#include #include #include #include #include "meshing.hpp" #ifdef SOLIDGEOM #include #endif #include namespace netgen { static constexpr int tetedges[6][2] = { { 0, 1 }, { 0, 2 }, { 0, 3 }, { 1, 2 }, { 1, 3 }, { 2, 3 } }; static constexpr int IMPROVEMENT_CONFORMING_EDGE = -1e6; static inline bool NotTooBad(double bad1, double bad2) { return (bad2 <= bad1) || (bad2 <= 100 * bad1 && bad2 <= 1e18) || (bad2 <= 1e8); } // Calc badness of new element where pi1 and pi2 are replaced by pnew double CalcBadReplacePoints (const Mesh::T_POINTS & points, const MeshingParameters & mp, const Element & elem, double h, PointIndex &pi1, PointIndex &pi2, MeshPoint &pnew) { if (elem.GetType() != TET) return 0; MeshPoint* p[] = {&points[elem[0]], &points[elem[1]], &points[elem[2]], &points[elem[3]]}; for (auto i : Range(4)) if(elem[i]==pi1 || elem[i]==pi2) p[i] = &pnew; return CalcTetBadness (*p[0], *p[1], *p[2], *p[3], h, mp); } static ArrayMem SplitElement (Element old, PointIndex pi0, PointIndex pi1, PointIndex pinew) { ArrayMem new_elements; // split element by cutting edge pi0,pi1 at pinew auto np = old.GetNP(); old.Touch(); if(np == 4) { // Split tet into two tets Element newel0 = old; Element newel1 = old; for (int i : Range(4)) { if(newel0[i] == pi0) newel0[i] = pinew; if(newel1[i] == pi1) newel1[i] = pinew; } new_elements.Append(newel0); new_elements.Append(newel1); } else if (np == 5) { // split pyramid into pyramid and two tets Element new_pyramid = old; new_pyramid[4] = pinew; new_elements.Append(new_pyramid); auto pibase = (pi0==old[4]) ? pi1 : pi0; auto pitop = (pi0==old[4]) ? pi0 : pi1; Element new_tet0 = old; Element new_tet1 = old; new_tet0.SetType(TET); new_tet1.SetType(TET); size_t pibase_index=0; for(auto i : Range(4)) if(old[i]==pibase) pibase_index = i; new_tet0[0] = old[(pibase_index+1)%4]; new_tet0[1] = old[(pibase_index+2)%4]; new_tet0[2] = pinew; new_tet0[3] = pitop; new_elements.Append(new_tet0); new_tet1[0] = old[(pibase_index+2)%4]; new_tet1[1] = old[(pibase_index+3)%4]; new_tet1[2] = pinew; new_tet1[3] = pitop; new_elements.Append(new_tet1); } return new_elements; } static double SplitElementBadness (const Mesh::T_POINTS & points, const MeshingParameters & mp, Element old, PointIndex pi0, PointIndex pi1, MeshPoint & pnew) { double badness = 0; auto np = old.GetNP(); PointIndex dummy{-1}; if(np == 4) { // Split tet into two tets badness += CalcBadReplacePoints ( points, mp, old, 0, pi0, dummy, pnew ); badness += CalcBadReplacePoints ( points, mp, old, 0, pi1, dummy, pnew ); } else if (np == 5) { // split pyramid into pyramid and two tets auto pibase = (pi0==old[4]) ? pi1 : pi0; auto pitop = (pi0==old[4]) ? pi0 : pi1; badness += CalcBadReplacePoints ( points, mp, old, 0, pitop, dummy, pnew ); Element tet = old; tet.SetType(TET); size_t pibase_index=0; for(auto i : Range(4)) if(old[i]==pibase) pibase_index = i; MeshPoint p[4]; p[0] = points[old[(pibase_index+1)%4]]; p[1] = points[old[(pibase_index+2)%4]]; p[2] = pnew; p[3] = points[pitop]; badness += CalcTetBadness (p[0], p[1], p[2], p[3], 0, mp); p[0] = points[old[(pibase_index+2)%4]]; p[1] = points[old[(pibase_index+3)%4]]; p[2] = pnew; p[3] = points[pitop]; badness += CalcTetBadness (p[0], p[1], p[2], p[3], 0, mp); } return badness; } tuple MeshOptimize3d :: UpdateBadness() { static Timer tbad("UpdateBadness"); RegionTimer reg(tbad); double totalbad = 0.0; double maxbad = 0.0; atomic bad_elements = 0; ParallelForRange(Range(mesh.GetNE()), [&] (auto myrange) { double totalbad_local = 0.0; double maxbad_local = 0.0; int bad_elements_local = 0; for (ElementIndex ei : myrange) { auto & el = mesh[ei]; if(mp.only3D_domain_nr && mp.only3D_domain_nr != el.GetIndex()) continue; if(!el.BadnessValid()) el.SetBadness(CalcBad(mesh.Points(), el, 0)); double bad = el.GetBadness(); totalbad_local += bad; maxbad_local = max(maxbad_local, bad); if(bad > min_badness) bad_elements_local++; } AtomicAdd(totalbad, totalbad_local); AtomicMax(maxbad, maxbad_local); bad_elements += bad_elements_local; }); return {totalbad, maxbad, bad_elements}; } bool MeshOptimize3d :: HasBadElement(FlatArray els) { for(auto ei : els) if(mesh[ei].GetBadness()>min_badness) return true; return false; } bool MeshOptimize3d :: HasIllegalElement(FlatArray els) { for(auto ei : els) if(!mesh.LegalTet(mesh[ei])) return true; return false; } bool MeshOptimize3d :: NeedsOptimization(FlatArray els) { if(goal == OPT_LEGAL) return HasIllegalElement(els); if(goal == OPT_QUALITY) return HasBadElement(els); return true; } /* Combine two points to one. Set new point into the center, if both are inner points. Connect inner point to boundary point, if one point is inner point. */ double MeshOptimize3d :: CombineImproveEdge ( Table & elements_of_point, PointIndex pi0, PointIndex pi1, FlatArray is_point_removed, bool check_only) { if (pi1 < pi0) Swap (pi0, pi1); if(is_point_removed[pi0] || is_point_removed[pi1]) return false; MeshPoint p0 = mesh[pi0]; MeshPoint p1 = mesh[pi1]; if (p1.Type() != INNERPOINT) return false; ArrayMem has_one_point; ArrayMem has_both_points; for (auto ei : elements_of_point[pi0] ) { Element & elem = mesh[ei]; if (elem.IsDeleted()) return false; if(elem.GetType() != TET) return false; // TODO: implement case where pi0 or pi1 is top of a pyramid if (elem[0] == pi1 || elem[1] == pi1 || elem[2] == pi1 || elem[3] == pi1) { if(!has_both_points.Contains(ei)) has_both_points.Append (ei); } else { if(!has_one_point.Contains(ei)) has_one_point.Append (ei); } } for (auto ei : elements_of_point[pi1] ) { Element & elem = mesh[ei]; if (elem.IsDeleted()) return false; if(elem.GetType() != TET) return false; // TODO: implement case where pi0 or pi1 is top of a pyramid if (elem[0] == pi0 || elem[1] == pi0 || elem[2] == pi0 || elem[3] == pi0) { ; } else { if(!has_one_point.Contains(ei)) has_one_point.Append (ei); } } double badness_old = 0.0; for (auto ei : has_one_point) badness_old += mesh[ei].GetBadness(); for (auto ei : has_both_points) badness_old += mesh[ei].GetBadness(); if (goal == OPT_CONFORM && p0.Type() <= EDGEPOINT) { // check if the optimization improves conformity with free segments std::set edges_before, edges_after; for (auto ei : has_one_point) { const auto el = mesh[ei]; for(auto i : Range(6)) { auto e0 = el[tetedges[i][0]]; auto e1 = el[tetedges[i][1]]; if(e0 == pi0 || e1 == pi0) edges_before.insert(e0 == pi0 ? e1 : e0); if(e0 == pi1 || e1 == pi1) edges_after.insert(e0 == pi1 ? e1 : e0); } } for(auto new_edge : edges_after) { if (edges_before.count(new_edge) == 0 && mesh[new_edge].Type() <= EDGEPOINT && mesh.BoundaryEdge (new_edge, pi0)) badness_old += GetLegalPenalty(); } } MeshPoint pnew = p0; if (p0.Type() == INNERPOINT) pnew = Center (p0, p1); ArrayMem one_point_badness(has_one_point.Size()); double badness_new = 0; for (auto i : Range(has_one_point)) { const Element & elem = mesh[has_one_point[i]]; double badness = CalcBadReplacePoints (mesh.Points(), mp, elem, 0, pi0, pi1, pnew); badness_new += badness; one_point_badness[i] = badness; } // Check if changed tets are topologically legal if (p0.Type() != INNERPOINT) { for (auto ei : has_one_point) { Element elem = mesh[ei]; // int l; for (int l = 0; l < 4; l++) if (elem[l] == pi1) { elem[l] = pi0; break; } elem.Touch(); if (!mesh.LegalTet(elem)) badness_new += GetLegalPenalty(); } } double d_badness = badness_new / has_one_point.Size() - badness_old / (has_one_point.Size()+has_both_points.Size()); // Do the actual combine operation if (d_badness < 0.0 && !check_only) { is_point_removed[pi1] = true; mesh[pi0] = pnew; for (auto ei : elements_of_point[pi1]) { Element & elem = mesh[ei]; if (elem.IsDeleted()) continue; for (int l = 0; l < elem.GetNP(); l++) if (elem[l] == pi1) elem[l] = pi0; elem.Touch(); if (!mesh.LegalTet (elem)) (*testout) << "illegal tet " << ei << endl; } for (auto i : Range(has_one_point)) mesh[has_one_point[i]].SetBadness(one_point_badness[i]); for (auto ei : has_both_points) { mesh[ei].Touch(); mesh[ei].Delete(); } } return d_badness; } void MeshOptimize3d :: CombineImprove () { static Timer t("MeshOptimize3d::CombineImprove"); RegionTimer reg(t); static Timer topt("Optimize"); static Timer tsearch("Search"); static Timer tbuild_elements_table("Build elements table"); mesh.BuildBoundaryEdges(false); int np = mesh.GetNP(); int ne = mesh.GetNE(); int ntasks = 4*ngcore::TaskManager::GetNumThreads(); Array is_point_removed (np); is_point_removed = false; PrintMessage (3, "CombineImprove"); (*testout) << "Start CombineImprove" << "\n"; // mesh.CalcSurfacesOfNode (); const char * savetask = multithread.task; multithread.task = "Optimize Volume: Combine Improve"; UpdateBadness(); if (goal == OPT_QUALITY && testout->good()) { double totalbad = mesh.CalcTotalBad (mp); (*testout) << "Total badness = " << totalbad << endl; } auto elementsonnode = mesh.CreatePoint2ElementTable(nullopt, mp.only3D_domain_nr); Array> edges; BuildEdgeList(mesh, elementsonnode, edges); // Find edges with improvement Array> combine_candidate_edges(edges.Size()); std::atomic improvement_counter(0); tsearch.Start(); ParallelForRange(Range(edges), [&] (auto myrange) { for(auto i : myrange) { auto [p0,p1] = edges[i]; double d_badness = CombineImproveEdge (elementsonnode, p0, p1, is_point_removed, true); if(d_badness<0.0) { int index = improvement_counter++; combine_candidate_edges[index] = make_tuple(d_badness, i); } } }, ntasks); tsearch.Stop(); auto edges_with_improvement = combine_candidate_edges.Part(0, improvement_counter.load()); QuickSort(edges_with_improvement); PrintMessage(5, edges.Size(), " edges"); PrintMessage(5, edges_with_improvement.Size(), " edges with improvement"); // Apply actual optimizations topt.Start(); int cnt = 0; for(auto [d_badness, ei] : edges_with_improvement) { auto [p0,p1] = edges[ei]; if (CombineImproveEdge (elementsonnode, p0, p1, is_point_removed, false) < 0.0) cnt++; } topt.Stop(); mesh.Compress(); mesh.MarkIllegalElements(); PrintMessage (5, cnt, " elements combined"); (*testout) << "CombineImprove done" << "\n"; if (goal == OPT_QUALITY && testout->good()) { double totalbad = mesh.CalcTotalBad (mp); (*testout) << "Total badness = " << totalbad << endl; int cntill = 0; for (ElementIndex ei = 0; ei < ne; ei++) if(!(mesh.GetDimension()==3 && mp.only3D_domain_nr && mp.only3D_domain_nr != mesh.VolumeElement(ei).GetIndex())) if (!mesh.LegalTet (mesh[ei])) cntill++; PrintMessage (5, cntill, " illegal tets"); } multithread.task = savetask; } double MeshOptimize3d :: SplitImproveEdge (Table & elementsonnode, NgArray &locfaces, double badmax, PointIndex pi1, PointIndex pi2, PointIndex ptmp, bool check_only) { double d_badness = 0.0; // int cnt = 0; ArrayMem hasbothpoints; if (mesh.BoundaryEdge (pi1, pi2)) return 0.0; for (ElementIndex ei : elementsonnode[pi1]) { Element & el = mesh[ei]; if(el.IsDeleted()) return 0.0; if (mesh[ei].GetType() != TET) return 0.0; bool has1 = el.PNums().Contains(pi1); bool has2 = el.PNums().Contains(pi2); if (has1 && has2) if (!hasbothpoints.Contains (ei)) hasbothpoints.Append (ei); } if(mp.only3D_domain_nr) for(auto ei : hasbothpoints) if(mp.only3D_domain_nr != mesh[ei].GetIndex()) return 0.0; if (!NeedsOptimization(hasbothpoints)) return 0.0; double bad1 = 0.0; double bad1_max = 0.0; for (ElementIndex ei : hasbothpoints) { double bad = mesh[ei].GetBadness(); bad1 += bad; bad1_max = max(bad1_max, bad); } if(bad1_max < 100.0) return 0.0; bool puretet = 1; for (ElementIndex ei : hasbothpoints) if (mesh[ei].GetType() != TET) puretet = 0; if (!puretet) return 0.0; Point3d p1 = mesh[pi1]; Point3d p2 = mesh[pi2]; locfaces.SetSize(0); for (ElementIndex ei : hasbothpoints) { const Element & el = mesh[ei]; for (int l = 0; l < 4; l++) if (el[l] == pi1 || el[l] == pi2) { INDEX_3 i3; Element2d face(TRIG); el.GetFace (l+1, face); for (int kk = 1; kk <= 3; kk++) i3.I(kk) = face.PNum(kk); locfaces.Append (i3); } } PointFunction1 pf (mesh.Points(), locfaces, mp, -1); OptiParameters par; par.maxit_linsearch = 50; par.maxit_bfgs = 20; Point3d pnew = Center (p1, p2); Vector px(3); px(0) = pnew.X(); px(1) = pnew.Y(); px(2) = pnew.Z(); if (bad1_max > 0.1 * badmax) { int pok = pf.Func (px) < 1e10; if (!pok) pok = FindInnerPoint (mesh.Points(), locfaces, pnew); if(pok) { px(0) = pnew.X(); px(1) = pnew.Y(); px(2) = pnew.Z(); BFGS (px, pf, par); pnew.X() = px(0); pnew.Y() = px(1); pnew.Z() = px(2); } } double bad2 = pf.Func (px); for (int k = 0; k < hasbothpoints.Size(); k++) { Element & oldel = mesh[hasbothpoints[k]]; Element newel1 = oldel; Element newel2 = oldel; newel1.Touch(); newel2.Touch(); for (int l = 0; l < 4; l++) { if (newel1[l] == pi2) newel1[l] = ptmp; if (newel2[l] == pi1) newel2[l] = ptmp; } if (!mesh.LegalTet (oldel)) return 0.0; if (!mesh.LegalTet (newel1)) return 0.0; if (!mesh.LegalTet (newel2)) return 0.0; } if(bad2 >= 1e24) return 0.0; d_badness = bad2-bad1; if(check_only) return d_badness; if (d_badness<0.0) { // cnt++; PointIndex pinew = mesh.AddPoint (pnew); for (ElementIndex ei : hasbothpoints) { Element & oldel = mesh[ei]; Element newel1 = oldel; Element newel2 = oldel; newel1.Touch(); newel2.Touch(); for (int l = 0; l < 4; l++) { if (newel1[l] == pi2) newel1[l] = pinew; if (newel2[l] == pi1) newel2[l] = pinew; } oldel.Touch(); oldel.Delete(); mesh.AddVolumeElement (newel1); mesh.AddVolumeElement (newel2); } } return d_badness; } void MeshOptimize3d :: SplitImprove () { static Timer t("MeshOptimize3d::SplitImprove"); RegionTimer reg(t); static Timer topt("Optimize"); static Timer tsearch("Search"); // int np = mesh.GetNP(); int ne = mesh.GetNE(); double bad = 0.0; double badmax = 0.0; auto