diff options
Diffstat (limited to 'tests')
-rw-r--r-- | tests/core/math/test_aabb.h | 21 | ||||
-rw-r--r-- | tests/core/math/test_basis.h | 34 | ||||
-rw-r--r-- | tests/core/math/test_plane.h | 23 | ||||
-rw-r--r-- | tests/core/math/test_quaternion.h | 57 | ||||
-rw-r--r-- | tests/core/math/test_rect2.h | 21 | ||||
-rw-r--r-- | tests/core/math/test_transform_2d.h | 34 | ||||
-rw-r--r-- | tests/core/math/test_transform_3d.h | 23 | ||||
-rw-r--r-- | tests/core/math/test_vector2.h | 26 | ||||
-rw-r--r-- | tests/core/math/test_vector3.h | 45 | ||||
-rw-r--r-- | tests/core/math/test_vector4.h | 78 |
10 files changed, 362 insertions, 0 deletions
diff --git a/tests/core/math/test_aabb.h b/tests/core/math/test_aabb.h index d5f54a139e..ebaf441abf 100644 --- a/tests/core/math/test_aabb.h +++ b/tests/core/math/test_aabb.h @@ -389,6 +389,27 @@ TEST_CASE("[AABB] Expanding") { aabb.expand(Vector3(-20, 0, 0)).is_equal_approx(AABB(Vector3(-20, 0, -2.5), Vector3(22.5, 7, 6))), "expand() with non-contained point should return the expected AABB."); } + +TEST_CASE("[AABB] Finite number checks") { + const Vector3 x(0, 1, 2); + const Vector3 infinite(NAN, NAN, NAN); + + CHECK_MESSAGE( + AABB(x, x).is_finite(), + "AABB with all components finite should be finite"); + + CHECK_FALSE_MESSAGE( + AABB(infinite, x).is_finite(), + "AABB with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + AABB(x, infinite).is_finite(), + "AABB with one component infinite should not be finite."); + + CHECK_FALSE_MESSAGE( + AABB(infinite, infinite).is_finite(), + "AABB with two components infinite should not be finite."); +} + } // namespace TestAABB #endif // TEST_AABB_H diff --git a/tests/core/math/test_basis.h b/tests/core/math/test_basis.h index b6493c5726..a65020597a 100644 --- a/tests/core/math/test_basis.h +++ b/tests/core/math/test_basis.h @@ -334,6 +334,40 @@ TEST_CASE("[Basis] Set axis angle") { bugNan.get_axis_angle(axis, angle); CHECK(!Math::is_nan(angle)); } + +TEST_CASE("[Basis] Finite number checks") { + const Vector3 x(0, 1, 2); + const Vector3 infinite(NAN, NAN, NAN); + + CHECK_MESSAGE( + Basis(x, x, x).is_finite(), + "Basis with all components finite should be finite"); + + CHECK_FALSE_MESSAGE( + Basis(infinite, x, x).is_finite(), + "Basis with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Basis(x, infinite, x).is_finite(), + "Basis with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Basis(x, x, infinite).is_finite(), + "Basis with one component infinite should not be finite."); + + CHECK_FALSE_MESSAGE( + Basis(infinite, infinite, x).is_finite(), + "Basis with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Basis(infinite, x, infinite).is_finite(), + "Basis with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Basis(x, infinite, infinite).is_finite(), + "Basis with two components infinite should not be finite."); + + CHECK_FALSE_MESSAGE( + Basis(infinite, infinite, infinite).is_finite(), + "Basis with three components infinite should not be finite."); +} + } // namespace TestBasis #endif // TEST_BASIS_H diff --git a/tests/core/math/test_plane.h b/tests/core/math/test_plane.h index d81a5af1ce..84d9a0ff7d 100644 --- a/tests/core/math/test_plane.h +++ b/tests/core/math/test_plane.h @@ -167,6 +167,29 @@ TEST_CASE("[Plane] Intersection") { vec_out.is_equal_approx(Vector3(1, 1, 1)), "intersects_segment() should modify vec_out to the expected result."); } + +TEST_CASE("[Plane] Finite number checks") { + const Vector3 x(0, 1, 2); + const Vector3 infinite_vec(NAN, NAN, NAN); + const real_t y = 0; + const real_t infinite_y = NAN; + + CHECK_MESSAGE( + Plane(x, y).is_finite(), + "Plane with all components finite should be finite"); + + CHECK_FALSE_MESSAGE( + Plane(x, infinite_y).is_finite(), + "Plane with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Plane(infinite_vec, y).is_finite(), + "Plane with one component