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227 lines
9.5 KiB
Markdown
227 lines
9.5 KiB
Markdown
---
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title: Word Vectors and Semantic Similarity
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menu:
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- ['Basics', 'basics']
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- ['Custom Vectors', 'custom']
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- ['GPU Usage', 'gpu']
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---
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## Basics {#basics hidden="true"}
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> #### Training word vectors
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>
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> Dense, real valued vectors representing distributional similarity information
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> are now a cornerstone of practical NLP. The most common way to train these
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> vectors is the [Word2vec](https://en.wikipedia.org/wiki/Word2vec) family of
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> algorithms. If you need to train a word2vec model, we recommend the
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> implementation in the Python library
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> [Gensim](https://radimrehurek.com/gensim/).
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import Vectors101 from 'usage/101/\_vectors-similarity.md'
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<Vectors101 />
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## Customizing word vectors {#custom}
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Word vectors let you import knowledge from raw text into your model. The
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knowledge is represented as a table of numbers, with one row per term in your
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vocabulary. If two terms are used in similar contexts, the algorithm that learns
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the vectors should assign them **rows that are quite similar**, while words that
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are used in different contexts will have quite different values. This lets you
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use the row-values assigned to the words as a kind of dictionary, to tell you
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some things about what the words in your text mean.
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Word vectors are particularly useful for terms which **aren't well represented
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in your labelled training data**. For instance, if you're doing named entity
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recognition, there will always be lots of names that you don't have examples of.
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For instance, imagine your training data happens to contain some examples of the
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term "Microsoft", but it doesn't contain any examples of the term "Symantec". In
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your raw text sample, there are plenty of examples of both terms, and they're
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used in similar contexts. The word vectors make that fact available to the
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entity recognition model. It still won't see examples of "Symantec" labelled as
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a company. However, it'll see that "Symantec" has a word vector that usually
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corresponds to company terms, so it can **make the inference**.
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In order to make best use of the word vectors, you want the word vectors table
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to cover a **very large vocabulary**. However, most words are rare, so most of
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the rows in a large word vectors table will be accessed very rarely, or never at
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all. You can usually cover more than **95% of the tokens** in your corpus with
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just **a few thousand rows** in the vector table. However, it's those **5% of
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rare terms** where the word vectors are **most useful**. The problem is that
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increasing the size of the vector table produces rapidly diminishing returns in
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coverage over these rare terms.
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### Converting word vectors for use in spaCy {#converting new="2.0.10"}
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Custom word vectors can be trained using a number of open-source libraries, such
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as [Gensim](https://radimrehurek.com/gensim), [Fast Text](https://fasttext.cc),
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or Tomas Mikolov's original
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[word2vec implementation](https://code.google.com/archive/p/word2vec/). Most
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word vector libraries output an easy-to-read text-based format, where each line
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consists of the word followed by its vector. For everyday use, we want to
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convert the vectors model into a binary format that loads faster and takes up
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less space on disk. The easiest way to do this is the
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[`init-model`](/api/cli#init-model) command-line utility:
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```bash
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wget https://s3-us-west-1.amazonaws.com/fasttext-vectors/word-vectors-v2/cc.la.300.vec.gz
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python -m spacy init-model en /tmp/la_vectors_wiki_lg --vectors-loc cc.la.300.vec.gz
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```
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This will output a spaCy model in the directory `/tmp/la_vectors_wiki_lg`,
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giving you access to some nice Latin vectors 😉 You can then pass the directory
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path to [`spacy.load()`](/api/top-level#spacy.load).
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```python
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nlp_latin = spacy.load("/tmp/la_vectors_wiki_lg")
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doc1 = nlp_latin("Caecilius est in horto")
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doc2 = nlp_latin("servus est in atrio")
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doc1.similarity(doc2)
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```
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The model directory will have a `/vocab` directory with the strings, lexical
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entries and word vectors from the input vectors model. The
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[`init-model`](/api/cli#init-model) command supports a number of archive formats
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for the word vectors: the vectors can be in plain text (`.txt`), zipped
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(`.zip`), or tarred and zipped (`.tgz`).
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### Optimizing vector coverage {#custom-vectors-coverage new="2"}
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To help you strike a good balance between coverage and memory usage, spaCy's
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[`Vectors`](/api/vectors) class lets you map **multiple keys** to the **same
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row** of the table. If you're using the
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[`spacy init-model`](/api/cli#init-model) command to create a vocabulary,
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pruning the vectors will be taken care of automatically if you set the
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`--prune-vectors` flag. You can also do it manually in the following steps:
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1. Start with a **word vectors model** that covers a huge vocabulary. For
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instance, the [`en_vectors_web_lg`](/models/en-starters#en_vectors_web_lg)
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model provides 300-dimensional GloVe vectors for over 1 million terms of
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English.
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2. If your vocabulary has values set for the `Lexeme.prob` attribute, the
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lexemes will be sorted by descending probability to determine which vectors
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to prune. Otherwise, lexemes will be sorted by their order in the `Vocab`.
