Functional units power gating in SMT processors

PACRIM. 2005 IEEE Pacific Rim Conference on Communications, Computers and signal Processing, 2005. Pub Date : 2005-10-17 DOI:10.1109/PACRIM.2005.1517241

H. Homayoun, K. Li, S. Rafatirad

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引用次数: 9

Abstract

Power consumption has emerged as a primary concern in processor design constraints. Power-aware techniques are being applied at all levels of circuit and system design. These techniques aim at reducing power or energy dissipation in all types of computer equipments while meeting a desired throughput. At the architectural level, power-aware design has been an active area of research in the last decade for superscalar processors. Simultaneous multithreading processor (SMT), introduced as a complementary architecture to superscalar to increase throughput, has received less attention in the context of low-power design techniques. In SMT processors functional units are one of the major power consumers. In this paper we first study the opportunity for reducing the power consumption of functional units. Our results show that functional units are idle for a significant portion of the total execution cycle. Then we reuse and evaluate a microarchitectural technique to reduce functional unit power through power gating which has been recently proposed for superscalar processors. We show that in SMT processors, this technique can reduce floating point unit power considerably while maintaining performance.

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SMT处理器中的功能单元功率门控

功耗已经成为处理器设计限制的主要关注点。功率感知技术正在应用于电路和系统设计的各个层面。这些技术旨在降低所有类型的计算机设备的功率或能量耗散，同时满足所需的吞吐量。在架构层面，功耗感知设计在过去十年中一直是超标量处理器的一个活跃研究领域。同步多线程处理器(SMT)作为超标量的补充架构而引入，以提高吞吐量，在低功耗设计技术中受到的关注较少。在SMT处理器中，功能单元是主要的电力消耗者之一。在本文中，我们首先研究降低功能单元功耗的机会。我们的结果表明，功能单元在整个执行周期的很大一部分是空闲的。然后，我们重用和评估了最近提出的用于超标量处理器的通过功率门控来降低功能单元功耗的微架构技术。我们表明，在SMT处理器中，该技术可以在保持性能的同时大大降低浮点单元功耗。

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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PACRIM. 2005 IEEE Pacific Rim Conference on Communications, Computers and signal Processing, 2005.

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