/**************************************************************************/ /* test_geometry_2d.h */ /**************************************************************************/ /* This file is part of: */ /* GODOT ENGINE */ /* https://godotengine.org */ /**************************************************************************/ /* Copyright (c) 2014-present Godot Engine contributors (see AUTHORS.md). */ /* Copyright (c) 2007-2014 Juan Linietsky, Ariel Manzur. */ /* */ /* 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 TEST_GEOMETRY_2D_H #define TEST_GEOMETRY_2D_H #include "core/math/geometry_2d.h" #include "thirdparty/doctest/doctest.h" namespace TestGeometry2D { TEST_CASE("[Geometry2D] Point in circle") { CHECK(Geometry2D::is_point_in_circle(Vector2(0, 0), Vector2(0, 0), 1.0)); CHECK(Geometry2D::is_point_in_circle(Vector2(0, 0), Vector2(11.99, 0), 12)); CHECK(Geometry2D::is_point_in_circle(Vector2(-11.99, 0), Vector2(0, 0), 12)); CHECK_FALSE(Geometry2D::is_point_in_circle(Vector2(0, 0), Vector2(12.01, 0), 12)); CHECK_FALSE(Geometry2D::is_point_in_circle(Vector2(-12.01, 0), Vector2(0, 0), 12)); CHECK(Geometry2D::is_point_in_circle(Vector2(7, -42), Vector2(4, -40), 3.7)); CHECK_FALSE(Geometry2D::is_point_in_circle(Vector2(7, -42), Vector2(4, -40), 3.5)); // This tests points on the edge of the circle. They are treated as being inside the circle. CHECK(Geometry2D::is_point_in_circle(Vector2(1.0, 0.0), Vector2(0, 0), 1.0)); CHECK(Geometry2D::is_point_in_circle(Vector2(0.0, -1.0), Vector2(0, 0), 1.0)); } TEST_CASE("[Geometry2D] Point in triangle") { CHECK(Geometry2D::is_point_in_triangle(Vector2(0, 0), Vector2(-1, 1), Vector2(0, -1), Vector2(1, 1))); CHECK_FALSE(Geometry2D::is_point_in_triangle(Vector2(-1.01, 1.0), Vector2(-1, 1), Vector2(0, -1), Vector2(1, 1))); CHECK(Geometry2D::is_point_in_triangle(Vector2(3, 2.5), Vector2(1, 4), Vector2(3, 2), Vector2(5, 4))); CHECK(Geometry2D::is_point_in_triangle(Vector2(-3, -2.5), Vector2(-1, -4), Vector2(-3, -2), Vector2(-5, -4))); CHECK_FALSE(Geometry2D::is_point_in_triangle(Vector2(0, 0), Vector2(1, 4), Vector2(3, 2), Vector2(5, 4))); // This tests points on the edge of the triangle. They are treated as being outside the triangle. // In `is_point_in_circle` and `is_point_in_polygon` they are treated as being inside, so in order the make // the behavior consistent this may change in the future (see issue #44717 and PR #44274). CHECK_FALSE(Geometry2D::is_point_in_triangle(Vector2(1, 1), Vector2(-1, 1), Vector2(0, -1), Vector2(1, 1))); CHECK_FALSE(Geometry2D::is_point_in_triangle(Vector2(0, 1), Vector2(-1, 1), Vector2(0, -1), Vector2(1, 1))); } TEST_CASE("[Geometry2D] Point in polygon") { Vector p; CHECK_FALSE(Geometry2D::is_point_in_polygon(Vector2(0, 0), p)); p.push_back(Vector2(-88, 120)); p.push_back(Vector2(-74, -38)); p.push_back(Vector2(135, -145)); p.push_back(Vector2(425, 70)); p.push_back(Vector2(68, 112)); p.push_back(Vector2(-120, 370)); p.push_back(Vector2(-323, -145)); CHECK_FALSE(Geometry2D::is_point_in_polygon(Vector2(-350, 0), p)); CHECK_FALSE(Geometry2D::is_point_in_polygon(Vector2(-110, 60), p)); CHECK_FALSE(Geometry2D::is_point_in_polygon(Vector2(412, 96), p)); CHECK_FALSE(Geometry2D::is_point_in_polygon(Vector2(83, 130), p)); CHECK_FALSE(Geometry2D::is_point_in_polygon(Vector2(-320, -153), p)); CHECK(Geometry2D::is_point_in_polygon(Vector2(0, 0), p)); CHECK(Geometry2D::is_point_in_polygon(Vector2(-230, 0), p)); CHECK(Geometry2D::is_point_in_polygon(Vector2(130, -110), p)); CHECK(Geometry2D::is_point_in_polygon(Vector2(370, 55), p)); CHECK(Geometry2D::is_point_in_polygon(Vector2(-160, 190), p)); // This tests points on the edge of the polygon. They are treated as being inside the polygon. int c = p.size(); for (int i = 0; i < c; i++) { const Vector2 &p1 = p[i]; CHECK(Geometry2D::is_point_in_polygon(p1, p)); const Vector2 &p2 = p[(i + 1) % c]; Vector2 midpoint((p1 + p2) * 0.5); CHECK(Geometry2D::is_point_in_polygon(midpoint, p)); } } TEST_CASE("[Geometry2D] Polygon clockwise") { Vector p; CHECK_FALSE(Geometry2D::is_polygon_clockwise(p)); p.push_back(Vector2(5, -5)); p.push_back(Vector2(-1, -5)); p.push_back(Vector2(-5, -1)); p.push_back(Vector2(-1, 3)); p.push_back(Vector2(1, 5)); CHECK(Geometry2D::is_polygon_clockwise(p)); p.reverse(); CHECK_FALSE(Geometry2D::is_polygon_clockwise(p)); } TEST_CASE("[Geometry2D] Line intersection") { Vector2 r; CHECK(Geometry2D::line_intersects_line(Vector2(2, 