/*
--------------------------------- libqhull_r.c Quickhull algorithm for convex hulls qhull() and top-level routines see qh-qhull_r.htm, libqhull.h, unix_r.c see qhull_ra.h for internal functions Copyright (c) 1993-2015 The Geometry Center. $Id: //main/2015/qhull/src/libqhull_r/libqhull_r.c#2 $$Change: 2047 $ $DateTime: 2016/01/04 22:03:18 $$Author: bbarber $ */ #include "qhull_ra.h" /*============= functions in alphabetic order after qhull() =======*/ /*--------------------------------- qh_qhull(qh) compute DIM3 convex hull of qh.num_points starting at qh.first_point qh->contains all global options and variables returns: returns polyhedron qh.facet_list, qh.num_facets, qh.vertex_list, qh.num_vertices, returns global variables qh.hulltime, qh.max_outside, qh.interior_point, qh.max_vertex, qh.min_vertex returns precision constants qh.ANGLEround, centrum_radius, cos_max, DISTround, MAXabs_coord, ONEmerge notes: unless needed for output qh.max_vertex and qh.min_vertex are max/min due to merges see: to add individual points to either qh.num_points use qh_addpoint() if qh.GETarea qh_produceoutput() returns qh.totarea and qh.totvol via qh_getarea() design: record starting time initialize hull and partition points build convex hull unless early termination update facet->maxoutside for vertices, coplanar, and near-inside points error if temporary sets exist record end time */ void qh_qhull(qhT *qh) { int numoutside; qh->hulltime= qh_CPUclock; if (qh->RERUN || qh->JOGGLEmax < REALmax/2) qh_build_withrestart(qh); else { qh_initbuild(qh); qh_buildhull(qh); } if (!qh->STOPpoint && !qh->STOPcone) { if (qh->ZEROall_ok && !qh->TESTvneighbors && qh->MERGEexact) qh_checkzero(qh, qh_ALL); if (qh->ZEROall_ok && !qh->TESTvneighbors && !qh->WAScoplanar) { trace2((qh, qh->ferr, 2055, "qh_qhull: all facets are clearly convex and no coplanar points. Post-merging and check of maxout not needed.\n")); qh->DOcheckmax= False; }else { if (qh->MERGEexact || (qh->hull_dim > qh_DIMreduceBuild && qh->PREmerge)) qh_postmerge(qh, "First post-merge", qh->premerge_centrum, qh->premerge_cos, (qh->POSTmerge ? False : qh->TESTvneighbors)); else if (!qh->POSTmerge && qh->TESTvneighbors) qh_postmerge(qh, "For testing vertex neighbors", qh->premerge_centrum, qh->premerge_cos, True); if (qh->POSTmerge) qh_postmerge(qh, "For post-merging", qh->postmerge_centrum, qh->postmerge_cos, qh->TESTvneighbors); if (qh->visible_list == qh->facet_list) { /* i.e., merging done */ qh->findbestnew= True; qh_partitionvisible(qh /*qh.visible_list*/, !qh_ALL, &numoutside); qh->findbestnew= False; qh_deletevisible(qh /*qh.visible_list*/); qh_resetlists(qh, False, qh_RESETvisible /*qh.visible_list newvertex_list newfacet_list */); } } if (qh->DOcheckmax){ if (qh->REPORTfreq) { qh_buildtracing(qh, NULL, NULL); qh_fprintf(qh, qh->ferr, 8115, "\nTesting all coplanar points.\n"); } qh_check_maxout(qh); } if (qh->KEEPnearinside && !qh->maxoutdone) qh_nearcoplanar(qh); } if (qh_setsize(qh, qh->qhmem.tempstack) != 0) { qh_fprintf(qh, qh->ferr, 6164, "qhull internal error (qh_qhull): temporary sets not empty(%d)\n", qh_setsize(qh, qh->qhmem.tempstack)); qh_errexit(qh, qh_ERRqhull, NULL, NULL); } qh->hulltime= qh_CPUclock - qh->hulltime; qh->QHULLfinished= True; trace1((qh, qh->ferr, 1036, "Qhull: algorithm completed\n")); } /* qhull */ /*--------------------------------- qh_addpoint(qh, furthest, facet, checkdist ) add point (usually furthest point) above facet to hull if checkdist, check that point is above facet. if point is not outside of the hull, uses qh_partitioncoplanar() assumes that facet is defined by qh_findbestfacet() else if facet specified, assumes that point is above facet (major damage if below) for Delaunay triangulations, Use qh_setdelaunay() to lift point to paraboloid and scale by 'Qbb' if needed Do not use options 'Qbk', 'QBk', or 'QbB' since they scale the coordinates. returns: returns False if user requested an early termination qh.visible_list, newfacet_list, delvertex_list, NEWfacets may be defined updates qh.facet_list, qh.num_facets, qh.vertex_list, qh.num_vertices clear qh.maxoutdone (will need to call qh_check_maxout() for facet->maxoutside) if unknown point, adds a pointer to qh.other_points do not deallocate the point's coordinates notes: assumes point is near its best facet and not at a local minimum of a lens distributions. Use qh_findbestfacet to avoid this case. uses qh.visible_list, qh.newfacet_list, qh.delvertex_list, qh.NEWfacets see also: qh_triangulate() -- triangulate non-simplicial facets design: add point to other_points if needed if checkdist if point not above facet partition coplanar point exit exit if pre STOPpoint requested find horizon and visible facets for point make new facets for point to horizon make hyperplanes for point compute balance statistics match neighboring new facets update vertex neighbors and delete interior vertices exit if STOPcone requested merge non-convex new facets if merge found, many merges, or 'Qf' use qh_findbestnew() instead of qh_findbest() partition outside points from visible facets delete visible facets check polyhedron if requested exit if post STOPpoint requested reset working lists of facets and vertices */ boolT qh_addpoint(qhT *qh, pointT *furthest, facetT *facet, boolT checkdist) { int goodvisible, goodhorizon; vertexT *vertex; facetT *newfacet; realT dist, newbalance, pbalance; boolT isoutside= False; int numpart, numpoints, numnew, firstnew; qh->maxoutdone= False; if (qh_pointid(qh, furthest) == qh_IDunknown) qh_setappend(qh, &qh->other_points, furthest); if (!facet) { qh_fprintf(qh, qh->ferr, 6213, "qhull internal error (qh_addpoint): NULL facet. Need to call qh_findbestfacet first\n"); qh_errexit(qh, qh_ERRqhull, NULL, NULL); } if (checkdist) { facet= qh_findbest(qh, furthest, facet, !qh_ALL, !qh_ISnewfacets, !qh_NOupper, &dist, &isoutside, &numpart); zzadd_(Zpartition, numpart); if (!isoutside) { zinc_(Znotmax); /* last point of outsideset is no longer furthest. */ facet->notfurthest= True; qh_partitioncoplanar(qh, furthest, facet, &dist); return True; } } qh_buildtracing(qh, furthest, facet); if (qh->STOPpoint < 0 && qh->furthest_id == -qh->STOPpoint-1) { facet->notfurthest= True; return False; } qh_findhorizon(qh, furthest, facet, &goodvisible, &goodhorizon); if (qh->ONLYgood && !