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374 lines
11 KiB
Plaintext
374 lines
11 KiB
Plaintext
.. Copyright (C) 2001-2020 NLTK Project
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.. For license information, see LICENSE.TXT
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==========
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Chunking
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==========
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>>> from nltk.chunk import *
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>>> from nltk.chunk.util import *
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>>> from nltk.chunk.regexp import *
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>>> from nltk import Tree
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>>> tagged_text = "[ The/DT cat/NN ] sat/VBD on/IN [ the/DT mat/NN ] [ the/DT dog/NN ] chewed/VBD ./."
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>>> gold_chunked_text = tagstr2tree(tagged_text)
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>>> unchunked_text = gold_chunked_text.flatten()
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Chunking uses a special regexp syntax for rules that delimit the chunks. These
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rules must be converted to 'regular' regular expressions before a sentence can
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be chunked.
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>>> tag_pattern = "<DT>?<JJ>*<NN.*>"
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>>> regexp_pattern = tag_pattern2re_pattern(tag_pattern)
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>>> regexp_pattern
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'(<(DT)>)?(<(JJ)>)*(<(NN[^\\{\\}<>]*)>)'
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Construct some new chunking rules.
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>>> chunk_rule = ChunkRule("<.*>+", "Chunk everything")
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>>> chink_rule = ChinkRule("<VBD|IN|\.>", "Chink on verbs/prepositions")
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>>> split_rule = SplitRule("<DT><NN>", "<DT><NN>",
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... "Split successive determiner/noun pairs")
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Create and score a series of chunk parsers, successively more complex.
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>>> chunk_parser = RegexpChunkParser([chunk_rule], chunk_label='NP')
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>>> chunked_text = chunk_parser.parse(unchunked_text)
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>>> print(chunked_text)
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(S
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(NP
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The/DT
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cat/NN
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sat/VBD
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on/IN
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the/DT
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mat/NN
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the/DT
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dog/NN
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chewed/VBD
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./.))
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>>> chunkscore = ChunkScore()
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>>> chunkscore.score(gold_chunked_text, chunked_text)
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>>> print(chunkscore.precision())
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0.0
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>>> print(chunkscore.recall())
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0.0
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>>> print(chunkscore.f_measure())
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0
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>>> for chunk in sorted(chunkscore.missed()): print(chunk)
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(NP The/DT cat/NN)
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(NP the/DT dog/NN)
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(NP the/DT mat/NN)
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>>> for chunk in chunkscore.incorrect(): print(chunk)
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(NP
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The/DT
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cat/NN
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sat/VBD
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on/IN
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the/DT
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mat/NN
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the/DT
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dog/NN
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chewed/VBD
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./.)
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>>> chunk_parser = RegexpChunkParser([chunk_rule, chink_rule],
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... chunk_label='NP')
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>>> chunked_text = chunk_parser.parse(unchunked_text)
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>>> print(chunked_text)
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(S
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(NP The/DT cat/NN)
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sat/VBD
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on/IN
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(NP the/DT mat/NN the/DT dog/NN)
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chewed/VBD
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./.)
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>>> assert chunked_text == chunk_parser.parse(list(unchunked_text))
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>>> chunkscore = ChunkScore()
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>>> chunkscore.score(gold_chunked_text, chunked_text)
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>>> chunkscore.precision()
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0.5
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>>> print(chunkscore.recall())
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0.33333333...
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>>> print(chunkscore.f_measure())
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0.4
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>>> for chunk in sorted(chunkscore.missed()): print(chunk)
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(NP the/DT dog/NN)
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(NP the/DT mat/NN)
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>>> for chunk in chunkscore.incorrect(): print(chunk)
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(NP the/DT mat/NN the/DT dog/NN)
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>>> chunk_parser = RegexpChunkParser([chunk_rule, chink_rule, split_rule],
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... chunk_label='NP')
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>>> chunked_text = chunk_parser.parse(unchunked_text, trace=True)
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# Input:
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<DT> <NN> <VBD> <IN> <DT> <NN> <DT> <NN> <VBD> <.>
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# Chunk everything:
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{<DT> <NN> <VBD> <IN> <DT> <NN> <DT> <NN> <VBD> <.>}
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# Chink on verbs/prepositions:
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{<DT> <NN>} <VBD> <IN> {<DT> <NN> <DT> <NN>} <VBD> <.>
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# Split successive determiner/noun pairs:
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{<DT> <NN>} <VBD> <IN> {<DT> <NN>}{<DT> <NN>} <VBD> <.>
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>>> print(chunked_text)
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(S
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(NP The/DT cat/NN)
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sat/VBD
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on/IN
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(NP the/DT mat/NN)
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(NP the/DT dog/NN)
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chewed/VBD
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./.)
