# # Author: Damian Eads # Date: April 17, 2008 # # Copyright (C) 2008 Damian Eads # # Redistribution and use in source and binary forms, with or without # modification, are permitted provided that the following conditions # are met: # # 1. Redistributions of source code must retain the above copyright # notice, this list of conditions and the following disclaimer. # # 2. Redistributions in binary form must reproduce the above # copyright notice, this list of conditions and the following # disclaimer in the documentation and/or other materials provided # with the distribution. # # 3. The name of the author may not be used to endorse or promote # products derived from this software without specific prior # written permission. # # THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS # OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED # WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE # ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY # DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL # DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE # GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS # INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, # WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING # NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS # SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. import numpy as np from numpy.testing import assert_allclose, assert_equal, assert_, assert_warns import pytest from pytest import raises as assert_raises import scipy.cluster.hierarchy from scipy.cluster.hierarchy import ( ClusterWarning, linkage, from_mlab_linkage, to_mlab_linkage, num_obs_linkage, inconsistent, cophenet, fclusterdata, fcluster, is_isomorphic, single, leaders, correspond, is_monotonic, maxdists, maxinconsts, maxRstat, is_valid_linkage, is_valid_im, to_tree, leaves_list, dendrogram, set_link_color_palette, cut_tree, optimal_leaf_ordering, _order_cluster_tree, _hierarchy, _LINKAGE_METHODS) from scipy.spatial.distance import pdist from scipy.cluster._hierarchy import Heap from . import hierarchy_test_data # Matplotlib is not a scipy dependency but is optionally used in dendrogram, so # check if it's available try: import matplotlib # type: ignore[import] # and set the backend to be Agg (no gui) matplotlib.use('Agg') # before importing pyplot import matplotlib.pyplot as plt # type: ignore[import] have_matplotlib = True except Exception: have_matplotlib = False class TestLinkage(object): def test_linkage_non_finite_elements_in_distance_matrix(self): # Tests linkage(Y) where Y contains a non-finite element (e.g. NaN or Inf). # Exception expected. y = np.zeros((6,)) y[0] = np.nan assert_raises(ValueError, linkage, y) def test_linkage_empty_distance_matrix(self): # Tests linkage(Y) where Y is a 0x4 linkage matrix. Exception expected. y = np.zeros((0,)) assert_raises(ValueError, linkage, y) def test_linkage_tdist(self): for method in ['single', 'complete', 'average', 'weighted']: self.check_linkage_tdist(method) def check_linkage_tdist(self, method): # Tests linkage(Y, method) on the tdist data set. Z = linkage(hierarchy_test_data.ytdist, method) expectedZ = getattr(hierarchy_test_data, 'linkage_ytdist_' + method) assert_allclose(Z, expectedZ, atol=1e-10) def test_linkage_X(self): for method in ['centroid', 'median', 'ward']: self.check_linkage_q(method) def check_linkage_q(self, method): # Tests linkage(Y, method) on the Q data set. Z = linkage(hierarchy_test_data.X, method) expectedZ = getattr(hierarchy_test_data, 'linkage_X_' + method) assert_allclose(Z, expectedZ, atol=1e-06) y = scipy.spatial.distance.pdist(hierarchy_test_data.X, metric="euclidean") Z = linkage(y, method) assert_allclose(Z, expectedZ, atol=1e-06) def test_compare_with_trivial(self): rng = np.random.RandomState(0) n = 20 X = rng.rand(n, 2) d = pdist(X) for method, code in _LINKAGE_METHODS.items(): Z_trivial = _hierarchy.linkage(d, n, code) Z = linkage(d, method) assert_allclose(Z_trivial, Z, rtol=1e-14, atol=1e-15) def test_optimal_leaf_ordering(self): Z = linkage(hierarchy_test_data.ytdist, optimal_ordering=True) expectedZ = getattr(hierarchy_test_data, 'linkage_ytdist_single_olo') assert_allclose(Z, expectedZ, atol=1e-10) class TestLinkageTies(object): _expectations = { 'single': np.array([[0, 