0), Vector2(0, 1), Vector2(0, 2), Vector2(1, 0), r)); CHECK(r.is_equal_approx(Vector2(2, 2))); CHECK(Geometry2D::line_intersects_line(Vector2(-1, 1), Vector2(1, -1), Vector2(4, 1), Vector2(-1, -1), r)); CHECK(r.is_equal_approx(Vector2(1.5, -1.5))); CHECK(Geometry2D::line_intersects_line(Vector2(-1, 0), Vector2(-1, -1), Vector2(1, 0), Vector2(1, -1), r)); CHECK(r.is_equal_approx(Vector2(0, 1))); CHECK_FALSE_MESSAGE( Geometry2D::line_intersects_line(Vector2(-1, 1), Vector2(1, -1), Vector2(0, 1), Vector2(1, -1), r), "Parallel lines should not intersect."); } TEST_CASE("[Geometry2D] Segment intersection") { Vector2 r; CHECK(Geometry2D::segment_intersects_segment(Vector2(-1, 1), Vector2(1, -1), Vector2(1, 1), Vector2(-1, -1), &r)); CHECK(r.is_equal_approx(Vector2(0, 0))); CHECK_FALSE(Geometry2D::segment_intersects_segment(Vector2(-1, 1), Vector2(1, -1), Vector2(1, 1), Vector2(0.1, 0.1), &r)); CHECK_FALSE(Geometry2D::segment_intersects_segment(Vector2(-1, 1), Vector2(1, -1), Vector2(0.1, 0.1), Vector2(1, 1), &r)); CHECK_FALSE_MESSAGE( Geometry2D::segment_intersects_segment(Vector2(-1, 1), Vector2(1, -1), Vector2(0, 1), Vector2(2, -1), &r), "Parallel segments should not intersect."); CHECK_FALSE_MESSAGE( Geometry2D::segment_intersects_segment(Vector2(1, 2), Vector2(3, 2), Vector2(0, 2), Vector2(-2, 2), &r), "Non-overlapping collinear segments should not intersect."); CHECK_MESSAGE( Geometry2D::segment_intersects_segment(Vector2(0, 0), Vector2(0, 1), Vector2(0, 0), Vector2(1, 0), &r), "Touching segments should intersect."); CHECK(r.is_equal_approx(Vector2(0, 0))); CHECK_MESSAGE( Geometry2D::segment_intersects_segment(Vector2(0, 1), Vector2(0, 0), Vector2(0, 0), Vector2(1, 0), &r), "Touching segments should intersect."); CHECK(r.is_equal_approx(Vector2(0, 0))); } TEST_CASE("[Geometry2D] Segment intersection with circle") { real_t minus_one = -1.0; real_t zero = 0.0; real_t one_quarter = 0.25; real_t three_quarters = 0.75; real_t one = 1.0; CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(0, 0), Vector2(4, 0), Vector2(0, 0), 1.0) == doctest::Approx(one_quarter), "Segment from inside to outside of circle should intersect it."); CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(4, 0), Vector2(0, 0), Vector2(0, 0), 1.0) == doctest::Approx(three_quarters), "Segment from outside to inside of circle should intersect it."); CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(-2, 0), Vector2(2, 0), Vector2(0, 0), 1.0) == doctest::Approx(one_quarter), "Segment running through circle should intersect it."); CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(2, 0), Vector2(-2, 0), Vector2(0, 0), 1.0) == doctest::Approx(one_quarter), "Segment running through circle should intersect it."); CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(0, 0), Vector2(1, 0), Vector2(0, 0), 1.0) == doctest::Approx(one), "Segment starting inside the circle and ending on the circle should intersect it"); CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(1, 0), Vector2(0, 0), Vector2(0, 0), 1.0) == doctest::Approx(zero), "Segment starting on the circle and going inwards should intersect it"); CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(1, 0), Vector2(2, 0), Vector2(0, 0), 1.0) == doctest::Approx(zero), "Segment starting on the circle and going outwards should intersect it"); CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(2, 0), Vector2(1, 0), Vector2(0, 0), 1.0) == doctest::Approx(one), "Segment starting outside the circle and ending on the circle intersect it"); CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(-1, 0), Vector2(1, 0), Vector2(0, 0), 2.0) == doctest::Approx(minus_one), "Segment completely within the circle should not intersect it"); CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(1, 0), Vector2(-1, 0), Vector2(0, 0), 2.0) == doctest::Approx(minus_one), "Segment completely within the circle should not intersect it"); CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(2, 0), Vector2(3, 0), Vector2(0, 0), 1.0) == doctest::Approx(minus_one), "Segment completely outside the circle should not intersect it"); CHECK_MESSAGE( Geometry2D::segment_intersects_circle(Vector2(3, 0), Vector2(2, 0), Vector2(0, 0), 1.0) == doctest::Approx(minus_one), "Segment completely outside the circle should not intersect it"); } TEST_CASE("[Geometry2D] Segment intersection with polygon") { Vector