#ifndef BOOST_GEOMETRY_PROJECTIONS_STERE_HPP #define BOOST_GEOMETRY_PROJECTIONS_STERE_HPP // Boost.Geometry - extensions-gis-projections (based on PROJ4) // This file is automatically generated. DO NOT EDIT. // Copyright (c) 2008-2015 Barend Gehrels, Amsterdam, the Netherlands. // This file was modified by Oracle on 2017, 2018. // Modifications copyright (c) 2017-2018, Oracle and/or its affiliates. // Contributed and/or modified by Adam Wulkiewicz, on behalf of Oracle. // Use, modification and distribution is subject to the Boost Software License, // Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // This file is converted from PROJ4, http://trac.osgeo.org/proj // PROJ4 is originally written by Gerald Evenden (then of the USGS) // PROJ4 is maintained by Frank Warmerdam // PROJ4 is converted to Boost.Geometry by Barend Gehrels // Last updated version of proj: 4.9.1 // Original copyright notice: // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the "Software"), // to deal in the Software without restriction, including without limitation // the rights to use, copy, modify, merge, publish, distribute, sublicense, // and/or sell copies of the Software, and to permit persons to whom the // Software is furnished to do so, subject to the following conditions: // The above copyright notice and this permission notice shall be included // in all copies or substantial portions of the Software. // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS // OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL // THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING // FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER // DEALINGS IN THE SOFTWARE. #include #include #include #include #include #include #include #include namespace boost { namespace geometry { namespace srs { namespace par4 { struct stere {}; struct ups {}; }} //namespace srs::par4 namespace projections { #ifndef DOXYGEN_NO_DETAIL namespace detail { namespace stere { static const double EPS10 = 1.e-10; static const double TOL = 1.e-8; static const int NITER = 8; static const double CONV = 1.e-10; static const int S_POLE = 0; static const int N_POLE = 1; static const int OBLIQ = 2; static const int EQUIT = 3; template struct par_stere { T phits; T sinX1; T cosX1; T akm1; int mode; }; template inline T ssfn_(T const& phit, T sinphi, T const& eccen) { sinphi *= eccen; return (tan (.5 * (geometry::math::half_pi() + phit)) * pow((1. - sinphi) / (1. + sinphi), .5 * eccen)); } // template class, using CRTP to implement forward/inverse template struct base_stere_ellipsoid : public base_t_fi, CalculationType, Parameters> { typedef CalculationType geographic_type; typedef CalculationType cartesian_type; par_stere m_proj_parm; inline base_stere_ellipsoid(const Parameters& par) : base_t_fi, CalculationType, Parameters>(*this, par) {} // FORWARD(e_forward) ellipsoid // Project coordinates from geographic (lon, lat) to cartesian (x, y) inline void fwd(geographic_type& lp_lon, geographic_type& lp_lat, cartesian_type& xy_x, cartesian_type& xy_y) const { static const CalculationType HALFPI = detail::HALFPI(); CalculationType coslam, sinlam, sinX=0.0, cosX=0.0, X, A, sinphi; coslam = cos(lp_lon); sinlam = sin(lp_lon); sinphi = sin(lp_lat); if (this->m_proj_parm.mode == OBLIQ || this->m_proj_parm.mode == EQUIT) { sinX = sin(X = 2. * atan(ssfn_(lp_lat, sinphi, this->m_par.e)) - HALFPI); cosX = cos(X); } switch (this->m_proj_parm.mode) { case OBLIQ: A = this->m_proj_parm.akm1 / (this->m_proj_parm.cosX1 * (1. + this->m_proj_parm.sinX1 * sinX + this->m_proj_parm.cosX1 * cosX * coslam)); xy_y = A * (this->m_proj_parm.cosX1 * sinX - this->m_proj_parm.sinX1 * cosX * coslam); goto xmul; case EQUIT: A = this->m_proj_parm.akm1 / (1. + cosX * coslam); xy_y = A * sinX; xmul: xy_x = A * cosX; break; case S_POLE: lp_lat = -lp_lat; coslam = - coslam; sinphi = -sinphi; BOOST_FALLTHROUGH; case N_POLE: xy_x = this->m_proj_parm.akm1 * pj_tsfn(lp_lat, sinphi, this->m_par.e); xy_y = - xy_x * coslam; break; } xy_x = xy_x * sinlam; } // INVERSE(e_inverse) ellipsoid // Project coordinates from cartesian (x, y) to geographic (lon, lat) inline void inv(cartesian_type& xy_x, cartesian_type& xy_y, geographic_type& lp_lon, geographic_type& lp_lat) const { static const CalculationType HALFPI = detail::HALFPI(); CalculationType cosphi, sinphi, tp=0.0, phi_l=0.0, rho, halfe=0.0, halfpi=0.0; int i; rho = boost::math::hypot(xy_x, xy_y); switch (this->m_proj_parm.mode) { case OBLIQ: case EQUIT: cosphi = cos( tp = 2. * atan2(rho * this->m_proj_parm.cosX1 , this->m_proj_parm.akm1) ); sinphi = sin(tp); if( rho == 0.0 ) phi_l = asin(cosphi * this->m_proj_parm.sinX1); else phi_l = asin(cosphi * this->m_proj_parm.sinX1 + (xy_y * sinphi * this->m_proj_parm.cosX1 / rho)); tp = tan(.5 * (HALFPI + phi_l)); xy_x *= sinphi; xy_y = rho * this->m_proj_parm.cosX1 * cosphi - xy_y * this->m_proj_parm.sinX1* sinphi; halfpi = HALFPI; halfe = .5 * this->m_par.e; break; case N_POLE: xy_y = -xy_y; BOOST_FALLTHROUGH; case S_POLE: phi_l = HALFPI - 2. * atan(tp = - rho / this->m_proj_parm.akm1); halfpi = -HALFPI; halfe = -.5 * this->m_par.e; break; } for (i = NITER; i--; phi_l = lp_lat) { sinphi = this->m_par.e * sin(phi_l); lp_lat = 2. * atan(tp * pow((1.+sinphi)/(1.-sinphi), halfe)) - halfpi; if (fabs(phi_l - lp_lat) < CONV) { if (this->m_proj_parm.mode == S_POLE) lp_lat = -lp_lat; lp_lon = (xy_x == 0. && xy_y == 0.) ? 0. : atan2(xy_x, xy_y); return; } } BOOST_THROW_EXCEPTION( projection_exception(-20) ); } static inline std::string get_name() { return "stere_ellipsoid"; } }; // template class, using CRTP to implement forward/inverse template struct base_stere_spheroid : public base_t_fi, CalculationType, Parameters> { typedef CalculationType geographic_type; typedef CalculationType cartesian_type; par_stere m_proj_parm; inline base_stere_spheroid(const Parameters& par) : base_t_fi, CalculationType, Parameters>(*this, par) {} // FORWARD(s_forward) spheroid // Project coordinates from geographic (lon, lat) to cartesian (x, y) inline void fwd(geographic_type& lp_lon, geographic_type& lp_lat, cartesian_type& xy_x, cartesian_type& xy_y) const { static const CalculationType FORTPI = detail::FORTPI(); static const CalculationType HALFPI = detail::HALFPI(); CalculationType sinphi, cosphi, coslam, sinlam; sinphi = sin(lp_lat); cosphi = cos(lp_lat); coslam = cos(lp_lon); sinlam = sin(lp_lon); switch (this->m_proj_parm.mode) { case EQUIT: xy_y = 1. + cosphi * coslam; goto oblcon; case OBLIQ: xy_y = 1. + this->m_proj_parm.sinX1 * sinphi + this->m_proj_parm.cosX1 * cosphi * coslam; oblcon: if (xy_y <= EPS10) BOOST_THROW_EXCEPTION( projection_exception(-20) ); xy_x = (xy_y = this->m_proj_parm.akm1 / xy_y) * cosphi * sinlam; xy_y *= (this->m_proj_parm.mode == EQUIT) ? sinphi : this->m_proj_parm.cosX1 * sinphi - this->m_proj_parm.sinX1 * cosphi * coslam; break; case N_POLE: coslam = - coslam; lp_lat = - lp_lat; BOOST_FALLTHROUGH; case