1, 1.41421356, 2], [2, 3, 1.41421356, 3]]), 'complete': np.array([[0, 1, 1.41421356, 2], [2, 3, 2.82842712, 3]]), 'average': np.array([[0, 1, 1.41421356, 2], [2, 3, 2.12132034, 3]]), 'weighted': np.array([[0, 1, 1.41421356, 2], [2, 3, 2.12132034, 3]]), 'centroid': np.array([[0, 1, 1.41421356, 2], [2, 3, 2.12132034, 3]]), 'median': np.array([[0, 1, 1.41421356, 2], [2, 3, 2.12132034, 3]]), 'ward': np.array([[0, 1, 1.41421356, 2], [2, 3, 2.44948974, 3]]), } def test_linkage_ties(self): for method in ['single', 'complete', 'average', 'weighted', 'centroid', 'median', 'ward']: self.check_linkage_ties(method) def check_linkage_ties(self, method): X = np.array([[-1, -1], [0, 0], [1, 1]]) Z = linkage(X, method=method) expectedZ = self._expectations[method] assert_allclose(Z, expectedZ, atol=1e-06) class TestInconsistent(object): def test_inconsistent_tdist(self): for depth in hierarchy_test_data.inconsistent_ytdist: self.check_inconsistent_tdist(depth) def check_inconsistent_tdist(self, depth): Z = hierarchy_test_data.linkage_ytdist_single assert_allclose(inconsistent(Z, depth), hierarchy_test_data.inconsistent_ytdist[depth]) class TestCopheneticDistance(object): def test_linkage_cophenet_tdist_Z(self): # Tests cophenet(Z) on tdist data set. expectedM = np.array([268, 295, 255, 255, 295, 295, 268, 268, 295, 295, 295, 138, 219, 295, 295]) Z = hierarchy_test_data.linkage_ytdist_single M = cophenet(Z) assert_allclose(M, expectedM, atol=1e-10) def test_linkage_cophenet_tdist_Z_Y(self): # Tests cophenet(Z, Y) on tdist data set. Z = hierarchy_test_data.linkage_ytdist_single (c, M) = cophenet(Z, hierarchy_test_data.ytdist) expectedM = np.array([268, 295, 255, 255, 295, 295, 268, 268, 295, 295, 295, 138, 219, 295, 295]) expectedc = 0.639931296433393415057366837573 assert_allclose(c, expectedc, atol=1e-10) assert_allclose(M, expectedM, atol=1e-10) class TestMLabLinkageConversion(object): def test_mlab_linkage_conversion_empty(self): # Tests from/to_mlab_linkage on empty linkage array. X = np.asarray([]) assert_equal(from_mlab_linkage([]), X) assert_equal(to_mlab_linkage([]), X) def test_mlab_linkage_conversion_single_row(self): # Tests from/to_mlab_linkage on linkage array with single row. Z = np.asarray([[0., 1., 3., 2.]]) Zm = [[1, 2, 3]] assert_equal(from_mlab_linkage(Zm), Z) assert_equal(to_mlab_linkage(Z), Zm) def test_mlab_linkage_conversion_multiple_rows(self): # Tests from/to_mlab_linkage on linkage array with multiple rows. Zm = np.asarray([[3, 6, 138], [4, 5, 219], [1, 8, 255], [2, 9, 268], [7, 10, 295]]) Z = np.array([[2., 5., 138., 2.], [3., 4., 219., 2.], [0., 7., 255., 3.], [1., 8., 268., 4.], [6., 9., 295., 6.]], dtype=np.double) assert_equal(from_mlab_linkage(Zm), Z) assert_equal(to_mlab_linkage(Z), Zm) class TestFcluster(object): def test_fclusterdata(self): for t in hierarchy_test_data.fcluster_inconsistent: self.check_fclusterdata(t, 'inconsistent') for t in hierarchy_test_data.fcluster_distance: self.check_fclusterdata(t, 'distance') for t in hierarchy_test_data.fcluster_maxclust: self.check_fclusterdata(t, 'maxclust') def check_fclusterdata(self, t, criterion): # Tests fclusterdata(X, criterion=criterion, t=t) on a random 3-cluster data set. expectedT = getattr(hierarchy_test_data, 'fcluster_' + criterion)[t] X = hierarchy_test_data.Q_X T = fclusterdata(X, criterion=criterion, t=t) assert_(is_isomorphic(T, expectedT)) def test_fcluster(self): for t in hierarchy_test_data.fcluster_inconsistent: self.check_fcluster(t, 'inconsistent') for t in hierarchy_test_data.fcluster_distance: self.check_fcluster(t, 'distance') for t in hierarchy_test_data.fcluster_maxclust: self.check_fcluster(t, 'maxclust') def check_fcluster(self, t, criterion): # Tests fcluster(Z, criterion=criterion, t=t) on a random 3-cluster data set. expectedT = getattr(hierarchy_test_data, 'fcluster_' + criterion)[t] Z = single(hierarchy_test_data.Q_X) T = fcluster(Z, criterion=criterion, t=t) assert_(is_isomorphic(T, expectedT)) def test_fcluster_monocrit(self): for t in hierarchy_test_data.fcluster_distance: self.check_fcluster_monocrit(t) for t in hierarchy_test_data.fcluster_maxclust: self.check_fcluster_maxclust_monocrit(t) def check_fcluster_monocrit(self, t): expectedT = hierarchy_test_data.fcluster_distance[t] Z = single(hierarchy_test_data.Q_X) T = fcluster(Z, t, criterion='monocrit', monocrit=maxdists(Z)) assert_(is_isomorphic(T, expectedT)) def check_fcluster_maxclust_monocrit(self, t): expectedT = hierarchy_test_data.fcluster_maxclust[t] Z = single(hierarchy_test_data.Q_X) T = fcluster(Z, t, criterion='maxclust_monocrit', monocrit=maxdists(Z)) assert_(is_isomorphic(T, expectedT)) class TestLeaders(object): def test_leaders_single(self): # Tests leaders using a flat clustering generated by single linkage. X = hierarchy_test_data.Q_X Y = pdist(X) Z = linkage(Y) T = fcluster(Z, criterion='maxclust', t=3) Lright = (np.array([53, 55, 56]), np.array([2, 3, 1])) L = leaders(Z, T) assert_equal(L, Lright) class TestIsIsomorphic(object): def test_is_isomorphic_1(self): # Tests is_isomorphic on test case #1 (one flat cluster, different labellings) a = [1, 1, 1] b = [2, 2, 2] assert_(is_isomorphic(a, b)) assert_(is_isomorphic(b, a)) def test_is_isomorphic_2(self): # Tests is_isomorphic on test case #2 (two flat clusters, different labelings) a = [1, 7, 1] b = [2, 3, 2] assert_(is_isomorphic(a, b)) assert_(is_isomorphic(b, a)) def test_is_isomorphic_3(self): # Tests is_isomorphic on test case #3 (no flat clusters) a = [] b = [] assert_(is_isomorphic(a, b)) def test_is_isomorphic_4A(self): # Tests is_isomorphic on test case #4A (3 flat clusters, different labelings, isomorphic) a = [1, 2, 3] b = [1, 3, 2] assert_(is_isomorphic(a, b)) assert_(is_isomorphic(b, a)) def test_is_isomorphic_4B(self): # Tests is_isomorphic on test case #4B (3 flat clusters, different labelings, nonisomorphic) a = [1, 2, 3, 3] b = [1, 3, 2, 3] assert_(is_isomorphic(a, b) == False) assert_(is_isomorphic(b, a) == False) def test_is_isomorphic_4C(self): # Tests is_isomorphic on test case #4C (3 flat clusters, different labelings, isomorphic) a = [7, 2, 3] b = [6, 3, 2] assert_(is_isomorphic(a, b)) assert_(is_isomorphic(b, a)) def test_is_isomorphic_5(self): # Tests is_isomorphic on test case #5 (1000 observations, 2/3/5 random # clusters, random permutation of the labeling). for nc in [2, 3, 5]: self.help_is_isomorphic_randperm(1000, nc) def test_is_isomorphic_6(self): # Tests is_isomorphic on test case #5A (1000 observations, 2/3/5 random # clusters, random permutation of the labeling, slightly # nonisomorphic.) for nc in [2, 3, 5]: self.help_is_isomorphic_randperm(1000, nc, True, 5) def test_is_isomorphic_7(self): # Regression test for gh-6271 assert_(not is_isomorphic([1, 2, 3], [1, 1, 1])) def help_is_isomorphic_randperm(self, nobs, nclusters, noniso=False, nerrors=0): for k in range(3): a = np.int_(np.random.rand(nobs) * nclusters) b = np.zeros(a.size, dtype=np.int_) P = np.random.permutation(nclusters) for i in range(0, a.shape[0]): b[i] = P[a[i]] if noniso: Q = np.random.permutation(nobs) b[Q[0:nerrors]] += 1 b[Q[0:nerrors]] %= nclusters assert_(is_isomorphic(a, b) == (not noniso)) assert_(is_isomorphic(b, a) == (not noniso)) class TestIsValidLinkage(object): def test_is_valid_linkage_various_size(self): for nrow, ncol, valid in [(2, 5, False), (2, 3, False), (1, 4, True), (2, 4, True)]: self.check_is_valid_linkage_various_size(nrow, ncol, valid) def check_is_valid_linkage_various_size(self, nrow, ncol, valid): # Tests is_valid_linkage(Z) with linkage matrics of various sizes Z = np.asarray([[0, 1, 3.0, 2, 5], [3, 2, 4.0, 3, 3]], dtype=np.double) Z = Z[:nrow, :ncol] assert_(is_valid_linkage(Z) == valid) if not valid: assert_raises(ValueError, is_valid_linkage, Z, throw=True) def test_is_valid_linkage_int_type(self): # Tests is_valid_linkage(Z) with integer type. Z = np.asarray([[0, 1, 3.0, 2], [3, 2, 4.0, 3]], dtype=int) assert_(is_valid_linkage(Z) == False) assert_raises(TypeError, is_valid_linkage, Z, throw=True) def test_is_valid_linkage_empty(self): # Tests is_valid_linkage(Z) with empty linkage. Z = np.zeros((0, 4), dtype=np.double) assert_(is_valid_linkage(Z) == False) assert_raises(ValueError, is_valid_linkage, Z, throw=True) def test_is_valid_linkage_4_and_up(self): # Tests is_valid_linkage(Z) on linkage on observation sets between # sizes 4 and 15 (step size 3). for i in range(4, 15, 3): y = np.random.rand(i*(i-1)//2) Z = linkage(y) assert_(is_valid_linkage(Z) == True) def test_is_valid_linkage_4_and_up_neg_index_left(self): # Tests is_valid_linkage(Z) on linkage on observation