# -*- coding: utf-8 -*- """Ordering Points To Identify the Clustering Structure (OPTICS) These routines execute the OPTICS algorithm, and implement various cluster extraction methods of the ordered list. Authors: Shane Grigsby Adrin Jalali Erich Schubert Hanmin Qin License: BSD 3 clause """ import warnings import numpy as np from ..utils import gen_batches, get_chunk_n_rows from ..utils.validation import _deprecate_positional_args from ..neighbors import NearestNeighbors from ..base import BaseEstimator, ClusterMixin from ..metrics import pairwise_distances class OPTICS(ClusterMixin, BaseEstimator): """Estimate clustering structure from vector array. OPTICS (Ordering Points To Identify the Clustering Structure), closely related to DBSCAN, finds core sample of high density and expands clusters from them [1]_. Unlike DBSCAN, keeps cluster hierarchy for a variable neighborhood radius. Better suited for usage on large datasets than the current sklearn implementation of DBSCAN. Clusters are then extracted using a DBSCAN-like method (cluster_method = 'dbscan') or an automatic technique proposed in [1]_ (cluster_method = 'xi'). This implementation deviates from the original OPTICS by first performing k-nearest-neighborhood searches on all points to identify core sizes, then computing only the distances to unprocessed points when constructing the cluster order. Note that we do not employ a heap to manage the expansion candidates, so the time complexity will be O(n^2). Read more in the :ref:`User Guide `. Parameters ---------- min_samples : int > 1 or float between 0 and 1 (default=5) The number of samples in a neighborhood for a point to be considered as a core point. Also, up and down steep regions can't have more then ``min_samples`` consecutive non-steep points. Expressed as an absolute number or a fraction of the number of samples (rounded to be at least 2). max_eps : float, optional (default=np.inf) The maximum distance between two samples for one to be considered as in the neighborhood of the other. Default value of ``np.inf`` will identify clusters across all scales; reducing ``max_eps`` will result in shorter run times. metric : str or callable, optional (default='minkowski') Metric to use for distance computation. Any metric from scikit-learn or scipy.spatial.distance can be used. If metric is a callable function, it is called on each pair of instances (rows) and the resulting value recorded. The callable should take two arrays as input and return one value indicating the distance between them. This works for Scipy's metrics, but is less efficient than passing the metric name as a string. If metric is "precomputed", X is assumed to be a distance matrix and must be square. Valid values for metric are: - from scikit-learn: ['cityblock', 'cosine', 'euclidean', 'l1', 'l2', 'manhattan'] - from scipy.spatial.distance: ['braycurtis', 'canberra', 'chebyshev', 'correlation', 'dice', 'hamming', 'jaccard', 'kulsinski', 'mahalanobis', 'minkowski', 'rogerstanimoto', 'russellrao', 'seuclidean', 'sokalmichener', 'sokalsneath', 'sqeuclidean', 'yule'] See the documentation for scipy.spatial.distance for details on these metrics. p : int, optional (default=2) Parameter for the Minkowski metric from :class:`sklearn.metrics.pairwise_distances`. When p = 1, this is equivalent to using manhattan_distance (l1), and euclidean_distance (l2) for p = 2. For arbitrary p, minkowski_distance (l_p) is used. metric_params : dict, optional (default=None) Additional keyword arguments for the metric function. cluster_method : str, optional (default='xi') The extraction method used to extract clusters using the calculated reachability and ordering. Possible values are "xi" and "dbscan". eps : float, optional (default=None) The maximum distance between two samples for one to be considered as in the neighborhood of the other. By default it assumes the same value as ``max_eps``. Used only when ``cluster_method='dbscan'``. xi : float, between 0 and 1, optional (default=0.05) Determines the minimum steepness on the reachability plot that constitutes a cluster boundary. For example, an upwards point in the reachability plot is defined by the ratio from one point to its successor being at most 1-xi. Used only when ``cluster_method='xi'``. predecessor_correction : bool, optional (default=True) Correct clusters according to the predecessors calculated by OPTICS [2]_. This parameter has minimal effect on most datasets. Used only when ``cluster_method='xi'``. min_cluster_size : int > 1 or float between 0 and 1 (default=None) Minimum number of samples in an OPTICS cluster, expressed as an absolute number or a fraction of the number of samples (rounded to be at least 2). If ``None``, the value of ``min_samples`` is used instead. Used only when ``cluster_method='xi'``. algorithm : {'auto', 'ball_tree', 'kd_tree', 'brute'}, optional Algorithm used to compute the nearest neighbors: - 'ball_tree' will use :class:`BallTree` - 'kd_tree' will use :class:`KDTree` - 'brute' will use a brute-force search. - 'auto' will attempt to decide the most appropriate algorithm based on the values passed to :meth:`fit` method. (default) Note: fitting on sparse input will override the setting of this parameter, using brute force. leaf_size : int, optional (default=30) Leaf size passed to :class:`BallTree` or :class:`KDTree`. This can affect the speed of the construction and query, as well as the memory required to store the tree. The optimal value depends on the nature of the problem. n_jobs : int or None, optional (default=None) The number of parallel jobs to run for neighbors search. ``None`` means 1 unless in a :obj:`joblib.parallel_backend` context. ``-1`` means using all processors. See :term:`Glossary ` for more details. Attributes ---------- labels_ : array, shape (n_samples,) Cluster labels for each point in the dataset given to fit(). Noisy samples and points which are not included in a leaf cluster of ``cluster_hierarchy_`` are labeled as -1. reachability_ : array, shape (n_samples,) Reachability distances per sample, indexed by object order. Use ``clust.reachability_[clust.ordering_]`` to access in cluster order. ordering_ : array, shape (n_samples,) The cluster ordered list of sample indices. core_distances_ : array, shape (n_samples,) Distance at which each sample becomes a core point, indexed by object order. Points which will never be core have a distance of inf. Use ``clust.core_distances_[clust.ordering_]`` to access in cluster order. predecessor_ : array, shape (n_samples,) Point that a sample was reached from, indexed by object order. Seed points have a predecessor of -1. cluster_hierarchy_ : array, shape (n_clusters, 2) The list of clusters in the form of ``[start, end]`` in each row, with all indices inclusive. The clusters are ordered according to ``(end, -start)`` (ascending) so that larger clusters encompassing smaller clusters come after those smaller ones. Since ``labels_`` does not reflect the hierarchy, usually ``len(cluster_hierarchy_) > np.unique(optics.labels_)``. Please also note that these indices are of the ``ordering_``, i.e. ``X[ordering_][start:end + 1]`` form a cluster. Only available when ``cluster_method='xi'``. See Also -------- DBSCAN A similar clustering for a specified neighborhood radius (eps). Our implementation is optimized for runtime. References ---------- .. [1] Ankerst, Mihael, Markus M. Breunig, Hans-Peter Kriegel, and Jörg Sander. "OPTICS: ordering points to identify the clustering structure." ACM SIGMOD Record 28, no. 2 (1999): 49-60. .. [2] Schubert, Erich, Michael Gertz. "Improving the Cluster Structure Extracted from OPTICS Plots." Proc. of the Conference "Lernen, Wissen, Daten, Analysen" (LWDA) (2018): 318-329. Examples -------- >>> from sklearn.cluster import OPTICS >>> import numpy as np >>> X = np.array([[1, 2], [2, 5], [3, 6], ... [8, 7], [8, 8], [7, 3]]) >>> clustering = OPTICS(min_samples=2).fit(X) >>> clustering.labels_ array([0, 0, 0, 1, 1, 1]) """ @_deprecate_positional_args def __init__(self, *, min_samples=5, max_eps=np.inf, metric='minkowski', p=2, metric_params=None, cluster_method='xi', eps=None, xi=0.05, predecessor_correction=True, min_cluster_size=None, algorithm='auto', leaf_size=30, n_jobs=None): self.max_eps = max_eps self.min_samples = min_samples self.min_cluster_size = min_cluster_size self.algorithm = algorithm self.metric = metric self.metric_params = metric_params self.p = p self.leaf_size = leaf_size self.cluster_method = cluster_method self.eps = eps self.xi = xi self.predecessor_correction = predecessor_correction self.n_jobs = n_jobs def fit(self, X, y=None): """Perform OPTICS clustering. Extracts an ordered list of points and reachability distances, and performs initial clustering using ``max_eps`` distance specified at