// Boost.Geometry - gis-projections (based on PROJ4)
// Copyright (c) 2008-2015 Barend Gehrels, Amsterdam, the Netherlands.
// Copyright (c) 2023 Adam Wulkiewicz, Lodz, Poland.
// This file was modified by Oracle on 2017-2020.
// Modifications copyright (c) 2017-2020, 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: 5.0.0
// 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.
#ifndef BOOST_GEOMETRY_PROJECTIONS_OB_TRAN_HPP
#define BOOST_GEOMETRY_PROJECTIONS_OB_TRAN_HPP
#include <memory>
#include <type_traits>
#include <boost/geometry/core/static_assert.hpp>
#include <boost/geometry/srs/projections/impl/aasincos.hpp>
#include <boost/geometry/srs/projections/impl/base_static.hpp>
#include <boost/geometry/srs/projections/impl/base_dynamic.hpp>
#include <boost/geometry/srs/projections/impl/factory_entry.hpp>
#include <boost/geometry/srs/projections/impl/pj_ell_set.hpp>
#include <boost/geometry/srs/projections/impl/projects.hpp>
#include <boost/geometry/util/math.hpp>
namespace boost { namespace geometry
{
namespace projections
{
#ifndef DOXYGEN_NO_DETAIL
namespace detail {
// fwd declaration needed below
template <typename T>
inline detail::dynamic_wrapper_b<T, projections::parameters<T> >*
create_new(srs::detail::proj4_parameters const& params,
projections::parameters<T> const& parameters);
template <typename T>
inline detail::dynamic_wrapper_b<T, projections::parameters<T> >*
create_new(srs::dpar::parameters<T> const& params,
projections::parameters<T> const& parameters);
} // namespace detail
namespace detail { namespace ob_tran
{
static const double tolerance = 1e-10;
template <typename Parameters>
inline Parameters o_proj_parameters(srs::detail::proj4_parameters const& params,
Parameters const& par)
{
/* copy existing header into new */
Parameters pj = par;
/* get name of projection to be translated */
pj.id = pj_get_param_s(params, "o_proj");
if (pj.id.is_unknown())
BOOST_THROW_EXCEPTION( projection_exception(error_no_rotation_proj) );
/* avoid endless recursion */
if( pj.id.name == "ob_tran")
BOOST_THROW_EXCEPTION( projection_exception(error_failed_to_find_proj) );
// Commented out for consistency with Proj4 >= 5.0.0
/* force spherical earth */
//pj.one_es = pj.rone_es = 1.;
//pj.es = pj.e = 0.;
return pj;
}
template <typename T, typename Parameters>
inline Parameters o_proj_parameters(srs::dpar::parameters<T> const& params,
Parameters const& par)
{
/* copy existing header into new */
Parameters pj = par;
/* get name of projection to be translated */
typename srs::dpar::parameters<T>::const_iterator
it = pj_param_find(params, srs::dpar::o_proj);
if (it != params.end())
pj.id = static_cast<srs::dpar::value_proj>(it->template get_value<int>());
else
BOOST_THROW_EXCEPTION( projection_exception(error_no_rotation_proj) );
/* avoid endless recursion */
if( pj.id.id == srs::dpar::proj_ob_tran)
BOOST_THROW_EXCEPTION( projection_exception(error_failed_to_find_proj) );
// Commented out for consistency with Proj4 >= 5.0.0
/* force spherical earth */
//pj.one_es = pj.rone_es = 1.;
//pj.es = pj.e = 0.;
return pj;
}
template <typename ...Ps, typename Parameters>
inline Parameters o_proj_parameters(srs::spar::parameters<Ps...> const& /*params*/,
