# PyTorch implementation of Google AI's BERT model with a script to load Google's pre-trained models ## Introduction This repository contains an op-for-op PyTorch reimplementation of [Google's TensorFlow code for the BERT model](https://github.com/google-research/bert) that was released together with the paper [BERT: Pre-training of Deep Bidirectional Transformers for Language Understanding](https://arxiv.org/abs/1810.04805) by Jacob Devlin, Ming-Wei Chang, Kenton Lee and Kristina Toutanova. This implementation can load any pre-trained TensorFlow BERT checkpoint (in particular [Google's pre-trained models](https://github.com/google-research/bert)) and a conversion script is provided (see below). ## Loading a TensorFlow checkpoint (e.g. Google's pre-trained models) You can convert any TensorFlow checkpoint for BERT (in particular the pre-trained weights released by GoogleAI) in a PyTorch save file by using [`convert_tf_checkpoint_to_pytorch.py`](convert_tf_checkpoint_to_pytorch.py). This script takes as input a TensorFlow checkpoint (`bert_model.ckpt`) and the associated configuration file (`bert_config.json`), and create a PyTorch model for this configuration, load the weights from the TensorFlow checpoint in the PyTorch model and save the resulting model in a standard PyTorch save file that can be imported using `torch.load()` (see examples in `extract_features.py`, `run_classifier.py` and `run_squad.py`). To run this specific script you will need to have TensorFlow and PyTorch installed (`pip install tensorflow`). You can find Google's pre-trained models in [Google's TensorFlow repository for BERT](https://github.com/google-research/bert). Here is an example of the conversion process for a pre-trained `BERT-Base Uncased` model: ```shell export BERT_BASE_DIR=/path/to/bert/uncased_L-12_H-768_A-12 python convert_tf_checkpoint_to_pytorch.py \ --tf_checkpoint_path=$BERT_BASE_DIR/bert_model.ckpt \ --bert_config_file=$BERT_BASE_DIR/bert_config.json \ --pytorch_dump_path=$BERT_BASE_DIR/pytorch_model.bin ``` ## PyTorch models for BERT This repository contains three PyTorch models that you can find in [`modeling.py`](modeling.py): - `BertModel` - the basic model - `BertForSequenceClassification` - the model with a sequence classification head - `BertForQuestionAnswering` - the model with a token classification head ### 1. `BertModel` `BertModel` is the basic BERT model with a layer of token, position and sequence embeddings followed by a series of identical self-attention blocks (12 for BERT-base, 24 for BERT-large). This model outputs a tuple of: - `all_encoder_layers`: a list of the full sequences of hidden-states at the end of each attention block (i.e. 12 full sequences for BERT-base, 24 for BERT-large), and - `pooled_output`: the output of a classifier pretrained on top of the hidden state associated to the first character of the input to classifier the Next-Sentence task (see BERT's paper). An example on how to use this class is given in the `extract_features.py` script which can be used to extract the hidden states of the model for a given input. ### 2. `BertForSequenceClassification` `BertForSequenceClassification` is a fine-tuning model that includes `BertModel` and a sequence (or pair of sequence) classifier on top of the `BertModel`. The sequence classifier is a linear layer that takes as input the last hidden state of the first character in the input sequence (see Figures 3a and 3b in the BERT paper). An example on how to use this class is given in the `run_classifier.py` script which can be used to fine-tune a single sequence (or pair of sequence) classifier using BERT, for example for the MRPC task. ### 3. `BertForQuestionAnswering` `BertForSequenceClassification` is a fine-tuning model that includes `BertModel` with a two-class classifiers on top of the full sequence of last hidden states. The token classifier takes as input the full sequence of the last hidden state and compute two scores for each tokens that can for example respectively be the score that a given token is a `start_span` or `end_span` token (see Figures 3c and 3d in the BERT paper). An example on how to use this class is given in the `run_squad.py` script which can be used to fine-tune a token classifier using BERT, for example for the SQuAS task. ## Installation, requirements, test This code was tested on Python 3.5+. The requirements are: - PyTorch (>= 0.4.0) - tqdm To install the dependencies: ````bash pip install -r ./requirements.txt ```` A series of tests is included in the [`test` folder](./test) and can be run using `pytest` (install pytest if needed: `pip install pytest`). You can run the tests with the command: ```bash pytest -sv ./tests/ ``` ## Training on large batches: gradient accumulation, multi-GPU and distributed training BERT-base and BERT-large are respectively 110M and 340M parameters models and it can be difficult to fine-tune them on a single GPU with the recommended batch size for good performance (in most case a batch_size of 32 is recommended). To help fine-tuning, we have included three techniques that you can leverage in the fine-tuning scripts `run_classifier.py` and `run_squad.py`: gradient-accumulation, multi-gpu and distributed training. For more details on how to use these techniques you can read [the tips on training large batches in