323 lines
12 KiB
Python
323 lines
12 KiB
Python
# -*- coding: utf-8 -*-
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# Natural Language Toolkit: Transformation-based learning
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#
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# Copyright (C) 2001-2019 NLTK Project
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# Author: Marcus Uneson <marcus.uneson@gmail.com>
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# based on previous (nltk2) version by
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# Christopher Maloof, Edward Loper, Steven Bird
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# URL: <http://nltk.org/>
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# For license information, see LICENSE.TXT
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from __future__ import print_function
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from abc import ABCMeta, abstractmethod
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from six import add_metaclass
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import itertools as it
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from nltk.tbl.feature import Feature
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from nltk.tbl.rule import Rule
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@add_metaclass(ABCMeta)
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class BrillTemplateI(object):
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"""
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An interface for generating lists of transformational rules that
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apply at given sentence positions. ``BrillTemplateI`` is used by
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``Brill`` training algorithms to generate candidate rules.
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"""
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@abstractmethod
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def applicable_rules(self, tokens, i, correctTag):
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"""
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Return a list of the transformational rules that would correct
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the *i*th subtoken's tag in the given token. In particular,
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return a list of zero or more rules that would change
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*tokens*[i][1] to *correctTag*, if applied to *token*[i].
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If the *i*th token already has the correct tag (i.e., if
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tagged_tokens[i][1] == correctTag), then
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``applicable_rules()`` should return the empty list.
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:param tokens: The tagged tokens being tagged.
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:type tokens: list(tuple)
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:param i: The index of the token whose tag should be corrected.
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:type i: int
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:param correctTag: The correct tag for the *i*th token.
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:type correctTag: any
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:rtype: list(BrillRule)
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"""
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@abstractmethod
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def get_neighborhood(self, token, index):
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"""
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Returns the set of indices *i* such that
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``applicable_rules(token, i, ...)`` depends on the value of
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the *index*th token of *token*.
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This method is used by the "fast" Brill tagger trainer.
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:param token: The tokens being tagged.
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:type token: list(tuple)
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:param index: The index whose neighborhood should be returned.
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:type index: int
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:rtype: set
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"""
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class Template(BrillTemplateI):
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"""
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A tbl Template that generates a list of L{Rule}s that apply at a given sentence
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position. In particular, each C{Template} is parameterized by a list of
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independent features (a combination of a specific
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property to extract and a list C{L} of relative positions at which to extract
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it) and generates all Rules that:
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- use the given features, each at its own independent position; and
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- are applicable to the given token.
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"""
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ALLTEMPLATES = []
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# record a unique id of form "001", for each template created
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# _ids = it.count(0)
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def __init__(self, *features):
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"""
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Construct a Template for generating Rules.
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Takes a list of Features. A C{Feature} is a combination
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of a specific property and its relative positions and should be
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a subclass of L{nltk.tbl.feature.Feature}.
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An alternative calling convention (kept for backwards compatibility,
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but less expressive as it only permits one feature type) is
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Template(Feature, (start1, end1), (start2, end2), ...)
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In new code, that would be better written
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Template(Feature(start1, end1), Feature(start2, end2), ...)
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#For instance, importing some features
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>>> from nltk.tbl.template import Template
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>>> from nltk.tag.brill import Word, Pos
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#create some features
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>>> wfeat1, wfeat2, pfeat = (Word([-1]), Word([1,2]), Pos([-2,-1]))
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#Create a single-feature template
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>>> Template(wfeat1)
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Template(Word([-1]))
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#or a two-feature one
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>>> Template(wfeat1, wfeat2)
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Template(Word([-1]),Word([1, 2]))
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#or a three-feature one with two different feature types
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>>> Template(wfeat1, wfeat2, pfeat)
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Template(Word([-1]),Word([1, 2]),Pos([-2, -1]))
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#deprecated api: Feature subclass, followed by list of (start,end) pairs
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#(permits only a single Feature)
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>>> Template(Word, (-2,-1), (0,0))
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Template(Word([-2, -1]),Word([0]))
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#incorrect specification raises TypeError
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>>> Template(Word, (-2,-1), Pos, (0,0))
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Traceback (most recent call last):
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File "<stdin>", line 1, in <module>
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File "nltk/tag/tbl/template.py", line 143, in __init__
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raise TypeError(
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TypeError: expected either Feature1(args), Feature2(args), ... or Feature, (start1, end1), (start2, end2), ...