a; a.push_back(Point2(-2, 2)); a.push_back(Point2(3, 4)); a.push_back(Point2(1, 1)); a.push_back(Point2(2, -2)); a.push_back(Point2(-1, -1)); CHECK_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(0, 2), Vector2(2, 2), a), "Segment from inside to outside of polygon should intersect it."); CHECK_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(2, 2), Vector2(0, 2), a), "Segment from outside to inside of polygon should intersect it."); CHECK_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(2, 4), Vector2(3, 3), a), "Segment running through polygon should intersect it."); CHECK_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(3, 3), Vector2(2, 4), a), "Segment running through polygon should intersect it."); CHECK_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(0, 0), Vector2(1, 1), a), "Segment starting inside the polygon and ending on the polygon should intersect it"); CHECK_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(1, 1), Vector2(0, 0), a), "Segment starting on the polygon and going inwards should intersect it"); CHECK_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(-2, 2), Vector2(-2, -1), a), "Segment starting on the polygon and going outwards should intersect it"); CHECK_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(-2, 1), Vector2(-2, 2), a), "Segment starting outside the polygon and ending on the polygon intersect it"); CHECK_FALSE_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(-1, 2), Vector2(1, -1), a), "Segment completely within the polygon should not intersect it"); CHECK_FALSE_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(1, -1), Vector2(-1, 2), a), "Segment completely within the polygon should not intersect it"); CHECK_FALSE_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(2, 2), Vector2(2, -1), a), "Segment completely outside the polygon should not intersect it"); CHECK_FALSE_MESSAGE( Geometry2D::is_segment_intersecting_polygon(Vector2(2, -1), Vector2(2, 2), a), "Segment completely outside the polygon should not intersect it"); } TEST_CASE("[Geometry2D] Closest point to segment") { Vector2 s[] = { Vector2(-4, -4), Vector2(4, 4) }; CHECK(Geometry2D::get_closest_point_to_segment(Vector2(4.1, 4.1), s).is_equal_approx(Vector2(4, 4))); CHECK(Geometry2D::get_closest_point_to_segment(Vector2(-4.1, -4.1), s).is_equal_approx(Vector2(-4, -4))); CHECK(Geometry2D::get_closest_point_to_segment(Vector2(-1, 1), s).is_equal_approx(Vector2(0, 0))); Vector2 t[] = { Vector2(1, -2), Vector2(1, -2) }; CHECK_MESSAGE( Geometry2D::get_closest_point_to_segment(Vector2(-3, 4), t).is_equal_approx(Vector2(1, -2)), "Line segment is only a single point. This point should be the closest."); } TEST_CASE("[Geometry2D] Closest point to uncapped segment") { Vector2 s[] = { Vector2(-4, -4), Vector2(4, 4) }; CHECK(Geometry2D::get_closest_point_to_segment_uncapped(Vector2(-1, 1), s).is_equal_approx(Vector2(0, 0))); CHECK(Geometry2D::get_closest_point_to_segment_uncapped(Vector2(-4, -6), s).is_equal_approx(Vector2(-5, -5))); CHECK(Geometry2D::get_closest_point_to_segment_uncapped(Vector2(4, 6), s).is_equal_approx(Vector2(5, 5))); } TEST_CASE("[Geometry2D] Closest points between segments") { Vector2 c1, c2; // Basis Path Testing suite SUBCASE("[Geometry2D] Both segments degenerate to a point") { Geometry2D::get_closest_points_between_segments(Vector2(0, 0), Vector2(0, 0), Vector2(0, 0), Vector2(0, 0), c1, c2); CHECK(c1.is_equal_approx(Vector2(0, 0))); CHECK(c2.is_equal_approx(Vector2(0, 0))); } SUBCASE("[Geometry2D] Closest point on second segment trajectory is above [0,1]") { Geometry2D::get_closest_points_between_segments(Vector2(50, -25), Vector2(50, -10), Vector2(-50, 10), Vector2(-40, 10), c1, c2); CHECK(c1.is_equal_approx(Vector2(50, -10))); CHECK(c2.is_equal_approx(Vector2(-40, 10))); } SUBCASE("[Geometry2D] Parallel segments") { Geometry2D::get_closest_points_between_segments(Vector2(2, 1), Vector2(4, 3), Vector2(2, 3), Vector2(4, 5), c1, c2); CHECK(c1.is_equal_approx(Vector2(3, 2))); CHECK(c2.is_equal_approx(Vector2(2, 3))); } SUBCASE("[Geometry2D] Closest point on second segment trajectory is within [0,1]") { Geometry2D::get_closest_points_between_segments(Vector2(2, 4), Vector2(2, 3), Vector2(1, 1), Vector2(4, 4), c1, c2); CHECK(c1.is_equal_approx(Vector2(2, 3))); CHECK(c2.is_equal_approx(Vector2(2.5, 2.5))); } SUBCASE("[Geometry2D] Closest point on second segment trajectory is below [0,1]") { Geometry2D::get_closest_points_between_segments(Vector2(-20, -20), Vector2(-10, -40), Vector2(10, 25), Vector2(25, 40), c1, c2); CHECK(c1.is_equal_approx(Vector2(-20, -20))); CHECK(c2.is_equal_approx(Vector2(10, 25))); } SUBCASE("[Geometry2D] Second segment degenerates to a point") { Geometry2D::get_closest_points_between_segments(Vector2(1, 2), Vector2(2, 1), Vector2(3, 3), Vector2(3, 3), c1, c2); CHECK(c1.is_equal_approx(Vector2(1.5, 1.5))); CHECK(c2.is_equal_approx(Vector2(3, 3))); } SUBCASE("[Geometry2D] First segment degenerates to a point") { Geometry2D::get_closest_points_between_segments(Vector2(1, 1), Vector2(1, 1), Vector2(2, 2), Vector2(4, 4), c1, c2); CHECK(c1.is_equal_approx(Vector2(1, 1))); CHECK(c2.is_equal_approx(Vector2(2, 2))); } // End Basis Path Testing suite SUBCASE("[Geometry2D] Segments are equal vectors") { Geometry2D::get_closest_points_between_segments(Vector2(2, 2), Vector2(3, 3), Vector2(4, 4), Vector2(4, 5), c1, c2); CHECK(c1.is_equal_approx(Vector2(3, 3))); CHECK(c2.is_equal_approx(Vector2(4, 4))); } SUBCASE("[Geometry2D] Standard case") { Geometry2D::get_closest_points_between_segments(Vector2(0, 1), Vector2(-2, -1), Vector2(0, 0), Vector2(2, -2), c1, c2); CHECK(c1.is_equal_approx(Vector2(-0.5, 0.5))); CHECK(c2.is_equal_approx(Vector2(0, 0))); } SUBCASE("[Geometry2D] Segments intersect") { Geometry2D::get_closest_points_between_segments(Vector2(-1, 1), Vector2(1, -1), Vector2(1, 1), Vector2(-1, -1), c1, c2); CHECK(c1.is_equal_approx(Vector2(0, 0))); CHECK(c2.is_equal_approx(Vector2(0, 0))); } } TEST_CASE("[Geometry2D] Make atlas") { Vector result; Size2i size; Vector r; r.push_back(Size2i(2, 2)); Geometry2D::make_atlas(r, result, size); CHECK(size == Size2i(2, 2)); CHECK(result.size() == r.size()); r.clear(); result.clear(); r.push_back(Size2i(1, 2)); r.push_back(Size2i(3, 4)); r.push_back(Size2i(5, 6)); r.push_back(Size2i(7, 8)); Geometry2D::make_atlas(r, result, size); CHECK(result.size() == r.size()); } TEST_CASE("[Geometry2D] Polygon intersection") { Vector a; Vector b; Vector> r; a.push_back(Point2(30, 60)); a.push_back(Point2(70, 5)); a.push_back(Point2(200, 40)); a.push_back(Point2(80, 200)); SUBCASE("[Geometry2D] Both polygons are empty") { r = Geometry2D::intersect_polygons(Vector(), Vector()); CHECK_MESSAGE(r.is_empty(), "Both polygons are empty. The intersection should also be empty."); } SUBCASE("[Geometry2D] One polygon is empty") { r = Geometry2D::intersect_polygons(a, b); REQUIRE_MESSAGE(r.is_empty(), "One polygon is empty. The intersection should also be empty."); } SUBCASE("[Geometry2D] Basic intersection") { b.push_back(Point2(200, 300)); b.push_back(Point2(90, 200)); b.push_back(Point2(50, 100)); b.push_back(Point2(200, 90)); r = Geometry2D::intersect_polygons(a, b); REQUIRE_MESSAGE(r.size() == 1, "The polygons should intersect each other with 1 resulting intersection polygon."); REQUIRE_MESSAGE(r[0].size() == 3, "The resulting intersection polygon should have 3 vertices."); CHECK(r[0][0].is_equal_approx(Point2(86.52174, 191.30436))); CHECK(r[0][1].is_equal_approx(Point2(50, 100))); CHECK(r[0][2].is_equal_approx(Point2(160.52632, 92.63157))); } SUBCASE("[Geometry2D] Intersection with one polygon being completely inside the other polygon") { b.push_back(Point2(80, 100)); b.push_back(Point2(50, 50)); b.push_back(Point2(150, 50)); r = Geometry2D::intersect_polygons(a, b); REQUIRE_MESSAGE(r.size() == 1, "The polygons should intersect each other with 1 resulting intersection polygon."); REQUIRE_MESSAGE(r[0].size() == 3, "The resulting intersection polygon should have 3 vertices."); CHECK(r[0][0].is_equal_approx(b[0])); CHECK(r[0][1].is_equal_approx(b[1])); CHECK(r[0][2].is_equal_approx(b[2])); } SUBCASE("[Geometry2D] No intersection with 2 non-empty polygons") { b.push_back(Point2(150, 150)); b.push_back(Point2(250, 100)); b.push_back(Point2(300, 200)); r = Geometry2D::intersect_polygons(a, b); REQUIRE_MESSAGE(r.is_empty(), "The polygons should not intersect each other."); } SUBCASE("[Geometry2D] Intersection with 2 resulting polygons") { a.clear(); a.push_back(Point2(70, 5)); a.push_back(Point2(140, 7)); a.push_back(Point2(100, 52)); a.push_back(Point2(170, 50)); a.push_back(Point2(60, 125)); b.push_back(Point2(70, 105)); b.push_back(Point2(115, 55)); b.push_back(Point2(90, 15)); b.push_back(Point2(160, 50)); r = Geometry2D::intersect_polygons(a, b); REQUIRE_MESSAGE(r.size() == 