Add customizing tokenizer and training workflow

This commit is contained in:
Ines Montani 2016-11-05 20:40:11 +01:00
parent 5e4e5b600f
commit c20abc8a6d
3 changed files with 374 additions and 2 deletions

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@ -12,7 +12,9 @@
"Custom pipelines": "customizing-pipeline", "Custom pipelines": "customizing-pipeline",
"Rule-based matching": "rule-based-matching", "Rule-based matching": "rule-based-matching",
"Word vectors": "word-vectors-similarities", "Word vectors": "word-vectors-similarities",
"Deep learning": "deep-learning" "Deep learning": "deep-learning",
"Custom tokenization": "customizing-tokenizer",
"Training": "training"
}, },
"Examples": { "Examples": {
"Tutorials": "tutorials", "Tutorials": "tutorials",
@ -35,7 +37,8 @@
}, },
"customizing-pipeline": { "customizing-pipeline": {
"title": "Customizing the pipeline" "title": "Customizing the pipeline",
"next": "customizing-tokenizer"
}, },
"processing-text": { "processing-text": {
@ -63,6 +66,15 @@
"title": "Hooking a deep learning model into spaCy" "title": "Hooking a deep learning model into spaCy"
}, },
"customizing-tokenizer": {
"title": "Customizing the tokenizer",
"next": "training"
},
"training": {
"title": "Training the tagger, parser and entity recognizer"
},
"showcase": { "showcase": {
"title": "Showcase", "title": "Showcase",

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//- <U+1F4AB> DOCS > USAGE > TOKENIZER
include ../../_includes/_mixins
p
| Tokenization is the task of splitting a text into meaningful segments,
| called #[em tokens]. The input to the tokenizer is a unicode text, and
| the output is a #[+api("doc") #[code Doc]] object. To construct a
| #[code Doc] object, you need a #[+api("vocab") #[code Vocab]] instance,
| a sequence of #[code word] strings, and optionally a sequence of
| #[code spaces] booleans, which allow you to maintain alignment of the
| tokens into the original string.
+aside("See Also")
| If you haven't read up on spaCy's #[+a("data-model") data model] yet,
| you should probably have a look. The main point to keep in mind is that
| spaCy's #[code Doc] doesn't copy or refer to the original string. The
| string is reconstructed from the tokens when required.
+h(2, "special-cases") Adding special case tokenization rules
p
| Most domains have at least some idiosyncracies that require custom
| tokenization rules. Here's how to add a special case rule to an existing
| #[+api("tokenizer") #[code Tokenizer]] instance:
+code.
nlp = spacy.load('en')
assert [w.text for w in nlp(u'gimme that')] == [u'gimme', u'that']
nlp.tokenizer.add_special_case(u'gimme',
[
{
ORTH: u'gim',
LEMMA: u'give',
POS: u'VERB'},
{
ORTH: u'me'}])
assert [w.text for w in nlp(u'gimme that')] == [u'gim', u'me', u'that']
assert [w.lemma_ for w in nlp(u'gimme that')] == [u'give', u'-PRON-', u'that']
p
| The special case doesn't have to match an entire whitespace-delimited
| substring. The tokenizer will incrementally split off punctuation, and
| keep looking up the remaining substring:
+code.
assert 'gimme' not in [w.text for w in nlp(u'gimme!')]
assert 'gimme' not in [w.text for w in nlp(u'("...gimme...?")')]
p
| The special case rules have precedence over the punctuation splitting:
+code.
nlp.tokenizer.add_special_case(u"...gimme...?",
[{
ORTH: u'...gimme...?", LEMMA: "give", TAG: "VB"}])
assert len(nlp(u'...gimme...?')) == 1
p
| Because the special-case rules allow you to set arbitrary token
| attributes, such as the part-of-speech, lemma, etc, they make a good
| mechanism for arbitrary fix-up rules. Having this logic live in the
| tokenizer isn't very satisfying from a design perspective, however, so
| the API may eventually be exposed on the
| #[+api("language") #[code Language]] class itself.
