/* * Copyright (c), Recep Aslantas. * * MIT License (MIT), http://opensource.org/licenses/MIT * Full license can be found in the LICENSE file */ #include "test_common.h" TEST_IMPL(GLM_PREFIX, translate) { mat4 m1; vec4 v1 = {1.0f, 2.0f, 3.0f, 1.0f}, v2; glm_mat4_identity(m1); GLM(translate)(m1, (vec3){13.0f, 11.0f, 7.0f}); glm_mat4_mulv(m1, v1, v2); ASSERT(test_eq(v2[0], 14.0f)) ASSERT(test_eq(v2[1], 13.0f)) ASSERT(test_eq(v2[2], 10.0f)) ASSERT(test_eq(v2[3], 1.0f)) glm_mat4_identity(m1); GLM(translate)(m1, (vec3){1.0f, -1.0f, -5.0f}); glm_mat4_mulv(m1, v2, v2); ASSERT(test_eq(v2[0], 15.0f)) ASSERT(test_eq(v2[1], 12.0f)) ASSERT(test_eq(v2[2], 5.0f)) ASSERT(test_eq(v2[3], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, translate_to) { mat4 m1, m2; vec4 v1 = {1.0f, 2.0f, 3.0f, 1.0f}, v2; glm_mat4_identity(m1); GLM(translate_to)(m1, (vec3){13.0f, 11.0f, 7.0f}, m2); glm_mat4_mulv(m2, v1, v2); ASSERT(test_eq(v2[0], 14.0f)) ASSERT(test_eq(v2[1], 13.0f)) ASSERT(test_eq(v2[2], 10.0f)) ASSERT(test_eq(v2[3], 1.0f)) glm_mat4_identity(m1); GLM(translate_to)(m1, (vec3){1.0f, -1.0f, -5.0f}, m2); glm_mat4_mulv(m2, v2, v2); ASSERT(test_eq(v2[0], 15.0f)) ASSERT(test_eq(v2[1], 12.0f)) ASSERT(test_eq(v2[2], 5.0f)) ASSERT(test_eq(v2[3], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, translate_x) { mat4 m1; vec4 v1 = {1.0f, 2.0f, 3.0f, 1.0f}, v2; glm_mat4_identity(m1); GLM(translate_x)(m1, 13.0f); glm_mat4_mulv(m1, v1, v2); ASSERT(test_eq(v2[0], 14.0f)) ASSERT(test_eq(v2[1], 2.0f)) ASSERT(test_eq(v2[2], 3.0f)) ASSERT(test_eq(v2[3], 1.0f)) glm_mat4_identity(m1); GLM(translate_x)(m1, -1.0f); glm_mat4_mulv(m1, v2, v2); ASSERT(test_eq(v2[0], 13.0f)) ASSERT(test_eq(v2[1], 2.0f)) ASSERT(test_eq(v2[2], 3.0f)) ASSERT(test_eq(v2[3], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, translate_y) { mat4 m1; vec4 v1 = {1.0f, 2.0f, 3.0f, 1.0f}, v2; glm_mat4_identity(m1); GLM(translate_y)(m1, 11.0f); glm_mat4_mulv(m1, v1, v2); ASSERT(test_eq(v2[0], 1.0f)) ASSERT(test_eq(v2[1], 13.0f)) ASSERT(test_eq(v2[2], 3.0f)) ASSERT(test_eq(v2[3], 1.0f)) glm_mat4_identity(m1); GLM(translate_y)(m1, -1.0f); glm_mat4_mulv(m1, v2, v2); ASSERT(test_eq(v2[0], 1.0f)) ASSERT(test_eq(v2[1], 12.0f)) ASSERT(test_eq(v2[2], 3.0f)) ASSERT(test_eq(v2[3], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, translate_z) { mat4 m1; vec4 v1 = {1.0f, 2.0f, 3.0f, 1.0f}, v2; glm_mat4_identity(m1); GLM(translate_z)(m1, 7.0f); glm_mat4_mulv(m1, v1, v2); ASSERT(test_eq(v2[0], 1.0f)) ASSERT(test_eq(v2[1], 2.0f)) ASSERT(test_eq(v2[2], 10.0f)) ASSERT(test_eq(v2[3], 