elementsonnode = mesh.CreatePoint2ElementTable(nullopt, mp.only3D_domain_nr); const char * savetask = multithread.task; multithread.task = "Optimize Volume: Split Improve"; PrintMessage (3, "SplitImprove"); (*testout) << "start SplitImprove" << "\n"; mesh.BuildBoundaryEdges(false); UpdateBadness(); if (goal == OPT_QUALITY && testout->good()) { bad = mesh.CalcTotalBad (mp); (*testout) << "Total badness = " << bad << endl; } Array> edges; BuildEdgeList(mesh, elementsonnode, edges); // Find edges with improvement Array> candidate_edges(edges.Size()); std::atomic improvement_counter(0); auto ptmp = mesh.AddPoint( {0,0,0} ); tsearch.Start(); ParallelForRange(Range(edges), [&] (auto myrange) { NgArray locfaces; for(auto i : myrange) { auto [p0,p1] = edges[i]; double d_badness = SplitImproveEdge (elementsonnode, locfaces, badmax, p0, p1, ptmp, true); if(d_badness<0.0) { int index = improvement_counter++; candidate_edges[index] = make_tuple(d_badness, i); } } }, ngcore::TasksPerThread(4)); tsearch.Stop(); auto edges_with_improvement = candidate_edges.Part(0, improvement_counter.load()); QuickSort(edges_with_improvement); PrintMessage(5, edges.Size(), " edges"); PrintMessage(5, edges_with_improvement.Size(), " edges with improvement"); // Apply actual optimizations topt.Start(); int cnt = 0; NgArray locfaces; for(auto [d_badness, ei] : edges_with_improvement) { auto [p0,p1] = edges[ei]; if (SplitImproveEdge (elementsonnode, locfaces, badmax, p0, p1, ptmp, false) < 0.0) cnt++; } topt.Stop(); mesh.Compress(); PrintMessage (5, cnt, " splits performed"); (*testout) << "Splitt - Improve done" << "\n"; if (goal == OPT_QUALITY) { if(testout->good()) { bad = mesh.CalcTotalBad (mp); (*testout) << "Total badness = " << bad << endl; } [[maybe_unused]] int cntill = 0; ne = mesh.GetNE(); for (ElementIndex ei = 0; ei < ne; ei++) if (!mesh.LegalTet (mesh[ei])) cntill++; // cout << cntill << " illegal tets" << endl; } multithread.task = savetask; } double MeshOptimize3d :: SwapImproveEdge ( const NgBitArray * working_elements, Table & elementsonnode, INDEX_3_HASHTABLE & faces, PointIndex pi1, PointIndex pi2, bool check_only) { PointIndex pi3(PointIndex::INVALID), pi4(PointIndex::INVALID), pi5(PointIndex::INVALID), pi6(PointIndex::INVALID); double bad1, bad2, bad3; Element el21(TET), el22(TET), el31(TET), el32(TET), el33(TET); Element el1(TET), el2(TET), el3(TET), el4(TET); Element el1b(TET), el2b(TET), el3b(TET), el4b(TET); ArrayMem hasbothpoints; double d_badness = 0.0; if (pi2 < pi1) Swap (pi1, pi2); if (mesh.BoundaryEdge (pi1, pi2)) return 0.0; hasbothpoints.SetSize (0); for (ElementIndex elnr : elementsonnode[pi1]) { bool has1 = 0, has2 = 0; const Element & elem = mesh[elnr]; if (elem.IsDeleted()) return 0.0; for (int l = 0; l < elem.GetNP(); l++) { if (elem[l] == pi1) has1 = 1; if (elem[l] == pi2) has2 = 1; } if (has1 && has2) { // only once if (hasbothpoints.Contains (elnr)) has1 = false; if (has1) { hasbothpoints.Append (elnr); } } } for (ElementIndex ei : hasbothpoints) { if (mesh[ei].GetType () != TET) return 0.0; if (mp.only3D_domain_nr && mp.only3D_domain_nr != mesh.VolumeElement(ei).GetIndex()) return 0.0; if ((mesh.ElementType(ei)) == FIXEDELEMENT) return 0.0; if(working_elements && ei < working_elements->Size() && !working_elements->Test(ei)) return 0.0; if (mesh[ei].IsDeleted()) return 0.0; } if(!NeedsOptimization(hasbothpoints)) return 0.0; int nsuround = hasbothpoints.Size(); int mattyp = mesh[hasbothpoints[0]].GetIndex(); if ( nsuround == 3 ) { Element & elem = mesh[hasbothpoints[0]]; for (int l = 0; l < 4; l++) if (elem[l] != pi1 && elem[l] != pi2) { pi4 = pi3; pi3 = elem[l]; } el31[0] = pi1; el31[1] = pi2; el31[2] = pi3; el31[3] = pi4; el31.SetIndex (mattyp); if (WrongOrientation (mesh.Points(), el31)) { Swap (pi3, pi4); el31[2] = pi3; el31[3] = pi4; } pi5.Invalidate(); for (int k = 0; k < 3; k++) // JS, 201212 { const Element & elemk = mesh[hasbothpoints[k]]; bool has1 = false; for (int l = 0; l < 4; l++) if (elemk[l] == pi4) has1 = true; if (has1) { for (int l = 0; l < 4; l++) if (elemk[l] != pi1 && elemk[l] != pi2 && elemk[l] != pi4) pi5 = elemk[l]; } } if (!pi5.IsValid()) throw NgException("Illegal state observed in SwapImprove"); el32[0] = pi1; el32[1] = pi2; el32[2] = pi4; el32[3] = pi5; el32.SetIndex (mattyp); el33[0] = pi1; el33[1] = pi2; el33[2] = pi5; el33[3] = pi3; el33.SetIndex (mattyp); bad1 = CalcBad (mesh.Points(), el31, 0) + CalcBad (mesh.Points(), el32, 0) + CalcBad (mesh.Points(), el33, 0); el31.Touch(); el32.Touch(); el33.Touch(); if (!mesh.LegalTet(el31) || !mesh.LegalTet(el32) || !mesh.LegalTet(el33)) bad1 += GetLegalPenalty(); el21[0] = pi3; el21[1] = pi4; el21[2] = pi5; el21[3] = pi2; el21.SetIndex (mattyp); el22[0] = pi5; el22[1] = pi4; el22[2] = pi3; el22[3] = pi1; el22.SetIndex (mattyp); bad2 = CalcBad (mesh.Points(), el21, 0) + CalcBad (mesh.Points(), el22, 0); el21.Touch(); el22.Touch(); if (!mesh.LegalTet(el21) || !mesh.LegalTet(el22)) bad2 += GetLegalPenalty(); if ((goal == OPT_CONFORM) && NotTooBad(bad1, bad2)) { INDEX_3 face(pi3, pi4, pi5); face.Sort(); if (faces.Used(face)) { // (*testout) << "3->2 swap, could improve conformity, bad1 = " << bad1 // << ", bad2 = " << bad2 << endl; bad2 = bad1 + IMPROVEMENT_CONFORMING_EDGE; } } if (bad2 < bad1) { // (*mycout) << "3->2 " << flush; // (*testout) << "3->2 conversion" << endl; d_badness = bad2-bad1; if(check_only) return d_badness; /* (*testout) << "3->2 swap, old els = " << endl << mesh[hasbothpoints[0]] << endl << mesh[hasbothpoints[1]] << endl << mesh[hasbothpoints[2]] << endl << "new els = " << endl << el21 << endl << el22 << endl; */ mesh[hasbothpoints[0]].Delete(); mesh[hasbothpoints[1]].Delete(); mesh[hasbothpoints[2]].Delete(); el21.Touch(); el22.Touch(); mesh.AddVolumeElement(el21); mesh.AddVolumeElement(el22); } } if (nsuround == 4) { const Element & elem1 = mesh[hasbothpoints[0]]; for (int l = 0; l < 4; l++) if (elem1[l] != pi1 && elem1[l] != pi2) { pi4 = pi3; pi3 = elem1[l]; } el1[0] = pi1; el1[1] = pi2; el1[2] = pi3; el1[3] = pi4; el1.SetIndex (mattyp); if (WrongOrientation (mesh.Points(), el1)) { Swap (pi3, pi4); el1[2] = pi3; el1[3] = pi4; } pi5.Invalidate(); for (int k = 0; k < 4; k++) { const Element & elem = mesh[hasbothpoints[k]]; bool has1 = elem.PNums().Contains(pi4); if (has1) { for (int l = 0; l < 4; l++) if (elem[l] != pi1 && elem[l] != pi2 && elem[l] != pi4) pi5 = elem[l]; } } pi6.Invalidate(); for (int k = 0; k < 4; k++) { const Element & elem = mesh[hasbothpoints[k]]; bool has1 = elem.PNums().Contains(pi3); if (has1) { for (int l = 0; l < 4; l++) if (elem[l] != pi1 && elem[l] != pi2 && elem[l] != pi3) pi6 = elem[l]; } } el1[0] = pi1; el1[1] = pi2; el1[2] = pi3; el1[3] = pi4; el1.SetIndex (mattyp); el2[0] = pi1; el2[1] = pi2; el2[2] = pi4; el2[3] = pi5; el2.SetIndex (mattyp); el3[0] = pi1; el3[1] = pi2; el3[2] = pi5; el3[3] = pi6; el3.SetIndex (mattyp); el4[0] = pi1; el4[1] = pi2; el4[2] = pi6; el4[3] = pi3; el4.SetIndex (mattyp); bad1 = CalcBad (mesh.Points(), el1, 0) + CalcBad (mesh.Points(), el2, 0) + CalcBad (mesh.Points(), el3, 0) + CalcBad (mesh.Points(), el4, 0); el1.Touch(); el2.Touch(); el3.Touch(); el4.Touch(); if (goal != OPT_CONFORM) { if (!mesh.LegalTet(el1) || !mesh.LegalTet(el2) || !mesh.LegalTet(el3) || !mesh.LegalTet(el4)) bad1 += GetLegalPenalty(); } el1[0] = pi3; el1[1] = pi5; el1[2] = pi2; el1[3] = pi4; el1.SetIndex (mattyp); el2[0] = pi3; el2[1] = pi5; el2[2] = pi4; el2[3] = pi1; el2.SetIndex (mattyp); el3[0] = pi3; el3[1] = pi5; el3[2] = pi1; el3[3] = pi6; el3.SetIndex (mattyp); el4[0] = pi3; el4[1] = pi5; el4[2] = pi6; el4[3] = pi2; el4.SetIndex (mattyp); bad2 = CalcBad (mesh.Points(), el1, 0) + CalcBad (mesh.Points(), el2, 0) + CalcBad (mesh.Points(), el3, 0) + CalcBad (mesh.Points(), el4, 0); el1.Touch(); el2.Touch(); el3.Touch(); el4.Touch(); if (goal != OPT_CONFORM) { if (!mesh.LegalTet(el1) || !mesh.LegalTet(el2) || !mesh.LegalTet(el3) || !mesh.LegalTet(el4)) bad2 += GetLegalPenalty(); } el1b[0] = pi4; el1b[1] = pi6; el1b[2] = pi3; el1b[3] = pi2; el1b.SetIndex (mattyp); el2b[0] = pi4; el2b[1] = pi6; el2b[2] = pi2; el2b[3] = pi5; el2b.SetIndex (mattyp); el3b[0] = pi4; el3b[1] = pi6; el3b[2] = pi5; el3b[3] = pi1; el3b.SetIndex (mattyp); el4b[0] = pi4; el4b[1] = pi6; el4b[2] = pi1; el4b[3] = pi3; el4b.SetIndex (mattyp); bad3 = CalcBad (mesh.Points(), el1b, 0) + CalcBad (mesh.Points(), el2b, 0) + CalcBad (mesh.Points(), el3b, 0) + CalcBad (mesh.Points(), el4b, 0); el1b.Touch(); el2b.Touch(); el3b.Touch(); el4b.Touch(); if (goal != OPT_CONFORM) { if (!mesh.LegalTet(el1b) || !mesh.LegalTet(el2b) || !mesh.LegalTet(el3b) || !mesh.LegalTet(el4b)) bad3 += GetLegalPenalty(); } bool swap2=false; bool swap3=false; if (goal == OPT_CONFORM) { swap2 = mesh.BoundaryEdge (pi3, pi5) && NotTooBad(bad1, bad2); swap3 = mesh.BoundaryEdge (pi4, pi6) && NotTooBad(bad1, bad3); if(swap2 || swap3) d_badness = IMPROVEMENT_CONFORMING_EDGE; } if (goal != OPT_CONFORM || (!swap2 && !swap3)) { swap2 = (bad2 < bad1) && (bad2 < bad3); swap3 = !swap2 && (bad3 < bad1); d_badness = swap2 ? bad2-bad1 : bad3-bad1; } if(check_only) return d_badness; if (swap2) { for (auto i : IntRange(4)) mesh[hasbothpoints[i]].Delete(); el1.Touch(); el2.Touch(); el3.Touch(); el4.Touch(); mesh.AddVolumeElement (el1); mesh.AddVolumeElement (el2); mesh.AddVolumeElement (el3); mesh.AddVolumeElement (el4); } else if (swap3) { for (auto i : IntRange(4)) mesh[hasbothpoints[i]].Delete(); el1b.Touch(); el2b.Touch(); el3b.Touch(); el4b.Touch(); mesh.AddVolumeElement (el1b); mesh.AddVolumeElement (el2b); mesh.AddVolumeElement (el3b); mesh.AddVolumeElement (el4b); } } // if (goal == OPT_QUALITY) if (nsuround >= 5) { Element hel(TET); NgArrayMem suroundpts(nsuround); NgArrayMem tetused(nsuround); Element & elem = mesh[hasbothpoints[0]]; for (int l = 0; l < 4; l++) if (elem[l] != pi1 && elem[l] != pi2) { pi4 = pi3; pi3 = elem[l]; } hel[0] = pi1; hel[1] = pi2; hel[2] = pi3; hel[3] = pi4; hel.SetIndex (mattyp); if (WrongOrientation (mesh.Points(), hel)) { Swap (pi3, pi4); hel[2] = pi3; hel[3] = pi4; } // suroundpts.SetSize (nsuround); suroundpts = PointIndex::INVALID; suroundpts[0] = pi3; suroundpts[1] = pi4; tetused = false; tetused[0] = true; for (int l = 2; l < nsuround; l++) { PointIndex oldpi = suroundpts[l-1]; PointIndex newpi; newpi.Invalidate(); for (int k = 0; k < nsuround && !newpi.IsValid(); k++) if (!tetused[k]) { const Element & nel = mesh[hasbothpoints[k]]; for (int k2 = 0; k2 < 4 && !newpi.IsValid(); k2++) if (nel[k2] == oldpi) { newpi = nel[0] + nel[1] + nel[2] + nel[3] - pi1 - pi2 - oldpi; tetused[k] = true; suroundpts[l] = newpi; } } } bad1 = 0; for (int k = 0; k < nsuround; k++) { hel[0] = pi1; hel[1] = pi2; hel[2] = suroundpts[k]; hel[3] = suroundpts[(k+1) % nsuround]; hel.SetIndex (mattyp); bad1 += CalcBad (mesh.Points(), hel, 0); } // (*testout) << "nsuround = " << nsuround << " bad1 = " << bad1 << endl; int bestl = -1; int confface = -1; int confedge = -1; double badopt = bad1; for (int l = 0; l < nsuround; l++) { bad2 = 0; for (int k = l+1; k <= nsuround + l - 2; k++) { hel[0] = suroundpts[l]; hel[1] = suroundpts[k % nsuround]; hel[2] = suroundpts[(k+1) % nsuround]; hel[3] = pi2; bad2 += CalcBad (mesh.Points(), hel, 0); hel.Touch(); if (!mesh.LegalTet(hel)) bad2 += GetLegalPenalty(); hel[2] = suroundpts[k % nsuround]; hel[1] = suroundpts[(k+1) % nsuround]; hel[3] = pi1; bad2 += CalcBad (mesh.Points(), hel, 0); hel.Touch(); if (!mesh.LegalTet(hel)) bad2 += GetLegalPenalty(); } // (*testout) << "bad2," << l << " = " << bad2 << endl; if ( bad2 < badopt ) { bestl = l; badopt = bad2; } if (goal == OPT_CONFORM) { bool nottoobad = NotTooBad(bad1, bad2); for (int k = l+1; k <= nsuround + l - 2; k++) { INDEX_3 hi3(suroundpts[l], suroundpts[k % nsuround], suroundpts[(k+1) % nsuround]); hi3.Sort(); if (faces.Used(hi3)) { // (*testout) << "could improve face conformity, bad1 = " << bad1 // << ", bad 2 = " << bad2 << ", nottoobad = " << nottoobad << endl; if (nottoobad) confface = l; } } for (int k = l+2; k <= nsuround+l-2; k++) { if (mesh.BoundaryEdge (suroundpts[l], suroundpts[k % nsuround])) { /* *testout << "could improve edge conformity, bad1 = " << bad1 << ", bad 2 = " << bad2 << ", nottoobad = " << nottoobad << endl; */ if (nottoobad) confedge = l; } } } } if (confedge != -1) bestl = confedge; if (confface != -1) bestl = confface; if(confface != -1 || confedge != -1) badopt = bad1 + IMPROVEMENT_CONFORMING_EDGE; if (bestl != -1) { // (*mycout) << nsuround << "->" << 2 * (nsuround-2) << " " << flush; d_badness = badopt-bad1; if(check_only) return d_badness; for (int k = bestl+1; k <= nsuround + bestl - 2; k++) { // int k1; hel[0] = suroundpts[bestl]; hel[1] = suroundpts[k % nsuround]; hel[2] = suroundpts[(k+1) % nsuround]; hel[3] = pi2; hel.Touch(); /* (*testout) << nsuround << "-swap, new el,top = " << hel << endl; */ mesh.AddVolumeElement (hel); hel[2] = suroundpts[k % nsuround]; hel[1] = suroundpts[(k+1) % nsuround]; hel[3] = pi1; /* (*testout) << nsuround << "-swap, new el,bot = " << hel << endl; */ mesh.AddVolumeElement (hel); } for (int k = 0; k < nsuround; k++) { Element & rel = mesh[hasbothpoints[k]]; /* (*testout) << nsuround << "-swap, old el = " << rel << endl; */ rel.Delete(); for (int k1 = 0; k1 < 4; k1++) rel[k1].Invalidate(); } } } return d_badness; } void MeshOptimize3d :: SwapImprove (const NgBitArray * working_elements) { static Timer t("MeshOptimize3d::SwapImprove"); RegionTimer reg(t); static Timer tloop("MeshOptimize3d::SwapImprove loop"); int cnt = 0; // int np = mesh.GetNP(); // int ne = mesh.GetNE(); mesh.BuildBoundaryEdges(false); BitArray