#include <boost/numeric/conversion/cast.hpp>
#include <boost/test/unit_test.hpp>
#include "util/bearing.hpp"
#include "util/coordinate_calculation.hpp"
#include "util/debug.hpp"
#include "util/web_mercator.hpp"
#include <osrm/coordinate.hpp>
#include <cmath>
using namespace osrm;
using namespace osrm::util;
BOOST_AUTO_TEST_SUITE(coordinate_calculation_tests)
BOOST_AUTO_TEST_CASE(compute_angle)
{
// Simple cases
// North-South straight line
Coordinate first(FloatLongitude{1}, FloatLatitude{-1});
Coordinate middle(FloatLongitude{1}, FloatLatitude{0});
Coordinate end(FloatLongitude{1}, FloatLatitude{1});
auto angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 180);
// North-South-North u-turn
first = Coordinate(FloatLongitude{1}, FloatLatitude{0});
middle = Coordinate(FloatLongitude{1}, FloatLatitude{1});
end = Coordinate(FloatLongitude{1}, FloatLatitude{0});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 0);
// East-west straight lines are harder, *simple* coordinates only
// work at the equator. For other locations, we need to follow
// a rhumb line.
first = Coordinate(FloatLongitude{1}, FloatLatitude{0});
middle = Coordinate(FloatLongitude{2}, FloatLatitude{0});
end = Coordinate(FloatLongitude{3}, FloatLatitude{0});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 180);
// East-West-East u-turn
first = Coordinate(FloatLongitude{1}, FloatLatitude{0});
middle = Coordinate(FloatLongitude{2}, FloatLatitude{0});
end = Coordinate(FloatLongitude{1}, FloatLatitude{0});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 0);
// 90 degree left turn
first = Coordinate(FloatLongitude{1}, FloatLatitude{1});
middle = Coordinate(FloatLongitude{0}, FloatLatitude{1});
end = Coordinate(FloatLongitude{0}, FloatLatitude{2});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 90);
// 90 degree right turn
first = Coordinate(FloatLongitude{1}, FloatLatitude{1});
middle = Coordinate(FloatLongitude{0}, FloatLatitude{1});
end = Coordinate(FloatLongitude{0}, FloatLatitude{0});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 270);
// Weird cases
// Crossing both the meridians
first = Coordinate(FloatLongitude{-1}, FloatLatitude{-1});
middle = Coordinate(FloatLongitude{0}, FloatLatitude{1});
end = Coordinate(FloatLongitude{1}, FloatLatitude{-1});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_CLOSE(angle, 53.1, 0.2);
// All coords in the same spot
first = Coordinate(FloatLongitude{-1}, FloatLatitude{-1});
middle = Coordinate(FloatLongitude{-1}, FloatLatitude{-1});
end = Coordinate(FloatLongitude{-1}, FloatLatitude{-1});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 180);
// First two coords in the same spot, then heading north-east
first = Coordinate(FloatLongitude{-1}, FloatLatitude{-1});
middle = Coordinate(FloatLongitude{-1}, FloatLatitude{-1});
end = Coordinate(FloatLongitude{1}, FloatLatitude{1});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 180);
// First two coords in the same spot, then heading west
first = Coordinate(FloatLongitude{1}, FloatLatitude{1});
middle = Coordinate(FloatLongitude{1}, FloatLatitude{1});
end = Coordinate(FloatLongitude{2}, FloatLatitude{1});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 180);
// First two coords in the same spot then heading north
first = Coordinate(FloatLongitude{1}, FloatLatitude{1});
middle = Coordinate(FloatLongitude{1}, FloatLatitude{1});
end = Coordinate(FloatLongitude{1}, FloatLatitude{2});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 180);
// Second two coords in the same spot
first = Coordinate(FloatLongitude{1}, FloatLatitude{1});
middle = Coordinate(FloatLongitude{-1}, FloatLatitude{-1});
end = Coordinate(FloatLongitude{-1}, FloatLatitude{-1});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 180);
// First and last coords on the same spot
first = Coordinate(FloatLongitude{1}, FloatLatitude{1});
middle = Coordinate(FloatLongitude{-1}, FloatLatitude{-1});
end = Coordinate(FloatLongitude{1}, FloatLatitude{1});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 0);
// Check the antimeridian
first = Coordinate(FloatLongitude{180}, FloatLatitude{90});
middle = Coordinate(FloatLongitude{180}, FloatLatitude{0});
end = Coordinate(FloatLongitude{180}, FloatLatitude{-90});
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 180);
// Tiny changes below our calculation resolution
// This should be equivalent to having two points on the same spot.
