projektAI/venv/Lib/site-packages/sklearn/cluster/tests/test_birch.py

"""
Tests for the birch clustering algorithm.
"""

from scipy import sparse
import numpy as np
import pytest

from sklearn.cluster.tests.common import generate_clustered_data
from sklearn.cluster import Birch
from sklearn.cluster import AgglomerativeClustering
from sklearn.datasets import make_blobs
from sklearn.exceptions import ConvergenceWarning
from sklearn.linear_model import ElasticNet
from sklearn.metrics import pairwise_distances_argmin, v_measure_score

from sklearn.utils._testing import assert_almost_equal
from sklearn.utils._testing import assert_array_equal
from sklearn.utils._testing import assert_array_almost_equal
from sklearn.utils._testing import assert_warns


def test_n_samples_leaves_roots():
    # Sanity check for the number of samples in leaves and roots
    X, y = make_blobs(n_samples=10)
    brc = Birch()
    brc.fit(X)
    n_samples_root = sum([sc.n_samples_ for sc in brc.root_.subclusters_])
    n_samples_leaves = sum([sc.n_samples_ for leaf in brc._get_leaves()
                            for sc in leaf.subclusters_])
    assert n_samples_leaves == X.shape[0]
    assert n_samples_root == X.shape[0]


def test_partial_fit():
    # Test that fit is equivalent to calling partial_fit multiple times
    X, y = make_blobs(n_samples=100)
    brc = Birch(n_clusters=3)
    brc.fit(X)
    brc_partial = Birch(n_clusters=None)
    brc_partial.partial_fit(X[:50])
    brc_partial.partial_fit(X[50:])
    assert_array_almost_equal(brc_partial.subcluster_centers_,
                              brc.subcluster_centers_)

    # Test that same global labels are obtained after calling partial_fit
    # with None
    brc_partial.set_params(n_clusters=3)
    brc_partial.partial_fit(None)
    assert_array_equal(brc_partial.subcluster_labels_, brc.subcluster_labels_)


def test_birch_predict():
    # Test the predict method predicts the nearest centroid.
    rng = np.random.RandomState(0)
    X = generate_clustered_data(n_clusters=3, n_features=3,
                                n_samples_per_cluster=10)

    # n_samples * n_samples_per_cluster
    shuffle_indices = np.arange(30)
    rng.shuffle(shuffle_indices)
    X_shuffle = X[shuffle_indices, :]
    brc = Birch(n_clusters=4, threshold=1.)
    brc.fit(X_shuffle)
    centroids = brc.subcluster_centers_
    assert_array_equal(brc.labels_, brc.predict(X_shuffle))
    nearest_centroid = pairwise_distances_argmin(X_shuffle, centroids)
    assert_almost_equal(v_measure_score(nearest_centroid, brc.labels_), 1.0)


def test_n_clusters():
    # Test that n_clusters param works properly
    X, y = make_blobs(n_samples=100, centers=10)
    brc1 = Birch(n_clusters=10)
    brc1.fit(X)
    assert len(brc1.subcluster_centers_) > 10
    assert len(np.unique(brc1.labels_)) == 10

    # Test that n_clusters = Agglomerative Clustering gives
    # the same results.
    gc = AgglomerativeClustering(n_clusters=10)
    brc2 = Birch(n_clusters=gc)
    brc2.fit(X)
    assert_array_equal(brc1.subcluster_labels_, brc2.subcluster_labels_)
    assert_array_equal(brc1.labels_, brc2.labels_)

    # Test that the wrong global clustering step raises an Error.
    clf = ElasticNet()
    brc3 = Birch(n_clusters=clf)
    with pytest.raises(ValueError):
        brc3.fit(X)

    # Test that a small number of clusters raises a warning.
    brc4 = Birch(threshold=10000.)
    assert_warns(ConvergenceWarning, brc4.fit, X)


def test_sparse_X():
    # Test that sparse and dense data give same results
    X, y = make_blobs(n_samples=100, centers=10)
    brc = Birch(n_clusters=10)
    brc.fit(X)

    csr = sparse.csr_matrix(X)
    brc_sparse = Birch(n_clusters=10)
    brc_sparse.fit(csr)

    assert_array_equal(brc.labels_, brc_sparse.labels_)
    assert_array_almost_equal(brc.subcluster_centers_,
                              brc_sparse.subcluster_centers_)


def test_partial_fit_second_call_error_checks():
    # second partial fit calls will error when n_features is not consistent
    # with the first call
    X, y = make_blobs(n_samples=100)
    brc = Birch(n_clusters=3)
    brc.partial_fit(X, y)

    msg = "X has 1 features, but Birch is expecting 2 features"
    with pytest.raises(ValueError, match=msg):
        brc.partial_fit(X[:, [0]], y)


def check_branching_factor(node, branching_factor):
    subclusters = node.subclusters_
    assert branching_factor >= len(subclusters)
    for cluster in subclusters:
        if cluster.child_:
            check_branching_factor(cluster.child_, branching_factor)


def test_branching_factor():
    # Test that nodes have at max branching_factor number of subclusters
    X, y = make_blobs()
    branching_factor = 9