OPTICS object instantiation. Parameters ---------- X : array, shape (n_samples, n_features), or (n_samples, n_samples) \ if metric=’precomputed’ A feature array, or array of distances between samples if metric='precomputed'. y : ignored Ignored. Returns ------- self : instance of OPTICS The instance. """ X = self._validate_data(X, dtype=np.float) if self.cluster_method not in ['dbscan', 'xi']: raise ValueError("cluster_method should be one of" " 'dbscan' or 'xi' but is %s" % self.cluster_method) (self.ordering_, self.core_distances_, self.reachability_, self.predecessor_) = compute_optics_graph( X=X, min_samples=self.min_samples, algorithm=self.algorithm, leaf_size=self.leaf_size, metric=self.metric, metric_params=self.metric_params, p=self.p, n_jobs=self.n_jobs, max_eps=self.max_eps) # Extract clusters from the calculated orders and reachability if self.cluster_method == 'xi': labels_, clusters_ = cluster_optics_xi( reachability=self.reachability_, predecessor=self.predecessor_, ordering=self.ordering_, min_samples=self.min_samples, min_cluster_size=self.min_cluster_size, xi=self.xi, predecessor_correction=self.predecessor_correction) self.cluster_hierarchy_ = clusters_ elif self.cluster_method == 'dbscan': if self.eps is None: eps = self.max_eps else: eps = self.eps if eps > self.max_eps: raise ValueError('Specify an epsilon smaller than %s. Got %s.' % (self.max_eps, eps)) labels_ = cluster_optics_dbscan( reachability=self.reachability_, core_distances=self.core_distances_, ordering=self.ordering_, eps=eps) self.labels_ = labels_ return self def _validate_size(size, n_samples, param_name): if size <= 0 or (size != int(size) and size > 1): raise ValueError('%s must be a positive integer ' 'or a float between 0 and 1. Got %r' % (param_name, size)) elif size > n_samples: raise ValueError('%s must be no greater than the' ' number of samples (%d). Got %d' % (param_name, n_samples, size)) # OPTICS helper functions def _compute_core_distances_(X, neighbors, min_samples, working_memory): """Compute the k-th nearest neighbor of each sample Equivalent to neighbors.kneighbors(X, self.min_samples)[0][:, -1] but with more memory efficiency. Parameters ---------- X : array, shape (n_samples, n_features) The data. neighbors : NearestNeighbors instance The fitted nearest neighbors estimator. working_memory : int, optional The sought maximum memory for temporary distance matrix chunks. When None (default), the value of ``sklearn.get_config()['working_memory']`` is used. Returns ------- core_distances : array, shape (n_samples,) Distance at which each sample becomes a core point. Points which will never be core have a distance of inf. """ n_samples = X.shape[0] core_distances = np.empty(n_samples) core_distances.fill(np.nan) chunk_n_rows = get_chunk_n_rows(row_bytes=16 * min_samples, max_n_rows=n_samples, working_memory=working_memory) slices = gen_batches(n_samples, chunk_n_rows) for sl in slices: core_distances[sl] = neighbors.kneighbors( X[sl], min_samples)[0][:, -1] return core_distances @_deprecate_positional_args def compute_optics_graph(X, *, min_samples, max_eps, metric, p, metric_params, algorithm, leaf_size, n_jobs): """Computes the OPTICS reachability graph. Read more in the :ref:`User Guide `. Parameters ---------- X : array, shape (n_samples, n_features), or (n_samples, n_samples) \ if metric=’precomputed’. A feature array, or array of distances between samples if metric='precomputed' min_samples : int > 1 or float between 0 and 1 The number of samples in a neighborhood for a point to be considered as a core point. Expressed as an absolute number or a fraction of the number of samples (rounded to be at least 2). max_eps : float, optional (default=np.inf) The maximum distance between two samples for one to be considered as in the neighborhood of the other. Default value of ``np.inf`` will identify clusters across all scales; reducing ``max_eps`` will result in shorter run times. metric : string or callable, optional (default='minkowski') Metric to use for distance computation. Any metric from scikit-learn or scipy.spatial.distance can be used. If metric is a callable function, it is called on each pair of instances (rows) and the resulting value recorded. The callable should take two arrays as input and return one value indicating the distance between them. This works for Scipy's metrics, but is less efficient than passing the