Theory learning with symmetry breaking

Proceedings of the 19th International Symposium on Principles and Practice of Declarative Programming Pub Date : 2017-10-09 DOI:10.1145/3131851.3131861

J. M. Howe, E. Robbins, A. King

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Abstract

This paper investigates the use of a Prolog coded SMT solver in tackling a well known constraints problem, namely packing a given set of consecutive squares into a given rectangle, and details the developments in the solver that this motivates. The packing problem has a natural model in the theory of quantifier-free integer difference logic, a theory supported by many SMT solvers. The solver used in this work exploits a data structure consisting of an incremental Floyd-Warshall matrix paired with a watch matrix that monitors the entailment status of integer difference constraints. It is shown how this structure can be used to build unsatisfiable theory cores on the fly, which in turn allows theory learning to be incorporated into the solver. Further, it is shown that a problem-specific and non-standard approach to learning can be taken where symmetry breaking is incorporated into the learning stage, magnifying the effect of learning. It is argued that the declarative framework allows the solver to be used in this white box manner and is a strength of the solver. The approach is experimentally evaluated.

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对称性破缺的理论学习

本文研究了Prolog编码的SMT求解器在解决一个众所周知的约束问题中的使用，即将一组给定的连续正方形打包到一个给定的矩形中，并详细介绍了求解器在这方面的发展。在无量词的整数差分逻辑理论中，填充问题具有一个自然的模型，该理论得到了许多SMT求解器的支持。本工作中使用的求解器利用了一种数据结构，该结构由一个增量Floyd-Warshall矩阵与一个监视整数差分约束的隐含状态的监视矩阵组成。它展示了如何使用这种结构在飞行中构建不令人满意的理论核心，这反过来又允许理论学习被纳入求解器。此外，研究表明，可以采取针对特定问题和非标准的学习方法，将对称性破坏纳入学习阶段，从而放大学习效果。有人认为声明性框架允许求解器以这种白盒方式使用，并且是求解器的优势。实验对该方法进行了验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the 19th International Symposium on Principles and Practice of Declarative Programming

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