    # Purposefully set a low threshold to maximize the subclusters.
    brc = Birch(n_clusters=None, branching_factor=branching_factor,
                threshold=0.01)
    brc.fit(X)
    check_branching_factor(brc.root_, branching_factor)
    brc = Birch(n_clusters=3, branching_factor=branching_factor,
                threshold=0.01)
    brc.fit(X)
    check_branching_factor(brc.root_, branching_factor)

    # Raises error when branching_factor is set to one.
    brc = Birch(n_clusters=None, branching_factor=1, threshold=0.01)
    with pytest.raises(ValueError):
        brc.fit(X)


def check_threshold(birch_instance, threshold):
    """Use the leaf linked list for traversal"""
    current_leaf = birch_instance.dummy_leaf_.next_leaf_
    while current_leaf:
        subclusters = current_leaf.subclusters_
        for sc in subclusters:
            assert threshold >= sc.radius
        current_leaf = current_leaf.next_leaf_


def test_threshold():
    # Test that the leaf subclusters have a threshold lesser than radius
    X, y = make_blobs(n_samples=80, centers=4)
    brc = Birch(threshold=0.5, n_clusters=None)
    brc.fit(X)
    check_threshold(brc, 0.5)

    brc = Birch(threshold=5.0, n_clusters=None)
    brc.fit(X)
    check_threshold(brc, 5.)


def test_birch_n_clusters_long_int():
    # Check that birch supports n_clusters with np.int64 dtype, for instance
    # coming from np.arange. #16484
    X, _ = make_blobs(random_state=0)
    n_clusters = np.int64(5)
    Birch(n_clusters=n_clusters).fit(X)
Działa 2021-06-06 22:13:05 +02:00			`"""`
			`Tests for the birch clustering algorithm.`
			`"""`

			`from scipy import sparse`
			`import numpy as np`
			`import pytest`

			`from sklearn.cluster.tests.common import generate_clustered_data`
			`from sklearn.cluster import Birch`
			`from sklearn.cluster import AgglomerativeClustering`
			`from sklearn.datasets import make_blobs`
			`from sklearn.exceptions import ConvergenceWarning`
			`from sklearn.linear_model import ElasticNet`
			`from sklearn.metrics import pairwise_distances_argmin, v_measure_score`

			`from sklearn.utils._testing import assert_almost_equal`
			`from sklearn.utils._testing import assert_array_equal`
			`from sklearn.utils._testing import assert_array_almost_equal`
			`from sklearn.utils._testing import assert_warns`


			`def test_n_samples_leaves_roots():`
			`# Sanity check for the number of samples in leaves and roots`
			`X, y = make_blobs(n_samples=10)`
			`brc = Birch()`
			`brc.fit(X)`
			`n_samples_root = sum([sc.n_samples_ for sc in brc.root_.subclusters_])`
			`n_samples_leaves = sum([sc.n_samples_ for leaf in brc._get_leaves()`
			`for sc in leaf.subclusters_])`
			`assert n_samples_leaves == X.shape[0]`
			`assert n_samples_root == X.shape[0]`


			`def test_partial_fit():`
			`# Test that fit is equivalent to calling partial_fit multiple times`
			`X, y = make_blobs(n_samples=100)`
			`brc = Birch(n_clusters=3)`
			`brc.fit(X)`
			`brc_partial = Birch(n_clusters=None)`
			`brc_partial.partial_fit(X[:50])`
			`brc_partial.partial_fit(X[50:])`
			`assert_array_almost_equal(brc_partial.subcluster_centers_,`
			`brc.subcluster_centers_)`

			`# Test that same global labels are obtained after calling partial_fit`
			`# with None`
			`brc_partial.set_params(n_clusters=3)`
			`brc_partial.partial_fit(None)`
			`assert_array_equal(brc_partial.subcluster_labels_, brc.subcluster_labels_)`


			`def test_birch_predict():`
			`# Test the predict method predicts the nearest centroid.`
			`rng = np.random.RandomState(0)`
			`X = generate_clustered_data(n_clusters=3, n_features=3,`
			`n_samples_per_cluster=10)`