(goodvisible+goodhorizon) && !qh->GOODclosest) { zinc_(Znotgood); facet->notfurthest= True; /* last point of outsideset is no longer furthest. This is ok since all points of the outside are likely to be bad */ qh_resetlists(qh, False, qh_RESETvisible /*qh.visible_list newvertex_list newfacet_list */); return True; } zzinc_(Zprocessed); firstnew= qh->facet_id; vertex= qh_makenewfacets(qh, furthest /*visible_list, attaches if !ONLYgood */); qh_makenewplanes(qh /* newfacet_list */); numnew= qh->facet_id - firstnew; newbalance= numnew - (realT) (qh->num_facets-qh->num_visible) * qh->hull_dim/qh->num_vertices; wadd_(Wnewbalance, newbalance); wadd_(Wnewbalance2, newbalance * newbalance); if (qh->ONLYgood && !qh_findgood(qh, qh->newfacet_list, goodhorizon) && !qh->GOODclosest) { FORALLnew_facets qh_delfacet(qh, newfacet); qh_delvertex(qh, vertex); qh_resetlists(qh, True, qh_RESETvisible /*qh.visible_list newvertex_list newfacet_list */); zinc_(Znotgoodnew); facet->notfurthest= True; return True; } if (qh->ONLYgood) qh_attachnewfacets(qh /*visible_list*/); qh_matchnewfacets(qh); qh_updatevertices(qh); if (qh->STOPcone && qh->furthest_id == qh->STOPcone-1) { facet->notfurthest= True; return False; /* visible_list etc. still defined */ } qh->findbestnew= False; if (qh->PREmerge || qh->MERGEexact) { qh_premerge(qh, vertex, qh->premerge_centrum, qh->premerge_cos); if (qh_USEfindbestnew) qh->findbestnew= True; else { FORALLnew_facets { if (!newfacet->simplicial) { qh->findbestnew= True; /* use qh_findbestnew instead of qh_findbest*/ break; } } } }else if (qh->BESToutside) qh->findbestnew= True; qh_partitionvisible(qh /*qh.visible_list*/, !qh_ALL, &numpoints); qh->findbestnew= False; qh->findbest_notsharp= False; zinc_(Zpbalance); pbalance= numpoints - (realT) qh->hull_dim /* assumes all points extreme */ * (qh->num_points - qh->num_vertices)/qh->num_vertices; wadd_(Wpbalance, pbalance); wadd_(Wpbalance2, pbalance * pbalance); qh_deletevisible(qh /*qh.visible_list*/); zmax_(Zmaxvertex, qh->num_vertices); qh->NEWfacets= False; if (qh->IStracing >= 4) { if (qh->num_facets < 2000) qh_printlists(qh); qh_printfacetlist(qh, qh->newfacet_list, NULL, True); qh_checkpolygon(qh, qh->facet_list); }else if (qh->CHECKfrequently) { if (qh->num_facets < 50) qh_checkpolygon(qh, qh->facet_list); else qh_checkpolygon(qh, qh->newfacet_list); } if (qh->STOPpoint > 0 && qh->furthest_id == qh->STOPpoint-1) return False; qh_resetlists(qh, True, qh_RESETvisible /*qh.visible_list newvertex_list newfacet_list */); /* qh_triangulate(qh); to test qh.TRInormals */ trace2((qh, qh->ferr, 2056, "qh_addpoint: added p%d new facets %d new balance %2.2g point balance %2.2g\n", qh_pointid(qh, furthest), numnew, newbalance, pbalance)); return True; } /* addpoint */ /*--------------------------------- qh_build_withrestart(qh) allow restarts due to qh.JOGGLEmax while calling qh_buildhull() qh_errexit always undoes qh_build_withrestart() qh.FIRSTpoint/qh.NUMpoints is point array it may be moved by qh_joggleinput(qh) */ void qh_build_withrestart(qhT *qh) { int restart; qh->ALLOWrestart= True; while (True) { restart= setjmp(qh->restartexit); /* simple statement for CRAY J916 */ if (restart) { /* only from qh_precision() */ zzinc_(Zretry); wmax_(Wretrymax, qh->JOGGLEmax); /* QH7078 warns about using 'TCn' with 'QJn' */ qh->STOPcone= qh_IDunknown; /* if break from joggle, prevents normal output */ } if (!qh->RERUN && qh->JOGGLEmax < REALmax/2) { if (qh->build_cnt > qh_JOGGLEmaxretry) { qh_fprintf(qh, qh->ferr, 6229, "qhull precision error: %d attempts to construct a convex hull\n\ with joggled input. Increase joggle above 'QJ%2.2g'\n\ or modify qh_JOGGLE... parameters in user.h\n", qh->build_cnt, qh->JOGGLEmax); qh_errexit(qh, qh_ERRqhull, NULL, NULL); } if (qh->build_cnt && !restart) break; }else if (qh->build_cnt && qh->build_cnt >= qh->RERUN) break; qh->STOPcone= 0; qh_freebuild(qh, True); /* first call is a nop */ qh->build_cnt++; if (!qh->qhull_optionsiz) qh->qhull_optionsiz= (int)strlen(qh->qhull_options); /* WARN64 */ else { qh->qhull_options [qh->qhull_optionsiz]= '\0'; qh->qhull_optionlen= qh_OPTIONline; /* starts a new line */ } qh_option(qh, "_run", &qh->build_cnt, NULL); if (qh->build_cnt == qh->RERUN) { qh->IStracing= qh->TRACElastrun; /* duplicated from qh_initqhull_globals */ if (qh->TRACEpoint != qh_IDunknown || qh->TRACEdist < REALmax/2 || qh->TRACEmerge) { qh->TRACElevel= (qh->IStracing? qh->IStracing : 3); qh->IStracing= 0; } qh->qhmem.IStracing= qh->IStracing; } if (qh->JOGGLEmax < REALmax/2) qh_joggleinput(qh); qh_initbuild(qh); qh_buildhull(qh); if (qh->JOGGLEmax < REALmax/2 && !qh->MERGING) qh_checkconvex(qh, qh->facet_list, qh_ALGORITHMfault); } qh->ALLOWrestart= False; } /* qh_build_withrestart */ /*--------------------------------- qh_buildhull(qh) construct a convex hull by adding outside points one at a time returns: notes: may be called multiple times checks facet and vertex lists for incorrect flags to recover from STOPcone, call qh_deletevisible and qh_resetlists design: check visible facet and newfacet flags check newlist vertex flags and qh.STOPcone/STOPpoint for each