mirror of https://github.com/explosion/spaCy.git
497 lines
22 KiB
Markdown
497 lines
22 KiB
Markdown
---
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title: TrainablePipe
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tag: class
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teaser: Base class for trainable pipeline components
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---
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This class is a base class and **not instantiated directly**. Trainable pipeline
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components like the [`EntityRecognizer`](/api/entityrecognizer) or
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[`TextCategorizer`](/api/textcategorizer) inherit from it and it defines the
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interface that components should follow to function as trainable components in a
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spaCy pipeline. See the docs on
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[writing trainable components](/usage/processing-pipelines#trainable-components)
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for how to use the `TrainablePipe` base class to implement custom components.
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<!-- TODO: Pipe vs TrainablePipe, check methods below (all renamed to TrainablePipe for now) -->
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> #### Why is it implemented in Cython?
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>
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> The `TrainablePipe` class is implemented in a `.pyx` module, the extension
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> used by [Cython](/api/cython). This is needed so that **other** Cython
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> classes, like the [`EntityRecognizer`](/api/entityrecognizer) can inherit from
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> it. But it doesn't mean you have to implement trainable components in Cython –
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> pure Python components like the [`TextCategorizer`](/api/textcategorizer) can
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> also inherit from `TrainablePipe`.
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```python
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%%GITHUB_SPACY/spacy/pipeline/trainable_pipe.pyx
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```
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## TrainablePipe.\_\_init\_\_ {#init tag="method"}
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> #### Example
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>
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> ```python
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> from spacy.pipeline import TrainablePipe
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> from spacy.language import Language
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>
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> class CustomPipe(TrainablePipe):
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> ...
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>
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> @Language.factory("your_custom_pipe", default_config={"model": MODEL})
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> def make_custom_pipe(nlp, name, model):
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> return CustomPipe(nlp.vocab, model, name)
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> ```
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Create a new pipeline instance. In your application, you would normally use a
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shortcut for this and instantiate the component using its string name and
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[`nlp.add_pipe`](/api/language#create_pipe).
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| Name | Description |
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| ------- | -------------------------------------------------------------------------------------------------------------------------- |
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| `vocab` | The shared vocabulary. ~~Vocab~~ |
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| `model` | The Thinc [`Model`](https://thinc.ai/docs/api-model) powering the pipeline component. ~~Model[List[Doc], Any]~~ |
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| `name` | String name of the component instance. Used to add entries to the `losses` during training. ~~str~~ |
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| `**cfg` | Additional config parameters and settings. Will be available as the dictionary `cfg` and is serialized with the component. |
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## TrainablePipe.\_\_call\_\_ {#call tag="method"}
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Apply the pipe to one document. The document is modified in place, and returned.
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This usually happens under the hood when the `nlp` object is called on a text
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and all pipeline components are applied to the `Doc` in order. Both
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[`__call__`](/api/pipe#call) and [`pipe`](/api/pipe#pipe) delegate to the
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[`predict`](/api/pipe#predict) and
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[`set_annotations`](/api/pipe#set_annotations) methods.
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> #### Example
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>
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> ```python
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> doc = nlp("This is a sentence.")
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> pipe = nlp.add_pipe("your_custom_pipe")
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> # This usually happens under the hood
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> processed = pipe(doc)
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> ```
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| Name | Description |
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| ----------- | -------------------------------- |
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| `doc` | The document to process. ~~Doc~~ |
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| **RETURNS** | The processed document. ~~Doc~~ |
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## TrainablePipe.pipe {#pipe tag="method"}
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Apply the pipe to a stream of documents. This usually happens under the hood
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when the `nlp` object is called on a text and all pipeline components are
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applied to the `Doc` in order. Both [`__call__`](/api/pipe#call) and
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[`pipe`](/api/pipe#pipe) delegate to the [`predict`](/api/pipe#predict) and
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[`set_annotations`](/api/pipe#set_annotations) methods.
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> for doc in pipe.pipe(docs, batch_size=50):
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> pass
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> ```
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| Name | Description |
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| -------------- | ------------------------------------------------------------- |
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| `stream` | A stream of documents. ~~Iterable[Doc]~~ |
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| _keyword-only_ | |
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| `batch_size` | The number of documents to buffer. Defaults to `128`. ~~int~~ |
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| **YIELDS** | The processed documents in order. ~~Doc~~ |
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## TrainablePipe.initialize {#initialize tag="method" new="3"}
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Initialize the component for training. `get_examples` should be a function that
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returns an iterable of [`Example`](/api/example) objects. The data examples are
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used to **initialize the model** of the component and can either be the full
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training data or a representative sample. Initialization includes validating the
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network,
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[inferring missing shapes](https://thinc.ai/docs/usage-models#validation) and
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setting up the label scheme based on the data. This method is typically called
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by [`Language.initialize`](/api/language#initialize).
