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306 lines
12 KiB
Markdown
---
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title: Transformers
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teaser: Using transformer models like BERT in spaCy
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menu:
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- ['Installation', 'install']
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- ['Runtime Usage', 'runtime']
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- ['Training Usage', 'training']
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next: /usage/training
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---
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## Installation {#install hidden="true"}
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Transformers are a family of neural network architectures that compute **dense,
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context-sensitive representations** for the tokens in your documents. Downstream
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models in your pipeline can then use these representations as input features to
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**improve their predictions**. You can connect multiple components to a single
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transformer model, with any or all of those components giving feedback to the
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transformer to fine-tune it to your tasks. spaCy's transformer support
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interoperates with [PyTorch](https://pytorch.org) and the
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[HuggingFace `transformers`](https://huggingface.co/transformers/) library,
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giving you access to thousands of pretrained models for your pipelines. There
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are many [great guides](http://jalammar.github.io/illustrated-transformer/) to
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transformer models, but for practical purposes, you can simply think of them as
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a drop-in replacement that let you achieve **higher accuracy** in exchange for
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**higher training and runtime costs**.
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### System requirements
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We recommend an NVIDIA GPU with at least 10GB of memory in order to work with
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transformer models. The exact requirements will depend on the transformer you
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model you choose and whether you're training the pipeline or simply running it.
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Training a transformer-based model without a GPU will be too slow for most
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practical purposes. You'll also need to make sure your GPU drivers are
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up-to-date and v9+ of the CUDA runtime is installed.
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Once you have CUDA installed, you'll need to install two pip packages,
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[`cupy`](https://docs.cupy.dev/en/stable/install.html) and
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[`spacy-transformers`](https://github.com/explosion/spacy-transformers). `cupy`
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is just like `numpy`, but for GPU. The best way to install it is to choose a
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wheel that matches the version of CUDA you're using. You may also need to set
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the `CUDA_PATH` environment variable if your CUDA runtime is installed in a
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non-standard location. Putting it all together, if you had installed CUDA 10.2
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in `/opt/nvidia/cuda`, you would run:
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```bash
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### Installation with CUDA
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export CUDA_PATH="/opt/nvidia/cuda"
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pip install cupy-cuda102
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pip install spacy-transformers
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```
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Provisioning a new machine will require about 5GB of data to be downloaded in
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total: 3GB for the CUDA runtime, 800MB for PyTorch, 400MB for CuPy, 500MB for
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the transformer weights, and about 200MB for spaCy and its various requirements.
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## Runtime usage {#runtime}
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Transformer models can be used as **drop-in replacements** for other types of
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neural networks, so your spaCy pipeline can include them in a way that's
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completely invisible to the user. Users will download, load and use the model in
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the standard way, like any other spaCy pipeline. Instead of using the
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transformers as subnetworks directly, you can also use them via the
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[`Transformer`](/api/transformer) pipeline component.
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![The processing pipeline with the transformer component](../images/pipeline_transformer.svg)
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The `Transformer` component sets the
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[`Doc._.trf_data`](/api/transformer#custom_attributes) extension attribute,
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which lets you access the transformers outputs at runtime.
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```bash
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$ python -m spacy download en_core_trf_lg
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```
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```python
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### Example
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import spacy
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from thinc.api import use_pytorch_for_gpu_memory, require_gpu
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# Use the GPU, with memory allocations directed via PyTorch.
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# This prevents out-of-memory errors that would otherwise occur from competing
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# memory pools.
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use_pytorch_for_gpu_memory()
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require_gpu(0)
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nlp = spacy.load("en_core_trf_lg")
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for doc in nlp.pipe(["some text", "some other text"]):
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tokvecs = doc._.trf_data.tensors[-1]
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```
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You can also customize how the [`Transformer`](/api/transformer) component sets
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annotations onto the [`Doc`](/api/doc), by customizing the `annotation_setter`.
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This callback will be called with the raw input and output data for the whole
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batch, along with the batch of `Doc` objects, allowing you to implement whatever
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you need. The annotation setter is called with a batch of [`Doc`](/api/doc)
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objects and a [`FullTransformerBatch`](/api/transformer#fulltransformerbatch)
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containing the transformers data for the batch.
