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ddffd09602
* add an anchor to the trainable lemmatizer section * add requirement for morphologizer,tagger to rule-based lemmatizer * morphologizer only
2026 lines
81 KiB
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2026 lines
81 KiB
Plaintext
---
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title: Linguistic Features
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next: /usage/rule-based-matching
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menu:
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- ['POS Tagging', 'pos-tagging']
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- ['Morphology', 'morphology']
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- ['Lemmatization', 'lemmatization']
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- ['Dependency Parse', 'dependency-parse']
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- ['Named Entities', 'named-entities']
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- ['Entity Linking', 'entity-linking']
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- ['Tokenization', 'tokenization']
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- ['Merging & Splitting', 'retokenization']
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- ['Sentence Segmentation', 'sbd']
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- ['Mappings & Exceptions', 'mappings-exceptions']
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- ['Vectors & Similarity', 'vectors-similarity']
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- ['Language Data', 'language-data']
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---
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Processing raw text intelligently is difficult: most words are rare, and it's
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common for words that look completely different to mean almost the same thing.
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The same words in a different order can mean something completely different.
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Even splitting text into useful word-like units can be difficult in many
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languages. While it's possible to solve some problems starting from only the raw
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characters, it's usually better to use linguistic knowledge to add useful
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information. That's exactly what spaCy is designed to do: you put in raw text,
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and get back a [`Doc`](/api/doc) object, that comes with a variety of
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annotations.
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## Part-of-speech tagging {id="pos-tagging",model="tagger, parser"}
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<PosDeps101 />
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<Infobox title="Part-of-speech tag scheme" emoji="📖">
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For a list of the fine-grained and coarse-grained part-of-speech tags assigned
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by spaCy's models across different languages, see the label schemes documented
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in the [models directory](/models).
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</Infobox>
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## Morphology {id="morphology"}
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Inflectional morphology is the process by which a root form of a word is
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modified by adding prefixes or suffixes that specify its grammatical function
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but do not change its part-of-speech. We say that a **lemma** (root form) is
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**inflected** (modified/combined) with one or more **morphological features** to
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create a surface form. Here are some examples:
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| Context | Surface | Lemma | POS | Morphological Features |
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| ---------------------------------------- | ------- | ----- | ------ | ---------------------------------------- |
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| I was reading the paper | reading | read | `VERB` | `VerbForm=Ger` |
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| I don't watch the news, I read the paper | read | read | `VERB` | `VerbForm=Fin`, `Mood=Ind`, `Tense=Pres` |
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| I read the paper yesterday | read | read | `VERB` | `VerbForm=Fin`, `Mood=Ind`, `Tense=Past` |
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Morphological features are stored in the
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[`MorphAnalysis`](/api/morphology#morphanalysis) under `Token.morph`, which
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allows you to access individual morphological features.
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> #### 📝 Things to try
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>
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> 1. Change "I" to "She". You should see that the morphological features change
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> and express that it's a pronoun in the third person.
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> 2. Inspect `token.morph` for the other tokens.
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```python {executable="true"}
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import spacy
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nlp = spacy.load("en_core_web_sm")
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print("Pipeline:", nlp.pipe_names)
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doc = nlp("I was reading the paper.")
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token = doc[0] # 'I'
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print(token.morph) # 'Case=Nom|Number=Sing|Person=1|PronType=Prs'
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print(token.morph.get("PronType")) # ['Prs']
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```
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### Statistical morphology {id="morphologizer",version="3",model="morphologizer"}
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spaCy's statistical [`Morphologizer`](/api/morphologizer) component assigns the
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morphological features and coarse-grained part-of-speech tags as `Token.morph`
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and `Token.pos`.
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```python {executable="true"}
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import spacy
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nlp = spacy.load("de_core_news_sm")
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doc = nlp("Wo bist du?") # English: 'Where are you?'
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print(doc[2].morph) # 'Case=Nom|Number=Sing|Person=2|PronType=Prs'
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print(doc[2].pos_) # 'PRON'
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```
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### Rule-based morphology {id="rule-based-morphology"}
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For languages with relatively simple morphological systems like English, spaCy
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can assign morphological features through a rule-based approach, which uses the
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**token text** and **fine-grained part-of-speech tags** to produce
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coarse-grained part-of-speech tags and morphological features.
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1. The part-of-speech tagger assigns each token a **fine-grained part-of-speech
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tag**. In the API, these tags are known as `Token.tag`. They express the
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part-of-speech (e.g. verb) and some amount of morphological information, e.g.
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that the verb is past tense (e.g. `VBD` for a past tense verb in the Penn
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Treebank) .
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2. For words whose coarse-grained POS is not set by a prior process, a
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[mapping table](#mappings-exceptions) maps the fine-grained tags to a
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coarse-grained POS tags and morphological features.
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```python {executable="true"}
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import spacy
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nlp = spacy.load("en_core_web_sm")
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doc = nlp("Where are you?")
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print(doc[2].morph) # 'Case=Nom|Person=2|PronType=Prs'
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print(doc[2].pos_) # 'PRON'
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```
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## Lemmatization {id="lemmatization",version="3"}
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spaCy provides two pipeline components for lemmatization:
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1. The [`Lemmatizer`](/api/lemmatizer) component provides lookup and rule-based
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lemmatization methods in a configurable component. An individual language can
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extend the `Lemmatizer` as part of its [language data](#language-data).
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2. The [`EditTreeLemmatizer`](/api/edittreelemmatizer)
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<Tag variant="new">3.3</Tag> component provides a trainable lemmatizer.
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```python {executable="true"}
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import spacy
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# English pipelines include a rule-based lemmatizer
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nlp = spacy.load("en_core_web_sm")
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lemmatizer = nlp.get_pipe("lemmatizer")
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print(lemmatizer.mode) # 'rule'
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doc = nlp("I was reading the paper.")
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print([token.lemma_ for token in doc])
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# ['I', 'be', 'read', 'the', 'paper', '.']
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```
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<Infobox title="Changed in v3.0" variant="warning">
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Unlike spaCy v2, spaCy v3 models do _not_ provide lemmas by default or switch
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automatically between lookup and rule-based lemmas depending on whether a tagger
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is in the pipeline. To have lemmas in a `Doc`, the pipeline needs to include a
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[`Lemmatizer`](/api/lemmatizer) component. The lemmatizer component is
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configured to use a single mode such as `"lookup"` or `"rule"` on
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initialization. The `"rule"` mode requires `Token.pos` to be set by a previous
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component.
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</Infobox>
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The data for spaCy's lemmatizers is distributed in the package
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[`spacy-lookups-data`](https://github.com/explosion/spacy-lookups-data). The
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provided trained pipelines already include all the required tables, but if you
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are creating new pipelines, you'll probably want to install `spacy-lookups-data`
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to provide the data when the lemmatizer is initialized.
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### Lookup lemmatizer {id="lemmatizer-lookup"}
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For pipelines without a tagger or morphologizer, a lookup lemmatizer can be
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added to the pipeline as long as a lookup table is provided, typically through
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[`spacy-lookups-data`](https://github.com/explosion/spacy-lookups-data). The
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lookup lemmatizer looks up the token surface form in the lookup table without
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reference to the token's part-of-speech or context.
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```python
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# pip install -U %%SPACY_PKG_NAME[lookups]%%SPACY_PKG_FLAGS
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import spacy
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nlp = spacy.blank("sv")
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nlp.add_pipe("lemmatizer", config={"mode": "lookup"})
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```
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### Rule-based lemmatizer {id="lemmatizer-rule",model="morphologizer"}
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When training pipelines that include a component that assigns part-of-speech
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tags (a morphologizer or a tagger with a [POS mapping](#mappings-exceptions)), a
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rule-based lemmatizer can be added using rule tables from
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[`spacy-lookups-data`](https://github.com/explosion/spacy-lookups-data):
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```python
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# pip install -U %%SPACY_PKG_NAME[lookups]%%SPACY_PKG_FLAGS
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import spacy
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nlp = spacy.blank("de")
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# Morphologizer (note: model is not yet trained!)
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nlp.add_pipe("morphologizer")
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# Rule-based lemmatizer
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nlp.add_pipe("lemmatizer", config={"mode": "rule"})
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```
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The rule-based deterministic lemmatizer maps the surface form to a lemma in
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light of the previously assigned coarse-grained part-of-speech and morphological
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information, without consulting the context of the token. The rule-based
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lemmatizer also accepts list-based exception files. For English, these are
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acquired from [WordNet](https://wordnet.princeton.edu/).
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### Trainable lemmatizer {id="lemmatizer-train",model="trainable_lemmatizer"}
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The [`EditTreeLemmatizer`](/api/edittreelemmatizer) can learn form-to-lemma
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transformations from a training corpus that includes lemma annotations. This
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removes the need to write language-specific rules and can (in many cases)
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provide higher accuracies than lookup and rule-based lemmatizers.
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```python
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import spacy
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nlp = spacy.blank("de")
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nlp.add_pipe("trainable_lemmatizer", name="lemmatizer")
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```
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## Dependency Parsing {id="dependency-parse",model="parser"}
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spaCy features a fast and accurate syntactic dependency parser, and has a rich
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API for navigating the tree. The parser also powers the sentence boundary
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detection, and lets you iterate over base noun phrases, or "chunks". You can
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check whether a [`Doc`](/api/doc) object has been parsed by calling
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`doc.has_annotation("DEP")`, which checks whether the attribute `Token.dep` has
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been set returns a boolean value. If the result is `False`, the default sentence
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iterator will raise an exception.
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<Infobox title="Dependency label scheme" emoji="📖">
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For a list of the syntactic dependency labels assigned by spaCy's models across
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different languages, see the label schemes documented in the
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[models directory](/models).
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</Infobox>
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### Noun chunks {id="noun-chunks"}
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Noun chunks are "base noun phrases" – flat phrases that have a noun as their
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head. You can think of noun chunks as a noun plus the words describing the noun
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– for example, "the lavish green grass" or "the world’s largest tech fund". To
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get the noun chunks in a document, simply iterate over
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[`Doc.noun_chunks`](/api/doc#noun_chunks).
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```python {executable="true"}
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import spacy
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nlp = spacy.load("en_core_web_sm")
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doc = nlp("Autonomous cars shift insurance liability toward manufacturers")
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for chunk in doc.noun_chunks:
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print(chunk.text, chunk.root.text, chunk.root.dep_,
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chunk.root.head.text)
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```
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> - **Text:** The original noun chunk text.
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> - **Root text:** The original text of the word connecting the noun chunk to
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> the rest of the parse.
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> - **Root dep:** Dependency relation connecting the root to its head.
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> - **Root head text:** The text of the root token's head.
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| Text | root.text | root.dep\_ | root.head.text |
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| ------------------- | ------------- | ---------- | -------------- |
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| Autonomous cars | cars | `nsubj` | shift |
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| insurance liability | liability | `dobj` | shift |
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| manufacturers | manufacturers | `pobj` | toward |
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### Navigating the parse tree {id="navigating"}
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spaCy uses the terms **head** and **child** to describe the words **connected by
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a single arc** in the dependency tree. The term **dep** is used for the arc
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label, which describes the type of syntactic relation that connects the child to
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the head. As with other attributes, the value of `.dep` is a hash value. You can
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get the string value with `.dep_`.
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```python {executable="true"}
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import spacy
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nlp = spacy.load("en_core_web_sm")
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doc = nlp("Autonomous cars shift insurance liability toward manufacturers")
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for token in doc:
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print(token.text, token.dep_, token.head.text, token.head.pos_,
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[child for child in token.children])
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```
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> - **Text:** The original token text.