infinite should not be finite."); + + CHECK_FALSE_MESSAGE( + Plane(infinite_vec, infinite_y).is_finite(), + "Plane with two components infinite should not be finite."); +} + } // namespace TestPlane #endif // TEST_PLANE_H diff --git a/tests/core/math/test_quaternion.h b/tests/core/math/test_quaternion.h index 63d30759bb..d1912cbf42 100644 --- a/tests/core/math/test_quaternion.h +++ b/tests/core/math/test_quaternion.h @@ -384,6 +384,63 @@ TEST_CASE("[Stress][Quaternion] Many vector xforms") { } } +TEST_CASE("[Quaternion] Finite number checks") { + const real_t x = NAN; + + CHECK_MESSAGE( + Quaternion(0, 1, 2, 3).is_finite(), + "Quaternion with all components finite should be finite"); + + CHECK_FALSE_MESSAGE( + Quaternion(x, 1, 2, 3).is_finite(), + "Quaternion with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Quaternion(0, x, 2, 3).is_finite(), + "Quaternion with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Quaternion(0, 1, x, 3).is_finite(), + "Quaternion with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Quaternion(0, 1, 2, x).is_finite(), + "Quaternion with one component infinite should not be finite."); + + CHECK_FALSE_MESSAGE( + Quaternion(x, x, 2, 3).is_finite(), + "Quaternion with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Quaternion(x, 1, x, 3).is_finite(), + "Quaternion with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Quaternion(x, 1, 2, x).is_finite(), + "Quaternion with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Quaternion(0, x, x, 3).is_finite(), + "Quaternion with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Quaternion(0, x, 2, x).is_finite(), + "Quaternion with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Quaternion(0, 1, x, x).is_finite(), + "Quaternion with two components infinite should not be finite."); + + CHECK_FALSE_MESSAGE( + Quaternion(0, x, x, x).is_finite(), + "Quaternion with three components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Quaternion(x, 1, x, x).is_finite(), + "Quaternion with three components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Quaternion(x, x, 2, x).is_finite(), + "Quaternion with three components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Quaternion(x, x, x, 3).is_finite(), + "Quaternion with three components infinite should not be finite."); + + CHECK_FALSE_MESSAGE( + Quaternion(x, x, x, x).is_finite(), + "Quaternion with four components infinite should not be finite."); +} + } // namespace TestQuaternion #endif // TEST_QUATERNION_H diff --git a/tests/core/math/test_rect2.h b/tests/core/math/test_rect2.h index 6323b214db..d784875c1c 100644 --- a/tests/core/math/test_rect2.h +++ b/tests/core/math/test_rect2.h @@ -300,6 +300,27 @@ TEST_CASE("[Rect2] Merging") { Rect2(0, 100, 1280, 720).merge(Rect2(-4000, -4000, 100, 100)).is_equal_approx(Rect2(-4000, -4000, 5280, 4820)), "merge() with non-enclosed Rect2 should return the expected result."); } + +TEST_CASE("[Rect2] Finite number checks") { + const Vector2 x(0, 1); + const Vector2 infinite(NAN, NAN); + + CHECK_MESSAGE( + Rect2(x, x).is_finite(), + "Rect2 with all components finite should be finite"); + + CHECK_FALSE_MESSAGE( + Rect2(infinite, x).is_finite(), + "Rect2 with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Rect2(x, infinite).is_finite(), + "Rect2 with one component infinite should not be finite."); + + CHECK_FALSE_MESSAGE( + Rect2(infinite, infinite).is_finite(), + "Rect2 with two components infinite should not be finite."); +} + } // namespace TestRect2 #endif // TEST_RECT2_H diff --git a/tests/core/math/test_transform_2d.h b/tests/core/math/test_transform_2d.h index 697bf63fc5..ab51bcd7da 100644 --- a/tests/core/math/test_transform_2d.h +++ b/tests/core/math/test_transform_2d.h @@ -83,6 +83,40 @@ TEST_CASE("[Transform2D] rotation") { CHECK(orig.rotated(phi) == R * orig); CHECK(orig.rotated_local(phi) == orig * R); } + +TEST_CASE("[Transform2D] Finite number checks") { + const Vector2 x(0, 1); + const Vector2 infinite(NAN, NAN); + + CHECK_MESSAGE( + Transform2D(x, x, x).is_finite(), + "Transform2D with all components finite should be finite"); + + CHECK_FALSE_MESSAGE( + Transform2D(infinite, x, x).is_finite(), + "Transform2D with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Transform2D(x, infinite, x).is_finite(), + "Transform2D with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Transform2D(x, x, infinite).is_finite(), + "Transform2D with one component infinite should not be finite."); + + CHECK_FALSE_MESSAGE( + Transform2D(infinite, infinite, x).is_finite(), + "Transform2D with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Transform2D(infinite, x, infinite).is_finite(), + "Transform2D with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Transform2D(x, infinite, infinite).is_finite(), + "Transform2D with two components infinite should not be finite."); + + CHECK_FALSE_MESSAGE( + Transform2D(infinite, infinite, infinite).is_finite(), + "Transform2D with three components infinite should not be finite."); +} + } // namespace TestTransform2D #endif // TEST_TRANSFORM_2D_H diff --git a/tests/core/math/test_transform_3d.h b/tests/core/math/test_transform_3d.h index da166b43f7..d2730f3577 100644 --- a/tests/core/math/test_transform_3d.h +++ b/tests/core/math/test_transform_3d.h @@ -84,6 +84,29 @@ TEST_CASE("[Transform3D] rotation") { CHECK(orig.rotated(axis, phi) == R * orig); CHECK(orig.rotated_local(axis, phi) == orig * R); } + +TEST_CASE("[Transform3D] Finite number checks") { + const Vector3 y(0, 1, 2); + const Vector3 infinite_vec(NAN, NAN, NAN); + const Basis x(y, y, y); + const Basis infinite_basis(infinite_vec, infinite_vec, infinite_vec); + + CHECK_MESSAGE( + Transform3D(x, y).is_finite(), + "Transform3D with all components finite should be finite"); + + CHECK_FALSE_MESSAGE( + Transform3D(x, infinite_vec).is_finite(), + "Transform3D with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Transform3D(infinite_basis, y).is_finite(), + "Transform3D with one component infinite should not be finite."); + + CHECK_FALSE_MESSAGE( + Transform3D(infinite_basis, infinite_vec).is_finite(), + "Transform3D with two components infinite should not be finite."); +} + } // namespace TestTransform3D #endif // TEST_TRANSFORM_3D_H diff --git a/tests/core/math/test_vector2.h b/tests/core/math/test_vector2.h index 0d7f1163e4..a87b9ffc02 100644 --- a/tests/core/math/test_vector2.h +++ b/tests/core/math/test_vector2.h @@ -465,6 +465,32 @@ TEST_CASE("[Vector2] Linear algebra methods") { Math::is_equal_approx(Vector2(-a.x, a.y).dot(Vector2(b.x, -b.y)), (real_t)-57.3), "Vector2 dot should return expected value."); } + +TEST_CASE("[Vector2] Finite number checks") { + const double infinite[] = { NAN, INFINITY, -INFINITY }; + + CHECK_MESSAGE( + Vector2(0, 1).is_finite(), + "Vector2(0, 1) should be finite"); + + for (double x : infinite) { + CHECK_FALSE_MESSAGE( + Vector2(x, 1).is_finite(), + "Vector2 with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector2(0, x).is_finite(), + "Vector2 with one component infinite should not be finite."); + } + + for (double x : infinite) { + for (double y : infinite) { + CHECK_FALSE_MESSAGE( + Vector2(x, y).is_finite(), + "Vector2 with two components infinite should not be finite."); + } + } +} + } // namespace TestVector2 #endif // TEST_VECTOR2_H diff --git a/tests/core/math/test_vector3.h b/tests/core/math/test_vector3.h index be271bad1f..4932cd04db 100644 --- a/tests/core/math/test_vector3.h +++ b/tests/core/math/test_vector3.h @@ -479,6 +479,51 @@ TEST_CASE("[Vector3] Linear algebra methods") { Math::is_equal_approx(Vector3(-a.x, a.y, -a.z).dot(Vector3(b.x, -b.y, b.z)), (real_t)-75.24), "Vector3 dot should return expected value."); } + +TEST_CASE("[Vector3] Finite