BLEURT is an evaluation metric for Natural Language Generation. It takes a pair of sentences as input, a reference and a candidate, and it returns a score that indicates to what extent the candidate is fluent and conveys the meaning of the reference. It is comparable to sentence-BLEU
, BERTscore
, and COMET
.
BLEURT is a trained metric, that is, it is a regression model trained on ratings data. The model is based on BERT
and RemBERT
. This repository contains all the code necessary to use it and/or fine-tune it for your own applications. BLEURT uses Tensorflow, and it benefits greatly from modern GPUs (it runs on CPU too).
An overview of BLEURT can be found in our our blog post. Further details are provided in the ACL paper BLEURT: Learning Robust Metrics for Text Generation and our EMNLP paper.
BLEURT runs in Python 3. It relies heavily on Tensorflow
(>=1.15) and the
library tf-slim
(>=1.1).
You may install it as follows:
pip install --upgrade pip # ensures that pip is current
git clone https://github.com/google-research/bleurt.git
cd bleurt
pip install .
You may check your install with unit tests:
python -m unittest bleurt.score_test
python -m unittest bleurt.score_not_eager_test
python -m unittest bleurt.finetune_test
python -m unittest bleurt.score_files_test
The following commands download the recommended checkpoint and run BLEURT:
# Downloads the BLEURT-base checkpoint.
wget https://storage.googleapis.com/bleurt-oss-21/BLEURT-20.zip .
unzip BLEURT-20.zip
# Runs the scoring.
python -m bleurt.score_files \
-candidate_file=bleurt/test_data/candidates \
-reference_file=bleurt/test_data/references \
-bleurt_checkpoint=BLEURT-20
The files bleurt/test_data/candidates
and references
contain test sentences,
included by default in the BLEURT distribution. The input format is one sentence per line.
You may replace them with your own files. The command outputs one score per sentence pair.
Oct 8th 2021 Update: we upgraded the recommended checkpoint to BLEURT-20, a more accurate, multilingual model 🎉.
Currently, there are three methods to invoke BLEURT: the command-line interface, the Python API, and the Tensorflow API.
The simplest way to use BLEURT is through command line, as shown below.
python -m bleurt.score_files \
-candidate_file=bleurt/test_data/candidates \
-reference_file=bleurt/test_data/references \
-bleurt_checkpoint=bleurt/test_checkpoint \
-scores_file=scores
The files candidates
and references
contain one sentence per line (see the folder test_data
for the exact format). Invoking the command should produce a file scores
which contains one BLEURT score per sentence pair. Alternatively you may use a JSONL file, as follows:
python -m bleurt.score_files \
-sentence_pairs_file=bleurt/test_data/sentence_pairs.jsonl \
-bleurt_checkpoint=bleurt/test_checkpoint
The flags bleurt_checkpoint
and scores_file
are optional. If bleurt_checkpoint
is not specified, BLEURT will default to a test checkpoint, based on BERT-Tiny, which is very light but also very inaccurate (we recommend against using it). If scores_files
is not specified, BLEURT will use the standard output.
The following command lists all the other command-line options:
python -m bleurt.score_files -helpshort
BLEURT may be used as a Python library as follows:
from bleurt import score
checkpoint = "bleurt/test_checkpoint"
references = ["This is a test."]
candidates = ["This is the test."]
scorer = score.BleurtScorer(checkpoint)
scores = scorer.score(references=references, candidates=candidates)
assert isinstance(scores, list) and len(scores) == 1
print(scores)
Here again, BLEURT will default to BERT-Tiny
if no checkpoint is specified.
BLEURT works both in eager_mode
(default in TF 2.0) and in a tf.Session
(TF 1.0), but the latter mode is slower and may be deprecated in the near
future.
BLEURT may be embedded in a TF computation graph, e.g., to visualize it on the Tensorboard while training a model.
The following piece of code shows an example:
import tensorflow as tf
# Set tf.enable_eager_execution() if using TF 1.x.
from bleurt import score
references = tf.constant(["This is a test."])
candidates = tf.constant(["This is the test."])
bleurt_ops = score.create_bleurt_ops()
bleurt_out = bleurt_ops(references=references, candidates=candidates)
assert bleurt_out["predictions"].shape == (1,)
print(bleurt_out["predictions"])
The crucial part is the call to score.create_bleurt_ops
, which creates the TF ops.
A BLEURT checkpoint is a self-contained folder that contains a regression model and some information that BLEURT needs to run. BLEURT checkpoints can be downloaded, copy-pasted, and stored anywhere. Furthermore, checkpoints are tunable, which means that they can be fine-tuned on custom ratings data.