first = Coordinate{FloatLongitude{0}, FloatLatitude{0}};
middle = Coordinate{FloatLongitude{1}, FloatLatitude{0}};
end = Coordinate{FloatLongitude{1 + std::numeric_limits<double>::epsilon()}, FloatLatitude{0}};
angle = coordinate_calculation::computeAngle(first, middle, end);
BOOST_CHECK_EQUAL(angle, 180);
}
BOOST_AUTO_TEST_CASE(invalid_values)
{
// Invalid values for unsafe types
BOOST_CHECK_THROW(coordinate_calculation::computeAngle(
Coordinate(UnsafeFloatLongitude{0}, UnsafeFloatLatitude{0}),
Coordinate(UnsafeFloatLongitude{1}, UnsafeFloatLatitude{0}),
Coordinate(UnsafeFloatLongitude{std::numeric_limits<double>::max()},
UnsafeFloatLatitude{0})),
boost::numeric::positive_overflow);
}
// Regression test for bug captured in #1347
BOOST_AUTO_TEST_CASE(regression_test_1347)
{
Coordinate u(FloatLongitude{-100}, FloatLatitude{10});
Coordinate v(FloatLongitude{-100.002}, FloatLatitude{10.001});
Coordinate q(FloatLongitude{-100.001}, FloatLatitude{10.002});
double d1 = coordinate_calculation::perpendicularDistance(u, v, q);
double ratio;
Coordinate nearest_location;
double d2 = coordinate_calculation::perpendicularDistance(u, v, q, nearest_location, ratio);
BOOST_CHECK_LE(std::abs(d1 - d2), 0.01);
}
BOOST_AUTO_TEST_CASE(regression_point_on_segment)
{
// ^
// | t
// |
// | i
// |
// |---|---|---|---|---|---|---|--->
// |
// |
// |
// |
// |
// |
// |
// |
// | s
FloatCoordinate input{FloatLongitude{55.995715}, FloatLatitude{48.332711}};
FloatCoordinate start{FloatLongitude{74.140427}, FloatLatitude{-180}};
FloatCoordinate target{FloatLongitude{53.041084}, FloatLatitude{77.21011}};
FloatCoordinate nearest;
double ratio;
std::tie(ratio, nearest) = coordinate_calculation::projectPointOnSegment(start, target, input);
FloatCoordinate diff{target.lon - start.lon, target.lat - start.lat};
BOOST_CHECK_CLOSE(static_cast<double>(start.lon + FloatLongitude{ratio} * diff.lon),
static_cast<double>(nearest.lon),
0.1);
BOOST_CHECK_CLOSE(static_cast<double>(start.lat + FloatLatitude{ratio} * diff.lat),
static_cast<double>(nearest.lat),
0.1);
}
BOOST_AUTO_TEST_CASE(point_on_segment)
{
// t
// |
// |---- i
// |
// s
auto result_1 =
coordinate_calculation::projectPointOnSegment({FloatLongitude{0}, FloatLatitude{0}},
{FloatLongitude{0}, FloatLatitude{2}},
{FloatLongitude{2}, FloatLatitude{1}});
auto reference_ratio_1 = 0.5;
auto reference_point_1 = FloatCoordinate{FloatLongitude{0}, FloatLatitude{1}};
BOOST_CHECK_EQUAL(result_1.first, reference_ratio_1);
BOOST_CHECK_EQUAL(result_1.second.lon, reference_point_1.lon);
BOOST_CHECK_EQUAL(result_1.second.lat, reference_point_1.lat);
// i
// :
// t
// |
// |
// |
// s
auto result_2 =
coordinate_calculation::projectPointOnSegment({FloatLongitude{0.}, FloatLatitude{0.}},
{FloatLongitude{0}, FloatLatitude{2}},
