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662 lines
22 KiB
Python
662 lines
22 KiB
Python
# Natural Language Toolkit: Collections
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#
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# Copyright (C) 2001-2020 NLTK Project
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# Author: Steven Bird <stevenbird1@gmail.com>
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# URL: <http://nltk.org/>
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# For license information, see LICENSE.TXT
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import bisect
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from itertools import islice, chain
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from functools import total_ordering
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# this unused import is for python 2.7
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from collections import defaultdict, deque, Counter
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from nltk.internals import slice_bounds, raise_unorderable_types
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##########################################################################
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# Ordered Dictionary
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##########################################################################
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class OrderedDict(dict):
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def __init__(self, data=None, **kwargs):
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self._keys = self.keys(data, kwargs.get("keys"))
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self._default_factory = kwargs.get("default_factory")
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if data is None:
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dict.__init__(self)
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else:
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dict.__init__(self, data)
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def __delitem__(self, key):
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dict.__delitem__(self, key)
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self._keys.remove(key)
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def __getitem__(self, key):
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try:
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return dict.__getitem__(self, key)
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except KeyError:
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return self.__missing__(key)
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def __iter__(self):
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return (key for key in self.keys())
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def __missing__(self, key):
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if not self._default_factory and key not in self._keys:
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raise KeyError()
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return self._default_factory()
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def __setitem__(self, key, item):
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dict.__setitem__(self, key, item)
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if key not in self._keys:
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self._keys.append(key)
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def clear(self):
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dict.clear(self)
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self._keys.clear()
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def copy(self):
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d = dict.copy(self)
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d._keys = self._keys
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return d
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def items(self):
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# returns iterator under python 3 and list under python 2
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return zip(self.keys(), self.values())
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def keys(self, data=None, keys=None):
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if data:
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if keys:
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assert isinstance(keys, list)
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assert len(data) == len(keys)
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return keys
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else:
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assert (
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isinstance(data, dict)
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or isinstance(data, OrderedDict)
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or isinstance(data, list)
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)
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if isinstance(data, dict) or isinstance(data, OrderedDict):
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return data.keys()
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elif isinstance(data, list):
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return [key for (key, value) in data]
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elif "_keys" in self.__dict__:
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return self._keys
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else:
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return []
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def popitem(self):
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if not self._keys:
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raise KeyError()
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key = self._keys.pop()
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value = self[key]
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del self[key]
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return (key, value)
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def setdefault(self, key, failobj=None):
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dict.setdefault(self, key, failobj)
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if key not in self._keys:
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self._keys.append(key)
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def update(self, data):
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dict.update(self, data)
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for key in self.keys(data):
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if key not in self._keys:
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self._keys.append(key)
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def values(self):
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# returns iterator under python 3
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return map(self.get, self._keys)
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######################################################################
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# Lazy Sequences
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######################################################################
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@total_ordering
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class AbstractLazySequence(object):
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"""
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An abstract base class for read-only sequences whose values are
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computed as needed. Lazy sequences act like tuples -- they can be
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indexed, sliced, and iterated over; but they may not be modified.
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The most common application of lazy sequences in NLTK is for
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corpus view objects, which provide access to the contents of a
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corpus without loading the entire corpus into memory, by loading
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pieces of the corpus from disk as needed.
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The result of modifying a mutable element of a lazy sequence is
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undefined. In particular, the modifications made to the element
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may or may not persist, depending on whether and when the lazy
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sequence caches that element's value or reconstructs it from
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scratch.
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Subclasses are required to define two methods: ``__len__()``
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and ``iterate_from()``.
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"""
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def __len__(self):
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"""
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Return the number of tokens in the corpus file underlying this
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corpus view.
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"""
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raise NotImplementedError("should be implemented by subclass")
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def iterate_from(self, start):
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"""
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Return an iterator that generates the tokens in the corpus
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file underlying this corpus view, starting at the token number
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``start``. If ``start>=len(self)``, then this iterator will
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generate no tokens.
