针对测试增强的非正式证明分析

13th International Symposium on Software Reliability Engineering, 2002. Proceedings. Pub Date : 2002-11-12 DOI:10.1109/ISSRE.2002.1173209

G. Lussier, H. Waeselynck

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引用次数: 3

摘要

本文旨在验证通用容错算法的性质。我们的目标是用从算法证明中提取的信息来增强测试过程，无论这个证明是正式的还是非正式的:理想情况下，测试旨在关注证明的薄弱部分(例如，未证明的引理或可疑的非正式证据)。本文以容错率单调调度算法为例进行了研究。该算法通过非正式演示得到了验证，但随后暴露出两个缺陷。在本文中，我们重点分析了非正式证明，并将其重构为基于自然演绎的半正式证明树。从这个证明树中，我们提取了几个功能用例，并用它们来测试算法的原型。实验结果表明，有缺陷的非正式证明不一定能为测试提供相关信息。形式上的(部分的)证明是否能更好地与潜在的错误联系起来还有待研究。

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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Informal proof analysis towards testing enhancement

This paper aims at verifying properties of generic fault-tolerance algorithms. Our goal is to enhance the testing process with information extracted from the proof of the algorithm, whether this proof is formal or informal: ideally, testing is intended to focus on the weak parts of the proof (e.g., unproved lemmas or doubtful informal evidence). We use the Fault-Tolerant Rate Monotonic Scheduling algorithm as a case study. This algorithm was proven by informal demonstration, but two faults were revealed afterwards. In this paper, we focus on the analysis of the informal proof, which we restructure in a semiformal proof tree based on natural deduction. From this proof tree, we extract several functional cases and use them for testing a prototype of the algorithm. Experimental results show that a flawed informal proof does not necessarily provide relevant information for testing. It remains to investigate whether formal (partial) proofs allow better connection with potential faults.

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13th International Symposium on Software Reliability Engineering, 2002. Proceedings.

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