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>>> chunkscore = ChunkScore()
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>>> chunkscore.score(gold_chunked_text, chunked_text)
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>>> chunkscore.precision()
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1.0
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>>> chunkscore.recall()
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1.0
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>>> chunkscore.f_measure()
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1.0
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>>> chunkscore.missed()
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[]
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>>> chunkscore.incorrect()
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[]
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>>> chunk_parser.rules() # doctest: +NORMALIZE_WHITESPACE
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[<ChunkRule: '<.*>+'>, <ChinkRule: '<VBD|IN|\\.>'>,
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<SplitRule: '<DT><NN>', '<DT><NN>'>]
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Printing parsers:
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>>> print(repr(chunk_parser))
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<RegexpChunkParser with 3 rules>
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>>> print(chunk_parser)
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RegexpChunkParser with 3 rules:
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Chunk everything
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<ChunkRule: '<.*>+'>
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Chink on verbs/prepositions
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<ChinkRule: '<VBD|IN|\\.>'>
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Split successive determiner/noun pairs
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<SplitRule: '<DT><NN>', '<DT><NN>'>
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Regression Tests
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~~~~~~~~~~~~~~~~
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ChunkParserI
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------------
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`ChunkParserI` is an abstract interface -- it is not meant to be
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instantiated directly.
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>>> ChunkParserI().parse([])
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Traceback (most recent call last):
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. . .
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NotImplementedError
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ChunkString
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-----------
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ChunkString can be built from a tree of tagged tuples, a tree of
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trees, or a mixed list of both:
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>>> t1 = Tree('S', [('w%d' % i, 't%d' % i) for i in range(10)])
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>>> t2 = Tree('S', [Tree('t0', []), Tree('t1', ['c1'])])
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>>> t3 = Tree('S', [('w0', 't0'), Tree('t1', ['c1'])])
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>>> ChunkString(t1)
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<ChunkString: '<t0><t1><t2><t3><t4><t5><t6><t7><t8><t9>'>
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>>> ChunkString(t2)
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<ChunkString: '<t0><t1>'>
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>>> ChunkString(t3)
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<ChunkString: '<t0><t1>'>
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Other values generate an error:
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>>> ChunkString(Tree('S', ['x']))
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Traceback (most recent call last):
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. . .
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ValueError: chunk structures must contain tagged tokens or trees
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The `str()` for a chunk string adds spaces to it, which makes it line
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up with `str()` output for other chunk strings over the same
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underlying input.
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>>> cs = ChunkString(t1)
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>>> print(cs)
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<t0> <t1> <t2> <t3> <t4> <t5> <t6> <t7> <t8> <t9>
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>>> cs.xform('<t3>', '{<t3>}')
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>>> print(cs)
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<t0> <t1> <t2> {<t3>} <t4> <t5> <t6> <t7> <t8> <t9>
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The `_verify()` method makes sure that our transforms don't corrupt
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the chunk string. By setting debug_level=2, `_verify()` will be
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called at the end of every call to `xform`.
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>>> cs = ChunkString(t1, debug_level=3)
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>>> # tag not marked with <...>:
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>>> cs.xform('<t3>', 't3')
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Traceback (most recent call last):
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. . .
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ValueError: Transformation generated invalid chunkstring:
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<t0><t1><t2>t3<t4><t5><t6><t7><t8><t9>
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>>> # brackets not balanced:
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>>> cs.xform('<t3>', '{<t3>')
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Traceback (most recent call last):
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. . .
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ValueError: Transformation generated invalid chunkstring:
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<t0><t1><t2>{<t3><t4><t5><t6><t7><t8><t9>
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>>> # nested brackets:
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>>> cs.xform('<t3><t4><t5>', '{<t3>{<t4>}<t5>}')
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Traceback (most recent call last):
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. . .
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ValueError: Transformation generated invalid chunkstring:
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<t0><t1><t2>{<t3>{<t4>}<t5>}<t6><t7><t8><t9>
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>>> # modified tags:
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>>> cs.xform('<t3>', '<t9>')
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Traceback (most recent call last):
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. . .
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ValueError: Transformation generated invalid chunkstring: tag changed
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>>> # added tags:
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>>> cs.xform('<t9>', '<t9><t10>')
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Traceback (most recent call last):
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. . .