+h(2, "how-tokenizer-works") How spaCy's tokenizer works
p
| spaCy introduces a novel tokenization algorithm, that gives a better
| balance between performance, ease of definition, and ease of alignment
| into the original string.
p
| After consuming a prefix or infix, we consult the special cases again.
| We want the special cases to handle things like "don't" in English, and
| we want the same rule to work for "(don't)!". We do this by splitting
| off the open bracket, then the exclamation, then the close bracket, and
| finally matching the special-case. Here's an implementation of the
| algorithm in Python, optimized for readability rather than performance:
+code.
def tokenizer_pseudo_code(text, find_prefix, find_suffix,
find_infixes, special_cases):
tokens = []
for substring in text.split(' '):
suffixes = []
while substring:
if substring in special_cases:
tokens.extend(special_cases[substring])
substring = ''
elif find_prefix(substring) is not None:
split = find_prefix(substring)
tokens.append(substring[:split])
substring = substring[split:]
elif find_suffix(substring) is not None:
split = find_suffix(substring)
suffixes.append(substring[split:])
substring = substring[:split]
elif find_infixes(substring):
infixes = find_infixes(substring)
offset = 0
for match in infixes:
tokens.append(substring[i : match.start()])
tokens.append(substring[match.start() : match.end()])
offset = match.end()
substring = substring[offset:]
else:
tokens.append(substring)
substring = ''
tokens.extend(suffixes)
return tokens
p
| The algorithm can be summarized as follows:
+list("numbers")
+item Iterate over space-separated substrings
+item
| Check whether we have an explicitly defined rule for this substring.
| If we do, use it.
+item Otherwise, try to consume a prefix.
+item
| If we consumed a prefix, go back to the beginning of the loop, so
| that special-cases always get priority.
+item If we didn't consume a prefix, try to consume a suffix.
+item
| If we can't consume a prefix or suffix, look for "infixes" — stuff
| like hyphens etc.
+item Once we can't consume any more of the string, handle it as a single token.
+h(2, "native-tokenizers") Customizing spaCy's Tokenizer class
p
| Let's imagine you wanted to create a tokenizer for a new language. There
| are four things you would need to define:
+list("numbers")
+item
| A dictionary of #[strong special cases]. This handles things like
| contractions, units of measurement, emoticons, certain
| abbreviations, etc.
+item
| A function #[code prefix_search], to handle
| #[strong preceding punctuation], such as open quotes, open brackets,
| etc
+item
| A function #[code suffix_search], to handle
| #[strong succeeding punctuation], such as commas, periods, close
| quotes, etc.
+item
| A function #[code infixes_finditer], to handle non-whitespace
| separators, such as hyphens etc.
p
| You shouldn't usually need to create a #[code Tokenizer] subclass.
| Standard usage is to use #[code re.compile()] to build a regular
| expression object, and pass its #[code .search()] and
| #[code .finditer()] methods:
+code.
import re
from spacy.tokenizer import Tokenizer
prefix_re = re.compile(r'''[\[\(&quot;']''')
suffix_re = re.compile(r'''[\]\)&quot;']''')
def create_tokenizer(nlp):
return Tokenizer(nlp.vocab,
prefix_search=prefix_re.search,
suffix_search=suffix_re.search)
nlp = spacy.load('en', tokenizer=create_make_doc)
p
| If you need to subclass the tokenizer instead, the relevant methods to
| specialize are #[code find_prefix], #[code find_suffix] and
| #[code find_infix].
+h(2, "custom-tokenizer") Hooking an arbitrary tokenizer into the pipeline
p
| You can pass a custom tokenizer using the #[code make_doc] keyword, when
| you're creating the pipeline:
+code.
import spacy
nlp = spacy.load('en', make_doc=my_tokenizer)
p
| However, this approach often leaves us with a chicken-and-egg problem.
| To construct the tokenizer, we usually want attributes of the #[code nlp]
| pipeline. Specifically, we want the tokenizer to hold a reference to the
| pipeline's vocabulary object. Let's say we have the following class as
| our tokenizer:
+code.
import spacy
from spacy.tokens import Doc
class WhitespaceTokenizer(object):
def __init__(self, nlp):
self.vocab = nlp.vocab
def __call__(self, text):
words = text.split(' ')
# All tokens 'own' a subsequent space character in this tokenizer
spaces = [True] * len(word)
return Doc(self.vocab, words=words, spaces=spaces)
p
| As you can see, we need a #[code vocab] instance to construct this — but
| we won't get the #[code vocab] instance until we get back the #[code nlp]
| object from #[code spacy.load()]. The simplest solution is to build the
| object in two steps:
+code.
nlp = spacy.load('en')
nlp.make_doc = WhitespaceTokenizer(nlp)
p
| You can instead pass the class to the #[code create_make_doc] keyword,
| which is invoked as callback once the #[code nlp] object is ready:
+code.
nlp = spacy.load('en', create_make_doc=WhitespaceTokenizer)
p
| Finally, you can of course create your own subclasses, and create a bound
| #[code make_doc] method. The disadvantage of this approach is that spaCy
| uses inheritance to give each language-specific pipeline its own class.
| If you're working with multiple languages, a naive solution will
| therefore require one custom class per language you're working with.
| This might be at least annoying. You may be able to do something more
| generic by doing some clever magic with metaclasses or mixins, if that's
| the sort of thing you're into.

