用于高活性验证的谓词抽象。

IF 0.8 4区计算机科学 Q3 COMPUTER SCIENCE, THEORY & METHODS

Formal Methods in System Design Pub Date : 2025-01-01 Epub Date: 2025-07-16 DOI:10.1007/s10703-025-00482-5

Raven Beutner, Bernd Finkbeiner

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引用次数: 0

摘要

时间超属性是与多个执行跟踪相关的系统属性。在有限状态系统中，时间超属性由模型检查算法支持，并且存在用于一般时间逻辑（如HyperLTL）的工具。在无限状态系统中，时间超性质的分析迄今为止仅限于k-安全性质，即规定任何k迹之间不存在不良相互作用的性质。在本文中，我们提出了一种在无限状态系统中验证∀k∃l -安全性质的自动化方法。∀k∃l -安全性质规定，对于任何k条迹，存在l条迹，使得所得到的k + l条迹不会严重相互作用。这种全称和存在量化的结合捕获了k安全之外的许多特性，包括高活性特性，如广义不干扰或程序精化。我们的验证方法基于基于策略的存在跟踪量化实例化，并结合了程序简化，两者都在固定谓词抽象的上下文中。

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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Predicate abstraction for hyperliveness verification.

Temporal hyperproperties are system properties that relate multiple execution traces. In finite-state systems, temporal hyperproperties are supported by model-checking algorithms, and tools for general temporal logics like HyperLTL exist. In infinite-state systems, the analysis of temporal hyperproperties has, so far, been limited to k-safety properties, i.e., properties that stipulate the absence of a bad interaction between any k traces. In this paper, we present an automated method for the verification of $\forall^{k} \exists^{l}$ -safety properties in infinite-state systems. A $\forall^{k} \exists^{l}$ -safety property stipulates that for any k traces, there exist l traces such that the resulting $k + l$ traces do not interact badly. This combination of universal and existential quantification captures many properties beyond k-safety, including hyperliveness properties such as generalized non-interference or program refinement. Our verification method is based on a strategy-based instantiation of existential trace quantification combined with a program reduction, both in the context of a fixed predicate abstraction.

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来源期刊

Formal Methods in System Design 工程技术-计算机：理论方法

CiteScore

2.00

自引率

12.50%

发文量

审稿时长

>12 weeks

期刊介绍： The focus of this journal is on formal methods for designing, implementing, and validating the correctness of hardware (VLSI) and software systems. The stimulus for starting a journal with this goal came from both academia and industry. In both areas, interest in the use of formal methods has increased rapidly during the past few years. The enormous cost and time required to validate new designs has led to the realization that more powerful techniques must be developed. A number of techniques and tools are currently being devised for improving the reliability, and robustness of complex hardware and software systems. While the boundary between the (sub)components of a system that are cast in hardware, firmware, or software continues to blur, the relevant design disciplines and formal methods are maturing rapidly. Consequently, an important (and useful) collection of commonly applicable formal methods are expected to emerge that will strongly influence future design environments and design methods.