透明获取管道中的失速周期重新分配

Eric L. Hill, Mikko H. Lipasti
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引用次数: 3

摘要

功率和功率密度现在是现代高性能微处理器的主要设计限制。高达70%的动态功耗可归因于时钟系统。这种趋势的结果是时钟门控已经成为一种必要和有效的方法,以显着降低动态功率。透明管道是最近提出的一种细粒度时钟门控技术,它有可能大大降低时钟功耗,超过传统的管道级时钟门控。以前对透明管道的研究主要集中在电路和实现相关的问题上,而忽略了更广泛的微架构含义。本文旨在量化在处理器的获取管道中使用透明管道所提供的微架构机会。我们开发了一种基于失速周期再分配的技术,旨在提高透明管道在读取和其他高利用率管道上的性能。我们的研究表明,失速周期的重新分配可以显著降低具有侵略性的流水线式单元微处理器的时钟开销
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Stall Cycle Redistribution in a Transparent Fetch Pipeline
Power and power density are now primary design constraints for modern high performance microprocessors. Up to 70% of the dynamic power consumed can be attributed to the clocking system. A consequence of this trend is that clock gating has emerged as both a necessary and efficient method to significantly reduce dynamic power. Transparent pipelining, a recently proposed fine-grain clock gating technique, has the potential to significantly reduce clock power above and beyond conventional pipestage-level clock gating. Previous studies of transparent pipelining have focused on the circuit and implementation-related issues of this approach, while neglecting the broader microarchitectural implications. This paper aims to quantify the microarchitectural opportunities that are afforded by the use of transparent pipelining in a processor's fetch pipeline. We develop a technique, based on stall cycle redistribution, designed to improve the performance of transparent pipelining on fetch and other high utilization pipelines. We show that stall cycle redistribution can dramatically reduce the clocking overhead of an aggressively pipelined cell-like microprocessor
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