Quantitative and Approximate Monitoring

2021 36th Annual ACM/IEEE Symposium on Logic in Computer Science (LICS) Pub Date : 2021-05-18 DOI:10.1109/LICS52264.2021.9470547

T. Henzinger, N. Saraç

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引用次数: 5

Abstract

In runtime verification, a monitor watches a trace of a system and, if possible, decides after observing each finite prefix whether or not the unknown infinite trace satisfies a given specification. We generalize the theory of runtime verification to monitors that attempt to estimate numerical values of quantitative trace properties (instead of attempting to conclude boolean values of trace specifications), such as maximal or average response time along a trace. Quantitative monitors are approximate: with every finite prefix, they can improve their estimate of the infinite trace’s unknown property value. Consequently, quantitative monitors can be compared with regard to a precision-cost trade-off: better approximations of the property value require more monitor resources, such as states (in the case of finite-state monitors) or registers, and additional resources yield better approximations. We introduce a formal framework for quantitative and approximate monitoring, show how it conservatively generalizes the classical boolean setting for monitoring, and give several precision-cost trade-offs for monitors. For example, we prove that there are quantitative properties for which every additional register improves monitoring precision.

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定量和近似监测

在运行时验证中，监视器监视系统的跟踪，如果可能的话，在观察每个有限前缀之后决定未知的无限跟踪是否满足给定的规范。我们将运行时验证理论推广到试图估计定量跟踪属性的数值(而不是试图得出跟踪规范的布尔值)的监视器，例如沿着跟踪的最大或平均响应时间。定量监视器是近似的:对于每个有限前缀，它们可以改进对无限轨迹未知属性值的估计。因此，可以将定量监视器与精度和成本之间的权衡进行比较:更好的属性值近似值需要更多的监视器资源，例如状态(在有限状态监视器的情况下)或寄存器，而额外的资源可以产生更好的近似值。我们介绍了一个用于定量和近似监测的正式框架，展示了它如何保守地推广用于监测的经典布尔设置，并给出了监视器的几个精度成本权衡。例如，我们证明了每增加一个寄存器就能提高监测精度的定量特性。

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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2021 36th Annual ACM/IEEE Symposium on Logic in Computer Science (LICS)

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