使用重写监视程序

Proceedings 16th Annual International Conference on Automated Software Engineering (ASE 2001) Pub Date : 2001-11-26 DOI:10.1109/ASE.2001.989799

K. Havelund, Grigore Roşu

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引用次数: 219

摘要

我们提出了一种重写算法，用于在有限的执行轨迹上有效地测试未来时间线性时序逻辑(LTL)公式。LTL的标准模型是无限轨迹，反映了反应性和并发系统的行为，这些系统在概念上可能是连续存在的。在过去的大多数LTL应用中，定理证明器和模型检查器已经被用来正式证明缩小模型满足这样的LTL规范。相反，我们的目标是将LTL用于实际软件应用程序的大规模测试，对应于根据LTL公式分析有限轨迹的一致性。我们首先描述了有限轨迹满足LTL公式的意义，然后提出了一种基于LTL公式变换的优化算法。我们使用Maude重写逻辑，它被证明是一个很好的符号，并且由一个高效的重写引擎支持来执行这些实验。这项工作构成了Java patheexplorer (JPAX)项目的一部分，该项目的目的是开发一种灵活的工具来监视Java程序的执行。

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Monitoring programs using rewriting

We present a rewriting algorithm for efficiently testing future time Linear Temporal Logic (LTL) formulae on finite execution traces. The standard models of LTL are infinite traces, reflecting the behavior of reactive and concurrent systems which conceptually may be continuously alive. In most past applications of LTL, theorem provers and model checkers have been used to formally prove that down-scaled models satisfy such LTL specifications. Our goal is instead to use LTL for up-scaled testing of real software applications, corresponding to analyzing the conformance of finite traces against LTL formulae. We first describe what it means for a finite trace to satisfy an LTL formula and then suggest an optimized algorithm based on transforming LTL formulae. We use the Maude rewriting logic, which turns out to be a good notation and being supported by an efficient rewriting engine for performing these experiments. The work constitutes part of the Java PathExplorer (JPAX) project, the purpose of which is to develop a flexible tool for monitoring Java program executions.

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Proceedings 16th Annual International Conference on Automated Software Engineering (ASE 2001)

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