264 lines
9.2 KiB
Python
264 lines
9.2 KiB
Python
"""Testing for Spectral Biclustering methods"""
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import numpy as np
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from scipy.sparse import csr_matrix, issparse
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from sklearn.model_selection import ParameterGrid
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from sklearn.utils.testing import assert_equal
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from sklearn.utils.testing import assert_almost_equal
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from sklearn.utils.testing import assert_array_equal
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from sklearn.utils.testing import assert_array_almost_equal
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from sklearn.utils.testing import assert_raises
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from sklearn.utils.testing import assert_true
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from sklearn.utils.testing import SkipTest
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from sklearn.base import BaseEstimator, BiclusterMixin
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from sklearn.cluster.bicluster import SpectralCoclustering
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from sklearn.cluster.bicluster import SpectralBiclustering
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from sklearn.cluster.bicluster import _scale_normalize
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from sklearn.cluster.bicluster import _bistochastic_normalize
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from sklearn.cluster.bicluster import _log_normalize
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from sklearn.metrics import consensus_score
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from sklearn.datasets import make_biclusters, make_checkerboard
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class MockBiclustering(BaseEstimator, BiclusterMixin):
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# Mock object for testing get_submatrix.
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def __init__(self):
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pass
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def get_indices(self, i):
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# Overridden to reproduce old get_submatrix test.
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return (np.where([True, True, False, False, True])[0],
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np.where([False, False, True, True])[0])
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def test_get_submatrix():
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data = np.arange(20).reshape(5, 4)
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model = MockBiclustering()
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for X in (data, csr_matrix(data), data.tolist()):
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submatrix = model.get_submatrix(0, X)
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if issparse(submatrix):
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submatrix = submatrix.toarray()
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assert_array_equal(submatrix, [[2, 3],
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[6, 7],
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[18, 19]])
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submatrix[:] = -1
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if issparse(X):
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X = X.toarray()
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assert_true(np.all(X != -1))
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def _test_shape_indices(model):
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# Test get_shape and get_indices on fitted model.
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for i in range(model.n_clusters):
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m, n = model.get_shape(i)
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i_ind, j_ind = model.get_indices(i)
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assert_equal(len(i_ind), m)
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assert_equal(len(j_ind), n)
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def test_spectral_coclustering():
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# Test Dhillon's Spectral CoClustering on a simple problem.
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param_grid = {'svd_method': ['randomized', 'arpack'],
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'n_svd_vecs': [None, 20],
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'mini_batch': [False, True],
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'init': ['k-means++'],
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'n_init': [10],
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'n_jobs': [1]}
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random_state = 0
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S, rows, cols = make_biclusters((30, 30), 3, noise=0.5,
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random_state=random_state)
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S -= S.min() # needs to be nonnegative before making it sparse
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S = np.where(S < 1, 0, S) # threshold some values
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for mat in (S, csr_matrix(S)):
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for kwargs in ParameterGrid(param_grid):
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model = SpectralCoclustering(n_clusters=3,
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random_state=random_state,
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**kwargs)
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model.fit(mat)
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assert_equal(model.rows_.shape, (3, 30))
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assert_array_equal(model.rows_.sum(axis=0), np.ones(30))
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assert_array_equal(model.columns_.sum(axis=0), np.ones(30))
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assert_equal(consensus_score(model.biclusters_,
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(rows, cols)), 1)
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_test_shape_indices(model)
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def test_spectral_biclustering():
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# Test Kluger methods on a checkerboard dataset.
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S, rows, cols = make_checkerboard((30, 30), 3, noise=0.5,
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random_state=0)
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non_default_params = {'method': ['scale', 'log'],
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'svd_method': ['arpack'],
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'n_svd_vecs': [20],
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'mini_batch': [True]}
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for mat in (S, csr_matrix(S)):
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for param_name, param_values in non_default_params.items():
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for param_value in param_values:
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model = SpectralBiclustering(
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n_clusters=3,
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n_init=3,
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init='k-means++',
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random_state=0,
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)
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model.set_params(**dict([(param_name, param_value)]))
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if issparse(mat) and model.get_params().get('method') == 'log':
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# cannot take log of sparse matrix
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assert_raises(ValueError, model.fit, mat)
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continue
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else:
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model.fit(mat)
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assert_equal(model.rows_.shape, (9, 30))
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assert_equal(model.columns_.shape, (9, 30))
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assert_array_equal(model.rows_.sum(axis=0),
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np.repeat(3, 30))
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assert_array_equal(model.columns_.sum(axis=0),
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np.repeat(3, 30))
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assert_equal(consensus_score(model.biclusters_,
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(rows, cols)), 1)
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_test_shape_indices(model)
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def _do_scale_test(scaled):
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"""Check that rows sum to one constant, and columns to another."""