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ValueError: Transformation generated invalid chunkstring: tag changed
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Chunking Rules
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--------------
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Test the different rule constructors & __repr__ methods:
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>>> r1 = RegexpChunkRule('<a|b>'+ChunkString.IN_CHINK_PATTERN,
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... '{<a|b>}', 'chunk <a> and <b>')
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>>> r2 = RegexpChunkRule(re.compile('<a|b>'+ChunkString.IN_CHINK_PATTERN),
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... '{<a|b>}', 'chunk <a> and <b>')
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>>> r3 = ChunkRule('<a|b>', 'chunk <a> and <b>')
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>>> r4 = ChinkRule('<a|b>', 'chink <a> and <b>')
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>>> r5 = UnChunkRule('<a|b>', 'unchunk <a> and <b>')
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>>> r6 = MergeRule('<a>', '<b>', 'merge <a> w/ <b>')
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>>> r7 = SplitRule('<a>', '<b>', 'split <a> from <b>')
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>>> r8 = ExpandLeftRule('<a>', '<b>', 'expand left <a> <b>')
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>>> r9 = ExpandRightRule('<a>', '<b>', 'expand right <a> <b>')
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>>> for rule in r1, r2, r3, r4, r5, r6, r7, r8, r9:
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... print(rule)
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<RegexpChunkRule: '<a|b>(?=[^\\}]*(\\{|$))'->'{<a|b>}'>
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<RegexpChunkRule: '<a|b>(?=[^\\}]*(\\{|$))'->'{<a|b>}'>
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<ChunkRule: '<a|b>'>
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<ChinkRule: '<a|b>'>
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<UnChunkRule: '<a|b>'>
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<MergeRule: '<a>', '<b>'>
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<SplitRule: '<a>', '<b>'>
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<ExpandLeftRule: '<a>', '<b>'>
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<ExpandRightRule: '<a>', '<b>'>
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`tag_pattern2re_pattern()` complains if the tag pattern looks problematic:
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>>> tag_pattern2re_pattern('{}')
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Traceback (most recent call last):
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. . .
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ValueError: Bad tag pattern: '{}'
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RegexpChunkParser
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-----------------
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A warning is printed when parsing an empty sentence:
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>>> parser = RegexpChunkParser([ChunkRule('<a>', '')])
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>>> parser.parse(Tree('S', []))
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Warning: parsing empty text
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Tree('S', [])
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RegexpParser
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------------
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>>> parser = RegexpParser('''
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... NP: {<DT>? <JJ>* <NN>*} # NP
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... P: {<IN>} # Preposition
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... V: {<V.*>} # Verb
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... PP: {<P> <NP>} # PP -> P NP
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... VP: {<V> <NP|PP>*} # VP -> V (NP|PP)*
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... ''')
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>>> print(repr(parser))
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<chunk.RegexpParser with 5 stages>
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>>> print(parser)
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chunk.RegexpParser with 5 stages:
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RegexpChunkParser with 1 rules:
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NP <ChunkRule: '<DT>? <JJ>* <NN>*'>
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RegexpChunkParser with 1 rules:
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Preposition <ChunkRule: '<IN>'>
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RegexpChunkParser with 1 rules:
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Verb <ChunkRule: '<V.*>'>
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RegexpChunkParser with 1 rules:
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PP -> P NP <ChunkRule: '<P> <NP>'>
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RegexpChunkParser with 1 rules:
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VP -> V (NP|PP)* <ChunkRule: '<V> <NP|PP>*'>
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>>> print(parser.parse(unchunked_text, trace=True))
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# Input:
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<DT> <NN> <VBD> <IN> <DT> <NN> <DT> <NN> <VBD> <.>
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# NP:
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{<DT> <NN>} <VBD> <IN> {<DT> <NN>}{<DT> <NN>} <VBD> <.>
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# Input:
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<NP> <VBD> <IN> <NP> <NP> <VBD> <.>
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# Preposition:
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<NP> <VBD> {<IN>} <NP> <NP> <VBD> <.>
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# Input:
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<NP> <VBD> <P> <NP> <NP> <VBD> <.>
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# Verb:
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<NP> {<VBD>} <P> <NP> <NP> {<VBD>} <.>
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# Input:
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<NP> <V> <P> <NP> <NP> <V> <.>
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# PP -> P NP:
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<NP> <V> {<P> <NP>} <NP> <V> <.>
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# Input:
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<NP> <V> <PP> <NP> <V> <.>
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# VP -> V (NP|PP)*:
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<NP> {<V> <PP> <NP>}{<V>} <.>
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(S
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(NP The/DT cat/NN)
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(VP
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(V sat/VBD)
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(PP (P on/IN) (NP the/DT mat/NN))
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(NP the/DT dog/NN))
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(VP (V chewed/VBD))
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./.)
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Test parsing of other rule types:
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>>> print(RegexpParser('''
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... X:
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... }<a><b>{ # chink rule
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... <a>}{<b> # split rule
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... <a>{}<b> # merge rule
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... <a>{<b>}<c> # chunk rule w/ context
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... '''))
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chunk.RegexpParser with 1 stages:
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RegexpChunkParser with 4 rules:
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chink rule <ChinkRule: '<a><b>'>
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split rule <SplitRule: '<a>', '<b>'>
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merge rule <MergeRule: '<a>', '<b>'>
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chunk rule w/ context <ChunkRuleWithContext: '<a>', '<b>', '<c>'>
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Illegal patterns give an error message:
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>>> print(RegexpParser('X: {<foo>} {<bar>}'))
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Traceback (most recent call last):
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. . .
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ValueError: Illegal chunk pattern: {<foo>} {<bar>}
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