PyTorch](https://medium.com/huggingface/training-larger-batches-practical-tips-on-1-gpu-multi-gpu-distributed-setups-ec88c3e51255) that we published earlier this month. Here are the details: - **Gradient Accumulation**: Gradient accumulation can be used by supplying a integer greater than one to the `--gradient_accumulation_steps` argument. The batch at each step will be divided by this integer and gradient will be accumulated over `gradient_accumulation_steps` steps. - **Multi-GPU**: Multi-GPU is automatically activated when several GPUs are detected and the batch are splitted over the GPUs. - **Distributed training**: Distributed training can be activated by suppying an integer greater or equal to zero to the `--local_rank` argument. To use Distributed training, you will need to run one training script on each of your machines. This can be done for example by running the following command on each server (see the above blog post for more details): ```bash python -m torch.distributed.launch --nproc_per_node=4 --nnodes=2 --node_rank=$THIS_MACHINE_INDEX --master_addr="192.168.1.1" --master_port=1234 run_classifier.py (--arg1 --arg2 --arg3 and all other arguments of the run_classifier script) ``` Where `$THIS_MACHINE_INDEX` is an sequential index assigned to each of your machine (0, 1, 2...) and the machine with rank 0 has an IP adress `192.168.1.1` and an open port `1234`. ## TPU support and pretraining scripts TPU are not supported by the current stable release of PyTorch (0.4.1). However, the next version of PyTorch (v1.0) should support training on TPU and is expected to be released soon (see the recent [official announcement](https://cloud.google.com/blog/products/ai-machine-learning/introducing-pytorch-across-google-cloud)). We will add TPU support when this next release is published. The original TensorFlow code furthe comprises two scripts for pre-training BERT: [create_pretraining_data.py](https://github.com/google-research/bert/blob/master/create_pretraining_data.py) and [run_pretraining.py](https://github.com/google-research/bert/blob/master/run_pretraining.py). Since, pre-training BERT is a particularly expensive operation that basically requires one or several TPUs to be completed in a reasonable amout of time (see details [here](https://github.com/google-research/bert#pre-training-with-bert)) we have decided to wait for the inclusion of TPU support in PyTorch to convert these pre-training scripts. ## Fine-tuning with BERT: running the examples We showcase the same examples as [the original implementation](https://github.com/google-research/bert/): fine-tuning a sequence-level classifier on the MRPC classification corpus and a token-level classifier on the question answering dataset SQuAD. Before running theses examples you should download the [GLUE data](https://gluebenchmark.com/tasks) by running [this script](https://gist.github.com/W4ngatang/60c2bdb54d156a41194446737ce03e2e) and unpack it to some directory `$GLUE_DIR`. Please also download the `BERT-Base` checkpoint, unzip it to some directory `$BERT_BASE_DIR`, and convert it to its PyTorch version as explained in the previous section. This example code fine-tunes `BERT-Base` on the Microsoft Research Paraphrase Corpus (MRPC) corpus and runs in less than 10 minutes on a single K-80. ```shell export GLUE_DIR=/path/to/glue python run_classifier.py \ --task_name MRPC \ --do_train \ --do_eval \ --do_lower_case \ --data_dir $GLUE_DIR/MRPC/ \ --vocab_file $BERT_BASE_DIR/vocab.txt \ --bert_config_file $BERT_BASE_DIR/bert_config.json \ --init_checkpoint $BERT_PYTORCH_DIR/pytorch_model.bin \ --max_seq_length 128 \ --train_batch_size 32 \ --learning_rate 2e-5 \ --num_train_epochs 3.0 \ --output_dir /tmp/mrpc_output/ ``` The next example fine-tunes `BERT-Base` on the SQuAD question answering task. This example runs in about 4 hours on a multi-GPU K-80. The data for SQuAD can be downloaded with the following links and should be saved in a `$SQUAD_DIR` directory. * [train-v1.1.json](https://rajpurkar.github.io/SQuAD-explorer/dataset/train-v1.1.json) * [dev-v1.1.json](https://rajpurkar.github.io/SQuAD-explorer/dataset/dev-v1.1.json) * [evaluate-v1.1.py](https://github.com/allenai/bi-att-flow/blob/master/squad/evaluate-v1.1.py) ```shell export SQUAD_DIR=/path/to/SQUAD python run_squad.py \ --vocab_file=$BERT_BASE_DIR/vocab.txt \ --bert_config_file=$BERT_BASE_DIR/bert_config.json \ --init_checkpoint=$BERT_PYTORCH_DIR/pytorch_model.bin \ --do_train \ --train_file=$SQUAD_DIR/train-v1.1.json \ --do_predict \ --predict_file=$SQUAD_DIR/dev-v1.1.json \ --train_batch_size=12 \ --learning_rate=5e-5 \ --num_train_epochs=2.0 \ --max_seq_length=384 \ --doc_stride=128 \ --output_dir=../debug_squad/ ``` ## Comparing the PyTorch model and the TensorFlow model predictions We also include [a simple Jupyter Notebook](https://github.com/huggingface/pytorch-pretrained-BERT/blob/master/Comparing%20TF%20and%20PT%20models.ipynb) that can be used to check that the predictions of the PyTorch model are identical to the predictions of the original TensorFlow model. This NoteBook extract the full sequence hidden state layers of each model and compute the sandard deviation between them. In our case we found a standard deviation of about 4e-7 on the last hidden state of the 12th layer. Please follow the instructions in the Notebook to run it.