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<Infobox variant="warning" title="Changed in v3.0" id="begin_training">
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This method was previously called `begin_training`.
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</Infobox>
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> pipe.initialize(lambda: [], pipeline=nlp.pipeline)
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> ```
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| Name | Description |
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| -------------- | ------------------------------------------------------------------------------------------------------------------------------------- |
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| `get_examples` | Function that returns gold-standard annotations in the form of [`Example`](/api/example) objects. ~~Callable[[], Iterable[Example]]~~ |
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| _keyword-only_ | |
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| `nlp` | The current `nlp` object. Defaults to `None`. ~~Optional[Language]~~ |
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## TrainablePipe.predict {#predict tag="method"}
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Apply the component's model to a batch of [`Doc`](/api/doc) objects, without
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modifying them.
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<Infobox variant="danger">
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This method needs to be overwritten with your own custom `predict` method.
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</Infobox>
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> scores = pipe.predict([doc1, doc2])
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> ```
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| Name | Description |
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| ----------- | ------------------------------------------- |
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| `docs` | The documents to predict. ~~Iterable[Doc]~~ |
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| **RETURNS** | The model's prediction for each document. |
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## TrainablePipe.set_annotations {#set_annotations tag="method"}
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Modify a batch of [`Doc`](/api/doc) objects, using pre-computed scores.
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<Infobox variant="danger">
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This method needs to be overwritten with your own custom `set_annotations`
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method.
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</Infobox>
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> scores = pipe.predict(docs)
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> pipe.set_annotations(docs, scores)
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> ```
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| Name | Description |
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| -------- | ------------------------------------------------ |
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| `docs` | The documents to modify. ~~Iterable[Doc]~~ |
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| `scores` | The scores to set, produced by `Tagger.predict`. |
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## TrainablePipe.update {#update tag="method"}
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Learn from a batch of [`Example`](/api/example) objects containing the
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predictions and gold-standard annotations, and update the component's model.
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> optimizer = nlp.initialize()
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> losses = pipe.update(examples, sgd=optimizer)
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> ```
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| Name | Description |
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| ----------------- | ---------------------------------------------------------------------------------------------------------------------------------- |
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| `examples` | A batch of [`Example`](/api/example) objects to learn from. ~~Iterable[Example]~~ |
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| _keyword-only_ | |
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| `drop` | The dropout rate. ~~float~~ |
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| `sgd` | An optimizer. Will be created via [`create_optimizer`](#create_optimizer) if not set. ~~Optional[Optimizer]~~ |
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| `losses` | Optional record of the loss during training. Updated using the component name as the key. ~~Optional[Dict[str, float]]~~ |
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| **RETURNS** | The updated `losses` dictionary. ~~Dict[str, float]~~ |
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## TrainablePipe.rehearse {#rehearse tag="method,experimental" new="3"}
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Perform a "rehearsal" update from a batch of data. Rehearsal updates teach the
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current model to make predictions similar to an initial model, to try to address
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the "catastrophic forgetting" problem. This feature is experimental.
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> optimizer = nlp.resume_training()
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> losses = pipe.rehearse(examples, sgd=optimizer)
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> ```
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| Name | Description |
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| -------------- | ------------------------------------------------------------------------------------------------------------------------ |
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| `examples` | A batch of [`Example`](/api/example) objects to learn from. ~~Iterable[Example]~~ |
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| _keyword-only_ | |
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| `sgd` | An optimizer. Will be created via [`create_optimizer`](#create_optimizer) if not set. ~~Optional[Optimizer]~~ |
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| `losses` | Optional record of the loss during training. Updated using the component name as the key. ~~Optional[Dict[str, float]]~~ |
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| **RETURNS** | The updated `losses` dictionary. ~~Dict[str, float]~~ |
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## TrainablePipe.get_loss {#get_loss tag="method"}
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Find the loss and gradient of loss for the batch of documents and their
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predicted scores.
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<Infobox variant="danger">
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This method needs to be overwritten with your own custom `get_loss` method.