Parameters const& par)
{
/* copy existing header into new */
Parameters pj = par;
/* get name of projection to be translated */
typedef srs::spar::parameters<Ps...> params_type;
typedef typename geometry::tuples::find_if
<
params_type,
srs::spar::detail::is_param_t<srs::spar::o_proj>::pred
>::type o_proj_type;
static const bool is_found = geometry::tuples::is_found<o_proj_type>::value;
BOOST_GEOMETRY_STATIC_ASSERT((is_found),
"Rotation projection not specified.",
params_type);
typedef typename o_proj_type::type proj_type;
static const bool is_specialized = srs::spar::detail::proj_traits<proj_type>::is_specialized;
BOOST_GEOMETRY_STATIC_ASSERT((is_specialized),
"Rotation projection not specified.",
params_type);
pj.id = srs::spar::detail::proj_traits<proj_type>::id;
/* avoid endless recursion */
static const bool is_non_resursive = ! std::is_same<proj_type, srs::spar::proj_ob_tran>::value;
BOOST_GEOMETRY_STATIC_ASSERT((is_non_resursive),
"o_proj parameter can not be set to ob_tran projection.",
params_type);
// Commented out for consistency with Proj4 >= 5.0.0
/* force spherical earth */
//pj.one_es = pj.rone_es = 1.;
//pj.es = pj.e = 0.;
return pj;
}
// TODO: It's possible that the original Parameters could be used
// instead of a copy in link.
// But it's not possible with the current implementation of
// dynamic_wrapper_b always storing params
template <typename T, typename Parameters>
struct par_ob_tran
{
template <typename Params>
par_ob_tran(Params const& params, Parameters const& par)
: link(projections::detail::create_new(params, o_proj_parameters(params, par)))
{
if (! link.get())
BOOST_THROW_EXCEPTION( projection_exception(error_unknown_projection_id) );
}
inline void fwd(T const& lp_lon, T const& lp_lat, T& xy_x, T& xy_y) const
{
link->fwd(link->params(), lp_lon, lp_lat, xy_x, xy_y);
}
inline void inv(T const& xy_x, T const& xy_y, T& lp_lon, T& lp_lat) const
{
link->inv(link->params(), xy_x, xy_y, lp_lon, lp_lat);
}
std::shared_ptr<dynamic_wrapper_b<T, Parameters> > link;
T lamp;
T cphip, sphip;
};
template <typename StaticParameters, typename T, typename Parameters>
struct par_ob_tran_static
{
// this metafunction handles static error handling
typedef typename srs::spar::detail::pick_o_proj_tag
<
StaticParameters
>::type o_proj_tag;
/* avoid endless recursion */
static const bool is_o_proj_not_ob_tran = ! std::is_same<o_proj_tag, srs::spar::proj_ob_tran>::value;
BOOST_GEOMETRY_STATIC_ASSERT((is_o_proj_not_ob_tran),
"o_proj parameter can not be set to ob_tran projection.",
StaticParameters);
typedef typename projections::detail::static_projection_type
<
o_proj_tag,
// Commented out for consistency with Proj4 >= 5.0.0
//srs_sphere_tag, // force spherical
typename projections::detail::static_srs_tag<StaticParameters>::type,
StaticParameters,
T,
Parameters
>::type projection_type;
par_ob_tran_static(StaticParameters const& params, Parameters const& par)
: link(params, o_proj_parameters(params, par))
{}
inline void fwd(T const& lp_lon, T const& lp_lat, T& xy_x, T& xy_y) const
{
link.fwd(link.params(), lp_lon, lp_lat, xy_x, xy_y);
}
inline void inv(T const& xy_x, T const& xy_y, T& lp_lon, T& lp_lat) const