{FloatLongitude{0}, FloatLatitude{3}});
auto reference_ratio_2 = 1.;
auto reference_point_2 = FloatCoordinate{FloatLongitude{0}, FloatLatitude{2}};
BOOST_CHECK_EQUAL(result_2.first, reference_ratio_2);
BOOST_CHECK_EQUAL(result_2.second.lon, reference_point_2.lon);
BOOST_CHECK_EQUAL(result_2.second.lat, reference_point_2.lat);
// t
// |
// |
// |
// s
// :
// i
auto result_3 =
coordinate_calculation::projectPointOnSegment({FloatLongitude{0.}, FloatLatitude{0.}},
{FloatLongitude{0}, FloatLatitude{2}},
{FloatLongitude{0}, FloatLatitude{-1}});
auto reference_ratio_3 = 0.;
auto reference_point_3 = FloatCoordinate{FloatLongitude{0}, FloatLatitude{0}};
BOOST_CHECK_EQUAL(result_3.first, reference_ratio_3);
BOOST_CHECK_EQUAL(result_3.second.lon, reference_point_3.lon);
BOOST_CHECK_EQUAL(result_3.second.lat, reference_point_3.lat);
// t
// /
// /.
// / i
// s
//
auto result_4 = coordinate_calculation::projectPointOnSegment(
{FloatLongitude{0}, FloatLatitude{0}},
{FloatLongitude{1}, FloatLatitude{1}},
{FloatLongitude{0.5 + 0.1}, FloatLatitude{0.5 - 0.1}});
auto reference_ratio_4 = 0.5;
auto reference_point_4 = FloatCoordinate{FloatLongitude{0.5}, FloatLatitude{0.5}};
BOOST_CHECK_EQUAL(result_4.first, reference_ratio_4);
BOOST_CHECK_EQUAL(result_4.second.lon, reference_point_4.lon);
BOOST_CHECK_EQUAL(result_4.second.lat, reference_point_4.lat);
}
BOOST_AUTO_TEST_CASE(circleCenter)
{
Coordinate a(FloatLongitude{-100.}, FloatLatitude{10.});
Coordinate b(FloatLongitude{-100.002}, FloatLatitude{10.001});
Coordinate c(FloatLongitude{-100.001}, FloatLatitude{10.002});
auto result = coordinate_calculation::circleCenter(a, b, c);
BOOST_CHECK(result);
BOOST_CHECK_EQUAL(*result, Coordinate(FloatLongitude{-100.0008333}, FloatLatitude{10.0008333}));
// Co-linear longitude
a = Coordinate(FloatLongitude{-100.}, FloatLatitude{10.});
b = Coordinate(FloatLongitude{-100.001}, FloatLatitude{10.001});
c = Coordinate(FloatLongitude{-100.001}, FloatLatitude{10.002});
result = coordinate_calculation::circleCenter(a, b, c);
BOOST_CHECK(result);
BOOST_CHECK_EQUAL(*result, Coordinate(FloatLongitude{-99.9995}, FloatLatitude{10.0015}));
// Co-linear longitude, impossible to calculate
a = Coordinate(FloatLongitude{-100.001}, FloatLatitude{10.});
b = Coordinate(FloatLongitude{-100.001}, FloatLatitude{10.001});
c = Coordinate(FloatLongitude{-100.001}, FloatLatitude{10.002});
result = coordinate_calculation::circleCenter(a, b, c);
BOOST_CHECK(!result);
// Co-linear latitude, this is a real case that failed
a = Coordinate(FloatLongitude{-112.096234}, FloatLatitude{41.147101});
b = Coordinate(FloatLongitude{-112.096606}, FloatLatitude{41.147101});
c = Coordinate(FloatLongitude{-112.096419}, FloatLatitude{41.147259});
result = coordinate_calculation::circleCenter(a, b, c);
BOOST_CHECK(result);
