This repository provides the code for training Japanese pretrained models. This code has been used for producing japanese-gpt2-medium, japanese-gpt2-small, japanese-gpt2-xsmall, and japanese-roberta-base released on HuggingFace model hub by rinna Co., Ltd.
Currently supported pretrained models include: GPT-2, RoBERTa.
| Table of Contents |
|---|
| Update log |
| Use tips |
| Use our pretrained models via Huggingface |
Train japanese-gpt2-xsmall from scratch |
Train japanese-roberta-base from scratch |
| License |
Please open an issue (in English/日本語) if you encounter any problem using the code or using our models via Huggingface.
if you find this work useful, please cite the following paper:
@article{rinna_pretrained2021,
title={日本語自然言語処理における事前学習モデルの公開},
author={趙 天雨 and 沢田 慶},
journal={人工知能学会研究会資料 言語・音声理解と対話処理研究会},
volume={93},
pages={169-170},
year={2021},
doi={10.11517/jsaislud.93.0_169}
}
-
2022/01/25 Updated link to
rinna/japanese-gpt-1bin the model summary table. -
2022/01/17 Updated citation information.
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2021/11/01 Updated corpora links.
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2021/09/13 Added tips on using
position_idswithjapanese-roberta-base. Refer to issue 3 for details. -
2021/08/26 [Important] Updated license from the MIT license to the Apache 2.0 license due to the use of the Wikipedia pre-processing code from cl-tohoku/bert-japanese. See issue 1 for details.
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2021/08/23 Added Japanese Wikipedia to training corpora. Published code for training
rinna/japanese-gpt2-small,rinna/japanese-gpt2-xsmall, andrinna/japanese-roberta-base. -
2021/08/18 Changed repo name from
japanese-gpt2tojapanese-pretrained-models -
2021/06/15 Fixed best PPL tracking bug when using a checkpoint.
-
2021/05/04 Fixed random seeding bug for Multi-GPU training.
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2021/04/06 Published code for training
rinna/japanese-gpt2-medium.
-
Use
[CLS]: To predict a masked token, be sure to add a[CLS]token before the sentence for the model to correctly encode it, as it is used during the model training. -
Use
[MASK]after tokenization: A) Directly typing[MASK]in an input string and B) replacing a token with[MASK]after tokenization will yield different token sequences, and thus different prediction results. It is more appropriate to use[MASK]after tokenization (as it is consistent with how the model was pretrained). However, the Huggingface Inference API only supports typing[MASK]in the input string and produces less robust predictions. -
Provide
position_idsas an argument explicitly: Whenposition_idsare not provided for aRoberta*model, Huggingface'stransformerswill automatically construct it but start frompadding_idxinstead of0(see issue and functioncreate_position_ids_from_input_ids()in Huggingface's implementation), which unfortunately does not work as expected withrinna/japanese-roberta-basesince thepadding_idxof the corresponding tokenizer is not0. So please be sure to constrcut theposition_idsby yourself and make it start from position id0.
| language model | # params | # layers | # emb dim | # epochs | dev ppl | training time* |
|---|---|---|---|---|---|---|
| rinna/japanese-gpt-1b | 1.3B | 24 | 2048 | 10+ | 13.9 | n/a** |
| rinna/japanese-gpt2-medium | 336M | 24 | 1024 | 4 | 18 | 45 days |
| rinna/japanese-gpt2-small | 110M | 12 | 768 | 3 | 21 | 15 days |
| rinna/japanese-gpt2-xsmall | 37M | 6 | 512 | 3 | 28 | 4 days |
| masked language model | # params | # layers | # emb dim | # epochs | dev ppl | training time* |
|---|---|---|---|---|---|---|
| rinna/japanese-roberta-base | 110M | 12 | 768 | 8 | 3.9 | 15 days |
* Training was conducted on a 8x V100 32GB machine.
