E < MC2: less energy through multi-copy cache

International Conference on Compilers, Architecture, and Synthesis for Embedded Systems Pub Date : 2010-10-24 DOI:10.1145/1878921.1878956

Arup Chakraborty, H. Homayoun, A. Djahromi, N. Dutt, A. Eltawil, F. Kurdahi

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引用次数: 43

Abstract

Caches are known to consume a large part of total microprocessor power. Traditionally, voltage scaling has been used to reduce both dynamic and leakage power in caches. However, aggressive voltage reduction causes process-variation-induced failures in cache SRAM arrays, which compromise cache reliability. We present Multi-Copy Cache (MC2), a new cache architecture that achieves significant reduction in energy consumption through aggressive voltage scaling, while maintaining high error resilience (reliability) by exploiting multiple copies of each data item in the cache. Unlike many previous approaches, MC2 does not require any error map characterization and therefore is responsive to changing operating conditions (e.g., Vdd-noise, temperature and leakage) of the cache. MC2 also incurs significantly lower overheads compared to other ECC-based caches. Our experimental results on embedded benchmarks demonstrate that MC2 achieves up to 60% reduction in energy and energy-delay product (EDP) with only 3.5% reduction in IPC and no appreciable area overhead.

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E < MC2:通过多副本缓存减少能量

众所周知，缓存消耗了微处理器总功率的很大一部分。传统上，电压缩放已被用于降低缓存中的动态功率和泄漏功率。然而，激进的电压降低会导致高速缓存SRAM阵列中工艺变化引起的故障，从而损害高速缓存的可靠性。我们提出了多副本缓存(MC2)，这是一种新的缓存架构，通过积极的电压缩放来显著降低能耗，同时通过利用缓存中每个数据项的多个副本来保持高错误弹性(可靠性)。与许多以前的方法不同，MC2不需要任何误差图表征，因此可以响应缓存的变化操作条件(例如，vdd噪声，温度和泄漏)。与其他基于ecc的缓存相比，MC2的开销也显著降低。我们在嵌入式基准测试上的实验结果表明，MC2实现了高达60%的能源和能源延迟产品(EDP)的降低，而IPC仅降低了3.5%，并且没有明显的面积开销。

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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International Conference on Compilers, Architecture, and Synthesis for Embedded Systems

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