S_POLE: if (fabs(lp_lat - HALFPI) < TOL) BOOST_THROW_EXCEPTION( projection_exception(-20) ); xy_x = sinlam * ( xy_y = this->m_proj_parm.akm1 * tan(FORTPI + .5 * lp_lat) ); xy_y *= coslam; break; } } // INVERSE(s_inverse) spheroid // Project coordinates from cartesian (x, y) to geographic (lon, lat) inline void inv(cartesian_type& xy_x, cartesian_type& xy_y, geographic_type& lp_lon, geographic_type& lp_lat) const { CalculationType c, rh, sinc, cosc; sinc = sin(c = 2. * atan((rh = boost::math::hypot(xy_x, xy_y)) / this->m_proj_parm.akm1)); cosc = cos(c); lp_lon = 0.; switch (this->m_proj_parm.mode) { case EQUIT: if (fabs(rh) <= EPS10) lp_lat = 0.; else lp_lat = asin(xy_y * sinc / rh); if (cosc != 0. || xy_x != 0.) lp_lon = atan2(xy_x * sinc, cosc * rh); break; case OBLIQ: if (fabs(rh) <= EPS10) lp_lat = this->m_par.phi0; else lp_lat = asin(cosc * this->m_proj_parm.sinX1 + xy_y * sinc * this->m_proj_parm.cosX1 / rh); if ((c = cosc - this->m_proj_parm.sinX1 * sin(lp_lat)) != 0. || xy_x != 0.) lp_lon = atan2(xy_x * sinc * this->m_proj_parm.cosX1, c * rh); break; case N_POLE: xy_y = -xy_y; BOOST_FALLTHROUGH; case S_POLE: if (fabs(rh) <= EPS10) lp_lat = this->m_par.phi0; else lp_lat = asin(this->m_proj_parm.mode == S_POLE ? - cosc : cosc); lp_lon = (xy_x == 0. && xy_y == 0.) ? 0. : atan2(xy_x, xy_y); break; } } static inline std::string get_name() { return "stere_spheroid"; } }; template inline void setup(Parameters& par, par_stere& proj_parm) /* general initialization */ { static const T FORTPI = detail::FORTPI(); static const T HALFPI = detail::HALFPI(); T t; if (fabs((t = fabs(par.phi0)) - HALFPI) < EPS10) proj_parm.mode = par.phi0 < 0. ? S_POLE : N_POLE; else proj_parm.mode = t > EPS10 ? OBLIQ : EQUIT; proj_parm.phits = fabs(proj_parm.phits); if (par.es != 0.0) { T X; switch (proj_parm.mode) { case N_POLE: case S_POLE: if (fabs(proj_parm.phits - HALFPI) < EPS10) proj_parm.akm1 = 2. * par.k0 / sqrt(pow(1+par.e,1+par.e)*pow(1-par.e,1-par.e)); else { proj_parm.akm1 = cos(proj_parm.phits) / pj_tsfn(proj_parm.phits, t = sin(proj_parm.phits), par.e); t *= par.e; proj_parm.akm1 /= sqrt(1. - t * t); } break; case EQUIT: //proj_parm.akm1 = 2. * par.k0; //break; case OBLIQ: t = sin(par.phi0); X = 2. * atan(ssfn_(par.phi0, t, par.e)) - HALFPI; t *= par.e; proj_parm.akm1 = 2. * par.k0 * cos(par.phi0) / sqrt(1. - t * t); proj_parm.sinX1 = sin(X); proj_parm.cosX1 = cos(X); break; } } else { switch (proj_parm.mode) { case OBLIQ: proj_parm.sinX1 = sin(par.phi0); proj_parm.cosX1 = cos(par.phi0); BOOST_FALLTHROUGH; case EQUIT: proj_parm.akm1 = 2. * par.k0; break; case S_POLE: case N_POLE: proj_parm.akm1 = fabs(proj_parm.phits - HALFPI) >= EPS10 ? cos(proj_parm.phits) / tan(FORTPI - .5 * proj_parm.phits) : 2. * par.k0 ; break; } } } // Stereographic template inline void setup_stere(Parameters& par, par_stere& proj_parm) { static const T HALFPI = detail::HALFPI(); proj_parm.phits = pj_param(par.params, "tlat_ts").i ? pj_param(par.params, "rlat_ts").f : HALFPI; setup(par, proj_parm); } // Universal Polar Stereographic template inline void setup_ups(Parameters& par, par_stere& proj_parm) { static const T HALFPI = detail::HALFPI(); /* International Ellipsoid */ par.phi0 = pj_param(par.params, "bsouth").i ? -HALFPI: HALFPI; if (!par.es) BOOST_THROW_EXCEPTION( projection_exception(-34) ); par.k0 = .994; par.x0 = 2000000.; par.y0 = 2000000.; proj_parm.phits = HALFPI; par.lam0 = 0.; setup(par, proj_parm); } }} // namespace detail::stere #endif // doxygen /*! \brief Stereographic projection \ingroup projections \tparam Geographic latlong point type \tparam Cartesian xy point type \tparam Parameters parameter type \par Projection characteristics - Azimuthal - Spheroid - Ellipsoid \par Projection parameters - lat_ts: Latitude of true scale (degrees) \par Example \image html ex_stere.gif */ template struct stere_ellipsoid : public detail::stere::base_stere_ellipsoid { inline stere_ellipsoid(const Parameters& par) : detail::stere::base_stere_ellipsoid(par) { detail::stere::setup_stere(this->m_par, this->m_proj_parm); } }; /*! \brief Stereographic projection \ingroup projections \tparam Geographic latlong point type \tparam Cartesian xy point type \tparam Parameters parameter type \par Projection characteristics - Azimuthal - Spheroid - Ellipsoid \par Projection parameters - lat_ts: Latitude of true scale (degrees) \par Example \image html ex_stere.gif */ template struct stere_spheroid : public detail::stere::base_stere_spheroid { inline stere_spheroid(const Parameters& par) : detail::stere::base_stere_spheroid(par) { detail::stere::setup_stere(this->m_par, this->m_proj_parm); } }; /*! \brief Universal Polar Stereographic projection \ingroup projections \tparam Geographic latlong point type \tparam Cartesian xy point type \tparam Parameters parameter type \par Projection characteristics - Azimuthal - Spheroid - Ellipsoid \par Projection parameters - south: Denotes southern hemisphere UTM zone (boolean) \par Example \image html ex_ups.gif */ template struct ups_ellipsoid : public detail::stere::base_stere_ellipsoid { inline ups_ellipsoid(const Parameters& par) : detail::stere::base_stere_ellipsoid(par) { detail::stere::setup_ups(this->m_par, this->m_proj_parm); } }; /*! \brief Universal Polar Stereographic projection \ingroup projections \tparam Geographic latlong point type \tparam Cartesian xy point type \tparam Parameters parameter type \par Projection characteristics - Azimuthal - Spheroid - Ellipsoid \par Projection parameters - south: Denotes southern hemisphere UTM zone (boolean) \par Example \image html ex_ups.gif */ template struct ups_spheroid : public detail::stere::base_stere_spheroid { inline ups_spheroid(const Parameters& par) : detail::stere::base_stere_spheroid(par) { detail::stere::setup_ups(this->m_par, this->m_proj_parm); } }; #ifndef DOXYGEN_NO_DETAIL namespace detail { // Static projection BOOST_GEOMETRY_PROJECTIONS_DETAIL_STATIC_PROJECTION(srs::par4::stere, stere_spheroid, stere_ellipsoid) BOOST_GEOMETRY_PROJECTIONS_DETAIL_STATIC_PROJECTION(srs::par4::ups, ups_spheroid, ups_ellipsoid) // Factory entry(s) template class stere_entry : public detail::factory_entry { public : virtual base_v* create_new(const Parameters& par) const { if (par.es) return new base_v_fi, CalculationType, Parameters>(par); else return new base_v_fi, CalculationType, Parameters>(par); } }; template class ups_entry : public detail::factory_entry { public : virtual base_v* create_new(const Parameters& par) const { if (par.es) return new base_v_fi, CalculationType, Parameters>(par); else return new base_v_fi, CalculationType, Parameters>(par); } }; template inline void stere_init(detail::base_factory& factory) { factory.add_to_factory("stere", new stere_entry); factory.add_to_factory("ups", new ups_entry); } } // namespace detail #endif // doxygen } // namespace projections }} // namespace boost::geometry #endif // BOOST_GEOMETRY_PROJECTIONS_STERE_HPP