{
link.inv(link.params(), xy_x, xy_y, lp_lon, lp_lat);
}
projection_type link;
T lamp;
T cphip, sphip;
};
template <typename T, typename Par>
inline void o_forward(T lp_lon, T lp_lat, T& xy_x, T& xy_y, Par const& proj_parm)
{
T coslam, sinphi, cosphi;
coslam = cos(lp_lon);
sinphi = sin(lp_lat);
cosphi = cos(lp_lat);
lp_lon = adjlon(aatan2(cosphi * sin(lp_lon), proj_parm.sphip * cosphi * coslam +
proj_parm.cphip * sinphi) + proj_parm.lamp);
lp_lat = aasin(proj_parm.sphip * sinphi - proj_parm.cphip * cosphi * coslam);
proj_parm.fwd(lp_lon, lp_lat, xy_x, xy_y);
}
template <typename T, typename Par>
inline void o_inverse(T const& xy_x, T const& xy_y, T& lp_lon, T& lp_lat, Par const& proj_parm)
{
T coslam, sinphi, cosphi;
proj_parm.inv(xy_x, xy_y, lp_lon, lp_lat);
if (lp_lon != HUGE_VAL) {
coslam = cos(lp_lon -= proj_parm.lamp);
sinphi = sin(lp_lat);
cosphi = cos(lp_lat);
lp_lat = aasin(proj_parm.sphip * sinphi + proj_parm.cphip * cosphi * coslam);
lp_lon = aatan2(cosphi * sin(lp_lon), proj_parm.sphip * cosphi * coslam -
proj_parm.cphip * sinphi);
}
}
template <typename T, typename Par>
inline void t_forward(T lp_lon, T lp_lat, T& xy_x, T& xy_y, Par const& proj_parm)
{
T cosphi, coslam;
cosphi = cos(lp_lat);
coslam = cos(lp_lon);
lp_lon = adjlon(aatan2(cosphi * sin(lp_lon), sin(lp_lat)) + proj_parm.lamp);
lp_lat = aasin(- cosphi * coslam);
proj_parm.fwd(lp_lon, lp_lat, xy_x, xy_y);
}
template <typename T, typename Par>
inline void t_inverse(T const& xy_x, T const& xy_y, T& lp_lon, T& lp_lat, Par const& proj_parm)
{
T cosphi, t;
proj_parm.inv(xy_x, xy_y, lp_lon, lp_lat);
if (lp_lon != HUGE_VAL) {
cosphi = cos(lp_lat);
t = lp_lon - proj_parm.lamp;
lp_lon = aatan2(cosphi * sin(t), - sin(lp_lat));
lp_lat = aasin(cosphi * cos(t));
}
}
// General Oblique Transformation
template <typename T, typename Params, typename Parameters, typename ProjParameters>
inline T setup_ob_tran(Params const& params, Parameters & /*par*/, ProjParameters& proj_parm)
{
static const T half_pi = detail::half_pi<T>();
T phip, alpha;
// Commented out for consistency with Proj4 >= 5.0.0
//par.es = 0.; /* force to spherical */
// proj_parm.link should be created at this point
if (pj_param_r<srs::spar::o_alpha>(params, "o_alpha", srs::dpar::o_alpha, alpha)) {
T lamc, phic;
lamc = pj_get_param_r<T, srs::spar::o_lon_c>(params, "o_lon_c", srs::dpar::o_lon_c);
phic = pj_get_param_r<T, srs::spar::o_lon_c>(params, "o_lat_c", srs::dpar::o_lat_c);
//alpha = pj_get_param_r(par.params, "o_alpha");
if (fabs(fabs(phic) - half_pi) <= tolerance)
BOOST_THROW_EXCEPTION( projection_exception(error_lat_0_or_alpha_eq_90) );
proj_parm.lamp = lamc + aatan2(-cos(alpha), -sin(alpha) * sin(phic));
phip = aasin(cos(phic) * sin(alpha));
} else if (pj_param_r<srs::spar::o_lat_p>(params, "o_lat_p", srs::dpar::o_lat_p, phip)) { /* specified new pole */
proj_parm.lamp = pj_get_param_r<T, srs::spar::o_lon_p>(params, "o_lon_p", srs::dpar::o_lon_p);
//phip = pj_param_r(par.params, "o_lat_p");
} else { /* specified new "equator" points */
T lam1, lam2, phi1, phi2, con;
lam1 = pj_get_param_r<T, srs::spar::o_lon_1>(params, "o_lon_1", srs::dpar::o_lon_1);
