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Main Authors: Zhang, Liao, Cerna, David M., Kaliszyk, Cezary
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.01188
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author Zhang, Liao
Cerna, David M.
Kaliszyk, Cezary
author_facet Zhang, Liao
Cerna, David M.
Kaliszyk, Cezary
contents Formally verifying the correctness of mathematical proofs is more accessible than ever, however, the learning curve remains steep for many of the state-of-the-art interactive theorem provers (ITP). Deriving the most appropriate subsequent proof step, and reasoning about it, given the multitude of possibilities, remains a daunting task for novice users. To improve the situation, several investigations have developed machine learning based guidance for tactic selection. Such approaches struggle to learn non-trivial relationships between the chosen tactic and the structure of the proof state and represent them as symbolic expressions. To address these issues we (i) We represent the problem as an Inductive Logic Programming (ILP) task, (ii) Using the ILP representation we enriched the feature space by encoding additional, computationally expensive properties as background knowledge predicates, (iii) We use this enriched feature space to learn rules explaining when a tactic is applicable to a given proof state, (iv) we use the learned rules to filter the output of an existing tactic selection approach and empirically show improvement over the non-filtering approaches.
format Preprint
id arxiv_https___arxiv_org_abs_2411_01188
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Learning Rules Explaining Interactive Theorem Proving Tactic Prediction
Zhang, Liao
Cerna, David M.
Kaliszyk, Cezary
Logic in Computer Science
Artificial Intelligence
Machine Learning
F.4.1, I.2.4
Formally verifying the correctness of mathematical proofs is more accessible than ever, however, the learning curve remains steep for many of the state-of-the-art interactive theorem provers (ITP). Deriving the most appropriate subsequent proof step, and reasoning about it, given the multitude of possibilities, remains a daunting task for novice users. To improve the situation, several investigations have developed machine learning based guidance for tactic selection. Such approaches struggle to learn non-trivial relationships between the chosen tactic and the structure of the proof state and represent them as symbolic expressions. To address these issues we (i) We represent the problem as an Inductive Logic Programming (ILP) task, (ii) Using the ILP representation we enriched the feature space by encoding additional, computationally expensive properties as background knowledge predicates, (iii) We use this enriched feature space to learn rules explaining when a tactic is applicable to a given proof state, (iv) we use the learned rules to filter the output of an existing tactic selection approach and empirically show improvement over the non-filtering approaches.
title Learning Rules Explaining Interactive Theorem Proving Tactic Prediction
topic Logic in Computer Science
Artificial Intelligence
Machine Learning
F.4.1, I.2.4
url https://arxiv.org/abs/2411.01188