facet with a furthest outside point add point to facet exit if qh.STOPcone or qh.STOPpoint requested if qh.NARROWhull for initial simplex partition remaining outside points to coplanar sets */ void qh_buildhull(qhT *qh) { facetT *facet; pointT *furthest; vertexT *vertex; int id; trace1((qh, qh->ferr, 1037, "qh_buildhull: start build hull\n")); FORALLfacets { if (facet->visible || facet->newfacet) { qh_fprintf(qh, qh->ferr, 6165, "qhull internal error (qh_buildhull): visible or new facet f%d in facet list\n", facet->id); qh_errexit(qh, qh_ERRqhull, facet, NULL); } } FORALLvertices { if (vertex->newlist) { qh_fprintf(qh, qh->ferr, 6166, "qhull internal error (qh_buildhull): new vertex f%d in vertex list\n", vertex->id); qh_errprint(qh, "ERRONEOUS", NULL, NULL, NULL, vertex); qh_errexit(qh, qh_ERRqhull, NULL, NULL); } id= qh_pointid(qh, vertex->point); if ((qh->STOPpoint>0 && id == qh->STOPpoint-1) || (qh->STOPpoint<0 && id == -qh->STOPpoint-1) || (qh->STOPcone>0 && id == qh->STOPcone-1)) { trace1((qh, qh->ferr, 1038,"qh_buildhull: stop point or cone P%d in initial hull\n", id)); return; } } qh->facet_next= qh->facet_list; /* advance facet when processed */ while ((furthest= qh_nextfurthest(qh, &facet))) { qh->num_outside--; /* if ONLYmax, furthest may not be outside */ if (!qh_addpoint(qh, furthest, facet, qh->ONLYmax)) break; } if (qh->NARROWhull) /* move points from outsideset to coplanarset */ qh_outcoplanar(qh /* facet_list */ ); if (qh->num_outside && !furthest) { qh_fprintf(qh, qh->ferr, 6167, "qhull internal error (qh_buildhull): %d outside points were never processed.\n", qh->num_outside); qh_errexit(qh, qh_ERRqhull, NULL, NULL); } trace1((qh, qh->ferr, 1039, "qh_buildhull: completed the hull construction\n")); } /* buildhull */ /*--------------------------------- qh_buildtracing(qh, furthest, facet ) trace an iteration of qh_buildhull() for furthest point and facet if !furthest, prints progress message returns: tracks progress with qh.lastreport updates qh.furthest_id (-3 if furthest is NULL) also resets visit_id, vertext_visit on wrap around see: qh_tracemerging() design: if !furthest print progress message exit if 'TFn' iteration print progress message else if tracing trace furthest point and facet reset qh.visit_id and qh.vertex_visit if overflow may occur set qh.furthest_id for tracing */ void qh_buildtracing(qhT *qh, pointT *furthest, facetT *facet) { realT dist= 0; float cpu; int total, furthestid; time_t timedata; struct tm *tp; vertexT *vertex; qh->old_randomdist= qh->RANDOMdist; qh->RANDOMdist= False; if (!furthest) { time(&timedata); tp= localtime(&timedata); cpu= (float)qh_CPUclock - (float)qh->hulltime; cpu /= (float)qh_SECticks; total= zzval_(Ztotmerge) - zzval_(Zcyclehorizon) + zzval_(Zcyclefacettot); qh_fprintf(qh, qh->ferr, 8118, "\n\ At %02d:%02d:%02d & %2.5g CPU secs, qhull has created %d facets and merged %d.\n\ The current hull contains %d facets and %d vertices. Last point was p%d\n", tp->tm_hour, tp->tm_min, tp->tm_sec, cpu, qh->facet_id -1, total, qh->num_facets, qh->num_vertices, qh->furthest_id); return; } furthestid= qh_pointid(qh, furthest); if (qh->TRACEpoint == furthestid) { qh->IStracing= qh->TRACElevel; qh->qhmem.IStracing= qh->TRACElevel; }else if (qh->TRACEpoint != qh_IDunknown && qh->TRACEdist < REALmax/2) { qh->IStracing= 0; qh->qhmem.IStracing= 0; } if (qh->REPORTfreq && (qh->facet_id-1 > qh->lastreport+qh->REPORTfreq)) { qh->lastreport= qh->facet_id-1; time(&timedata); tp= localtime(&timedata); cpu= (float)qh_CPUclock - (float)qh->hulltime; cpu /= (float)qh_SECticks; total= zzval_(Ztotmerge) - zzval_(Zcyclehorizon) + zzval_(Zcyclefacettot); zinc_(Zdistio); qh_distplane(qh, furthest, facet, &dist); qh_fprintf(qh, qh->ferr, 8119, "\n\ At %02d:%02d:%02d & %2.5g CPU secs, qhull has created %d facets and merged %d.\n\ The current hull contains %d facets and %d vertices. There are %d\n\ outside points. Next is point p%d(v%d), %2.2g above f%d.\n", tp->tm_hour, tp->tm_min, tp->tm_sec, cpu, qh->facet_id -1, total, qh->num_facets, qh->num_vertices, qh->num_outside+1, furthestid, qh->vertex_id, dist, getid_(facet)); }else if (qh->IStracing >=1) { cpu= (float)qh_CPUclock - (float)qh->hulltime; cpu /= (float)qh_SECticks; qh_distplane(qh, furthest, facet, &dist); qh_fprintf(qh, qh->ferr, 8120, "qh_addpoint: add p%d(v%d) to hull of %d facets(%2.2g above f%d) and %d outside at %4.4g CPU secs. Previous was p%d.\n", furthestid, qh->vertex_id, qh->num_facets, dist, getid_(facet), qh->num_outside+1, cpu, qh->furthest_id); } zmax_(Zvisit2max, (int)qh->visit_id/2); if (qh->visit_id > (unsigned) INT_MAX) { /* 31 bits */ zinc_(Zvisit); qh->visit_id= 0; FORALLfacets facet->visitid= 0; } zmax_(Zvvisit2max, (int)qh->vertex_visit/2); if (qh->vertex_visit > (unsigned) INT_MAX) { /* 31 bits */ zinc_(Zvvisit); qh->vertex_visit= 0; FORALLvertices vertex->visitid= 0; } qh->furthest_id= furthestid; qh->RANDOMdist= qh->old_randomdist; } /* buildtracing */ /*--------------------------------- qh_errexit2(qh, exitcode, facet, otherfacet ) return exitcode to system after an error report two facets returns: assumes exitcode non-zero see: normally use qh_errexit() in user.c(reports a facet and a ridge) */ void qh_errexit2(qhT *qh, int exitcode, facetT *facet, facetT *otherfacet) { qh_errprint(qh, "ERRONEOUS", facet, otherfacet, NULL, NULL); qh_errexit(qh, exitcode, NULL, NULL); } /* errexit2 */ /*--------------------------------- qh_findhorizon(qh, point, facet, goodvisible, goodhorizon ) given a visible facet, find the point's horizon and visible facets for all facets, !facet-visible returns: returns qh.visible_list/num_visible with all visible facets marks visible facets with ->visible updates count of good visible and