metric name as a string. If metric is "precomputed", X is assumed to be a distance matrix and must be square. Valid values for metric are: - from scikit-learn: ['cityblock', 'cosine', 'euclidean', 'l1', 'l2', 'manhattan'] - from scipy.spatial.distance: ['braycurtis', 'canberra', 'chebyshev', 'correlation', 'dice', 'hamming', 'jaccard', 'kulsinski', 'mahalanobis', 'minkowski', 'rogerstanimoto', 'russellrao', 'seuclidean', 'sokalmichener', 'sokalsneath', 'sqeuclidean', 'yule'] See the documentation for scipy.spatial.distance for details on these metrics. p : integer, optional (default=2) Parameter for the Minkowski metric from :class:`sklearn.metrics.pairwise_distances`. When p = 1, this is equivalent to using manhattan_distance (l1), and euclidean_distance (l2) for p = 2. For arbitrary p, minkowski_distance (l_p) is used. metric_params : dict, optional (default=None) Additional keyword arguments for the metric function. algorithm : {'auto', 'ball_tree', 'kd_tree', 'brute'}, optional Algorithm used to compute the nearest neighbors: - 'ball_tree' will use :class:`BallTree` - 'kd_tree' will use :class:`KDTree` - 'brute' will use a brute-force search. - 'auto' will attempt to decide the most appropriate algorithm based on the values passed to :meth:`fit` method. (default) Note: fitting on sparse input will override the setting of this parameter, using brute force. leaf_size : int, optional (default=30) Leaf size passed to :class:`BallTree` or :class:`KDTree`. This can affect the speed of the construction and query, as well as the memory required to store the tree. The optimal value depends on the nature of the problem. n_jobs : int or None, optional (default=None) The number of parallel jobs to run for neighbors search. ``None`` means 1 unless in a :obj:`joblib.parallel_backend` context. ``-1`` means using all processors. See :term:`Glossary ` for more details. Returns ------- ordering_ : array, shape (n_samples,) The cluster ordered list of sample indices. core_distances_ : array, shape (n_samples,) Distance at which each sample becomes a core point, indexed by object order. Points which will never be core have a distance of inf. Use ``clust.core_distances_[clust.ordering_]`` to access in cluster order. reachability_ : array, shape (n_samples,) Reachability distances per sample, indexed by object order. Use ``clust.reachability_[clust.ordering_]`` to access in cluster order. predecessor_ : array, shape (n_samples,) Point that a sample was reached from, indexed by object order. Seed points have a predecessor of -1. References ---------- .. [1] Ankerst, Mihael, Markus M. Breunig, Hans-Peter Kriegel, and Jörg Sander. "OPTICS: ordering points to identify the clustering structure." ACM SIGMOD Record 28, no. 2 (1999): 49-60. """ n_samples = X.shape[0] _validate_size(min_samples, n_samples, 'min_samples') if min_samples <= 1: min_samples = max(2, int(min_samples * n_samples)) # Start all points as 'unprocessed' ## reachability_ = np.empty(n_samples) reachability_.fill(np.inf) predecessor_ = np.empty(n_samples, dtype=int) predecessor_.fill(-1) nbrs = NearestNeighbors(n_neighbors=min_samples, algorithm=algorithm, leaf_size=leaf_size, metric=metric, metric_params=metric_params, p=p, n_jobs=n_jobs) nbrs.fit(X) # Here we first do a kNN query for each point, this differs from # the original OPTICS that only used epsilon range queries. # TODO: handle working_memory somehow? core_distances_ = _compute_core_distances_(X=X, neighbors=nbrs, min_samples=min_samples, working_memory=None) # OPTICS puts an upper limit on these, use inf for undefined. core_distances_[core_distances_ > max_eps] = np.inf # Main OPTICS loop. Not parallelizable. The order that entries are # written to the 'ordering_' list is important! # Note that this implementation is O(n^2) theoretically, but # supposedly with very low constant factors. processed = np.zeros(X.shape[0], dtype=bool) ordering = np.zeros(X.shape[0], dtype=int) for ordering_idx in range(X.shape[0]): # Choose next based on smallest reachability distance # (And prefer smaller ids on ties, possibly np.inf!) index = np.where(processed == 0)[0] point = index[np.argmin(reachability_[index])] processed[point] = True ordering[ordering_idx] = point if core_distances_[point] != np.inf: _set_reach_dist(core_distances_=core_distances_, reachability_=reachability_, predecessor_=predecessor_, point_index=point, processed=processed, X=X, nbrs=nbrs, metric=metric, metric_params=metric_params, p=p, max_eps=max_eps) if