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This repository is a toolkit to do machine learning for programming languages. It implements tokenization, dataset preprocessing, model training and model evaluation.

We provide reference implementations of the following papers:

We also provide pre-trained models for language modeling, translation and deobfuscation.

You can find some documentation for each projects in the docs folder:

Dependencies

Run install_env.sh. We use black code formatter.

Data

Source code processors

This repository contains programming languages processors for C++, Java and Python. These processors include:

These processors are based on TreeSitter parsers. As these parsers are available in more than 30 programming languages, one can easily create a new programming language processor.

Example of code tokenization:

from codegen_sources.preprocessing.lang_processors.java_processor import JavaProcessor

java_code = r"""class HelloWorld {
    public static void main(String[] args) {
        System.out.println("Hello, World!"); 
    }
}"""
java_processor = JavaProcessor(root_folder="<YOUR_TREESITER_FOLDER>")
tokenized_java_code = java_processor.tokenize_code(java_code)
print(tokenized_java_code)

BPE

This repository provides wrappers for fast BPE and Roberta BPE at file level.

Dataset Preprocessing

This repository contains a pipeline to create programming languages datasets. Now it supports four datasets modes:

First, download C++ / Java / Python source code from Google BigQuery. To run our preprocessing pipeline, you need to donwload the raw source code on your machine in a JSON format. A sample of it is given here.

The pipeline does the following:

To run the pipeline :

python -m codegen_sources.preprocessing.preprocess \
<DATA_PATH> \                            # folder containing json.gz
--langs java cpp python  \               # languages to process
--mode monolingual_functions \           # dataset mode
--bpe_mode=fast \                    # BPE mode. by default it is fast. can be roberta
--local=True \                           # Run on your local machine if True. If False run on a cluster (requires submitit setup)
--train_splits=1                         # Number of trainings splits

If you give several languages, the BPE codes and vocab will be learned commonly on these languages , so that you will have a common vocabulary to train one model for several languages. If you do not want that, launch the pipeline on every language separatly. These tests test the pipeline on different modes. It will give you an overview of the possible options.

Also, we provide the BPE codes and vocabulary here. These are the codes and vocabulary used for TransCoder and DOBF. They were learned on concatenated C++, Java, and Python data. If you want to use them instead of learning new ones, give the corresponding paths as fastbpe_code_path and fastbpe_vocab_path arguments.

In TransCoder and DOBF readmes, we provide the commands to preprocess the respective datasets.

Model

Overview

In this repository, we provide code to train transformer-based models (code based on XLM repository). The available training tasks are the following:

We evaluate our models with metrics adapted to each task (e.g. computation accuracy and BLEU score for TransCoder, subtoken score for Deobfuscation).

Also, we provide wrappers to fine-tune and evaluate our models on CodeXGLUE benchmark.

Download models

You can download the following models:

Re train specific models

To have details on how to retrain specific models, please refer to the README specific to each model.

References

TransCoder model (NeurIPS 2020)

[1] B. Roziere*, M.A. Lachaux*, L. Chanussot, G. Lample Unsupervised Translation of Programming Languages.

@article{roziere2020unsupervised,
  title={Unsupervised translation of programming languages},
  author={Roziere, Baptiste and Lachaux, Marie-Anne and Chanussot, Lowik and Lample, Guillaume},
  journal={Advances in Neural Information Processing Systems},
  volume={33},
  year={2020}
}

DOBF

[2] B. Roziere*, M.A. Lachaux*, M. Szafraniec , G. Lample DOBF: A Deobfuscation Pre-Training Objective for Programming Languages.

@article{roziere2021dobf,
  title={{DOBF}: A Deobfuscation Pre-Training Objective for Programming Languages},
  author={Roziere, Baptiste and Lachaux, Marie-Anne and Szafraniec, Marc and Lample, Guillaume},
  journal={arXiv preprint arXiv:2102.07492},
  year={2021}
}

TransCoder-ST

[3] B. Roziere, J.M. Zhang, F. Charton, M. Harman, G. Synnaeve, G. Lample Leveraging Automated Unit Tests for Unsupervised Code Translation.

@article{roziere2021leveraging,
  title={Leveraging Automated Unit Tests for Unsupervised Code Translation},
  author={Roziere, Baptiste and Zhang, Jie M and Charton, Francois and Harman, Mark and Synnaeve, Gabriel and Lample, Guillaume},
  journal={ICLR},
  year={2022}
}

TransCoder-IR

@article{szafraniec2022code,
  title={Code translation with Compiler Representations},
  author={Szafraniec, Marc and Roziere, Baptiste and Charton, Hugh Leather Francois and Labatut, Patrick and Synnaeve, Gabriel},
  journal={ICLR},
  year={2023}
}

* Equal Contribution

License

The validation and test parallel datasets from GeeksForGeeks, and the evaluation scripts under data/transcoder_evaluation_gfg are released under the Creative Commons Attribution-ShareAlike 2.0 license. See https://creativecommons.org/licenses/by-sa/2.0/ for more information.

The rest of the CodeGen repository is under the MIT license. See LICENSE for more details.