@inproceedings{cunningham-etal-2022-towards,
    title = "Towards Autoformalization of Mathematics and Code Correctness: Experiments with Elementary Proofs",
    author = "Cunningham, Garett  and
      Bunescu, Razvan  and
      Juedes, David",
    editor = "Ferreira, Deborah  and
      Valentino, Marco  and
      Freitas, Andre  and
      Welleck, Sean  and
      Schubotz, Moritz",
    booktitle = "Proceedings of the 1st Workshop on Mathematical Natural Language Processing (MathNLP)",
    month = dec,
    year = "2022",
    address = "Abu Dhabi, United Arab Emirates (Hybrid)",
    publisher = "Association for Computational Linguistics",
    url = "https://preview.aclanthology.org/jlcl-multiple-ingestion/2022.mathnlp-1.4/",
    doi = "10.18653/v1/2022.mathnlp-1.4",
    pages = "25--32",
    abstract = "The ever-growing complexity of mathematical proofs makes their manual verification by mathematicians very cognitively demanding. Autoformalization seeks to address this by translating proofs written in natural language into a formal representation that is computer-verifiable via interactive theorem provers. In this paper, we introduce a semantic parsing approach, based on the Universal Transformer architecture, that translates elementary mathematical proofs into an equivalent formalization in the language of the Coq interactive theorem prover. The same architecture is also trained to translate simple imperative code decorated with Hoare triples into formally verifiable proofs of correctness in Coq. Experiments on a limited domain of artificial and human-written proofs show that the models generalize well to intermediate lengths not seen during training and variations in natural language."
}