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3. Call [`Vocab.prune_vectors`](/api/vocab#prune_vectors) with the number of
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vectors you want to keep.
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```python
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nlp = spacy.load('en_vectors_web_lg')
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n_vectors = 105000 # number of vectors to keep
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removed_words = nlp.vocab.prune_vectors(n_vectors)
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assert len(nlp.vocab.vectors) <= n_vectors # unique vectors have been pruned
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assert nlp.vocab.vectors.n_keys > n_vectors # but not the total entries
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```
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[`Vocab.prune_vectors`](/api/vocab#prune_vectors) reduces the current vector
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table to a given number of unique entries, and returns a dictionary containing
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the removed words, mapped to `(string, score)` tuples, where `string` is the
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entry the removed word was mapped to, and `score` the similarity score between
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the two words.
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```python
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### Removed words
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{
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"Shore": ("coast", 0.732257),
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"Precautionary": ("caution", 0.490973),
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"hopelessness": ("sadness", 0.742366),
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"Continous": ("continuous", 0.732549),
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"Disemboweled": ("corpse", 0.499432),
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"biostatistician": ("scientist", 0.339724),
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"somewheres": ("somewheres", 0.402736),
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"observing": ("observe", 0.823096),
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"Leaving": ("leaving", 1.0),
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}
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```
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In the example above, the vector for "Shore" was removed and remapped to the
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vector of "coast", which is deemed about 73% similar. "Leaving" was remapped to
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the vector of "leaving", which is identical.
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If you're using the [`init-model`](/api/cli#init-model) command, you can set the
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`--prune-vectors` option to easily reduce the size of the vectors as you add
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them to a spaCy model:
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```bash
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$ python -m spacy init-model /tmp/la_vectors_web_md --vectors-loc la.300d.vec.tgz --prune-vectors 10000
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```
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This will create a spaCy model with vectors for the first 10,000 words in the
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vectors model. All other words in the vectors model are mapped to the closest
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vector among those retained.
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### Adding vectors {#custom-vectors-add new="2"}
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spaCy's new [`Vectors`](/api/vectors) class greatly improves the way word
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vectors are stored, accessed and used. The data is stored in two structures:
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- An array, which can be either on CPU or [GPU](#gpu).
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- A dictionary mapping string-hashes to rows in the table.
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Keep in mind that the `Vectors` class itself has no
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[`StringStore`](/api/stringstore), so you have to store the hash-to-string
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mapping separately. If you need to manage the strings, you should use the
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`Vectors` via the [`Vocab`](/api/vocab) class, e.g. `vocab.vectors`. To add
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vectors to the vocabulary, you can use the
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[`Vocab.set_vector`](/api/vocab#set_vector) method.
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```python
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### Adding vectors
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from spacy.vocab import Vocab
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vector_data = {"dog": numpy.random.uniform(-1, 1, (300,)),
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"cat": numpy.random.uniform(-1, 1, (300,)),
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"orange": numpy.random.uniform(-1, 1, (300,))}
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vocab = Vocab()
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for word, vector in vector_data.items():
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vocab.set_vector(word, vector)
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```
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### Using custom similarity methods {#custom-similarity}
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By default, [`Token.vector`](/api/token#vector) returns the vector for its
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underlying [`Lexeme`](/api/lexeme), while [`Doc.vector`](/api/doc#vector) and
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[`Span.vector`](/api/span#vector) return an average of the vectors of their
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tokens. You can customize these behaviors by modifying the `doc.user_hooks`,
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`doc.user_span_hooks` and `doc.user_token_hooks` dictionaries.
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<Infobox title="📖 Custom user hooks">
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For more details on **adding hooks** and **overwriting** the built-in `Doc`,
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`Span` and `Token` methods, see the usage guide on
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[user hooks](/usage/processing-pipelines#custom-components-user-hooks).
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</Infobox>
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## Storing vectors on a GPU {#gpu}
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If you're using a GPU, it's much more efficient to keep the word vectors on the
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device. You can do that by setting the [`Vectors.data`](/api/vectors#attributes)
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attribute to a `cupy.ndarray` object if you're using spaCy or
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[Chainer](https://chainer.org), or a `torch.Tensor` object if you're using
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[PyTorch](http://pytorch.org). The `data` object just needs to support
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`__iter__` and `__getitem__`, so if you're using another library such as
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[TensorFlow](https://www.tensorflow.org), you could also create a wrapper for
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your vectors data.
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```python
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### spaCy, Thinc or Chainer
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import cupy.cuda
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from spacy.vectors import Vectors
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vector_table = numpy.zeros((3, 300), dtype="f")
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vectors = Vectors(["dog", "cat", "orange"], vector_table)
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with cupy.cuda.Device(0):
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vectors.data = cupy.asarray(vectors.data)
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```
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```python
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### PyTorch
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import torch
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from spacy.vectors import Vectors
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vector_table = numpy.zeros((3, 300), dtype="f")
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vectors = Vectors(["dog", "cat", "orange"], vector_table)
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vectors.data = torch.Tensor(vectors.data).cuda(0)
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```
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