good horizon facets updates qh.max_outside, qh.max_vertex, facet->maxoutside see: similar to qh_delpoint() design: move facet to qh.visible_list at end of qh.facet_list for all visible facets for each unvisited neighbor of a visible facet compute distance of point to neighbor if point above neighbor move neighbor to end of qh.visible_list else if point is coplanar with neighbor update qh.max_outside, qh.max_vertex, neighbor->maxoutside mark neighbor coplanar (will create a samecycle later) update horizon statistics */ void qh_findhorizon(qhT *qh, pointT *point, facetT *facet, int *goodvisible, int *goodhorizon) { facetT *neighbor, **neighborp, *visible; int numhorizon= 0, coplanar= 0; realT dist; trace1((qh, qh->ferr, 1040,"qh_findhorizon: find horizon for point p%d facet f%d\n",qh_pointid(qh, point),facet->id)); *goodvisible= *goodhorizon= 0; zinc_(Ztotvisible); qh_removefacet(qh, facet); /* visible_list at end of qh->facet_list */ qh_appendfacet(qh, facet); qh->num_visible= 1; if (facet->good) (*goodvisible)++; qh->visible_list= facet; facet->visible= True; facet->f.replace= NULL; if (qh->IStracing >=4) qh_errprint(qh, "visible", facet, NULL, NULL, NULL); qh->visit_id++; FORALLvisible_facets { if (visible->tricoplanar && !qh->TRInormals) { qh_fprintf(qh, qh->ferr, 6230, "Qhull internal error (qh_findhorizon): does not work for tricoplanar facets. Use option 'Q11'\n"); qh_errexit(qh, qh_ERRqhull, visible, NULL); } visible->visitid= qh->visit_id; FOREACHneighbor_(visible) { if (neighbor->visitid == qh->visit_id) continue; neighbor->visitid= qh->visit_id; zzinc_(Znumvisibility); qh_distplane(qh, point, neighbor, &dist); if (dist > qh->MINvisible) { zinc_(Ztotvisible); qh_removefacet(qh, neighbor); /* append to end of qh->visible_list */ qh_appendfacet(qh, neighbor); neighbor->visible= True; neighbor->f.replace= NULL; qh->num_visible++; if (neighbor->good) (*goodvisible)++; if (qh->IStracing >=4) qh_errprint(qh, "visible", neighbor, NULL, NULL, NULL); }else { if (dist > - qh->MAXcoplanar) { neighbor->coplanar= True; zzinc_(Zcoplanarhorizon); qh_precision(qh, "coplanar horizon"); coplanar++; if (qh->MERGING) { if (dist > 0) { maximize_(qh->max_outside, dist); maximize_(qh->max_vertex, dist); #if qh_MAXoutside maximize_(neighbor->maxoutside, dist); #endif }else minimize_(qh->min_vertex, dist); /* due to merge later */ } trace2((qh, qh->ferr, 2057, "qh_findhorizon: point p%d is coplanar to horizon f%d, dist=%2.7g < qh->MINvisible(%2.7g)\n", qh_pointid(qh, point), neighbor->id, dist, qh->MINvisible)); }else neighbor->coplanar= False; zinc_(Ztothorizon); numhorizon++; if (neighbor->good) (*goodhorizon)++; if (qh->IStracing >=4) qh_errprint(qh, "horizon", neighbor, NULL, NULL, NULL); } } } if (!numhorizon) { qh_precision(qh, "empty horizon"); qh_fprintf(qh, qh->ferr, 6168, "qhull precision error (qh_findhorizon): empty horizon\n\ QhullPoint p%d was above all facets.\n", qh_pointid(qh, point)); qh_printfacetlist(qh, qh->facet_list, NULL, True); qh_errexit(qh, qh_ERRprec, NULL, NULL); } trace1((qh, qh->ferr, 1041, "qh_findhorizon: %d horizon facets(good %d), %d visible(good %d), %d coplanar\n", numhorizon, *goodhorizon, qh->num_visible, *goodvisible, coplanar)); if (qh->IStracing >= 4 && qh->num_facets < 50) qh_printlists(qh); } /* findhorizon */ /*--------------------------------- qh_nextfurthest(qh, visible ) returns next furthest point and visible facet for qh_addpoint() starts search at qh.facet_next returns: removes furthest point from outside set NULL if none available advances qh.facet_next over facets with empty outside sets design: for each facet from qh.facet_next if empty outside set advance qh.facet_next else if qh.NARROWhull determine furthest outside point if furthest point is not outside advance qh.facet_next(point will be coplanar) remove furthest point from outside set */ pointT *qh_nextfurthest(qhT *qh, facetT **visible) { facetT *facet; int size, idx; realT randr, dist; pointT *furthest; while ((facet= qh->facet_next) != qh->facet_tail) { if (!facet->outsideset) { qh->facet_next= facet->next; continue; } SETreturnsize_(facet->outsideset, size); if (!size) { qh_setfree(qh, &facet->outsideset); qh->facet_next= facet->next; continue; } if (qh->NARROWhull) { if (facet->notfurthest) qh_furthestout(qh, facet); furthest= (pointT*)qh_setlast(facet->outsideset); #if qh_COMPUTEfurthest qh_distplane(qh, furthest, facet, &dist); zinc_(Zcomputefurthest); #else dist= facet->furthestdist; #endif if (dist < qh->MINoutside) { /* remainder of outside set is coplanar for qh_outcoplanar */ qh->facet_next= facet->next; continue; } } if (!qh->RANDOMoutside && !qh->VIRTUALmemory) { if (qh->PICKfurthest) { qh_furthestnext(qh /* qh->facet_list */); facet= qh->facet_next; } *visible= facet; return((pointT*)qh_setdellast(facet->outsideset)); } if (qh->RANDOMoutside) { int outcoplanar = 0; if (qh->NARROWhull) { FORALLfacets { if (facet == qh->facet_next) break; if (facet->outsideset) outcoplanar += qh_setsize(qh, facet->outsideset); } } randr= qh_RANDOMint; randr= randr/(qh_RANDOMmax+1); idx= (int)floor((qh->num_outside - outcoplanar) * randr); FORALLfacet_(qh->facet_next) { if (facet->outsideset) { SETreturnsize_(facet->outsideset, size); if (!size) qh_setfree(qh, &facet->outsideset); else if (size > idx) { *visible= facet; return((pointT*)qh_setdelnth(qh, facet->outsideset, idx)); }else idx -= size; } } qh_fprintf(qh, qh->ferr, 6169, "qhull internal error (qh_nextfurthest): num_outside %d is too low\nby at least %d, or a random real %g >= 1.0\n", qh->num_outside, idx+1, randr); qh_errexit(qh, qh_ERRqhull, NULL, NULL); }else { /* VIRTUALmemory */ facet= qh->facet_tail->previous; if (!