BOOST_CHECK_EQUAL(*result, Coordinate(FloatLongitude{-112.09642}, FloatLatitude{41.1470705}));
// Co-linear latitude, variation
a = Coordinate(FloatLongitude{-112.096234}, FloatLatitude{41.147101});
b = Coordinate(FloatLongitude{-112.096606}, FloatLatitude{41.147259});
c = Coordinate(FloatLongitude{-112.096419}, FloatLatitude{41.147259});
result = coordinate_calculation::circleCenter(a, b, c);
BOOST_CHECK(result);
BOOST_CHECK_EQUAL(*result, Coordinate(FloatLongitude{-112.0965125}, FloatLatitude{41.1469622}));
// Co-linear latitude, impossible to calculate
a = Coordinate(FloatLongitude{-112.096234}, FloatLatitude{41.147259});
b = Coordinate(FloatLongitude{-112.096606}, FloatLatitude{41.147259});
c = Coordinate(FloatLongitude{-112.096419}, FloatLatitude{41.147259});
result = coordinate_calculation::circleCenter(a, b, c);
BOOST_CHECK(!result);
// Out of bounds
a = Coordinate(FloatLongitude{-112.096234}, FloatLatitude{41.147258});
b = Coordinate(FloatLongitude{-112.106606}, FloatLatitude{41.147259});
c = Coordinate(FloatLongitude{-113.096419}, FloatLatitude{41.147258});
result = coordinate_calculation::circleCenter(a, b, c);
BOOST_CHECK(!result);
}
// For overflow issue #3483, introduced in 68ee4eab61548. Run with -fsanitize=integer.
BOOST_AUTO_TEST_CASE(squaredEuclideanDistance)
{
// Overflow happens when left hand side values are smaller than right hand side values,
// then `lhs - rhs` will be negative but stored in a uint64_t (wraps around).
Coordinate lhs(FloatLongitude{-180}, FloatLatitude{-90});
Coordinate rhs(FloatLongitude{180}, FloatLatitude{90});
const auto result = coordinate_calculation::squaredEuclideanDistance(lhs, rhs);
BOOST_CHECK_EQUAL(result, 162000000000000000ull);
}
BOOST_AUTO_TEST_CASE(vertical_regression)
{
// check a vertical line for its bearing
std::vector<Coordinate> coordinates;
for (std::size_t i = 0; i < 100; ++i)
coordinates.push_back(Coordinate(FloatLongitude{0.0}, FloatLatitude{i / 100.0}));
const auto regression =
util::coordinate_calculation::leastSquareRegression(coordinates.begin(), coordinates.end());
const auto is_valid =
util::angularDeviation(
util::coordinate_calculation::bearing(regression.first, regression.second), 0) < 2;
BOOST_CHECK(is_valid);
}
BOOST_AUTO_TEST_CASE(sinus_curve)
{
// create a full sinus curve, sampled in 3.6 degree
std::vector<Coordinate> coordinates;
for (std::size_t i = 0; i < 360; ++i)
coordinates.push_back(Coordinate(
FloatLongitude{i / 360.0},
FloatLatitude{sin(util::coordinate_calculation::detail::degToRad(i / 360.0))}));
const auto regression =
util::coordinate_calculation::leastSquareRegression(coordinates.begin(), coordinates.end());
const auto is_valid =
util::angularDeviation(
util::coordinate_calculation::bearing(regression.first, regression.second), 90) < 2;