free_points(mesh.GetNP()+PointIndex::BASE); free_points.Clear(); ParallelForRange(mesh.VolumeElements().Range(), [&] (auto myrange) { for (ElementIndex eli : myrange) { const auto & el = mesh[eli]; if(el.Flags().fixed || el.GetType() != TET) continue; if(mp.only3D_domain_nr && mp.only3D_domain_nr != el.GetIndex()) continue; for (auto pi : el.PNums()) if(!free_points[pi]) free_points.SetBitAtomic(pi); } }); auto elementsonnode = mesh.CreatePoint2ElementTable(free_points, mp.only3D_domain_nr ); NgArray hasbothpoints; PrintMessage (3, "SwapImprove "); (*testout) << "\n" << "Start SwapImprove" << endl; const char * savetask = multithread.task; multithread.task = "Optimize Volume: Swap Improve"; INDEX_3_HASHTABLE faces(mesh.GetNOpenElements()/3 + 2); if (goal == OPT_CONFORM) { for (int i = 1; i <= mesh.GetNOpenElements(); i++) { const Element2d & hel = mesh.OpenElement(i); INDEX_3 face(hel[0], hel[1], hel[2]); face.Sort(); faces.Set (face, i); } } // Calculate total badness if (goal == OPT_QUALITY && testout->good()) { double bad1 = mesh.CalcTotalBad (mp); (*testout) << "Total badness = " << bad1 << endl; } Array> edges; BuildEdgeList(mesh, elementsonnode, edges); Array> candidate_edges(edges.Size()); std::atomic improvement_counter(0); UpdateBadness(); tloop.Start(); auto num_elements_before = mesh.VolumeElements().Range().Next(); ParallelForRange(Range(edges), [&] (auto myrange) { for(auto i : myrange) { if (multithread.terminate) break; auto [pi0, pi1] = edges[i]; double d_badness = SwapImproveEdge (working_elements, elementsonnode, faces, pi0, pi1, true); if(d_badness<0.0) { int index = improvement_counter++; candidate_edges[index] = make_tuple(d_badness, i); } } }, TasksPerThread (4)); auto edges_with_improvement = candidate_edges.Part(0, improvement_counter.load()); QuickSort(edges_with_improvement); for(auto [d_badness, ei] : edges_with_improvement) { auto [pi0,pi1] = edges[ei]; if(SwapImproveEdge (working_elements, elementsonnode, faces, pi0, pi1, false) < 0.0) cnt++; } tloop.Stop(); PrintMessage (5, cnt, " swaps performed"); if(goal == OPT_CONFORM) { // Remove open elements that were closed by new tets auto & open_els = mesh.OpenElements(); for (auto & el : mesh.VolumeElements().Range( num_elements_before, mesh.VolumeElements().Range().Next() )) { for (auto i : Range(1,5)) { Element2d sel; el.GetFace(i, sel); INDEX_3 face(sel[0], sel[1], sel[2]); face.Sort(); if(faces.Used(face)) open_els[faces.Get(face)-1].Delete(); } } for(int i=open_els.Size()-1; i>=0; i--) if(open_els[i].IsDeleted()) open_els.Delete(i); mesh.DeleteBoundaryEdges(); } mesh.Compress (); multithread.task = savetask; } void MeshOptimize3d :: SwapImproveSurface ( const NgBitArray * working_elements, const NgArray< NgArray* > * idmaps) { NgArray< NgArray* > locidmaps; const NgArray< NgArray* > * used_idmaps; if(idmaps) used_idmaps = idmaps; else { used_idmaps = &locidmaps; for(int i=1; i<=mesh.GetIdentifications().GetMaxNr(); i++) { if(mesh.GetIdentifications().GetType(i) == Identifications::PERIODIC) { locidmaps.Append(new NgArray); mesh.GetIdentifications().GetMap(i,*locidmaps.Last(),true); } } } PointIndex pi1, pi2; // , pi3, pi4, pi5, pi6; PointIndex pi1other, pi2other; int cnt = 0; //double bad1, bad2, bad3, sbad; double bad1, sbad; double h; int np = mesh.GetNP(); int ne = mesh.GetNE(); int nse = mesh.GetNSE(); int mattype, othermattype; // contains at least all elements at node TABLE elementsonnode(np); TABLE surfaceelementsonnode(np); TABLE surfaceindicesonnode(np); NgArray hasbothpoints; NgArray hasbothpointsother; PrintMessage (3, "SwapImproveSurface "); (*testout) << "\n" << "Start SwapImproveSurface" << endl; const char * savetask = multithread.task; multithread.task = "Swap Improve Surface"; // find elements on node for (ElementIndex ei = 0; ei < ne; ei++) for (int j = 0; j < mesh[ei].GetNP(); j++) elementsonnode.Add (mesh[ei][j], ei); for (SurfaceElementIndex sei = 0; sei < nse; sei++) for(int j=0; j edgeused(2 * ne + 5); INDEX_2_CLOSED_HASHTABLE edgeused(12 * ne + 5); for (ElementIndex ei = 0; ei < ne; ei++) { if (multithread.terminate) break; multithread.percent = 100.0 * (ei+1) / ne; if (mesh.ElementType(ei) == FIXEDELEMENT) continue; if(working_elements && ei < working_elements->Size() && !working_elements->Test(ei)) continue; if (mesh[ei].IsDeleted()) continue; if (goal == OPT_LEGAL && mesh.LegalTet (mesh[ei])) continue; const Element & elemi = mesh[ei]; //Element elemi = mesh[ei]; if (elemi.IsDeleted()) continue; mattype = elemi.GetIndex(); bool swapped = false; for (int j = 0; !swapped && j < 6; j++) { // loop over edges pi1 = elemi[tetedges[j][0]]; pi2 = elemi[tetedges[j][1]]; if (pi2 < pi1) Swap (pi1, pi2); bool found = false; for(int k=0; !found && kSize(); k++) { if(pi2 < (*used_idmaps)[k]->Size() + PointIndex::BASE) { pi1other = (*(*used_idmaps)[k])[pi1]; pi2other = (*(*used_idmaps)[k])[pi2]; found = (pi1other != 0 && pi2other != 0 && pi1other != pi1 && pi2other != pi2); if(found) idnum = k; } } if(found) periodic = true; else { periodic = false; pi1other = pi1; pi2other = pi2; } if (!mesh.BoundaryEdge (pi1, pi2) || mesh.IsSegment(pi1, pi2)) continue; othermattype = -1; INDEX_2 i2 (pi1, pi2); i2.Sort(); if (edgeused.Used(i2)) continue; edgeused.Set (i2, 1); if(periodic) { i2.I1() = pi1other; i2.I2() = pi2other; i2.Sort(); edgeused.Set(i2,1); } hasbothpoints.SetSize (0); hasbothpointsother.SetSize (0); for (int k = 0; k < elementsonnode[pi1].Size(); k++) { bool has1 = false, has2 = false; ElementIndex elnr = elementsonnode[pi1][k]; const Element & elem = mesh[elnr]; if (elem.IsDeleted()) continue; for (int l = 0; l < elem.GetNP(); l++) { if (elem[l] == pi1) has1 = true; if (elem[l] == pi2) has2 = true; } if (has1 && has2) { if(othermattype == -1 && elem.GetIndex() != mattype) othermattype = elem.GetIndex(); if(elem.GetIndex() == mattype) { // only once for (int l = 0; l < hasbothpoints.Size(); l++) if (hasbothpoints[l] == elnr) has1 = 0; if (has1) hasbothpoints.Append (elnr); } else if(elem.GetIndex() == othermattype) { // only once for (int l = 0; l < hasbothpointsother.Size(); l++) if (hasbothpointsother[l] == elnr) has1 = 0; if (has1) hasbothpointsother.Append (elnr); } else { cout << "problem with domain indices" << endl; (*testout) << "problem: mattype = " << mattype << ", othermattype = " << othermattype << " elem " << elem << " mt " << elem.GetIndex() << endl << " pi1 " << pi1 << " pi2 " << pi2 << endl; (*testout) << "hasbothpoints:" << endl; for(int ii=0; ii < hasbothpoints.Size(); ii++) (*testout) << mesh[hasbothpoints[ii]] << endl; (*testout) << "hasbothpointsother:" << endl; for(int ii=0; ii < hasbothpointsother.Size(); ii++) (*testout) << mesh[hasbothpointsother[ii]] << endl; } } } if(hasbothpointsother.Size() > 0 && periodic) throw