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- // Boost.Geometry (aka GGL, Generic Geometry Library)
- // Unit Test
- // Copyright (c) 2007-2016 Barend Gehrels, Amsterdam, the Netherlands.
- // Copyright (c) 2008-2016 Bruno Lalande, Paris, France.
- // Copyright (c) 2009-2016 Mateusz Loskot, London, UK.
- // This file was modified by Oracle on 2014-2017.
- // Modifications copyright (c) 2014-2017 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
- // Parts of Boost.Geometry are redesigned from Geodan's Geographic Library
- // (geolib/GGL), copyright (c) 1995-2010 Geodan, Amsterdam, the Netherlands.
- // 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 <geometry_test_common.hpp>
- #include <boost/concept_check.hpp>
- #include <boost/geometry/algorithms/assign.hpp>
- #include <boost/geometry/algorithms/distance.hpp>
- #include <boost/geometry/geometries/point.hpp>
- #include <boost/geometry/srs/spheroid.hpp>
- #include <boost/geometry/strategies/concepts/distance_concept.hpp>
- #include <boost/geometry/strategies/geographic/distance_andoyer.hpp>
- #include <boost/geometry/strategies/geographic/side_andoyer.hpp>
- #include <test_common/test_point.hpp>
- #ifdef HAVE_TTMATH
- # include <boost/geometry/extensions/contrib/ttmath_stub.hpp>
- #endif
- double make_deg(double deg, double min, double sec)
- {
- return deg + min / 60.0 + sec / 3600.0;
- }
- double to_rad(double deg)
- {
- return bg::math::pi<double>() * deg / 180.0;
- }
- double to_deg(double rad)
- {
- return 180.0 * rad / bg::math::pi<double>();
- }
- double normlized_deg(double deg)
- {
- if (deg > 180)
- return deg - 360;
- else if (deg < -180)
- return deg + 360;
- else
- return deg;
- }
- template <typename P1, typename P2>
- void test_distance(double lon1, double lat1, double lon2, double lat2, double expected_km)
- {
- // Set radius type, but for integer coordinates we want to have floating point radius type
- typedef typename bg::promote_floating_point
- <
- typename bg::coordinate_type<P1>::type
- >::type rtype;
- typedef bg::srs::spheroid<rtype> stype;
- typedef bg::strategy::distance::andoyer<stype> andoyer_type;
- typedef bg::strategy::distance::geographic<bg::strategy::andoyer, stype> geographic_type;
- typedef bg::formula::andoyer_inverse<rtype, true, false> andoyer_inverse_type;
- BOOST_CONCEPT_ASSERT
- (
- (bg::concepts::PointDistanceStrategy<andoyer_type, P1, P2>)
- );
- andoyer_type andoyer;
- geographic_type geographic;
- typedef typename bg::strategy::distance
- ::services::return_type<andoyer_type, P1, P2>::type return_type;
- P1 p1;
- P2 p2;
- bg::assign_values(p1, lon1, lat1);
- bg::assign_values(p2, lon2, lat2);
- return_type d_strategy = andoyer.apply(p1, p2);
- return_type d_strategy2 = geographic.apply(p1, p2);
- return_type d_function = bg::distance(p1, p2, andoyer);
- double diff = bg::math::longitude_distance_signed<bg::degree>(lon1, lon2);
- return_type d_formula;
- // if the points lay on a meridian, distance strategy calls the special formula
- // for meridian distance that returns different result than andoyer formula
- // for nearly antipodal points
- if (bg::math::equals(diff, 0.0)
- || bg::math::equals(bg::math::abs(diff), 180.0))
- {
- d_formula = d_strategy;
- }
- else
- {
- d_formula = andoyer_inverse_type::apply(to_rad(lon1), to_rad(lat1),
- to_rad(lon2), to_rad(lat2),
- stype()).distance;
- }
- BOOST_CHECK_CLOSE(d_strategy / 1000.0, expected_km, 0.001);
- BOOST_CHECK_CLOSE(d_strategy2 / 1000.0, expected_km, 0.001);
- BOOST_CHECK_CLOSE(d_function / 1000.0, expected_km, 0.001);
- BOOST_CHECK_CLOSE(d_formula / 1000.0, expected_km, 0.001);
- }
- template <typename PS, typename P>
- void test_azimuth(double lon1, double lat1,
- double lon2, double lat2,
- double expected_azimuth_deg)
- {
- // Set radius type, but for integer coordinates we want to have floating point radius type
- typedef typename bg::promote_floating_point