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```python
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def custom_annotation_setter(docs, trf_data):
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# TODO:
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...
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nlp = spacy.load("en_core_trf_lg")
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nlp.get_pipe("transformer").annotation_setter = custom_annotation_setter
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doc = nlp("This is a text")
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print() # TODO:
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```
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## Training usage {#training}
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The recommended workflow for training is to use spaCy's
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[config system](/usage/training#config), usually via the
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[`spacy train`](/api/cli#train) command. The training config defines all
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component settings and hyperparameters in one place and lets you describe a tree
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of objects by referring to creation functions, including functions you register
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yourself. For details on how to get started with training your own model, check
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out the [training quickstart](/usage/training#quickstart).
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<Project id="en_core_bert">
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The easiest way to get started is to clone a transformers-based project
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template. Swap in your data, edit the settings and hyperparameters and train,
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evaluate, package and visualize your model.
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</Project>
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The `[components]` section in the [`config.cfg`](/api/data-formats#config)
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describes the pipeline components and the settings used to construct them,
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including their model implementation. Here's a config snippet for the
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[`Transformer`](/api/transformer) component, along with matching Python code. In
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this case, the `[components.transformer]` block describes the `transformer`
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component:
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> #### Python equivalent
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>
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> ```python
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> from spacy_transformers import Transformer, TransformerModel
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> from spacy_transformers.annotation_setters import null_annotation_setter
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> from spacy_transformers.span_getters import get_doc_spans
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>
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> trf = Transformer(
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> nlp.vocab,
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> TransformerModel(
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> "bert-base-cased",
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> get_spans=get_doc_spans,
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> tokenizer_config={"use_fast": True},
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> ),
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> annotation_setter=null_annotation_setter,
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> max_batch_items=4096,
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> )
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> ```
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```ini
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### config.cfg (excerpt)
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[components.transformer]
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factory = "transformer"
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max_batch_items = 4096
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[components.transformer.model]
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@architectures = "spacy-transformers.TransformerModel.v1"
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name = "bert-base-cased"
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tokenizer_config = {"use_fast": true}
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[components.transformer.model.get_spans]
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@span_getters = "doc_spans.v1"
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[components.transformer.annotation_setter]
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@annotation_setters = "spacy-transformer.null_annotation_setter.v1"
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```
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The `[components.transformer.model]` block describes the `model` argument passed
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to the transformer component. It's a Thinc
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[`Model`](https://thinc.ai/docs/api-model) object that will be passed into the
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component. Here, it references the function
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[spacy-transformers.TransformerModel.v1](/api/architectures#TransformerModel)
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registered in the [`architectures` registry](/api/top-level#registry). If a key
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in a block starts with `@`, it's **resolved to a function** and all other
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settings are passed to the function as arguments. In this case, `name`,
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`tokenizer_config` and `get_spans`.
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`get_spans` is a function that takes a batch of `Doc` object and returns lists
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of potentially overlapping `Span` objects to process by the transformer. Several
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[built-in functions](/api/transformer#span-getters) are available – for example,
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to process the whole document or individual sentences. When the config is
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resolved, the function is created and passed into the model as an argument.
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<Infobox variant="warning">
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Remember that the `config.cfg` used for training should contain **no missing
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values** and requires all settings to be defined. You don't want any hidden
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defaults creeping in and changing your results! spaCy will tell you if settings
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are missing, and you can run
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[`spacy init fill-config`](/api/cli#init-fill-config) to automatically fill in
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all defaults.