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"""
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raise NotImplementedError("should be implemented by subclass")
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def __getitem__(self, i):
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"""
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Return the *i* th token in the corpus file underlying this
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corpus view. Negative indices and spans are both supported.
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"""
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if isinstance(i, slice):
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start, stop = slice_bounds(self, i)
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return LazySubsequence(self, start, stop)
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else:
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# Handle negative indices
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if i < 0:
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i += len(self)
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if i < 0:
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raise IndexError("index out of range")
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# Use iterate_from to extract it.
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try:
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return next(self.iterate_from(i))
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except StopIteration:
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raise IndexError("index out of range")
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def __iter__(self):
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"""Return an iterator that generates the tokens in the corpus
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file underlying this corpus view."""
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return self.iterate_from(0)
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def count(self, value):
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"""Return the number of times this list contains ``value``."""
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return sum(1 for elt in self if elt == value)
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def index(self, value, start=None, stop=None):
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"""Return the index of the first occurrence of ``value`` in this
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list that is greater than or equal to ``start`` and less than
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``stop``. Negative start and stop values are treated like negative
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slice bounds -- i.e., they count from the end of the list."""
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start, stop = slice_bounds(self, slice(start, stop))
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for i, elt in enumerate(islice(self, start, stop)):
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if elt == value:
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return i + start
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raise ValueError("index(x): x not in list")
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def __contains__(self, value):
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"""Return true if this list contains ``value``."""
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return bool(self.count(value))
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def __add__(self, other):
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"""Return a list concatenating self with other."""
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return LazyConcatenation([self, other])
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def __radd__(self, other):
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"""Return a list concatenating other with self."""
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return LazyConcatenation([other, self])
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def __mul__(self, count):
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"""Return a list concatenating self with itself ``count`` times."""
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return LazyConcatenation([self] * count)
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def __rmul__(self, count):
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"""Return a list concatenating self with itself ``count`` times."""
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return LazyConcatenation([self] * count)
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_MAX_REPR_SIZE = 60
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def __repr__(self):
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"""
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Return a string representation for this corpus view that is
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similar to a list's representation; but if it would be more
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than 60 characters long, it is truncated.
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"""
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pieces = []
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length = 5
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for elt in self:
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pieces.append(repr(elt))
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length += len(pieces[-1]) + 2
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if length > self._MAX_REPR_SIZE and len(pieces) > 2:
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return "[%s, ...]" % ", ".join(pieces[:-1])
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return "[%s]" % ", ".join(pieces)
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def __eq__(self, other):
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return type(self) == type(other) and list(self) == list(other)
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def __ne__(self, other):
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return not self == other
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def __lt__(self, other):
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if type(other) != type(self):
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raise_unorderable_types("<", self, other)
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return list(self) < list(other)
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def __hash__(self):
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"""
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:raise ValueError: Corpus view objects are unhashable.
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"""
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raise ValueError("%s objects are unhashable" % self.__class__.__name__)
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class LazySubsequence(AbstractLazySequence):
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"""
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A subsequence produced by slicing a lazy sequence. This slice
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keeps a reference to its source sequence, and generates its values
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by looking them up in the source sequence.
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"""
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MIN_SIZE = 100
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"""
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The minimum size for which lazy slices should be created. If
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``LazySubsequence()`` is called with a subsequence that is
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shorter than ``MIN_SIZE``, then a tuple will be returned instead.
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"""
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def __new__(cls, source, start, stop):
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"""
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Construct a new slice from a given underlying sequence. The
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``start`` and ``stop`` indices should be absolute indices --
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i.e., they should not be negative (for indexing from the back
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of a list) or greater than the length of ``source``.
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"""
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# If the slice is small enough, just use a tuple.
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if stop - start < cls.MIN_SIZE:
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return list(islice(source.iterate_from(start), stop - start))
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else:
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return object.__new__(cls)
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def __init__(self, source, start, stop):
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self._source = source
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self._start = start
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self._stop = stop
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def __len__(self):
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return self._stop - self._start
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def iterate_from(self, start):
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return islice(
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self._source.iterate_from(start + self._start), max(0, len(self) - start)
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)
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class LazyConcatenation(AbstractLazySequence):
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"""
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A lazy sequence formed by concatenating a list of lists. This
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underlying list of lists may itself be lazy. ``LazyConcatenation``
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maintains an index that it uses to keep track of the relationship
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between offsets in the concatenated lists and offsets in the
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sublists.
