TEMPORISE: Extracting semantic representations of varied input executions for silent data corruption evaluation

IF 6.2 2区计算机科学 Q1 COMPUTER SCIENCE, THEORY & METHODS

Future Generation Computer Systems-The International Journal of Escience Pub Date : 2025-01-27 DOI:10.1016/j.future.2025.107734

Junchi Ma, Yuzhu Ding, Sulei Huang, Zongtao Duan, Lei Tang

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引用次数: 0

Abstract

The continuous advancement of technology has led to increasingly complex computing systems, but it has also made them more susceptible to soft errors. Among the challenges posed by soft errors, silent data corruption (SDC) stands out as a particularly insidious threat, often occurring without warning. Estimating SDC probabilities for a program is a formidable task due to the diversity of inputs it can encounter, resulting in significant variations in these probabilities. This paper introduces TEMPORISE, a novel approach designed to tackle this challenge. TEMPORISE leverages the control data flow graph and calling context tree to represent the commonalities and distinctions between different input executions. The embeddings of these graphs are learned through structured graph attention network and AttrE2vec. These embeddings are then combined and input into a regression model to calculate SDC probabilities. The experiments demonstrate that TEMPORISE excels in predicting SDC probabilities, achieving a 78.4 % reduction in mean absolute error compared to vTRIDENT, the state-of-the-art baseline model. Moreover, TEMPORISE improves the rank correlation of SDC probabilities for various inputs by 11.4 % compared to vTRIDENT, indicating its superior ability to capture the relative ordering of SDC probabilities. In terms of computational efficiency, TEMPORISE boasts an impressive 91.3 % reduction in time cost compared to the traditional fault injection approach.

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来源期刊

Future Generation Computer Systems-The International Journal of Escience 工程技术-计算机：理论方法

CiteScore

19.90

自引率

2.70%

发文量

376

审稿时长

10.6 months

期刊介绍： Computing infrastructures and systems are constantly evolving, resulting in increasingly complex and collaborative scientific applications. To cope with these advancements, there is a growing need for collaborative tools that can effectively map, control, and execute these applications. Furthermore, with the explosion of Big Data, there is a requirement for innovative methods and infrastructures to collect, analyze, and derive meaningful insights from the vast amount of data generated. This necessitates the integration of computational and storage capabilities, databases, sensors, and human collaboration. Future Generation Computer Systems aims to pioneer advancements in distributed systems, collaborative environments, high-performance computing, and Big Data analytics. It strives to stay at the forefront of developments in grids, clouds, and the Internet of Things (IoT) to effectively address the challenges posed by these wide-area, fully distributed sensing and computing systems.