage (3, "Check subdomain ", domain, " / ", mesh.GetNDomains()); mesh.FindOpenElements(domain); bool res = (mesh.CheckConsistentBoundary() != 0); if (res) { PrintError ("Surface mesh not consistent"); throw NgException ("Stop meshing since surface mesh not consistent"); } } } void MergeMeshes( Mesh & mesh, Array & md ) { // todo: optimize: count elements, alloc all memory, copy vol elements in parallel static Timer t("MergeMeshes"); RegionTimer rt(t); if(md.Size()==1) { // assume that mesh was never divided, no need to do anything if(&mesh != md[0].mesh.get()) throw Exception("Illegal Mesh pointer in MeshingData"); md[0].mesh.release(); return; } for(auto & m_ : md) { auto first_new_pi = m_.pmap.Range().Next(); auto & m = *m_.mesh; Array pmap(m.Points().Size()); for(auto pi : Range(PointIndex(PointIndex::BASE), first_new_pi)) pmap[pi] = m_.pmap[pi]; for (auto pi : Range(first_new_pi, m.Points().Range().Next())) pmap[pi] = mesh.AddPoint(m[pi]); for ( auto el : m.VolumeElements() ) { for (auto i : Range(el.GetNP())) el[i] = pmap[el[i]]; el.SetIndex(m_.domain); mesh.AddVolumeElement(el); } } } void MergeMeshes( Mesh & mesh, FlatArray meshes, PointIndex first_new_pi ) { // todo: optimize: count elements, alloc all memory, copy vol elements in parallel static Timer t("MergeMeshes"); RegionTimer rt(t); for(auto & m : meshes) { Array pmap(m.Points().Size()); for(auto pi : Range(PointIndex(PointIndex::BASE), first_new_pi)) pmap[pi] = pi; for (auto pi : Range(first_new_pi, m.Points().Range().Next())) pmap[pi] = mesh.AddPoint(m[pi]); for ( auto el : m.VolumeElements() ) { for (auto i : Range(el.GetNP())) el[i] = pmap[el[i]]; mesh.AddVolumeElement(el); } } } // extern double teterrpow; MESHING3_RESULT MeshVolume (const MeshingParameters & mp, Mesh& mesh3d) { static Timer t("MeshVolume"); RegionTimer reg(t); mesh3d.Compress(); if(mesh3d.GetNDomains()==0) return MESHING3_OK; if (!mesh3d.HasLocalHFunction()) mesh3d.CalcLocalH(mp.grading); auto md = DivideMesh(mesh3d, mp); ParallelFor( md.Range(), [&](int i) { if (mp.checkoverlappingboundary) if (md[i].mesh->CheckOverlappingBoundary()) throw NgException ("Stop meshing since boundary mesh is overlapping"); CloseOpenQuads( md[i] ); MeshDomain(md[i]); }); MergeMeshes(mesh3d, md); MeshQuality3d (mesh3d); return MESHING3_OK; } MESHING3_RESULT OptimizeVolume (const MeshingParameters & mp, Mesh & mesh3d) // const CSGeometry * geometry) { static Timer t("OptimizeVolume"); RegionTimer reg(t); RegionTaskManager rtm(mp.parallel_meshing ? mp.nthreads : 0); const char* savetask = multithread.task; multithread.task = "Optimize Volume"; 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 (auto i : Range(mp.optsteps3d)) { if (multithread.terminate) break; MeshOptimize3d optmesh(mp); // teterrpow = mp.opterrpow; // for (size_t j = 1; j <= strlen(mp.optimize3d); j++) for (auto j : Range(mp.optimize3d.size())) { multithread.percent = 100.* (double(j)/mp.optimize3d.size() + i)/mp.optsteps3d; if (multithread.terminate) break; switch (mp.optimize3d[j]) { case 'c': optmesh.CombineImprove(mesh3d, OPT_REST); break; case 'd': optmesh.SplitImprove(mesh3d); break; case 'D': optmesh.SplitImprove2(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(mp); break; case 'M': mesh3d.ImproveMesh(mp); break; #endif case 'j': mesh3d.ImproveMeshJacobian(mp); break; } } // mesh3d.mglevels = 1; MeshQuality3d (mesh3d); } multithread.task = savetask; return MESHING3_OK; } void RemoveIllegalElements (Mesh & mesh3d) { static Timer t("RemoveIllegalElements"); RegionTimer reg(t); 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(); MeshingParameters dummymp; MeshOptimize3d optmesh(dummymp); 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"); } }