Deterministic clock gating for microprocessor power reduction

The Ninth International Symposium on High-Performance Computer Architecture, 2003. HPCA-9 2003. Proceedings. Pub Date : 2003-02-08 DOI:10.1109/HPCA.2003.1183529

Hai Helen Li, S. Bhunia, Yiran Chen, T. N. Vijaykumar, K. Roy

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引用次数: 110

Abstract

With the scaling of technology and the need for higher performance and more functionality, power dissipation is becoming a major bottleneck for microprocessor designs. Pipeline balancing (PLB), a previous technique, is essentially a methodology to clock-gate unused components whenever a program's instruction-level parallelism is predicted to be low. However, no nonpredictive methodologies are available in the literature for efficient clock gating. This paper introduces deterministic clock gating (DCG) based on the key observation that for many of the stages in a modern pipeline, a circuit block's usage in a specific cycle in the near future is deterministically known a few cycles ahead of time. Our experiments show an average of 19.9% reduction in processor power with virtually no performance loss for an 8-issue, out-of-order superscalar processor by applying DCG to execution units, pipeline latches, D-Cache wordline decoders, and result bus drivers. In contrast, PLB achieves 9.9% average power savings at 2.9% performance loss.

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用于微处理器功耗降低的确定性时钟门控

随着技术的规模化以及对更高性能和更多功能的需求，功耗正成为微处理器设计的主要瓶颈。管道平衡(PLB)是以前的一种技术，本质上是一种方法，每当预测程序的指令级并行性较低时，就对未使用的组件进行时钟门控制。然而，在文献中没有非预测性的方法可用于有效的时钟门控。本文介绍了确定性时钟门控(DCG)，它基于一个关键观察，即对于现代管道中的许多阶段，电路块在不久的将来在特定周期中的使用情况是提前几个周期确定的。我们的实验表明，通过将DCG应用于执行单元、管道锁存器、D-Cache字行解码器和结果总线驱动程序，处理器功耗平均降低了19.9%，并且几乎没有性能损失。相比之下，PLB实现了9.9%的平均功耗节省和2.9%的性能损失。

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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The Ninth International Symposium on High-Performance Computer Architecture, 2003. HPCA-9 2003. Proceedings.

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