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:type features: list of Features
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:param features: the features to build this Template on
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"""
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# determine the calling form: either
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# Template(Feature, args1, [args2, ...)]
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# Template(Feature1(args), Feature2(args), ...)
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if all(isinstance(f, Feature) for f in features):
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self._features = features
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elif issubclass(features[0], Feature) and all(
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isinstance(a, tuple) for a in features[1:]
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):
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self._features = [features[0](*tp) for tp in features[1:]]
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else:
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raise TypeError(
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"expected either Feature1(args), Feature2(args), ... or Feature, (start1, end1), (start2, end2), ..."
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)
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self.id = "{0:03d}".format(len(self.ALLTEMPLATES))
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self.ALLTEMPLATES.append(self)
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def __repr__(self):
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return "%s(%s)" % (
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self.__class__.__name__,
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",".join([str(f) for f in self._features]),
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)
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def applicable_rules(self, tokens, index, correct_tag):
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if tokens[index][1] == correct_tag:
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return []
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# For each of this Template's features, find the conditions
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# that are applicable for the given token.
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# Then, generate one Rule for each combination of features
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# (the crossproduct of the conditions).
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applicable_conditions = self._applicable_conditions(tokens, index)
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xs = list(it.product(*applicable_conditions))
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return [Rule(self.id, tokens[index][1], correct_tag, tuple(x)) for x in xs]
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def _applicable_conditions(self, tokens, index):
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"""
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:returns: A set of all conditions for rules
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that are applicable to C{tokens[index]}.
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"""
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conditions = []
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for feature in self._features:
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conditions.append([])
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for pos in feature.positions:
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if not (0 <= index + pos < len(tokens)):
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continue
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value = feature.extract_property(tokens, index + pos)
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conditions[-1].append((feature, value))
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return conditions
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def get_neighborhood(self, tokens, index):
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# inherit docs from BrillTemplateI
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# applicable_rules(tokens, index, ...) depends on index.
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neighborhood = set([index]) # set literal for python 2.7+
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# applicable_rules(tokens, i, ...) depends on index if
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# i+start < index <= i+end.
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allpositions = [0] + [p for feat in self._features for p in feat.positions]
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start, end = min(allpositions), max(allpositions)
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s = max(0, index + (-end))
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e = min(index + (-start) + 1, len(tokens))
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for i in range(s, e):
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neighborhood.add(i)
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return neighborhood
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@classmethod
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def expand(cls, featurelists, combinations=None, skipintersecting=True):
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"""
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Factory method to mass generate Templates from a list L of lists of Features.
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#With combinations=(k1, k2), the function will in all possible ways choose k1 ... k2
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#of the sublists in L; it will output all Templates formed by the Cartesian product
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#of this selection, with duplicates and other semantically equivalent
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#forms removed. Default for combinations is (1, len(L)).
