// Boost.Geometry // Unit Test // Copyright (c) 2016-2018 Oracle and/or its affiliates. // Contributed and/or modified by Vissarion Fysikopoulos, on behalf of Oracle // Contributed and/or modified by Adam Wulkiewicz, on behalf of Oracle // Contributed and/or modified by Adeel Ahmad, as part of Google Summer of Code 2018 program // 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) #include "test_formula.hpp" #include "direct_cases.hpp" #include "direct_cases_antipodal.hpp" #include #include #include //#include #include #include #ifdef BOOST_GEOEMTRY_TEST_WITH_GEOGRAPHICLIB #include #include #endif // BOOST_GEOEMTRY_TEST_WITH_GEOGRAPHICLIB inline void symmetrize_wrt_origin(expected_result & r) { r.lon2 = -r.lon2; r.lat2 = -r.lat2; r.reduced_length = -r.reduced_length; } inline expected_results symmetric_wrt_origin(expected_results r) { r.distance = -r.distance; symmetrize_wrt_origin(r.karney); symmetrize_wrt_origin(r.series); symmetrize_wrt_origin(r.spherical); symmetrize_wrt_origin(r.thomas); symmetrize_wrt_origin(r.thomas1st); symmetrize_wrt_origin(r.vincenty); return r; } template void check_direct(Result const& result, expected_result const& expected, expected_result const& reference, double reference_error, bool check_reference_only = false) { check_direct_sph(result, expected, reference, reference_error, check_reference_only); check_one(result.reduced_length, expected.reduced_length, reference.reduced_length, reference_error); check_one(result.geodesic_scale, expected.geodesic_scale, reference.geodesic_scale, reference_error); } template void check_direct_sph(Result const& result, expected_result const& expected, expected_result const& reference, double reference_error, bool check_reference_only = false) { check_one(result.lon2, expected.lon2, reference.lon2, reference_error, true, check_reference_only); check_one(result.lat2, expected.lat2, reference.lat2, reference_error, true, check_reference_only); check_one(result.reverse_azimuth, expected.reverse_azimuth, reference.reverse_azimuth, reference_error, true, check_reference_only); } void test_all(expected_results const& results) { double const d2r = bg::math::d2r(); double const r2d = bg::math::r2d(); double lon1r = results.p1.lon * d2r; double lat1r = results.p1.lat * d2r; double distance = results.distance; double azi12r = results.azimuth12 * d2r; double lon1d = results.p1.lon; double lat1d = results.p1.lat; double azi12d = results.azimuth12; // WGS84 bg::srs::spheroid spheroid(6378137.0, 6356752.3142451793); bg::srs::sphere const sphere; bg::formula::result_direct result; typedef bg::formula::vincenty_direct vi_t; result = vi_t::apply(lon1r, lat1r, distance, azi12r, spheroid); result.lon2 *= r2d; result.lat2 *= r2d; result.reverse_azimuth *= r2d; check_direct(result, results.vincenty, results.karney, 0.00000001); typedef bg::formula::thomas_direct th_t; result = th_t::apply(lon1r, lat1r, distance, azi12r, spheroid); result.lon2 *= r2d; result.lat2 *= r2d; result.reverse_azimuth *= r2d; check_direct(result, results.thomas, results.karney, 0.0000001); typedef bg::formula::thomas_direct th_t1st; result = th_t1st::apply(lon1r, lat1r, distance, azi12r, spheroid); result.lon2 *= r2d; result.lat2 *= r2d; result.reverse_azimuth *= r2d; check_direct(result, results.thomas1st, results.karney, 0.0000001); /* typedef bg::formula::series_expansion_direct series; result = series::apply(lon1r, lat1r, distance, azi12r, spheroid); result.lon2 *= r2d; result.lat2 *= r2d; result.reverse_azimuth *= r2d; check_direct(result, results.series, results.karney, 0.0000001); */ result = bg::formula::spherical_direct(lon1r, lat1r, distance, azi12r, sphere); result.lon2 *= r2d; result.lat2 *= r2d; result.reverse_azimuth *= r2d; check_direct_sph(result, results.spherical, results.karney, 0.1); typedef bg::formula::karney_direct ka_t; result = ka_t::apply(lon1d, lat1d, distance, azi12d, spheroid); check_direct(result, results.karney, results.karney, 0.0000001); #ifdef BOOST_GEOEMTRY_TEST_WITH_GEOGRAPHICLIB { using namespace GeographicLib; Geodesic geod(Constants::WGS84_a(), Constants::WGS84_f()); double foo = 0; geod.Direct(lat1d, lon1d, azi12d, distance, result.lat2, result.lon2, result.reverse_azimuth, result.reduced_length, result.geodesic_scale, foo); boost::ignore_unused(foo); check_direct(result, results.karney, results.karney, 0.0000001); } #endif } void test_karney_antipodal(expected_results_antipodal const& results) { double lon1d = results.p1.lon; double lat1d = results.p1.lat; double distance = results.distance; double azi12d = results.azimuth12; // WGS84 bg::srs::spheroid spheroid(6378137.0, 6356752.3142451793); bg::formula::result_direct result; typedef bg::formula::karney_direct ka_t; result = ka_t::apply(lon1d, lat1d, distance, azi12d, spheroid); check_direct(result, results.karney, results.karney, 0.0000001, true); } int test_main(int, char*[]) { for (size_t i = 0; i < expected_size; ++i) { test_all(expected[i]); if (expected[i].p1.lon == 0 && expected[i].p1.lat == 0) { test_all(symmetric_wrt_origin(expected[i])); } } for (size_t i = 0; i < expected_size_antipodal; ++i) { test_karney_antipodal(expected_antipodal[i]); } return 0; }