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301 lines
9.5 KiB
Python
301 lines
9.5 KiB
Python
# Natural Language Toolkit: Clusterer Utilities
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#
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# Copyright (C) 2001-2020 NLTK Project
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# Author: Trevor Cohn <tacohn@cs.mu.oz.au>
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# Contributor: J Richard Snape
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# URL: <http://nltk.org/>
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# For license information, see LICENSE.TXT
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from abc import abstractmethod
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import copy
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from sys import stdout
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from math import sqrt
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try:
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import numpy
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except ImportError:
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pass
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from nltk.cluster.api import ClusterI
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class VectorSpaceClusterer(ClusterI):
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"""
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Abstract clusterer which takes tokens and maps them into a vector space.
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Optionally performs singular value decomposition to reduce the
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dimensionality.
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"""
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def __init__(self, normalise=False, svd_dimensions=None):
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"""
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:param normalise: should vectors be normalised to length 1
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:type normalise: boolean
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:param svd_dimensions: number of dimensions to use in reducing vector
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dimensionsionality with SVD
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:type svd_dimensions: int
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"""
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self._Tt = None
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self._should_normalise = normalise
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self._svd_dimensions = svd_dimensions
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def cluster(self, vectors, assign_clusters=False, trace=False):
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assert len(vectors) > 0
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# normalise the vectors
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if self._should_normalise:
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vectors = list(map(self._normalise, vectors))
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# use SVD to reduce the dimensionality
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if self._svd_dimensions and self._svd_dimensions < len(vectors[0]):
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[u, d, vt] = numpy.linalg.svd(numpy.transpose(numpy.array(vectors)))
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S = d[: self._svd_dimensions] * numpy.identity(
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self._svd_dimensions, numpy.float64
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)
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T = u[:, : self._svd_dimensions]
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Dt = vt[: self._svd_dimensions, :]
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vectors = numpy.transpose(numpy.dot(S, Dt))
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self._Tt = numpy.transpose(T)
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# call abstract method to cluster the vectors
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self.cluster_vectorspace(vectors, trace)
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# assign the vectors to clusters
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if assign_clusters:
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return [self.classify(vector) for vector in vectors]
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@abstractmethod
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def cluster_vectorspace(self, vectors, trace):
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"""
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Finds the clusters using the given set of vectors.
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"""
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def classify(self, vector):
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if self._should_normalise:
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vector = self._normalise(vector)
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if self._Tt is not None:
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vector = numpy.dot(self._Tt, vector)
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cluster = self.classify_vectorspace(vector)
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return self.cluster_name(cluster)
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@abstractmethod
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def classify_vectorspace(self, vector):
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"""
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Returns the index of the appropriate cluster for the vector.
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"""
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def likelihood(self, vector, label):
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if self._should_normalise:
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vector = self._normalise(vector)
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if self._Tt is not None:
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vector = numpy.dot(self._Tt, vector)
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return self.likelihood_vectorspace(vector, label)
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def likelihood_vectorspace(self, vector, cluster):
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"""
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Returns the likelihood of the vector belonging to the cluster.
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"""
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predicted = self.classify_vectorspace(vector)
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return 1.0 if cluster == predicted else 0.0
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def vector(self, vector):
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"""
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Returns the vector after normalisation and dimensionality reduction
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"""
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if self._should_normalise:
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vector = self._normalise(vector)
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if self._Tt is not None:
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vector = numpy.dot(self._Tt, vector)
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return vector
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def _normalise(self, vector):
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"""
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Normalises the vector to unit length.
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"""
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return vector / sqrt(numpy.dot(vector, vector))
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def euclidean_distance(u, v):
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"""
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Returns the euclidean distance between vectors u and v. This is equivalent
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to the length of the vector (u - v).
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"""
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diff = u - v
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return sqrt(numpy.dot(diff, diff))
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def cosine_distance(u, v):
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"""
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Returns 1 minus the cosine of the angle between vectors v and u. This is
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equal to 1 - (u.v / |u||v|).