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"""
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def __init__(self, list_of_lists):
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self._list = list_of_lists
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self._offsets = [0]
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def __len__(self):
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if len(self._offsets) <= len(self._list):
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for tok in self.iterate_from(self._offsets[-1]):
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pass
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return self._offsets[-1]
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def iterate_from(self, start_index):
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if start_index < self._offsets[-1]:
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sublist_index = bisect.bisect_right(self._offsets, start_index) - 1
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else:
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sublist_index = len(self._offsets) - 1
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index = self._offsets[sublist_index]
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# Construct an iterator over the sublists.
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if isinstance(self._list, AbstractLazySequence):
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sublist_iter = self._list.iterate_from(sublist_index)
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else:
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sublist_iter = islice(self._list, sublist_index, None)
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for sublist in sublist_iter:
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if sublist_index == (len(self._offsets) - 1):
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assert (
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index + len(sublist) >= self._offsets[-1]
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), "offests not monotonic increasing!"
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self._offsets.append(index + len(sublist))
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else:
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assert self._offsets[sublist_index + 1] == index + len(
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sublist
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), "inconsistent list value (num elts)"
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for value in sublist[max(0, start_index - index) :]:
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yield value
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index += len(sublist)
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sublist_index += 1
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class LazyMap(AbstractLazySequence):
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"""
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A lazy sequence whose elements are formed by applying a given
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function to each element in one or more underlying lists. The
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function is applied lazily -- i.e., when you read a value from the
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list, ``LazyMap`` will calculate that value by applying its
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function to the underlying lists' value(s). ``LazyMap`` is
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essentially a lazy version of the Python primitive function
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``map``. In particular, the following two expressions are
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equivalent:
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>>> from nltk.collections import LazyMap
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>>> function = str
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>>> sequence = [1,2,3]
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>>> map(function, sequence) # doctest: +SKIP
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['1', '2', '3']
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>>> list(LazyMap(function, sequence))
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['1', '2', '3']
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Like the Python ``map`` primitive, if the source lists do not have
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equal size, then the value None will be supplied for the
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'missing' elements.
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Lazy maps can be useful for conserving memory, in cases where
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individual values take up a lot of space. This is especially true
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if the underlying list's values are constructed lazily, as is the
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case with many corpus readers.
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A typical example of a use case for this class is performing
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feature detection on the tokens in a corpus. Since featuresets
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are encoded as dictionaries, which can take up a lot of memory,
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using a ``LazyMap`` can significantly reduce memory usage when
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training and running classifiers.
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"""
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def __init__(self, function, *lists, **config):
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"""
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:param function: The function that should be applied to
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elements of ``lists``. It should take as many arguments
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as there are ``lists``.
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:param lists: The underlying lists.
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:param cache_size: Determines the size of the cache used
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by this lazy map. (default=5)
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"""
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if not lists:
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raise TypeError("LazyMap requires at least two args")
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self._lists = lists
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self._func = function
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self._cache_size = config.get("cache_size", 5)
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self._cache = {} if self._cache_size > 0 else None
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# If you just take bool() of sum() here _all_lazy will be true just
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# in case n >= 1 list is an AbstractLazySequence. Presumably this
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# isn't what's intended.
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self._all_lazy = sum(
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isinstance(lst, AbstractLazySequence) for lst in lists
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) == len(lists)
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def iterate_from(self, index):
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# Special case: one lazy sublist
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if len(self._lists) == 1 and self._all_lazy:
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for value in self._lists[0].iterate_from(index):
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yield self._func(value)
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return
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# Special case: one non-lazy sublist
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elif len(self._lists) == 1:
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while True:
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try:
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yield self._func(self._lists[0][index])
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except IndexError:
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return
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index += 1
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# Special case: n lazy sublists
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elif self._all_lazy:
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iterators = [lst.iterate_from(index) for lst in self._lists]
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while True:
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elements = []
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for iterator in iterators:
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try:
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elements.append(next(iterator))
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except: # FIXME: What is this except really catching? StopIteration?
