AVICA: An access-time variation insensitive L1 cache architecture

2013 Design, Automation & Test in Europe Conference & Exhibition (DATE) Pub Date : 2013-03-18 DOI:10.7873/DATE.2013.028

Seokin Hong, Soontae Kim

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引用次数: 8

Abstract

Ever scaling process technology increases variations in transistors. The process variations cause large fluctuations in the access times of SRAM cells. Caches made of those SRAM cells cannot be accessed within the target clock cycle time, which reduces yield of processors. To combat these access time failures in caches, many schemes have been proposed, which are, however, limited in their coverage and do not scale well at high failure rates. We propose a new L1 cache architecture (AVICA) employing asymmetric pipelining and pseudo multi-banking. Asymmetric pipelining eliminates all access time failures in L1 caches. Pseudo multi-banking minimizes the performance impact of asymmetric pipelining. For further performance improvement, architectural techniques are proposed. Our experimental results show that our proposed L1 cache architecture incurs less than 1% performance hit compared to the conventional cache architecture with no access time failure. Our proposed architecture is not sensitive to access time failure rates and has low overheads compared to the previously proposed competitive schemes.

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AVICA:访问时间变化不敏感的L1缓存架构

不断缩放的工艺技术增加了晶体管的变化。过程的变化导致SRAM单元的访问时间有很大的波动。由这些SRAM单元组成的缓存不能在目标时钟周期内被访问，这降低了处理器的产量。为了解决这些缓存中的访问时间故障，已经提出了许多方案，然而，它们的覆盖范围有限，并且在高故障率下不能很好地扩展。我们提出了一种新的L1缓存架构(AVICA)，采用非对称管道和伪多银行。非对称管道消除了L1缓存中的所有访问时间故障。伪多银行最大限度地减少了非对称管道对性能的影响。为了进一步提高性能，提出了体系结构技术。我们的实验结果表明，与传统的缓存体系结构相比，我们提出的L1缓存体系结构在没有访问时间故障的情况下导致不到1%的性能损失。我们提出的架构对访问时间故障率不敏感，与之前提出的竞争方案相比，开销低。

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 Design, Automation & Test in Europe Conference & Exhibition (DATE)

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