sets between # sizes 4 and 15 (step size 3) with negative indices (left). for i in range(4, 15, 3): y = np.random.rand(i*(i-1)//2) Z = linkage(y) Z[i//2,0] = -2 assert_(is_valid_linkage(Z) == False) assert_raises(ValueError, is_valid_linkage, Z, throw=True) def test_is_valid_linkage_4_and_up_neg_index_right(self): # Tests is_valid_linkage(Z) on linkage on observation sets between # sizes 4 and 15 (step size 3) with negative indices (right). for i in range(4, 15, 3): y = np.random.rand(i*(i-1)//2) Z = linkage(y) Z[i//2,1] = -2 assert_(is_valid_linkage(Z) == False) assert_raises(ValueError, is_valid_linkage, Z, throw=True) def test_is_valid_linkage_4_and_up_neg_dist(self): # Tests is_valid_linkage(Z) on linkage on observation sets between # sizes 4 and 15 (step size 3) with negative distances. for i in range(4, 15, 3): y = np.random.rand(i*(i-1)//2) Z = linkage(y) Z[i//2,2] = -0.5 assert_(is_valid_linkage(Z) == False) assert_raises(ValueError, is_valid_linkage, Z, throw=True) def test_is_valid_linkage_4_and_up_neg_counts(self): # Tests is_valid_linkage(Z) on linkage on observation sets between # sizes 4 and 15 (step size 3) with negative counts. for i in range(4, 15, 3): y = np.random.rand(i*(i-1)//2) Z = linkage(y) Z[i//2,3] = -2 assert_(is_valid_linkage(Z) == False) assert_raises(ValueError, is_valid_linkage, Z, throw=True) class TestIsValidInconsistent(object): def test_is_valid_im_int_type(self): # Tests is_valid_im(R) with integer type. R = np.asarray([[0, 1, 3.0, 2], [3, 2, 4.0, 3]], dtype=int) assert_(is_valid_im(R) == False) assert_raises(TypeError, is_valid_im, R, throw=True) def test_is_valid_im_various_size(self): for nrow, ncol, valid in [(2, 5, False), (2, 3, False), (1, 4, True), (2, 4, True)]: self.check_is_valid_im_various_size(nrow, ncol, valid) def check_is_valid_im_various_size(self, nrow, ncol, valid): # Tests is_valid_im(R) with linkage matrics of various sizes R = np.asarray([[0, 1, 3.0, 2, 5], [3, 2, 4.0, 3, 3]], dtype=np.double) R = R[:nrow, :ncol] assert_(is_valid_im(R) == valid) if not valid: assert_raises(ValueError, is_valid_im, R, throw=True) def test_is_valid_im_empty(self): # Tests is_valid_im(R) with empty inconsistency matrix. R = np.zeros((0, 4), dtype=np.double) assert_(is_valid_im(R) == False) assert_raises(ValueError, is_valid_im, R, throw=True) def test_is_valid_im_4_and_up(self): # Tests is_valid_im(R) on im on observation sets between sizes 4 and 15 # (step size 3). for i in range(4, 15, 3): y = np.random.rand(i*(i-1)//2) Z = linkage(y) R = inconsistent(Z) assert_(is_valid_im(R) == True) def test_is_valid_im_4_and_up_neg_index_left(self): # Tests is_valid_im(R) on im on observation sets between sizes 4 and 15 # (step size 3) with negative link height means. for i in range(4, 15, 3): y = np.random.rand(i*(i-1)//2) Z = linkage(y) R = inconsistent(Z) R[i//2,0] = -2.0 assert_(is_valid_im(R) == False) assert_raises(ValueError, is_valid_im, R, throw=True) def test_is_valid_im_4_and_up_neg_index_right(self): # Tests is_valid_im(R) on im on observation sets between sizes 4 and 15 # (step size 3) with negative link height standard deviations. for i in range(4, 15, 3): y = np.random.rand(i*(i-1)//2) Z = linkage(y) R = inconsistent(Z) R[i//2,1] = -2.0 assert_(is_valid_im(R) == False) assert_raises(ValueError, is_valid_im, R, throw=True) def test_is_valid_im_4_and_up_neg_dist(self): # Tests is_valid_im(R) on im on observation sets between sizes 4 and 15 # (step size 3) with negative link counts. for i in range(4, 15, 3): y = np.random.rand(i*(i-1)//2) Z = linkage(y) R = inconsistent(Z) R[i//2,2] = -0.5 assert_(is_valid_im(R) == False) assert_raises(ValueError, is_valid_im, R, throw=True) class TestNumObsLinkage(object): def test_num_obs_linkage_empty(self): # Tests num_obs_linkage(Z) with empty linkage. Z = np.zeros((0, 4), dtype=np.double) assert_raises(ValueError, num_obs_linkage, Z) def test_num_obs_linkage_1x4(self): # Tests num_obs_linkage(Z) on linkage over 2 observations. Z = np.asarray([[0, 1, 3.0, 2]], dtype=np.double) assert_equal(num_obs_linkage(Z), 2) def test_num_obs_linkage_2x4(self): # Tests num_obs_linkage(Z) on linkage over 3 observations. Z = np.asarray([[0, 1, 3.0, 2], [3, 2, 4.0, 3]], dtype=np.double) assert_equal(num_obs_linkage(Z), 3) def test_num_obs_linkage_4_and_up(self): # Tests