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"""
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return 1 - (numpy.dot(u, v) / (sqrt(numpy.dot(u, u)) * sqrt(numpy.dot(v, v))))
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class _DendrogramNode(object):
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""" Tree node of a dendrogram. """
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def __init__(self, value, *children):
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self._value = value
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self._children = children
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def leaves(self, values=True):
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if self._children:
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leaves = []
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for child in self._children:
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leaves.extend(child.leaves(values))
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return leaves
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elif values:
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return [self._value]
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else:
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return [self]
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def groups(self, n):
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queue = [(self._value, self)]
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while len(queue) < n:
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priority, node = queue.pop()
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if not node._children:
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queue.push((priority, node))
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break
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for child in node._children:
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if child._children:
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queue.append((child._value, child))
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else:
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queue.append((0, child))
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# makes the earliest merges at the start, latest at the end
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queue.sort()
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groups = []
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for priority, node in queue:
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groups.append(node.leaves())
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return groups
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def __lt__(self, comparator):
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return cosine_distance(self._value, comparator._value) < 0
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class Dendrogram(object):
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"""
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Represents a dendrogram, a tree with a specified branching order. This
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must be initialised with the leaf items, then iteratively call merge for
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each branch. This class constructs a tree representing the order of calls
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to the merge function.
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"""
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def __init__(self, items=[]):
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"""
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:param items: the items at the leaves of the dendrogram
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:type items: sequence of (any)
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"""
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self._items = [_DendrogramNode(item) for item in items]
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self._original_items = copy.copy(self._items)
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self._merge = 1
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def merge(self, *indices):
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"""
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Merges nodes at given indices in the dendrogram. The nodes will be
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combined which then replaces the first node specified. All other nodes
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involved in the merge will be removed.
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:param indices: indices of the items to merge (at least two)
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:type indices: seq of int
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"""
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assert len(indices) >= 2
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node = _DendrogramNode(self._merge, *[self._items[i] for i in indices])
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self._merge += 1
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self._items[indices[0]] = node
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for i in indices[1:]:
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del self._items[i]
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def groups(self, n):
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"""
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Finds the n-groups of items (leaves) reachable from a cut at depth n.
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:param n: number of groups
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:type n: int
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"""
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if len(self._items) > 1:
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root = _DendrogramNode(self._merge, *self._items)
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else:
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root = self._items[0]
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return root.groups(n)
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def show(self, leaf_labels=[]):
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"""
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Print the dendrogram in ASCII art to standard out.
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:param leaf_labels: an optional list of strings to use for labeling the
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leaves
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:type leaf_labels: list
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"""
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# ASCII rendering characters
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JOIN, HLINK, VLINK = "+", "-", "|"
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# find the root (or create one)
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if len(self._items) > 1:
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root = _DendrogramNode(self._merge, *self._items)
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else:
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root = self._items[0]
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leaves = self._original_items
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if leaf_labels:
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last_row = leaf_labels
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else:
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last_row = ["%s" % leaf._value for leaf in leaves]
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# find the bottom row and the best cell width
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width = max(map(len, last_row)) + 1
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lhalf = width // 2
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rhalf = int(width - lhalf - 1)
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# display functions
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def format(centre, left=" ", right=" "):
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return "%s%s%s" % (lhalf * left, centre, right * rhalf)
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def display(str):
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stdout.write(str)
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# for each merge, top down
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queue = [(root._value, root)]
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verticals = [format(" ") for leaf in leaves]
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while queue:
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priority, node = queue.pop()
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child_left_leaf = list(map(lambda c: c.leaves(False)[0], node._children))
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indices = list(map(leaves.index, child_left_leaf))
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if child_left_leaf:
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min_idx = min(indices)
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max_idx = max(indices)
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for i in range(len(leaves)):
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if leaves[i] in child_left_leaf:
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if i == min_idx:
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display(format(JOIN, " ", HLINK))
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elif i == max_idx:
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display(format(JOIN, HLINK, " "))
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else:
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display(format(JOIN, HLINK, HLINK))
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verticals[i] = format(VLINK)
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elif min_idx <= i <= max_idx:
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display(format(HLINK, HLINK, HLINK))
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else:
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display(verticals[i])
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display("\n")
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for child in node._children:
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if child._children:
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queue.append((child._value, child))
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queue.sort()
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for vertical in verticals:
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display(vertical)
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display("\n")
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# finally, display the last line
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display("".join(item.center(width) for item in last_row))
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display("\n")
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def __repr__(self):
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if len(self._items) > 1:
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root = _DendrogramNode(self._merge, *self._items)
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else:
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root = self._items[0]
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leaves = root.leaves(False)
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return "<Dendrogram with %d leaves>" % len(leaves)
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