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> - **Dep:** The syntactic relation connecting child to head.
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> - **Head text:** The original text of the token head.
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> - **Head POS:** The part-of-speech tag of the token head.
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> - **Children:** The immediate syntactic dependents of the token.
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| Text | Dep | Head text | Head POS | Children |
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| ------------- | ---------- | --------- | -------- | ----------------------- |
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| Autonomous | `amod` | cars | `NOUN` | |
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| cars | `nsubj` | shift | `VERB` | Autonomous |
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| shift | `ROOT` | shift | `VERB` | cars, liability, toward |
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| insurance | `compound` | liability | `NOUN` | |
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| liability | `dobj` | shift | `VERB` | insurance |
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| toward | `prep` | shift | `NOUN` | manufacturers |
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| manufacturers | `pobj` | toward | `ADP` | |
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<Iframe
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title="displaCy visualization of dependencies and entities 2"
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src="/images/displacy-long2.html"
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height={450}
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/>
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Because the syntactic relations form a tree, every word has **exactly one
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head**. You can therefore iterate over the arcs in the tree by iterating over
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the words in the sentence. This is usually the best way to match an arc of
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interest – from below:
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```python {executable="true"}
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import spacy
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from spacy.symbols import nsubj, VERB
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nlp = spacy.load("en_core_web_sm")
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doc = nlp("Autonomous cars shift insurance liability toward manufacturers")
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# Finding a verb with a subject from below — good
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verbs = set()
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for possible_subject in doc:
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if possible_subject.dep == nsubj and possible_subject.head.pos == VERB:
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verbs.add(possible_subject.head)
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print(verbs)
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```
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If you try to match from above, you'll have to iterate twice. Once for the head,
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and then again through the children:
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```python
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# Finding a verb with a subject from above — less good
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verbs = []
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for possible_verb in doc:
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if possible_verb.pos == VERB:
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for possible_subject in possible_verb.children:
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if possible_subject.dep == nsubj:
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verbs.append(possible_verb)
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break
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```
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To iterate through the children, use the `token.children` attribute, which
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provides a sequence of [`Token`](/api/token) objects.
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#### Iterating around the local tree {id="navigating-around"}
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A few more convenience attributes are provided for iterating around the local
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tree from the token. [`Token.lefts`](/api/token#lefts) and
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[`Token.rights`](/api/token#rights) attributes provide sequences of syntactic
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children that occur before and after the token. Both sequences are in sentence
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order. There are also two integer-typed attributes,
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[`Token.n_lefts`](/api/token#n_lefts) and
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[`Token.n_rights`](/api/token#n_rights) that give the number of left and right
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children.
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```python {executable="true"}
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import spacy
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nlp = spacy.load("en_core_web_sm")
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doc = nlp("bright red apples on the tree")
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print([token.text for token in doc[2].lefts]) # ['bright', 'red']
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print([token.text for token in doc[2].rights]) # ['on']
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print(doc[2].n_lefts) # 2
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print(doc[2].n_rights) # 1
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```
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```python {executable="true"}
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import spacy
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nlp = spacy.load("de_core_news_sm")
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doc = nlp("schöne rote Äpfel auf dem Baum")
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print([token.text for token in doc[2].lefts]) # ['schöne', 'rote']
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print([token.text for token in doc[2].rights]) # ['auf']
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```
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You can get a whole phrase by its syntactic head using the
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[`Token.subtree`](/api/token#subtree) attribute. This returns an ordered
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sequence of tokens. You can walk up the tree with the
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[`Token.ancestors`](/api/token#ancestors) attribute, and check dominance with
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[`Token.is_ancestor`](/api/token#is_ancestor)
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> #### Projective vs. non-projective
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>
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> For the [default English pipelines](/models/en), the parse tree is
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> **projective**, which means that there are no crossing brackets. The tokens
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> returned by `.subtree` are therefore guaranteed to be contiguous. This is not
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> true for the German pipelines, which have many
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> [non-projective dependencies](https://explosion.ai/blog/german-model#word-order).
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```python {executable="true"}
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import spacy
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nlp = spacy.load("en_core_web_sm")
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doc = nlp("Credit and mortgage account holders must submit their requests")
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root = [token for token in doc if token.head == token][0]
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subject = list(root.lefts)[0]
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for descendant in subject.subtree:
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assert subject is descendant or subject.is_ancestor(descendant)
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print(descendant.text, descendant.dep_, descendant.n_lefts,
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descendant.n_rights,
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[ancestor.text for ancestor in descendant.ancestors])
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```
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| Text | Dep | n_lefts | n_rights | ancestors |
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| -------- | ---------- | ------- | -------- | -------------------------------- |
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| Credit | `nmod` | `0` | `2` | holders, submit |
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| and | `cc` | `0` | `0` | holders, submit |
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| mortgage | `compound` | `0` | `0` | account, Credit, holders, submit |
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| account | `conj` | `1` | `0` | Credit, holders, submit |
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| holders | `nsubj` | `1` | `0` | submit |
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Finally, the `.left_edge` and `.right_edge` attributes can be especially useful,
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because they give you the first and last token of the subtree. This is the
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easiest way to create a `Span` object for a syntactic phrase. Note that
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`.right_edge` gives a token **within** the subtree – so if you use it as the
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end-point of a range, don't forget to `+1`!
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```python {executable="true"}
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import spacy
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nlp = spacy.load("en_core_web_sm")
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doc = nlp("Credit and mortgage account holders must submit their requests")
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span = doc[doc[4].left_edge.i : doc[4].right_edge.i+1]
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with doc.retokenize() as retokenizer:
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retokenizer.merge(span)
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for token in doc:
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print(token.text, token.pos_, token.dep_, token.head.text)
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```
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| Text | POS | Dep | Head text |
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| ----------------------------------- | ------ | ------- | --------- |
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| Credit and mortgage account holders | `NOUN` | `nsubj` | submit |
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| must | `VERB` | `aux` | submit |
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| submit | `VERB` | `ROOT` | submit |
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| their | `ADJ` | `poss` | requests |
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| requests | `NOUN` | `dobj` | submit |
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The dependency parse can be a useful tool for **information extraction**,
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especially when combined with other predictions like
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[named entities](#named-entities). The following example extracts money and
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currency values, i.e. entities labeled as `MONEY`, and then uses the dependency
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parse to find the noun phrase they are referring to – for example `"Net income"`
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→ `"$9.4 million"`.
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```python {executable="true"}
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import spacy
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||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
# Merge noun phrases and entities for easier analysis
|
||
nlp.add_pipe("merge_entities")
|
||
nlp.add_pipe("merge_noun_chunks")
|
||
|
||
TEXTS = [
|
||
"Net income was $9.4 million compared to the prior year of $2.7 million.",
|
||
"Revenue exceeded twelve billion dollars, with a loss of $1b.",
|
||
]
|
||
for doc in nlp.pipe(TEXTS):
|
||
for token in doc:
|
||
if token.ent_type_ == "MONEY":
|
||
# We have an attribute and direct object, so check for subject
|
||
if token.dep_ in ("attr", "dobj"):
|
||
subj = [w for w in token.head.lefts if w.dep_ == "nsubj"]
|
||
if subj:
|
||
print(subj[0], "-->", token)
|
||
# We have a prepositional object with a preposition
|
||
elif token.dep_ == "pobj" and token.head.dep_ == "prep":
|
||
print(token.head.head, "-->", token)
|
||
```
|
||
|
||
<Infobox title="Combining models and rules" emoji="📖">
|
||
|
||
For more examples of how to write rule-based information extraction logic that
|
||
takes advantage of the model's predictions produced by the different components,
|
||
see the usage guide on
|
||
[combining models and rules](/usage/rule-based-matching#models-rules).
|
||
|
||
</Infobox>
|
||
|
||
### Visualizing dependencies {id="displacy"}
|
||
|
||
The best way to understand spaCy's dependency parser is interactively. To make
|
||
this easier, spaCy comes with a visualization module. You can pass a `Doc` or a
|
||
list of `Doc` objects to displaCy and run
|
||
[`displacy.serve`](/api/top-level#displacy.serve) to run the web server, or
|
||
[`displacy.render`](/api/top-level#displacy.render) to generate the raw markup.
|
||
If you want to know how to write rules that hook into some type of syntactic
|
||
construction, just plug the sentence into the visualizer and see how spaCy
|
||
annotates it.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
from spacy import displacy
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp("Autonomous cars shift insurance liability toward manufacturers")
|
||
# Since this is an interactive Jupyter environment, we can use displacy.render here
|
||
displacy.render(doc, style='dep')
|
||
```
|
||
|
||
<Infobox>
|
||
|
||
For more details and examples, see the
|
||
[usage guide on visualizing spaCy](/usage/visualizers). You can also test
|
||
displaCy in our [online demo](https://explosion.ai/demos/displacy)..
|
||
|
||
</Infobox>
|
||
|
||
### Disabling the parser {id="disabling"}
|
||
|
||
In the [trained pipelines](/models) provided by spaCy, the parser is loaded and
|
||
enabled by default as part of the
|
||
[standard processing pipeline](/usage/processing-pipelines). If you don't need
|
||
any of the syntactic information, you should disable the parser. Disabling the
|
||
parser will make spaCy load and run much faster. If you want to load the parser,
|
||
but need to disable it for specific documents, you can also control its use on
|
||
the `nlp` object. For more details, see the usage guide on
|
||
[disabling pipeline components](/usage/processing-pipelines/#disabling).
|
||
|
||
```python
|
||
nlp = spacy.load("en_core_web_sm", disable=["parser"])
|
||
```
|
||
|
||
## Named Entity Recognition {id="named-entities"}
|
||
|
||
spaCy features an extremely fast statistical entity recognition system, that
|
||
assigns labels to contiguous spans of tokens. The default
|
||
[trained pipelines](/models) can identify a variety of named and numeric
|
||
entities, including companies, locations, organizations and products. You can
|
||
add arbitrary classes to the entity recognition system, and update the model
|
||
with new examples.
|
||
|
||
### Named Entity Recognition 101 {id="named-entities-101"}
|
||
|
||
<NER101 />
|
||
|
||
### Accessing entity annotations and labels {id="accessing-ner"}
|
||
|
||
The standard way to access entity annotations is the [`doc.ents`](/api/doc#ents)
|
||
property, which produces a sequence of [`Span`](/api/span) objects. The entity
|
||
type is accessible either as a hash value or as a string, using the attributes
|
||
`ent.label` and `ent.label_`. The `Span` object acts as a sequence of tokens, so
|
||
you can iterate over the entity or index into it. You can also get the text form
|
||
of the whole entity, as though it were a single token.
|
||
|
||
You can also access token entity annotations using the
|
||
[`token.ent_iob`](/api/token#attributes) and
|
||
[`token.ent_type`](/api/token#attributes) attributes. `token.ent_iob` indicates
|
||
whether an entity starts, continues or ends on the tag. If no entity type is set
|
||
on a token, it will return an empty string.
|
||
|
||
> #### IOB Scheme
|
||
>
|
||
> - `I` – Token is **inside** an entity.
|
||
> - `O` – Token is **outside** an entity.
|
||
> - `B` – Token is the **beginning** of an entity.
|
||
>
|
||
> #### BILUO Scheme
|
||
>
|
||
> - `B` – Token is the **beginning** of a multi-token entity.
|
||
> - `I` – Token is **inside** a multi-token entity.
