Towards analyzing and improving robustness of software applications to intermittent and permanent faults in hardware

2013 IEEE 31st International Conference on Computer Design (ICCD) Pub Date : 2013-11-07 DOI:10.1109/ICCD.2013.6657076

A. Sharma, Joseph Sloan, L. Wanner, Salma Elmalaki, M. Srivastava, Puneet Gupta

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引用次数: 4

Abstract

Although a significant fraction of emerging failure and wearout mechanisms result in intermittent or permanent faults in hardware, their impact (as distinct from transient faults) on software applications has not been well studied. In this paper, we develop a distinguishing application characteristic, referred to as similarity from fundamental circuit-level understanding of the failure mechanisms. We present a mathematical definition and a procedure for similarity computation for practical software applications and experimentally verify the relationship between similarity and fault rate. Leveraging dependence of application robustness on the similarity metric, we present example architecture independent code transformations to reduce similarity and thereby the worst-case fault rate with minimal performance degradation. Our experimental results with arithmetic unit faults show as much as 74% improvement in the worst case fault rate on benchmark kernels, with less than 10% runtime penalty.

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分析和提高软件应用程序对硬件中间歇性和永久性故障的鲁棒性

尽管出现故障和磨损机制的很大一部分会导致硬件中的间歇性或永久性故障，但它们对软件应用程序的影响(与瞬时故障不同)尚未得到很好的研究。在本文中，我们开发了一个区分应用特征，即从基本电路级的故障机制理解的相似性。本文给出了一个数学定义和一种实用软件应用的相似度计算方法，并通过实验验证了相似度与故障率之间的关系。利用应用程序鲁棒性对相似度度量的依赖性，我们给出了与体系结构无关的代码转换示例，以减少相似度，从而在最小的性能下降的情况下降低最坏情况的故障率。我们使用算术单元错误的实验结果显示，在基准内核上，最坏情况下的故障率提高了74%，运行时间损失不到10%。

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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2013 IEEE 31st International Conference on Computer Design (ICCD)

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