			`# n_samples * n_samples_per_cluster`
			`shuffle_indices = np.arange(30)`
			`rng.shuffle(shuffle_indices)`
			`X_shuffle = X[shuffle_indices, :]`
			`brc = Birch(n_clusters=4, threshold=1.)`
			`brc.fit(X_shuffle)`
			`centroids = brc.subcluster_centers_`
			`assert_array_equal(brc.labels_, brc.predict(X_shuffle))`
			`nearest_centroid = pairwise_distances_argmin(X_shuffle, centroids)`
			`assert_almost_equal(v_measure_score(nearest_centroid, brc.labels_), 1.0)`


			`def test_n_clusters():`
			`# Test that n_clusters param works properly`
			`X, y = make_blobs(n_samples=100, centers=10)`
			`brc1 = Birch(n_clusters=10)`
			`brc1.fit(X)`
			`assert len(brc1.subcluster_centers_) > 10`
			`assert len(np.unique(brc1.labels_)) == 10`

			`# Test that n_clusters = Agglomerative Clustering gives`
			`# the same results.`
			`gc = AgglomerativeClustering(n_clusters=10)`
			`brc2 = Birch(n_clusters=gc)`
			`brc2.fit(X)`
			`assert_array_equal(brc1.subcluster_labels_, brc2.subcluster_labels_)`
			`assert_array_equal(brc1.labels_, brc2.labels_)`

			`# Test that the wrong global clustering step raises an Error.`
			`clf = ElasticNet()`
			`brc3 = Birch(n_clusters=clf)`
			`with pytest.raises(ValueError):`
			`brc3.fit(X)`

			`# Test that a small number of clusters raises a warning.`
			`brc4 = Birch(threshold=10000.)`
			`assert_warns(ConvergenceWarning, brc4.fit, X)`


			`def test_sparse_X():`
			`# Test that sparse and dense data give same results`
			`X, y = make_blobs(n_samples=100, centers=10)`
			`brc = Birch(n_clusters=10)`
			`brc.fit(X)`

			`csr = sparse.csr_matrix(X)`
			`brc_sparse = Birch(n_clusters=10)`
			`brc_sparse.fit(csr)`

			`assert_array_equal(brc.labels_, brc_sparse.labels_)`
			`assert_array_almost_equal(brc.subcluster_centers_,`
			`brc_sparse.subcluster_centers_)`


			`def test_partial_fit_second_call_error_checks():`
			`# second partial fit calls will error when n_features is not consistent`
			`# with the first call`
			`X, y = make_blobs(n_samples=100)`
			`brc = Birch(n_clusters=3)`
			`brc.partial_fit(X, y)`

			`msg = "X has 1 features, but Birch is expecting 2 features"`
			`with pytest.raises(ValueError, match=msg):`
			`brc.partial_fit(X[:, [0]], y)`


			`def check_branching_factor(node, branching_factor):`
			`subclusters = node.subclusters_`
			`assert branching_factor >= len(subclusters)`
			`for cluster in subclusters:`
			`if cluster.child_:`
			`check_branching_factor(cluster.child_, branching_factor)`


			`def test_branching_factor():`
			`# Test that nodes have at max branching_factor number of subclusters`
			`X, y = make_blobs()`
			`branching_factor = 9`

			`# Purposefully set a low threshold to maximize the subclusters.`
			`brc = Birch(n_clusters=None, branching_factor=branching_factor,`
			`threshold=0.01)`
			`brc.fit(X)`
			`check_branching_factor(brc.root_, branching_factor)`
			`brc = Birch(n_clusters=3, branching_factor=branching_factor,`
			`threshold=0.01)`
			`brc.fit(X)`
			`check_branching_factor(brc.root_, branching_factor)`

			`# Raises error when branching_factor is set to one.`
			`brc = Birch(n_clusters=None, branching_factor=1, threshold=0.01)`
			`with pytest.raises(ValueError):`
			`brc.fit(X)`


			`def check_threshold(birch_instance, threshold):`
			`"""Use the leaf linked list for traversal"""`
			`current_leaf = birch_instance.dummy_leaf_.next_leaf_`
			`while current_leaf:`
			`subclusters = current_leaf.subclusters_`
			`for sc in subclusters:`
			`assert threshold >= sc.radius`
			`current_leaf = current_leaf.next_leaf_`


			`def test_threshold():`
			`# Test that the leaf subclusters have a threshold lesser than radius`
			`X, y = make_blobs(n_samples=80, centers=4)`
			`brc = Birch(threshold=0.5, n_clusters=None)`
			`brc.fit(X)`
			`check_threshold(brc, 0.5)`

			`brc = Birch(threshold=5.0, n_clusters=None)`
			`brc.fit(X)`
			`check_threshold(brc, 5.)`


			`def test_birch_n_clusters_long_int():`
			`# Check that birch supports n_clusters with np.int64 dtype, for instance`
			`# coming from np.arange. #16484`
			`X, _ = make_blobs(random_state=0)`
			`n_clusters = np.int64(5)`
			`Birch(n_clusters=n_clusters).fit(X)`