import copy import numpy as np from numpy.testing import (assert_allclose, assert_almost_equal, assert_array_equal, assert_array_almost_equal) import pytest from matplotlib import scale import matplotlib.pyplot as plt import matplotlib.patches as mpatches import matplotlib.transforms as mtransforms from matplotlib.path import Path from matplotlib.testing.decorators import image_comparison def test_non_affine_caching(): class AssertingNonAffineTransform(mtransforms.Transform): """ This transform raises an assertion error when called when it shouldn't be and ``self.raise_on_transform`` is True. """ input_dims = output_dims = 2 is_affine = False def __init__(self, *args, **kwargs): super().__init__(*args, **kwargs) self.raise_on_transform = False self.underlying_transform = mtransforms.Affine2D().scale(10, 10) def transform_path_non_affine(self, path): assert not self.raise_on_transform, \ 'Invalidated affine part of transform unnecessarily.' return self.underlying_transform.transform_path(path) transform_path = transform_path_non_affine def transform_non_affine(self, path): assert not self.raise_on_transform, \ 'Invalidated affine part of transform unnecessarily.' return self.underlying_transform.transform(path) transform = transform_non_affine my_trans = AssertingNonAffineTransform() ax = plt.axes() plt.plot(np.arange(10), transform=my_trans + ax.transData) plt.draw() # enable the transform to raise an exception if it's non-affine transform # method is triggered again. my_trans.raise_on_transform = True ax.transAxes.invalidate() plt.draw() def test_external_transform_api(): class ScaledBy: def __init__(self, scale_factor): self._scale_factor = scale_factor def _as_mpl_transform(self, axes): return (mtransforms.Affine2D().scale(self._scale_factor) + axes.transData) ax = plt.axes() line, = plt.plot(np.arange(10), transform=ScaledBy(10)) ax.set_xlim(0, 100) ax.set_ylim(0, 100) # assert that the top transform of the line is the scale transform. assert_allclose(line.get_transform()._a.get_matrix(), mtransforms.Affine2D().scale(10).get_matrix()) @image_comparison(['pre_transform_data'], tol=0.08, remove_text=True, style='mpl20') def test_pre_transform_plotting(): # a catch-all for as many as possible plot layouts which handle # pre-transforming the data NOTE: The axis range is important in this # plot. It should be x10 what the data suggests it should be # Remove this line when this test image is regenerated. plt.rcParams['pcolormesh.snap'] = False ax = plt.axes() times10 = mtransforms.Affine2D().scale(10) ax.contourf(np.arange(48).reshape(6, 8), transform=times10 + ax.transData) ax.pcolormesh(np.linspace(0, 4, 7), np.linspace(5.5, 8, 9), np.arange(48).reshape(8, 6), transform=times10 + ax.transData) ax.scatter(np.linspace(0, 10), np.linspace(10, 0), transform=times10 + ax.transData) x = np.linspace(8, 10, 20) y = np.linspace(1, 5, 20) u = 2*np.sin(x) + np.cos(y[:, np.newaxis]) v = np.sin(x) - np.cos(y[:, np.newaxis]) df = 25. / 30. # Compatibility factor for old test image ax.streamplot(x, y, u, v, transform=times10 + ax.transData, density=(df, df), linewidth=u**2 + v**2) # reduce the vector data down a bit for barb and quiver plotting x, y = x[::3], y[::3] u, v = u[::3, ::3], v[::3, ::3] ax.quiver(x, y + 5, u, v, transform=times10 + ax.transData) ax.barbs(x - 3, y + 5, u**2, v**2, transform=times10 + ax.transData) def test_contour_pre_transform_limits(): ax = plt.axes() xs, ys = np.meshgrid(np.linspace(15, 20, 15), np.linspace(12.4, 12.5, 20)) ax.contourf(xs, ys, np.log(xs * ys), transform=mtransforms.Affine2D().scale(0.1) + ax.transData) expected = np.array([[1.5, 1.24], [2., 1.25]]) assert_almost_equal(expected, ax.dataLim.get_points()) def test_pcolor_pre_transform_limits(): # Based on test_contour_pre_transform_limits() ax = plt.axes() xs, ys = np.meshgrid(np.linspace(15, 20, 15), np.linspace(12.4, 12.5, 20)) ax.pcolor(xs, ys, np.log(xs * ys)[:-1, :-1], transform=mtransforms.Affine2D().scale(0.1) + ax.transData) expected = np.array([[1.5, 1.24], [2., 1.25]]) assert_almost_equal(expected, ax.dataLim.get_points()) def test_pcolormesh_pre_transform_limits(): # Based on test_contour_pre_transform_limits() ax = plt.axes() xs, ys = np.meshgrid(np.linspace(15, 20, 15), np.linspace(12.4, 12.5, 20)) ax.pcolormesh(xs, ys, np.log(xs * ys)[:-1, :-1], transform=mtransforms.Affine2D().scale(0.1) + ax.transData) expected = np.array([[1.5, 1.24], [2., 1.25]]) assert_almost_equal(expected, ax.dataLim.get_points()) def test_Affine2D_from_values(): points = np.array([[0, 0], [10, 20], [-1, 0], ]) t = mtransforms.Affine2D.from_values(1, 0, 0, 0, 0, 0) actual = t.transform(points) expected = np.array([[0, 0], [10, 0], [-1, 0]]) assert_almost_equal(actual, expected) t = mtransforms.Affine2D.from_values(0, 2, 0, 0, 0, 0) actual = t.transform(points) expected = np.array([[0, 0], [0, 20], [0, -2]]) assert_almost_equal(actual, expected) t = mtransforms.Affine2D.from_values(0, 0, 3, 0, 0, 0) actual = t.transform(points) expected = np.array([[0, 0], [60, 0], [0, 0]]) assert_almost_equal(actual, expected) t = mtransforms.Affine2D.from_values(0, 0, 0, 4, 0, 0) actual = t.transform(points) expected = np.array([[0, 0], [0, 80], [0, 0]]) assert_almost_equal(actual, expected) t = mtransforms.Affine2D.from_values(0, 0, 0, 0, 5, 0) actual = t.transform(points) expected = np.array([[5, 0], [5, 0], [5, 0]]) assert_almost_equal(actual, expected) t = mtransforms.Affine2D.from_values(0, 0, 0, 0, 0, 6) actual = t.transform(points) expected = np.array([[0, 6], [0, 6], [0, 6]]) assert_almost_equal(actual, expected) def test_affine_inverted_invalidated(): # Ensure that the an affine transform is not declared valid on access point = [1.0, 1.0] t = mtransforms.Affine2D() assert_almost_equal(point, t.transform(t.inverted().transform(point))) # Change and access the transform t.translate(1.0, 1.0).get_matrix() assert_almost_equal(point, t.transform(t.inverted().transform(point))) def test_clipping_of_log(): # issue 804 path = Path([(0.2, -99), (0.4, -99), (0.4, 20), (0.2, 20), (0.2, -99)], closed=True) # something like this happens in plotting logarithmic histograms trans = mtransforms.BlendedGenericTransform( mtransforms.Affine2D(), scale.LogTransform(10, 'clip')) tpath = trans.transform_path_non_affine(path) result = tpath.iter_segments(trans.get_affine(), clip=(0, 0, 100, 100), simplify=False) tpoints, tcodes = zip(*result) assert_allclose(tcodes, path.codes) class NonAffineForTest(mtransforms.Transform): """ A class which looks like a non affine transform, but does whatever the given transform does (even if it is affine). This is very useful for testing NonAffine behaviour with a simple Affine transform. """ is_affine = False output_dims = 2 input_dims = 2 def __init__(self, real_trans, *args, **kwargs): self.real_trans = real_trans super().