1.0f)) glm_mat4_identity(m1); GLM(translate_z)(m1, -5.0f); glm_mat4_mulv(m1, v2, v2); ASSERT(test_eq(v2[0], 1.0f)) ASSERT(test_eq(v2[1], 2.0f)) ASSERT(test_eq(v2[2], 5.0f)) ASSERT(test_eq(v2[3], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, translate_make) { mat4 m1; vec4 v1 = {1.0f, 2.0f, 3.0f, 1.0f}, v2; glm_mat4_identity(m1); GLM(translate_make)(m1, (vec3){13.0f, 11.0f, 7.0f}); glm_mat4_mulv(m1, v1, v2); ASSERT(test_eq(v2[0], 14.0f)) ASSERT(test_eq(v2[1], 13.0f)) ASSERT(test_eq(v2[2], 10.0f)) ASSERT(test_eq(v2[3], 1.0f)) glm_mat4_identity(m1); GLM(translate_make)(m1, (vec3){1.0f, -1.0f, -5.0f}); glm_mat4_mulv(m1, v2, v2); ASSERT(test_eq(v2[0], 15.0f)) ASSERT(test_eq(v2[1], 12.0f)) ASSERT(test_eq(v2[2], 5.0f)) ASSERT(test_eq(v2[3], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, scale_to) { mat4 m1, m2; vec4 v1 = {1.0f, 2.0f, 3.0f, 1.0f}, v2; glm_mat4_identity(m1); GLM(scale_to)(m1, (vec3){13.0f, 11.0f, 7.0f}, m2); glm_mat4_mulv(m2, v1, v2); ASSERT(test_eq(v2[0], 13.0f)) ASSERT(test_eq(v2[1], 22.0f)) ASSERT(test_eq(v2[2], 21.0f)) ASSERT(test_eq(v2[3], 1.0f)) glm_mat4_identity(m1); GLM(scale_to)(m1, (vec3){1.0f, -1.0f, -5.0f}, m2); glm_mat4_mulv(m2, v2, v2); ASSERT(test_eq(v2[0], 13.0f)) ASSERT(test_eq(v2[1], -22.0f)) ASSERT(test_eq(v2[2], -105.0f)) ASSERT(test_eq(v2[3], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, scale_make) { mat4 m1; vec4 v1 = {1.0f, 2.0f, 3.0f, 1.0f}, v2; GLM(scale_make)(m1, (vec3){13.0f, 11.0f, 7.0f}); glm_mat4_mulv(m1, v1, v2); ASSERT(test_eq(v2[0], 13.0f)) ASSERT(test_eq(v2[1], 22.0f)) ASSERT(test_eq(v2[2], 21.0f)) ASSERT(test_eq(v2[3], 1.0f)) GLM(scale_make)(m1, (vec3){1.0f, -1.0f, -5.0f}); glm_mat4_mulv(m1, v2, v2); ASSERT(test_eq(v2[0], 13.0f)) ASSERT(test_eq(v2[1], -22.0f)) ASSERT(test_eq(v2[2], -105.0f)) ASSERT(test_eq(v2[3], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, scale) { mat4 m1; vec4 v1 = {1.0f, 2.0f, 3.0f, 1.0f}, v2; glm_mat4_identity(m1); GLM(scale)(m1, (vec3){13.0f, 11.0f, 7.0f}); glm_mat4_mulv(m1, v1, v2); ASSERT(test_eq(v2[0], 13.0f)) ASSERT(test_eq(v2[1], 22.0f)) ASSERT(test_eq(v2[2], 21.0f)) ASSERT(test_eq(v2[3], 1.0f)) glm_mat4_identity(m1); GLM(scale)(m1, (vec3){1.0f, -1.0f, -5.0f}); glm_mat4_mulv(m1, v2, v2); ASSERT(test_eq(v2[0], 13.0f)) ASSERT(test_eq(v2[1], -22.0f)) ASSERT(test_eq(v2[2], -105.0f)) ASSERT(test_eq(v2[3], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, scale_uni) { mat4 m1; vec4 v1 = {1.0f, 2.0f, 3.0f, 1.0f}, v2; glm_mat4_identity(m1); GLM(scale_uni)(m1, 13.0f); glm_mat4_mulv(m1, v1, v2); ASSERT(test_eq(v2[0], 13.0f)) ASSERT(test_eq(v2[1], 26.0f)) ASSERT(test_eq(v2[2], 