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elements.append(None)
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if elements == [None] * len(self._lists):
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return
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yield self._func(*elements)
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index += 1
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# general case
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else:
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while True:
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try:
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elements = [lst[index] for lst in self._lists]
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except IndexError:
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elements = [None] * len(self._lists)
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for i, lst in enumerate(self._lists):
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try:
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elements[i] = lst[index]
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except IndexError:
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pass
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if elements == [None] * len(self._lists):
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return
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yield self._func(*elements)
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index += 1
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def __getitem__(self, index):
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if isinstance(index, slice):
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sliced_lists = [lst[index] for lst in self._lists]
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return LazyMap(self._func, *sliced_lists)
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else:
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# Handle negative indices
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if index < 0:
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index += len(self)
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if index < 0:
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raise IndexError("index out of range")
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# Check the cache
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if self._cache is not None and index in self._cache:
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return self._cache[index]
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# Calculate the value
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try:
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val = next(self.iterate_from(index))
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except StopIteration:
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raise IndexError("index out of range")
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# Update the cache
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if self._cache is not None:
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if len(self._cache) > self._cache_size:
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self._cache.popitem() # discard random entry
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self._cache[index] = val
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# Return the value
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return val
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def __len__(self):
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return max(len(lst) for lst in self._lists)
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class LazyZip(LazyMap):
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"""
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A lazy sequence whose elements are tuples, each containing the i-th
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element from each of the argument sequences. The returned list is
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truncated in length to the length of the shortest argument sequence. The
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tuples are constructed lazily -- i.e., when you read a value from the
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list, ``LazyZip`` will calculate that value by forming a tuple from
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the i-th element of each of the argument sequences.
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``LazyZip`` is essentially a lazy version of the Python primitive function
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``zip``. In particular, an evaluated LazyZip is equivalent to a zip:
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>>> from nltk.collections import LazyZip
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>>> sequence1, sequence2 = [1, 2, 3], ['a', 'b', 'c']
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>>> zip(sequence1, sequence2) # doctest: +SKIP
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[(1, 'a'), (2, 'b'), (3, 'c')]
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>>> list(LazyZip(sequence1, sequence2))
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[(1, 'a'), (2, 'b'), (3, 'c')]
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>>> sequences = [sequence1, sequence2, [6,7,8,9]]
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>>> list(zip(*sequences)) == list(LazyZip(*sequences))
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True
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Lazy zips can be useful for conserving memory in cases where the argument
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sequences are particularly long.
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A typical example of a use case for this class is combining long sequences
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of gold standard and predicted values in a classification or tagging task
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in order to calculate accuracy. By constructing tuples lazily and
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avoiding the creation of an additional long sequence, memory usage can be
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significantly reduced.
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"""
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def __init__(self, *lists):
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"""
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:param lists: the underlying lists
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:type lists: list(list)
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"""
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LazyMap.__init__(self, lambda *elts: elts, *lists)
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def iterate_from(self, index):
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iterator = LazyMap.iterate_from(self, index)
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while index < len(self):
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yield next(iterator)
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index += 1
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return
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def __len__(self):
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return min(len(lst) for lst in self._lists)
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class LazyEnumerate(LazyZip):
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"""
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A lazy sequence whose elements are tuples, each ontaining a count (from
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zero) and a value yielded by underlying sequence. ``LazyEnumerate`` is
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useful for obtaining an indexed list. The tuples are constructed lazily
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-- i.e., when you read a value from the list, ``LazyEnumerate`` will
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calculate that value by forming a tuple from the count of the i-th
|
|
element and the i-th element of the underlying sequence.