num_obs_linkage(Z) on linkage on observation sets between sizes # 4 and 15 (step size 3). for i in range(4, 15, 3): y = np.random.rand(i*(i-1)//2) Z = linkage(y) assert_equal(num_obs_linkage(Z), i) class TestLeavesList(object): def test_leaves_list_1x4(self): # Tests leaves_list(Z) on a 1x4 linkage. Z = np.asarray([[0, 1, 3.0, 2]], dtype=np.double) to_tree(Z) assert_equal(leaves_list(Z), [0, 1]) def test_leaves_list_2x4(self): # Tests leaves_list(Z) on a 2x4 linkage. Z = np.asarray([[0, 1, 3.0, 2], [3, 2, 4.0, 3]], dtype=np.double) to_tree(Z) assert_equal(leaves_list(Z), [0, 1, 2]) def test_leaves_list_Q(self): for method in ['single', 'complete', 'average', 'weighted', 'centroid', 'median', 'ward']: self.check_leaves_list_Q(method) def check_leaves_list_Q(self, method): # Tests leaves_list(Z) on the Q data set X = hierarchy_test_data.Q_X Z = linkage(X, method) node = to_tree(Z) assert_equal(node.pre_order(), leaves_list(Z)) def test_Q_subtree_pre_order(self): # Tests that pre_order() works when called on sub-trees. X = hierarchy_test_data.Q_X Z = linkage(X, 'single') node = to_tree(Z) assert_equal(node.pre_order(), (node.get_left().pre_order() + node.get_right().pre_order())) class TestCorrespond(object): def test_correspond_empty(self): # Tests correspond(Z, y) with empty linkage and condensed distance matrix. y = np.zeros((0,)) Z = np.zeros((0,4)) assert_raises(ValueError, correspond, Z, y) def test_correspond_2_and_up(self): # Tests correspond(Z, y) on linkage and CDMs over observation sets of # different sizes. for i in range(2, 4): y = np.random.rand(i*(i-1)//2) Z = linkage(y) assert_(correspond(Z, y)) for i in range(4, 15, 3): y = np.random.rand(i*(i-1)//2) Z = linkage(y) assert_(correspond(Z, y)) def test_correspond_4_and_up(self): # Tests correspond(Z, y) on linkage and CDMs over observation sets of # different sizes. Correspondence should be false. for (i, j) in (list(zip(list(range(2, 4)), list(range(3, 5)))) + list(zip(list(range(3, 5)), list(range(2, 4))))): y = np.random.rand(i*(i-1)//2) y2 = np.random.rand(j*(j-1)//2) Z = linkage(y) Z2 = linkage(y2) assert_equal(correspond(Z, y2), False) assert_equal(correspond(Z2, y), False) def test_correspond_4_and_up_2(self): # Tests correspond(Z, y) on linkage and CDMs over observation sets of # different sizes. Correspondence should be false. for (i, j) in (list(zip(list(range(2, 7)), list(range(16, 21)))) + list(zip(list(range(2, 7)), list(range(16, 21))))): y = np.random.rand(i*(i-1)//2) y2 = np.random.rand(j*(j-1)//2) Z = linkage(y) Z2 = linkage(y2) assert_equal(correspond(Z, y2), False) assert_equal(correspond(Z2, y), False) def test_num_obs_linkage_multi_matrix(self): # Tests num_obs_linkage with observation matrices of multiple sizes. for n in range(2, 10): X = np.random.rand(n, 4) Y = pdist(X) Z = linkage(Y) assert_equal(num_obs_linkage(Z), n) class TestIsMonotonic(object): def test_is_monotonic_empty(self): # Tests is_monotonic(Z) on an empty linkage. Z = np.zeros((0, 4)) assert_raises(ValueError, is_monotonic, Z) def test_is_monotonic_1x4(self): # Tests is_monotonic(Z) on 1x4 linkage. Expecting True. Z = np.asarray([[0, 1, 0.3, 2]], dtype=np.double) assert_equal(is_monotonic(Z), True) def test_is_monotonic_2x4_T(self): # Tests is_monotonic(Z) on 2x4 linkage. Expecting True. Z = np.asarray([[0, 1, 0.3, 2], [2, 3, 0.4, 3]], dtype=np.double) assert_equal(is_monotonic(Z), True) def test_is_monotonic_2x4_F(self): # Tests is_monotonic(Z) on 2x4 linkage. Expecting False. Z = np.asarray([[0, 1, 0.4, 2], [2, 3, 0.3, 3]], dtype=np.double) assert_equal(is_monotonic(Z), False) def test_is_monotonic_3x4_T(self): # Tests is_monotonic(Z) on 3x4 linkage. Expecting True. Z = np.asarray([[0, 1, 0.3, 2], [2, 3, 0.4, 2], [4, 5, 0.6, 4]], dtype=np.double) assert_equal(is_monotonic(Z), True) def test_is_monotonic_3x4_F1(self): # Tests is_monotonic(Z) on 3x4 linkage (case 1). Expecting False. Z = np.asarray([[0, 1, 0.3, 2], [2, 3, 0.2, 2], [4, 5, 0.6, 4]], dtype=np.double) assert_equal(is_monotonic(Z), False) def test_is_monotonic_3x4_F2(self): # Tests is_monotonic(Z) on 3x4 linkage (case 2). Expecting False. Z = np.asarray([[0, 1, 0.8, 2], [2, 3, 0.4, 2], [4, 5, 0.6, 4]], dtype=np.double) assert_equal(is_monotonic(Z), False) def test_is_monotonic_3x4_F3(self): # Tests