39.0f)) ASSERT(test_eq(v2[3], 1.0f)) glm_mat4_identity(m1); GLM(scale_uni)(m1, -5.0f); glm_mat4_mulv(m1, v2, v2); ASSERT(test_eq(v2[0], -65.0f)) ASSERT(test_eq(v2[1], -130.0f)) ASSERT(test_eq(v2[2], -195.0f)) ASSERT(test_eq(v2[3], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, rotate_x) { mat4 m1 = GLM_MAT4_IDENTITY_INIT; vec4 v1 = {0.0f, 1.0f, 0.0f, 1.0f}, v2 = {0.0f, 1.0f, 0.0f, 1.0f}; GLM(rotate_x)(m1, GLM_PI_2f, m1); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], 1.0f)) glm_vec3_copy(v2, v1); GLM(rotate_x)(m1, GLM_PI_2f, m1); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], -1.0f)) ASSERT(test_eq(v1[2], 0.0f)) glm_vec3_copy(v2, v1); GLM(rotate_x)(m1, GLM_PI_2f, m1); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], -1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, rotate_y) { mat4 m1 = GLM_MAT4_IDENTITY_INIT; vec4 v1 = {1.0f, 0.0f, 0.0f, 1.0f}, v2 = {1.0f, 0.0f, 0.0f, 1.0f}; GLM(rotate_y)(m1, GLM_PI_2f, m1); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], -1.0f)) glm_vec3_copy(v2, v1); GLM(rotate_y)(m1, GLM_PI_2f, m1); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], -1.0f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], 0.0f)) glm_vec3_copy(v2, v1); GLM(rotate_y)(m1, GLM_PI_2f, m1); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, rotate_z) { mat4 m1 = GLM_MAT4_IDENTITY_INIT; vec4 v1 = {0.0f, 1.0f, 0.0f, 1.0f}, v2 = {0.0f, 1.0f, 0.0f, 1.0f}; GLM(rotate_z)(m1, GLM_PI_2f, m1); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], -1.0f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], 0.0f)) glm_vec3_copy(v2, v1); GLM(rotate_z)(m1, GLM_PI_2f, m1); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], -1.0f)) ASSERT(test_eq(v1[2], 0.0f)) glm_vec3_copy(v2, v1); GLM(rotate_z)(m1, GLM_PI_2f, m1); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 1.0f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], 0.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, rotate_make) { mat4 m1 = GLM_MAT4_IDENTITY_INIT; vec4 v1 = {1.0f, 0.0f, 0.0f, 1.0f}; /* rotate X around Y = -Z */ GLM(rotate_make)(m1, GLM_PI_2f, GLM_YUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], -1.0f)) /* rotate -Z around X = Y */ GLM(rotate_make)(m1, GLM_PI_2f, GLM_XUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 1.0f)) ASSERT(test_eq(v1[2], 0.0f)) /* rotate Y around X = +Z */ GLM(rotate_make)(m1, GLM_PI_2f, GLM_XUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, rotate) { mat4 m1 = GLM_MAT4_IDENTITY_INIT, m2 = GLM_MAT4_IDENTITY_INIT; vec4 v1 = {1.0f, 0.0f, 0.0f, 1.0f}; /* 360 deg */ glm_rotate(m1, GLM_PI_2f, GLM_YUP); glm_rotate(m1, GLM_PI_2f, GLM_YUP); glm_rotate(m1, GLM_PI_2f, GLM_YUP); glm_rotate(m1, GLM_PI_2f, GLM_YUP); ASSERTIFY(test_assert_mat4_eq(m1, m2)) /* rotate X around Y = -Z */ GLM(rotate)(m1, GLM_PI_2f, GLM_YUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], -1.0f)) glm_mat4_identity(m1); /* rotate -Z around X = Y */ GLM(rotate)(m1, GLM_PI_2f, GLM_XUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 1.0f)) ASSERT(test_eq(v1[2], 0.0f)) glm_mat4_identity(m1); /* rotate Y around X = +Z */ GLM(rotate)(m1, GLM_PI_2f, GLM_XUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, rotate_at) { mat4 m1 = GLM_MAT4_IDENTITY_INIT; vec4 v1 = {1.0f, 0.0f, 0.0f, 1.0f}; GLM(rotate_at)(m1, (vec3){0.5f, 0.0f, 0.0f}, GLM_PI_2f, GLM_YUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.5f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], -0.5f)) glm_mat4_identity(m1); GLM(rotate_at)(m1, GLM_VEC3_ZERO, GLM_PI_2f, GLM_ZUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 0.5f)) ASSERT(test_eq(v1[2], -0.5f)) glm_mat4_identity(m1); v1[0] = 1.0f; v1[1] = 1.0f; v1[2] = 1.0f; GLM(rotate_at)(m1, GLM_VEC3_ZERO, GLM_PI_2f, GLM_XUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 1.0f)) ASSERT(test_eq(v1[1], -1.0f)) ASSERT(test_eq(v1[2], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, rotate_atm) { mat4 m1 = GLM_MAT4_IDENTITY_INIT; vec4 v1 = {1.0f, 0.0f, 0.0f, 1.0f}; GLM(rotate_atm)(m1, (vec3){0.5f, 0.0f, 0.0f}, GLM_PI_2f, GLM_YUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.5f)) ASSERT(test_eq(v1[1], 0.0f)) ASSERT(test_eq(v1[2], -0.5f)) GLM(rotate_atm)(m1, GLM_VEC3_ZERO, GLM_PI_2f, GLM_ZUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 0.0f)) ASSERT(test_eq(v1[1], 0.5f)) ASSERT(test_eq(v1[2], -0.5f)) v1[0] = 1.0f; v1[1] = 1.0f; v1[2] = 1.0f; GLM(rotate_atm)(m1, GLM_VEC3_ZERO, GLM_PI_2f, GLM_XUP); glm_mat4_mulv(m1, v1, v1); ASSERT(test_eq(v1[0], 1.0f)) ASSERT(test_eq(v1[1], -1.0f)) ASSERT(test_eq(v1[2], 1.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, decompose_scalev) { mat4 m1; vec3 s1; GLM(scale_make)(m1, (vec3){7.0f, 8.0f, 9.0f}); GLM(decompose_scalev)(m1, s1); ASSERT(test_eq(s1[0], 7.0f)) ASSERT(test_eq(s1[1], 8.0f)) ASSERT(test_eq(s1[2], 9.0f)) GLM(scale)(m1, (vec3){7.0f, 8.0f, 9.0f}); GLM(decompose_scalev)(m1, s1); ASSERT(test_eq(s1[0], 49.0f)) ASSERT(test_eq(s1[1], 64.0f)) ASSERT(test_eq(s1[2], 81.0f)) glm_rotate(m1, GLM_PI_4f, (vec3){23.0f, 45.0f, 66.0f}); ASSERT(test_eq(s1[0], 49.0f)) ASSERT(test_eq(s1[1], 64.0f)) ASSERT(test_eq(s1[2], 81.0f)) glm_translate(m1, (vec3){4.0f, 5.0f, 