|
||
> - `L` – Token is the **last** token of a multi-token entity.
|
||
> - `U` – Token is a single-token **unit** entity.
|
||
> - `O` – Token is **outside** an entity.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp("San Francisco considers banning sidewalk delivery robots")
|
||
|
||
# document level
|
||
ents = [(e.text, e.start_char, e.end_char, e.label_) for e in doc.ents]
|
||
print(ents)
|
||
|
||
# token level
|
||
ent_san = [doc[0].text, doc[0].ent_iob_, doc[0].ent_type_]
|
||
ent_francisco = [doc[1].text, doc[1].ent_iob_, doc[1].ent_type_]
|
||
print(ent_san) # ['San', 'B', 'GPE']
|
||
print(ent_francisco) # ['Francisco', 'I', 'GPE']
|
||
```
|
||
|
||
| Text | ent_iob | ent_iob\_ | ent_type\_ | Description |
|
||
| --------- | ------- | --------- | ---------- | ---------------------- |
|
||
| San | `3` | `B` | `"GPE"` | beginning of an entity |
|
||
| Francisco | `1` | `I` | `"GPE"` | inside an entity |
|
||
| considers | `2` | `O` | `""` | outside an entity |
|
||
| banning | `2` | `O` | `""` | outside an entity |
|
||
| sidewalk | `2` | `O` | `""` | outside an entity |
|
||
| delivery | `2` | `O` | `""` | outside an entity |
|
||
| robots | `2` | `O` | `""` | outside an entity |
|
||
|
||
### Setting entity annotations {id="setting-entities"}
|
||
|
||
To ensure that the sequence of token annotations remains consistent, you have to
|
||
set entity annotations **at the document level**. However, you can't write
|
||
directly to the `token.ent_iob` or `token.ent_type` attributes, so the easiest
|
||
way to set entities is to use the [`doc.set_ents`](/api/doc#set_ents) function
|
||
and create the new entity as a [`Span`](/api/span).
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
from spacy.tokens import Span
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp("fb is hiring a new vice president of global policy")
|
||
ents = [(e.text, e.start_char, e.end_char, e.label_) for e in doc.ents]
|
||
print('Before', ents)
|
||
# The model didn't recognize "fb" as an entity :(
|
||
|
||
# Create a span for the new entity
|
||
fb_ent = Span(doc, 0, 1, label="ORG")
|
||
orig_ents = list(doc.ents)
|
||
|
||
# Option 1: Modify the provided entity spans, leaving the rest unmodified
|
||
doc.set_ents([fb_ent], default="unmodified")
|
||
|
||
# Option 2: Assign a complete list of ents to doc.ents
|
||
doc.ents = orig_ents + [fb_ent]
|
||
|
||
ents = [(e.text, e.start, e.end, e.label_) for e in doc.ents]
|
||
print('After', ents)
|
||
# [('fb', 0, 1, 'ORG')] 🎉
|
||
```
|
||
|
||
Keep in mind that `Span` is initialized with the start and end **token**
|
||
indices, not the character offsets. To create a span from character offsets, use
|
||
[`Doc.char_span`](/api/doc#char_span):
|
||
|
||
```python
|
||
fb_ent = doc.char_span(0, 2, label="ORG")
|
||
```
|
||
|
||
#### Setting entity annotations from array {id="setting-from-array"}
|
||
|
||
You can also assign entity annotations using the
|
||
[`doc.from_array`](/api/doc#from_array) method. To do this, you should include
|
||
both the `ENT_TYPE` and the `ENT_IOB` attributes in the array you're importing
|
||
from.
|
||
|
||
```python {executable="true"}
|
||
import numpy
|
||
import spacy
|
||
from spacy.attrs import ENT_IOB, ENT_TYPE
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp.make_doc("London is a big city in the United Kingdom.")
|
||
print("Before", doc.ents) # []
|
||
|
||
header = [ENT_IOB, ENT_TYPE]
|
||
attr_array = numpy.zeros((len(doc), len(header)), dtype="uint64")
|
||
attr_array[0, 0] = 3 # B
|
||
attr_array[0, 1] = doc.vocab.strings["GPE"]
|
||
doc.from_array(header, attr_array)
|
||
print("After", doc.ents) # [London]
|
||
```
|
||
|
||
#### Setting entity annotations in Cython {id="setting-cython"}
|
||
|
||
Finally, you can always write to the underlying struct if you compile a
|
||
[Cython](http://cython.org/) function. This is easy to do, and allows you to
|
||
write efficient native code.
|
||
|
||
```python
|
||
# cython: infer_types=True
|
||
from spacy.typedefs cimport attr_t
|
||
from spacy.tokens.doc cimport Doc
|
||
|
||
cpdef set_entity(Doc doc, int start, int end, attr_t ent_type):
|
||
for i in range(start, end):
|
||
doc.c[i].ent_type = ent_type
|
||
doc.c[start].ent_iob = 3
|
||
for i in range(start+1, end):
|
||
doc.c[i].ent_iob = 2
|
||
```
|
||
|
||
Obviously, if you write directly to the array of `TokenC*` structs, you'll have
|
||
responsibility for ensuring that the data is left in a consistent state.
|
||
|
||
### Built-in entity types {id="entity-types"}
|
||
|
||
> #### Tip: Understanding entity types
|
||
>
|
||
> You can also use `spacy.explain()` to get the description for the string
|
||
> representation of an entity label. For example, `spacy.explain("LANGUAGE")`
|
||
> will return "any named language".
|
||
|
||
<Infobox title="Annotation scheme">
|
||
|
||
For details on the entity types available in spaCy's trained pipelines, see the
|
||
"label scheme" sections of the individual models in the
|
||
[models directory](/models).
|
||
|
||
</Infobox>
|
||
|
||
### Visualizing named entities {id="displacy"}
|
||
|
||
The
|
||
[displaCy <sup>ENT</sup> visualizer](https://explosion.ai/demos/displacy-ent)
|
||
lets you explore an entity recognition model's behavior interactively. If you're
|
||
training a model, it's very useful to run the visualization yourself. To help
|
||
you do that, spaCy comes with a visualization module. You can pass a `Doc` or a
|
||
list of `Doc` objects to displaCy and run
|
||
[`displacy.serve`](/api/top-level#displacy.serve) to run the web server, or
|
||
[`displacy.render`](/api/top-level#displacy.render) to generate the raw markup.
|
||
|
||
For more details and examples, see the
|
||
[usage guide on visualizing spaCy](/usage/visualizers).
|
||
|
||
```python {title="Named Entity example"}
|
||
import spacy
|
||
from spacy import displacy
|
||
|
||
text = "When Sebastian Thrun started working on self-driving cars at Google in 2007, few people outside of the company took him seriously."
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp(text)
|
||
displacy.serve(doc, style="ent")
|
||
```
|
||
|
||
<Iframe
|
||
title="displaCy visualizer for entities"
|
||
src="/images/displacy-ent2.html"
|
||
height={180}
|
||
/>
|
||
|
||
## Entity Linking {id="entity-linking"}
|
||
|
||
To ground the named entities into the "real world", spaCy provides functionality
|
||
to perform entity linking, which resolves a textual entity to a unique
|
||
identifier from a knowledge base (KB). You can create your own
|
||
[`KnowledgeBase`](/api/kb) and [train](/usage/training) a new
|
||
[`EntityLinker`](/api/entitylinker) using that custom knowledge base.
|
||
|
||
### Accessing entity identifiers {id="entity-linking-accessing",model="entity linking"}
|
||
|
||
The annotated KB identifier is accessible as either a hash value or as a string,
|
||
using the attributes `ent.kb_id` and `ent.kb_id_` of a [`Span`](/api/span)
|
||
object, or the `ent_kb_id` and `ent_kb_id_` attributes of a
|
||
[`Token`](/api/token) object.
|
||
|
||
```python
|
||
import spacy
|
||
|
||
nlp = spacy.load("my_custom_el_pipeline")
|
||
doc = nlp("Ada Lovelace was born in London")
|
||
|
||
# Document level
|
||
ents = [(e.text, e.label_, e.kb_id_) for e in doc.ents]
|
||
print(ents) # [('Ada Lovelace', 'PERSON', 'Q7259'), ('London', 'GPE', 'Q84')]
|
||
|
||
# Token level
|
||
ent_ada_0 = [doc[0].text, doc[0].ent_type_, doc[0].ent_kb_id_]
|
||
ent_ada_1 = [doc[1].text, doc[1].ent_type_, doc[1].ent_kb_id_]
|
||
ent_london_5 = [doc[5].text, doc[5].ent_type_, doc[5].ent_kb_id_]
|
||
print(ent_ada_0) # ['Ada', 'PERSON', 'Q7259']
|
||
print(ent_ada_1) # ['Lovelace', 'PERSON', 'Q7259']
|
||
print(ent_london_5) # ['London', 'GPE', 'Q84']
|
||
```
|
||
|
||
## Tokenization {id="tokenization"}
|
||
|
||
Tokenization is the task of splitting a text into meaningful segments, called
|
||
_tokens_. The input to the tokenizer is a unicode text, and the output is a
|
||
[`Doc`](/api/doc) object. To construct a `Doc` object, you need a
|
||
[`Vocab`](/api/vocab) instance, a sequence of `word` strings, and optionally a
|
||
sequence of `spaces` booleans, which allow you to maintain alignment of the
|
||
tokens into the original string.
|
||
|
||
<Infobox title="Important note" variant="warning">
|
||
|
||
spaCy's tokenization is **non-destructive**, which means that you'll always be
|
||
able to reconstruct the original input from the tokenized output. Whitespace
|
||
information is preserved in the tokens and no information is added or removed
|
||
during tokenization. This is kind of a core principle of spaCy's `Doc` object:
|
||
`doc.text == input_text` should always hold true.
|
||
|
||
</Infobox>
|
||
|
||
<Tokenization101 />
|
||
|
||
<Accordion title="Algorithm details: How spaCy's tokenizer works" id="how-tokenizer-works" spaced>
|
||
|
||
spaCy introduces a novel tokenization algorithm that gives a better balance
|
||
between performance, ease of definition and ease of alignment into the original
|
||
string.
|
||
|
||
After consuming a prefix or suffix, 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 closed bracket, and finally matching the special case.
|
||
Here's an implementation of the algorithm in Python optimized for readability
|
||
rather than performance:
|
||
|
||
```python
|
||
def tokenizer_pseudo_code(
|
||
text,
|
||
special_cases,
|
||
prefix_search,
|
||
suffix_search,
|
||
infix_finditer,
|
||
token_match,
|
||
url_match
|
||
):
|
||
tokens = []
|
||
for substring in text.split():
|
||
suffixes = []
|
||
while substring:
|
||
if substring in special_cases:
|
||
tokens.extend(special_cases[substring])
|
||
substring = ""
|
||
continue
|
||
while prefix_search(substring) or suffix_search(substring):
|
||
if token_match(substring):
|
||
tokens.append(substring)
|
||
substring = ""
|
||
break
|
||
if substring in special_cases:
|
||
tokens.extend(special_cases[substring])
|
||
substring = ""
|
||
break
|
||
if prefix_search(substring):
|
||
split = prefix_search(substring).end()
|
||
tokens.append(substring[:split])
|
||
substring = substring[split:]
|
||
if substring in special_cases:
|
||
continue
|
||
if suffix_search(substring):
|
||
split = suffix_search(substring).start()
|
||
suffixes.append(substring[split:])
|
||
substring = substring[:split]
|
||
if token_match(substring):
|
||
tokens.append(substring)
|
||
substring = ""
|
||
elif url_match(substring):
|
||
tokens.append(substring)
|
||
substring = ""
|
||
elif substring in special_cases:
|
||
tokens.extend(special_cases[substring])
|
||
substring = ""
|
||
elif list(infix_finditer(substring)):
|
||
infixes = infix_finditer(substring)
|
||
offset = 0
|
||
for match in infixes:
|
||
if offset == 0 and match.start() == 0:
|
||
continue
|
||
tokens.append(substring[offset : match.start()])
|
||
tokens.append(substring[match.start() : match.end()])
|
||
offset = match.end()
|
||
if substring[offset:]:
|
||
tokens.append(substring[offset:])
|
||
substring = ""
|
||
elif substring:
|
||
tokens.append(substring)
|
||
substring = ""
|
||
tokens.extend(reversed(suffixes))
|
||
for match in matcher(special_cases, text):
|
||
tokens.replace(match, special_cases[match])
|
||
return tokens
|
||
```
|
||
|
||
The algorithm can be summarized as follows:
|
||
|
||
1. Iterate over space-separated substrings.
|
||
2. Check whether we have an explicitly defined special case for this substring.
|
||
If we do, use it.