(furthest= (pointT*)qh_setdellast(facet->outsideset))) { if (facet->outsideset) qh_setfree(qh, &facet->outsideset); qh_removefacet(qh, facet); qh_prependfacet(qh, facet, &qh->facet_list); continue; } *visible= facet; return furthest; } } return NULL; } /* nextfurthest */ /*--------------------------------- qh_partitionall(qh, vertices, points, numpoints ) partitions all points in points/numpoints to the outsidesets of facets vertices= vertices in qh.facet_list(!partitioned) returns: builds facet->outsideset does not partition qh.GOODpoint if qh.ONLYgood && !qh.MERGING, does not partition qh.GOODvertex notes: faster if qh.facet_list sorted by anticipated size of outside set design: initialize pointset with all points remove vertices from pointset remove qh.GOODpointp from pointset (unless it's qh.STOPcone or qh.STOPpoint) for all facets for all remaining points in pointset compute distance from point to facet if point is outside facet remove point from pointset (by not reappending) update bestpoint append point or old bestpoint to facet's outside set append bestpoint to facet's outside set (furthest) for all points remaining in pointset partition point into facets' outside sets and coplanar sets */ void qh_partitionall(qhT *qh, setT *vertices, pointT *points, int numpoints){ setT *pointset; vertexT *vertex, **vertexp; pointT *point, **pointp, *bestpoint; int size, point_i, point_n, point_end, remaining, i, id; facetT *facet; realT bestdist= -REALmax, dist, distoutside; trace1((qh, qh->ferr, 1042, "qh_partitionall: partition all points into outside sets\n")); pointset= qh_settemp(qh, numpoints); qh->num_outside= 0; pointp= SETaddr_(pointset, pointT); for (i=numpoints, point= points; i--; point += qh->hull_dim) *(pointp++)= point; qh_settruncate(qh, pointset, numpoints); FOREACHvertex_(vertices) { if ((id= qh_pointid(qh, vertex->point)) >= 0) SETelem_(pointset, id)= NULL; } id= qh_pointid(qh, qh->GOODpointp); if (id >=0 && qh->STOPcone-1 != id && -qh->STOPpoint-1 != id) SETelem_(pointset, id)= NULL; if (qh->GOODvertexp && qh->ONLYgood && !qh->MERGING) { /* matches qhull()*/ if ((id= qh_pointid(qh, qh->GOODvertexp)) >= 0) SETelem_(pointset, id)= NULL; } if (!qh->BESToutside) { /* matches conditional for qh_partitionpoint below */ distoutside= qh_DISToutside; /* multiple of qh.MINoutside & qh.max_outside, see user.h */ zval_(Ztotpartition)= qh->num_points - qh->hull_dim - 1; /*misses GOOD... */ remaining= qh->num_facets; point_end= numpoints; FORALLfacets { size= point_end/(remaining--) + 100; facet->outsideset= qh_setnew(qh, size); bestpoint= NULL; point_end= 0; FOREACHpoint_i_(qh, pointset) { if (point) { zzinc_(Zpartitionall); qh_distplane(qh, point, facet, &dist); if (dist < distoutside) SETelem_(pointset, point_end++)= point; else { qh->num_outside++; if (!bestpoint) { bestpoint= point; bestdist= dist; }else if (dist > bestdist) { qh_setappend(qh, &facet->outsideset, bestpoint); bestpoint= point; bestdist= dist; }else qh_setappend(qh, &facet->outsideset, point); } } } if (bestpoint) { qh_setappend(qh, &facet->outsideset, bestpoint); #if !qh_COMPUTEfurthest facet->furthestdist= bestdist; #endif }else qh_setfree(qh, &facet->outsideset); qh_settruncate(qh, pointset, point_end); } } /* if !qh->BESToutside, pointset contains points not assigned to outsideset */ if (qh->BESToutside || qh->MERGING || qh->KEEPcoplanar || qh->KEEPinside) { qh->findbestnew= True; FOREACHpoint_i_(qh, pointset) { if (point) qh_partitionpoint(qh, point, qh->facet_list); } qh->findbestnew= False; } zzadd_(Zpartitionall, zzval_(Zpartition)); zzval_(Zpartition)= 0; qh_settempfree(qh, &pointset); if (qh->IStracing >= 4) qh_printfacetlist(qh, qh->facet_list, NULL, True); } /* partitionall */ /*--------------------------------- qh_partitioncoplanar(qh, point, facet, dist ) partition coplanar point to a facet dist is distance from point to facet if dist NULL, searches for bestfacet and does nothing if inside if qh.findbestnew set, searches new facets instead of using qh_findbest() returns: qh.max_ouside updated if qh.KEEPcoplanar or qh.KEEPinside point assigned to best coplanarset notes: facet->maxoutside is updated at end by qh_check_maxout design: if dist undefined find best facet for point if point sufficiently below facet (depends on qh.NEARinside and qh.KEEPinside) exit if keeping coplanar/nearinside/inside points if point is above furthest coplanar point append point to coplanar set (it is the new furthest) update qh.max_outside else append point one before end of coplanar set else if point is clearly outside of qh.max_outside and bestfacet->coplanarset and bestfacet is more than perpendicular to facet repartition the point using qh_findbest() -- it may be put on an outsideset else update qh.max_outside */ void qh_partitioncoplanar(qhT *qh, pointT *point, facetT *facet, realT *dist) { facetT *bestfacet; pointT *oldfurthest; realT bestdist, dist2= 0, angle; int numpart= 0, oldfindbest; boolT isoutside; qh->WAScoplanar= True; if (!dist) { if (qh->findbestnew) bestfacet= qh_findbestnew(qh, point, facet, &bestdist, qh_ALL, &isoutside, &numpart); else bestfacet= qh_findbest(qh, point, facet, qh_ALL, !qh_ISnewfacets, qh->DELAUNAY, &bestdist, &isoutside, &numpart); zinc_(Ztotpartcoplanar); zzadd_(Zpartcoplanar, numpart); if (!qh->DELAUNAY && !qh->KEEPinside) { /* for 'd', bestdist skips upperDelaunay facets */ if (qh->KEEPnearinside) { if (bestdist < -qh->NEARinside) { zinc_(Zcoplanarinside); trace4((qh, qh->ferr, 4062, "qh_partitioncoplanar: point p%d is more than near-inside facet f%d dist %2.2g findbestnew %d\n", qh_pointid(qh, point), bestfacet->id, bestdist, qh->findbestnew)); return; } }else if (bestdist < -qh->MAXcoplanar) { trace4((qh, qh->ferr, 4063, "qh_partitioncoplanar: point p%d is inside facet f%d dist %2.2g findbestnew %d\n", qh_pointid(qh, point), bestfacet->id, bestdist, qh->findbestnew)); zinc_(Zcoplanarinside); return; } } }else { bestfacet= facet; bestdist= *dist; } if (bestdist > qh->max_outside) { if (!dist && facet != bestfacet) { zinc_(Zpartangle); angle= qh_getangle(qh, facet->normal, bestfacet->normal); if (angle < 0) { /* typically due to deleted vertex and coplanar facets, e.g., RBOX 1000 s Z1 G1e-13 t1001185205 | QHULL Tv */ zinc_(Zpartflip); trace2((qh, qh->ferr, 2058, "qh_partitioncoplanar: repartition point p%d from f%d. It is above flipped facet f%d dist %2.2g\n", qh_pointid(qh, point), facet->id, bestfacet->id, bestdist)); oldfindbest= qh->findbestnew; qh->findbestnew= False; qh_partitionpoint(qh, point, bestfacet); qh->findbestnew= oldfindbest; return; } } qh->max_outside= bestdist; if (bestdist > qh->TRACEdist) { qh_fprintf(qh, qh->ferr, 8122, "qh_partitioncoplanar: ====== p%d from f%d increases max_outside to %2.2g of f%d last p%d\n", qh_pointid(qh, point), facet->id, bestdist, bestfacet->id, qh->furthest_id); qh_errprint(qh, "DISTANT", facet, bestfacet, NULL, NULL); } } if (qh->KEEPcoplanar + qh->KEEPinside + qh->KEEPnearinside) { oldfurthest= (pointT*)qh_setlast(bestfacet->coplanarset); if (oldfurthest) { zinc_(Zcomputefurthest); qh_distplane(qh, oldfurthest, bestfacet, &dist2); } if (!oldfurthest || dist2 < bestdist) qh_setappend(qh, &bestfacet->coplanarset, point); else qh_setappend2ndlast(qh, &bestfacet->coplanarset, point); } trace4((qh, qh->ferr, 4064, "qh_partitioncoplanar: point p%d is coplanar with facet f%d(or inside) dist %2.2g\n", qh_pointid(qh, point), bestfacet->id, bestdist)); } /* partitioncoplanar */ /*--------------------------------- qh_partitionpoint(qh, point, facet ) assigns point to an outside set, coplanar set, or inside set (i.e., dropt) if qh.findbestnew uses qh_findbestnew() to search all new facets else uses qh_findbest() notes: after qh_distplane(), this and qh_findbest() are most expensive in 3-d design: find best facet for point (either exhaustive search of new facets or directed search from facet) if qh.NARROWhull retain coplanar and nearinside points as outside points if point is outside bestfacet if point above furthest point for bestfacet append point to outside set (it becomes the new furthest) if outside set was empty move bestfacet to end of qh.facet_list (i.e., after qh.facet_next) update bestfacet->furthestdist else append point one before end of outside set else if point is coplanar to bestfacet if keeping coplanar points or need to update qh.max_outside partition coplanar point into bestfacet else if near-inside point partition as coplanar point into bestfacet else is an inside point if keeping inside points partition as coplanar point into bestfacet */ void qh_partitionpoint(qhT *qh, pointT *point, facetT *facet) { realT bestdist; boolT isoutside; facetT *bestfacet; int numpart; #if qh_COMPUTEfurthest realT dist; #endif if (qh->findbestnew) bestfacet= qh_findbestnew(qh, point, facet, &bestdist, qh->BESToutside, &isoutside, &numpart); else bestfacet= qh_findbest(qh, point, facet, qh->BESToutside, qh_ISnewfacets, !qh_NOupper, &bestdist, &isoutside, &numpart); zinc_(Ztotpartition); zzadd_(Zpartition, numpart); if (qh->NARROWhull) { if (qh->DELAUNAY && !isoutside && bestdist >= -qh->MAXcoplanar) qh_precision(qh, "nearly incident point(narrow hull)"); if (qh->KEEPnearinside) { if (bestdist >= -qh->NEARinside) isoutside= True; }else if (bestdist >= -qh->MAXcoplanar) isoutside= True; } if (isoutside) { if (!bestfacet->outsideset || !qh_setlast(bestfacet->outsideset)) { qh_setappend(qh, &(bestfacet->outsideset), point); if (!bestfacet->newfacet) { qh_removefacet(qh, bestfacet); /* make sure it's after qh->facet_next */ qh_appendfacet(qh, bestfacet); } #if !qh_COMPUTEfurthest bestfacet->furthestdist= bestdist; #endif }else { #if qh_COMPUTEfurthest zinc_(Zcomputefurthest); qh_distplane(qh, oldfurthest, bestfacet, &dist); if (dist < bestdist) qh_setappend(qh, &(bestfacet->outsideset), point); else qh_setappend2ndlast(qh, &(bestfacet->outsideset), point); #else if (bestfacet->furthestdist < bestdist) { qh_setappend(qh, &(bestfacet->outsideset), point); bestfacet->furthestdist= bestdist; }else qh_setappend2ndlast(qh, &(bestfacet->outsideset), point); #endif } qh->num_outside++; trace4((qh, qh->ferr, 4065, "qh_partitionpoint: point p%d is outside facet f%d new? %d (or narrowhull)\n", qh_pointid(qh, point), bestfacet->id, bestfacet->newfacet)); }else if (qh->DELAUNAY || bestdist >= -qh->MAXcoplanar) { /* for 'd', bestdist skips upperDelaunay facets */ zzinc_(Zcoplanarpart); if (qh->DELAUNAY) qh_precision(qh, "nearly incident point"); if ((qh->KEEPcoplanar + qh->KEEPnearinside) || bestdist > qh->max_outside) qh_partitioncoplanar(qh, point, bestfacet, &bestdist); else { trace4((qh, qh->ferr, 4066, "qh_partitionpoint: point p%d is coplanar to facet f%d (dropped)\n", qh_pointid(qh, point), bestfacet->id)); } }else if (qh->KEEPnearinside && bestdist > -qh->NEARinside) { zinc_(Zpartnear); qh_partitioncoplanar(qh, point, bestfacet, &bestdist); }else { zinc_(Zpartinside); trace4((qh, qh->ferr, 4067, "qh_partitionpoint: point p%d is inside all facets, closest to f%d dist %2.2g\n", qh_pointid(qh, point), bestfacet->id, bestdist)); if (qh->KEEPinside) qh_partitioncoplanar(qh, point, bestfacet, &bestdist); } } /* partitionpoint */ /*--------------------------------- qh_partitionvisible(qh, allpoints, numoutside ) partitions points in visible facets to qh.newfacet_list qh.visible_list= visible facets for visible facets 1st neighbor (if any) points to a horizon facet or a new facet if allpoints(!used), repartitions coplanar points returns: updates outside sets and coplanar sets of