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</Infobox>
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> #### Example
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>
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> ```python
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> ner = nlp.add_pipe("ner")
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> scores = ner.predict([eg.predicted for eg in examples])
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> loss, d_loss = ner.get_loss(examples, scores)
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> ```
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| Name | Description |
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| ----------- | --------------------------------------------------------------------------- |
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| `examples` | The batch of examples. ~~Iterable[Example]~~ |
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| `scores` | Scores representing the model's predictions. |
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| **RETURNS** | The loss and the gradient, i.e. `(loss, gradient)`. ~~Tuple[float, float]~~ |
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## TrainablePipe.score {#score tag="method" new="3"}
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Score a batch of examples.
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> #### Example
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>
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> ```python
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> scores = pipe.score(examples)
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> ```
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| Name | Description |
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| ----------- | ------------------------------------------------------------------------------------------------------- |
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| `examples` | The examples to score. ~~Iterable[Example]~~ |
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| **RETURNS** | The scores, e.g. produced by the [`Scorer`](/api/scorer). ~~Dict[str, Union[float, Dict[str, float]]]~~ |
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## TrainablePipe.create_optimizer {#create_optimizer tag="method"}
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Create an optimizer for the pipeline component. Defaults to
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[`Adam`](https://thinc.ai/docs/api-optimizers#adam) with default settings.
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> optimizer = pipe.create_optimizer()
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> ```
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| Name | Description |
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| ----------- | ---------------------------- |
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| **RETURNS** | The optimizer. ~~Optimizer~~ |
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## TrainablePipe.use_params {#use_params tag="method, contextmanager"}
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Modify the pipe's model, to use the given parameter values. At the end of the
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context, the original parameters are restored.
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> with pipe.use_params(optimizer.averages):
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> pipe.to_disk("/best_model")
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> ```
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| Name | Description |
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| -------- | -------------------------------------------------- |
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| `params` | The parameter values to use in the model. ~~dict~~ |
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## TrainablePipe.finish_update {#finish_update tag="method"}
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Update parameters using the current parameter gradients. Defaults to calling
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[`self.model.finish_update`](https://thinc.ai/docs/api-model#finish_update).
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> optimizer = nlp.initialize()
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> losses = pipe.update(examples, sgd=None)
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> pipe.finish_update(sgd)
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> ```
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| Name | Description |
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| ----- | ------------------------------------- |
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| `sgd` | An optimizer. ~~Optional[Optimizer]~~ |
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## TrainablePipe.add_label {#add_label tag="method"}
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> pipe.add_label("MY_LABEL")
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> ```
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Add a new label to the pipe, to be predicted by the model. The actual
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implementation depends on the specific component, but in general `add_label`
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shouldn't be called if the output dimension is already set, or if the model has
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already been fully [initialized](#initialize). If these conditions are violated,
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the function will raise an Error. The exception to this rule is when the
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component is [resizable](#is_resizable), in which case
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[`set_output`](#set_output) should be called to ensure that the model is
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properly resized.
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<Infobox variant="danger">
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This method needs to be overwritten with your own custom `add_label` method.
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</Infobox>
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| Name | Description |
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| ----------- | ------------------------------------------------------- |
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| `label` | The label to add. ~~str~~ |
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| **RETURNS** | 0 if the label is already present, otherwise 1. ~~int~~ |
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Note that in general, you don't have to call `pipe.add_label` if you provide a
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representative data sample to the [`initialize`](#initialize) method. In this
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case, all labels found in the sample will be automatically added to the model,
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and the output dimension will be
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[inferred](/usage/layers-architectures#thinc-shape-inference) automatically.
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## TrainablePipe.is_resizable {#is_resizable tag="property"}
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> #### Example
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>
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> ```python
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> can_resize = pipe.is_resizable
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> ```
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>
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> With custom resizing implemented by a component:
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>
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> ```python
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> def custom_resize(model, new_nO):
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> # adjust model
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> return model
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>
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> custom_model.attrs["resize_output"] = custom_resize
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> ```
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Check whether or not the output dimension of the component's model can be
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resized. If this method returns `True`, [`set_output`](#set_output) can be
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called to change the model's output dimension.
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For built-in components that are not resizable, you have to create and train a
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new model from scratch with the appropriate architecture and output dimension.
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For custom components, you can implement a `resize_output` function and add it
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as an attribute to the component's model.