2, "The polygons should intersect each other with 2 resulting intersection polygons."); REQUIRE_MESSAGE(r[0].size() == 4, "The resulting intersection polygon should have 4 vertices."); CHECK(r[0][0].is_equal_approx(Point2(70, 105))); CHECK(r[0][1].is_equal_approx(Point2(115, 55))); CHECK(r[0][2].is_equal_approx(Point2(112.894737, 51.63158))); CHECK(r[0][3].is_equal_approx(Point2(159.509537, 50.299728))); REQUIRE_MESSAGE(r[1].size() == 3, "The intersection polygon should have 3 vertices."); CHECK(r[1][0].is_equal_approx(Point2(119.692307, 29.846149))); CHECK(r[1][1].is_equal_approx(Point2(107.706421, 43.33028))); CHECK(r[1][2].is_equal_approx(Point2(90, 15))); } } TEST_CASE("[Geometry2D] Merge polygons") { Vector a; Vector b; Vector> r; a.push_back(Point2(225, 180)); a.push_back(Point2(160, 230)); a.push_back(Point2(20, 212)); a.push_back(Point2(50, 115)); SUBCASE("[Geometry2D] Both polygons are empty") { r = Geometry2D::merge_polygons(Vector(), Vector()); REQUIRE_MESSAGE(r.is_empty(), "Both polygons are empty. The union should also be empty."); } SUBCASE("[Geometry2D] One polygon is empty") { r = Geometry2D::merge_polygons(a, b); REQUIRE_MESSAGE(r.size() == 1, "One polygon is non-empty. There should be 1 resulting merged polygon."); REQUIRE_MESSAGE(r[0].size() == 4, "The resulting merged polygon should have 4 vertices."); CHECK(r[0][0].is_equal_approx(a[0])); CHECK(r[0][1].is_equal_approx(a[1])); CHECK(r[0][2].is_equal_approx(a[2])); CHECK(r[0][3].is_equal_approx(a[3])); } SUBCASE("[Geometry2D] Basic merge with 2 polygons") { b.push_back(Point2(180, 190)); b.push_back(Point2(60, 140)); b.push_back(Point2(160, 80)); r = Geometry2D::merge_polygons(a, b); REQUIRE_MESSAGE(r.size() == 1, "The merged polygons should result in 1 polygon."); REQUIRE_MESSAGE(r[0].size() == 7, "The resulting merged polygon should have 7 vertices."); CHECK(r[0][0].is_equal_approx(Point2(174.791077, 161.350967))); CHECK(r[0][1].is_equal_approx(Point2(225, 180))); CHECK(r[0][2].is_equal_approx(Point2(160, 230))); CHECK(r[0][3].is_equal_approx(Point2(20, 212))); CHECK(r[0][4].is_equal_approx(Point2(50, 115))); CHECK(r[0][5].is_equal_approx(Point2(81.911758, 126.852943))); CHECK(r[0][6].is_equal_approx(Point2(160, 80))); } SUBCASE("[Geometry2D] Merge with 2 resulting merged polygons (outline and hole)") { b.push_back(Point2(180, 190)); b.push_back(Point2(140, 125)); b.push_back(Point2(60, 140)); b.push_back(Point2(160, 80)); r = Geometry2D::merge_polygons(a, b); REQUIRE_MESSAGE(r.size() == 2, "The merged polygons should result in 2 polygons."); REQUIRE_MESSAGE(!Geometry2D::is_polygon_clockwise(r[0]), "The merged polygon (outline) should be counter-clockwise."); REQUIRE_MESSAGE(r[0].size() == 7, "The resulting merged polygon (outline) should have 7 vertices."); CHECK(r[0][0].is_equal_approx(Point2(174.791077, 161.350967))); CHECK(r[0][1].is_equal_approx(Point2(225, 180))); CHECK(r[0][2].is_equal_approx(Point2(160, 230))); CHECK(r[0][3].is_equal_approx(Point2(20, 212))); CHECK(r[0][4].is_equal_approx(Point2(50, 115))); CHECK(r[0][5].is_equal_approx(Point2(81.911758, 126.852943))); CHECK(r[0][6].is_equal_approx(Point2(160, 80))); REQUIRE_MESSAGE(Geometry2D::is_polygon_clockwise(r[1]), "The resulting merged polygon (hole) should be clockwise."); REQUIRE_MESSAGE(r[1].size() == 3, "The resulting merged polygon (hole) should have 3 vertices."); CHECK(r[1][0].is_equal_approx(Point2(98.083069, 132.859421))); CHECK(r[1][1].is_equal_approx(Point2(158.689453, 155.370377))); CHECK(r[1][2].is_equal_approx(Point2(140, 125))); } } TEST_CASE("[Geometry2D] Clip polygons") { Vector a; Vector b; Vector> r; a.push_back(Point2(225, 180)); a.push_back(Point2(160, 230)); a.push_back(Point2(20, 212)); a.push_back(Point2(50, 115)); SUBCASE("[Geometry2D] Both polygons are empty") { r = Geometry2D::clip_polygons(Vector(), Vector()); CHECK_MESSAGE(r.is_empty(), "Both polygons are empty. The clip should also be empty."); } SUBCASE("[Geometry2D] Basic clip with one result polygon") { b.push_back(Point2(250, 170)); b.push_back(Point2(175, 270)); b.push_back(Point2(120, 260)); b.push_back(Point2(25, 80)); r = Geometry2D::clip_polygons(a, b); REQUIRE_MESSAGE(r.size() == 1, "The clipped polygons should result in 1 polygon."); REQUIRE_MESSAGE(r[0].size() == 3, "The resulting clipped polygon should have 3 vertices."); CHECK(r[0][0].is_equal_approx(Point2(100.102173, 222.298843))); CHECK(r[0][1].is_equal_approx(Point2(20, 