is_monotonic(Z) on 3x4 linkage (case 3). Expecting False Z = np.asarray([[0, 1, 0.3, 2], [2, 3, 0.4, 2], [4, 5, 0.2, 4]], dtype=np.double) assert_equal(is_monotonic(Z), False) def test_is_monotonic_tdist_linkage1(self): # Tests is_monotonic(Z) on clustering generated by single linkage on # tdist data set. Expecting True. Z = linkage(hierarchy_test_data.ytdist, 'single') assert_equal(is_monotonic(Z), True) def test_is_monotonic_tdist_linkage2(self): # Tests is_monotonic(Z) on clustering generated by single linkage on # tdist data set. Perturbing. Expecting False. Z = linkage(hierarchy_test_data.ytdist, 'single') Z[2,2] = 0.0 assert_equal(is_monotonic(Z), False) def test_is_monotonic_Q_linkage(self): # Tests is_monotonic(Z) on clustering generated by single linkage on # Q data set. Expecting True. X = hierarchy_test_data.Q_X Z = linkage(X, 'single') assert_equal(is_monotonic(Z), True) class TestMaxDists(object): def test_maxdists_empty_linkage(self): # Tests maxdists(Z) on empty linkage. Expecting exception. Z = np.zeros((0, 4), dtype=np.double) assert_raises(ValueError, maxdists, Z) def test_maxdists_one_cluster_linkage(self): # Tests maxdists(Z) on linkage with one cluster. Z = np.asarray([[0, 1, 0.3, 4]], dtype=np.double) MD = maxdists(Z) expectedMD = calculate_maximum_distances(Z) assert_allclose(MD, expectedMD, atol=1e-15) def test_maxdists_Q_linkage(self): for method in ['single', 'complete', 'ward', 'centroid', 'median']: self.check_maxdists_Q_linkage(method) def check_maxdists_Q_linkage(self, method): # Tests maxdists(Z) on the Q data set X = hierarchy_test_data.Q_X Z = linkage(X, method) MD = maxdists(Z) expectedMD = calculate_maximum_distances(Z) assert_allclose(MD, expectedMD, atol=1e-15) class TestMaxInconsts(object): def test_maxinconsts_empty_linkage(self): # Tests maxinconsts(Z, R) on empty linkage. Expecting exception. Z = np.zeros((0, 4), dtype=np.double) R = np.zeros((0, 4), dtype=np.double) assert_raises(ValueError, maxinconsts, Z, R) def test_maxinconsts_difrow_linkage(self): # Tests maxinconsts(Z, R) on linkage and inconsistency matrices with # different numbers of clusters. Expecting exception. Z = np.asarray([[0, 1, 0.3, 4]], dtype=np.double) R = np.random.rand(2, 4) assert_raises(ValueError, maxinconsts, Z, R) def test_maxinconsts_one_cluster_linkage(self): # Tests maxinconsts(Z, R) on linkage with one cluster. Z = np.asarray([[0, 1, 0.3, 4]], dtype=np.double) R = np.asarray([[0, 0, 0, 0.3]], dtype=np.double) MD = maxinconsts(Z, R) expectedMD = calculate_maximum_inconsistencies(Z, R) assert_allclose(MD, expectedMD, atol=1e-15) def test_maxinconsts_Q_linkage(self): for method in ['single', 'complete', 'ward', 'centroid', 'median']: self.check_maxinconsts_Q_linkage(method) def check_maxinconsts_Q_linkage(self, method): # Tests maxinconsts(Z, R) on the Q data set X = hierarchy_test_data.Q_X Z = linkage(X, method) R = inconsistent(Z) MD = maxinconsts(Z, R) expectedMD = calculate_maximum_inconsistencies(Z, R) assert_allclose(MD, expectedMD, atol=1e-15) class TestMaxRStat(object): def test_maxRstat_invalid_index(self): for i in [3.3, -1, 4]: self.check_maxRstat_invalid_index(i) def check_maxRstat_invalid_index(self, i): # Tests maxRstat(Z, R, i). Expecting exception. Z = np.asarray([[0, 1, 0.3, 4]], dtype=np.double) R = np.asarray([[0, 0, 0, 0.3]], dtype=np.double) if isinstance(i, int): assert_raises(ValueError, maxRstat, Z, R, i) else: assert_raises(TypeError, maxRstat, Z, R, i) def test_maxRstat_empty_linkage(self): for i in range(4): self.check_maxRstat_empty_linkage(i) def check_maxRstat_empty_linkage(self, i): # Tests maxRstat(Z, R, i) on empty linkage. Expecting exception. Z = np.zeros((0, 4), dtype=np.double) R = np.zeros((0, 4), dtype=np.double) assert_raises(ValueError, maxRstat, Z, R, i) def test_maxRstat_difrow_linkage(self): for i in range(4): self.check_maxRstat_difrow_linkage(i) def check_maxRstat_difrow_linkage(self, i): # Tests maxRstat(Z, R, i) on linkage and inconsistency matrices with # different numbers of clusters. Expecting exception. Z = np.asarray([[0, 1, 0.3, 4]], dtype=np.double) R = np.random.rand(2, 4) assert_raises(ValueError, maxRstat, Z, R, i) def test_maxRstat_one_cluster_linkage(self): for i in range(4): self.check_maxRstat_one_cluster_linkage(i) def