NgException("SwapImproveSurface: Assumption about interface/periodicity wrong!"); if(periodic) { for (int k = 0; k < elementsonnode[pi1other].Size(); k++) { bool has1 = false, has2 = false; ElementIndex elnr = elementsonnode[pi1other][k]; const Element & elem = mesh[elnr]; if (elem.IsDeleted()) continue; for (int l = 0; l < elem.GetNP(); l++) { if (elem[l] == pi1other) has1 = true; if (elem[l] == pi2other) has2 = true; } if (has1 && has2) { if(othermattype == -1) othermattype = elem.GetIndex(); // only once for (int l = 0; l < hasbothpointsother.Size(); l++) if (hasbothpointsother[l] == elnr) has1 = 0; if (has1) hasbothpointsother.Append (elnr); } } } //for(k=0; k v1 = mesh[sp1]-mesh[pi1], v2 = mesh[sp2]-mesh[pi1], v3 = mesh[sp1]-mesh[pi2], v4 = mesh[sp2]-mesh[pi2]; double vol = 0.5*(Cross(v1,v2).Length() + Cross(v3,v4).Length()); h = sqrt(vol); h = 0; sbad = CalcTriangleBadness (mesh[pi1],mesh[pi2],mesh[sp1],0,0) + CalcTriangleBadness (mesh[pi2],mesh[pi1],mesh[sp2],0,0); bool puretet = true; for (int k = 0; puretet && k < hasbothpoints.Size(); k++) if (mesh[hasbothpoints[k]].GetType () != TET) puretet = false; for (int k = 0; puretet && k < hasbothpointsother.Size(); k++) if (mesh[hasbothpointsother[k]].GetType () != TET) puretet = false; if (!puretet) continue; int nsuround = hasbothpoints.Size(); int nsuroundother = hasbothpointsother.Size(); NgArray < int > outerpoints(nsuround+1); outerpoints[0] = sp1; for(int i=0; i 0) (*testout) << mesh[hasbothpoints[ii]][jj] << " between " << mesh.mlbetweennodes[mesh[hasbothpoints[ii]][jj]][0] << " and " << mesh.mlbetweennodes[mesh[hasbothpoints[ii]][jj]][1] << endl; } (*testout) << "outerpoints: " << outerpoints << endl; (*testout) << "sel1 " << mesh[sel1] << endl << "sel2 " << mesh[sel2] << endl; for(int ii=0; ii<3; ii++) { if(mesh.mlbetweennodes[mesh[sel1][ii]][0] > 0) (*testout) << mesh[sel1][ii] << " between " << mesh.mlbetweennodes[mesh[sel1][ii]][0] << " and " << mesh.mlbetweennodes[mesh[sel1][ii]][1] << endl; if(mesh.mlbetweennodes[mesh[sel2][ii]][0] > 0) (*testout) << mesh[sel2][ii] << " between " << mesh.mlbetweennodes[mesh[sel2][ii]][0] << " and " << mesh.mlbetweennodes[mesh[sel2][ii]][1] << endl; } } NgArray < int > outerpointsother; if(nsuroundother > 0) { outerpointsother.SetSize(nsuroundother+1); outerpointsother[0] = sp2other; } for(int i=0; i 0 && outerpointsother[nsuroundother] != sp1other) { cerr << "OJE OJE OJE (other)" << endl; (*testout) << "OJE OJE OJE (other)" << endl; (*testout) << "pi1 " << pi1 << " pi2 " << pi2 << " sp1 " << sp1 << " sp2 " << sp2 << endl; (*testout) << "hasbothpoints: " << endl; for(int ii=0; ii < hasbothpoints.Size(); ii++) { (*testout) << mesh[hasbothpoints[ii]] << endl; for(int jj=0; jj 0) (*testout) << mesh[hasbothpoints[ii]][jj] << " between " << mesh.mlbetweennodes[mesh[hasbothpoints[ii]][jj]][0] << " and " << mesh.mlbetweennodes[mesh[hasbothpoints[ii]][jj]][1] << endl; } (*testout) << "outerpoints: " << outerpoints << endl; (*testout) << "sel1 " << mesh[sel1] << endl << "sel2 " << mesh[sel2] << endl; for(int ii=0; ii<3; ii++) { if(mesh.mlbetweennodes[mesh[sel1][ii]][0] > 0) (*testout) << mesh[sel1][ii] << " between " << mesh.mlbetweennodes[mesh[sel1][ii]][0] << " and " << mesh.mlbetweennodes[mesh[sel1][ii]][1] << endl; if(mesh.mlbetweennodes[mesh[sel2][ii]][0] > 0) (*testout) << mesh[sel2][ii] << " between " << mesh.mlbetweennodes[mesh[sel2][ii]][0] << " and " << mesh.mlbetweennodes[mesh[sel2][ii]][1] << endl; } (*testout) << "pi1other " << pi1other << " pi2other " << pi2other << " sp1other " << sp1other << " sp2other " << sp2other << endl; (*testout) << "hasbothpointsother: " << endl; for(int ii=0; ii < hasbothpointsother.Size(); ii++) { (*testout) << mesh[hasbothpointsother[ii]] << endl; for(int jj=0; jj 0) (*testout) << mesh[hasbothpointsother[ii]][jj] << " between " << mesh.mlbetweennodes[mesh[hasbothpointsother[ii]][jj]][0] << " and " << mesh.mlbetweennodes[mesh[hasbothpointsother[ii]][jj]][1] << endl; } (*testout) << "outerpoints: " << outerpointsother << endl; (*testout) << "sel1other " << mesh[sel1other] << endl << "sel2other " << mesh[sel2other] << endl; for(int ii=0; ii<3; ii++) { if(mesh.mlbetweennodes[mesh[sel1other][ii]][0] > 0) (*testout) << mesh[sel1other][ii] << " between " << mesh.mlbetweennodes[mesh[sel1other][ii]][0] << " and " << mesh.mlbetweennodes[mesh[sel1other][ii]][1] << endl; if(mesh.mlbetweennodes[mesh[sel2other][ii]][0] > 0) (*testout) << mesh[sel2other][ii] << " between " << mesh.mlbetweennodes[mesh[sel2other][ii]][0] << " and " << mesh.mlbetweennodes[mesh[sel2other][ii]][1] << endl; } } bad1=0; for(int i=0; i * > newelts(startpoints); NgArray < NgArray < Element* > * > neweltsother(startpointsother); double minbad = 1e50, minbadother = 1e50, currbad; int minpos = -1, minposother = -1; //(*testout) << "pi1 " << pi1 << " pi2 " << pi2 << " outerpoints " << outerpoints << endl; for(int i=0; i(2*(nsuround-1)); for(int jj=0; jjSize(); jj++) wrongorientation = wrongorientation && WrongOrientation(mesh.Points(), *(*newelts[i])[jj]); currbad = 0; for(int jj=0; jjSize(); jj++) { if(wrongorientation) Swap((*(*newelts[i])[jj])[2],(*(*newelts[i])[jj])[3]); // not two new faces on same surface NgArray face_index; for(int k = 0; kSize()); if(currbad < minbad) { minbad = currbad; minpos = i; } } if(startpointsother == 0) minbadother = 0; for(int i=0; i(2*(nsuroundother)); for(int jj=0; jjSize(); jj++) wrongorientation = wrongorientation && WrongOrientation(mesh.Points(), *(*neweltsother[i])[jj]); currbad = 0; for(int jj=0; jjSize(); jj++) { if(wrongorientation) Swap((*(*neweltsother[i])[jj])[2],(*(*neweltsother[i])[jj])[3]); currbad += CalcBad(mesh.Points(),*(*neweltsother[i])[jj],h); } //currbad /= double(neweltsother[i]->Size()); if(currbad < minbadother) { minbadother = currbad; minposother = i; } } //(*testout) << "minbad " << minbad << " bad1 " << bad1 << endl; double sbadnew = CalcTriangleBadness (mesh[pi1],mesh[sp2],mesh[sp1],0,0) + CalcTriangleBadness (mesh[pi2],mesh[sp1],mesh[sp2],0,0); int denom = newelts[minpos]->Size(); if(minposother >= 0) denom += neweltsother[minposother]->Size(); if((minbad+minbadother)/double(denom) < bad1 && sbadnew < sbad) { cnt++; swapped = true; int start1 = -1; for(int l=0; l<3; l++) if(mesh[sel1][l] == pi1) start1 = l; if(mesh[sel1][(start1+1)%3] == pi2) { mesh[sel1][0] = pi1; mesh[sel1][1] = sp2; mesh[sel1][2] = sp1; mesh[sel2][0] = pi2; mesh[sel2][1] = sp1; mesh[sel2][2] = sp2; } else { mesh[sel1][0] = pi2; mesh[sel1][1] = sp2; mesh[sel1][2] = sp1; mesh[sel2][0] = pi1; mesh[sel2][1] = sp1; mesh[sel2][2] = sp2; } //(*testout) << "changed surface element " << sel1 << " to " << mesh[sel1] << ", " << sel2 << " to " << mesh[sel2] << endl; for(int l=0; l<3; l++) { surfaceelementsonnode.Add(mesh[sel1][l],sel1); surfaceelementsonnode.Add(mesh[sel2][l],sel2); } if(periodic) { start1 = -1; for(int l=0; l<3; l++) if(mesh[sel1other][l] == pi1other) start1 = l; //(*testout) << "changed surface elements " << mesh[sel1other] << " and " << mesh[sel2other] << endl; if(mesh[sel1other][(start1+1)%3] == pi2other) { mesh[sel1other][0] = pi1other; mesh[sel1other][1] = sp2other; mesh[sel1other][2] = sp1other; mesh[sel2other][0] = pi2other; mesh[sel2other][1] = sp1other; mesh[sel2other][2] = sp2other; //(*testout) << " with rule 1" << endl; } else { mesh[sel1other][0] = pi2other; mesh[sel1other][1] = sp2other; mesh[sel1other][2] = sp1other; mesh[sel2other][0] = pi1other; mesh[sel2other][1] = sp1other; mesh[sel2other][2] = sp2other; //(*testout) << " with rule 2" << endl; } //(*testout) << " to " << mesh[sel1other] << " and " << mesh[sel2other] << endl; //(*testout) << " and surface element " << sel1other << " to " << mesh[sel1other] << ", " << sel2other << " to " << mesh[sel2other] << endl; for(int l=0; l<3; l++) { surfaceelementsonnode.Add(mesh[sel1other][l],sel1other); surfaceelementsonnode.Add(mesh[sel2other][l],sel2other); } } for(int i=0; i 0) { for(int i=0; iSize(); jj++) delete (*newelts[i])[jj]; delete newelts[i]; } for(int i=0; iSize(); jj++) delete (*neweltsother[i])[jj]; delete neweltsother[i]; } } } PrintMessage (5, cnt, " swaps performed"); for(int i=0; i 3 conversion */ double MeshOptimize3d :: SwapImprove2 ( ElementIndex eli1, int face, Table & elementsonnode, TABLE & belementsonnode, bool check_only ) { PointIndex pi1, pi2, pi3, pi4, pi5; Element el21(TET), el22(TET), el31(TET), el32(TET), el33(TET); int j = face; double bad1, bad2; double d_badness = 0.0; Element & elem = mesh[eli1]; if (elem.IsDeleted()) return 0.0; int mattyp = elem.GetIndex(); switch (j) { case 0: pi1 = elem.PNum(1); pi2 = elem.PNum(2); pi3 = elem.PNum(3); pi4 = elem.PNum(4); break; case 1: pi1 = elem.PNum(1); pi2 = elem.PNum(4); pi3 = elem.PNum(2); pi4 = elem.PNum(3); break; case 2: pi1 = elem.PNum(1); pi2 = elem.PNum(3); pi3 = elem.PNum(4); pi4 = elem.PNum(2); break; case 3: pi1 = elem.PNum(2); pi2 = elem.PNum(4); pi3 = elem.PNum(3); pi4 = elem.PNum(1); break; } bool bface = 0; for (int k = 0; k < belementsonnode[pi1].Size(); k++) { const Element2d & bel = mesh[belementsonnode[pi1][k]]; bool bface1 = 1; for (int l = 0; l < 3; l++) if (bel[l] != pi1 && bel[l] != pi2 && bel[l] != pi3) { bface1 = 0; break; } if (bface1) { bface = 1; break; } } if (bface) return 0.0; FlatArray row = elementsonnode[pi1]; for(auto ei : row) if (mesh[ei].IsDeleted()) return 0.0; for(auto ei : elementsonnode[pi2]) if (mesh[ei].IsDeleted()) return 0.0; for(auto ei : elementsonnode[pi3]) if (mesh[ei].IsDeleted()) return 0.0; for(auto ei : elementsonnode[pi4]) if (mesh[ei].IsDeleted()) return 0.0; for (int k = 0; k < row.Size(); k++) { ElementIndex eli2 = row[k]; if ( eli1 != eli2 ) { Element & elem2 = mesh[eli2]; if (elem2.GetType() != TET) continue; ArrayMem elis = {eli1, eli2}; if(!NeedsOptimization(elis)) continue; int comnodes=0; for (int l = 1; l <= 4; l++) if (elem2.PNum(l) == pi1 || elem2.PNum(l) == pi2 || elem2.PNum(l) == pi3) { comnodes++; } else { pi5 = elem2.PNum(l); } if (comnodes == 3) { bad1 = elem.GetBadness() + elem2.GetBadness(); if (!mesh.LegalTet(elem) || !mesh.LegalTet(elem2)) bad1 += GetLegalPenalty(); if(mesh.BoundaryEdge (pi4, pi5)) bad1 += GetLegalPenalty(); el31.PNum(1) = pi1; el31.PNum(2) = pi2; el31.PNum(3) = pi5; el31.PNum(4) = pi4; el31.SetIndex (mattyp); el32.PNum(1) = pi2; el32.PNum(2) = pi3; el32.PNum(3) = pi5; el32.PNum(4) = pi4; el32.SetIndex (mattyp); el33.PNum(1) = pi3; el33.PNum(2) = pi1; el33.PNum(3) = pi5; el33.PNum(4) = pi4; el33.SetIndex (mattyp); bad2 = CalcBad (mesh.Points(), el31, 0) + CalcBad (mesh.Points(), el32, 0) + CalcBad (mesh.Points(), el33, 0); el31.Touch(); el32.Touch(); el33.Touch(); if (!mesh.LegalTet(el31) || !mesh.LegalTet(el32) || !mesh.LegalTet(el33)) bad2 += GetLegalPenalty(); d_badness = bad2 - bad1; if ( ((bad2 < 1e6) || (bad2 < 10 * bad1)) && mesh.BoundaryEdge (pi4, pi5)) d_badness = -1e4; if(check_only) return d_badness; if (d_badness<0.0) { el31.Touch(); el32.Touch(); el33.Touch(); mesh[eli1].Delete(); mesh[eli2].Delete(); mesh.AddVolumeElement (el31); mesh.AddVolumeElement (el32); mesh.AddVolumeElement (el33); } return d_badness; } } } return d_badness; } /* 2 -> 3 conversion */ void MeshOptimize3d :: SwapImprove2 () { static Timer t("MeshOptimize3d::SwapImprove2"); RegionTimer reg(t); if (goal == OPT_CONFORM) return; mesh.BuildBoundaryEdges(false); int cnt = 0; // double bad1, bad2; int np = mesh.GetNP(); int ne = mesh.GetNE(); int nse = mesh.GetNSE(); // contains at least all elements at node TABLE belementsonnode(np); PrintMessage (3, "SwapImprove2 "); (*testout) << "\n" << "Start SwapImprove2" << "\n"; if(testout->good()) { double bad1 = mesh.CalcTotalBad (mp); (*testout) << "Total badness = " << bad1 << endl; } // find elements on node auto elementsonnode = mesh.CreatePoint2ElementTable(nullopt, mp.only3D_domain_nr); // todo: respect mp.only3D_domain_nr for (SurfaceElementIndex sei = 0; sei < nse; sei++) for (int j = 0; j < 3; j++) belementsonnode.Add (mesh[sei][j], sei); int num_threads = ngcore::TaskManager::GetNumThreads(); Array> faces_with_improvement; Array>> faces_with_improvement_threadlocal(num_threads); UpdateBadness(); ParallelForRange( Range(ne), [&]( auto myrange ) { int tid = ngcore::TaskManager::GetThreadId(); auto & my_faces_with_improvement = faces_with_improvement_threadlocal[tid]; for (ElementIndex eli1 : myrange) { if (multithread.terminate) break; if (mesh.ElementType (eli1) == FIXEDELEMENT) continue; if (mesh[eli1].GetType() != TET) continue; if (goal == OPT_LEGAL && mesh.LegalTet (mesh[eli1])) continue; if(mesh.GetDimension()==3 && mp.only3D_domain_nr && mp.only3D_domain_nr != mesh.VolumeElement(eli1).GetIndex()) continue; for (int j = 0; j < 4; j++) { double d_badness = SwapImprove2( eli1, j, elementsonnode, belementsonnode, true); if(d_badness<0.0) my_faces_with_improvement.Append( std::make_tuple(d_badness, eli1, j) ); } } }); for (auto & a : faces_with_improvement_threadlocal) faces_with_improvement.Append(a); QuickSort(faces_with_improvement); for (auto [dummy, eli,j] : faces_with_improvement) { if(mesh[eli].IsDeleted()) continue; if(SwapImprove2( eli, j, elementsonnode, belementsonnode, false) < 0.0) cnt++; } PrintMessage (5, cnt, " swaps performed"); mesh.Compress(); if(testout->good()) { double bad1 = mesh.CalcTotalBad (mp); (*testout) << "Total badness = " << bad1 << endl; (*testout) << "swapimprove2 done" << "\n"; } } double MeshOptimize3d :: SplitImprove2Element ( ElementIndex ei, const Table & elements_of_point, bool check_only) { auto & el = mesh[ei]; if(el.GetType() != TET) return false; // Optimize only bad elements