#include #include #include #include namespace netgen { ostream & operator<<(ostream & s, const Point3d & p) { return s << "(" << p.x[0] << ", " << p.x[1] << ", " << p.x[2] << ")"; } ostream & operator<<(ostream & s, const Vec3d & v) { return s << "(" << v.x[0] << ", " << v.x[1] << ", " << v.x[2] << ")"; } double Angle (const Vec3d & v1, const Vec3d & v2) { double co = (v1 * v2) / (v1.Length() * v2.Length()); if (co > 1) co = 1; if (co < -1) co = -1; return acos ( co ); } void Vec3d :: GetNormal (Vec3d & n) const { if (fabs (X()) > fabs (Z())) { n.X() = -Y(); n.Y() = X(); n.Z() = 0; } else { n.X() = 0; n.Y() = Z(); n.Z() = -Y(); } double len = n.Length(); if (len == 0) { n.X() = 1; n.Y() = n.Z() = 0; } else n /= len; } /* ostream & operator<<(ostream & s, const ROTDenseMatrix3D & r) { return s << "{ (" << r.txx << ", " << r.txy << ", " << r.txz << ") , (" << r.tyx << ", " << r.tyy << ", " << r.tyz << ") , (" << r.tzx << ", " << r.tzy << ", " << r.tzz << ") }"; } */ /* Vec3d operator- (const Point3d & p1, const Point3d & p2) { return Vec3d (p1.X() - p2.X(), p1.Y() - p2.Y(),p1.Z() - p2.Z()); } Point3d operator- (const Point3d & p1, const Vec3d & v) { return Point3d (p1.X() - v.X(), p1.Y() - v.Y(),p1.Z() - v.Z()); } Point3d operator+ (const Point3d & p1, const Vec3d & v) { return Point3d (p1.X() + v.X(), p1.Y() + v.Y(),p1.Z() + v.Z()); } Vec3d operator- (const Vec3d & v1, const Vec3d & v2) { return Vec3d (v1.X() - v2.X(), v1.Y() - v2.Y(),v1.Z() - v2.Z()); } Vec3d operator+ (const Vec3d & v1, const Vec3d & v2) { return Vec3d (v1.X() + v2.X(), v1.Y() + v2.Y(),v1.Z() + v2.Z()); } Vec3d operator* (double scal, const Vec3d & v) { return Vec3d (scal * v.X(), scal * v.Y(), scal * v.Z()); } */ /* double operator* (const Vec3d & v1, const Vec3d & v2) { return v1.X() * v2.X() + v1.Y() * v2.Y() + v1.Z() * v2.Z(); } double Cross (const Vec3d & v1, const Vec3d & v2) { return v1.X() * v2.Y() - v1.Y() * v2.X(); } */ /* void ROTDenseMatrix3D :: CalcRotMat(double ag, double bg, double lg, double size2, Vec3d r) { size = size2; txx=size * ( cos(bg) * cos(lg) ); txy=size * ( cos(bg) * sin(lg) ); txz=size * (-sin(bg) ); tyx=size * ( sin(ag) * sin(bg) * cos(lg) - cos(ag) * sin(lg) ); tyy=size * ( sin(ag) * sin(bg) * sin(lg) + cos(ag) * cos(lg) ); tyz=size * ( sin(ag) * cos(bg) ); tzx=size * ( cos(ag) * sin(bg) * cos(lg) + sin(ag) * sin(lg) ); tzy=size * ( cos(ag) * sin(bg) * sin(lg) - sin(ag) * cos(lg) ); tzz=size * ( cos(ag) * cos(bg) ); deltaR=r; } ROTDenseMatrix3D :: ROTDenseMatrix3D(double ag, double bg, double lg, double size2, Vec3d r) {CalcRotMat(ag, bg, lg, size2, r); } ROTDenseMatrix3D :: ROTDenseMatrix3D(Vec3d rot2) { Vec3d r2(0,0,0); CalcRotMat(rot2.X(), rot2.Y(), rot2.Z(), 1, r2); } ROTDenseMatrix3D ROTDenseMatrix3D :: INV() { ROTDenseMatrix3D rinv(txx/sqr(size),tyx/sqr(size),tzx/sqr(size), txy/sqr(size),tyy/sqr(size),tzy/sqr(size), txz/sqr(size),tyz/sqr(size),tzz/sqr(size), 1/size,deltaR); return rinv; } Vec3d operator* (const ROTDenseMatrix3D & r, const Vec3d & v) { return Vec3d (r.XX() * v.X() + r.XY() * v.Y() + r.XZ() * v.Z(), r.YX() * v.X() + r.YY() * v.Y() + r.YZ() * v.Z(), r.ZX() * v.X() + r.ZY() * v.Y() + r.ZZ() * v.Z() ); } Point3d operator* (const ROTDenseMatrix3D & r, const Point3d & p) { return Point3d (r.XX() * p.X() + r.XY() * p.Y() + r.XZ() * p.Z(), r.YX() * p.X() + r.YY() * p.Y() + r.YZ() * p.Z(), r.ZX() * p.X() + r.ZY() * p.Y() + r.ZZ() * p.Z() ); } */ Box3d :: Box3d ( double aminx, double amaxx, double aminy, double amaxy, double aminz, double amaxz ) { minx[0] = aminx; maxx[0] = amaxx; minx[1] = aminy; maxx[1] = amaxy; minx[2] = aminz; maxx[2] = amaxz; } Box3d :: Box3d ( const Box3d & b2 ) { for (int i = 0; i < 3; i++) { minx[i] = b2.minx[i]; maxx[i] = b2.maxx[i]; } } Box3d :: Box3d ( const Box<3> & b2 ) { for (int i = 0; i < 3; i++) { minx[i] = b2.PMin()(i); maxx[i] = b2.PMax()(i); } } /* int Box3d :: Intersect (const Box3d & box2) const { int i; for (i = 0; i <= 2; i++) if (minx[i] > box2.maxx[i] || maxx[i] < box2.minx[i]) return 0; return 1; } */ /* void Box3d :: SetPoint (const Point3d & p) { minx[0] = maxx[0] = p.X(); minx[1] = maxx[1] = p.Y(); minx[2] = maxx[2] = p.Z(); } void Box3d :: AddPoint (const Point3d & p) { if (p.X() < minx[0]) minx[0] = p.X(); if (p.X() > maxx[0]) maxx[0] = p.X(); if (p.Y() < minx[1]) minx[1] = p.Y(); if (p.Y() > maxx[1]) maxx[1] = p.Y(); if (p.Z() < minx[2]) minx[2] = p.Z(); if (p.Z() > maxx[2]) maxx[2] = p.Z(); } */ void Box3d :: GetPointNr (int i, Point3d & point) const { i--; point.X() = (i & 1) ? maxx[0] : minx[0]; point.Y() = (i & 2) ? maxx[1] : minx[1]; point.Z() = (i & 4) ? maxx[2] : minx[2]; } void Box3d :: Increase (double d) { for (int i = 0; i <= 2; i++) { minx[i] -= d; maxx[i] += d; } } void Box3d :: IncreaseRel (double /* rel */) { for (int i = 0; i <= 2; i++) { double d = 0.5 * (maxx[i] - minx[i]); minx[i] -= d; maxx[i] += d; } } Box3d :: Box3d (const Point3d& p1, const Point3d& p2) { minx[0] = min2 (p1.X(), p2.X()); minx[1] = min2 (p1.Y(), p2.Y()); minx[2] = min2 (p1.Z(), p2.Z()); maxx[0] = max2 (p1.X(), p2.X()); maxx[1] = max2 (p1.Y(), p2.Y()); maxx[2] = max2 (p1.Z(), p2.Z()); } const Box3d& Box3d :: operator+=(const Box3d& b) { minx[0] = min2 (minx[0], b.minx[0]); minx[1] = min2 (minx[1], b.minx[1]); minx[2] = min2 (minx[2], b.minx[2]); maxx[0] = max2 (maxx[0], b.maxx[0]); maxx[1] = max2 (maxx[1], b.maxx[1]); maxx[2] = max2 (maxx[2], b.maxx[2]); return *this; } Point3d Box3d :: MaxCoords() const { return Point3d(maxx[0], maxx[1], maxx[2]); } Point3d