EVOLUTION-MANAGER

Edit File: stere.cpp

#define PJ_LIB__ #include <errno.h> #include "proj.h" #include "proj_internal.h" #include <math.h> PROJ_HEAD(stere, "Stereographic") "\n\tAzi, Sph&Ell\n\tlat_ts="; PROJ_HEAD(ups, "Universal Polar Stereographic") "\n\tAzi, Sph&Ell\n\tsouth"; namespace { // anonymous namespace enum Mode { S_POLE = 0, N_POLE = 1, OBLIQ = 2, EQUIT = 3 }; } // anonymous namespace namespace { // anonymous namespace struct pj_opaque { double phits; double sinX1; double cosX1; double akm1; enum Mode mode; }; } // anonymous namespace #define sinph0 static_cast<struct pj_opaque*>(P->opaque)->sinX1 #define cosph0 static_cast<struct pj_opaque*>(P->opaque)->cosX1 #define EPS10 1.e-10 #define TOL 1.e-8 #define NITER 8 #define CONV 1.e-10 static double ssfn_ (double phit, double sinphi, double eccen) { sinphi *= eccen; return (tan (.5 * (M_HALFPI + phit)) * pow ((1. - sinphi) / (1. + sinphi), .5 * eccen)); } static PJ_XY stere_e_forward (PJ_LP lp, PJ *P) { /* Ellipsoidal, forward */ PJ_XY xy = {0.0,0.0}; struct pj_opaque *Q = static_cast<struct pj_opaque*>(P->opaque); double coslam, sinlam, sinX = 0.0, cosX = 0.0, X, A = 0.0, sinphi; coslam = cos (lp.lam); sinlam = sin (lp.lam); sinphi = sin (lp.phi); if (Q->mode == OBLIQ || Q->mode == EQUIT) { sinX = sin (X = 2. * atan(ssfn_(lp.phi, sinphi, P->e)) - M_HALFPI); cosX = cos (X); } switch (Q->mode) { case OBLIQ: { const double denom = Q->cosX1 * (1. + Q->sinX1 * sinX + Q->cosX1 * cosX * coslam); if( denom == 0 ) { proj_errno_set(P, PJD_ERR_TOLERANCE_CONDITION); return proj_coord_error().xy; } A = Q->akm1 / denom; xy.y = A * (Q->cosX1 * sinX - Q->sinX1 * cosX * coslam); xy.x = A * cosX; break; } case EQUIT: /* avoid zero division */ if (1. + cosX * coslam == 0.0) { xy.y = HUGE_VAL; } else { A = Q->akm1 / (1. + cosX * coslam); xy.y = A * sinX; } xy.x = A * cosX; break; case S_POLE: lp.phi = -lp.phi; coslam = - coslam; sinphi = -sinphi; /*-fallthrough*/ case N_POLE: xy.x = Q->akm1 * pj_tsfn (lp.phi, sinphi, P->e); xy.y = - xy.x * coslam; break; } xy.x = xy.x * sinlam; return xy; } static PJ_XY stere_s_forward (PJ_LP lp, PJ *P) { /* Spheroidal, forward */ PJ_XY xy = {0.0,0.0}; struct pj_opaque *Q = static_cast<struct pj_opaque*>(P->opaque); double sinphi, cosphi, coslam, sinlam; sinphi = sin(lp.phi); cosphi = cos(lp.phi); coslam = cos(lp.lam); sinlam = sin(lp.lam); switch (Q->mode) { case EQUIT: xy.y = 1. + cosphi * coslam; goto oblcon; case OBLIQ: xy.y = 1. + sinph0 * sinphi + cosph0 * cosphi * coslam; oblcon: if (xy.y <= EPS10) { proj_errno_set(P, PJD_ERR_TOLERANCE_CONDITION); return xy; } xy.x = (xy.y = Q->akm1 / xy.y) * cosphi * sinlam; xy.y *= (Q->mode == EQUIT) ? sinphi : cosph0 * sinphi - sinph0 * cosphi * coslam; break; case N_POLE: coslam = - coslam; lp.phi = - lp.phi; /*-fallthrough*/ case S_POLE: if (fabs (lp.phi - M_HALFPI) < TOL) { proj_errno_set(P, PJD_ERR_TOLERANCE_CONDITION); return xy; } xy.x = sinlam * ( xy.y = Q->akm1 * tan (M_FORTPI + .5 * lp.phi) ); xy.y *= coslam; break; } return xy; } static PJ_LP stere_e_inverse (PJ_XY xy, PJ *P) { /* Ellipsoidal, inverse */ PJ_LP lp = {0.0,0.0}; struct pj_opaque *Q = static_cast<struct pj_opaque*>(P->opaque); double cosphi, sinphi, tp=0.0, phi_l=0.0, rho, halfe=0.0, halfpi=0.0; rho = hypot (xy.x, xy.y); switch (Q->mode) { case OBLIQ: case EQUIT: cosphi = cos ( tp = 2. * atan2 (rho * Q->cosX1 , Q->akm1) ); sinphi = sin (tp); if ( rho == 0.0 ) phi_l = asin (cosphi * Q->sinX1); else phi_l = asin (cosphi * Q->sinX1 + (xy.y * sinphi * Q->cosX1 / rho)); tp = tan (.5 * (M_HALFPI + phi_l)); xy.x *= sinphi; xy.y = rho * Q->cosX1 * cosphi - xy.y * Q->sinX1* sinphi; halfpi = M_HALFPI; halfe = .5 * P->e; break; case N_POLE: xy.y = -xy.y; /*-fallthrough*/ case S_POLE: phi_l = M_HALFPI - 2. * atan (tp = - rho / Q->akm1); halfpi = -M_HALFPI; halfe = -.5 * P->e; break; } for (int i = NITER; i > 0; --i) { sinphi = P->e * sin(phi_l); lp.phi = 2. * atan (tp * pow ((1.