check_maxRstat_one_cluster_linkage(self, i): # Tests maxRstat(Z, R, i) on linkage with one cluster. Z = np.asarray([[0, 1, 0.3, 4]], dtype=np.double) R = np.asarray([[0, 0, 0, 0.3]], dtype=np.double) MD = maxRstat(Z, R, 1) expectedMD = calculate_maximum_inconsistencies(Z, R, 1) assert_allclose(MD, expectedMD, atol=1e-15) def test_maxRstat_Q_linkage(self): for method in ['single', 'complete', 'ward', 'centroid', 'median']: for i in range(4): self.check_maxRstat_Q_linkage(method, i) def check_maxRstat_Q_linkage(self, method, i): # Tests maxRstat(Z, R, i) on the Q data set X = hierarchy_test_data.Q_X Z = linkage(X, method) R = inconsistent(Z) MD = maxRstat(Z, R, 1) expectedMD = calculate_maximum_inconsistencies(Z, R, 1) assert_allclose(MD, expectedMD, atol=1e-15) class TestDendrogram(object): def test_dendrogram_single_linkage_tdist(self): # Tests dendrogram calculation on single linkage of the tdist data set. Z = linkage(hierarchy_test_data.ytdist, 'single') R = dendrogram(Z, no_plot=True) leaves = R["leaves"] assert_equal(leaves, [2, 5, 1, 0, 3, 4]) def test_valid_orientation(self): Z = linkage(hierarchy_test_data.ytdist, 'single') assert_raises(ValueError, dendrogram, Z, orientation="foo") def test_labels_as_array_or_list(self): # test for gh-12418 Z = linkage(hierarchy_test_data.ytdist, 'single') labels = np.array([1, 3, 2, 6, 4, 5]) result1 = dendrogram(Z, labels=labels, no_plot=True) result2 = dendrogram(Z, labels=labels.tolist(), no_plot=True) assert result1 == result2 @pytest.mark.skipif(not have_matplotlib, reason="no matplotlib") def test_valid_label_size(self): link = np.array([ [0, 1, 1.0, 4], [2, 3, 1.0, 5], [4, 5, 2.0, 6], ]) plt.figure() with pytest.raises(ValueError) as exc_info: dendrogram(link, labels=list(range(100))) assert "Dimensions of Z and labels must be consistent."\ in str(exc_info.value) with pytest.raises( ValueError, match="Dimensions of Z and labels must be consistent."): dendrogram(link, labels=[]) plt.close() @pytest.mark.skipif(not have_matplotlib, reason="no matplotlib") def test_dendrogram_plot(self): for orientation in ['top', 'bottom', 'left', 'right']: self.check_dendrogram_plot(orientation) def check_dendrogram_plot(self, orientation): # Tests dendrogram plotting. Z = linkage(hierarchy_test_data.ytdist, 'single') expected = {'color_list': ['C1', 'C0', 'C0', 'C0', 'C0'], 'dcoord': [[0.0, 138.0, 138.0, 0.0], [0.0, 219.0, 219.0, 0.0], [0.0, 255.0, 255.0, 219.0], [0.0, 268.0, 268.0, 255.0], [138.0, 295.0, 295.0, 268.0]], 'icoord': [[5.0, 5.0, 15.0, 15.0], [45.0, 45.0, 55.0, 55.0], [35.0, 35.0, 50.0, 50.0], [25.0, 25.0, 42.5, 42.5], [10.0, 10.0, 33.75, 33.75]], 'ivl': ['2', '5', '1', '0', '3', '4'], 'leaves': [2, 5, 1, 0, 3, 4], 'leaves_color_list': ['C1', 'C1', 'C0', 'C0', 'C0', 'C0'], } fig = plt.figure() ax = fig.add_subplot(221) # test that dendrogram accepts ax keyword R1 = dendrogram(Z, ax=ax, orientation=orientation) assert_equal(R1, expected) # test that dendrogram accepts and handle the leaf_font_size and # leaf_rotation keywords dendrogram(Z, ax=ax, orientation=orientation, leaf_font_size=20, leaf_rotation=90) testlabel = ( ax.get_xticklabels()[0] if orientation in ['top', 'bottom'] else ax.get_yticklabels()[0] ) assert_equal(testlabel.get_rotation(), 90) assert_equal(testlabel.get_size(), 20) dendrogram(Z, ax=ax, orientation=orientation, leaf_rotation=90) testlabel = ( ax.get_xticklabels()[0] if orientation in ['top', 'bottom'] else ax.get_yticklabels()[0] ) assert_equal(testlabel.get_rotation(), 90) dendrogram(Z, ax=ax, orientation=orientation, leaf_font_size=20) testlabel = ( ax.get_xticklabels()[0] if orientation in ['top', 'bottom'] else ax.get_yticklabels()[0] ) assert_equal(testlabel.get_size(), 20) plt.close() # test plotting to gca (will import pylab) R2 = dendrogram(Z, orientation=orientation) plt.close() assert_equal(R2, expected) @pytest.mark.skipif(not have_matplotlib, reason="no matplotlib") def test_dendrogram_truncate_mode(self): Z = linkage(hierarchy_test_data.ytdist, 'single') R = dendrogram(Z, 2, 'lastp', show_contracted=True) plt.close() assert_equal(R, {'color_list': ['C0'], 'dcoord': [[0.0, 295.0, 295.0, 0.0]], 'icoord': [[5.0, 5.0, 15.0, 15.0]], 'ivl': ['(2)', '(4)'], 'leaves': [6, 9], 'leaves_color_list': ['C0', 'C0'], }) R = dendrogram(Z, 2, 