Box3d :: MinCoords() const { return Point3d(minx[0], minx[1], minx[2]); } /* void Box3d :: CreateNegMinMaxBox() { minx[0] = MAXDOUBLE; minx[1] = MAXDOUBLE; minx[2] = MAXDOUBLE; maxx[0] = MINDOUBLE; maxx[1] = MINDOUBLE; maxx[2] = MINDOUBLE; } */ void Box3d :: WriteData(ofstream& fout) const { for(int i = 0; i < 3; i++) { fout << minx[i] << " " << maxx[i] << " "; } fout << "\n"; } void Box3d :: ReadData(ifstream& fin) { for(int i = 0; i < 3; i++) { fin >> minx[i]; fin >> maxx[i]; } } Box3dSphere :: Box3dSphere ( double aminx, double amaxx, double aminy, double amaxy, double aminz, double amaxz ) : Box3d (aminx, amaxx, aminy, amaxy, aminz, amaxz) { CalcDiamCenter (); } void Box3dSphere :: CalcDiamCenter () { diam = sqrt( sqr (maxx[0] - minx[0]) + sqr (maxx[1] - minx[1]) + sqr (maxx[2] - minx[2])); c.X() = 0.5 * (minx[0] + maxx[0]); c.Y() = 0.5 * (minx[1] + maxx[1]); c.Z() = 0.5 * (minx[2] + maxx[2]); inner = min2 ( min2 (maxx[0] - minx[0], maxx[1] - minx[1]), maxx[2] - minx[2]) / 2; } void Box3dSphere :: GetSubBox (int i, Box3dSphere & sbox) const { i--; if (i & 1) { sbox.minx[0] = c.X(); sbox.maxx[0] = maxx[0]; } else { sbox.minx[0] = minx[0]; sbox.maxx[0] = c.X(); } if (i & 2) { sbox.minx[1] = c.Y(); sbox.maxx[1] = maxx[1]; } else { sbox.minx[1] = minx[1]; sbox.maxx[1] = c.Y(); } if (i & 4) { sbox.minx[2] = c.Z(); sbox.maxx[2] = maxx[2]; } else { sbox.minx[2] = minx[2]; sbox.maxx[2] = c.Z(); } // sbox.CalcDiamCenter (); sbox.c.X() = 0.5 * (sbox.minx[0] + sbox.maxx[0]); sbox.c.Y() = 0.5 * (sbox.minx[1] + sbox.maxx[1]); sbox.c.Z() = 0.5 * (sbox.minx[2] + sbox.maxx[2]); sbox.diam = 0.5 * diam; sbox.inner = 0.5 * inner; } /* double Determinant (const Vec3d & col1, const Vec3d & col2, const Vec3d & col3) { return col1.x[0] * ( col2.x[1] * col3.x[2] - col2.x[2] * col3.x[1]) + col1.x[1] * ( col2.x[2] * col3.x[0] - col2.x[0] * col3.x[2]) + col1.x[2] * ( col2.x[0] * col3.x[1] - col2.x[1] * col3.x[0]); } */ void Transpose (Vec3d & v1, Vec3d & v2, Vec3d & v3) { Swap (v1.Y(), v2.X()); Swap (v1.Z(), v3.X()); Swap (v2.Z(), v3.Y()); } int SolveLinearSystem (const Vec3d & col1, const Vec3d & col2, const Vec3d & col3, const Vec3d & rhs, Vec3d & sol) { // changed by MW double matrix[3][3]; double locrhs[3]; int retval = 0; for(int i=0; i<3; i++) { matrix[i][0] = col1.X(i+1); matrix[i][1] = col2.X(i+1); matrix[i][2] = col3.X(i+1); locrhs[i] = rhs.X(i+1); } for(int i=0; i<2; i++) { int pivot = i; double maxv = fabs(matrix[i][i]); for(int j=i+1; j<3; j++) if(fabs(matrix[j][i]) > maxv) { maxv = fabs(matrix[j][i]); pivot = j; } if(fabs(maxv) > 1e-40) { if(pivot != i) { swap(matrix[i][0],matrix[pivot][0]); swap(matrix[i][1],matrix[pivot][1]); swap(matrix[i][2],matrix[pivot][2]); swap(locrhs[i],locrhs[pivot]); } for(int