Compress-fastText
This Python 3 package allows to compress fastText word embedding models
(from the gensim package) by orders of magnitude,
without significantly affecting their quality.
Here are some links to the models that have already been compressed.
This blogpost in Russian and this one in English give more details about the motivation and methods for compressing fastText models.
Note: gensim==4.0.0 has introduced some backward-incompatible changes:
- With gensim<4.0.0, please use compress-fasttext<=0.0.7 (and optionally Russian models from our first release).
- With gensim>=4.0.0, please use compress-fasttext>=0.1.0 (and optionally Russian or English models from our 0.1.0 release).
- Some models are no longer supported in the new version of gensim+compress-fasttext
(for example, multiple models from RusVectores that use
compatible_hash=False). - For any particular model, compatibility should be determined experimentally. If you notice any strange behaviour, please report in the Github issues.
The package can be installed with pip:
pip install compress-fasttext[full]
If you are not going to perform matrix decomposition or quantization, you can install a variety with less dependencies:
pip install compress-fasttext
Model compression
You can use this package to compress your own fastText model (or one downloaded e.g. from RusVectores):
Compress a model in Gensim format:
import gensim
import compress_fasttext
big_model = gensim.models.fasttext.FastTextKeyedVectors.load('path-to-original-model')
small_model = compress_fasttext.prune_ft_freq(big_model, pq=True)
small_model.save('path-to-new-model')Import a model in Facebook original format and compress it:
from gensim.models.fasttext import load_facebook_model
import compress_fasttext
big_model = load_facebook_model('path-to-original-model').wv
small_model = compress_fasttext.prune_ft_freq(big_model, pq=True)
small_model.save('path-to-new-model')To perform this compression, you will need to pip install gensim==3.8.3 sklearn beforehand.
Different compression methods include:
- matrix decomposition (
svd_ft) - product quantization (
quantize_ft) - optimization of feature hashing (
prune_ft) - feature selection (
prune_ft_freq)
The recommended approach is combination of feature selection and quantization (prune_ft_freq with pq=True).
Model usage
If you just need a tiny fastText model for Russian, you can download this 21-megabyte model. It's a compressed version of geowac_tokens_none_fasttextskipgram_300_5_2020 model from RusVectores.
If compress-fasttext is already installed, you can download and use this tiny model
import compress_fasttext
small_model = compress_fasttext.models.CompressedFastTextKeyedVectors.load(
'https://github.com/avidale/compress-fasttext/releases/download/gensim-4-draft/geowac_tokens_sg_300_5_2020-100K-20K-100.bin'
)
print(small_model['ΡΠΏΠ°ΡΠΈΠ±ΠΎ'])
# [ 0.26762889 0.35489027 ... -0.06149674] # a 300-dimensional vector
print(small_model.most_similar('ΠΊΠΎΡΠ΅Π½ΠΎΠΊ'))
# [('ΠΊΠΎΡ', 0.7391024827957153), ('ΠΏΠ΅Ρ', 0.7388300895690918), ('ΠΌΠ°Π»ΡΡ', 0.7280327081680298), ... ]The class CompressedFastTextKeyedVectors inherits from gensim.models.fasttext.FastTextKeyedVectors,
but makes a few additional optimizations.
For English, you can use this tiny model, obtained by compressing the model by Facebook.
import compress_fasttext
small_model = compress_fasttext.models.CompressedFastTextKeyedVectors.load(
'https://github.com/avidale/compress-fasttext/releases/download/v0.0.4/cc.en.300.compressed.bin'
)
print(small_model['hello'])
# [ 1.84736611e-01 6.32683930e-03 4.43901886e-03 ... -2.88431027e-02] # a 300-dimensional vector
print(small_model.most_similar('Python'))
# [('PHP', 0.5252903699874878), ('.NET', 0.5027452707290649), ('Java', 0.4897131323814392), ... ]More compressed models for 101 various languages can be found at https://zenodo.org/record/4905385.
Example of application
In practical applications, you usually feed fastText embeddings to some other model.
The class FastTextTransformer uses the scikit-learn interface
and represents a text as the average of the embedding of its words.
With it you can, for example, train a classifier on top of fastText
to tell edible things from inedible ones:
import compress_fasttext
from sklearn.pipeline import make_pipeline
from sklearn.linear_model import LogisticRegression
from compress_fasttext.feature_extraction import FastTextTransformer
small_model = compress_fasttext.models.CompressedFastTextKeyedVectors.load(
'https://github.com/avidale/compress-fasttext/releases/download/v0.0.4/cc.en.300.compressed.bin'
)
classifier = make_pipeline(
FastTextTransformer(model=small_model),
LogisticRegression()
).fit(
['banana', 'soup', 'burger', 'car', 'tree', 'city'],
[1, 1, 1, 0, 0, 0]
)
classifier.predict(['jet', 'train', 'cake', 'apple'])
# array([0, 0, 1, 1])Notes
This code is heavily based on the navec package by Alexander Kukushkin and the blogpost by Andrey Vasnetsov about shrinking fastText embeddings.