phi1 = pj_get_param_r<T, srs::spar::o_lat_1>(params, "o_lat_1", srs::dpar::o_lat_1);
lam2 = pj_get_param_r<T, srs::spar::o_lon_2>(params, "o_lon_2", srs::dpar::o_lon_2);
phi2 = pj_get_param_r<T, srs::spar::o_lat_2>(params, "o_lat_2", srs::dpar::o_lat_2);
if (fabs(phi1 - phi2) <= tolerance || (con = fabs(phi1)) <= tolerance ||
fabs(con - half_pi) <= tolerance || fabs(fabs(phi2) - half_pi) <= tolerance)
BOOST_THROW_EXCEPTION( projection_exception(error_lat_1_or_2_zero_or_90) );
proj_parm.lamp = atan2(cos(phi1) * sin(phi2) * cos(lam1) -
sin(phi1) * cos(phi2) * cos(lam2),
sin(phi1) * cos(phi2) * sin(lam2) -
cos(phi1) * sin(phi2) * sin(lam1));
phip = atan(-cos(proj_parm.lamp - lam1) / tan(phi1));
}
if (fabs(phip) > tolerance) { /* oblique */
proj_parm.cphip = cos(phip);
proj_parm.sphip = sin(phip);
} else { /* transverse */
}
// TODO:
/* Support some rather speculative test cases, where the rotated projection */
/* is actually latlong. We do not want scaling in that case... */
//if (proj_parm.link...mutable_parameters().right==PJ_IO_UNITS_ANGULAR)
// par.right = PJ_IO_UNITS_PROJECTED;
// return phip to choose model
return phip;
}
template <typename T, typename Parameters>
struct base_ob_tran_oblique
{
par_ob_tran<T, Parameters> m_proj_parm;
inline base_ob_tran_oblique(par_ob_tran<T, Parameters> const& proj_parm)
: m_proj_parm(proj_parm)
{}
// FORWARD(o_forward) spheroid
// Project coordinates from geographic (lon, lat) to cartesian (x, y)
inline void fwd(Parameters const& , T const& lp_lon, T const& lp_lat, T& xy_x, T& xy_y) const
{
// NOTE: Parameters ignored, m_proj_parm.link has a copy
o_forward(lp_lon, lp_lat, xy_x, xy_y, this->m_proj_parm);
}
// INVERSE(o_inverse) spheroid
// Project coordinates from cartesian (x, y) to geographic (lon, lat)
inline void inv(Parameters const& , T const& xy_x, T const& xy_y, T& lp_lon, T& lp_lat) const
{
// NOTE: Parameters ignored, m_proj_parm.link has a copy
o_inverse(xy_x, xy_y, lp_lon, lp_lat, this->m_proj_parm);
}
static inline std::string get_name()
{
return "ob_tran_oblique";
}
};
template <typename T, typename Parameters>
struct base_ob_tran_transverse
{
par_ob_tran<T, Parameters> m_proj_parm;
inline base_ob_tran_transverse(par_ob_tran<T, Parameters> const& proj_parm)
: m_proj_parm(proj_parm)
{}
// FORWARD(t_forward) spheroid
// Project coordinates from geographic (lon, lat) to cartesian (x, y)
inline void fwd(Parameters const& , T const& lp_lon, T const& lp_lat, T& xy_x, T& xy_y) const
{
// NOTE: Parameters ignored, m_proj_parm.link has a copy
t_forward(lp_lon, lp_lat, xy_x, xy_y, this->m_proj_parm);
}
// INVERSE(t_inverse) spheroid
// Project coordinates from cartesian (x, y) to geographic (lon, lat)
inline void inv(Parameters const& , T const& xy_x, T const& xy_y, T& lp_lon, T& lp_lat) const
{
// NOTE: Parameters ignored, m_proj_parm.link has a copy
t_inverse(xy_x, xy_y, lp_lon, lp_lat, this->m_proj_parm);
}
static inline std::string get_name()
{
return "ob_tran_transverse";
}
};
template <typename StaticParameters, typename T, typename Parameters>
struct base_ob_tran_static
{
par_ob_tran_static<StaticParameters, T, Parameters> m_proj_parm;
bool m_is_oblique;