- <
- typename bg::coordinate_type<PS>::type
- >::type rtype;
- typedef bg::srs::spheroid<rtype> stype;
- typedef bg::formula::andoyer_inverse<rtype, false, true> andoyer_inverse_type;
- rtype a_formula = andoyer_inverse_type::apply(to_rad(lon1), to_rad(lat1), to_rad(lon2), to_rad(lat2), stype()).azimuth;
- rtype azimuth_deg = to_deg(a_formula);
- if (bg::math::equals(azimuth_deg, -180.0))
- azimuth_deg = 180.0;
- if (bg::math::equals(expected_azimuth_deg, -180.0))
- expected_azimuth_deg = 180.0;
- if (bg::math::equals(expected_azimuth_deg, 0.0))
- {
- BOOST_CHECK(bg::math::equals(azimuth_deg, expected_azimuth_deg));
- }
- else
- {
- BOOST_CHECK_CLOSE(azimuth_deg, expected_azimuth_deg, 0.001);
- }
- }
- template <typename P1, typename P2>
- void test_distazi(double lon1, double lat1, double lon2, double lat2,
- double expected_km, double expected_azimuth_deg)
- {
- test_distance<P1, P2>(lon1, lat1, lon2, lat2, expected_km);
- test_azimuth<P1, P2>(lon1, lat1, lon2, lat2, expected_azimuth_deg);
- }
- // requires SW->NE
- template <typename P1, typename P2>
- void test_distazi_symm(double lon1, double lat1, double lon2, double lat2,
- double expected_km, double expected_azimuth_deg,
- bool is_antipodal = false)
- {
- double d180 = is_antipodal ? 0 : 180;
- test_distazi<P1, P2>(lon1, lat1, lon2, lat2, expected_km, expected_azimuth_deg);
- test_distazi<P1, P2>(-lon1, lat1, -lon2, lat2, expected_km, -expected_azimuth_deg);
- test_distazi<P1, P2>(lon1, -lat1, lon2, -lat2, expected_km, d180 - expected_azimuth_deg);
- test_distazi<P1, P2>(-lon1, -lat1, -lon2, -lat2, expected_km, -d180 + expected_azimuth_deg);
- }
- template <typename P1, typename P2>
- void test_distazi_symmNS(double lon1, double lat1, double lon2, double lat2,
- double expected_km, double expected_azimuth_deg)
- {
- test_distazi<P1, P2>(lon1, lat1, lon2, lat2, expected_km, expected_azimuth_deg);
- test_distazi<P1, P2>(lon1, -lat1, lon2, -lat2, expected_km, 180 - expected_azimuth_deg);
- }
- template <typename PS, typename P>
- void test_side(double lon1, double lat1,
- double lon2, double lat2,
- double lon, double lat,
- int expected_side)
- {
- // Set radius type, but for integer coordinates we want to have floating point radius type
- typedef typename bg::promote_floating_point
- <
- typename bg::coordinate_type<PS>::type
- >::type rtype;
- typedef bg::srs::spheroid<rtype> stype;
- typedef bg::strategy::side::andoyer<stype> strategy_type;
- typedef bg::strategy::side::geographic<bg::strategy::andoyer, stype> strategy2_type;
- strategy_type strategy;
- strategy2_type strategy2;
- PS p1, p2;
- P p;
- bg::assign_values(p1, lon1, lat1);
- bg::assign_values(p2, lon2, lat2);
- bg::assign_values(p, lon, lat);
- int side = strategy.apply(p1, p2, p);
- int side2 = strategy2.apply(p1, p2, p);
- BOOST_CHECK_EQUAL(side, expected_side);
- BOOST_CHECK_EQUAL(side2, expected_side);
- }
- template <typename P1, typename P2>
- void test_all()
- {
- // polar
- test_distazi<P1, P2>(0, 90, 1, 80,
- 1116.814237, 179);
-
- // no point difference
- test_distazi<P1, P2>(4, 52, 4, 52,
- 0.0, 0.0);
- // normal cases
- test_distazi<P1, P2>(4, 52, 3, 40,
- 1336.039890, -176.3086);
- test_distazi<P1, P2>(3, 52, 4, 40,
- 1336.039890, 176.3086);
- test_distazi<P1, P2>(make_deg(17, 19, 43.28),
- make_deg(40, 30, 31.151),
- 18, 40,
- 80.323245,
- make_deg(134, 27, 50.05));
- // antipodal
- // ok? in those cases shorter path would pass through a pole
- // but 90 or -90 would be consistent with distance?
- test_distazi<P1, P2>(0, 0, 180, 0, 20003.9, 0.0);
- test_distazi<P1, P2>(0, 0, -180, 0, 20003.9, 0.0);
- test_distazi<P1, P2>(-90, 0, 90, 0, 20003.9, 0.0);
- test_distazi<P1, P2>(90, 0, -90, 0, 20003.9, 0.0);
- // 0, 45, 90 ...
- for (int i = 0 ; i < 360 ; i += 45)
- {
- // 0 45 90 ...
- double l = normlized_deg(i);
- // -1 44 89 ...
- double l1 = normlized_deg(i - 1);
- // 1 46 91 ...