BLEURT defaults to the test
checkpoint, which is very inaccaurate. We recommend
using BLEURT-20
for results reporting. You may use it as follows:
wget https://storage.googleapis.com/bleurt-oss-21/BLEURT-20.zip .
unzip BLEURT-20.zip
python -m bleurt.score_files \
-candidate_file=bleurt/test_data/candidates \
-reference_file=bleurt/test_data/references \
-bleurt_checkpoint=BLEURT-20
The checkpoints page provides more information about how these checkpoints were trained, as well as pointers to smaller models. Additionally, you can fine-tune BERT or existing BLEURT checkpoints on your own ratings data. The checkpoints page describes how to do so.
Different BLEURT checkpoints yield different scores. The currently recommended checkpoint BLEURT-20
generates scores which are roughly between 0 and 1 (sometimes less than 0, sometimes more than 1), where 0 indicates a random output and 1 a perfect one. As with all automatic metrics, BLEURT scores are noisy. For a robust evaluation of a system's quality, we recommend averaging BLEURT scores across the sentences in a corpus. See the WMT Metrics Shared Task for a comparison of metrics on this aspect.
In principle, BLEURT should measure adequacy: most of its training data was collected by the WMT organizers who asked to annotators "How much do you agree that the system output adequately expresses the meaning of the reference?" (WMT Metrics'18, Graham et al., 2015). In practice however, the answers tend to be very correlated with fluency ("Is the text fluent English?"), and we added synthetic noise in the training set which makes the distinction between adequacy and fluency somewhat fuzzy.
Currently, BLEURT-20
was tested on 13 languages: Chinese, Czech, English, French, German, Japanese, Korean, Polish, Portugese, Russian, Spanish, Tamil, Vietnamese (these are languages for which we have held-out ratings data). In theory, it should work for the 100+ languages of multilingual C4, on which RemBERT was trained.
If you tried any other language and would like to share your experience, either positive or negative, please send us feedback!
We describe three methods to speed up BLEURT, and how to combine them.
You may specify the flag -bleurt_batch_size
which determines the number of sentence pairs processed at once by BLEURT. The default value is 16, you may want to increase or decrease it based on the memory available and the presence of a GPU (we typically use 16 when using a laptop without a GPU, 100 on a workstation with a GPU).
Length-based batching is an optimization which consists in batching examples that have a similar a length and cropping the resulting tensor, to avoid wasting computations on padding tokens. This technique oftentimes results in spectacular speed-ups (typically, ~2-10X). It is described here, and it was successfully used by BERTScore in the field of learned metrics.
You can enable length-based by specifying -batch_same_length=True
when calling score_files
with the command line, or by instantiating a LengthBatchingBleurtScorer
instead of BleurtScorer
when using the Python API.
We provide pointers to several compressed checkpoints on the checkpoints page. These models were obtained by distillation, a lossy process, and therefore the outputs cannot be directly compared to those of the original BLEURT model (though they should be strongly correlated).
The following command illustrates how to combine these three techniques, speeding up BLEURT by an order of magnitude (up to 20X with our configuration) on larger files:
# Downloads the 12-layer distilled model, which is ~3.5X smaller.
wget https://storage.googleapis.com/bleurt-oss-21/BLEURT-20-D12.zip .
unzip BLEURT-20-D12.zip
python -m bleurt.score_files \
-candidate_file=bleurt/test_data/candidates \
-reference_file=bleurt/test_data/references \
-bleurt_batch_size=100 \ # Optimization 1.
-batch_same_length=True \ # Optimization 2.
-bleurt_checkpoint=BLEURT-20-D12 # Optimization 3.
You may find information about how to work with ratings from the WMT Metrics Shared Task, reproduce results from our ACL paper, and a selection of models from our EMNLP paper on this page.
Please cite our ACL paper:
@inproceedings{sellam2020bleurt,
title = {BLEURT: Learning Robust Metrics for Text Generation},
author = {Thibault Sellam and Dipanjan Das and Ankur P Parikh},
year = {2020},
booktitle = {Proceedings of ACL}
}
The latest model, BLEURT-20, is based on work that led to this follow-up paper:
@inproceedings{pu2021learning,
title = {Learning compact metrics for MT},
author = {Pu, Amy and Chung, Hyung Won and Parikh, Ankur P and Gehrmann, Sebastian and Sellam, Thibault},
booktitle = {Proceedings of EMNLP},
year = {2021}
}