|
||
3. Look for a token match. If there is a match, stop processing and keep this
|
||
token.
|
||
4. Check whether we have an explicitly defined special case for this substring.
|
||
If we do, use it.
|
||
5. Otherwise, try to consume one prefix. If we consumed a prefix, go back to #3,
|
||
so that the token match and special cases always get priority.
|
||
6. If we didn't consume a prefix, try to consume a suffix and then go back to
|
||
#3.
|
||
7. If we can't consume a prefix or a suffix, look for a URL match.
|
||
8. If there's no URL match, then look for a special case.
|
||
9. Look for "infixes" – stuff like hyphens etc. and split the substring into
|
||
tokens on all infixes.
|
||
10. Once we can't consume any more of the string, handle it as a single token.
|
||
11. Make a final pass over the text to check for special cases that include
|
||
spaces or that were missed due to the incremental processing of affixes.
|
||
|
||
</Accordion>
|
||
|
||
**Global** and **language-specific** tokenizer data is supplied via the language
|
||
data in [`spacy/lang`](%%GITHUB_SPACY/spacy/lang). The tokenizer exceptions
|
||
define special cases like "don't" in English, which needs to be split into two
|
||
tokens: `{ORTH: "do"}` and `{ORTH: "n't", NORM: "not"}`. The prefixes, suffixes
|
||
and infixes mostly define punctuation rules – for example, when to split off
|
||
periods (at the end of a sentence), and when to leave tokens containing periods
|
||
intact (abbreviations like "U.S.").
|
||
|
||
<Accordion title="Should I change the language data or add custom tokenizer rules?" id="lang-data-vs-tokenizer">
|
||
|
||
Tokenization rules that are specific to one language, but can be **generalized
|
||
across that language**, should ideally live in the language data in
|
||
[`spacy/lang`](%%GITHUB_SPACY/spacy/lang) – we always appreciate pull requests!
|
||
Anything that's specific to a domain or text type – like financial trading
|
||
abbreviations or Bavarian youth slang – should be added as a special case rule
|
||
to your tokenizer instance. If you're dealing with a lot of customizations, it
|
||
might make sense to create an entirely custom subclass.
|
||
|
||
</Accordion>
|
||
|
||
---
|
||
|
||
### Adding special case tokenization rules {id="special-cases"}
|
||
|
||
Most domains have at least some idiosyncrasies that require custom tokenization
|
||
rules. This could be very certain expressions, or abbreviations only used in
|
||
this specific field. Here's how to add a special case rule to an existing
|
||
[`Tokenizer`](/api/tokenizer) instance:
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
from spacy.symbols import ORTH
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp("gimme that") # phrase to tokenize
|
||
print([w.text for w in doc]) # ['gimme', 'that']
|
||
|
||
# Add special case rule
|
||
special_case = [{ORTH: "gim"}, {ORTH: "me"}]
|
||
nlp.tokenizer.add_special_case("gimme", special_case)
|
||
|
||
# Check new tokenization
|
||
print([w.text for w in nlp("gimme that")]) # ['gim', 'me', 'that']
|
||
```
|
||
|
||
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. The special case rules also have precedence over the
|
||
punctuation splitting.
|
||
|
||
```python
|
||
assert "gimme" not in [w.text for w in nlp("gimme!")]
|
||
assert "gimme" not in [w.text for w in nlp('("...gimme...?")')]
|
||
|
||
nlp.tokenizer.add_special_case("...gimme...?", [{"ORTH": "...gimme...?"}])
|
||
assert len(nlp("...gimme...?")) == 1
|
||
```
|
||
|
||
#### Debugging the tokenizer {id="tokenizer-debug",version="2.2.3"}
|
||
|
||
A working implementation of the pseudo-code above is available for debugging as
|
||
[`nlp.tokenizer.explain(text)`](/api/tokenizer#explain). It returns a list of
|
||
tuples showing which tokenizer rule or pattern was matched for each token. The
|
||
tokens produced are identical to `nlp.tokenizer()` except for whitespace tokens:
|
||
|
||
> #### Expected output
|
||
>
|
||
> ```
|
||
> " PREFIX
|
||
> Let SPECIAL-1
|
||
> 's SPECIAL-2
|
||
> go TOKEN
|
||
> ! SUFFIX
|
||
> " SUFFIX
|
||
> ```
|
||
|
||
```python {executable="true"}
|
||
from spacy.lang.en import English
|
||
|
||
nlp = English()
|
||
text = '''"Let's go!"'''
|
||
doc = nlp(text)
|
||
tok_exp = nlp.tokenizer.explain(text)
|
||
assert [t.text for t in doc if not t.is_space] == [t[1] for t in tok_exp]
|
||
for t in tok_exp:
|
||
print(t[1], "\\t", t[0])
|
||
```
|
||
|
||
### Customizing spaCy's Tokenizer class {id="native-tokenizers"}
|
||
|
||
Let's imagine you wanted to create a tokenizer for a new language or specific
|
||
domain. There are six things you may need to define:
|
||
|
||
1. A dictionary of **special cases**. This handles things like contractions,
|
||
units of measurement, emoticons, certain abbreviations, etc.
|
||
2. A function `prefix_search`, to handle **preceding punctuation**, such as open
|
||
quotes, open brackets, etc.
|
||
3. A function `suffix_search`, to handle **succeeding punctuation**, such as
|
||
commas, periods, close quotes, etc.
|
||
4. A function `infix_finditer`, to handle non-whitespace separators, such as
|
||
hyphens etc.
|
||
5. An optional boolean function `token_match` matching strings that should never
|
||
be split, overriding the infix rules. Useful for things like numbers.
|
||
6. An optional boolean function `url_match`, which is similar to `token_match`
|
||
except that prefixes and suffixes are removed before applying the match.
|
||
|
||
You shouldn't usually need to create a `Tokenizer` subclass. Standard usage is
|
||
to use `re.compile()` to build a regular expression object, and pass its
|
||
`.search()` and `.finditer()` methods:
|
||
|
||
```python {executable="true"}
|
||
import re
|
||
import spacy
|
||
from spacy.tokenizer import Tokenizer
|
||
|
||
special_cases = {":)": [{"ORTH": ":)"}]}
|
||
prefix_re = re.compile(r'''^[\\[\\("']''')
|
||
suffix_re = re.compile(r'''[\\]\\)"']$''')
|
||
infix_re = re.compile(r'''[-~]''')
|
||
simple_url_re = re.compile(r'''^https?://''')
|
||
|
||
def custom_tokenizer(nlp):
|
||
return Tokenizer(nlp.vocab, rules=special_cases,
|
||
prefix_search=prefix_re.search,
|
||
suffix_search=suffix_re.search,
|
||
infix_finditer=infix_re.finditer,
|
||
url_match=simple_url_re.match)
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
nlp.tokenizer = custom_tokenizer(nlp)
|
||
doc = nlp("hello-world. :)")
|
||
print([t.text for t in doc]) # ['hello', '-', 'world.', ':)']
|
||
```
|
||
|
||
If you need to subclass the tokenizer instead, the relevant methods to
|
||
specialize are `find_prefix`, `find_suffix` and `find_infix`.
|
||
|
||
<Infobox title="Important note" variant="warning">
|
||
|
||
When customizing the prefix, suffix and infix handling, remember that you're
|
||
passing in **functions** for spaCy to execute, e.g. `prefix_re.search` – not
|
||
just the regular expressions. This means that your functions also need to define
|
||
how the rules should be applied. For example, if you're adding your own prefix
|
||
rules, you need to make sure they're only applied to characters at the
|
||
**beginning of a token**, e.g. by adding `^`. Similarly, suffix rules should
|
||
only be applied at the **end of a token**, so your expression should end with a
|
||
`$`.
|
||
|
||
</Infobox>
|
||
|
||
#### Modifying existing rule sets {id="native-tokenizer-additions"}
|
||
|
||
In many situations, you don't necessarily need entirely custom rules. Sometimes
|
||
you just want to add another character to the prefixes, suffixes or infixes. The
|
||
default prefix, suffix and infix rules are available via the `nlp` object's
|
||
`Defaults` and the `Tokenizer` attributes such as
|
||
[`Tokenizer.suffix_search`](/api/tokenizer#attributes) are writable, so you can
|
||
overwrite them with compiled regular expression objects using modified default
|
||
rules. spaCy ships with utility functions to help you compile the regular
|
||
expressions – for example,
|
||
[`compile_suffix_regex`](/api/top-level#util.compile_suffix_regex):
|
||
|
||
```python
|
||
suffixes = nlp.Defaults.suffixes + [r'''-+$''',]
|
||
suffix_regex = spacy.util.compile_suffix_regex(suffixes)
|
||
nlp.tokenizer.suffix_search = suffix_regex.search
|
||
```
|
||
|
||
Similarly, you can remove a character from the default suffixes:
|
||
|
||
```python
|
||
suffixes = list(nlp.Defaults.suffixes)
|
||
suffixes.remove("\\\\[")
|
||
suffix_regex = spacy.util.compile_suffix_regex(suffixes)
|
||
nlp.tokenizer.suffix_search = suffix_regex.search
|
||
```
|
||
|
||
The `Tokenizer.suffix_search` attribute should be a function which takes a
|
||
unicode string and returns a **regex match object** or `None`. Usually we use
|
||
the `.search` attribute of a compiled regex object, but you can use some other
|
||
function that behaves the same way.
|
||
|
||
<Infobox title="Important note" variant="warning">
|
||
|
||
If you've loaded a trained pipeline, writing to the
|
||
[`nlp.Defaults`](/api/language#defaults) or `English.Defaults` directly won't
|
||
work, since the regular expressions are read from the pipeline data and will be
|
||
compiled when you load it. If you modify `nlp.Defaults`, you'll only see the
|
||
effect if you call [`spacy.blank`](/api/top-level#spacy.blank). If you want to
|
||
modify the tokenizer loaded from a trained pipeline, you should modify
|
||
`nlp.tokenizer` directly. If you're training your own pipeline, you can register
|
||
[callbacks](/usage/training/#custom-code-nlp-callbacks) to modify the `nlp`
|
||
object before training.