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include ../../_includes/_mixins
p
| This tutorial describes how to train new statistical models for spaCy's
| part-of-speech tagger, named entity recognizer and dependency parser.
p
| I'll start with some quick code examples, that describe how to train
| each model. I'll then provide a bit of background about the algorithms,
| and explain how the data and feature templates work.
+h(2, "train-pos-tagger") Training the part-of-speech tagger
+code.
from spacy.vocab import Vocab
from spacy.pipeline import Tagger
from spacy.tokens import Doc
vocab = Vocab(tag_map={'N': {'pos': 'NOUN'}, 'V': {'pos': 'VERB'}})
tagger = Tagger(vocab)
doc = Doc(vocab, words=['I', 'like', 'stuff'])
tagger.update(doc, ['N', 'V', 'N'])
tagger.model.end_training()
p
+button(gh("spaCy", "examples/training/train_tagger.py"), false, "secondary") Full example
+h(2, "train-entity") Training the named entity recognizer
+code.
from spacy.vocab import Vocab
from spacy.pipeline import EntityRecognizer
from spacy.tokens import Doc
vocab = Vocab()
entity = EntityRecognizer(vocab, entity_types=['PERSON', 'LOC'])
doc = Doc(vocab, words=['Who', 'is', 'Shaka', 'Khan', '?'])
entity.update(doc, ['O', 'O', 'B-PERSON', 'L-PERSON', 'O'])
entity.model.end_training()
p
+button(gh("spaCy", "examples/training/train_ner.py"), false, "secondary") Full example
+h(2, "train-entity") Training the dependency parser
+code.
from spacy.vocab import Vocab
from spacy.pipeline import DependencyParser
from spacy.tokens import Doc
vocab = Vocab()
parser = DependencyParser(vocab, labels=['nsubj', 'compound', 'dobj', 'punct'])
doc = Doc(vocab, words=['Who', 'is', 'Shaka', 'Khan', '?'])
parser.update(doc, [(1, 'nsubj'), (1, 'ROOT'), (3, 'compound'), (1, 'dobj'),
(1, 'punct')])
parser.model.end_training()
p
+button(gh("spaCy", "examples/training/train_parser.py"), false, "secondary") Full example
+h(2, 'feature-templates') Customizing the feature extraction
p
| spaCy currently uses linear models for the tagger, parser and entity
| recognizer, with weights learned using the
| #[+a("https://explosion.ai/blog/part-of-speech-pos-tagger-in-python") Averaged Perceptron algorithm].
p
| Because it's a linear model, it's important for accuracy to build
| conjunction features out of the atomic predictors. Let's say you have
| two atomic predictors asking, "What is the part-of-speech of the
| previous token?", and "What is the part-of-speech of the previous
| previous token?". These ppredictors will introduce a number of features,
| e.g. #[code Prev-pos=NN], #[code Prev-pos=VBZ], etc. A conjunction
| template introduces features such as #[code Prev-pos=NN&Prev-pos=VBZ].
p
| The feature extraction proceeds in two passes. In the first pass, we
| fill an array with the values of all of the atomic predictors. In the
| second pass, we iterate over the feature templates, and fill a small
| temporary array with the predictors that will be combined into a
| conjunction feature. Finally, we hash this array into a 64-bit integer,
| using the MurmurHash algorithm. You can see this at work in the
| #[+a(gh("thinc", "thinc/linear/features.pyx", "94dbe06fd3c8f24d86ab0f5c7984e52dbfcdc6cb")) #[code thinc.linear.features]] module.
p
| It's very easy to change the feature templates, to create novel
| combinations of the existing atomic predictors. There's currently no API
| available to add new atomic predictors, though. You'll have to create a
| subclass of the model, and write your own #[code set_featuresC] method.
p
| The feature templates are passed in using the #[code features] keyword
| argument to the constructors of the #[+api("tagger") #[code Tagger]],
| #[+api("dependencyparser") #[code DependencyParser]] and
| #[+api("entityrecognizer") #[code EntityRecognizer]]:
+code.
from spacy.vocab import Vocab
from spacy.pipeline import Tagger
from spacy.tagger import P2_orth, P1_orth
from spacy.tagger import P2_cluster, P1_cluster, W_orth, N1_orth, N2_orth
vocab = Vocab(tag_map={'N': {'pos': 'NOUN'}, 'V': {'pos': 'VERB'}})
tagger = Tagger(vocab, features=[(P2_orth, P2_cluster), (P1_orth, P1_cluster),
(P2_orth,), (P1_orth,), (W_orth,),
(N1_orth,), (N2_orth,)])
p
| Custom feature templates can be passed to the #[code DependencyParser]
| and #[code EntityRecognizer] as well, also using the #[code features]
| keyword argument of the constructor.