np.all(np.isinf(reachability_)): warnings.warn("All reachability values are inf. Set a larger" " max_eps or all data will be considered outliers.", UserWarning) return ordering, core_distances_, reachability_, predecessor_ def _set_reach_dist(core_distances_, reachability_, predecessor_, point_index, processed, X, nbrs, metric, metric_params, p, max_eps): P = X[point_index:point_index + 1] # Assume that radius_neighbors is faster without distances # and we don't need all distances, nevertheless, this means # we may be doing some work twice. indices = nbrs.radius_neighbors(P, radius=max_eps, return_distance=False)[0] # Getting indices of neighbors that have not been processed unproc = np.compress(~np.take(processed, indices), indices) # Neighbors of current point are already processed. if not unproc.size: return # Only compute distances to unprocessed neighbors: if metric == 'precomputed': dists = X[point_index, unproc] else: _params = dict() if metric_params is None else metric_params.copy() if metric == 'minkowski' and 'p' not in _params: # the same logic as neighbors, p is ignored if explicitly set # in the dict params _params['p'] = p dists = pairwise_distances(P, np.take(X, unproc, axis=0), metric=metric, n_jobs=None, **_params).ravel() rdists = np.maximum(dists, core_distances_[point_index]) improved = np.where(rdists < np.take(reachability_, unproc)) reachability_[unproc[improved]] = rdists[improved] predecessor_[unproc[improved]] = point_index @_deprecate_positional_args def cluster_optics_dbscan(*, reachability, core_distances, ordering, eps): """Performs DBSCAN extraction for an arbitrary epsilon. Extracting the clusters runs in linear time. Note that this results in ``labels_`` which are close to a :class:`~sklearn.cluster.DBSCAN` with similar settings and ``eps``, only if ``eps`` is close to ``max_eps``. Parameters ---------- reachability : array, shape (n_samples,) Reachability distances calculated by OPTICS (``reachability_``) core_distances : array, shape (n_samples,) Distances at which points become core (``core_distances_``) ordering : array, shape (n_samples,) OPTICS ordered point indices (``ordering_``) eps : float DBSCAN ``eps`` parameter. Must be set to < ``max_eps``. Results will be close to DBSCAN algorithm if ``eps`` and ``max_eps`` are close to one another. Returns ------- labels_ : array, shape (n_samples,) The estimated labels. """ n_samples = len(core_distances) labels = np.zeros(n_samples, dtype=int) far_reach = reachability > eps near_core = core_distances <= eps labels[ordering] = np.cumsum(far_reach[ordering] & near_core[ordering]) - 1 labels[far_reach & ~near_core] = -1 return labels def cluster_optics_xi(*, reachability, predecessor, ordering, min_samples, min_cluster_size=None, xi=0.05, predecessor_correction=True): """Automatically extract clusters according to the Xi-steep method. Parameters ---------- reachability : array, shape (n_samples,) Reachability distances calculated by OPTICS (`reachability_`) predecessor : array, shape (n_samples,) Predecessors calculated by OPTICS. ordering : array, shape (n_samples,) OPTICS ordered point indices (`ordering_`) min_samples : int > 1 or float between 0 and 1 The same as the min_samples given to OPTICS. Up and down steep regions can't have more then ``min_samples`` consecutive non-steep points. Expressed as an absolute number or a fraction of the number of samples (rounded to be at least 2). min_cluster_size : int > 1 or float between 0 and 1 (default=None) Minimum number of samples in an OPTICS cluster, expressed as an absolute number or a fraction of the number of samples (rounded to be at least 2). If ``None``, the value of ``min_samples`` is used instead. xi : float, between 0 and 1, optional (default=0.05) Determines the minimum steepness on the reachability plot that constitutes a cluster boundary. For example, an upwards point in the reachability plot is defined by the ratio from one point to its successor being at most 1-xi. predecessor_correction : bool, optional (default=True) Correct clusters based on the calculated predecessors. Returns ------- labels : array, shape (n_samples) The labels assigned to samples. Points which are not included in any cluster are labeled as -1. clusters : array, shape (n_clusters, 2) The list of clusters