__init__(*args, **kwargs) def transform_non_affine(self, values): return self.real_trans.transform(values) def transform_path_non_affine(self, path): return self.real_trans.transform_path(path) class TestBasicTransform: def setup_method(self): self.ta1 = mtransforms.Affine2D(shorthand_name='ta1').rotate(np.pi / 2) self.ta2 = mtransforms.Affine2D(shorthand_name='ta2').translate(10, 0) self.ta3 = mtransforms.Affine2D(shorthand_name='ta3').scale(1, 2) self.tn1 = NonAffineForTest(mtransforms.Affine2D().translate(1, 2), shorthand_name='tn1') self.tn2 = NonAffineForTest(mtransforms.Affine2D().translate(1, 2), shorthand_name='tn2') self.tn3 = NonAffineForTest(mtransforms.Affine2D().translate(1, 2), shorthand_name='tn3') # creates a transform stack which looks like ((A, (N, A)), A) self.stack1 = (self.ta1 + (self.tn1 + self.ta2)) + self.ta3 # creates a transform stack which looks like (((A, N), A), A) self.stack2 = self.ta1 + self.tn1 + self.ta2 + self.ta3 # creates a transform stack which is a subset of stack2 self.stack2_subset = self.tn1 + self.ta2 + self.ta3 # when in debug, the transform stacks can produce dot images: # self.stack1.write_graphviz(file('stack1.dot', 'w')) # self.stack2.write_graphviz(file('stack2.dot', 'w')) # self.stack2_subset.write_graphviz(file('stack2_subset.dot', 'w')) def test_transform_depth(self): assert self.stack1.depth == 4 assert self.stack2.depth == 4 assert self.stack2_subset.depth == 3 def test_left_to_right_iteration(self): stack3 = (self.ta1 + (self.tn1 + (self.ta2 + self.tn2))) + self.ta3 # stack3.write_graphviz(file('stack3.dot', 'w')) target_transforms = [stack3, (self.tn1 + (self.ta2 + self.tn2)) + self.ta3, (self.ta2 + self.tn2) + self.ta3, self.tn2 + self.ta3, self.ta3, ] r = [rh for _, rh in stack3._iter_break_from_left_to_right()] assert len(r) == len(target_transforms) for target_stack, stack in zip(target_transforms, r): assert target_stack == stack def test_transform_shortcuts(self): assert self.stack1 - self.stack2_subset == self.ta1 assert self.stack2 - self.stack2_subset == self.ta1 assert self.stack2_subset - self.stack2 == self.ta1.inverted() assert (self.stack2_subset - self.stack2).depth == 1 with pytest.raises(ValueError): self.stack1 - self.stack2 aff1 = self.ta1 + (self.ta2 + self.ta3) aff2 = self.ta2 + self.ta3 assert aff1 - aff2 == self.ta1 assert aff1 - self.ta2 == aff1 + self.ta2.inverted() assert self.stack1 - self.ta3 == self.ta1 + (self.tn1 + self.ta2) assert self.stack2 - self.ta3 == self.ta1 + self.tn1 + self.ta2 assert ((self.ta2 + self.ta3) - self.ta3 + self.ta3 == self.ta2 + self.ta3) def test_contains_branch(self): r1 = (self.ta2 + self.ta1) r2 = (self.ta2 + self.ta1) assert r1 == r2 assert r1 != self.ta1 assert r1.contains_branch(r2) assert r1.contains_branch(self.ta1) assert not r1.contains_branch(self.ta2) assert not r1.contains_branch(self.ta2 + self.ta2) assert r1 == r2 assert self.stack1.contains_branch(self.ta3) assert self.stack2.contains_branch(self.ta3) assert self.stack1.contains_branch(self.stack2_subset) assert self.stack2.contains_branch(self.stack2_subset) assert not self.stack2_subset.contains_branch(self.stack1) assert not self.stack2_subset.contains_branch(self.stack2) assert