# SPDX-License-Identifier: Apache-2.0 # ./blender.bin --background -noaudio --python tests/python/bl_pyapi_mathutils.py -- --verbose import unittest from mathutils import Matrix, Vector, Quaternion, Euler from mathutils import kdtree, geometry import math # keep globals immutable vector_data = ( (1.0, 0.0, 0.0), (0.0, 1.0, 0.0), (0.0, 0.0, 1.0), (1.0, 1.0, 1.0), (0.33783, 0.715698, -0.611206), (-0.944031, -0.326599, -0.045624), (-0.101074, -0.416443, -0.903503), (0.799286, 0.49411, -0.341949), (-0.854645, 0.518036, 0.033936), (0.42514, -0.437866, -0.792114), (-0.358948, 0.597046, 0.717377), (-0.985413, 0.144714, 0.089294), ) # get data at different scales vector_data = sum( (tuple(tuple(a * scale for a in v) for v in vector_data) for scale in (s * sign for s in (0.0001, 0.1, 1.0, 10.0, 1000.0, 100000.0) for sign in (1.0, -1.0))), ()) + ((0.0, 0.0, 0.0),) class MatrixTesting(unittest.TestCase): def test_matrix_column_access(self): # mat = # [ 1 2 3 4 ] # [ 1 2 3 4 ] # [ 1 2 3 4 ] mat = Matrix(((1, 11, 111), (2, 22, 222), (3, 33, 333), (4, 44, 444))) self.assertEqual(mat[0], Vector((1, 11, 111))) self.assertEqual(mat[1], Vector((2, 22, 222))) self.assertEqual(mat[2], Vector((3, 33, 333))) self.assertEqual(mat[3], Vector((4, 44, 444))) def test_item_access(self): args = ((1, 4, 0, -1), (2, -1, 2, -2), (0, 3, 8, 3), (-2, 9, 1, 0)) mat = Matrix(args) for row in range(4): for col in range(4): self.assertEqual(mat[row][col], args[row][col]) self.assertEqual(mat[0][2], 0) self.assertEqual(mat[3][1], 9) self.assertEqual(mat[2][3], 3) self.assertEqual(mat[0][0], 1) self.assertEqual(mat[3][3], 0) def test_item_assignment(self): mat = Matrix() - Matrix() indices = (0, 0), (1, 3), (2, 0), (3, 2), (3, 1) checked_indices = [] for row, col in indices: mat[row][col] = 1 for row in range(4): for col in range(4): if mat[row][col]: checked_indices.append((row, col)) for item in checked_indices: self.assertIn(item, indices) def test_matrix_to_3x3(self): # mat = # [ 1 2 3 4 ] # [ 2 4 6 8 ] # [ 3 6 9 12 ] # [ 4 8 12 16 ] mat = Matrix(tuple((i, 2 * i, 3 * i, 4 * i) for i in range(1, 5))) mat_correct = Matrix(((1, 2, 3), (2, 4, 6), (3, 6, 9))) self.assertEqual(mat.to_3x3(), mat_correct) def test_matrix_to_translation(self): mat = Matrix() mat[0][3] = 1 mat[1][3] = 2 mat[2][3] = 3 self.assertEqual(mat.to_translation(), Vector((1, 2, 3))) def test_matrix_translation(self): mat = Matrix() mat.translation = Vector((1, 2, 3)) self.assertEqual(mat[0][3], 1) self.assertEqual(mat[1][3], 2) self.assertEqual(mat[2][3], 3) def test_matrix_non_square_matmul(self): mat1 = Matrix(((1, 2, 3), (4, 5, 6))) mat2 = Matrix(((1, 2), (3, 4), (5, 6))) prod_mat1 = Matrix(((22, 28), (49, 64))) prod_mat2 = Matrix(((9, 12, 15), (19, 26, 33), (29, 40, 51))) self.assertEqual(mat1 @ mat2, prod_mat1) self.assertEqual(mat2 @ mat1, prod_mat2) def test_mat4x4_vec3D_matmul(self): mat = Matrix(((1, 0, 2, 0), (0, 6, 0, 0), (0, 0, 1, 1), (0, 0, 0, 1))) vec = Vector((1, 2, 3)) prod_mat_vec = Vector((7, 12, 4)) prod_vec_mat = Vector((1, 12, 5)) self.assertEqual(mat @ vec, prod_mat_vec) self.assertEqual(vec @ mat, prod_vec_mat) def test_mat_vec_matmul(self): mat1 = Matrix() vec = Vector((1, 2)) self.assertRaises(ValueError, mat1.__matmul__, vec) self.assertRaises(ValueError, vec.