** Training was conducted using a different codebase and a different computing environment.
import torch
from transformers import T5Tokenizer, RobertaForMaskedLM
# load tokenizer
tokenizer = T5Tokenizer.from_pretrained("rinna/japanese-roberta-base")
tokenizer.do_lower_case = True # due to some bug of tokenizer config loading
# load model
model = RobertaForMaskedLM.from_pretrained("rinna/japanese-roberta-base")
model = model.eval()
# original text
text = "4年に1度オリンピックは開かれる。"
# prepend [CLS]
text = "[CLS]" + text
# tokenize
tokens = tokenizer.tokenize(text)
print(tokens) # output: ['[CLS]', '▁4', '年に', '1', '度', 'オリンピック', 'は', '開かれる', '。']']
# mask a token
masked_idx = 5
tokens[masked_idx] = tokenizer.mask_token
print(tokens) # output: ['[CLS]', '▁4', '年に', '1', '度', '[MASK]', 'は', '開かれる', '。']
# convert to ids
token_ids = tokenizer.convert_tokens_to_ids(tokens)
print(token_ids) # output: [4, 1602, 44, 24, 368, 6, 11, 21583, 8]
# convert to tensor
token_tensor = torch.LongTensor([token_ids])
# provide position ids explicitly
position_ids = list(range(0, token_tensor.size(1)))
print(position_ids) # output: [0, 1, 2, 3, 4, 5, 6, 7, 8]
position_id_tensor = torch.LongTensor([position_ids])
# get the top 10 predictions of the masked token
with torch.no_grad():
outputs = model(input_ids=token_tensor, position_ids=position_id_tensor)
predictions = outputs[0][0, masked_idx].topk(10)
for i, index_t in enumerate(predictions.indices):
index = index_t.item()
token = tokenizer.convert_ids_to_tokens([index])[0]
print(i, token)
"""
0 総会
1 サミット
2 ワールドカップ
3 フェスティバル
4 大会
5 オリンピック
6 全国大会
7 党大会
8 イベント
9 世界選手権
"""
Install required packages by running the following command under the repo directory:
pip install -r requirements.txt
- Set up fugashi tokenzier for preprocessing Wikipedia corpus by running:
python -m unidic download
-
Download training corpus Japanese CC-100 and extract the
ja.txtfile. -
Move the
ja.txtfile or modifysrc/corpus/jp_cc100/config.pyto match the filepath ofja.txtwithself.raw_data_dirin the config file. -
Split
ja.txtto smaller files by running:
cd src/
python -m corpus.jp_cc100.split_to_small_files
- First check the versions of Wikipedia dump at Wikipedia cirrussearch and fill in
self.download_link(in filesrc/corpus/jp_wiki/config.py) with the link to your preferred Wikipedia dump version. Then download training corpus Japanese Wikipedia and split it by running:
python -m corpus.jp_wiki.build_pretrain_dataset
python -m corpus.jp_wiki.split_to_small_files
- Train a xsmall-sized GPT-2 on, for example, 4 V100 GPUs by running:
CUDA_VISIBLE_DEVICES=0,1,2,3 python -m task.pretrain_gpt2.train \
--n_gpus 4 \
--save_model True \
--enable_log True \
--model_size xsmall \
--model_config_filepath model/gpt2-ja-xsmall-config.json \
--batch_size 20 \
--eval_batch_size 40 \
--n_training_steps 1600000 \
--n_accum_steps 3 \
--init_lr 0.0007
Assume you have run the training script and saved your xsmall-sized GPT-2 to data/model/pretrain_gpt2/gpt2-ja-xsmall-xxx.checkpoint. Run the following command to use it to complete text on one GPU by nucleus sampling with p=0.95 and k=40:
CUDA_VISIBLE_DEVICES=0 python -m task.pretrain_gpt2.interact \
--checkpoint_path ../data/model/pretrain_gpt2/gpt2-ja-medium-xxx.checkpoint \
--gen_type top \
--top_p 0.95 \
--top_k 40
-
Make your Huggingface account. Create a model repo. Clone it to your local machine.
-
Create model and config files from a checkpoint by running:
python -m task.pretrain_gpt2.checkpoint2huggingface \
--checkpoint_path ../data/model/gpt2-medium-xxx.checkpoint \
--save_dir {huggingface's model repo directory}
- Validate the created files by running:
python -m task.pretrain_gpt2.check_huggingface \
--model_dir {huggingface's model repo directory}
- Add files, commit, and push to your Huggingface repo.
Check available arguments of GPT-2 training script by running:
python -m task.pretrain_gpt2.train --help
Assume you have finished the data construction process as described above, run the following command to train a base-sized Japanese RoBERTa on, for example, 8 V100 GPUs:
CUDA_VISIBLE_DEVICES=0,1,2,3,4,5,6,7 python -m task.pretrain_roberta.train \
--n_gpus 8 \
--save_model True \
--enable_log True \
--model_size base \
--model_config_filepath model/roberta-ja-base-config.json \
--batch_size 32 \
--eval_batch_size 32 \
--n_training_steps 3000000 \
--n_accum_steps 16 \
--init_lr 0.0006