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row_sum = scaled.sum(axis=1)
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col_sum = scaled.sum(axis=0)
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if issparse(scaled):
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row_sum = np.asarray(row_sum).squeeze()
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col_sum = np.asarray(col_sum).squeeze()
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assert_array_almost_equal(row_sum, np.tile(row_sum.mean(), 100),
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decimal=1)
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assert_array_almost_equal(col_sum, np.tile(col_sum.mean(), 100),
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decimal=1)
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def _do_bistochastic_test(scaled):
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"""Check that rows and columns sum to the same constant."""
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_do_scale_test(scaled)
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assert_almost_equal(scaled.sum(axis=0).mean(),
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scaled.sum(axis=1).mean(),
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decimal=1)
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def test_scale_normalize():
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generator = np.random.RandomState(0)
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X = generator.rand(100, 100)
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for mat in (X, csr_matrix(X)):
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scaled, _, _ = _scale_normalize(mat)
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_do_scale_test(scaled)
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if issparse(mat):
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assert issparse(scaled)
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def test_bistochastic_normalize():
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generator = np.random.RandomState(0)
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X = generator.rand(100, 100)
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for mat in (X, csr_matrix(X)):
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scaled = _bistochastic_normalize(mat)
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_do_bistochastic_test(scaled)
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if issparse(mat):
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assert issparse(scaled)
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def test_log_normalize():
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# adding any constant to a log-scaled matrix should make it
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# bistochastic
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generator = np.random.RandomState(0)
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mat = generator.rand(100, 100)
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scaled = _log_normalize(mat) + 1
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_do_bistochastic_test(scaled)
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def test_fit_best_piecewise():
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model = SpectralBiclustering(random_state=0)
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vectors = np.array([[0, 0, 0, 1, 1, 1],
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[2, 2, 2, 3, 3, 3],
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[0, 1, 2, 3, 4, 5]])
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best = model._fit_best_piecewise(vectors, n_best=2, n_clusters=2)
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assert_array_equal(best, vectors[:2])
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def test_project_and_cluster():
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model = SpectralBiclustering(random_state=0)
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data = np.array([[1, 1, 1],
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[1, 1, 1],
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[3, 6, 3],
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[3, 6, 3]])
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vectors = np.array([[1, 0],
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[0, 1],
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[0, 0]])
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for mat in (data, csr_matrix(data)):
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labels = model._project_and_cluster(data, vectors,
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n_clusters=2)
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assert_array_equal(labels, [0, 0, 1, 1])
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def test_perfect_checkerboard():
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raise SkipTest("This test is failing on the buildbot, but cannot"
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" reproduce. Temporarily disabling it until it can be"
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" reproduced and fixed.")
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model = SpectralBiclustering(3, svd_method="arpack", random_state=0)
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S, rows, cols = make_checkerboard((30, 30), 3, noise=0,
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random_state=0)
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model.fit(S)
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assert_equal(consensus_score(model.biclusters_,
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(rows, cols)), 1)
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S, rows, cols = make_checkerboard((40, 30), 3, noise=0,
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random_state=0)
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model.fit(S)
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assert_equal(consensus_score(model.biclusters_,
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(rows, cols)), 1)
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S, rows, cols = make_checkerboard((30, 40), 3, noise=0,
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random_state=0)
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model.fit(S)
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assert_equal(consensus_score(model.biclusters_,
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(rows, cols)), 1)
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def test_errors():
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data = np.arange(25).reshape((5, 5))
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model = SpectralBiclustering(n_clusters=(3, 3, 3))
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assert_raises(ValueError, model.fit, data)
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model = SpectralBiclustering(n_clusters='abc')
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assert_raises(ValueError, model.fit, data)
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model = SpectralBiclustering(n_clusters=(3, 'abc'))
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assert_raises(ValueError, model.fit, data)
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model = SpectralBiclustering(method='unknown')
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assert_raises(ValueError, model.fit, data)
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model = SpectralBiclustering(svd_method='unknown')
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assert_raises(ValueError, model.fit, data)
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model = SpectralBiclustering(n_components=0)
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assert_raises(ValueError, model.fit, data)
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model = SpectralBiclustering(n_best=0)
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assert_raises(ValueError, model.fit, data)
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model = SpectralBiclustering(n_components=3, n_best=4)
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assert_raises(ValueError, model.fit, data)
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model = SpectralBiclustering()
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data = np.arange(27).reshape((3, 3, 3))
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assert_raises(ValueError, model.fit, data)
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