LUKE (Language Understanding with Knowledge-based Embeddings) is a new pre-trained contextualized representation of words and entities based on transformer. It achieves state-of-the-art results on important NLP benchmarks including SQuAD v1.1 (extractive question answering), CoNLL-2003 (named entity recognition), ReCoRD (cloze-style question answering), TACRED (relation classification), and Open Entity (entity typing).
This repository contains the source code to pre-train the model and fine-tune it to solve downstream tasks.
May 5, 2021: LUKE is added to Hugging Face Transformers
LUKE has been added to the master branch of the Hugging Face Transformers library. You can now solve entity-related tasks (e.g., named entity recognition, relation classification, entity typing) easily using this library.
For example, the LUKE-large model fine-tuned on the TACRED dataset can be used as follows:
>>> from transformers import LukeTokenizer, LukeForEntityPairClassification
>>> model = LukeForEntityPairClassification.from_pretrained("studio-ousia/luke-large-finetuned-tacred")
>>> tokenizer = LukeTokenizer.from_pretrained("studio-ousia/luke-large-finetuned-tacred")
>>> text = "Beyoncé lives in Los Angeles."
>>> entity_spans = [(0, 7), (17, 28)] # character-based entity spans corresponding to "Beyoncé" and "Los Angeles"
>>> inputs = tokenizer(text, entity_spans=entity_spans, return_tensors="pt")
>>> outputs = model(**inputs)
>>> logits = outputs.logits
>>> predicted_class_idx = int(logits[0].argmax())
>>> print("Predicted class:", model.config.id2label[predicted_class_idx])
Predicted class: per:cities_of_residence
We also provide the following three Colab notebooks that show how to reproduce our experimental results on CoNLL-2003, TACRED, and Open Entity datasets using the library:
- Reproducing experimental results of LUKE on CoNLL-2003 Using Hugging Face Transformers
- Reproducing experimental results of LUKE on TACRED Using Hugging Face Transformers
- Reproducing experimental results of LUKE on Open Entity Using Hugging Face Transformers
Please refer to the official documentation for further details.
November 5, 2021: LUKE-500K (base) model
We released LUKE-500K (base), a new pretrained LUKE model which is smaller than existing LUKE-500K (large). The experimental results of the LUKE-500K (base) and LUKE-500K (large) on SQuAD v1 and CoNLL-2003 are shown as follows:
Task | Dataset | Metric | LUKE-500K (base) | LUKE-500K (large) |
---|---|---|---|---|
Extractive Question Answering | SQuAD v1.1 | EM/F1 | 86.1/92.3 | 90.2/95.4 |
Named Entity Recognition | CoNLL-2003 | F1 | 93.3 | 94.3 |
We tuned only the batch size and learning rate in the experiments based on LUKE-500K (base).
LUKE outperforms the previous state-of-the-art methods on five important NLP tasks:
Task | Dataset | Metric | LUKE-500K (large) | Previous SOTA |
---|---|---|---|---|
Extractive Question Answering | SQuAD v1.1 | EM/F1 | 90.2/95.4 | 89.9/95.1 (Yang et al., 2019) |
Named Entity Recognition | CoNLL-2003 | F1 | 94.3 | 93.5 (Baevski et al., 2019) |
Cloze-style Question Answering | ReCoRD | EM/F1 | 90.6/91.2 | 83.1/83.7 (Li et al., 2019) |
Relation Classification | TACRED | F1 | 72.7 | 72.0 (Wang et al. , 2020) |
Fine-grained Entity Typing | Open Entity | F1 | 78.2 | 77.6 (Wang et al. , 2020) |
These numbers are reported in our EMNLP 2020 paper.
LUKE can be installed using Poetry:
$ poetry install
The virtual environment automatically created by Poetry can be activated by
poetry shell
.
We initially release the pre-trained model with 500K entity vocabulary based on
the roberta.large
model.
Name | Base Model | Entity Vocab Size | Params | Download |
---|---|---|---|---|
LUKE-500K (base) | roberta.base | 500K | 253 M | Link |
LUKE-500K (large) | roberta.large | 500K | 483 M | Link |
The experiments were conducted using Python3.6 and PyTorch 1.2.0 installed on a server with a single or eight NVidia V100 GPUs. We used NVidia's PyTorch Docker container 19.02. For computational efficiency, we used mixed precision training based on APEX library which can be installed as follows:
$ git clone https://github.com/NVIDIA/apex.git
$ cd apex
$ git checkout c3fad1ad120b23055f6630da0b029c8b626db78f
$ pip install -v --no-cache-dir --global-option="--cpp_ext" --global-option="--cuda_ext" .
The APEX library is not needed if you do not use --fp16
option or reproduce
the results based on the trained checkpoint files.