in the form of ``[start, end]`` in each row, with all indices inclusive. The clusters are ordered according to ``(end, -start)`` (ascending) so that larger clusters encompassing smaller clusters come after such nested smaller clusters. Since ``labels`` does not reflect the hierarchy, usually ``len(clusters) > np.unique(labels)``. """ n_samples = len(reachability) _validate_size(min_samples, n_samples, 'min_samples') if min_samples <= 1: min_samples = max(2, int(min_samples * n_samples)) if min_cluster_size is None: min_cluster_size = min_samples _validate_size(min_cluster_size, n_samples, 'min_cluster_size') if min_cluster_size <= 1: min_cluster_size = max(2, int(min_cluster_size * n_samples)) clusters = _xi_cluster(reachability[ordering], predecessor[ordering], ordering, xi, min_samples, min_cluster_size, predecessor_correction) labels = _extract_xi_labels(ordering, clusters) return labels, clusters def _extend_region(steep_point, xward_point, start, min_samples): """Extend the area until it's maximal. It's the same function for both upward and downward reagions, depending on the given input parameters. Assuming: - steep_{upward/downward}: bool array indicating whether a point is a steep {upward/downward}; - upward/downward: bool array indicating whether a point is upward/downward; To extend an upward reagion, ``steep_point=steep_upward`` and ``xward_point=downward`` are expected, and to extend a downward region, ``steep_point=steep_downward`` and ``xward_point=upward``. Parameters ---------- steep_point : bool array, shape (n_samples) True if the point is steep downward (upward). xward_point : bool array, shape (n_samples) True if the point is an upward (respectively downward) point. start : integer The start of the xward region. min_samples : integer The same as the min_samples given to OPTICS. Up and down steep regions can't have more then ``min_samples`` consecutive non-steep points. Returns ------- index : integer The current index iterating over all the samples, i.e. where we are up to in our search. end : integer The end of the region, which can be behind the index. The region includes the ``end`` index. """ n_samples = len(steep_point) non_xward_points = 0 index = start end = start # find a maximal area while index < n_samples: if steep_point[index]: non_xward_points = 0 end = index elif not xward_point[index]: # it's not a steep point, but still goes up. non_xward_points += 1 # region should include no more than min_samples consecutive # non steep xward points. if non_xward_points > min_samples: break else: return end index += 1 return end def _update_filter_sdas(sdas, mib, xi_complement, reachability_plot): """Update steep down areas (SDAs) using the new maximum in between (mib) value, and the given complement of xi, i.e. ``1 - xi``. """ if np.isinf(mib): return [] res = [sda for sda in sdas if mib <= reachability_plot[sda['start']] * xi_complement] for sda in res: sda['mib'] = max(sda['mib'], mib) return res def _correct_predecessor(reachability_plot, predecessor_plot, ordering, s, e): """Correct for predecessors. Applies Algorithm 2 of [1]_. Input parameters are ordered by the computer OPTICS ordering. .. [1] Schubert, Erich, Michael Gertz. "Improving the Cluster Structure Extracted from OPTICS Plots." Proc. of the Conference "Lernen, Wissen, Daten, Analysen" (LWDA) (2018): 318-329. """ while s < e: if reachability_plot[s] > reachability_plot[e]: return s, e p_e = ordering[predecessor_plot[e]] for i in range(s, e): if p_e == ordering[i]: return s, e e -= 1 return None, None def _xi_cluster(reachability_plot, predecessor_plot, ordering, xi, min_samples, min_cluster_size, predecessor_correction): """Automatically extract clusters according to the Xi-steep method. This is rouphly an implementation of Figure 19 of the OPTICS paper. Parameters ---------- reachability_plot : array, shape (n_samples) The reachability plot, i.e. reachability ordered according to the calculated ordering, all computed by OPTICS. predecessor_plot : array, shape (n_samples) Predecessors ordered according to the calculated ordering. xi : float, between 0 and 1 Determines the minimum steepness on the reachability plot that constitutes a cluster boundary. For example, an upwards point in the reachability plot is defined by the ratio from one point to its successor being at most 1-xi. min_samples : int > 1 The same as the min_samples given to