|
||
|
||
</Infobox>
|
||
|
||
The prefix, infix and suffix rule sets include not only individual characters
|
||
but also detailed regular expressions that take the surrounding context into
|
||
account. For example, there is a regular expression that treats a hyphen between
|
||
letters as an infix. If you do not want the tokenizer to split on hyphens
|
||
between letters, you can modify the existing infix definition from
|
||
[`lang/punctuation.py`](%%GITHUB_SPACY/spacy/lang/punctuation.py):
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
from spacy.lang.char_classes import ALPHA, ALPHA_LOWER, ALPHA_UPPER
|
||
from spacy.lang.char_classes import CONCAT_QUOTES, LIST_ELLIPSES, LIST_ICONS
|
||
from spacy.util import compile_infix_regex
|
||
|
||
# Default tokenizer
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp("mother-in-law")
|
||
print([t.text for t in doc]) # ['mother', '-', 'in', '-', 'law']
|
||
|
||
# Modify tokenizer infix patterns
|
||
infixes = (
|
||
LIST_ELLIPSES
|
||
+ LIST_ICONS
|
||
+ [
|
||
r"(?<=[0-9])[+\\-\\*^](?=[0-9-])",
|
||
r"(?<=[{al}{q}])\\.(?=[{au}{q}])".format(
|
||
al=ALPHA_LOWER, au=ALPHA_UPPER, q=CONCAT_QUOTES
|
||
),
|
||
r"(?<=[{a}]),(?=[{a}])".format(a=ALPHA),
|
||
# ✅ Commented out regex that splits on hyphens between letters:
|
||
# r"(?<=[{a}])(?:{h})(?=[{a}])".format(a=ALPHA, h=HYPHENS),
|
||
r"(?<=[{a}0-9])[:<>=/](?=[{a}])".format(a=ALPHA),
|
||
]
|
||
)
|
||
|
||
infix_re = compile_infix_regex(infixes)
|
||
nlp.tokenizer.infix_finditer = infix_re.finditer
|
||
doc = nlp("mother-in-law")
|
||
print([t.text for t in doc]) # ['mother-in-law']
|
||
```
|
||
|
||
For an overview of the default regular expressions, see
|
||
[`lang/punctuation.py`](%%GITHUB_SPACY/spacy/lang/punctuation.py) and
|
||
language-specific definitions such as
|
||
[`lang/de/punctuation.py`](%%GITHUB_SPACY/spacy/lang/de/punctuation.py) for
|
||
German.
|
||
|
||
### Hooking a custom tokenizer into the pipeline {id="custom-tokenizer"}
|
||
|
||
The tokenizer is the first component of the processing pipeline and the only one
|
||
that can't be replaced by writing to `nlp.pipeline`. This is because it has a
|
||
different signature from all the other components: it takes a text and returns a
|
||
[`Doc`](/api/doc), whereas all other components expect to already receive a
|
||
tokenized `Doc`.
|
||
|
||
![The processing pipeline](/images/pipeline.svg)
|
||
|
||
To overwrite the existing tokenizer, you need to replace `nlp.tokenizer` with a
|
||
custom function that takes a text and returns a [`Doc`](/api/doc).
|
||
|
||
> #### Creating a Doc
|
||
>
|
||
> Constructing a [`Doc`](/api/doc) object manually requires at least two
|
||
> arguments: the shared `Vocab` and a list of words. Optionally, you can pass in
|
||
> a list of `spaces` values indicating whether the token at this position is
|
||
> followed by a space (default `True`). See the section on
|
||
> [pre-tokenized text](#own-annotations) for more info.
|
||
>
|
||
> ```python
|
||
> words = ["Let", "'s", "go", "!"]
|
||
> spaces = [False, True, False, False]
|
||
> doc = Doc(nlp.vocab, words=words, spaces=spaces)
|
||
> ```
|
||
|
||
```python
|
||
nlp = spacy.blank("en")
|
||
nlp.tokenizer = my_tokenizer
|
||
```
|
||
|
||
| Argument | Type | Description |
|
||
| ----------- | ----------------- | ------------------------- |
|
||
| `text` | `str` | The raw text to tokenize. |
|
||
| **RETURNS** | [`Doc`](/api/doc) | The tokenized document. |
|
||
|
||
#### Example 1: Basic whitespace tokenizer {id="custom-tokenizer-example"}
|
||
|
||
Here's an example of the most basic whitespace tokenizer. It takes the shared
|
||
vocab, so it can construct `Doc` objects. When it's called on a text, it returns
|
||
a `Doc` object consisting of the text split on single space characters. We can
|
||
then overwrite the `nlp.tokenizer` attribute with an instance of our custom
|
||
tokenizer.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
from spacy.tokens import Doc
|
||
|
||
class WhitespaceTokenizer:
|
||
def __init__(self, vocab):
|
||
self.vocab = vocab
|
||
|
||
def __call__(self, text):
|
||
words = text.split(" ")
|
||
spaces = [True] * len(words)
|
||
# Avoid zero-length tokens
|
||
for i, word in enumerate(words):
|
||
if word == "":
|
||
words[i] = " "
|
||
spaces[i] = False
|
||
# Remove the final trailing space
|
||
if words[-1] == " ":
|
||
words = words[0:-1]
|
||
spaces = spaces[0:-1]
|
||
else:
|
||
spaces[-1] = False
|
||
|
||
return Doc(self.vocab, words=words, spaces=spaces)
|
||
|
||
nlp = spacy.blank("en")
|
||
nlp.tokenizer = WhitespaceTokenizer(nlp.vocab)
|
||
doc = nlp("What's happened to me? he thought. It wasn't a dream.")
|
||
print([token.text for token in doc])
|
||
```
|
||
|
||
#### Example 2: Third-party tokenizers (BERT word pieces) {id="custom-tokenizer-example2"}
|
||
|
||
You can use the same approach to plug in any other third-party tokenizers. Your
|
||
custom callable just needs to return a `Doc` object with the tokens produced by
|
||
your tokenizer. In this example, the wrapper uses the **BERT word piece
|
||
tokenizer**, provided by the
|
||
[`tokenizers`](https://github.com/huggingface/tokenizers) library. The tokens
|
||
available in the `Doc` object returned by spaCy now match the exact word pieces
|
||
produced by the tokenizer.
|
||
|
||
> #### 💡 Tip: spacy-transformers
|
||
>
|
||
> If you're working with transformer models like BERT, check out the
|
||
> [`spacy-transformers`](https://github.com/explosion/spacy-transformers)
|
||
> extension package and [documentation](/usage/embeddings-transformers). It
|
||
> includes a pipeline component for using pretrained transformer weights and
|
||
> **training transformer models** in spaCy, as well as helpful utilities for
|
||
> aligning word pieces to linguistic tokenization.
|
||
|
||
```python {title="Custom BERT word piece tokenizer"}
|
||
from tokenizers import BertWordPieceTokenizer
|
||
from spacy.tokens import Doc
|
||
import spacy
|
||
|
||
class BertTokenizer:
|
||
def __init__(self, vocab, vocab_file, lowercase=True):
|
||
self.vocab = vocab
|
||
self._tokenizer = BertWordPieceTokenizer(vocab_file, lowercase=lowercase)
|
||
|
||
def __call__(self, text):
|
||
tokens = self._tokenizer.encode(text)
|
||
words = []
|
||
spaces = []
|
||
for i, (text, (start, end)) in enumerate(zip(tokens.tokens, tokens.offsets)):
|
||
words.append(text)
|
||
if i < len(tokens.tokens) - 1:
|
||
# If next start != current end we assume a space in between
|
||
next_start, next_end = tokens.offsets[i + 1]
|
||
spaces.append(next_start > end)
|
||
else:
|
||
spaces.append(True)
|
||
return Doc(self.vocab, words=words, spaces=spaces)
|
||
|
||
nlp = spacy.blank("en")
|
||
nlp.tokenizer = BertTokenizer(nlp.vocab, "bert-base-uncased-vocab.txt")
|
||
doc = nlp("Justin Drew Bieber is a Canadian singer, songwriter, and actor.")
|
||
print(doc.text, [token.text for token in doc])
|
||
# [CLS]justin drew bi##eber is a canadian singer, songwriter, and actor.[SEP]
|
||
# ['[CLS]', 'justin', 'drew', 'bi', '##eber', 'is', 'a', 'canadian', 'singer',
|
||
# ',', 'songwriter', ',', 'and', 'actor', '.', '[SEP]']
|
||
```
|
||
|
||
<Infobox title="Important note on tokenization and models" variant="warning">
|
||
|
||
Keep in mind that your models' results may be less accurate if the tokenization
|
||
during training differs from the tokenization at runtime. So if you modify a
|
||
trained pipeline's tokenization afterwards, it may produce very different
|
||
predictions. You should therefore train your pipeline with the **same
|
||
tokenizer** it will be using at runtime. See the docs on
|
||
[training with custom tokenization](#custom-tokenizer-training) for details.
|
||
|
||
</Infobox>
|
||
|
||
#### Training with custom tokenization {id="custom-tokenizer-training",version="3"}
|
||
|
||
spaCy's [training config](/usage/training#config) describes the settings,
|
||
hyperparameters, pipeline and tokenizer used for constructing and training the
|
||
pipeline. The `[nlp.tokenizer]` block refers to a **registered function** that
|
||
takes the `nlp` object and returns a tokenizer. Here, we're registering a
|
||
function called `whitespace_tokenizer` in the
|
||
[`@tokenizers` registry](/api/top-level#registry). To make sure spaCy knows how
|
||
to construct your tokenizer during training, you can pass in your Python file by
|
||
setting `--code functions.py` when you run [`spacy train`](/api/cli#train).
|
||
|
||
> #### config.cfg
|
||
>
|
||
> ```ini
|
||
> [nlp.tokenizer]
|
||
> @tokenizers = "whitespace_tokenizer"
|
||
> ```
|
||
|
||
```python {title="functions.py",highlight="1"}
|
||
@spacy.registry.tokenizers("whitespace_tokenizer")
|
||
def create_whitespace_tokenizer():
|
||
def create_tokenizer(nlp):
|
||
return WhitespaceTokenizer(nlp.vocab)
|
||
|
||
return create_tokenizer
|
||
```
|
||
|
||
Registered functions can also take arguments that are then passed in from the
|
||
config. This allows you to quickly change and keep track of different settings.
|
||
Here, the registered function called `bert_word_piece_tokenizer` takes two
|
||
arguments: the path to a vocabulary file and whether to lowercase the text. The
|
||
Python type hints `str` and `bool` ensure that the received values have the
|
||
correct type.
|
||
|
||
> #### config.cfg
|
||
>
|
||
> ```ini
|
||
> [nlp.tokenizer]
|
||
> @tokenizers = "bert_word_piece_tokenizer"
|
||
> vocab_file = "bert-base-uncased-vocab.txt"
|
||
> lowercase = true
|
||
> ```
|
||
|
||
```python {title="functions.py",highlight="1"}
|
||
@spacy.registry.tokenizers("bert_word_piece_tokenizer")
|
||
def create_whitespace_tokenizer(vocab_file: str, lowercase: bool):
|
||
def create_tokenizer(nlp):
|
||
return BertWordPieceTokenizer(nlp.vocab, vocab_file, lowercase)
|
||
|
||
return create_tokenizer
|
||
```
|
||
|
||
To avoid hard-coding local paths into your config file, you can also set the
|
||
vocab path on the CLI by using the `--nlp.tokenizer.vocab_file`
|
||
[override](/usage/training#config-overrides) when you run
|
||
[`spacy train`](/api/cli#train). For more details on using registered functions,
|
||
see the docs in [training with custom code](/usage/training#custom-code).
