超越CPU频率缩放的HPC系统细粒度能量控制

2012 IEEE 24th International Symposium on Computer Architecture and High Performance Computing Pub Date : 2012-10-24 DOI:10.1109/SBAC-PAD.2012.32

Ghislain Landry Tsafack Chetsa, L. Lefèvre, J. Pierson, P. Stolf, Georges Da Costa

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引用次数: 19

摘要

现代高性能计算子系统(HPC)——包括处理器、网络、内存和IO——都提供了电源管理机制。其中包括动态速度缩放和动态资源休眠。了解高性能计算系统在运行时的行为模式可以带来许多优化机会，包括控制和限制它们的能源使用。在本文中，我们提出了一种通用的方法来优化高性能计算系统的能量性能，考虑处理器，磁盘和网络。我们依靠执行向量的概念以及部分阶段识别技术来进行动态管理，而无需任何工作负载的先验知识。我们在两个实际工作负载下展示了我们的管理政策的有效性。实验结果表明，与基线非托管执行相比，我们的管理策略在实际工作负载中节省了高达24%的能源，而性能开销不到4%。

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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Beyond CPU Frequency Scaling for a Fine-grained Energy Control of HPC Systems

Modern high performance computing subsystems (HPC) - including processor, network, memory, and IO - are provided with power management mechanisms. These include dynamic speed scaling and dynamic resource sleeping. Understanding the behavioral patterns of high performance computing systems at runtime can lead to a multitude of optimization opportunities including controlling and limiting their energy usage. In this paper, we present a general purpose methodology for optimizing energy performance of HPC systems considering processor, disk and network. We rely on the concept of execution vector along with a partial phase recognition technique for on-the-fly dynamic management without any a priori knowledge of the workload. We demonstrate the effectiveness of our management policy under two real-life workloads. Experimental results show that our management policy in comparison with baseline unmanaged execution saves up to 24% of energy with less than 4% performance overhead for our real-life workloads.

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2012 IEEE 24th International Symposium on Computer Architecture and High Performance Computing

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