BOOST_CHECK(is_valid);
}
BOOST_AUTO_TEST_CASE(parallel_lines_slight_offset)
{
std::vector<Coordinate> coordinates_lhs;
for (std::size_t i = 0; i < 100; ++i)
coordinates_lhs.push_back(Coordinate(util::FloatLongitude{(50 - (rand() % 101)) / 100000.0},
util::FloatLatitude{i / 100000.0}));
std::vector<Coordinate> coordinates_rhs;
for (std::size_t i = 0; i < 100; ++i)
coordinates_rhs.push_back(
Coordinate(util::FloatLongitude{(150 - (rand() % 101)) / 100000.0},
util::FloatLatitude{i / 100000.0}));
const auto are_parallel = util::coordinate_calculation::areParallel(coordinates_lhs.begin(),
coordinates_lhs.end(),
coordinates_rhs.begin(),
coordinates_rhs.end());
BOOST_CHECK(are_parallel);
}
BOOST_AUTO_TEST_CASE(consistent_invalid_bearing_result)
{
const auto pos1 = Coordinate(util::FloatLongitude{0.}, util::FloatLatitude{0.});
const auto pos2 = Coordinate(util::FloatLongitude{5.}, util::FloatLatitude{5.});
const auto pos3 = Coordinate(util::FloatLongitude{-5.}, util::FloatLatitude{-5.});
BOOST_CHECK_EQUAL(0., util::coordinate_calculation::bearing(pos1, pos1));
BOOST_CHECK_EQUAL(0., util::coordinate_calculation::bearing(pos2, pos2));
BOOST_CHECK_EQUAL(0., util::coordinate_calculation::bearing(pos3, pos3));
}
// Regression test for bug captured in #3516
BOOST_AUTO_TEST_CASE(regression_test_3516)
{
Coordinate u(FloatLongitude{-73.989687}, FloatLatitude{40.752288});
Coordinate v(FloatLongitude{-73.990134}, FloatLatitude{40.751658});
Coordinate q(FloatLongitude{-73.99039}, FloatLatitude{40.75171});
BOOST_CHECK_EQUAL(Coordinate{web_mercator::toWGS84(web_mercator::fromWGS84(u))}, u);
BOOST_CHECK_EQUAL(Coordinate{web_mercator::toWGS84(web_mercator::fromWGS84(v))}, v);
double ratio;
Coordinate nearest_location;
coordinate_calculation::perpendicularDistance(u, v, q, nearest_location, ratio);
BOOST_CHECK_EQUAL(ratio, 1.);
BOOST_CHECK_EQUAL(nearest_location, v);
}
BOOST_AUTO_TEST_CASE(computeArea)
{
using osrm::util::coordinate_calculation::computeArea;
//
auto rhombus = std::vector<Coordinate>{{FloatLongitude{.00}, FloatLatitude{.00}},
{FloatLongitude{.01}, FloatLatitude{.01}},
{FloatLongitude{.02}, FloatLatitude{.00}},
{FloatLongitude{.01}, FloatLatitude{-.01}},
{FloatLongitude{.00}, FloatLatitude{.00}}};
BOOST_CHECK_CLOSE(2 * 1112.263 * 1112.263, computeArea(rhombus), 1e-3);
// edge cases
auto self_intersection = std::vector<Coordinate>{{FloatLongitude{.00}, FloatLatitude{.00}},
{FloatLongitude{.00}, FloatLatitude{.02}},
{FloatLongitude{.01}, FloatLatitude{.01}},
{FloatLongitude{.02}, FloatLatitude{.00}},
{FloatLongitude{.02}, FloatLatitude{.02}},
{FloatLongitude{.01}, FloatLatitude{.01}},
{FloatLongitude{.00}, FloatLatitude{.00}}};
BOOST_CHECK(computeArea(self_intersection) < 1e-3);
BOOST_CHECK_CLOSE(0, computeArea({}), 1e-3);
}
BOOST_AUTO_TEST_SUITE_END()