j=i+1; j<3; j++) { double fac = matrix[j][i] / matrix[i][i]; for(int k=i+1; k<3; k++) matrix[j][k] -= fac*matrix[i][k]; locrhs[j] -= fac*locrhs[i]; } } else retval = 1; } if(fabs(matrix[2][2]) < 1e-40) retval = 1; if(retval != 0) return retval; for(int i=2; i>=0; i--) { double sum = locrhs[i]; for(int j=2; j>i; j--) sum -= matrix[i][j]*sol.X(j+1); sol.X(i+1) = sum/matrix[i][i]; } return 0; /* double det = Determinant (col1, col2, col3); if (fabs (det) < 1e-40) return 1; sol.X() = Determinant (rhs, col2, col3) / det; sol.Y() = Determinant (col1, rhs, col3) / det; sol.Z() = Determinant (col1, col2, rhs) / det; return 0; */ /* Vec3d cr; Cross (col1, col2, cr); double det = cr * col3; if (fabs (det) < 1e-40) return 1; if (fabs(cr.Z()) > 1e-12) { // solve for 3. component sol.Z() = (cr * rhs) / det; // 2x2 system for 1. and 2. component double res1 = rhs.X() - sol.Z() * col3.X(); double res2 = rhs.Y() - sol.Z() * col3.Y(); sol.X() = (col2.Y() * res1 - col2.X() * res2) / cr.Z(); sol.Y() = (col1.X() * res2 - col1.Y() * res1) / cr.Z(); } else { det = Determinant (col1, col2, col3); if (fabs (det) < 1e-40) return 1; sol.X() = Determinant (rhs, col2, col3) / det; sol.Y() = Determinant (col1, rhs, col3) / det; sol.Z() = Determinant (col1, col2, rhs) / det; } return 0; */ } int SolveLinearSystemLS (const Vec3d & col1, const Vec3d & col2, const Vec2d & rhs, Vec3d & sol) { double a11 = col1 * col1; double a12 = col1 * col2; double a22 = col2 * col2; double det = a11 * a22 - a12 * a12; if (det*det <= 1e-24 * a11 * a22) { sol = Vec3d (0, 0, 0); return 1; } Vec2d invrhs; invrhs.X() = ( a22 * rhs.X() - a12 * rhs.Y()) / det; invrhs.Y() = (-a12 * rhs.X() + a11 * rhs.Y()) / det; sol.X() = invrhs.X() * col1.X() + invrhs.Y() * col2.X(); sol.Y() = invrhs.X() * col1.Y() + invrhs.Y() * col2.Y(); sol.Z() = invrhs.X() * col1.Z() + invrhs.Y() * col2.Z(); return 0; /* Vec3d inv1, inv2; int err = PseudoInverse (col1, col2, inv1, inv2); sol = rhs.X() * inv1 + rhs.Y() * inv2; return err; */ } int SolveLinearSystemLS2 (const Vec3d & col1, const Vec3d & col2, const Vec2d & rhs, Vec3d & sol, double & x, double & y) { double a11 = col1 * col1; double a12 = col1 * col2; double a22 = col2 * col2; double det = a11 * a22 - a12 * a12; if (fabs (det) <= 1e-12 * col1.Length() * col2.Length() || col1.Length2() == 0 || col2.Length2() == 0) { sol = Vec3d (0, 0, 0); x = 0; y = 0; return 1; } Vec2d invrhs; invrhs.X() = ( a22 * rhs.X() - a12 * rhs.Y()) / det; invrhs.Y() = (-a12 * rhs.X() + a11 * rhs.Y()) / det; sol.X() = invrhs.X() * col1.X() + invrhs.Y() * col2.X(); sol.Y() = invrhs.X() * col1.Y() + invrhs.Y() * col2.Y(); sol.Z() = invrhs.X() * col1.Z() + invrhs.Y() * col2.Z(); x = invrhs.X(); y = invrhs.Y(); return 0; /* Vec3d