self.stack1.contains_branch(self.ta2 + self.ta3) assert self.stack2.contains_branch(self.ta2 + self.ta3) assert not self.stack1.contains_branch(self.tn1 + self.ta2) def test_affine_simplification(self): # tests that a transform stack only calls as much is absolutely # necessary "non-affine" allowing the best possible optimization with # complex transformation stacks. points = np.array([[0, 0], [10, 20], [np.nan, 1], [-1, 0]], dtype=np.float64) na_pts = self.stack1.transform_non_affine(points) all_pts = self.stack1.transform(points) na_expected = np.array([[1., 2.], [-19., 12.], [np.nan, np.nan], [1., 1.]], dtype=np.float64) all_expected = np.array([[11., 4.], [-9., 24.], [np.nan, np.nan], [11., 2.]], dtype=np.float64) # check we have the expected results from doing the affine part only assert_array_almost_equal(na_pts, na_expected) # check we have the expected results from a full transformation assert_array_almost_equal(all_pts, all_expected) # check we have the expected results from doing the transformation in # two steps assert_array_almost_equal(self.stack1.transform_affine(na_pts), all_expected) # check that getting the affine transformation first, then fully # transforming using that yields the same result as before. assert_array_almost_equal(self.stack1.get_affine().transform(na_pts), all_expected) # check that the affine part of stack1 & stack2 are equivalent # (i.e. the optimization is working) expected_result = (self.ta2 + self.ta3).get_matrix() result = self.stack1.get_affine().get_matrix() assert_array_equal(expected_result, result) result = self.stack2.get_affine().get_matrix() assert_array_equal(expected_result, result) class TestTransformPlotInterface: def test_line_extent_axes_coords(self): # a simple line in axes coordinates ax = plt.axes() ax.plot([0.1, 1.2, 0.8], [0.9, 0.5, 0.8], transform=ax.transAxes) assert_array_equal(ax.dataLim.get_points(), np.array([[np.inf, np.inf], [-np.inf, -np.inf]])) def test_line_extent_data_coords(self): # a simple line in data coordinates ax = plt.axes() ax.plot([0.1, 1.2, 0.8], [0.9, 0.5, 0.8], transform=ax.transData) assert_array_equal(ax.dataLim.get_points(), np.array([[0.1, 0.5], [1.2, 0.9]])) def test_line_extent_compound_coords1(self): # a simple line in data coordinates in the y component, and in axes # coordinates in the x ax = plt.axes() trans = mtransforms.blended_transform_factory(ax.transAxes, ax.transData) ax.plot([0.1, 1.2, 0.8], [35, -5, 18], transform=trans) assert_array_equal(ax.dataLim.get_points(), np.array([[np.inf, -5.], [-np.inf, 35.]])) def test_line_extent_predata_transform_coords(self): # a simple line in (offset + data) coordinates ax = plt.axes() trans = mtransforms.Affine2D().scale(10) + ax.transData ax.plot([0.1, 1.2, 0.8], [35, -5, 18], transform=trans) assert_array_equal(ax.dataLim.get_points(), np.array([[1., -50.], [12., 350.]])) def test_line_extent_compound_coords2(self): # a simple line in (offset + data) coordinates in the y component, and # in axes coordinates in the x ax = plt.axes() trans = mtransforms.blended_transform_factory( ax.transAxes, mtransforms.Affine2D().scale(10) + ax.transData) ax.plot([0.1, 1.2, 0.8], [35, -5, 18], transform=trans) assert_array_equal(ax.dataLim.get_points(), np.array([[np.inf, -50.], [-np.inf, 350.]])) def test_line_extents_affine(self): ax = plt.axes() offset = mtransforms.Affine2D().translate(10, 10) plt.plot(np.arange(10), transform=offset + ax.transData) expected_data_lim = np.array([[0., 0.], [9., 9.]]) + 10 assert_array_almost_equal(ax.dataLim.get_points(), expected_data_lim) def test_line_extents_non_affine(self): ax = plt.axes() offset = mtransforms.Affine2D().translate(10, 10) na_offset = NonAffineForTest(mtransforms.Affine2D().translate(10, 10)) plt.plot(np.arange(10), transform=offset + na_offset + ax.transData) expected_data_lim = np.array([[0., 0.], [9., 9.]]) + 20 assert_array_almost_equal(ax.dataLim.get_points(), expected_data_lim) def test_pathc_extents_non_affine(self): ax = plt.axes() offset = mtransforms.Affine2D().translate(10, 10) na_offset = NonAffineForTest(mtransforms.Affine2D().translate(10, 10)) pth = Path(np.array([[0, 0], [0, 10], [10, 10], [10, 0]])) patch = mpatches.PathPatch(pth, transform=offset + na_offset + ax.transData) ax.add_patch(patch) expected_data_lim = np.array([[0., 0.], [10., 10.]]) + 20 assert_array_almost_equal(ax.dataLim.get_points(), expected_data_lim) def test_pathc_extents_affine(self): ax = plt.axes() offset = mtransforms.Affine2D().translate(10, 10) pth = Path(np.array([[0, 0], [0, 10], [10, 10], [10, 0]])) patch = mpatches.PathPatch(pth, transform=offset + ax.transData) ax.add_patch(patch) expected_data_lim = np.array([[0., 0.], [10., 10.]]) + 10 assert_array_almost_equal(ax.dataLim.get_points(), expected_data_lim) def test_line_extents_for_non_affine_transData(self): ax = plt.axes(projection='polar') # add 10 to the radius of the data offset = mtransforms.Affine2D().translate(0, 10) plt.plot(np.arange(10), transform=offset + ax.transData) # the data lim of a polar plot is stored in coordinates # before a transData transformation, hence the data limits # are not what is being shown on the actual plot. expected_data_lim = np.array([[0., 0.], [9., 9.]]) + [0, 10] assert_array_almost_equal(ax.dataLim.get_points(), expected_data_lim) def assert_bbox_eq(bbox1, bbox2): assert_array_equal(bbox1.bounds, bbox2.bounds) def test_bbox_intersection(): bbox_from_ext = mtransforms.Bbox.from_extents inter = mtransforms.Bbox.intersection r1 = bbox_from_ext(0, 0, 1, 1) r2 = bbox_from_ext(0.5, 0.5, 1.5, 1.5) r3 = bbox_from_ext(0.5, 0, 0.75, 0.75) r4 = bbox_from_ext(0.5, 1.5, 1, 2.5) r5 = bbox_from_ext(1, 1, 2, 2) # self intersection -> no change assert_bbox_eq(inter(r1, r1), r1) # simple intersection assert_bbox_eq(inter(r1, r2), bbox_from_ext(0.5, 0.5, 1, 1)) # r3 contains r2 assert_bbox_eq(inter(r1, r3), r3) # no intersection assert inter(r1, r4) is None # single point assert_bbox_eq(inter(r1, r5), bbox_from_ext(1, 1, 1, 1)) def test_bbox_as_strings(): b = mtransforms.Bbox([[.5, 0], [.75, .75]]) assert_bbox_eq(b, eval(repr(b), {'Bbox': mtransforms.Bbox})) asdict = eval(str(b), {'Bbox': dict}) for k, v in asdict.items(): assert getattr(b, k) == v fmt = '.1f' asdict = eval(format(b, fmt), {'Bbox': dict}) for k, v in asdict.items(): assert eval(format(getattr(b, k), fmt)) == v def test_str_transform(): # The str here should not be considered as "absolutely stable", and may be # reformatted later; this is just a smoketest for __str__. assert str(plt.subplot(projection="polar").transData) == """\ CompositeGenericTransform( CompositeGenericTransform( CompositeGenericTransform( TransformWrapper( BlendedAffine2D( IdentityTransform(), IdentityTransform())), CompositeAffine2D( Affine2D( [[1. 