212))); CHECK(r[0][2].is_equal_approx(Point2(47.588089, 122.798492))); } SUBCASE("[Geometry2D] Polygon b completely overlaps polygon a") { b.push_back(Point2(250, 170)); b.push_back(Point2(175, 270)); b.push_back(Point2(10, 210)); b.push_back(Point2(55, 80)); r = Geometry2D::clip_polygons(a, b); CHECK_MESSAGE(r.is_empty(), "Polygon 'b' completely overlaps polygon 'a'. This should result in no clipped polygons."); } SUBCASE("[Geometry2D] Polygon a completely overlaps polygon b") { b.push_back(Point2(150, 200)); b.push_back(Point2(65, 190)); b.push_back(Point2(80, 140)); r = Geometry2D::clip_polygons(a, b); REQUIRE_MESSAGE(r.size() == 2, "Polygon 'a' completely overlaps polygon 'b'. This should result in 2 clipped polygons."); REQUIRE_MESSAGE(r[0].size() == 4, "The resulting clipped polygon should have 4 vertices."); REQUIRE_MESSAGE(!Geometry2D::is_polygon_clockwise(r[0]), "The resulting clipped polygon (outline) should be counter-clockwise."); CHECK(r[0][0].is_equal_approx(a[0])); CHECK(r[0][1].is_equal_approx(a[1])); CHECK(r[0][2].is_equal_approx(a[2])); CHECK(r[0][3].is_equal_approx(a[3])); REQUIRE_MESSAGE(r[1].size() == 3, "The resulting clipped polygon should have 3 vertices."); REQUIRE_MESSAGE(Geometry2D::is_polygon_clockwise(r[1]), "The resulting clipped polygon (hole) should be clockwise."); CHECK(r[1][0].is_equal_approx(b[1])); CHECK(r[1][1].is_equal_approx(b[0])); CHECK(r[1][2].is_equal_approx(b[2])); } } TEST_CASE("[Geometry2D] Exclude polygons") { Vector a; Vector b; Vector> r; a.push_back(Point2(225, 180)); a.push_back(Point2(160, 230)); a.push_back(Point2(20, 212)); a.push_back(Point2(50, 115)); SUBCASE("[Geometry2D] Both polygons are empty") { r = Geometry2D::exclude_polygons(Vector(), Vector()); CHECK_MESSAGE(r.is_empty(), "Both polygons are empty. The excluded polygon should also be empty."); } SUBCASE("[Geometry2D] One polygon is empty") { r = Geometry2D::exclude_polygons(a, b); REQUIRE_MESSAGE(r.size() == 1, "One polygon is non-empty. There should be 1 resulting excluded polygon."); REQUIRE_MESSAGE(r[0].size() == 4, "The resulting excluded polygon should have 4 vertices."); CHECK(r[0][0].is_equal_approx(a[0])); CHECK(r[0][1].is_equal_approx(a[1])); CHECK(r[0][2].is_equal_approx(a[2])); CHECK(r[0][3].is_equal_approx(a[3])); } SUBCASE("[Geometry2D] Exclude with 2 resulting polygons (outline and hole)") { b.push_back(Point2(140, 160)); b.push_back(Point2(150, 220)); b.push_back(Point2(40, 200)); b.push_back(Point2(60, 140)); r = Geometry2D::exclude_polygons(a, b); REQUIRE_MESSAGE(r.size() == 2, "There should be 2 resulting excluded polygons (outline and hole)."); REQUIRE_MESSAGE(r[0].size() == 4, "The resulting excluded polygon should have 4 vertices."); REQUIRE_MESSAGE(!Geometry2D::is_polygon_clockwise(r[0]), "The resulting excluded polygon (outline) should be counter-clockwise."); CHECK(r[0][0].is_equal_approx(a[0])); CHECK(r[0][1].is_equal_approx(a[1])); CHECK(r[0][2].is_equal_approx(a[2])); CHECK(r[0][3].is_equal_approx(a[3])); REQUIRE_MESSAGE(r[1].size() == 4, "The resulting excluded polygon should have 4 vertices."); REQUIRE_MESSAGE(Geometry2D::is_polygon_clockwise(r[1]), "The resulting excluded polygon (hole) should be clockwise."); CHECK(r[1][0].is_equal_approx(Point2(40, 200))); CHECK(r[1][1].is_equal_approx(Point2(150, 220))); CHECK(r[1][2].is_equal_approx(Point2(140, 160))); CHECK(r[1][3].is_equal_approx(Point2(60, 140))); } } TEST_CASE("[Geometry2D] Intersect polyline with polygon") { Vector l; Vector p; Vector> r; l.push_back(Vector2(100, 90)); l.push_back(Vector2(120, 250)); p.push_back(Vector2(225, 180)); p.push_back(Vector2(160, 230)); p.push_back(Vector2(20, 212)); p.push_back(Vector2(50, 115)); SUBCASE("[Geometry2D] Both line and polygon are empty") { r = Geometry2D::intersect_polyline_with_polygon(Vector(), Vector()); CHECK_MESSAGE(r.is_empty(), "Both line and polygon are empty. The intersection line should also be empty."); } SUBCASE("[Geometry2D] Line is non-empty and polygon is empty") { r = Geometry2D::intersect_polyline_with_polygon(l, Vector()); CHECK_MESSAGE(r.is_empty(), "The polygon is empty while the line is non-empty. The intersection line should be empty."); } SUBCASE("[Geometry2D] Basic intersection with 1 resulting intersection line") { r = Geometry2D::intersect_polyline_with_polygon(l, p); REQUIRE_MESSAGE(r.size() == 1, "There should be 1 resulting intersection