|
||
|
||
<Infobox variant="warning">
|
||
|
||
Remember that a registered function should always be a function that spaCy
|
||
**calls to create something**, not the "something" itself. In this case, it
|
||
**creates a function** that takes the `nlp` object and returns a callable that
|
||
takes a text and returns a `Doc`.
|
||
|
||
</Infobox>
|
||
|
||
#### Using pre-tokenized text {id="own-annotations"}
|
||
|
||
spaCy generally assumes by default that your data is **raw text**. However,
|
||
sometimes your data is partially annotated, e.g. with pre-existing tokenization,
|
||
part-of-speech tags, etc. The most common situation is that you have
|
||
**pre-defined tokenization**. If you have a list of strings, you can create a
|
||
[`Doc`](/api/doc) object directly. Optionally, you can also specify a list of
|
||
boolean values, indicating whether each word is followed by a space.
|
||
|
||
> #### ✏️ Things to try
|
||
>
|
||
> 1. Change a boolean value in the list of `spaces`. You should see it reflected
|
||
> in the `doc.text` and whether the token is followed by a space.
|
||
> 2. Remove `spaces=spaces` from the `Doc`. You should see that every token is
|
||
> now followed by a space.
|
||
> 3. Copy-paste a random sentence from the internet and manually construct a
|
||
> `Doc` with `words` and `spaces` so that the `doc.text` matches the original
|
||
> input text.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
from spacy.tokens import Doc
|
||
|
||
nlp = spacy.blank("en")
|
||
words = ["Hello", ",", "world", "!"]
|
||
spaces = [False, True, False, False]
|
||
doc = Doc(nlp.vocab, words=words, spaces=spaces)
|
||
print(doc.text)
|
||
print([(t.text, t.text_with_ws, t.whitespace_) for t in doc])
|
||
```
|
||
|
||
If provided, the spaces list must be the **same length** as the words list. The
|
||
spaces list affects the `doc.text`, `span.text`, `token.idx`, `span.start_char`
|
||
and `span.end_char` attributes. If you don't provide a `spaces` sequence, spaCy
|
||
will assume that all words are followed by a space. Once you have a
|
||
[`Doc`](/api/doc) object, you can write to its attributes to set the
|
||
part-of-speech tags, syntactic dependencies, named entities and other
|
||
attributes.
|
||
|
||
#### Aligning tokenization {id="aligning-tokenization"}
|
||
|
||
spaCy's tokenization is non-destructive and uses language-specific rules
|
||
optimized for compatibility with treebank annotations. Other tools and resources
|
||
can sometimes tokenize things differently – for example, `"I'm"` →
|
||
`["I", "'", "m"]` instead of `["I", "'m"]`.
|
||
|
||
In situations like that, you often want to align the tokenization so that you
|
||
can merge annotations from different sources together, or take vectors predicted
|
||
by a
|
||
[pretrained BERT model](https://github.com/huggingface/pytorch-transformers) and
|
||
apply them to spaCy tokens. spaCy's [`Alignment`](/api/example#alignment-object)
|
||
object allows the one-to-one mappings of token indices in both directions as
|
||
well as taking into account indices where multiple tokens align to one single
|
||
token.
|
||
|
||
> #### ✏️ Things to try
|
||
>
|
||
> 1. Change the capitalization in one of the token lists – for example,
|
||
> `"obama"` to `"Obama"`. You'll see that the alignment is case-insensitive.
|
||
> 2. Change `"podcasts"` in `other_tokens` to `"pod", "casts"`. You should see
|
||
> that there are now two tokens of length 2 in `y2x`, one corresponding to
|
||
> "'s", and one to "podcasts".
|
||
> 3. Make `other_tokens` and `spacy_tokens` identical. You'll see that all
|
||
> tokens now correspond 1-to-1.
|
||
|
||
```python {executable="true"}
|
||
from spacy.training import Alignment
|
||
|
||
other_tokens = ["i", "listened", "to", "obama", "'", "s", "podcasts", "."]
|
||
spacy_tokens = ["i", "listened", "to", "obama", "'s", "podcasts", "."]
|
||
align = Alignment.from_strings(other_tokens, spacy_tokens)
|
||
print(f"a -> b, lengths: {align.x2y.lengths}") # array([1, 1, 1, 1, 1, 1, 1, 1])
|
||
print(f"a -> b, mapping: {align.x2y.data}") # array([0, 1, 2, 3, 4, 4, 5, 6]) : two tokens both refer to "'s"
|
||
print(f"b -> a, lengths: {align.y2x.lengths}") # array([1, 1, 1, 1, 2, 1, 1]) : the token "'s" refers to two tokens
|
||
print(f"b -> a, mappings: {align.y2x.data}") # array([0, 1, 2, 3, 4, 5, 6, 7])
|
||
```
|
||
|
||
Here are some insights from the alignment information generated in the example
|
||
above:
|
||
|
||
- The one-to-one mappings for the first four tokens are identical, which means
|
||
they map to each other. This makes sense because they're also identical in the
|
||
input: `"i"`, `"listened"`, `"to"` and `"obama"`.
|
||
- The value of `x2y.data[6]` is `5`, which means that `other_tokens[6]`
|
||
(`"podcasts"`) aligns to `spacy_tokens[5]` (also `"podcasts"`).
|
||
- `x2y.data[4]` and `x2y.data[5]` are both `4`, which means that both tokens 4
|
||
and 5 of `other_tokens` (`"'"` and `"s"`) align to token 4 of `spacy_tokens`
|
||
(`"'s"`).
|
||
|
||
<Infobox title="Important note" variant="warning">
|
||
|
||
The current implementation of the alignment algorithm assumes that both
|
||
tokenizations add up to the same string. For example, you'll be able to align
|
||
`["I", "'", "m"]` and `["I", "'m"]`, which both add up to `"I'm"`, but not
|
||
`["I", "'m"]` and `["I", "am"]`.
|
||
|
||
</Infobox>
|
||
|
||
## Merging and splitting {id="retokenization",version="2.1"}
|
||
|
||
The [`Doc.retokenize`](/api/doc#retokenize) context manager lets you merge and
|
||
split tokens. Modifications to the tokenization are stored and performed all at
|
||
once when the context manager exits. To merge several tokens into one single
|
||
token, pass a `Span` to [`retokenizer.merge`](/api/doc#retokenizer.merge). An
|
||
optional dictionary of `attrs` lets you set attributes that will be assigned to
|
||
the merged token – for example, the lemma, part-of-speech tag or entity type. By
|
||
default, the merged token will receive the same attributes as the merged span's
|
||
root.
|
||
|
||
> #### ✏️ Things to try
|
||
>
|
||
> 1. Inspect the `token.lemma_` attribute with and without setting the `attrs`.
|
||
> You'll see that the lemma defaults to "New", the lemma of the span's root.
|
||
> 2. Overwrite other attributes like the `"ENT_TYPE"`. Since "New York" is also
|
||
> recognized as a named entity, this change will also be reflected in the
|
||
> `doc.ents`.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp("I live in New York")
|
||
print("Before:", [token.text for token in doc])
|
||
|
||
with doc.retokenize() as retokenizer:
|
||
retokenizer.merge(doc[3:5], attrs={"LEMMA": "new york"})
|
||
print("After:", [token.text for token in doc])
|
||
```
|
||
|
||
> #### Tip: merging entities and noun phrases
|
||
>
|
||
> If you need to merge named entities or noun chunks, check out the built-in
|
||
> [`merge_entities`](/api/pipeline-functions#merge_entities) and
|
||
> [`merge_noun_chunks`](/api/pipeline-functions#merge_noun_chunks) pipeline
|
||
> components. When added to your pipeline using `nlp.add_pipe`, they'll take
|
||
> care of merging the spans automatically.
|
||
|
||
If an attribute in the `attrs` is a context-dependent token attribute, it will
|
||
be applied to the underlying [`Token`](/api/token). For example `LEMMA`, `POS`
|
||
or `DEP` only apply to a word in context, so they're token attributes. If an
|
||
attribute is a context-independent lexical attribute, it will be applied to the
|
||
underlying [`Lexeme`](/api/lexeme), the entry in the vocabulary. For example,
|
||
`LOWER` or `IS_STOP` apply to all words of the same spelling, regardless of the
|
||
context.
|
||
|
||
<Infobox variant="warning" title="Note on merging overlapping spans">
|
||
|
||
If you're trying to merge spans that overlap, spaCy will raise an error because
|
||
it's unclear how the result should look. Depending on the application, you may
|
||
want to match the shortest or longest possible span, so it's up to you to filter
|
||
them. If you're looking for the longest non-overlapping span, you can use the
|
||
[`util.filter_spans`](/api/top-level#util.filter_spans) helper:
|
||
|
||
```python
|
||
doc = nlp("I live in Berlin Kreuzberg")
|
||
spans = [doc[3:5], doc[3:4], doc[4:5]]
|
||
filtered_spans = filter_spans(spans)
|
||
```
|
||
|
||
</Infobox>
|
||
|
||
### Splitting tokens
|
||
|
||
The [`retokenizer.split`](/api/doc#retokenizer.split) method allows splitting
|
||
one token into two or more tokens. This can be useful for cases where
|
||
tokenization rules alone aren't sufficient. For example, you might want to split
|
||
"its" into the tokens "it" and "is" – but not the possessive pronoun "its". You
|
||
can write rule-based logic that can find only the correct "its" to split, but by
|
||
that time, the `Doc` will already be tokenized.
|
||
|
||
This process of splitting a token requires more settings, because you need to
|
||
specify the text of the individual tokens, optional per-token attributes and how
|
||
the tokens should be attached to the existing syntax tree. This can be done by
|
||
supplying a list of `heads` – either the token to attach the newly split token
|
||
to, or a `(token, subtoken)` tuple if the newly split token should be attached
|
||
to another subtoken. In this case, "New" should be attached to "York" (the
|
||
second split subtoken) and "York" should be attached to "in".
|
||
|
||
> #### ✏️ Things to try
|
||
>
|
||
> 1. Assign different attributes to the subtokens and compare the result.
|
||
> 2. Change the heads so that "New" is attached to "in" and "York" is attached
|
||
> to "New".
|
||
> 3. Split the token into three tokens instead of two – for example,
|
||
> `["New", "Yo", "rk"]`.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
from spacy import displacy
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp("I live in NewYork")
|
||
print("Before:", [token.text for token in doc])
|
||
displacy.render(doc) # displacy.serve if you're not in a Jupyter environment
|
||
|
||
with doc.retokenize() as retokenizer:
|
||
heads = [(doc[3], 1), doc[2]]
|
||
attrs = {"POS": ["PROPN", "PROPN"], "DEP": ["pobj", "compound"]}
|
||
retokenizer.split(doc[3], ["New", "York"], heads=heads, attrs=attrs)
|
||
print("After:", [token.text for token in doc])
|
||
displacy.render(doc) # displacy.serve if you're not in a Jupyter environment
|
||
```
|
||
|
||
Specifying the heads as a list of `token` or `(token, subtoken)` tuples allows
|
||
attaching split subtokens to other subtokens, without having to keep track of
|
||
the token indices after splitting.