The commands that reproduce the experimental results are provided as follows:
Dataset: Link
Checkpoint file (compressed): Link
Using the checkpoint file:
$ python -m examples.cli \
--model-file=luke_large_500k.tar.gz \
--output-dir=<OUTPUT_DIR> \
entity-typing run \
--data-dir=<DATA_DIR> \
--checkpoint-file=<CHECKPOINT_FILE> \
--no-train
Fine-tuning the model:
$ python -m examples.cli \
--model-file=luke_large_500k.tar.gz \
--output-dir=<OUTPUT_DIR> \
entity-typing run \
--data-dir=<DATA_DIR> \
--train-batch-size=2 \
--gradient-accumulation-steps=2 \
--learning-rate=1e-5 \
--num-train-epochs=3 \
--fp16
Dataset: Link
Checkpoint file (compressed): Link
Using the checkpoint file:
$ python -m examples.cli \
--model-file=luke_large_500k.tar.gz \
--output-dir=<OUTPUT_DIR> \
relation-classification run \
--data-dir=<DATA_DIR> \
--checkpoint-file=<CHECKPOINT_FILE> \
--no-train
Fine-tuning the model:
$ python -m examples.cli \
--model-file=luke_large_500k.tar.gz \
--output-dir=<OUTPUT_DIR> \
relation-classification run \
--data-dir=<DATA_DIR> \
--train-batch-size=4 \
--gradient-accumulation-steps=8 \
--learning-rate=1e-5 \
--num-train-epochs=5 \
--fp16
Dataset: Link
Checkpoint file (compressed): Link
Using the checkpoint file:
$ python -m examples.cli \
--model-file=luke_large_500k.tar.gz \
--output-dir=<OUTPUT_DIR> \
ner run \
--data-dir=<DATA_DIR> \
--checkpoint-file=<CHECKPOINT_FILE> \
--no-train
Fine-tuning the model:
$ python -m examples.cli\
--model-file=luke_large_500k.tar.gz \
--output-dir=<OUTPUT_DIR> \
ner run \
--data-dir=<DATA_DIR> \
--train-batch-size=2 \
--gradient-accumulation-steps=4 \
--learning-rate=1e-5 \
--num-train-epochs=5 \
--fp16
Dataset: Link
Checkpoint file (compressed): Link
Using the checkpoint file:
$ python -m examples.cli \
--model-file=luke_large_500k.tar.gz \
--output-dir=<OUTPUT_DIR> \
entity-span-qa run \
--data-dir=<DATA_DIR> \
--checkpoint-file=<CHECKPOINT_FILE> \
--no-train
Fine-tuning the model:
$ python -m examples.cli \
--num-gpus=8 \
--model-file=luke_large_500k.tar.gz \
--output-dir=<OUTPUT_DIR> \
entity-span-qa run \
--data-dir=<DATA_DIR> \
--train-batch-size=1 \
--gradient-accumulation-steps=4 \
--learning-rate=1e-5 \
--num-train-epochs=2 \
--fp16
Dataset: Link
Checkpoint file (compressed): Link
Wikipedia data files (compressed):
Link
Using the checkpoint file:
$ python -m examples.cli \
--model-file=luke_large_500k.tar.gz \
--output-dir=<OUTPUT_DIR> \
reading-comprehension run \
--data-dir=<DATA_DIR> \
--checkpoint-file=<CHECKPOINT_FILE> \
--no-negative \
--wiki-link-db-file=enwiki_20160305.pkl \
--model-redirects-file=enwiki_20181220_redirects.pkl \
--link-redirects-file=enwiki_20160305_redirects.pkl \
--no-train
Fine-tuning the model:
$ python -m examples.cli \
--num-gpus=8 \
--model-file=luke_large_500k.tar.gz \
--output-dir=<OUTPUT_DIR> \
reading-comprehension run \
--data-dir=<DATA_DIR> \
--no-negative \
--wiki-link-db-file=enwiki_20160305.pkl \
--model-redirects-file=enwiki_20181220_redirects.pkl \
--link-redirects-file=enwiki_20160305_redirects.pkl \
--train-batch-size=2 \
--gradient-accumulation-steps=3 \
--learning-rate=15e-6 \
--num-train-epochs=2 \
--fp16
If you use LUKE in your work, please cite the original paper:
@inproceedings{yamada2020luke,
title={LUKE: Deep Contextualized Entity Representations with Entity-aware Self-attention},
author={Ikuya Yamada and Akari Asai and Hiroyuki Shindo and Hideaki Takeda and Yuji Matsumoto},
booktitle={EMNLP},
year={2020}
}
Please submit a GitHub issue or send an e-mail to Ikuya Yamada
([email protected]
) for help or issues using LUKE.