inline base_ob_tran_static(StaticParameters const& params, Parameters const& par)
: m_proj_parm(params, par)
{}
// FORWARD(o_forward) spheroid
// Project coordinates from geographic (lon, lat) to cartesian (x, y)
inline void fwd(Parameters const& , T const& lp_lon, T const& lp_lat, T& xy_x, T& xy_y) const
{
// NOTE: Parameters ignored, m_proj_parm.link has a copy
if (m_is_oblique) {
o_forward(lp_lon, lp_lat, xy_x, xy_y, this->m_proj_parm);
} else {
t_forward(lp_lon, lp_lat, xy_x, xy_y, this->m_proj_parm);
}
}
// INVERSE(o_inverse) spheroid
// Project coordinates from cartesian (x, y) to geographic (lon, lat)
inline void inv(Parameters const& , T const& xy_x, T const& xy_y, T& lp_lon, T& lp_lat) const
{
// NOTE: Parameters ignored, m_proj_parm.link has a copy
if (m_is_oblique) {
o_inverse(xy_x, xy_y, lp_lon, lp_lat, this->m_proj_parm);
} else {
t_inverse(xy_x, xy_y, lp_lon, lp_lat, this->m_proj_parm);
}
}
static inline std::string get_name()
{
return "ob_tran";
}
};
}} // namespace detail::ob_tran
#endif // doxygen
/*!
\brief General Oblique Transformation projection
\ingroup projections
\tparam Geographic latlong point type
\tparam Cartesian xy point type
\tparam Parameters parameter type
\par Projection characteristics
- Miscellaneous
- Spheroid
\par Projection parameters
- o_proj (string)
- Plus projection parameters
- o_lat_p (degrees)
- o_lon_p (degrees)
- New pole
- o_alpha: Alpha (degrees)
- o_lon_c (degrees)
- o_lat_c (degrees)
- o_lon_1 (degrees)
- o_lat_1: Latitude of first standard parallel (degrees)
- o_lon_2 (degrees)
- o_lat_2: Latitude of second standard parallel (degrees)
\par Example
\image html ex_ob_tran.gif
*/
template <typename T, typename Parameters>
struct ob_tran_oblique : public detail::ob_tran::base_ob_tran_oblique<T, Parameters>
{
template <typename Params>
inline ob_tran_oblique(Params const& , Parameters const& ,
detail::ob_tran::par_ob_tran<T, Parameters> const& proj_parm)
: detail::ob_tran::base_ob_tran_oblique<T, Parameters>(proj_parm)
{
// already done
//detail::ob_tran::setup_ob_tran(this->m_par, this->m_proj_parm);
}
};
/*!
\brief General Oblique Transformation projection
\ingroup projections
\tparam Geographic latlong point type
\tparam Cartesian xy point type
\tparam Parameters parameter type
\par Projection characteristics
- Miscellaneous
- Spheroid
\par Projection parameters
- o_proj (string)
- Plus projection parameters
- o_lat_p (degrees)
- o_lon_p (degrees)
- New pole
- o_alpha: Alpha (degrees)
- o_lon_c (degrees)
- o_lat_c (degrees)
- o_lon_1 (degrees)
- o_lat_1: Latitude of first standard parallel (degrees)
- o_lon_2 (degrees)
- o_lat_2: Latitude of second standard parallel (degrees)
\par Example
\image html ex_ob_tran.gif
*/
template <typename T, typename Parameters>
struct ob_tran_transverse : public detail::ob_tran::base_ob_tran_transverse<T, Parameters>
{
template <typename Params>
inline ob_tran_transverse(Params const& , Parameters const& ,
detail::ob_tran::par_ob_tran<T, Parameters> const& proj_parm)
: detail::ob_tran::base_ob_tran_transverse<T, Parameters>(proj_parm)
{
// already done
//detail::ob_tran::setup_ob_tran(this->m_par, this->m_proj_parm);
}
};
/*!