|
||
|
||
| Token | Head | Description |
|
||
| -------- | ------------- | --------------------------------------------------------------------------------------------------- |
|
||
| `"New"` | `(doc[3], 1)` | Attach this token to the second subtoken (index `1`) that `doc[3]` will be split into, i.e. "York". |
|
||
| `"York"` | `doc[2]` | Attach this token to `doc[1]` in the original `Doc`, i.e. "in". |
|
||
|
||
If you don't care about the heads (for example, if you're only running the
|
||
tokenizer and not the parser), you can attach each subtoken to itself:
|
||
|
||
```python {highlight="3"}
|
||
doc = nlp("I live in NewYorkCity")
|
||
with doc.retokenize() as retokenizer:
|
||
heads = [(doc[3], 0), (doc[3], 1), (doc[3], 2)]
|
||
retokenizer.split(doc[3], ["New", "York", "City"], heads=heads)
|
||
```
|
||
|
||
<Infobox title="Important note" variant="warning">
|
||
|
||
When splitting tokens, the subtoken texts always have to match the original
|
||
token text – or, put differently `"".join(subtokens) == token.text` always needs
|
||
to hold true. If this wasn't the case, splitting tokens could easily end up
|
||
producing confusing and unexpected results that would contradict spaCy's
|
||
non-destructive tokenization policy.
|
||
|
||
```diff
|
||
doc = nlp("I live in L.A.")
|
||
with doc.retokenize() as retokenizer:
|
||
- retokenizer.split(doc[3], ["Los", "Angeles"], heads=[(doc[3], 1), doc[2]])
|
||
+ retokenizer.split(doc[3], ["L.", "A."], heads=[(doc[3], 1), doc[2]])
|
||
```
|
||
|
||
</Infobox>
|
||
|
||
### Overwriting custom extension attributes {id="retokenization-extensions"}
|
||
|
||
If you've registered custom
|
||
[extension attributes](/usage/processing-pipelines#custom-components-attributes),
|
||
you can overwrite them during tokenization by providing a dictionary of
|
||
attribute names mapped to new values as the `"_"` key in the `attrs`. For
|
||
merging, you need to provide one dictionary of attributes for the resulting
|
||
merged token. For splitting, you need to provide a list of dictionaries with
|
||
custom attributes, one per split subtoken.
|
||
|
||
<Infobox title="Important note" variant="warning">
|
||
|
||
To set extension attributes during retokenization, the attributes need to be
|
||
**registered** using the [`Token.set_extension`](/api/token#set_extension)
|
||
method and they need to be **writable**. This means that they should either have
|
||
a default value that can be overwritten, or a getter _and_ setter. Method
|
||
extensions or extensions with only a getter are computed dynamically, so their
|
||
values can't be overwritten. For more details, see the
|
||
[extension attribute docs](/usage/processing-pipelines/#custom-components-attributes).
|
||
|
||
</Infobox>
|
||
|
||
> #### ✏️ Things to try
|
||
>
|
||
> 1. Add another custom extension – maybe `"music_style"`? – and overwrite it.
|
||
> 2. Change the extension attribute to use only a `getter` function. You should
|
||
> see that spaCy raises an error, because the attribute is not writable
|
||
> anymore.
|
||
> 3. Rewrite the code to split a token with `retokenizer.split`. Remember that
|
||
> you need to provide a list of extension attribute values as the `"_"`
|
||
> property, one for each split subtoken.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
from spacy.tokens import Token
|
||
|
||
# Register a custom token attribute, token._.is_musician
|
||
Token.set_extension("is_musician", default=False)
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp("I like David Bowie")
|
||
print("Before:", [(token.text, token._.is_musician) for token in doc])
|
||
|
||
with doc.retokenize() as retokenizer:
|
||
retokenizer.merge(doc[2:4], attrs={"_": {"is_musician": True}})
|
||
print("After:", [(token.text, token._.is_musician) for token in doc])
|
||
```
|
||
|
||
## Sentence Segmentation {id="sbd"}
|
||
|
||
A [`Doc`](/api/doc) object's sentences are available via the `Doc.sents`
|
||
property. To view a `Doc`'s sentences, you can iterate over the `Doc.sents`, a
|
||
generator that yields [`Span`](/api/span) objects. You can check whether a `Doc`
|
||
has sentence boundaries by calling
|
||
[`Doc.has_annotation`](/api/doc#has_annotation) with the attribute name
|
||
`"SENT_START"`.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp("This is a sentence. This is another sentence.")
|
||
assert doc.has_annotation("SENT_START")
|
||
for sent in doc.sents:
|
||
print(sent.text)
|
||
```
|
||
|
||
spaCy provides four alternatives for sentence segmentation:
|
||
|
||
1. [Dependency parser](#sbd-parser): the statistical
|
||
[`DependencyParser`](/api/dependencyparser) provides the most accurate
|
||
sentence boundaries based on full dependency parses.
|
||
2. [Statistical sentence segmenter](#sbd-senter): the statistical
|
||
[`SentenceRecognizer`](/api/sentencerecognizer) is a simpler and faster
|
||
alternative to the parser that only sets sentence boundaries.
|
||
3. [Rule-based pipeline component](#sbd-component): the rule-based
|
||
[`Sentencizer`](/api/sentencizer) sets sentence boundaries using a
|
||
customizable list of sentence-final punctuation.
|
||
4. [Custom function](#sbd-custom): your own custom function added to the
|
||
processing pipeline can set sentence boundaries by writing to
|
||
`Token.is_sent_start`.
|
||
|
||
### Default: Using the dependency parse {id="sbd-parser",model="parser"}
|
||
|
||
Unlike other libraries, spaCy uses the dependency parse to determine sentence
|
||
boundaries. This is usually the most accurate approach, but it requires a
|
||
**trained pipeline** that provides accurate predictions. If your texts are
|
||
closer to general-purpose news or web text, this should work well out-of-the-box
|
||
with spaCy's provided trained pipelines. For social media or conversational text
|
||
that doesn't follow the same rules, your application may benefit from a custom
|
||
trained or rule-based component.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp("This is a sentence. This is another sentence.")
|
||
for sent in doc.sents:
|
||
print(sent.text)
|
||
```
|
||
|
||
spaCy's dependency parser respects already set boundaries, so you can preprocess
|
||
your `Doc` using custom components _before_ it's parsed. Depending on your text,
|
||
this may also improve parse accuracy, since the parser is constrained to predict
|
||
parses consistent with the sentence boundaries.
|
||
|
||
### Statistical sentence segmenter {id="sbd-senter",model="senter",version="3"}
|
||
|
||
The [`SentenceRecognizer`](/api/sentencerecognizer) is a simple statistical
|
||
component that only provides sentence boundaries. Along with being faster and
|
||
smaller than the parser, its primary advantage is that it's easier to train
|
||
because it only requires annotated sentence boundaries rather than full
|
||
dependency parses. spaCy's [trained pipelines](/models) include both a parser
|
||
and a trained sentence segmenter, which is
|
||
[disabled](/usage/processing-pipelines#disabling) by default. If you only need
|
||
sentence boundaries and no parser, you can use the `exclude` or `disable`
|
||
argument on [`spacy.load`](/api/top-level#spacy.load) to load the pipeline
|
||
without the parser and then enable the sentence recognizer explicitly with
|
||
[`nlp.enable_pipe`](/api/language#enable_pipe).
|
||
|
||
> #### senter vs. parser
|
||
>
|
||
> The recall for the `senter` is typically slightly lower than for the parser,
|
||
> which is better at predicting sentence boundaries when punctuation is not
|
||
> present.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
|
||
nlp = spacy.load("en_core_web_sm", exclude=["parser"])
|
||
nlp.enable_pipe("senter")
|
||
doc = nlp("This is a sentence. This is another sentence.")
|
||
for sent in doc.sents:
|
||
print(sent.text)
|
||
```
|
||
|
||
### Rule-based pipeline component {id="sbd-component"}
|
||
|
||
The [`Sentencizer`](/api/sentencizer) component is a
|
||
[pipeline component](/usage/processing-pipelines) that splits sentences on
|
||
punctuation like `.`, `!` or `?`. You can plug it into your pipeline if you only
|
||
need sentence boundaries without dependency parses.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
from spacy.lang.en import English
|
||
|
||
nlp = English() # just the language with no pipeline
|
||
nlp.add_pipe("sentencizer")
|
||
doc = nlp("This is a sentence. This is another sentence.")
|
||
for sent in doc.sents:
|
||
print(sent.text)
|
||
```
|
||
|
||
### Custom rule-based strategy {id="sbd-custom"}
|
||
|
||
If you want to implement your own strategy that differs from the default
|
||
rule-based approach of splitting on sentences, you can also create a
|
||
[custom pipeline component](/usage/processing-pipelines#custom-components) that
|
||
takes a `Doc` object and sets the `Token.is_sent_start` attribute on each
|
||
individual token. If set to `False`, the token is explicitly marked as _not_ the
|
||
start of a sentence. If set to `None` (default), it's treated as a missing value
|
||
and can still be overwritten by the parser.
|
||
|
||
<Infobox title="Important note" variant="warning">
|
||
|
||
To prevent inconsistent state, you can only set boundaries **before** a document
|
||
is parsed (and `doc.has_annotation("DEP")` is `False`). To ensure that your
|
||
component is added in the right place, you can set `before='parser'` or
|
||
`first=True` when adding it to the pipeline using
|
||
[`nlp.add_pipe`](/api/language#add_pipe).
|
||
|
||
</Infobox>
|
||
|
||
Here's an example of a component that implements a pre-processing rule for
|
||
splitting on `"..."` tokens. The component is added before the parser, which is
|
||
then used to further segment the text. That's possible, because `is_sent_start`
|
||
is only set to `True` for some of the tokens – all others still specify `None`
|
||
for unset sentence boundaries. This approach can be useful if you want to
|
||
implement **additional** rules specific to your data, while still being able to
|
||
take advantage of dependency-based sentence segmentation.
|
||
|
||
```python {executable="true"}
|
||
from spacy.language import Language
|
||
import spacy
|
||
|
||
text = "this is a sentence...hello...and another sentence."
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
doc = nlp(text)
|
||
print("Before:", [sent.text for sent in doc.sents])
|
||
|
||
@Language.component("set_custom_boundaries")
|
||
def set_custom_boundaries(doc):
|
||
for token in doc[:-1]:
|
||
if token.text == "...":
|
||
doc[token.i + 1].is_sent_start = True
|
||
return doc
|
||
|
||
nlp.add_pipe("set_custom_boundaries", before="parser")
|
||
doc = nlp(text)
|
||
print("After:", [sent.text for sent in doc.sents])
|
||
```
|
||
|
||
## Mappings & Exceptions {id="mappings-exceptions",version="3"}
|
||
|
||
The [`AttributeRuler`](/api/attributeruler) manages **rule-based mappings and
|
||
exceptions** for all token-level attributes. As the number of
|
||
[pipeline components](/api/#architecture-pipeline) has grown from spaCy v2 to
|
||
v3, handling rules and exceptions in each component individually has become
|
||
impractical, so the `AttributeRuler` provides a single component with a unified
|
||
pattern format for all token attribute mappings and exceptions.
|
||
|
||
The `AttributeRuler` uses
|
||
[`Matcher` patterns](/usage/rule-based-matching#adding-patterns) to identify
|
||
tokens and then assigns them the provided attributes. If needed, the
|
||
[`Matcher`](/api/matcher) patterns can include context around the target token.
|
||
For example, the attribute ruler can:
|
||
|
||
- provide exceptions for any **token attributes**
|
||
- map **fine-grained tags** to **coarse-grained tags** for languages without
|
||
statistical morphologizers (replacing the v2.x `tag_map` in the
|
||
[language data](#language-data))
|
||
- map token **surface form + fine-grained tags** to **morphological features**
|
||
(replacing the v2.x `morph_rules` in the [language data](#language-data))
|
||
- specify the **tags for space tokens** (replacing hard-coded behavior in the
|
||
tagger)
|
||
|
||
The following example shows how the tag and POS `NNP`/`PROPN` can be specified
|
||
for the phrase `"The Who"`, overriding the tags provided by the statistical
|
||
tagger and the POS tag map.