qh.newfacet_list updates qh.num_outside (count of outside points) notes: qh.findbest_notsharp should be clear (extra work if set) design: for all visible facets with outside set or coplanar set select a newfacet for visible facet if outside set partition outside set into new facets if coplanar set and keeping coplanar/near-inside/inside points if allpoints partition coplanar set into new facets, may be assigned outside else partition coplanar set into coplanar sets of new facets for each deleted vertex if allpoints partition vertex into new facets, may be assigned outside else partition vertex into coplanar sets of new facets */ void qh_partitionvisible(qhT *qh /*qh.visible_list*/, boolT allpoints, int *numoutside) { facetT *visible, *newfacet; pointT *point, **pointp; int coplanar=0, size; unsigned count; vertexT *vertex, **vertexp; if (qh->ONLYmax) maximize_(qh->MINoutside, qh->max_vertex); *numoutside= 0; FORALLvisible_facets { if (!visible->outsideset && !visible->coplanarset) continue; newfacet= visible->f.replace; count= 0; while (newfacet && newfacet->visible) { newfacet= newfacet->f.replace; if (count++ > qh->facet_id) qh_infiniteloop(qh, visible); } if (!newfacet) newfacet= qh->newfacet_list; if (newfacet == qh->facet_tail) { qh_fprintf(qh, qh->ferr, 6170, "qhull precision error (qh_partitionvisible): all new facets deleted as\n degenerate facets. Can not continue.\n"); qh_errexit(qh, qh_ERRprec, NULL, NULL); } if (visible->outsideset) { size= qh_setsize(qh, visible->outsideset); *numoutside += size; qh->num_outside -= size; FOREACHpoint_(visible->outsideset) qh_partitionpoint(qh, point, newfacet); } if (visible->coplanarset && (qh->KEEPcoplanar + qh->KEEPinside + qh->KEEPnearinside)) { size= qh_setsize(qh, visible->coplanarset); coplanar += size; FOREACHpoint_(visible->coplanarset) { if (allpoints) /* not used */ qh_partitionpoint(qh, point, newfacet); else qh_partitioncoplanar(qh, point, newfacet, NULL); } } } FOREACHvertex_(qh->del_vertices) { if (vertex->point) { if (allpoints) /* not used */ qh_partitionpoint(qh, vertex->point, qh->newfacet_list); else qh_partitioncoplanar(qh, vertex->point, qh->newfacet_list, NULL); } } trace1((qh, qh->ferr, 1043,"qh_partitionvisible: partitioned %d points from outsidesets and %d points from coplanarsets\n", *numoutside, coplanar)); } /* partitionvisible */ /*--------------------------------- qh_precision(qh, reason ) restart on precision errors if not merging and if 'QJn' */ void qh_precision(qhT *qh, const char *reason) { if (qh->ALLOWrestart && !qh->PREmerge && !qh->MERGEexact) { if (qh->JOGGLEmax < REALmax/2) { trace0((qh, qh->ferr, 26, "qh_precision: qhull restart because of %s\n", reason)); /* May be called repeatedly if qh->ALLOWrestart */ longjmp(qh->restartexit, qh_ERRprec); } } } /* qh_precision */ /*--------------------------------- qh_printsummary(qh, fp ) prints summary to fp notes: not in io_r.c so that user_eg.c can prevent io_r.c from loading qh_printsummary and qh_countfacets must match counts design: determine number of points, vertices, and coplanar points print summary */ void qh_printsummary(qhT *qh, FILE *fp) { realT ratio, outerplane, innerplane; float cpu; int size, id, nummerged, numvertices, numcoplanars= 0, nonsimplicial=0; int goodused; facetT *facet; const char *s; int numdel= zzval_(Zdelvertextot); int numtricoplanars= 0; size= qh->num_points + qh_setsize(qh, qh->other_points); numvertices= qh->num_vertices - qh_setsize(qh, qh->del_vertices); id= qh_pointid(qh, qh->GOODpointp); FORALLfacets { if (facet->coplanarset) numcoplanars += qh_setsize(qh, facet->coplanarset); if (facet->good) { if (facet->simplicial) { if (facet->keepcentrum && facet->tricoplanar) numtricoplanars++; }else if (qh_setsize(qh, facet->vertices) != qh->hull_dim) nonsimplicial++; } } if (id >=0 && qh->STOPcone-1 != id && -qh->STOPpoint-1 != id) size--; if (qh->STOPcone || qh->STOPpoint) qh_fprintf(qh, fp, 9288, "\nAt a premature exit due to 'TVn', 'TCn', 'TRn', or precision error with 'QJn'."); if (qh->UPPERdelaunay) goodused= qh->GOODvertex + qh->GOODpoint + qh->SPLITthresholds; else if (qh->DELAUNAY) goodused= qh->GOODvertex + qh->GOODpoint + qh->GOODthreshold; else goodused= qh->num_good; nummerged= zzval_(Ztotmerge) - zzval_(Zcyclehorizon) + zzval_(Zcyclefacettot); if (qh->VORONOI) { if (qh->UPPERdelaunay) qh_fprintf(qh, fp, 9289, "\n\ Furthest-site Voronoi vertices by the convex hull of %d points in %d-d:\n\n", size, qh->hull_dim); else qh_fprintf(qh, fp, 9290, "\n\ Voronoi diagram by the convex hull of %d points in %d-d:\n\n", size, qh->hull_dim); qh_fprintf(qh, fp, 9291, " Number of Voronoi regions%s: %d\n", qh->ATinfinity ? " and at-infinity" : "", numvertices); if (numdel) qh_fprintf(qh, fp, 9292, " Total number of deleted points due to merging: %d\n", numdel); if (numcoplanars - numdel > 0) qh_fprintf(qh, fp, 9293, " Number of nearly incident points: %d\n", numcoplanars - numdel); else if (size - numvertices - numdel > 0) qh_fprintf(qh, fp, 9294, " Total number of nearly incident points: %d\n", size - numvertices - numdel); qh_fprintf(qh, fp, 9295, " Number of%s Voronoi vertices: %d\n", goodused ? " 'good'" : "", qh->num_good); if (nonsimplicial) qh_fprintf(qh, fp, 9296, " Number of%s non-simplicial Voronoi vertices: %d\n", goodused ? " 'good'" : "", nonsimplicial); }else if (qh->DELAUNAY) { if (qh->UPPERdelaunay) qh_fprintf(qh, fp, 9297, "\n\ Furthest-site Delaunay triangulation by the convex hull of %d points in %d-d:\n\n", size, qh->hull_dim); else qh_fprintf(qh, fp, 9298, "\n\ Delaunay triangulation by the convex hull of %d points in %d-d:\n\n", size, qh->hull_dim); qh_fprintf(qh, fp, 9299, " Number of input sites%s: %d\n", qh->ATinfinity ? " and