Enhancing Fault Tolerance in High-Performance Computing: A Real Hardware Case Study on a RISC-V Vector Processing Unit

IEEE Open Journal of the Computer Society Pub Date : 2024-09-25 DOI:10.1109/OJCS.2024.3468895

Marcello Barbirotta;Francesco Minervini;Carlos Rojas Morales;Adrian Cristal;Osman Unsal;Mauro Olivieri

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Abstract

High-Performance Computing (HPC) systems are designed for large-scale processing and complex dataset analysis leveraging scalability, efficiency, and parallelism, often integrating specialized hardware structures such as Vector Processing Units (VPUs). As these systems have grown in complexity and scale, their vulnerability to errors and failures has become an important and complex issue in the HPC world. Our research addresses this challenge by exploring and implementing advanced fault tolerance techniques inside the Vitruvius+ architecture, a partial out-of-order Vector Processing Unit. To the best of our knowledge, this is the first full RTL-level implementation of instruction replication in an HPC-class vector processor for reliability. Specifically, we investigate the integration and interaction of redundancy mechanisms inside the most sensitive architectural units, obtaining a reduction of 75% in non-silent faults causing system failure, proven by an extensive fault injection simulation campaign, with a hardware overhead of only 7.5% and a negligible variation in clock frequency.

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增强高性能计算的容错性：RISC-V 矢量处理单元的真实硬件案例研究

高性能计算（HPC）系统旨在利用可扩展性、效率和并行性进行大规模处理和复杂数据集分析，通常集成了矢量处理单元（VPU）等专用硬件结构。随着这些系统的复杂性和规模不断扩大，它们易受错误和故障影响的问题已成为高性能计算领域一个重要而复杂的问题。我们的研究通过探索和实施 Vitruvius+ 架构（部分无序矢量处理单元）内的高级容错技术来应对这一挑战。据我们所知，这是首次在高性能计算级矢量处理器中全面实施RTL级指令复制，以提高可靠性。具体来说，我们研究了最敏感架构单元内冗余机制的集成和交互，通过大量故障注入仿真活动证明，导致系统故障的非静态故障减少了 75%，硬件开销仅为 7.5%，时钟频率变化可忽略不计。

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来源期刊

IEEE Open Journal of the Computer Society

CiteScore

12.60

自引率

0.00%

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