number checks") { + const double infinite[] = { NAN, INFINITY, -INFINITY }; + + CHECK_MESSAGE( + Vector3(0, 1, 2).is_finite(), + "Vector3(0, 1, 2) should be finite"); + + for (double x : infinite) { + CHECK_FALSE_MESSAGE( + Vector3(x, 1, 2).is_finite(), + "Vector3 with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector3(0, x, 2).is_finite(), + "Vector3 with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector3(0, 1, x).is_finite(), + "Vector3 with one component infinite should not be finite."); + } + + for (double x : infinite) { + for (double y : infinite) { + CHECK_FALSE_MESSAGE( + Vector3(x, y, 2).is_finite(), + "Vector3 with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector3(x, 1, y).is_finite(), + "Vector3 with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector3(0, x, y).is_finite(), + "Vector3 with two components infinite should not be finite."); + } + } + + for (double x : infinite) { + for (double y : infinite) { + for (double z : infinite) { + CHECK_FALSE_MESSAGE( + Vector3(x, y, z).is_finite(), + "Vector3 with three components infinite should not be finite."); + } + } + } +} + } // namespace TestVector3 #endif // TEST_VECTOR3_H diff --git a/tests/core/math/test_vector4.h b/tests/core/math/test_vector4.h index 3f50f16635..b31db56f67 100644 --- a/tests/core/math/test_vector4.h +++ b/tests/core/math/test_vector4.h @@ -314,6 +314,84 @@ TEST_CASE("[Vector4] Linear algebra methods") { Math::is_equal_approx((vector1 * 2).dot(vector2 * 4), (real_t)-25.9 * 8), "Vector4 dot product should work as expected."); } + +TEST_CASE("[Vector4] Finite number checks") { + const double infinite[] = { NAN, INFINITY, -INFINITY }; + + CHECK_MESSAGE( + Vector4(0, 1, 2, 3).is_finite(), + "Vector4(0, 1, 2, 3) should be finite"); + + for (double x : infinite) { + CHECK_FALSE_MESSAGE( + Vector4(x, 1, 2, 3).is_finite(), + "Vector4 with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector4(0, x, 2, 3).is_finite(), + "Vector4 with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector4(0, 1, x, 3).is_finite(), + "Vector4 with one component infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector4(0, 1, 2, x).is_finite(), + "Vector4 with one component infinite should not be finite."); + } + + for (double x : infinite) { + for (double y : infinite) { + CHECK_FALSE_MESSAGE( + Vector4(x, y, 2, 3).is_finite(), + "Vector4 with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector4(x, 1, y, 3).is_finite(), + "Vector4 with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector4(x, 1, 2, y).is_finite(), + "Vector4 with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector4(0, x, y, 3).is_finite(), + "Vector4 with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector4(0, x, 2, y).is_finite(), + "Vector4 with two components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector4(0, 1, x, y).is_finite(), + "Vector4 with two components infinite should not be finite."); + } + } + + for (double x : infinite) { + for (double y : infinite) { + for (double z : infinite) { + CHECK_FALSE_MESSAGE( + Vector4(0, x, y, z).is_finite(), + "Vector4 with three components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector4(x, 1, y, z).is_finite(), + "Vector4 with three components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector4(x, y, 2, z).is_finite(), + "Vector4 with three components infinite should not be finite."); + CHECK_FALSE_MESSAGE( + Vector4(x, y, z, 3).is_finite(), + "Vector4 with three components infinite should not be finite."); + } + } + } + + for (double x : infinite) { + for (double y : infinite) { + for (double z : infinite) { + for (double w : infinite) { + CHECK_FALSE_MESSAGE( + Vector4(x, y, z, w).is_finite(), + "Vector4 with four components infinite should not be finite."); + } + } + } + } +} + } // namespace TestVector4 #endif // TEST_VECTOR4_H |