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The feature lists may have been specified
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manually, or generated from Feature.expand(). For instance,
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>>> from nltk.tbl.template import Template
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>>> from nltk.tag.brill import Word, Pos
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#creating some features
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>>> (wd_0, wd_01) = (Word([0]), Word([0,1]))
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>>> (pos_m2, pos_m33) = (Pos([-2]), Pos([3-2,-1,0,1,2,3]))
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>>> list(Template.expand([[wd_0], [pos_m2]]))
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[Template(Word([0])), Template(Pos([-2])), Template(Pos([-2]),Word([0]))]
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>>> list(Template.expand([[wd_0, wd_01], [pos_m2]]))
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[Template(Word([0])), Template(Word([0, 1])), Template(Pos([-2])), Template(Pos([-2]),Word([0])), Template(Pos([-2]),Word([0, 1]))]
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#note: with Feature.expand(), it is very easy to generate more templates
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#than your system can handle -- for instance,
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>>> wordtpls = Word.expand([-2,-1,0,1], [1,2], excludezero=False)
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>>> len(wordtpls)
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7
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>>> postpls = Pos.expand([-3,-2,-1,0,1,2], [1,2,3], excludezero=True)
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>>> len(postpls)
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9
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#and now the Cartesian product of all non-empty combinations of two wordtpls and
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#two postpls, with semantic equivalents removed
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>>> templates = list(Template.expand([wordtpls, wordtpls, postpls, postpls]))
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>>> len(templates)
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713
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will return a list of eight templates
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Template(Word([0])),
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Template(Word([0, 1])),
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Template(Pos([-2])),
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Template(Pos([-1])),
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Template(Pos([-2]),Word([0])),
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Template(Pos([-1]),Word([0])),
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Template(Pos([-2]),Word([0, 1])),
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Template(Pos([-1]),Word([0, 1]))]
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#Templates where one feature is a subset of another, such as
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#Template(Word([0,1]), Word([1]), will not appear in the output.
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#By default, this non-subset constraint is tightened to disjointness:
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#Templates of type Template(Word([0,1]), Word([1,2]) will also be filtered out.
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#With skipintersecting=False, then such Templates are allowed
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WARNING: this method makes it very easy to fill all your memory when training
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generated templates on any real-world corpus
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:param featurelists: lists of Features, whose Cartesian product will return a set of Templates
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:type featurelists: list of (list of Features)
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:param combinations: given n featurelists: if combinations=k, all generated Templates will have
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k features; if combinations=(k1,k2) they will have k1..k2 features; if None, defaults to 1..n
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:type combinations: None, int, or (int, int)
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:param skipintersecting: if True, do not output intersecting Templates (non-disjoint positions for some feature)
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:type skipintersecting: bool
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:returns: generator of Templates
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"""
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def nonempty_powerset(xs): # xs is a list
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# itertools docnonempty_powerset([1,2,3]) --> (1,) (2,) (3,) (1,2) (1,3) (2,3) (1,2,3)
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# find the correct tuple given combinations, one of {None, k, (k1,k2)}
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k = combinations # for brevity
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combrange = (
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(1, len(xs) + 1)
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if k is None
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else (k, k + 1) # n over 1 .. n over n (all non-empty combinations)
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if isinstance(k, int)
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else (k[0], k[1] + 1) # n over k (only
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) # n over k1, n over k1+1... n over k2
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return it.chain.from_iterable(
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it.combinations(xs, r) for r in range(*combrange)
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)
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seentemplates = set()
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for picks in nonempty_powerset(featurelists):
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for pick in it.product(*picks):
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if any(
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i != j and x.issuperset(y)
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for (i, x) in enumerate(pick)
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for (j, y) in enumerate(pick)
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):
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continue
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if skipintersecting and any(
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i != j and x.intersects(y)
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for (i, x) in enumerate(pick)
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for (j, y) in enumerate(pick)
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):
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continue
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thistemplate = cls(*sorted(pick))
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strpick = str(thistemplate)
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#!!FIXME --this is hackish
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if strpick in seentemplates: # already added
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cls._poptemplate()
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continue
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seentemplates.add(strpick)
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yield thistemplate
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@classmethod
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def _cleartemplates(cls):
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cls.ALLTEMPLATES = []
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@classmethod
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def _poptemplate(cls):
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return cls.ALLTEMPLATES.pop() if cls.ALLTEMPLATES else None
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