#include #include #include namespace netgen { Polyhedra::Face::Face (int pi1, int pi2, int pi3, const Array > & points, int ainputnr) { inputnr = ainputnr; pnums[0] = pi1; pnums[1] = pi2; pnums[2] = pi3; bbox.Set (points[pi1]); bbox.Add (points[pi2]); bbox.Add (points[pi3]); v1 = points[pi2] - points[pi1]; v2 = points[pi3] - points[pi1]; n = Cross (v1, v2); nn = n; nn.Normalize(); // PseudoInverse (v1, v2, w1, w2); Mat<2,3> mat; Mat<3,2> inv; for (int i = 0; i < 3; i++) { mat(0,i) = v1(i); mat(1,i) = v2(i); } CalcInverse (mat, inv); for (int i = 0; i < 3; i++) { w1(i) = inv(i,0); w2(i) = inv(i,1); } } Polyhedra :: Polyhedra () { surfaceactive.SetSize(0); surfaceids.SetSize(0); eps_base1 = 1e-8; } Polyhedra :: ~Polyhedra () { ; } Primitive * Polyhedra :: CreateDefault () { return new Polyhedra(); } INSOLID_TYPE Polyhedra :: BoxInSolid (const BoxSphere<3> & box) const { /* for (i = 1; i <= faces.Size(); i++) if (FaceBoxIntersection (i, box)) return DOES_INTERSECT; */ for (int i = 0; i < faces.Size(); i++) { if (!faces[i].bbox.Intersect (box)) continue; //(*testout) << "face " << i << endl; const Point<3> & p1 = points[faces[i].pnums[0]]; const Point<3> & p2 = points[faces[i].pnums[1]]; const Point<3> & p3 = points[faces[i].pnums[2]]; if (fabs (faces[i].nn * (p1 - box.Center())) > box.Diam()/2) continue; //(*testout) << "still in loop" << endl; double dist2 = MinDistTP2 (p1, p2, p3, box.Center()); //(*testout) << "p1 " << p1 << " p2 " << p2 << " p3 " << p3 << endl // << " box.Center " << box.Center() << " box.Diam() " << box.Diam() << endl // << " dist2 " << dist2 << " sqr(box.Diam()/2) " << sqr(box.Diam()/2) << endl; if (dist2 < sqr (box.Diam()/2)) { //(*testout) << "DOES_INTERSECT" << endl; return DOES_INTERSECT; } }; return PointInSolid (box.Center(), 1e-3 * box.Diam()); } INSOLID_TYPE Polyhedra :: PointInSolid (const Point<3> & p, double eps) const { //(*testout) << "PointInSolid p " << p << " eps " << eps << endl; //(*testout) << "bbox " << poly_bbox << endl; if((p(0) > poly_bbox.PMax()(0) + eps) || (p(0) < poly_bbox.PMin()(0) - eps) || (p(1) > poly_bbox.PMax()(1) + eps) || (p(1) < poly_bbox.PMin()(1) - eps) || (p(2) > poly_bbox.PMax()(2) + eps) || (p(2) < poly_bbox.PMin()(2) - eps)) { //(*testout) << "returning IS_OUTSIDE" << endl; return IS_OUTSIDE; } Vec<3> n, v1, v2; // random (?) numbers: n(0) = -0.424621; n(1) = 0.15432; n(2) = 0.89212238; int cnt = 0; for (int i = 0; i < faces.Size(); i++) { const Point<3> & p1 = points[faces[i].pnums[0]]; Vec<3> v0 = p - p1; double lam3 = faces[i].nn * v0; if(fabs(lam3) < eps) { double lam1 = (faces[i].w1 * v0); double lam2 = (faces[i].w2 * v0); if (lam1 >= -eps_base1 && lam2 >= -eps_base1 && lam1+lam2 <= 1+eps_base1) { //(*testout) << "returning DOES_INTERSECT" << endl; return DOES_INTERSECT; } } else { lam3 = -(faces[i].n * v0) / (faces[i].n * n); if (lam3 < 0) continue; Vec<3> rs = v0 + lam3 * n; double lam1 = (faces[i].w1 * rs); double lam2 = (faces[i].w2 * rs); if (lam1 >= 0 && lam2 >= 0 && lam1+lam2 <= 1) cnt++; } } //(*testout) << " cnt = " << cnt%2 << endl; return (cnt % 2) ? IS_INSIDE : IS_OUTSIDE; } void Polyhedra :: GetTangentialSurfaceIndices (const Point<3> & p, Array & surfind, double eps) const { for (int i = 0; i < faces.Size(); i++) { const Point<3> & p1 = points[faces[i].pnums[0]]; Vec<3> v0 = p - p1; double lam3 = -(faces[i].nn * v0); // n->nn if (fabs (lam3) > eps) continue; double lam1 = (faces[i].w1 * v0); double lam2 = (faces[i].w2 * v0); if (lam1 >= -eps_base1 && lam2 >= -eps_base1 && lam1+lam2 <= 1+eps_base1) if (!surfind.Contains (GetSurfaceId(i))) surfind.Append (GetSurfaceId(i)); } } INSOLID_TYPE Polyhedra :: VecInSolid (const Point<3> & p, const Vec<3> & v, double eps) const { Array point_on_faces; INSOLID_TYPE res(DOES_INTERSECT); Vec<3> vn = v; vn.Normalize(); for (int i = 0; i < faces.Size(); i++) { const Point<3> & p1 = points[faces[i].pnums[0]]; Vec<3> v0 = p - p1; double lam3 = -(faces[i].nn * v0); // n->nn if (fabs (lam3) > eps) continue; //(*testout) << "lam3 <= eps" << endl; double lam1 = (faces[i].w1 * v0); double lam2 = (faces[i].w2 * v0); if (lam1 >= -eps_base1 && lam2 >= -eps_base1 && lam1+lam2 <= 1+eps_base1) { point_on_faces.Append(i); double scal = vn * faces[i].nn; // n->nn res = DOES_INTERSECT; if (scal > eps_base1) res = IS_OUTSIDE; if (scal < -eps_base1) res = IS_INSIDE; } } //(*testout) << "point_on_faces.Size() " << point_on_faces.Size() // << " res " << res << endl; if (point_on_faces.Size() == 0) return PointInSolid (p, 0); if (point_on_faces.Size() == 1) return res; double mindist(0); bool first = true; for(int i=0; i eps && (first || dist < mindist)) { mindist = dist; first = false; } } } Point<3> p2 = p + (1e-2*mindist) * vn; res = PointInSolid (p2, eps); // (*testout) << "mindist " << mindist << " res " << res << endl; return res; } /* INSOLID_TYPE Polyhedra :: VecInSolid2 (const Point<3> & p, const Vec<3> & v1, const Vec<3> & v2, double eps) const { INSOLID_TYPE res; res = VecInSolid(p,v1,eps); if(res != DOES_INTERSECT) return res; int point_on_n_faces = 0; Vec<3> v1n = v1; v1n.Normalize(); Vec<3> v2n = v2; v2n.Normalize(); for (int i = 0; i < faces.Size(); i++) { const Point<3> & p1 = points[faces[i].pnums[0]]; Vec<3> v0 = p - p1; double lam3 = -(faces[i].n * v0); if (fabs (lam3) > eps) continue; double lam1 = (faces[i].w1 * v0); double lam2 = (faces[i].w2 * v0); if (lam1 >= -eps && lam2 >= -eps && lam1+lam2 <= 1+eps) { double scal1 = v1n * faces[i].n; if (fabs (scal1) > eps) continue; point_on_n_faces++; double scal2 = v2n * faces[i].n; res = DOES_INTERSECT; if (scal2 > eps) res = IS_OUTSIDE; if (scal2 < -eps) res = IS_INSIDE; } } if (point_on_n_faces == 1) return res; cerr << "primitive::vecinsolid2 makes nonsense for polyhedra" << endl; return Primitive :: VecInSolid2 (p, v1, v2, eps); } */ INSOLID_TYPE Polyhedra :: VecInSolid2 (const Point<3> & p, const Vec<3> & v1, const Vec<3> & v2, double eps) const { //(*testout) << "VecInSolid2 eps " << eps << endl; INSOLID_TYPE res = VecInSolid(p,v1,eps); //(*testout) << "VecInSolid = " < v1n = v1; v1n.Normalize(); Vec<3> v2n = v2 - (v2 * v1n) * v1n; v2n.Normalize(); double cosv2, cosv2max = -99; for (int i = 0; i < faces.Size(); i++) { const Point<3> & p1 = points[faces[i].pnums[0]]; Vec<3> v0 = p - p1; if (fabs (faces[i].nn * v0) > eps) continue; // n->nn if (fabs (v1n * faces[i].nn) > eps_base1) continue; // n->nn double lam1 = (faces[i].w1 * v0); double lam2 = (faces[i].w2 * v0); if (lam1 >= -eps_base1 && lam2 >= -eps_base1 && lam1+lam2 <= 1+eps_base1) { // v1 is in face Point<3> fc = Center (points[faces[i].pnums[0]], points[faces[i].pnums[1]], points[faces[i].pnums[2]]); Vec<3> vpfc = fc - p; cosv2 = (v2n * vpfc) / vpfc.Length(); if (cosv2 > cosv2max) { cosv2max = cosv2; point_on_n_faces++; double scal2 = v2n * faces[i].nn; // n->nn res = DOES_INTERSECT; if (scal2 > eps_base1) res = IS_OUTSIDE; if (scal2 < -eps_base1) res = IS_INSIDE; } } } if (point_on_n_faces >= 1) return res; (*testout) << "primitive::vecinsolid2 makes nonsense for polyhedra" << endl; cerr << "primitive::vecinsolid2 makes nonsense for polyhedra" << endl; return Primitive :: VecInSolid2 (p, v1, v2, eps); } void Polyhedra :: GetTangentialVecSurfaceIndices2 (const Point<3> & p, const Vec<3> & v1, const Vec<3> & v2, Array & surfind, double eps) const { Vec<3> v1n = v1; v1n.Normalize(); Vec<3> v2n = v2; // - (v2 * v1n) * v1n; v2n.Normalize(); for (int i = 0; i < faces.Size(); i++) { const Point<3> & p1 = points[faces[i].pnums[0]]; Vec<3> v0 = p - p1; if (fabs (v0 * faces[i].nn) > eps) continue; // n->nn if (fabs (v1n * faces[i].nn) > eps_base1) continue; // n->nn if (fabs (v2n * faces[i].nn) > eps_base1) continue; // n->nn double lam01 = (faces[i].w1 * v0); double lam02 = (faces[i].w2 * v0); double lam03 = 1-lam01-lam02; double lam11 = (faces[i].w1 * v1); double lam12 = (faces[i].w2 * v1); double lam13 = -lam11-lam12; double lam21 = (faces[i].w1 * v2); double lam22 = (faces[i].w2 * v2); double lam23 = -lam21-lam22; bool ok1 = lam01 > eps_base1 || (lam01 > -eps_base1 && lam11 > eps_base1) || (lam01 > -eps_base1 && lam11 > -eps_base1 && lam21 > eps_base1); bool ok2 = lam02 > eps_base1 || (lam02 > -eps_base1 && lam12 > eps_base1) || (lam02 > -eps_base1 && lam12 > -eps_base1 && lam22 > eps_base1); bool ok3 = lam03 > eps_base1 || (lam03 > -eps_base1 && lam13 > eps_base1) || (lam03 > -eps_base1 && lam13 > -eps_base1 && lam23 > eps_base1); if (ok1 && ok2 && ok3) { if (!surfind.Contains (GetSurfaceId(faces[i].planenr))) surfind.Append (GetSurfaceId(faces[i].planenr)); } } } void Polyhedra :: GetPrimitiveData (const char *& classname, Array & coeffs) const { classname = "Polyhedra"; coeffs.SetSize(0); coeffs.Append (points.Size()); coeffs.Append (faces.Size()); coeffs.Append (planes.Size()); /* int i, j; for (i = 1; i <= planes.Size(); i++) { planes.Elem(i)->Print (*testout); } for (i = 1; i <= faces.Size(); i++) { (*testout) << "face " << i << " has plane " << faces.Get(i).planenr << endl; for (j = 1; j <= 3; j++) (*testout) << points.Get(faces.Get(i).pnums[j-1]); (*testout) << endl; } */ } void Polyhedra :: SetPrimitiveData (Array & /* coeffs */) { ; } void Polyhedra :: Reduce (const BoxSphere<3> & box) { for (int i = 0; i < planes.Size(); i++) surfaceactive[i] = 0; for (int i = 0; i < faces.Size(); i++) if (FaceBoxIntersection (i, box)) surfaceactive[faces[i].planenr] = 1; } void Polyhedra :: UnReduce () { for (int i = 0; i < planes.Size(); i++) surfaceactive[i] = 1; } int Polyhedra :: AddPoint (const Point<3> & p) { if(points.Size() == 0) poly_bbox.Set(p); else poly_bbox.Add(p); return points.Append (p); } int Polyhedra :: AddFace (int pi1, int pi2, int pi3, int inputnum) { (*testout) << "polyhedra, add face " << pi1 << ", " << pi2 << ", " << pi3 << endl; if(pi1 == pi2 || pi2 == pi3 || pi3 == pi1) { ostringstream msg; msg << "Illegal point numbers for polyhedron face: " << pi1+1 << ", " << pi2+1 << ", " << pi3+1; throw NgException(msg.str()); } faces.Append (Face (pi1, pi2, pi3, points, inputnum)); Point<3> p1 = points[pi1]; Point<3> p2 = points[pi2]; Point<3> p3 = points[pi3]; Vec<3> v1 = p2 - p1; Vec<3> v2 = p3 - p1; Vec<3> n = Cross (v1, v2); n.Normalize(); Plane pl (p1, n); // int inverse; // int identicto = -1; // for (int i = 0; i < planes.Size(); i++) // if (pl.IsIdentic (*planes[i], inverse, 1e-9*max3(v1.Length(),v2.Length(),Dist(p2,p3)))) // { // if (!inverse) // identicto = i; // } // // cout << "is identic = " << identicto << endl; // identicto = -1; // changed April 10, JS // if (identicto != -1) // faces.Last().planenr = identicto; // else { planes.Append (new Plane (p1, n)); surfaceactive.Append (1); surfaceids.Append (0); faces.Last().planenr = planes.Size()-1; } // (*testout) << "is plane nr " << faces.Last().planenr << endl; return faces.Size(); } int Polyhedra :: FaceBoxIntersection (int fnr, const BoxSphere<3> & box) const { /* (*testout) << "check face box intersection, fnr = " << fnr << endl; (*testout) << "box = " << box << endl; (*testout) << "face-box = " << faces[fnr].bbox << endl; */ if (!faces[fnr].bbox.Intersect (box)) return 0; const Point<3> & p1 = points[faces[fnr].pnums[0]]; const Point<3> & p2 = points[faces[fnr].pnums[1]]; const Point<3> & p3 = points[faces[fnr].pnums[2]]; double dist2 = MinDistTP2 (p1, p2, p3, box.Center()); /* (*testout) << "p1 = " << p1 << endl; (*testout) << "p2 = " << p2 << endl; (*testout) << "p3 = " << p3 << endl; (*testout) << "box.Center() = " << box.Center() << endl; (*testout) << "center = " << box.Center() << endl; (*testout) << "dist2 = " << dist2 << endl; (*testout) << "diam = " << box.Diam() << endl; */ if (dist2 < sqr (box.Diam()/2)) { // (*testout) << "intersect" << endl; return 1; } return 0; } void Polyhedra :: GetPolySurfs(Array < Array * > & polysurfs) { int maxnum = -1; for(int i = 0; i maxnum) maxnum = faces[i].inputnr; } polysurfs.SetSize(maxnum+1); for(int i=0; i; for(int i = 0; iAppend(faces[i].planenr); } void Polyhedra::CalcSpecialPoints (Array > & pts) const { for (int i = 0; i < points.Size(); i++) pts.Append (points[i]); } void Polyhedra :: AnalyzeSpecialPoint (const Point<3> & /* pt */, Array > & /* specpts */) const { ; } Vec<3> Polyhedra :: SpecialPointTangentialVector (const Point<3> & p, int s1, int s2) const { const double eps = 1e-10*poly_bbox.Diam(); for (int fi1 = 0; fi1 < faces.Size(); fi1++) for (int fi2 = 0; fi2 < faces.Size(); fi2++) { int si1 = faces[fi1].planenr; int si2 = faces[fi2].planenr; if (surfaceids[si1] != s1 || surfaceids[si2] != s2) continue; //(*testout) << "check pair fi1/fi2 " << fi1 << "/" << fi2 << endl; Vec<3> n1 = GetSurface(si1) . GetNormalVector (p); Vec<3> n2 = GetSurface(si2) . GetNormalVector (p); Vec<3> t = Cross (n1, n2); //(*testout) << "t = " << t << endl; /* int samepts = 0; for (int j = 0; j < 3; j++) for (int k = 0; k < 3; k++) if (Dist(points[faces[fi1].pnums[j]], points[faces[fi2].pnums[k]]) < eps) samepts++; if (samepts < 2) continue; */ bool shareedge = false; for(int j = 0; !shareedge && j < 3; j++) { Vec<3> v1 = points[faces[fi1].pnums[(j+1)%3]] - points[faces[fi1].pnums[j]]; double smax = v1.Length(); v1 *= 1./smax; int pospos; if(fabs(v1(0)) > 0.5) pospos = 0; else if(fabs(v1(1)) > 0.5) pospos = 1; else pospos = 2; double sp = (p(pospos) - points[faces[fi1].pnums[j]](pospos)) / v1(pospos); if(sp < -eps || sp > smax+eps) continue; for (int k = 0; !shareedge && k < 3; k ++) { Vec<3> v2 = points[faces[fi2].pnums[(k+1)%3]] - points[faces[fi2].pnums[k]]; v2.Normalize(); if(v2 * v1 > 0) v2 -= v1; else v2 += v1; //(*testout) << "v2.Length2() " << v2.Length2() << endl; if(v2.Length2() > 1e-18) continue; double sa,sb; sa = (points[faces[fi2].pnums[k]](pospos) - points[faces[fi1].pnums[j]](pospos)) / v1(pospos); sb = (points[faces[fi2].pnums[(k+1)%3]](pospos) - points[faces[fi1].pnums[j]](pospos)) / v1(pospos); if(Dist(points[faces[fi1].pnums[j]] + sa*v1, points[faces[fi2].pnums[k]]) > eps) continue; if(sa > sb) { double aux = sa; sa = sb; sb = aux; } //testout->precision(20); //(*testout) << "sa " << sa << " sb " << sb << " smax " << smax << " sp " << sp << " v1 " << v1 << endl; //testout->precision(8); shareedge = (sa < -eps && sb > eps) || (sa < smax-eps && sb > smax+eps) || (sa > -eps && sb < smax+eps); if(!shareedge) continue; sa = max2(sa,0.); sb = min2(sb,smax); if(sp < sa+eps) shareedge = (t * v1 > 0); else if (sp > sb-eps) shareedge = (t * v1 < 0); } } if (!shareedge) continue; t.Normalize(); return t; } return Vec<3> (0,0,0); } }