6.0f}); ASSERT(test_eq(s1[0], 49.0f)) ASSERT(test_eq(s1[1], 64.0f)) ASSERT(test_eq(s1[2], 81.0f)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, uniscaled) { mat4 m1; GLM(scale_make)(m1, (vec3){7.0f, 8.0f, 9.0f}); ASSERT(!GLM(uniscaled)(m1)) GLM(scale_make)(m1, (vec3){7.0f, 7.0f, 7.0f}); ASSERT(GLM(uniscaled)(m1)) glm_rotate(m1, GLM_PI_4f, (vec3){23.0f, 45.0f, 66.0f}); ASSERT(GLM(uniscaled)(m1)) glm_translate(m1, (vec3){4.0f, 5.0f, 6.0f}); ASSERT(GLM(uniscaled)(m1)) TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, decompose_rs) { mat4 m1, m2, r; vec3 s1; GLM(scale_make)(m1, (vec3){7.0f, 8.0f, 9.0f}); GLM(decompose_rs)(m1, r, s1); ASSERT(test_eq(s1[0], 7.0f)) ASSERT(test_eq(s1[1], 8.0f)) ASSERT(test_eq(s1[2], 9.0f)) ASSERTIFY(test_assert_mat4_eq_identity(r)); GLM(scale)(m1, (vec3){7.0f, 8.0f, 9.0f}); GLM(decompose_rs)(m1, r, s1); ASSERT(test_eq(s1[0], 49.0f)) ASSERT(test_eq(s1[1], 64.0f)) ASSERT(test_eq(s1[2], 81.0f)) ASSERTIFY(test_assert_mat4_eq_identity(r)); glm_rotate(m1, GLM_PI_4f, (vec3){23.0f, 45.0f, 66.0f}); ASSERT(test_eq(s1[0], 49.0f)) ASSERT(test_eq(s1[1], 64.0f)) ASSERT(test_eq(s1[2], 81.0f)) GLM(decompose_rs)(m1, r, s1); glm_mat4_identity(m2); glm_mat4_mul(m2, r, m2); glm_scale(m2, s1); ASSERTIFY(test_assert_mat4_eq2(m1, m2, 0.00001f)); TEST_SUCCESS } TEST_IMPL(GLM_PREFIX, decompose) { mat4 m1, m2, r; vec4 t; vec3 s; GLM(scale_make)(m1, (vec3){7.0f, 8.0f, 9.0f}); GLM(decompose)(m1, t, r, s); ASSERT(test_eq(s[0], 7.0f)) ASSERT(test_eq(s[1], 8.0f)) ASSERT(test_eq(s[2], 9.0f)) ASSERTIFY(test_assert_mat4_eq_identity(r)); GLM(scale)(m1, (vec3){7.0f, 8.0f, 9.0f}); GLM(decompose)(m1, t, r, s); ASSERT(test_eq(s[0], 49.0f)) ASSERT(test_eq(s[1], 64.0f)) ASSERT(test_eq(s[2], 81.0f)) ASSERTIFY(test_assert_mat4_eq_identity(r)); glm_rotate(m1, GLM_PI_4f, (vec3){23.0f, 45.0f, 66.0f}); ASSERT(test_eq(s[0], 49.0f)) ASSERT(test_eq(s[1], 64.0f)) ASSERT(test_eq(s[2], 81.0f)) GLM(decompose)(m1, t, r, s); glm_mat4_identity(m2); glm_mat4_mul(m2, r, m2); glm_scale(m2, s); ASSERTIFY(test_assert_mat4_eq2(m1, m2, 0.00001f)); glm_mat4_identity(m1); glm_translate(m1, (vec3){56.0f, 13.0f, 90.0f}); glm_rotate(m1, GLM_PI_4f, (vec3){23.0f, 45.0f, 66.0f}); glm_scale(m1, (vec3){12.0f, 34.0f, 23.0f}); GLM(decompose)(m1, t, r, s); ASSERT(test_eq(t[0], 56.0f)) ASSERT(test_eq(t[1], 13.0f)) ASSERT(test_eq(t[2], 90.0f)) ASSERT(test_eq(s[0], 12.0f)) ASSERT(test_eq(s[1], 34.0f)) ASSERT(test_eq(s[2], 23.0f)) glm_mat4_identity(m2); glm_translate(m2, t); glm_mat4_mul(m2, r, m2); glm_scale(m2, s); ASSERTIFY(test_assert_mat4_eq2(m1, m2, 0.00001f)); TEST_SUCCESS }