line."); REQUIRE_MESSAGE(r[0].size() == 2, "The resulting intersection line should have 2 vertices."); CHECK(r[0][0].is_equal_approx(Vector2(105.711609, 135.692886))); CHECK(r[0][1].is_equal_approx(Vector2(116.805809, 224.446457))); } SUBCASE("[Geometry2D] Complex intersection with 2 resulting intersection lines") { l.clear(); l.push_back(Vector2(100, 90)); l.push_back(Vector2(190, 255)); l.push_back(Vector2(135, 260)); l.push_back(Vector2(57, 200)); l.push_back(Vector2(50, 170)); l.push_back(Vector2(15, 155)); r = Geometry2D::intersect_polyline_with_polygon(l, p); REQUIRE_MESSAGE(r.size() == 2, "There should be 2 resulting intersection lines."); REQUIRE_MESSAGE(r[0].size() == 2, "The resulting intersection line should have 2 vertices."); CHECK(r[0][0].is_equal_approx(Vector2(129.804565, 144.641693))); CHECK(r[0][1].is_equal_approx(Vector2(171.527084, 221.132996))); REQUIRE_MESSAGE(r[1].size() == 4, "The resulting intersection line should have 4 vertices."); CHECK(r[1][0].is_equal_approx(Vector2(83.15609, 220.120087))); CHECK(r[1][1].is_equal_approx(Vector2(57, 200))); CHECK(r[1][2].is_equal_approx(Vector2(50, 170))); CHECK(r[1][3].is_equal_approx(Vector2(34.980492, 163.563065))); } } TEST_CASE("[Geometry2D] Clip polyline with polygon") { Vector l; Vector p; Vector> r; l.push_back(Vector2(70, 140)); l.push_back(Vector2(160, 320)); p.push_back(Vector2(225, 180)); p.push_back(Vector2(160, 230)); p.push_back(Vector2(20, 212)); p.push_back(Vector2(50, 115)); SUBCASE("[Geometry2D] Both line and polygon are empty") { r = Geometry2D::clip_polyline_with_polygon(Vector(), Vector()); CHECK_MESSAGE(r.is_empty(), "Both line and polygon are empty. The clipped line should also be empty."); } SUBCASE("[Geometry2D] Polygon is empty and line is non-empty") { r = Geometry2D::clip_polyline_with_polygon(l, Vector()); REQUIRE_MESSAGE(r.size() == 1, "There should be 1 resulting clipped line."); REQUIRE_MESSAGE(r[0].size() == 2, "The resulting clipped line should have 2 vertices."); CHECK(r[0][0].is_equal_approx(l[0])); CHECK(r[0][1].is_equal_approx(l[1])); } SUBCASE("[Geometry2D] Basic clip with 1 resulting clipped line") { r = Geometry2D::clip_polyline_with_polygon(l, p); REQUIRE_MESSAGE(r.size() == 1, "There should be 1 resulting clipped line."); REQUIRE_MESSAGE(r[0].size() == 2, "The resulting clipped line should have 2 vertices."); CHECK(r[0][0].is_equal_approx(Vector2(111.908401, 223.816803))); CHECK(r[0][1].is_equal_approx(Vector2(160, 320))); } SUBCASE("[Geometry2D] Complex clip with 2 resulting clipped lines") { l.clear(); l.push_back(Vector2(55, 70)); l.push_back(Vector2(50, 190)); l.push_back(Vector2(120, 165)); l.push_back(Vector2(122, 250)); l.push_back(Vector2(160, 320)); r = Geometry2D::clip_polyline_with_polygon(l, p); REQUIRE_MESSAGE(r.size() == 2, "There should be 2 resulting clipped lines."); REQUIRE_MESSAGE(r[0].size() == 3, "The resulting clipped line should have 3 vertices."); CHECK(r[0][0].is_equal_approx(Vector2(160, 320))); CHECK(r[0][1].is_equal_approx(Vector2(122, 250))); CHECK(r[0][2].is_equal_approx(Vector2(121.412682, 225.038757))); REQUIRE_MESSAGE(r[1].size() == 2, "The resulting clipped line should have 2 vertices."); CHECK(r[1][0].is_equal_approx(Vector2(53.07737, 116.143021))); CHECK(r[1][1].is_equal_approx(Vector2(55, 70))); } } TEST_CASE("[Geometry2D] Convex hull") { Vector a; Vector r; a.push_back(Point2(-4, -8)); a.push_back(Point2(-10, -4)); a.push_back(Point2(8, 2)); a.push_back(Point2(-6, 10)); a.push_back(Point2(-12, 4)); a.push_back(Point2(10, -8)); a.push_back(Point2(4, 8)); SUBCASE("[Geometry2D] No points") { r = Geometry2D::convex_hull(Vector()); CHECK_MESSAGE(r.is_empty(), "The convex hull should be empty if there are no input points."); } SUBCASE("[Geometry2D] Single point") { Vector b; b.push_back(Point2(4, -3)); r = Geometry2D::convex_hull(b); REQUIRE_MESSAGE(r.size() == 1, "Convex hull should contain 1 point."); CHECK(r[0].is_equal_approx(b[0])); } SUBCASE("[Geometry2D] All points form the convex hull") { r = Geometry2D::convex_hull(a); REQUIRE_MESSAGE(r.size() == 8, "Convex hull should contain 8 points."); CHECK(r[0].is_equal_approx(Point2(-12, 4))); CHECK(r[1].is_equal_approx(Point2(-10, -4))); CHECK(r[2].is_equal_approx(Point2(-4, -8))); CHECK(r[3].is_equal_approx(Point2(10, -8))); CHECK(r[4].is_equal_approx(Point2(8, 2))); CHECK(r[5].is_equal_approx(Point2(4, 8))); CHECK(r[6].is_equal_approx(Point2(-6, 