Computing prime implicants

2013 Formal Methods in Computer-Aided Design Pub Date : 2013-12-11 DOI:10.1109/FMCAD.2013.6679390

D. Déharbe, P. Fontaine, Daniel Le Berre, Bertrand Mazure

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引用次数: 7

Abstract

Model checking and counter-example guided abstraction refinement are examples of applications of SAT solving requiring the production of models for satisfiable formulas. Better than giving a truth value to every variable, one can provide an implicant, i.e. a partial assignment of the variables such that every full extension is a model for the formula. An implicant is prime if every assignment is necessary. Since prime implicants contain no literal irrelevant for the satisfiability of the formula, they are considered as highly refined information. We here propose a novel algorithm that uses data structures found in modern CDCL SAT solvers to efficiently compute prime implicants starting from an existing model. The original aspects are (1) the algorithm is based on watched literals and a form of propagation of required literals, adapted to CDCL solvers (2) the algorithm works not only on clauses, but also on generalized constraints (3) for clauses and, more generally for cardinality constraints, the algorithm complexity is linear in the size of the constraints found. We implemented and evaluated the algorithm with the Sat4j library.

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计算质数

模型检查和反例引导的抽象细化是SAT求解需要为可满足的公式生成模型的应用实例。比起给每个变量一个真值，我们可以提供一个隐含的，即变量的部分赋值，使得每个完全扩展都是公式的一个模型。如果每个赋值都是必要的，则隐含是素数。由于素蕴涵不包含与公式的可满足性无关的文字，它们被认为是高度精炼的信息。我们在这里提出了一种新的算法，该算法使用现代CDCL SAT求解器中的数据结构，从现有模型开始有效地计算质数蕴涵。最初的方面是(1)该算法基于观察文字和所需文字的传播形式，适用于CDCL解算器(2)该算法不仅适用于子句，还适用于广义约束(3)对于子句，更普遍的是对于基数约束，算法复杂性在发现的约束的大小上是线性的。我们使用Sat4j库实现并评估了该算法。

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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2013 Formal Methods in Computer-Aided Design

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