\brief General Oblique Transformation projection
\ingroup projections
\tparam Geographic latlong point type
\tparam Cartesian xy point type
\tparam Parameters parameter type
\par Projection characteristics
- Miscellaneous
- Spheroid
\par Projection parameters
- o_proj (string)
- Plus projection parameters
- o_lat_p (degrees)
- o_lon_p (degrees)
- New pole
- o_alpha: Alpha (degrees)
- o_lon_c (degrees)
- o_lat_c (degrees)
- o_lon_1 (degrees)
- o_lat_1: Latitude of first standard parallel (degrees)
- o_lon_2 (degrees)
- o_lat_2: Latitude of second standard parallel (degrees)
\par Example
\image html ex_ob_tran.gif
*/
template <typename StaticParameters, typename T, typename Parameters>
struct ob_tran_static : public detail::ob_tran::base_ob_tran_static<StaticParameters, T, Parameters>
{
inline ob_tran_static(StaticParameters const& params, Parameters const& par)
: detail::ob_tran::base_ob_tran_static<StaticParameters, T, Parameters>(params, par)
{
T phip = detail::ob_tran::setup_ob_tran<T>(params, par, this->m_proj_parm);
this->m_is_oblique = fabs(phip) > detail::ob_tran::tolerance;
}
};
#ifndef DOXYGEN_NO_DETAIL
namespace detail
{
// Static projection
template <typename SP, typename CT, typename P>
struct static_projection_type<srs::spar::proj_ob_tran, srs_sphere_tag, SP, CT, P>
{
typedef static_wrapper_fi<ob_tran_static<SP, CT, P>, P> type;
};
template <typename SP, typename CT, typename P>
struct static_projection_type<srs::spar::proj_ob_tran, srs_spheroid_tag, SP, CT, P>
{
typedef static_wrapper_fi<ob_tran_static<SP, CT, P>, P> type;
};
// Factory entry(s)
BOOST_GEOMETRY_PROJECTIONS_DETAIL_FACTORY_ENTRY_BEGIN(ob_tran_entry)
{
Parameters parameters_copy = parameters;
detail::ob_tran::par_ob_tran<T, Parameters> proj_parm(params, parameters_copy);
T phip = detail::ob_tran::setup_ob_tran<T>(params, parameters_copy, proj_parm);
if (fabs(phip) > detail::ob_tran::tolerance)
return new dynamic_wrapper_fi<ob_tran_oblique<T, Parameters>, T, Parameters>(params, parameters_copy, proj_parm);
else
return new dynamic_wrapper_fi<ob_tran_transverse<T, Parameters>, T, Parameters>(params, parameters_copy, proj_parm);
}
BOOST_GEOMETRY_PROJECTIONS_DETAIL_FACTORY_ENTRY_END
BOOST_GEOMETRY_PROJECTIONS_DETAIL_FACTORY_INIT_BEGIN(ob_tran_init)
{
BOOST_GEOMETRY_PROJECTIONS_DETAIL_FACTORY_INIT_ENTRY(ob_tran, ob_tran_entry)
}
} // namespace detail
#endif // doxygen
} // namespace projections
}} // namespace boost::geometry
#endif // BOOST_GEOMETRY_PROJECTIONS_OB_TRAN_HPP