0. 0.] [0. 1. 0.] [0. 0. 1.]]), Affine2D( [[1. 0. 0.] [0. 1. 0.] [0. 0. 1.]]))), PolarTransform( PolarAxesSubplot(0.125,0.1;0.775x0.8), use_rmin=True, _apply_theta_transforms=False)), CompositeGenericTransform( CompositeGenericTransform( PolarAffine( TransformWrapper( BlendedAffine2D( IdentityTransform(), IdentityTransform())), LockableBbox( Bbox(x0=0.0, y0=0.0, x1=6.283185307179586, y1=1.0), [[-- --] [-- --]])), BboxTransformFrom( _WedgeBbox( (0.5, 0.5), TransformedBbox( Bbox(x0=0.0, y0=0.0, x1=6.283185307179586, y1=1.0), CompositeAffine2D( Affine2D( [[1. 0. 0.] [0. 1. 0.] [0. 0. 1.]]), Affine2D( [[1. 0. 0.] [0. 1. 0.] [0. 0. 1.]]))), LockableBbox( Bbox(x0=0.0, y0=0.0, x1=6.283185307179586, y1=1.0), [[-- --] [-- --]])))), BboxTransformTo( TransformedBbox( Bbox(x0=0.125, y0=0.09999999999999998, x1=0.9, y1=0.9), BboxTransformTo( TransformedBbox( Bbox(x0=0.0, y0=0.0, x1=8.0, y1=6.0), Affine2D( [[80. 0. 0.] [ 0. 80. 0.] [ 0. 0. 1.]])))))))""" def test_transform_single_point(): t = mtransforms.Affine2D() r = t.transform_affine((1, 1)) assert r.shape == (2,) def test_log_transform(): # Tests that the last line runs without exception (previously the # transform would fail if one of the axes was logarithmic). fig, ax = plt.subplots() ax.set_yscale('log') ax.transData.transform((1, 1)) def test_nan_overlap(): a = mtransforms.Bbox([[0, 0], [1, 1]]) b = mtransforms.Bbox([[0, 0], [1, np.nan]]) assert not a.overlaps(b) def test_transform_angles(): t = mtransforms.Affine2D() # Identity transform angles = np.array([20, 45, 60]) points = np.array([[0, 0], [1, 1], [2, 2]]) # Identity transform does not change angles new_angles = t.transform_angles(angles, points) assert_array_almost_equal(angles, new_angles) # points missing a 2nd dimension with pytest.raises(ValueError): t.transform_angles(angles, points[0:2, 0:1]) # Number of angles != Number of points with pytest.raises(ValueError): t.transform_angles(angles, points[0:2, :]) def test_nonsingular(): # test for zero-expansion type cases; other cases may be added later zero_expansion = np.array([-0.001, 0.001]) cases = [(0, np.nan), (0, 0), (0, 7.9e-317)] for args in cases: out = np.array(mtransforms.nonsingular(*args)) assert_array_equal(out, zero_expansion) def test_invalid_arguments(): t = mtransforms.Affine2D() # There are two different exceptions, since the wrong number of # dimensions is caught when constructing an array_view, and that # raises a ValueError, and a wrong shape with a possible number # of dimensions is caught by our CALL_CPP macro, which always # raises the less precise RuntimeError. with pytest.raises(ValueError): t.transform(1) with pytest.raises(ValueError): t.transform([[[1]]]) with pytest.raises(RuntimeError): t.transform([]) with pytest.raises(RuntimeError): t.transform([1]) with pytest.raises(RuntimeError): t.transform([[1]]) with pytest.raises(RuntimeError): t.transform([[1, 2, 3]]) def test_transformed_path(): points = [(0, 0), (1, 0), (1, 1), (0, 1)] path = Path(points, closed=True) trans = mtransforms.Affine2D() trans_path = mtransforms.TransformedPath(path, trans) assert_allclose(trans_path.get_fully_transformed_path().vertices, points) # Changing the transform should change the result. r2 = 1 / np.sqrt(2) trans.rotate(np.pi / 