'mtica', show_contracted=True) plt.close() assert_equal(R, {'color_list': ['C1', 'C0', 'C0', 'C0'], 'dcoord': [[0.0, 138.0, 138.0, 0.0], [0.0, 255.0, 255.0, 0.0], [0.0, 268.0, 268.0, 255.0], [138.0, 295.0, 295.0, 268.0]], 'icoord': [[5.0, 5.0, 15.0, 15.0], [35.0, 35.0, 45.0, 45.0], [25.0, 25.0, 40.0, 40.0], [10.0, 10.0, 32.5, 32.5]], 'ivl': ['2', '5', '1', '0', '(2)'], 'leaves': [2, 5, 1, 0, 7], 'leaves_color_list': ['C1', 'C1', 'C0', 'C0', 'C0'], }) def test_dendrogram_colors(self): # Tests dendrogram plots with alternate colors Z = linkage(hierarchy_test_data.ytdist, 'single') set_link_color_palette(['c', 'm', 'y', 'k']) R = dendrogram(Z, no_plot=True, above_threshold_color='g', color_threshold=250) set_link_color_palette(['g', 'r', 'c', 'm', 'y', 'k']) color_list = R['color_list'] assert_equal(color_list, ['c', 'm', 'g', 'g', 'g']) # reset color palette (global list) set_link_color_palette(None) def calculate_maximum_distances(Z): # Used for testing correctness of maxdists. n = Z.shape[0] + 1 B = np.zeros((n-1,)) q = np.zeros((3,)) for i in range(0, n - 1): q[:] = 0.0 left = Z[i, 0] right = Z[i, 1] if left >= n: q[0] = B[int(left) - n] if right >= n: q[1] = B[int(right) - n] q[2] = Z[i, 2] B[i] = q.max() return B def calculate_maximum_inconsistencies(Z, R, k=3): # Used for testing correctness of maxinconsts. n = Z.shape[0] + 1 B = np.zeros((n-1,)) q = np.zeros((3,)) for i in range(0, n - 1): q[:] = 0.0 left = Z[i, 0] right = Z[i, 1] if left >= n: q[0] = B[int(left) - n] if right >= n: q[1] = B[int(right) - n] q[2] = R[i, k] B[i] = q.max() return B def within_tol(a, b, tol): return np.abs(a - b).max() < tol def test_unsupported_uncondensed_distance_matrix_linkage_warning(): assert_warns(ClusterWarning, linkage, [[0, 1], [1, 0]]) def test_euclidean_linkage_value_error(): for method in scipy.cluster.hierarchy._EUCLIDEAN_METHODS: assert_raises(ValueError, linkage, [[1, 1], [1, 1]], method=method, metric='cityblock') def test_2x2_linkage(): Z1 = linkage([1], method='single', metric='euclidean') Z2 = linkage([[0, 1], [0, 0]], method='single', metric='euclidean') assert_allclose(Z1, Z2) def test_node_compare(): np.random.seed(23) nobs = 50 X = np.random.randn(nobs, 4) Z = scipy.cluster.hierarchy.ward(X) tree = to_tree(Z) assert_(tree > tree.get_left()) assert_(tree.get_right() > tree.get_left()) assert_(tree.get_right() == tree.get_right()) assert_(tree.get_right() != tree.get_left()) def test_cut_tree(): np.random.seed(23) nobs = 50 X = np.random.randn(nobs, 4) Z = scipy.cluster.hierarchy.ward(X) cutree = cut_tree(Z) assert_equal(cutree[:, 0], np.arange(nobs)) assert_equal(cutree[:, -1], np.zeros(nobs)) assert_equal(cutree.max(0), np.arange(nobs - 1, -1, -1)) assert_equal(cutree[:, [-5]], cut_tree(Z, n_clusters=5)) assert_equal(cutree[:, [-5, -10]], cut_tree(Z, n_clusters=[5, 10])) assert_equal(cutree[:, [-10, -5]], cut_tree(Z, n_clusters=[10, 5])) nodes = _order_cluster_tree(Z) heights = np.array([node.dist for node in nodes]) assert_equal(cutree[:, np.searchsorted(heights, [5])], cut_tree(Z, height=5)) assert_equal(cutree[:, np.searchsorted(heights, [5, 10])], cut_tree(Z, height=[5, 10])) assert_equal(cutree[:, np.searchsorted(heights, [10, 5])], cut_tree(Z, height=[10, 5])) def test_optimal_leaf_ordering(): # test with the distance vector y Z = optimal_leaf_ordering(linkage(hierarchy_test_data.ytdist), hierarchy_test_data.ytdist) expectedZ = hierarchy_test_data.linkage_ytdist_single_olo assert_allclose(Z, expectedZ, atol=1e-10) # test with the observation matrix X Z = optimal_leaf_ordering(linkage(hierarchy_test_data.X, 'ward'), hierarchy_test_data.X) expectedZ = hierarchy_test_data.linkage_X_ward_olo assert_allclose(Z, expectedZ, atol=1e-06) def test_Heap(): values = np.array([2, -1, 0, -1.5, 3]) heap = Heap(values) pair = heap.get_min() assert_equal(pair['key'], 3) assert_equal(pair['value'], -1.5) heap.remove_min() pair = heap.get_min() assert_equal(pair['key'], 1) assert_equal(pair['value'], -1) heap.change_value(1, 2.5) pair = heap.get_min() assert_equal(pair['key'], 2) assert_equal(pair['value'], 0) heap.remove_min() heap.remove_min() heap.change_value(1, 10) pair = heap.get_min() assert_equal(pair['key'], 4) assert_equal(pair['value'], 3) heap.remove_min() pair = heap.get_min() assert_equal(pair['key'], 1) assert_equal(pair['value'], 10)