|
||
|
||
```python {executable="true"}
|
||
import spacy
|
||
|
||
nlp = spacy.load("en_core_web_sm")
|
||
text = "I saw The Who perform. Who did you see?"
|
||
doc1 = nlp(text)
|
||
print(doc1[2].tag_, doc1[2].pos_) # DT DET
|
||
print(doc1[3].tag_, doc1[3].pos_) # WP PRON
|
||
|
||
# Add attribute ruler with exception for "The Who" as NNP/PROPN NNP/PROPN
|
||
ruler = nlp.get_pipe("attribute_ruler")
|
||
# Pattern to match "The Who"
|
||
patterns = [[{"LOWER": "the"}, {"TEXT": "Who"}]]
|
||
# The attributes to assign to the matched token
|
||
attrs = {"TAG": "NNP", "POS": "PROPN"}
|
||
# Add rules to the attribute ruler
|
||
ruler.add(patterns=patterns, attrs=attrs, index=0) # "The" in "The Who"
|
||
ruler.add(patterns=patterns, attrs=attrs, index=1) # "Who" in "The Who"
|
||
|
||
doc2 = nlp(text)
|
||
print(doc2[2].tag_, doc2[2].pos_) # NNP PROPN
|
||
print(doc2[3].tag_, doc2[3].pos_) # NNP PROPN
|
||
# The second "Who" remains unmodified
|
||
print(doc2[5].tag_, doc2[5].pos_) # WP PRON
|
||
```
|
||
|
||
<Infobox variant="warning" title="Migrating from spaCy v2.x">
|
||
|
||
The [`AttributeRuler`](/api/attributeruler) can import a **tag map and morph
|
||
rules** in the v2.x format via its built-in methods or when the component is
|
||
initialized before training. See the
|
||
[migration guide](/usage/v3#migrating-training-mappings-exceptions) for details.
|
||
|
||
</Infobox>
|
||
|
||
## Word vectors and semantic similarity {id="vectors-similarity"}
|
||
|
||
<Vectors101 />
|
||
|
||
### Adding word vectors {id="adding-vectors"}
|
||
|
||
Custom word vectors can be trained using a number of open-source libraries, such
|
||
as [Gensim](https://radimrehurek.com/gensim), [FastText](https://fasttext.cc),
|
||
or Tomas Mikolov's original
|
||
[Word2vec implementation](https://code.google.com/archive/p/word2vec/). Most
|
||
word vector libraries output an easy-to-read text-based format, where each line
|
||
consists of the word followed by its vector. For everyday use, we want to
|
||
convert the vectors into a binary format that loads faster and takes up less
|
||
space on disk. The easiest way to do this is the
|
||
[`init vectors`](/api/cli#init-vectors) command-line utility. This will output a
|
||
blank spaCy pipeline in the directory `/tmp/la_vectors_wiki_lg`, giving you
|
||
access to some nice Latin vectors. You can then pass the directory path to
|
||
[`spacy.load`](/api/top-level#spacy.load) or use it in the
|
||
[`[initialize]`](/api/data-formats#config-initialize) of your config when you
|
||
[train](/usage/training) a model.
|
||
|
||
> #### Usage example
|
||
>
|
||
> ```python
|
||
> nlp_latin = spacy.load("/tmp/la_vectors_wiki_lg")
|
||
> doc1 = nlp_latin("Caecilius est in horto")
|
||
> doc2 = nlp_latin("servus est in atrio")
|
||
> doc1.similarity(doc2)
|
||
> ```
|
||
|
||
```bash
|
||
$ wget https://dl.fbaipublicfiles.com/fasttext/vectors-crawl/cc.la.300.vec.gz
|
||
$ python -m spacy init vectors en cc.la.300.vec.gz /tmp/la_vectors_wiki_lg
|
||
```
|
||
|
||
<Accordion title="How to optimize vector coverage" id="custom-vectors-coverage" spaced>
|
||
|
||
To help you strike a good balance between coverage and memory usage, spaCy's
|
||
[`Vectors`](/api/vectors) class lets you map **multiple keys** to the **same
|
||
row** of the table. If you're using the
|
||
[`spacy init vectors`](/api/cli#init-vectors) command to create a vocabulary,
|
||
pruning the vectors will be taken care of automatically if you set the `--prune`
|
||
flag. You can also do it manually in the following steps:
|
||
|
||
1. Start with a **word vectors package** that covers a huge vocabulary. For
|
||
instance, the [`en_core_web_lg`](/models/en#en_core_web_lg) package provides
|
||
300-dimensional GloVe vectors for 685k terms of English.
|
||
2. If your vocabulary has values set for the `Lexeme.prob` attribute, the
|
||
lexemes will be sorted by descending probability to determine which vectors
|
||
to prune. Otherwise, lexemes will be sorted by their order in the `Vocab`.
|
||
3. Call [`Vocab.prune_vectors`](/api/vocab#prune_vectors) with the number of
|
||
vectors you want to keep.
|
||
|
||
```python
|
||
nlp = spacy.load("en_core_web_lg")
|
||
n_vectors = 105000 # number of vectors to keep
|
||
removed_words = nlp.vocab.prune_vectors(n_vectors)
|
||
|
||
assert len(nlp.vocab.vectors) <= n_vectors # unique vectors have been pruned
|
||
assert nlp.vocab.vectors.n_keys > n_vectors # but not the total entries
|
||
```
|
||
|
||
[`Vocab.prune_vectors`](/api/vocab#prune_vectors) reduces the current vector
|
||
table to a given number of unique entries, and returns a dictionary containing
|
||
the removed words, mapped to `(string, score)` tuples, where `string` is the
|
||
entry the removed word was mapped to and `score` the similarity score between
|
||
the two words.
|
||
|
||
```python {title="Removed words"}
|
||
{
|
||
"Shore": ("coast", 0.732257),
|
||
"Precautionary": ("caution", 0.490973),
|
||
"hopelessness": ("sadness", 0.742366),
|
||
"Continous": ("continuous", 0.732549),
|
||
"Disemboweled": ("corpse", 0.499432),
|
||
"biostatistician": ("scientist", 0.339724),
|
||
"somewheres": ("somewheres", 0.402736),
|
||
"observing": ("observe", 0.823096),
|
||
"Leaving": ("leaving", 1.0),
|
||
}
|
||
```
|
||
|
||
In the example above, the vector for "Shore" was removed and remapped to the
|
||
vector of "coast", which is deemed about 73% similar. "Leaving" was remapped to
|
||
the vector of "leaving", which is identical. If you're using the
|
||
[`init vectors`](/api/cli#init-vectors) command, you can set the `--prune`
|
||
option to easily reduce the size of the vectors as you add them to a spaCy
|
||
pipeline:
|
||
|
||
```bash
|
||
$ python -m spacy init vectors en la.300d.vec.tgz /tmp/la_vectors_web_md --prune 10000
|
||
```
|
||
|
||
This will create a blank spaCy pipeline with vectors for the first 10,000 words
|
||
in the vectors. All other words in the vectors are mapped to the closest vector
|
||
among those retained.
|
||
|
||
</Accordion>
|
||
|
||
### Adding vectors individually {id="adding-individual-vectors"}
|
||
|
||
The `vector` attribute is a **read-only** numpy or cupy array (depending on
|
||
whether you've configured spaCy to use GPU memory), with dtype `float32`. The
|
||
array is read-only so that spaCy can avoid unnecessary copy operations where
|
||
possible. You can modify the vectors via the [`Vocab`](/api/vocab) or
|
||
[`Vectors`](/api/vectors) table. Using the
|
||
[`Vocab.set_vector`](/api/vocab#set_vector) method is often the easiest approach
|
||
if you have vectors in an arbitrary format, as you can read in the vectors with
|
||
your own logic, and just set them with a simple loop. This method is likely to
|
||
be slower than approaches that work with the whole vectors table at once, but
|
||
it's a great approach for once-off conversions before you save out your `nlp`
|
||
object to disk.
|
||
|
||
```python {title="Adding vectors"}
|
||
from spacy.vocab import Vocab
|
||
|
||
vector_data = {
|
||
"dog": numpy.random.uniform(-1, 1, (300,)),
|
||
"cat": numpy.random.uniform(-1, 1, (300,)),
|
||
"orange": numpy.random.uniform(-1, 1, (300,))
|
||
}
|
||
vocab = Vocab()
|
||
for word, vector in vector_data.items():
|
||
vocab.set_vector(word, vector)
|
||
```
|
||
|
||
## Language Data {id="language-data"}
|
||
|
||
<LanguageData101 />
|
||
|
||
### Creating a custom language subclass {id="language-subclass"}
|
||
|
||
If you want to customize multiple components of the language data or add support
|
||
for a custom language or domain-specific "dialect", you can also implement your
|
||
own language subclass. The subclass should define two attributes: the `lang`
|
||
(unique language code) and the `Defaults` defining the language data. For an
|
||
overview of the available attributes that can be overwritten, see the
|
||
[`Language.Defaults`](/api/language#defaults) documentation.
|
||
|
||
```python {executable="true"}
|
||
from spacy.lang.en import English
|
||
|
||
class CustomEnglishDefaults(English.Defaults):
|
||
stop_words = set(["custom", "stop"])
|
||
|
||
class CustomEnglish(English):
|
||
lang = "custom_en"
|
||
Defaults = CustomEnglishDefaults
|
||
|
||
nlp1 = English()
|
||
nlp2 = CustomEnglish()
|
||
|
||
print(nlp1.lang, [token.is_stop for token in nlp1("custom stop")])
|
||
print(nlp2.lang, [token.is_stop for token in nlp2("custom stop")])
|
||
```
|
||
|
||
The [`@spacy.registry.languages`](/api/top-level#registry) decorator lets you
|
||
register a custom language class and assign it a string name. This means that
|
||
you can call [`spacy.blank`](/api/top-level#spacy.blank) with your custom
|
||
language name, and even train pipelines with it and refer to it in your
|
||
[training config](/usage/training#config).
|
||
|
||
> #### Config usage
|
||
>
|
||
> After registering your custom language class using the `languages` registry,
|
||
> you can refer to it in your [training config](/usage/training#config). This
|
||
> means spaCy will train your pipeline using the custom subclass.
|
||
>
|
||
> ```ini
|
||
> [nlp]
|
||
> lang = "custom_en"
|
||
> ```
|
||
>
|
||
> In order to resolve `"custom_en"` to your subclass, the registered function
|
||
> needs to be available during training. You can load a Python file containing
|
||
> the code using the `--code` argument:
|
||
>
|
||
> ```bash
|
||
> python -m spacy train config.cfg --code code.py
|
||
> ```
|
||
|
||
```python {title="Registering a custom language",highlight="7,12-13"}
|
||
import spacy
|
||
from spacy.lang.en import English
|
||
|
||
class CustomEnglishDefaults(English.Defaults):
|
||
stop_words = set(["custom", "stop"])
|
||
|
||
@spacy.registry.languages("custom_en")
|
||
class CustomEnglish(English):
|
||
lang = "custom_en"
|
||
Defaults = CustomEnglishDefaults
|
||
|
||
# This now works! 🎉
|
||
nlp = spacy.blank("custom_en")
|
||
```
|