at-infinity" : "", numvertices); if (numdel) qh_fprintf(qh, fp, 9300, " Total number of deleted points due to merging: %d\n", numdel); if (numcoplanars - numdel > 0) qh_fprintf(qh, fp, 9301, " Number of nearly incident points: %d\n", numcoplanars - numdel); else if (size - numvertices - numdel > 0) qh_fprintf(qh, fp, 9302, " Total number of nearly incident points: %d\n", size - numvertices - numdel); qh_fprintf(qh, fp, 9303, " Number of%s Delaunay regions: %d\n", goodused ? " 'good'" : "", qh->num_good); if (nonsimplicial) qh_fprintf(qh, fp, 9304, " Number of%s non-simplicial Delaunay regions: %d\n", goodused ? " 'good'" : "", nonsimplicial); }else if (qh->HALFspace) { qh_fprintf(qh, fp, 9305, "\n\ Halfspace intersection by the convex hull of %d points in %d-d:\n\n", size, qh->hull_dim); qh_fprintf(qh, fp, 9306, " Number of halfspaces: %d\n", size); qh_fprintf(qh, fp, 9307, " Number of non-redundant halfspaces: %d\n", numvertices); if (numcoplanars) { if (qh->KEEPinside && qh->KEEPcoplanar) s= "similar and redundant"; else if (qh->KEEPinside) s= "redundant"; else s= "similar"; qh_fprintf(qh, fp, 9308, " Number of %s halfspaces: %d\n", s, numcoplanars); } qh_fprintf(qh, fp, 9309, " Number of intersection points: %d\n", qh->num_facets - qh->num_visible); if (goodused) qh_fprintf(qh, fp, 9310, " Number of 'good' intersection points: %d\n", qh->num_good); if (nonsimplicial) qh_fprintf(qh, fp, 9311, " Number of%s non-simplicial intersection points: %d\n", goodused ? " 'good'" : "", nonsimplicial); }else { qh_fprintf(qh, fp, 9312, "\n\ Convex hull of %d points in %d-d:\n\n", size, qh->hull_dim); qh_fprintf(qh, fp, 9313, " Number of vertices: %d\n", numvertices); if (numcoplanars) { if (qh->KEEPinside && qh->KEEPcoplanar) s= "coplanar and interior"; else if (qh->KEEPinside) s= "interior"; else s= "coplanar"; qh_fprintf(qh, fp, 9314, " Number of %s points: %d\n", s, numcoplanars); } qh_fprintf(qh, fp, 9315, " Number of facets: %d\n", qh->num_facets - qh->num_visible); if (goodused) qh_fprintf(qh, fp, 9316, " Number of 'good' facets: %d\n", qh->num_good); if (nonsimplicial) qh_fprintf(qh, fp, 9317, " Number of%s non-simplicial facets: %d\n", goodused ? " 'good'" : "", nonsimplicial); } if (numtricoplanars) qh_fprintf(qh, fp, 9318, " Number of triangulated facets: %d\n", numtricoplanars); qh_fprintf(qh, fp, 9319, "\nStatistics for: %s | %s", qh->rbox_command, qh->qhull_command); if (qh->ROTATErandom != INT_MIN) qh_fprintf(qh, fp, 9320, " QR%d\n\n", qh->ROTATErandom); else qh_fprintf(qh, fp, 9321, "\n\n"); qh_fprintf(qh, fp, 9322, " Number of points processed: %d\n", zzval_(Zprocessed)); qh_fprintf(qh, fp, 9323, " Number of hyperplanes created: %d\n", zzval_(Zsetplane)); if (qh->DELAUNAY) qh_fprintf(qh, fp, 9324, " Number of facets in hull: %d\n", qh->num_facets - qh->num_visible); qh_fprintf(qh, fp, 9325, " Number of distance tests for qhull: %d\n", zzval_(Zpartition)+ zzval_(Zpartitionall)+zzval_(Znumvisibility)+zzval_(Zpartcoplanar)); #if 0 /* NOTE: must print before printstatistics() */ {realT stddev, ave; qh_fprintf(qh, fp, 9326, " average new facet balance: %2.2g\n", wval_(Wnewbalance)/zval_(Zprocessed)); stddev= qh_stddev(zval_(Zprocessed), wval_(Wnewbalance), wval_(Wnewbalance2), &ave); qh_fprintf(qh, fp, 9327, " new facet standard deviation: %2.2g\n", stddev); qh_fprintf(qh, fp, 9328, " average partition balance: %2.2g\n", wval_(Wpbalance)/zval_(Zpbalance)); stddev= qh_stddev(zval_(Zpbalance), wval_(Wpbalance), wval_(Wpbalance2), &ave); qh_fprintf(qh, fp, 9329, " partition standard deviation: %2.2g\n", stddev); } #endif if (nummerged) { qh_fprintf(qh, fp, 9330," Number of distance tests for merging: %d\n",zzval_(Zbestdist)+ zzval_(Zcentrumtests)+zzval_(Zdistconvex)+zzval_(Zdistcheck)+ zzval_(Zdistzero)); qh_fprintf(qh, fp, 9331," Number of distance tests for checking: %d\n",zzval_(Zcheckpart)); qh_fprintf(qh, fp, 9332," Number of merged facets: %d\n", nummerged); } if (!qh->RANDOMoutside && qh->QHULLfinished) { cpu= (float)qh->hulltime; cpu /= (float)qh_SECticks; wval_(Wcpu)= cpu; qh_fprintf(qh, fp, 9333, " CPU seconds to compute hull (after input): %2.4g\n", cpu); } if (qh->RERUN) { if (!qh->PREmerge && !qh->MERGEexact) qh_fprintf(qh, fp, 9334, " Percentage of runs with precision errors: %4.1f\n", zzval_(Zretry)*100.0/qh->build_cnt); /* careful of order */ }else if (qh->JOGGLEmax < REALmax/2) { if (zzval_(Zretry)) qh_fprintf(qh, fp, 9335, " After %d retries, input joggled by: %2.2g\n", zzval_(Zretry), qh->JOGGLEmax); else qh_fprintf(qh, fp, 9336, " Input joggled by: %2.2g\n", qh->JOGGLEmax); } if (qh->totarea != 0.0) qh_fprintf(qh, fp, 9337, " %s facet area: %2.8g\n", zzval_(Ztotmerge) ? "Approximate" : "Total", qh->totarea); if (qh->totvol != 0.0) qh_fprintf(qh, fp, 9338, " %s volume: %2.8g\n", zzval_(Ztotmerge) ? "Approximate" : "Total", qh->totvol); if (qh->MERGING) { qh_outerinner(qh, NULL, &outerplane, &innerplane); if (outerplane > 2 * qh->DISTround) { qh_fprintf(qh, fp, 9339, " Maximum distance of %spoint above facet: %2.2g", (qh->QHULLfinished ? "" : "merged "), outerplane); ratio= outerplane/(qh->ONEmerge + qh->DISTround); /* don't report ratio if MINoutside is large */ if (ratio > 0.05 && 2* qh->ONEmerge > qh->MINoutside && qh->JOGGLEmax > REALmax/2) qh_fprintf(qh, fp, 9340, " (%.1fx)\n", ratio); else qh_fprintf(qh, fp, 9341, "\n"); } if (innerplane < -2 * qh->DISTround) { qh_fprintf(qh, fp, 9342, " Maximum distance of %svertex below facet: %2.2g", (qh->QHULLfinished ? "" : "merged "), innerplane); ratio= -innerplane/(qh->ONEmerge+qh->DISTround); if (ratio > 0.05 && qh->JOGGLEmax > REALmax/2) qh_fprintf(qh, fp, 9343, " (%.1fx)\n", ratio); else qh_fprintf(qh, fp, 9344, "\n"); } } qh_fprintf(qh, fp, 9345, "\n"); } /* printsummary */