- double l2 = normlized_deg(i + 1);
- // near equator
- test_distazi_symm<P1, P2>(l1, -1, l2, 1, 313.7956, 45.1964);
- // near poles
- test_distazi_symmNS<P1, P2>(l, -89.5, l, 89.5, 19892.2, 0.0);
- test_distazi_symmNS<P1, P2>(l, -89.6, l, 89.6, 19914.6, 0.0);
- test_distazi_symmNS<P1, P2>(l, -89.7, l, 89.7, 19936.9, 0.0);
- test_distazi_symmNS<P1, P2>(l, -89.8, l, 89.8, 19959.2, 0.0);
- test_distazi_symmNS<P1, P2>(l, -89.9, l, 89.9, 19981.6, 0.0);
- test_distazi_symmNS<P1, P2>(l, -89.99, l, 89.99, 20001.7, 0.0);
- test_distazi_symmNS<P1, P2>(l, -89.999, l, 89.999, 20003.7, 0.0);
- // antipodal
- test_distazi_symmNS<P1, P2>(l, -90, l, 90, 20003.9, 0.0);
- test_distazi_symm<P1, P2>(normlized_deg(l-10.0), -10.0, normlized_deg(l+135), 45, 14892.1, 34.1802);
- test_distazi_symm<P1, P2>(normlized_deg(l-30.0), -30.0, normlized_deg(l+135), 45, 17890.7, 33.7002);
- test_distazi_symm<P1, P2>(normlized_deg(l-40.0), -40.0, normlized_deg(l+135), 45, 19319.7, 33.4801);
- test_distazi_symm<P1, P2>(normlized_deg(l-41.0), -41.0, normlized_deg(l+135), 45, 19459.1, 33.2408);
- test_distazi_symm<P1, P2>(normlized_deg(l-42.0), -42.0, normlized_deg(l+135), 45, 19597.8, 32.7844);
- test_distazi_symm<P1, P2>(normlized_deg(l-43.0), -43.0, normlized_deg(l+135), 45, 19735.8, 31.7784);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.0), -44.0, normlized_deg(l+135), 45, 19873.0, 28.5588);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.1), -44.1, normlized_deg(l+135), 45, 19886.7, 27.8304);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.2), -44.2, normlized_deg(l+135), 45, 19900.4, 26.9173);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.3), -44.3, normlized_deg(l+135), 45, 19914.1, 25.7401);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.4), -44.4, normlized_deg(l+135), 45, 19927.7, 24.1668);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.5), -44.5, normlized_deg(l+135), 45, 19941.4, 21.9599);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.6), -44.6, normlized_deg(l+135), 45, 19955.0, 18.6438);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.7), -44.7, normlized_deg(l+135), 45, 19968.6, 13.1096);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.8), -44.8, normlized_deg(l+135), 45, 19982.3, 2.0300);
- // nearly antipodal
- test_distazi_symm<P1, P2>(normlized_deg(l-44.9), -44.9, normlized_deg(l+135), 45, 19995.9, 0.0);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.95), -44.95, normlized_deg(l+135), 45, 20002.7, 0.0);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.99), -44.99, normlized_deg(l+135), 45, 20008.1, 0.0);
- test_distazi_symm<P1, P2>(normlized_deg(l-44.999), -44.999, normlized_deg(l+135), 45, 20009.4, 0.0);
- // antipodal
- test_distazi_symm<P1, P2>(normlized_deg(l-45), -45, normlized_deg(l+135), 45, 20003.92, 0.0, true);
- }
- /* SQL Server gives:
- 1116.82586908528, 0, 1336.02721932545
- with:
- SELECT 0.001 * geography::STGeomFromText('POINT(0 90)', 4326).STDistance(geography::STGeomFromText('POINT(1 80)', 4326))
- union SELECT 0.001 * geography::STGeomFromText('POINT(4 52)', 4326).STDistance(geography::STGeomFromText('POINT(4 52)', 4326))
- union SELECT 0.001 * geography::STGeomFromText('POINT(4 52)', 4326).STDistance(geography::STGeomFromText('POINT(3 40)', 4326))
- */
- test_side<P1, P2>(0, 0, 0, 1, 0, 2, 0);
- test_side<P1, P2>(0, 0, 0, 1, 0, -2, 0);
- test_side<P1, P2>(10, 0, 10, 1, 10, 2, 0);
- test_side<P1, P2>(10, 0, 10, -1, 10, 2, 0);
- test_side<P1, P2>(10, 0, 10, 1, 0, 2, 1); // left
- test_side<P1, P2>(10, 0, 10, -1, 0, 2, -1); // right
- test_side<P1, P2>(-10, -10, 10, 10, 10, 0, -1); // right
- test_side<P1, P2>(-10, -10, 10, 10, -10, 0, 1); // left
- test_side<P1, P2>(170, -10, -170, 10, -170, 0, -1); // right
- test_side<P1, P2>(170, -10, -170, 10, 170, 0, 1); // left
- }
- template <typename P>
- void test_all()
- {
- test_all<P, P>();
- }
- int test_main(int, char* [])
- {
- //test_all<float[2]>();
- //test_all<double[2]>();
- //test_all<bg::model::point<int, 2, bg::cs::geographic<bg::degree> > >();
- //test_all<bg::model::point<float, 2, bg::cs::geographic<bg::degree> > >();
- test_all<bg::model::point<double, 2, bg::cs::geographic<bg::degree> > >();
- #if defined(HAVE_TTMATH)
- test_all<bg::model::point<ttmath::Big<1,4>, 2, bg::cs::geographic<bg::degree> > >();
- test_all<bg::model::point<ttmath_big, 2, bg::cs::geographic<bg::degree> > >();
- #endif
- return 0;
- }
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