if(el.GetBadness() < 100) return false; // search for very flat tets, with two disjoint edges nearly crossing, like a rectangle with diagonals int minedge = -1; double mindist = 1e99; double minlam0=0, minlam1=0; for (int i : Range(3)) { auto pi0 = el[tetedges[i][0]]; auto pi1 = el[tetedges[i][1]]; auto pi2 = el[tetedges[5-i][0]]; auto pi3 = el[tetedges[5-i][1]]; double lam0, lam1; double dist = MinDistLL2(mesh[pi0], mesh[pi1], mesh[pi2], mesh[pi3], lam0, lam1 ); if(dist has_both_points0; ArrayMem has_both_points1; Point3d p[4] = { mesh[el[0]], mesh[el[1]], mesh[el[2]], mesh[el[3]] }; auto center = Center(p[0]+minlam0*(p[1]-p[0]), p[2]+minlam1*(p[3]-p[2])); MeshPoint pnew; pnew(0) = center.X(); pnew(1) = center.Y(); pnew(2) = center.Z(); // find all tets with edge (pi0,pi1) or (pi2,pi3) for (auto ei0 : elements_of_point[pi0] ) { Element & elem = mesh[ei0]; if (elem.IsDeleted()) return false; if (ei0 == ei) continue; if (elem.GetType() != TET) return false; if (elem[0] == pi1 || elem[1] == pi1 || elem[2] == pi1 || elem[3] == pi1 || (elem.GetNP()==5 && elem[4]==pi1) ) if(!has_both_points0.Contains(ei0)) has_both_points0.Append (ei0); } for (auto ei1 : elements_of_point[pi2] ) { Element & elem = mesh[ei1]; if (elem.IsDeleted()) return false; if (ei1 == ei) continue; if (elem.GetType() != TET) return false; if (elem[0] == pi3 || elem[1] == pi3 || elem[2] == pi3 || elem[3] == pi3 || (elem.GetNP()==5 && elem[4]==pi3)) if(!has_both_points1.Contains(ei1)) has_both_points1.Append (ei1); } double badness_before = mesh[ei].GetBadness(); double badness_after = 0.0; for (auto ei0 : has_both_points0) { if(mesh[ei0].GetType()!=TET) return false; badness_before += mesh[ei0].GetBadness(); badness_after += SplitElementBadness (mesh.Points(), mp, mesh[ei0], pi0, pi1, pnew); } for (auto ei1 : has_both_points1) { if(mesh[ei1].GetType()!=TET) return false; badness_before += mesh[ei1].GetBadness(); badness_after += SplitElementBadness (mesh.Points(), mp, mesh[ei1], pi2, pi3, pnew); } if(check_only) return badness_after-badness_before; if(badness_after new point where diagonals cross, remove the flat tet void MeshOptimize3d :: SplitImprove2 () { static Timer t("MeshOptimize3d::SplitImprove2"); RegionTimer reg(t); static Timer tsearch("Search"); static Timer topt("Optimize"); int ne = mesh.GetNE(); auto elements_of_point = mesh.CreatePoint2ElementTable(nullopt, mp.only3D_domain_nr); int ntasks = 4*ngcore::TaskManager::GetNumThreads(); const char * savetask = multithread.task; multithread.task = "Optimize Volume: Split Improve 2"; UpdateBadness(); mesh.BuildBoundaryEdges(false); Array> split_candidates(ne); std::atomic improvement_counter(0); tsearch.Start(); ParallelForRange(Range(ne), [&] (auto myrange) { for(ElementIndex ei : myrange) { if(mp.only3D_domain_nr && mp.only3D_domain_nr != mesh[ei].GetIndex()) continue; double d_badness = SplitImprove2Element(ei, elements_of_point, true); if(d_badness<0.0) { int index = improvement_counter++; split_candidates[index] = make_tuple(d_badness, ei); } } }, ntasks); tsearch.Stop(); auto elements_with_improvement = split_candidates.Part(0, improvement_counter.load()); QuickSort(elements_with_improvement); size_t cnt = 0; topt.Start(); for(auto [d_badness, ei] : elements_with_improvement) { if( SplitImprove2Element(ei, elements_of_point, false) < 0.0) cnt++; } topt.Stop(); PrintMessage (5, cnt, " elements split"); (*testout) << "SplitImprove2 done" << "\n"; if(cnt>0) mesh.Compress(); multithread.task = savetask; } /* void Mesh :: SwapImprove2 (OPTIMIZEGOAL goal) { int i, j; int eli1, eli2; int mattyp; Element el31(4), el32(4), el33(4); double bad1, bad2; INDEX_3_HASHTABLE elsonface (GetNE()); (*mycout) << "SwapImprove2 " << endl; (*testout) << "\n" << "Start SwapImprove2" << "\n"; // Calculate total badness if (goal == OPT_QUALITY) { double bad1 = CalcTotalBad (points, volelements); (*testout) << "Total badness = " << bad1 << endl; } // find elements on node Element2d face; for (i = 1; i <= GetNE(); i++) if ( (i > eltyps.Size()) || (eltyps.Get(i) != FIXEDELEMENT) ) { const Element & el = VolumeElement(i); if (!el.PNum(1)) continue; for (j = 1; j <= 4; j++) { el.GetFace (j, face); INDEX_3 i3 (face.PNum(1), face.PNum(2), face.PNum(3)); i3.Sort(); int bnr, posnr; if (!elsonface.PositionCreate (i3, bnr, posnr)) { INDEX_2 i2; elsonface.GetData (bnr, posnr, i3, i2); i2.I2() = i; elsonface.SetData (bnr, posnr, i3, i2); } else { INDEX_2 i2 (i, 0); elsonface.SetData (bnr, posnr, i3, i2); } // if (elsonface.Used (i3)) // { // INDEX_2 i2 = elsonface.Get(i3); // i2.I2() = i; // elsonface.Set (i3, i2); // } // else // { // INDEX_2 i2 (i, 0); // elsonface.Set (i3, i2); // } } } NgBitArray original(GetNE()); original.Set(); for (i = 1; i <= GetNSE(); i++) { const Element2d & sface = SurfaceElement(i); INDEX_3 i3 (sface.PNum(1), sface.PNum(2), sface.PNum(3)); i3.Sort(); INDEX_2 i2(0,0); elsonface.Set (i3, i2); } for (i = 1; i <= elsonface.GetNBags(); i++) for (j = 1; j <= elsonface.GetBagSize(i); j++) { INDEX_3 i3; INDEX_2 i2; elsonface.GetData (i, j, i3, i2); int eli1 = i2.I1(); int eli2 = i2.I2(); if (eli1 && eli2 && original.Test(eli1) && original.Test(eli2) ) { Element & elem = volelements.Elem(eli1); Element & elem2 = volelements.Elem(eli2); int pi1 = i3.I1(); int pi2 = i3.I2(); int pi3 = i3.I3(); int pi4 = elem.PNum(1) + elem.PNum(2) + elem.PNum(3) + elem.PNum(4) - pi1 - pi2 - pi3; int pi5 = elem2.PNum(1) + elem2.PNum(2) + elem2.PNum(3) + elem2.PNum(4) - pi1 - pi2 - pi3; el31.PNum(1) = pi1; el31.PNum(2) = pi2; el31.PNum(3) = pi3; el31.PNum(4) = pi4; el31.SetIndex (mattyp); if (WrongOrientation (points, el31)) swap (pi1, pi2); bad1 = CalcBad (points, elem, 0) + CalcBad (points, elem2, 0); // if (!LegalTet(elem) || !LegalTet(elem2)) // bad1 += 1e4; el31.PNum(1) = pi1; el31.PNum(2) = pi2; el31.PNum(3) = pi5; el31.PNum(4) = pi4; el31.SetIndex (mattyp); el32.PNum(1) = pi2; el32.PNum(2) = pi3; el32.PNum(3) = pi5; el32.PNum(4) = pi4; el32.SetIndex (mattyp); el33.PNum(1) = pi3; el33.PNum(2) = pi1; el33.PNum(3) = pi5; el33.PNum(4) = pi4; el33.SetIndex (mattyp); bad2 = CalcBad (points, el31, 0) + CalcBad (points, el32, 0) + CalcBad (points, el33, 0); // if (!LegalTet(el31) || !LegalTet(el32) || // !LegalTet(el33)) // bad2 += 1e4; int swap = (bad2 < bad1); INDEX_2 hi2b(pi4, pi5); hi2b.Sort(); if ( ((bad2 < 1e6) || (bad2 < 10 * bad1)) && boundaryedges->Used (hi2b) ) swap = 1; if (swap) { (*mycout) << "2->3 " << flush; volelements.Elem(eli1) = el31; volelements.Elem(eli2) = el32; volelements.Append (el33); original.Clear (eli1); original.Clear (eli2); } } } (*mycout) << endl; if (goal == OPT_QUALITY) { bad1 = CalcTotalBad (points, volelements); (*testout) << "Total badness = " << bad1 << endl; } // FindOpenElements (); (*testout) << "swapimprove2 done" << "\n"; } */ }