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spaCy/examples/matcher_example.py
Matthew Honnibal a6e2a44283 * Add clarifying comment
2015-09-27 18:17:41 +10:00

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from __future__ import unicode_literals, print_function
import spacy.en
import spacy.matcher
from spacy.attrs import ORTH, TAG, LOWER, IS_ALPHA, FLAG63
import plac
def main():
nlp = spacy.en.English()
example = u"I prefer Siri to Google Now. I'll google now to find out how the google now service works."
before = nlp(example)
print("Before")
for ent in before.ents:
print(ent.text, ent.label_, [w.tag_ for w in ent])
# Output:
# Google ORG [u'NNP']
# google ORG [u'VB']
# google ORG [u'NNP']
nlp.matcher.add(
"GoogleNow", # Entity ID: Not really used at the moment.
"PRODUCT", # Entity type: should be one of the types in the NER data
{"wiki_en": "Google_Now"}, # Arbitrary attributes. Currently unused.
[ # List of patterns that can be Surface Forms of the entity
# This Surface Form matches "Google Now", verbatim
[ # Each Surface Form is a list of Token Specifiers.
{ # This Token Specifier matches tokens whose orth field is "Google"
ORTH: "Google"
},
{ # This Token Specifier matches tokens whose orth field is "Now"
ORTH: "Now"
}
],
[ # This Surface Form matches "google now", verbatim, and requires
# "google" to have the NNP tag. This helps prevent the pattern from
# matching cases like "I will google now to look up the time"
{
ORTH: "google",
TAG: "NNP"
},
{
ORTH: "now"
}
]
]
)
after = nlp(example)
print("After")
for ent in after.ents:
print(ent.text, ent.label_, [w.tag_ for w in ent])
# Output
# Google Now PRODUCT [u'NNP', u'RB']
# google ORG [u'VB']
# google now PRODUCT [u'NNP', u'RB']
#
# You can customize attribute values in the lexicon, and then refer to the
# new attributes in your Token Specifiers.
# This is particularly good for word-set membership.
#
australian_capitals = ['Brisbane', 'Sydney', 'Canberra', 'Melbourne', 'Hobart',
'Darwin', 'Adelaide', 'Perth']
# Internally, the tokenizer immediately maps each token to a pointer to a
# LexemeC struct. These structs hold various features, e.g. the integer IDs
# of the normalized string forms.
# For our purposes, the key attribute is a 64-bit integer, used as a bit field.
# spaCy currently only uses 12 of the bits for its built-in features, so
# the others are available for use. It's best to use the higher bits, as
# future versions of spaCy may add more flags. For instance, we might add
# a built-in IS_MONTH flag, taking up FLAG13. So, we bind our user-field to
# FLAG63 here.
is_australian_capital = FLAG63
# Now we need to set the flag value. It's False on all tokens by default,
# so we just need to set it to True for the tokens we want.
# Here we iterate over the strings, and set it on only the literal matches.
for string in australian_capitals:
lexeme = nlp.vocab[string]
lexeme.set_flag(is_australian_capital, True)
print('Sydney', nlp.vocab[u'Sydney'].check_flag(is_australian_capital))
print('sydney', nlp.vocab[u'sydney'].check_flag(is_australian_capital))
# If we want case-insensitive matching, we have to be a little bit more
# round-about, as there's no case-insensitive index to the vocabulary. So
# we have to iterate over the vocabulary.
# We'll be looking up attribute IDs in this set a lot, so it's good to pre-build it
target_ids = {nlp.vocab.strings[s.lower()] for s in australian_capitals}
for lexeme in nlp.vocab:
if lexeme.lower in target_ids:
lexeme.set_flag(is_australian_capital, True)
print('Sydney', nlp.vocab[u'Sydney'].check_flag(is_australian_capital))
print('sydney', nlp.vocab[u'sydney'].check_flag(is_australian_capital))
print('SYDNEY', nlp.vocab[u'SYDNEY'].check_flag(is_australian_capital))
# Output
# Sydney True
# sydney False
# Sydney True
# sydney True
# SYDNEY True
#
# The key thing to note here is that we're setting these attributes once,
# over the vocabulary --- and then reusing them at run-time. This means the
# amortized complexity of anything we do this way is going to be O(1). You
# can match over expressions that need to have sets with tens of thousands
# of values, e.g. "all the street names in Germany", and you'll still have
# O(1) complexity. Most regular expression algorithms don't scale well to
# this sort of problem.
#
# Now, let's use this in a pattern
nlp.matcher.add("AuCitySportsTeam", "ORG", {},
[
[
{LOWER: "the"},
{is_australian_capital: True},
{TAG: "NNS"}
],
[
{LOWER: "the"},
{is_australian_capital: True},
{TAG: "NNPS"}
],
[
{LOWER: "the"},
{IS_ALPHA: True}, # Allow a word in between, e.g. The Western Sydney
{is_australian_capital: True},
{TAG: "NNS"}
],
[
{LOWER: "the"},
{IS_ALPHA: True}, # Allow a word in between, e.g. The Western Sydney
{is_australian_capital: True},
{TAG: "NNPS"}
]
])
doc = nlp(u'The pattern should match the Brisbane Broncos and the South Darwin Spiders, but not the Colorado Boulders')
for ent in doc.ents:
print(ent.text, ent.label_)
# Output
# the Brisbane Broncos ORG
# the South Darwin Spiders ORG
# Output
# Before
# Google ORG [u'NNP']
# google ORG [u'VB']
# google ORG [u'NNP']
# After
# Google Now PRODUCT [u'NNP', u'RB']
# google ORG [u'VB']
# google now PRODUCT [u'NNP', u'RB']
# Sydney True
# sydney False
# Sydney True
# sydney True
# SYDNEY True
# the Brisbane Broncos ORG
# the South Darwin Spiders ORG
if __name__ == '__main__':
main()
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