4) assert_allclose(trans_path.get_fully_transformed_path().vertices, [(0, 0), (r2, r2), (0, 2 * r2), (-r2, r2)], atol=1e-15) # Changing the path does not change the result (it's cached). path.points = [(0, 0)] * 4 assert_allclose(trans_path.get_fully_transformed_path().vertices, [(0, 0), (r2, r2), (0, 2 * r2), (-r2, r2)], atol=1e-15) def test_transformed_patch_path(): trans = mtransforms.Affine2D() patch = mpatches.Wedge((0, 0), 1, 45, 135, transform=trans) tpatch = mtransforms.TransformedPatchPath(patch) points = tpatch.get_fully_transformed_path().vertices # Changing the transform should change the result. trans.scale(2) assert_allclose(tpatch.get_fully_transformed_path().vertices, points * 2) # Changing the path should change the result (and cancel out the scaling # from the transform). patch.set_radius(0.5) assert_allclose(tpatch.get_fully_transformed_path().vertices, points) @pytest.mark.parametrize('locked_element', ['x0', 'y0', 'x1', 'y1']) def test_lockable_bbox(locked_element): other_elements = ['x0', 'y0', 'x1', 'y1'] other_elements.remove(locked_element) orig = mtransforms.Bbox.unit() locked = mtransforms.LockableBbox(orig, **{locked_element: 2}) # LockableBbox should keep its locked element as specified in __init__. assert getattr(locked, locked_element) == 2 assert getattr(locked, 'locked_' + locked_element) == 2 for elem in other_elements: assert getattr(locked, elem) == getattr(orig, elem) # Changing underlying Bbox should update everything but locked element. orig.set_points(orig.get_points() + 10) assert getattr(locked, locked_element) == 2 assert getattr(locked, 'locked_' + locked_element) == 2 for elem in other_elements: assert getattr(locked, elem) == getattr(orig, elem) # Unlocking element should revert values back to the underlying Bbox. setattr(locked, 'locked_' + locked_element, None) assert getattr(locked, 'locked_' + locked_element) is None assert np.all(orig.get_points() == locked.get_points()) # Relocking an element should change its value, but not others. setattr(locked, 'locked_' + locked_element, 3) assert getattr(locked, locked_element) == 3 assert getattr(locked, 'locked_' + locked_element) == 3 for elem in other_elements: assert getattr(locked, elem) == getattr(orig, elem) def test_copy(): a = mtransforms.Affine2D() b = mtransforms.Affine2D() s = a + b # Updating a dependee should invalidate a copy of the dependent. s.get_matrix() # resolve it. s1 = copy.copy(s) assert not s._invalid and not s1._invalid a.translate(1, 2) assert s._invalid and s1._invalid assert (s1.get_matrix() == a.get_matrix()).all() # Updating a copy of a dependee shouldn't invalidate a dependent. s.get_matrix() # resolve it. b1 = copy.copy(b) b1.translate(3, 4) assert not s._invalid assert (s.get_matrix() == a.get_matrix()).all() def test_deepcopy(): a = mtransforms.Affine2D() b = mtransforms.Affine2D() s = a + b # Updating a dependee shouldn't invalidate a deepcopy of the dependent. s.get_matrix() # resolve it. s1 = copy.deepcopy(s) assert not s._invalid and not s1._invalid a.translate(1, 2) assert s._invalid and not s1._invalid assert (s1.get_matrix() == mtransforms.Affine2D().get_matrix()).all() # Updating a deepcopy of a dependee shouldn't invalidate a dependent. s.get_matrix() # resolve it. b1 = copy.deepcopy(b) b1.translate(3, 4) assert not s._invalid assert (s.get_matrix() == a.get_matrix()).all()