__matmul__, mat1) mat2 = Matrix(((1, 2), (-2, 3))) prod = Vector((5, 4)) self.assertEqual(mat2 @ vec, prod) def test_matrix_square_matmul(self): mat1 = Matrix(((1, 0), (1, 2))) mat2 = Matrix(((1, 2), (-2, 3))) prod1 = Matrix(((1, 2), (-3, 8))) prod2 = Matrix(((3, 4), (1, 6))) self.assertEqual(mat1 @ mat2, prod1) self.assertEqual(mat2 @ mat1, prod2) """ # tests for element-wise multiplication def test_matrix_mul(self): mat1 = Matrix(((1, 0), (1, 2))) mat2 = Matrix(((1, 2), (-2, 3))) mat3 = Matrix(((1, 0, 2, 0), (0, 6, 0, 0), (0, 0, 1, 1), (0, 0, 0, 1))) prod = Matrix(((1, 0), (-2, 6))) self.assertEqual(mat1 * mat2, prod) self.assertEqual(mat2 * mat1, prod) self.assertRaises(ValueError, mat1.__mul__, mat3) """ def test_matrix_inverse(self): mat = Matrix(((1, 4, 0, -1), (2, -1, 2, -2), (0, 3, 8, 3), (-2, 9, 1, 0))) inv_mat = (1 / 285) * Matrix(((195, -57, 27, -102), (50, -19, 4, 6), (-60, 57, 18, 27), (110, -133, 43, -78))) self.assertEqual(mat.inverted(), inv_mat) def test_matrix_inverse_safe(self): mat = Matrix(((1, 4, 0, -1), (2, -1, 0, -2), (0, 3, 0, 3), (-2, 9, 0, 0))) # Warning, if we change epsilon in py api we have to update this!!! epsilon = 1e-8 inv_mat_safe = mat.copy() inv_mat_safe[0][0] += epsilon inv_mat_safe[1][1] += epsilon inv_mat_safe[2][2] += epsilon inv_mat_safe[3][3] += epsilon inv_mat_safe.invert() ''' inv_mat_safe = Matrix(((1.0, -0.5, 0.0, -0.5), (0.222222, -0.111111, -0.0, 0.0), (-333333344.0, 316666656.0, 100000000.0, 150000000.0), (0.888888, -0.9444444, 0.0, -0.5))) ''' self.assertEqual(mat.inverted_safe(), inv_mat_safe) def test_matrix_matmult(self): mat = Matrix(((1, 4, 0, -1), (2, -1, 2, -2), (0, 3, 8, 3), (-2, 9, 1, 0))) prod_mat = Matrix(((11, -9, 7, -9), (4, -3, 12, 6), (0, 48, 73, 18), (16, -14, 26, -13))) self.assertEqual(mat @ mat, prod_mat) def test_loc_rot_scale(self): euler = Euler((math.radians(90), 0, math.radians(90)), 'ZYX') expected = Matrix(((0, -5, 0, 1), (0, 0, -6, 2), (4, 0, 0, 3), (0, 0, 0, 1))) result = Matrix.LocRotScale((1, 2, 3), euler, (4, 5, 6)) self.assertAlmostEqualMatrix(result, expected, 4) result = Matrix.LocRotScale((1, 2, 3), euler.to_quaternion(), (4, 5, 6)) self.assertAlmostEqualMatrix(result, expected, 4) result = Matrix.LocRotScale((1, 2, 3), euler.to_matrix(), (4, 5, 6)) self.assertAlmostEqualMatrix(result, expected, 4) def assertAlmostEqualMatrix(self, first, second, size, *, places=6, msg=None, delta=None): for i in range(size): for j in range(size): self.assertAlmostEqual(first[i][j], second[i][j], places=places, msg=msg, delta=delta) class VectorTesting(unittest.TestCase): def test_orthogonal(self): angle_90d = math.pi / 2.0 for v in vector_data: v = Vector(v) if v.length_squared != 0.0: self.assertAlmostEqual(v.angle(v.orthogonal()), angle_90d) def test_vector_matmul(self): # produces dot product for vectors vec1 = Vector((1, 3, 5)) vec2 = Vector((1, 2)) self.assertRaises(ValueError, vec1.__matmul__, vec2) self.assertEqual(vec1 @ vec1, 35) self.assertEqual(vec2 @ vec2, 5) def test_vector_imatmul(self): vec = Vector((1, 3, 5)) with self.assertRaises(TypeError): vec @= vec """ # tests for element-wise multiplication def test_vector_mul(self): # element-wise multiplication vec1 = Vector((1, 3, 5)) vec2 = Vector((1, 2)) prod1 = Vector((1, 9, 25)) prod2 = Vector((2, 6, 10)) self.assertRaises(ValueError, vec1.