Harmonia: Balancing compute and memory power in high-performance GPUs

2015 ACM/IEEE 42nd Annual International Symposium on Computer Architecture (ISCA) Pub Date : 2015-06-13 DOI:10.1145/2749469.2750404

Indrani Paul, Wei Huang, Manish Arora, S. Yalamanchili

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引用次数: 58

Abstract

In this paper, we address the problem of efficiently managing the relative power demands of a high-performance GPU and its memory subsystem. We develop a management approach that dynamically tunes the hardware operating configurations to maintain balance between the power dissipated in compute versus memory access across GPGPU application phases. Our goal is to reduce power with minimal performance degradation. Accordingly, we construct predictors that assess the online sensitivity of applications to three hardware tunables-compute frequency, number of active compute units, and memory bandwidth. Using these sensitivity predictors, we propose a two-level coordinated power management scheme, Harmonia, which coordinates the hardware power states of the GPU and the memory system. Through hardware measurements on a commodity GPU, we evaluate Harmonia against a state-of-the-practice commodity GPU power management scheme, as well as an oracle scheme. Results show that Harmonia improves measured energy-delay squared (ED2) by up to 36% (12% on average) with negligible performance loss across representative GPGPU workloads, and on an average is within 3% of the oracle scheme.

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和谐:在高性能gpu上平衡计算能力和内存能力

在本文中，我们解决了高效管理高性能GPU及其内存子系统的相对功率需求的问题。我们开发了一种管理方法，可以动态调整硬件操作配置，以保持GPGPU应用程序阶段的计算功耗与内存访问之间的平衡。我们的目标是在最小化性能下降的情况下降低功耗。因此，我们构建了预测器来评估应用程序对三个硬件可调项的在线敏感性——计算频率、活动计算单元的数量和内存带宽。利用这些灵敏度预测，我们提出了一种两级协调电源管理方案Harmonia，该方案协调了GPU和存储系统的硬件电源状态。通过对商品GPU的硬件测量，我们将Harmonia与最实用的商品GPU电源管理方案以及oracle方案进行了比较。结果表明，Harmonia将测量的能量延迟平方(ED2)提高了36%(平均12%)，而在代表性GPGPU工作负载上的性能损失可以忽略不计，平均在oracle方案的3%以内。

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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2015 ACM/IEEE 42nd Annual International Symposium on Computer Architecture (ISCA)

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