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| Name | Description |
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| ----------- | ---------------------------------------------------------------------------------------------- |
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| **RETURNS** | Whether or not the output dimension of the model can be changed after initialization. ~~bool~~ |
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## TrainablePipe.set_output {#set_output tag="method"}
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Change the output dimension of the component's model. If the component is not
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[resizable](#is_resizable), this method will raise a `NotImplementedError`. If a
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component is resizable, the model's attribute `resize_output` will be called.
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This is a function that takes the original model and the new output dimension
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`nO`, and changes the model in place. When resizing an already trained model,
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care should be taken to avoid the "catastrophic forgetting" problem.
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> #### Example
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>
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> ```python
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> if pipe.is_resizable:
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> pipe.set_output(512)
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> ```
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| Name | Description |
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| ---- | --------------------------------- |
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| `nO` | The new output dimension. ~~int~~ |
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## TrainablePipe.to_disk {#to_disk tag="method"}
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Serialize the pipe to disk.
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> pipe.to_disk("/path/to/pipe")
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> ```
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| Name | Description |
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| -------------- | ------------------------------------------------------------------------------------------------------------------------------------------ |
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| `path` | A path to a directory, which will be created if it doesn't exist. Paths may be either strings or `Path`-like objects. ~~Union[str, Path]~~ |
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| _keyword-only_ | |
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| `exclude` | String names of [serialization fields](#serialization-fields) to exclude. ~~Iterable[str]~~ |
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## TrainablePipe.from_disk {#from_disk tag="method"}
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Load the pipe from disk. Modifies the object in place and returns it.
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> pipe.from_disk("/path/to/pipe")
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> ```
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| Name | Description |
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| -------------- | ----------------------------------------------------------------------------------------------- |
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| `path` | A path to a directory. Paths may be either strings or `Path`-like objects. ~~Union[str, Path]~~ |
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| _keyword-only_ | |
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| `exclude` | String names of [serialization fields](#serialization-fields) to exclude. ~~Iterable[str]~~ |
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| **RETURNS** | The modified pipe. ~~TrainablePipe~~ |
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## TrainablePipe.to_bytes {#to_bytes tag="method"}
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> #### Example
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>
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> ```python
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> pipe = nlp.add_pipe("your_custom_pipe")
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> pipe_bytes = pipe.to_bytes()
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> ```
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Serialize the pipe to a bytestring.
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| Name | Description |
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| -------------- | ------------------------------------------------------------------------------------------- |
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| _keyword-only_ | |
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| `exclude` | String names of [serialization fields](#serialization-fields) to exclude. ~~Iterable[str]~~ |
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| **RETURNS** | The serialized form of the pipe. ~~bytes~~ |
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## TrainablePipe.from_bytes {#from_bytes tag="method"}
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Load the pipe from a bytestring. Modifies the object in place and returns it.
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> #### Example
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>
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> ```python
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> pipe_bytes = pipe.to_bytes()
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> pipe = nlp.add_pipe("your_custom_pipe")
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> pipe.from_bytes(pipe_bytes)
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> ```
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| Name | Description |
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| -------------- | ------------------------------------------------------------------------------------------- |
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| `bytes_data` | The data to load from. ~~bytes~~ |
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| _keyword-only_ | |
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| `exclude` | String names of [serialization fields](#serialization-fields) to exclude. ~~Iterable[str]~~ |
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| **RETURNS** | The pipe. ~~TrainablePipe~~ |
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## Attributes {#attributes}
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| Name | Description |
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| ------- | --------------------------------------------------------------------------------------------------------------------------------- |
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| `vocab` | The shared vocabulary that's passed in on initialization. ~~Vocab~~ |
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| `model` | The model powering the component. ~~Model[List[Doc], Any]~~ |
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| `name` | The name of the component instance in the pipeline. Can be used in the losses. ~~str~~ |
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| `cfg` | Keyword arguments passed to [`TrainablePipe.__init__`](/api/pipe#init). Will be serialized with the component. ~~Dict[str, Any]~~ |
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## Serialization fields {#serialization-fields}
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During serialization, spaCy will export several data fields used to restore
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different aspects of the object. If needed, you can exclude them from
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serialization by passing in the string names via the `exclude` argument.
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> #### Example
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>
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> ```python
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> data = pipe.to_disk("/path")
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> ```
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| Name | Description |
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| ------- | -------------------------------------------------------------- |
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| `cfg` | The config file. You usually don't want to exclude this. |
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| `model` | The binary model data. You usually don't want to exclude this. |
|