|
|
|
|
``LazyEnumerate`` is essentially a lazy version of the Python primitive
|
|
function ``enumerate``. In particular, the following two expressions are
|
|
equivalent:
|
|
|
|
>>> from nltk.collections import LazyEnumerate
|
|
>>> sequence = ['first', 'second', 'third']
|
|
>>> list(enumerate(sequence))
|
|
[(0, 'first'), (1, 'second'), (2, 'third')]
|
|
>>> list(LazyEnumerate(sequence))
|
|
[(0, 'first'), (1, 'second'), (2, 'third')]
|
|
|
|
Lazy enumerations can be useful for conserving memory in cases where the
|
|
argument sequences are particularly long.
|
|
|
|
A typical example of a use case for this class is obtaining an indexed
|
|
list for a long sequence of values. By constructing tuples lazily and
|
|
avoiding the creation of an additional long sequence, memory usage can be
|
|
significantly reduced.
|
|
"""
|
|
|
|
def __init__(self, lst):
|
|
"""
|
|
:param lst: the underlying list
|
|
:type lst: list
|
|
"""
|
|
LazyZip.__init__(self, range(len(lst)), lst)
|
|
|
|
|
|
class LazyIteratorList(AbstractLazySequence):
|
|
"""
|
|
Wraps an iterator, loading its elements on demand
|
|
and making them subscriptable.
|
|
__repr__ displays only the first few elements.
|
|
"""
|
|
|
|
def __init__(self, it, known_len=None):
|
|
self._it = it
|
|
self._len = known_len
|
|
self._cache = []
|
|
|
|
def __len__(self):
|
|
if self._len:
|
|
return self._len
|
|
for x in self.iterate_from(len(self._cache)):
|
|
pass
|
|
self._len = len(self._cache)
|
|
return self._len
|
|
|
|
def iterate_from(self, start):
|
|
"""Create a new iterator over this list starting at the given offset."""
|
|
while len(self._cache) < start:
|
|
v = next(self._it)
|
|
self._cache.append(v)
|
|
i = start
|
|
while i < len(self._cache):
|
|
yield self._cache[i]
|
|
i += 1
|
|
while True:
|
|
v = next(self._it)
|
|
self._cache.append(v)
|
|
yield v
|
|
i += 1
|
|
|
|
def __add__(self, other):
|
|
"""Return a list concatenating self with other."""
|
|
return type(self)(chain(self, other))
|
|
|
|
def __radd__(self, other):
|
|
"""Return a list concatenating other with self."""
|
|
return type(self)(chain(other, self))
|
|
|
|
|
|
######################################################################
|
|
# Trie Implementation
|
|
######################################################################
|
|
class Trie(dict):
|
|
"""A Trie implementation for strings"""
|
|
|
|
LEAF = True
|
|
|
|
def __init__(self, strings=None):
|
|
"""Builds a Trie object, which is built around a ``dict``
|
|
|
|
If ``strings`` is provided, it will add the ``strings``, which
|
|
consist of a ``list`` of ``strings``, to the Trie.
|
|
Otherwise, it'll construct an empty Trie.
|
|
|
|
:param strings: List of strings to insert into the trie
|
|
(Default is ``None``)
|
|
:type strings: list(str)
|
|
|
|
"""
|
|
super(Trie, self).__init__()
|
|
if strings:
|
|
for string in strings:
|
|
self.insert(string)
|
|
|
|
def insert(self, string):
|
|
"""Inserts ``string`` into the Trie
|
|
|
|
:param string: String to insert into the trie
|
|
:type string: str
|
|
|
|
:Example:
|
|
|
|
>>> from nltk.collections import Trie
|
|
>>> trie = Trie(["abc", "def"])
|
|
>>> expected = {'a': {'b': {'c': {True: None}}}, \
|
|
'd': {'e': {'f': {True: None}}}}
|
|
>>> trie == expected
|
|
True
|
|
|
|
"""
|
|
if len(string):
|
|
self[string[0]].insert(string[1:])
|
|
else:
|
|
# mark the string is complete
|
|
self[Trie.LEAF] = None
|
|
|
|
def __missing__(self, key):
|
|
self[key] = Trie()
|
|
return self[key]
|