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Models | Downloadable pretrained models for spaCy |
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The models directory includes two types of pretrained models:
- Core models: General-purpose pretrained models to predict named entities, part-of-speech tags and syntactic dependencies. Can be used out-of-the-box and fine-tuned on more specific data.
- Starter models: Transfer learning starter packs with pretrained weights you can initialize your models with to achieve better accuracy. They can include word vectors (which will be used as features during training) or other pretrained representations like BERT. These models don't include components for specific tasks like NER or text classification and are intended to be used as base models when training your own models.
Quickstart
import QuickstartModels from 'widgets/quickstart-models.js'
For more details on how to use models with spaCy, see the usage guide on models.
Model architecture
spaCy v2.0 features new neural models for tagging, parsing and entity recognition. The models have been designed and implemented from scratch specifically for spaCy, to give you an unmatched balance of speed, size and accuracy. A novel bloom embedding strategy with subword features is used to support huge vocabularies in tiny tables. Convolutional layers with residual connections, layer normalization and maxout non-linearity are used, giving much better efficiency than the standard BiLSTM solution.
The parser and NER use an imitation learning objective to deliver accuracy in-line with the latest research systems, even when evaluated from raw text. With these innovations, spaCy v2.0's models are 10× smaller, 20% more accurate, and even cheaper to run than the previous generation. The current architecture hasn't been published yet, but in the meantime we prepared a video that explains how the models work, with particular focus on NER.
The parsing model is a blend of recent results. The two recent inspirations have been the work of Eli Klipperwasser and Yoav Goldberg at Bar Ilan[^1], and the SyntaxNet team from Google. The foundation of the parser is still based on the work of Joakim Nivre[^2], who introduced the transition-based framework[^3], the arc-eager transition system, and the imitation learning objective. The model is implemented using Thinc, spaCy's machine learning library. We first predict context-sensitive vectors for each word in the input:
(embed_lower | embed_prefix | embed_suffix | embed_shape)
>> Maxout(token_width)
>> convolution ** 4
This convolutional layer is shared between the tagger, parser and NER, and will also be shared by the future neural lemmatizer. Because the parser shares these layers with the tagger, the parser does not require tag features. I got this trick from David Weiss's "Stack Combination" paper[^4].
To boost the representation, the tagger actually predicts a "super tag" with POS, morphology and dependency label[^5]. The tagger predicts these supertags by adding a softmax layer onto the convolutional layer – so, we're teaching the convolutional layer to give us a representation that's one affine transform from this informative lexical information. This is obviously good for the parser (which backprops to the convolutions, too). The parser model makes a state vector by concatenating the vector representations for its context tokens. The current context tokens:
Context tokens | Description |
---|---|
S0 , S1 , S2 |
Top three words on the stack. |
B0 , B1 |
First two words of the buffer. |
S0L1 , S1L1 , S2L1 , B0L1 , B1L1 S0L2 , S1L2 , S2L2 , B0L2 , B1L2 |
Leftmost and second leftmost children of S0 , S1 , S2 , B0 and B1 . |
S0R1 , S1R1 , S2R1 , B0R1 , B1R1 S0R2 , S1R2 , S2R2 , B0R2 , B1R2 |
Rightmost and second rightmost children of S0 , S1 , S2 , B0 and B1 . |
This makes the state vector quite long: 13*T
, where T
is the token vector
width (128 is working well). Fortunately, there's a way to structure the
computation to save some expense (and make it more GPU-friendly).
The parser typically visits 2*N
states for a sentence of length N
(although
it may visit more, if it back-tracks with a non-monotonic transition[^4]). A
naive implementation would require 2*N (B, 13*T) @ (13*T, H)
matrix
multiplications for a batch of size B
. We can instead perform one
(B*N, T) @ (T, 13*H)
multiplication, to pre-compute the hidden weights for
each positional feature with respect to the words in the batch. (Note that our
token vectors come from the CNN — so we can't play this trick over the
vocabulary. That's how Stanford's NN parser[^3] works — and why its model is so
big.)
This pre-computation strategy allows a nice compromise between GPU-friendliness and implementation simplicity. The CNN and the wide lower layer are computed on the GPU, and then the precomputed hidden weights are moved to the CPU, before we start the transition-based parsing process. This makes a lot of things much easier. We don't have to worry about variable-length batch sizes, and we don't have to implement the dynamic oracle in CUDA to train.
Currently the parser's loss function is multi-label log loss[^6], as the dynamic
oracle allows multiple states to be 0 cost. This is defined as follows, where
gZ
is the sum of the scores assigned to gold classes:
(exp(score) / Z) - (exp(score) / gZ)
- Simple and Accurate Dependency Parsing Using Bidirectional LSTM Feature Representations {#fn-1}. Eliyahu Kiperwasser, Yoav Goldberg. (2016)
- A Dynamic Oracle for Arc-Eager Dependency Parsing {#fn-2}. Yoav Goldberg, Joakim Nivre (2012)
- Parsing English in 500 Lines of Python {#fn-3}. Matthew Honnibal (2013)
- Stack-propagation: Improved Representation Learning for Syntax {#fn-4}. Yuan Zhang, David Weiss (2016)
- Deep multi-task learning with low level tasks supervised at lower layers {#fn-5}. Anders Søgaard, Yoav Goldberg (2016)
- An Improved Non-monotonic Transition System for Dependency Parsing {#fn-6}. Matthew Honnibal, Mark Johnson (2015)
- A Fast and Accurate Dependency Parser using Neural Networks {#fn-7}. Danqi Cheng, Christopher D. Manning (2014)
- Parsing the Wall Street Journal using a Lexical-Functional Grammar and Discriminative Estimation Techniques {#fn-8}. Stefan Riezler et al. (2002)
Model naming conventions
In general, spaCy expects all model packages to follow the naming convention of
[lang
_[name]]. For spaCy's models, we also chose to divide the name into
three components:
- Type: Model capabilities (e.g.
core
for general-purpose model with vocabulary, syntax, entities and word vectors, ordepent
for only vocab, syntax and entities). - Genre: Type of text the model is trained on, e.g.
web
ornews
. - Size: Model size indicator,
sm
,md
orlg
.
For example, en_core_web_sm
is a small English model trained on written web
text (blogs, news, comments), that includes vocabulary, vectors, syntax and
entities.
Model versioning
Additionally, the model versioning reflects both the compatibility with spaCy,
as well as the major and minor model version. A model version a.b.c
translates
to:
a
: spaCy major version. For example,2
for spaCy v2.x.b
: Model major version. Models with a different major version can't be loaded by the same code. For example, changing the width of the model, adding hidden layers or changing the activation changes the model major version.c
: Model minor version. Same model structure, but different parameter values, e.g. from being trained on different data, for different numbers of iterations, etc.
For a detailed compatibility overview, see the
compatibility.json
in the models repository. This is also the source of spaCy's internal
compatibility check, performed when you run the download
command.