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</Infobox>
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### Customizing the settings {#training-custom-settings}
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To change any of the settings, you can edit the `config.cfg` and re-run the
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training. To change any of the functions, like the span getter, you can replace
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the name of the referenced function – e.g. `@span_getters = "sent_spans.v1"` to
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process sentences. You can also register your own functions using the
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`span_getters` registry:
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> #### config.cfg
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>
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> ```ini
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> [components.transformer.model.get_spans]
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> @span_getters = "custom_sent_spans"
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> ```
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```python
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### code.py
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import spacy_transformers
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@spacy_transformers.registry.span_getters("custom_sent_spans")
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def configure_custom_sent_spans():
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# TODO: write custom example
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def get_sent_spans(docs):
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return [list(doc.sents) for doc in docs]
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return get_sent_spans
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```
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To resolve the config during training, spaCy needs to know about your custom
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function. You can make it available via the `--code` argument that can point to
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a Python file. For more details on training with custom code, see the
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[training documentation](/usage/training#custom-code).
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```bash
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$ python -m spacy train ./config.cfg --code ./code.py
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```
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### Customizing the model implementations {#training-custom-model}
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The [`Transformer`](/api/transformer) component expects a Thinc
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[`Model`](https://thinc.ai/docs/api-model) object to be passed in as its `model`
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argument. You're not limited to the implementation provided by
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`spacy-transformers` – the only requirement is that your registered function
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must return an object of type ~~Model[List[Doc], FullTransformerBatch]~~: that
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is, a Thinc model that takes a list of [`Doc`](/api/doc) objects, and returns a
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[`FullTransformerBatch`](/api/transformer#fulltransformerbatch) object with the
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transformer data.
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> #### Model type annotations
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>
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> In the documentation and code base, you may come across type annotations and
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> descriptions of [Thinc](https://thinc.ai) model types, like ~~Model[List[Doc],
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> List[Floats2d]]~~. This so-called generic type describes the layer and its
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> input and output type – in this case, it takes a list of `Doc` objects as the
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> input and list of 2-dimensional arrays of floats as the output. You can read
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> more about defining Thinc models [here](https://thinc.ai/docs/usage-models).
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> Also see the [type checking](https://thinc.ai/docs/usage-type-checking) for
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> how to enable linting in your editor to see live feedback if your inputs and
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> outputs don't match.
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The same idea applies to task models that power the **downstream components**.
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Most of spaCy's built-in model creation functions support a `tok2vec` argument,
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which should be a Thinc layer of type `Model[List[Doc], List[Floats2d]]`. This
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is where we'll plug in our transformer model, using the
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[Tok2VecListener](/api/architectures#Tok2VecListener) layer, which sneakily
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delegates to the `Transformer` pipeline component.
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```ini
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### config.cfg (excerpt) {highlight="12"}
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[components.ner]
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factory = "ner"
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[nlp.pipeline.ner.model]
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@architectures = "spacy.TransitionBasedParser.v1"
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nr_feature_tokens = 3
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hidden_width = 128
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maxout_pieces = 3
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use_upper = false
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[nlp.pipeline.ner.model.tok2vec]
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@architectures = "spacy-transformers.Tok2VecListener.v1"
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grad_factor = 1.0
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[nlp.pipeline.ner.model.tok2vec.pooling]
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@layers = "reduce_mean.v1"
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```
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The [Tok2VecListener](/api/architectures#Tok2VecListener) layer expects a
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[pooling layer](https://thinc.ai/docs/api-layers#reduction-ops) as the argument
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`pooling`, which needs to be of type `Model[Ragged, Floats2d]`. This layer
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determines how the vector for each spaCy token will be computed from the zero or
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more source rows the token is aligned against. Here we use the
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[`reduce_mean`](https://thinc.ai/docs/api-layers#reduce_mean) layer, which
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averages the wordpiece rows. We could instead use
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[`reduce_max`](https://thinc.ai/docs/api-layers#reduce_max), or a custom
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function you write yourself.
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You can have multiple components all listening to the same transformer model,
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and all passing gradients back to it. By default, all of the gradients will be
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**equally weighted**. You can control this with the `grad_factor` setting, which
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lets you reweight the gradients from the different listeners. For instance,
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setting `grad_factor = 0` would disable gradients from one of the listeners,
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while `grad_factor = 2.0` would multiply them by 2. This is similar to having a
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custom learning rate for each component. Instead of a constant, you can also
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provide a schedule, allowing you to freeze the shared parameters at the start of
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training.
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