OPTICS. Up and down steep regions can't have more then ``min_samples`` consecutive non-steep points. min_cluster_size : int > 1 Minimum number of samples in an OPTICS cluster. predecessor_correction : bool Correct clusters based on the calculated predecessors. Returns ------- clusters : array, shape (n_clusters, 2) The list of clusters in the form of [start, end] in each row, with all indices inclusive. The clusters are ordered in a way that larger clusters encompassing smaller clusters come after those smaller clusters. """ # Our implementation adds an inf to the end of reachability plot # this helps to find potential clusters at the end of the # reachability plot even if there's no upward region at the end of it. reachability_plot = np.hstack((reachability_plot, np.inf)) xi_complement = 1 - xi sdas = [] # steep down areas, introduced in section 4.3.2 of the paper clusters = [] index = 0 mib = 0. # maximum in between, section 4.3.2 # Our implementation corrects a mistake in the original # paper, i.e., in Definition 9 steep downward point, # r(p) * (1 - x1) <= r(p + 1) should be # r(p) * (1 - x1) >= r(p + 1) with np.errstate(invalid='ignore'): ratio = reachability_plot[:-1] / reachability_plot[1:] steep_upward = ratio <= xi_complement steep_downward = ratio >= 1 / xi_complement downward = ratio > 1 upward = ratio < 1 # the following loop is is almost exactly as Figure 19 of the paper. # it jumps over the areas which are not either steep down or up areas for steep_index in iter(np.flatnonzero(steep_upward | steep_downward)): # just continue if steep_index has been a part of a discovered xward # area. if steep_index < index: continue mib = max(mib, np.max(reachability_plot[index:steep_index + 1])) # steep downward areas if steep_downward[steep_index]: sdas = _update_filter_sdas(sdas, mib, xi_complement, reachability_plot) D_start = steep_index D_end = _extend_region(steep_downward, upward, D_start, min_samples) D = {'start': D_start, 'end': D_end, 'mib': 0.} sdas.append(D) index = D_end + 1 mib = reachability_plot[index] # steep upward areas else: sdas = _update_filter_sdas(sdas, mib, xi_complement, reachability_plot) U_start = steep_index U_end = _extend_region(steep_upward, downward, U_start, min_samples) index = U_end + 1 mib = reachability_plot[index] U_clusters = [] for D in sdas: c_start = D['start'] c_end = U_end # line (**), sc2* if reachability_plot[c_end + 1] * xi_complement < D['mib']: continue # Definition 11: criterion 4 D_max = reachability_plot[D['start']] if D_max * xi_complement >= reachability_plot[c_end + 1]: # Find the first index from the left side which is almost # at the same level as the end of the detected cluster. while (reachability_plot[c_start + 1] > reachability_plot[c_end + 1] and c_start < D['end']): c_start += 1 elif reachability_plot[c_end + 1] * xi_complement >= D_max: # Find the first index from the right side which is almost # at the same level as the beginning of the detected # cluster. # Our implementation corrects a mistake in the original # paper, i.e., in Definition 11 4c, r(x) < r(sD) should be # r(x) > r(sD). while (reachability_plot[c_end - 1] > D_max and c_end > U_start): c_end -= 1 # predecessor correction if predecessor_correction: c_start, c_end = _correct_predecessor(reachability_plot, predecessor_plot, ordering, c_start, c_end) if c_start is None: continue # Definition 11: criterion 3.a if c_end - c_start + 1 < min_cluster_size: continue # Definition 11: criterion 1 if c_start > D['end']: continue # Definition 11: criterion 2 if c_end < U_start: continue U_clusters.append((c_start, c_end)) # add smaller clusters first. U_clusters.reverse() clusters.extend(U_clusters) return np.array(clusters) def _extract_xi_labels(ordering, clusters): """Extracts the labels from the clusters returned by `_xi_cluster`. We rely on the fact that clusters are stored with the smaller clusters coming before the larger ones. Parameters ---------- ordering : array, shape (n_samples) The ordering of points calculated by OPTICS clusters : array, shape (n_clusters, 2) List of clusters i.e. (start, end) tuples, as returned by `_xi_cluster`. Returns ------- labels : array, shape (n_samples) """ labels = np.full(len(ordering), -1, dtype=int) label = 0 for c in clusters: if not np.any(labels[c[0]:(c[1] + 1)] != -1): labels[c[0]:(c[1] + 1)] = label label += 1 labels[ordering] = labels.copy() return labels