+sinphi)/(1.-sinphi), halfe)) - halfpi; if (fabs (phi_l - lp.phi) < CONV) { if (Q->mode == S_POLE) lp.phi = -lp.phi; lp.lam = (xy.x == 0. && xy.y == 0.) ? 0. : atan2 (xy.x, xy.y); return lp; } phi_l = lp.phi; } proj_errno_set(P, PJD_ERR_TOLERANCE_CONDITION); return lp; } static PJ_LP stere_s_inverse (PJ_XY xy, PJ *P) { /* Spheroidal, inverse */ PJ_LP lp = {0.0,0.0}; struct pj_opaque *Q = static_cast<struct pj_opaque*>(P->opaque); double c, rh, sinc, cosc; sinc = sin (c = 2. * atan ((rh = hypot (xy.x, xy.y)) / Q->akm1)); cosc = cos (c); lp.lam = 0.; switch (Q->mode) { case EQUIT: if (fabs (rh) <= EPS10) lp.phi = 0.; else lp.phi = asin (xy.y * sinc / rh); if (cosc != 0. || xy.x != 0.) lp.lam = atan2 (xy.x * sinc, cosc * rh); break; case OBLIQ: if (fabs (rh) <= EPS10) lp.phi = P->phi0; else lp.phi = asin (cosc * sinph0 + xy.y * sinc * cosph0 / rh); if ((c = cosc - sinph0 * sin (lp.phi)) != 0. || xy.x != 0.) lp.lam = atan2 (xy.x * sinc * cosph0, c * rh); break; case N_POLE: xy.y = -xy.y; /*-fallthrough*/ case S_POLE: if (fabs (rh) <= EPS10) lp.phi = P->phi0; else lp.phi = asin (Q->mode == S_POLE ? - cosc : cosc); lp.lam = (xy.x == 0. && xy.y == 0.) ? 0. : atan2 (xy.x, xy.y); break; } return lp; } static PJ *setup(PJ *P) { /* general initialization */ double t; struct pj_opaque *Q = static_cast<struct pj_opaque*>(P->opaque); if (fabs ((t = fabs (P->phi0)) - M_HALFPI) < EPS10) Q->mode = P->phi0 < 0. ? S_POLE : N_POLE; else Q->mode = t > EPS10 ? OBLIQ : EQUIT; Q->phits = fabs (Q->phits); if (P->es != 0.0) { double X; switch (Q->mode) { case N_POLE: case S_POLE: if (fabs (Q->phits - M_HALFPI) < EPS10) Q->akm1 = 2. * P->k0 / sqrt (pow (1+P->e,1+P->e) * pow (1-P->e,1-P->e)); else { Q->akm1 = cos (Q->phits) / pj_tsfn (Q->phits, t = sin (Q->phits), P->e); t *= P->e; Q->akm1 /= sqrt(1. - t * t); } break; case EQUIT: case OBLIQ: t = sin (P->phi0); X = 2. * atan (ssfn_(P->phi0, t, P->e)) - M_HALFPI; t *= P->e; Q->akm1 = 2. * P->k0 * cos (P->phi0) / sqrt(1. - t * t); Q->sinX1 = sin (X); Q->cosX1 = cos (X); break; } P->inv = stere_e_inverse; P->fwd = stere_e_forward; } else { switch (Q->mode) { case OBLIQ: sinph0 = sin (P->phi0); cosph0 = cos (P->phi0); /*-fallthrough*/ case EQUIT: Q->akm1 = 2. * P->k0; break; case S_POLE: case N_POLE: Q->akm1 = fabs (Q->phits - M_HALFPI) >= EPS10 ? cos (Q->phits) / tan (M_FORTPI - .5 * Q->phits) : 2. * P->k0 ; break; } P->inv = stere_s_inverse; P->fwd = stere_s_forward; } return P; } PJ *PROJECTION(stere) { struct pj_opaque *Q = static_cast<struct pj_opaque*>(pj_calloc (1, sizeof (struct pj_opaque))); if (nullptr==Q) return pj_default_destructor (P, ENOMEM); P->opaque = Q; Q->phits = pj_param (P->ctx, P->params, "tlat_ts").i ? pj_param (P->ctx, P->params, "rlat_ts").f : M_HALFPI; return setup(P); } PJ *PROJECTION(ups) { struct pj_opaque *Q = static_cast<struct pj_opaque*>(pj_calloc (1, sizeof (struct pj_opaque))); if (nullptr==Q) return pj_default_destructor (P, ENOMEM); P->opaque = Q; /* International Ellipsoid */ P->phi0 = pj_param(P->ctx, P->params, "bsouth").i ? - M_HALFPI: M_HALFPI; if (P->es == 0.0) { proj_errno_set(P, PJD_ERR_ELLIPSOID_USE_REQUIRED); return pj_default_destructor (P, ENOMEM); } P->k0 = .994; P->x0 = 2000000.; P->y0 = 2000000.; Q->phits = M_HALFPI; P->lam0 = 0.; return setup(P); }