Robustness Inside Out Testing

2020 50th Annual IEEE-IFIP International Conference on Dependable Systems and Networks-Supplemental Volume (DSN-S) Pub Date : 2020-06-01 DOI:10.1109/DSN-S50200.2020.00013

Deborah S. Katz, Milda Zizyte, Casidhe Hutchison, David Guttendorf, Patrick E. Lanigan, Eric Sample, P. Koopman, Michael D. Wagner, Claire Le Goues

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引用次数: 7

Abstract

Robustness testing is an important technique to reveal defects and vulnerabilities in software, especially software for Unmanned Autonomous Systems (UAS). We present Robustness Inside Out Testing (RIOT) as a technique directed at finding failures in autonomy systems that are able to be activated from external interfaces. The technique consists of four main steps: unit-level robustness testing, generalization, permeability analysis, and activation. Each of these steps yields a valuable deliverable in the testing process, and, when applied in succession, expands a unit-level bug to an external interface. RIOT has the following advantages over traditional robustness testing: it finds faults faster, it can find faults missed by traditional approaches, it identifies faults that can be triggered from inputs at an external interface, and it produces useful artifacts to aid in fault diagnosis and repair. In this paper, we outline each step of the RIOT process and provide an example of RIOT finding a bug on a real system that would not have been discovered using existing techniques.

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健壮性测试

鲁棒性测试是发现软件缺陷和漏洞的一项重要技术，尤其是无人自主系统(UAS)软件。我们提出健壮性内外测试(RIOT)作为一种技术，旨在发现能够从外部接口激活的自治系统中的故障。该技术包括四个主要步骤:单元级鲁棒性测试、泛化、渗透率分析和激活。这些步骤中的每一个都在测试过程中产生有价值的可交付成果，并且，当连续应用时，将单元级错误扩展到外部接口。与传统的健壮性测试相比，RIOT具有以下优点:它可以更快地发现故障，它可以发现传统方法遗漏的故障，它可以识别可以从外部接口输入触发的故障，并且它产生有用的工件来帮助故障诊断和修复。在本文中，我们概述了RIOT过程的每个步骤，并提供了一个RIOT在使用现有技术无法发现的真实系统上发现bug的示例。

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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2020 50th Annual IEEE-IFIP International Conference on Dependable Systems and Networks-Supplemental Volume (DSN-S)

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