__mul__, vec2) self.assertEqual(vec1 * vec1, prod1) self.assertEqual(2 * vec1, prod2) def test_vector_imul(self): # inplace element-wise multiplication vec = Vector((1, 3, 5)) prod1 = Vector((1, 9, 25)) prod2 = Vector((2, 18, 50)) vec *= vec self.assertEqual(vec, prod1) vec *= 2 self.assertEqual(vec, prod2) """ class QuaternionTesting(unittest.TestCase): def test_to_expmap(self): q = Quaternion((0, 0, 1), math.radians(90)) e = q.to_exponential_map() self.assertAlmostEqual(e.x, 0) self.assertAlmostEqual(e.y, 0) self.assertAlmostEqual(e.z, math.radians(90), 6) def test_expmap_axis_normalization(self): q = Quaternion((1, 1, 0), 2) e = q.to_exponential_map() self.assertAlmostEqual(e.x, 2 * math.sqrt(0.5), 6) self.assertAlmostEqual(e.y, 2 * math.sqrt(0.5), 6) self.assertAlmostEqual(e.z, 0) def test_from_expmap(self): e = Vector((1, 1, 0)) q = Quaternion(e) axis, angle = q.to_axis_angle() self.assertAlmostEqual(angle, math.sqrt(2), 6) self.assertAlmostEqual(axis.x, math.sqrt(0.5), 6) self.assertAlmostEqual(axis.y, math.sqrt(0.5), 6) self.assertAlmostEqual(axis.z, 0) class KDTreeTesting(unittest.TestCase): @staticmethod def kdtree_create_grid_3d_data(tot): index = 0 mul = 1.0 / (tot - 1) for x in range(tot): for y in range(tot): for z in range(tot): yield (x * mul, y * mul, z * mul), index index += 1 @staticmethod def kdtree_create_grid_3d(tot, *, filter_fn=None): k = kdtree.KDTree(tot * tot * tot) for co, index in KDTreeTesting.kdtree_create_grid_3d_data(tot): if (filter_fn is not None) and (not filter_fn(co, index)): continue k.insert(co, index) k.balance() return k def assertAlmostEqualVector(self, first, second, places=7, msg=None, delta=None): self.assertAlmostEqual(first[0], second[0], places=places, msg=msg, delta=delta) self.assertAlmostEqual(first[1], second[1], places=places, msg=msg, delta=delta) self.assertAlmostEqual(first[2], second[2], places=places, msg=msg, delta=delta) def test_kdtree_single(self): co = (0,) * 3 index = 2 k = kdtree.KDTree(1) k.insert(co, index) k.balance() co_found, index_found, dist_found = k.find(co) self.assertEqual(tuple(co_found), co) self.assertEqual(index_found, index) self.assertEqual(dist_found, 0.0) def test_kdtree_empty(self): co = (0,) * 3 k = kdtree.KDTree(0) k.balance() co_found, index_found, dist_found = k.find(co) self.assertIsNone(co_found) self.assertIsNone(index_found) self.assertIsNone(dist_found) def test_kdtree_line(self): tot = 10 k = kdtree.KDTree(tot) for i in range(tot): k.insert((i,) * 3, i) k.balance() co_found, index_found, dist_found = k.find((-1,) * 3) self.assertEqual(tuple(co_found), (0,) * 3) co_found, index_found, dist_found = k.find((tot,) * 3) self.assertEqual(tuple(co_found), (tot - 1,) * 3) def test_kdtree_grid(self): size = 10 k = self.kdtree_create_grid_3d(size) # find_range ret = k.find_range((0.5,) * 3, 2.0) self.assertEqual(len(ret), size * size * size) ret = k.find_range((1.0,) * 3, 1.0 / size) self.assertEqual(len(ret), 1) ret = k.find_range((1.0,) * 3, 2.0 / size) self.assertEqual(len(ret), 8) ret = k.find_range((10,) * 3, 0.5) self.assertEqual(len(ret), 0) # find_n tot = 0 ret = k.find_n((1.0,) * 3, tot) self.assertEqual(len(ret), tot) tot = 10 ret = k.find_n((1.0,) * 3, tot) self.assertEqual(len(ret), tot) self.assertEqual(ret[0][2], 0.0) tot = size * size * size ret = k.find_n((1.0,) * 3, tot) self.assertEqual(len(ret), tot) def test_kdtree_grid_filter_simple(self): size = 10 k = self.kdtree_create_grid_3d(size) # filter exact index ret_regular = k.find((1.0,) * 3) ret_filter = k.find((1.0,) * 3, filter=lambda i: i == ret_regular[1]) self.assertEqual(ret_regular, ret_filter) ret_filter = k.find((-1.0,) * 3, filter=lambda i: i == ret_regular[1]) self.assertEqual(ret_regular[:2], ret_filter[:2]) # ignore distance def test_kdtree_grid_filter_pairs(self): size = 10 k_all = self.kdtree_create_grid_3d(size) k_odd = self.kdtree_create_grid_3d(size, filter_fn=lambda co, i: (i % 2) == 1) k_evn = self.kdtree_create_grid_3d(size, filter_fn=lambda co, i: (i % 2) == 0) samples = 5 mul = 1 / (samples - 1) for x in range(samples): for y in range(samples): for z in range(samples): co = (x * mul, y * mul, z * mul) ret_regular = k_odd.find(co) self.assertEqual(ret_regular[1] % 2, 1) ret_filter = k_all.find(co, filter=lambda i: (i % 2) == 1) self.assertAlmostEqualVector(ret_regular, ret_filter) ret_regular = k_evn.find(co) self.assertEqual(ret_regular[1] % 2, 0) ret_filter = k_all.find(co, filter=lambda i: (i % 2) == 0) self.assertAlmostEqualVector(ret_regular, ret_filter) # filter out all values (search odd tree for even values and the reverse) co = (0,) * 3 ret_filter = k_odd.find(co, filter=lambda i: (i % 2) == 0) self.assertEqual(ret_filter[1], None) ret_filter = k_evn.find(co, filter=lambda i: (i % 2) == 1) self.assertEqual(ret_filter[1], None) def test_kdtree_invalid_size(self): with self.assertRaises(ValueError): kdtree.KDTree(-1) def test_kdtree_invalid_balance(self): co = (0,) * 3 index = 2 k = kdtree.KDTree(2) k.insert(co, index) k.balance() k.insert(co, index) with self.assertRaises(RuntimeError): k.find(co) def test_kdtree_invalid_filter(self): k = kdtree.KDTree(1) k.insert((0,) * 3, 0) k.balance() # not callable with self.assertRaises(TypeError): k.find((0,) * 3, filter=None) # no args with self.assertRaises(TypeError): k.find((0,) * 3, filter=lambda: None) # bad return value with self.assertRaises(ValueError): k.find((0,) * 3, filter=lambda i: None) class TesselatePolygon(unittest.TestCase): def test_empty(self): self.assertEqual([], geometry.tessellate_polygon([])) def test_2d(self): polyline = [ Vector((-0.14401324093341827, 0.1266411542892456)), Vector((-0.14401324093341827, 0.13)), Vector((0.13532273471355438, 0.1266411542892456)), Vector((0.13532273471355438, 0.13)), ] expect = [(0, 1, 2), (0, 3, 2)] self.assertEqual(expect, geometry.tessellate_polygon([polyline])) def test_3d(self): polyline = [ Vector((-0.14401324093341827, 0.1266411542892456, -0.13966798782348633)), Vector((-0.14401324093341827, 0.1266411542892456, 0.13966798782348633)), Vector((0.13532273471355438, 0.1266411542892456, 0.13966798782348633)), Vector((0.13532273471355438, 0.1266411542892456, -0.13966798782348633)), ] expect = [(2, 3, 0), (2, 0, 1)] self.assertEqual(expect, geometry.tessellate_polygon([polyline])) def test_3d_degenerate(self): polyline = [ Vector((-0.14401324093341827, -0.15269476175308228, -0.13966798782348633)), Vector((0.13532273471355438, -0.15269476175308228, -0.13966798782348633)), Vector((0.13532273471355438, -0.15269476175308228, -0.13966798782348633)), Vector((-0.14401324093341827, -0.15269476175308228, -0.13966798782348633)), ] # If this returns a proper result, rather than [(0, 0, 0)], it could mean that # degenerate geometry is handled properly. expect = [(0, 0, 0)] self.assertEqual(expect, geometry.tessellate_polygon([polyline])) if __name__ == '__main__': import sys sys.argv = [__file__] + (sys.argv[sys.argv.index("--") + 1:] if "--" in sys.argv else []) unittest.main()