10))); CHECK(r[7].is_equal_approx(Point2(-12, 4))); } SUBCASE("[Geometry2D] Add extra points inside original convex hull") { a.push_back(Point2(-4, -8)); a.push_back(Point2(0, 0)); a.push_back(Point2(0, 8)); a.push_back(Point2(-10, -3)); a.push_back(Point2(9, -4)); a.push_back(Point2(6, 4)); r = Geometry2D::convex_hull(a); REQUIRE_MESSAGE(r.size() == 8, "Convex hull should contain 8 points."); CHECK(r[0].is_equal_approx(Point2(-12, 4))); CHECK(r[1].is_equal_approx(Point2(-10, -4))); CHECK(r[2].is_equal_approx(Point2(-4, -8))); CHECK(r[3].is_equal_approx(Point2(10, -8))); CHECK(r[4].is_equal_approx(Point2(8, 2))); CHECK(r[5].is_equal_approx(Point2(4, 8))); CHECK(r[6].is_equal_approx(Point2(-6, 10))); CHECK(r[7].is_equal_approx(Point2(-12, 4))); } SUBCASE("[Geometry2D] Add extra points on border of original convex hull") { a.push_back(Point2(9, -3)); a.push_back(Point2(-2, -8)); r = Geometry2D::convex_hull(a); REQUIRE_MESSAGE(r.size() == 8, "Convex hull should contain 8 points."); CHECK(r[0].is_equal_approx(Point2(-12, 4))); CHECK(r[1].is_equal_approx(Point2(-10, -4))); CHECK(r[2].is_equal_approx(Point2(-4, -8))); CHECK(r[3].is_equal_approx(Point2(10, -8))); CHECK(r[4].is_equal_approx(Point2(8, 2))); CHECK(r[5].is_equal_approx(Point2(4, 8))); CHECK(r[6].is_equal_approx(Point2(-6, 10))); CHECK(r[7].is_equal_approx(Point2(-12, 4))); } SUBCASE("[Geometry2D] Add extra points outside border of original convex hull") { a.push_back(Point2(-11, -1)); a.push_back(Point2(7, 6)); r = Geometry2D::convex_hull(a); REQUIRE_MESSAGE(r.size() == 10, "Convex hull should contain 10 points."); CHECK(r[0].is_equal_approx(Point2(-12, 4))); CHECK(r[1].is_equal_approx(Point2(-11, -1))); CHECK(r[2].is_equal_approx(Point2(-10, -4))); CHECK(r[3].is_equal_approx(Point2(-4, -8))); CHECK(r[4].is_equal_approx(Point2(10, -8))); CHECK(r[5].is_equal_approx(Point2(8, 2))); CHECK(r[6].is_equal_approx(Point2(7, 6))); CHECK(r[7].is_equal_approx(Point2(4, 8))); CHECK(r[8].is_equal_approx(Point2(-6, 10))); CHECK(r[9].is_equal_approx(Point2(-12, 4))); } } TEST_CASE("[Geometry2D] Bresenham line") { Vector r; SUBCASE("[Geometry2D] Single point") { r = Geometry2D::bresenham_line(Point2i(0, 0), Point2i(0, 0)); REQUIRE_MESSAGE(r.size() == 1, "The Bresenham line should contain exactly one point."); CHECK(r[0] == Vector2i(0, 0)); } SUBCASE("[Geometry2D] Line parallel to x-axis") { r = Geometry2D::bresenham_line(Point2i(1, 2), Point2i(5, 2)); REQUIRE_MESSAGE(r.size() == 5, "The Bresenham line should contain exactly five points."); CHECK(r[0] == Vector2i(1, 2)); CHECK(r[1] == Vector2i(2, 2)); CHECK(r[2] == Vector2i(3, 2)); CHECK(r[3] == Vector2i(4, 2)); CHECK(r[4] == Vector2i(5, 2)); } SUBCASE("[Geometry2D] 45 degree line from the origin") { r = Geometry2D::bresenham_line(Point2i(0, 0), Point2i(4, 4)); REQUIRE_MESSAGE(r.size() == 5, "The Bresenham line should contain exactly five points."); CHECK(r[0] == Vector2i(0, 0)); CHECK(r[1] == Vector2i(1, 1)); CHECK(r[2] == Vector2i(2, 2)); CHECK(r[3] == Vector2i(3, 3)); CHECK(r[4] == Vector2i(4, 4)); } SUBCASE("[Geometry2D] Sloped line going up one unit") { r = Geometry2D::bresenham_line(Point2i(0, 0), Point2i(4, 1)); REQUIRE_MESSAGE(r.size() == 5, "The Bresenham line should contain exactly five points."); CHECK(r[0] == Vector2i(0, 0)); CHECK(r[1] == Vector2i(1, 0)); CHECK(r[2] == Vector2i(2, 0)); CHECK(r[3] == Vector2i(3, 1)); CHECK(r[4] == Vector2i(4, 1)); } SUBCASE("[Geometry2D] Sloped line going up two units") { r = Geometry2D::bresenham_line(Point2i(0, 0), Point2i(4, 2)); REQUIRE_MESSAGE(r.size() == 5, "The Bresenham line should contain exactly five points."); CHECK(r[0] == Vector2i(0, 0)); CHECK(r[1] == Vector2i(1, 0)); CHECK(r[2] == Vector2i(2, 1)); CHECK(r[3] == Vector2i(3, 1)); CHECK(r[4] == Vector2i(4, 2)); } SUBCASE("[Geometry2D] Long sloped line") { r = Geometry2D::bresenham_line(Point2i(0, 0), Point2i(11, 5)); REQUIRE_MESSAGE(r.size() == 12, "The Bresenham line should contain exactly twelve points."); CHECK(r[0] == Vector2i(0, 0)); CHECK(r[1] == Vector2i(1, 0)); CHECK(r[2] == Vector2i(2, 1)); CHECK(r[3] == Vector2i(3, 1)); CHECK(r[4] == Vector2i(4, 2)); CHECK(r[5] == Vector2i(5, 2)); CHECK(r[6] == Vector2i(6, 3)); CHECK(r[7] == Vector2i(7, 3)); CHECK(r[8] == Vector2i(8, 4)); CHECK(r[9] == Vector2i(9, 4)); CHECK(r[10] == Vector2i(10, 5)); CHECK(r[11] == Vector2i(11, 5)); } } } // namespace TestGeometry2D #endif // TEST_GEOMETRY_2D_H