inv1, inv2; int err = PseudoInverse (col1, col2, inv1, inv2); sol = rhs.X() * inv1 + rhs.Y() * inv2; return err; */ } int PseudoInverse (const Vec3d & col1, const Vec3d & col2, Vec3d & inv1, Vec3d & inv2) { double a11 = col1 * col1; double a12 = col1 * col2; double a22 = col2 * col2; double det = a11 * a22 - a12 * a12; if (fabs (det) < 1e-12 * col1.Length() * col2.Length()) { inv1 = Vec3d (0, 0, 0); inv2 = Vec3d (0, 0, 0); return 1; } double ia11 = a22 / det; double ia12 = -a12 / det; double ia22 = a11 / det; inv1 = ia11 * col1 + ia12 * col2; inv2 = ia12 * col1 + ia22 * col2; return 0; } QuadraticFunction3d :: QuadraticFunction3d (const Point3d & p, const Vec3d & v) { Vec3d hv(v); hv /= (hv.Length() + 1e-12); Vec3d t1, t2; hv.GetNormal (t1); Cross (hv, t1, t2); double t1p = t1.X() * p.X() + t1.Y() * p.Y() + t1.Z() * p.Z(); double t2p = t2.X() * p.X() + t2.Y() * p.Y() + t2.Z() * p.Z(); c0 = sqr (t1p) + sqr (t2p); cx = -2 * (t1p * t1.X() + t2p * t2.X()); cy = -2 * (t1p * t1.Y() + t2p * t2.Y()); cz = -2 * (t1p * t1.Z() + t2p * t2.Z()); cxx = t1.X() * t1.X() + t2.X() * t2.X(); cyy = t1.Y() * t1.Y() + t2.Y() * t2.Y(); czz = t1.Z() * t1.Z() + t2.Z() * t2.Z(); cxy = 2 * t1.X() * t1.Y() + 2 * t2.X() * t2.Y(); cxz = 2 * t1.X() * t1.Z() + 2 * t2.X() * t2.Z(); cyz = 2 * t1.Y() * t1.Z() + 2 * t2.Y() * t2.Z(); /* (*testout) << "c0 = " << c0 << " clin = " << cx << " " << cy << " " << cz << " cq = " << cxx << " " << cyy << " " << czz << cxy << " " << cyz << " " << cyz << endl; */ } // QuadraticFunction3d gqf (Point3d (0,0,0), Vec3d (1, 0, 0)); void referencetransform :: Set (const Point3d & p1, const Point3d & p2, const Point3d & p3, double ah) { ex = p2 - p1; ex /= ex.Length(); ey = p3 - p1; ey -= (ex * ey) * ex; ey /= ey.Length(); ez = Cross (ex, ey); rp = p1; h = ah; exh = ah * ex; eyh = ah * ey; ezh = ah * ez; ah = 1 / ah; ex_h = ah * ex; ey_h = ah * ey; ez_h = ah * ez; } void referencetransform :: ToPlain (const Point3d & p, Point3d & pp) const { Vec3d v; v = p - rp; pp.X() = (ex_h * v); pp.Y() = (ey_h * v); pp.Z() = (ez_h * v); } void referencetransform :: ToPlain (const Array & p, Array & pp) const { Vec3d v; int i; pp.SetSize (p.Size()); for (i = 1; i <= p.Size(); i++) { v = p.Get(i) - rp; pp.Elem(i).X() = (ex_h * v); pp.Elem(i).Y() = (ey_h * v); pp.Elem(i).Z() = (ez_h * v); } } void referencetransform :: FromPlain (const Point3d & pp, Point3d & p) const { Vec3d v; // v = (h * pp.X()) * ex + (h * pp.Y()) * ey + (h * pp.Z()) * ez; // p = rp + v; v.X() = pp.X() * exh.X() + pp.Y() * eyh.X() + pp.Z() * ezh.X(); v.Y() = pp.X() * exh.Y() + pp.Y() * eyh.Y() + pp.Z() * ezh.Y(); v.Z() = pp.X() * exh.Z() + pp.Y() * eyh.Z() + pp.Z() * ezh.Z(); p.X() = rp.X() + v.X(); p.Y() = rp.Y() + v.Y(); p.Z() = rp.Z() + v.Z(); } }