HpMC: An Energy-aware Management System of Multi-level Memory Architectures

Proceedings of the 2015 International Symposium on Memory Systems Pub Date : 2015-10-05 DOI:10.1145/2818950.2818974

Chun-Yi Su, D. Roberts, E. León, K. Cameron, B. D. Supinski, G. Loh, Dimitrios S. Nikolopoulos

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引用次数: 27

Abstract

DRAM technology faces density and power challenges to increase capacity because of limitations of physical cell design. To overcome these limitations, system designers are exploring alternative solutions that combine DRAM and emerging NVRAM technologies. Previous work on heterogeneous memories focuses, mainly, on two system designs: PCache, a hierarchical, inclusive memory system, and HRank, a flat, non-inclusive memory system. We demonstrate that neither of these designs can universally achieve high performance and energy efficiency across a suite of HPC workloads. In this work, we investigate the impact of a number of multi-level memory designs on the performance, power, and energy consumption of applications. To achieve this goal and overcome the limited number of available tools to study heterogeneous memories, we created HMsim, an infrastructure that enables n-level, heterogeneous memory studies by leveraging existing memory simulators. We, then, propose HpMC, a new memory controller design that combines the best aspects of existing management policies to improve performance and energy. Our energy-aware memory management system dynamically switches between PCache and HRank based on the temporal locality of applications. Our results show that HpMC reduces energy consumption from 13% to 45% compared to PCache and HRank, while providing the same bandwidth and higher capacity than a conventional DRAM system.

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HpMC:一种多级存储器架构的能量感知管理系统

由于物理单元设计的限制，DRAM技术在提高容量方面面临密度和功率方面的挑战。为了克服这些限制，系统设计人员正在探索结合DRAM和新兴NVRAM技术的替代解决方案。以前对异构存储器的研究主要集中在两种系统设计上:PCache是一种分层的、包容的存储器系统，HRank是一种扁平的、不包容的存储器系统。我们证明，这两种设计都不能在一套HPC工作负载中普遍实现高性能和能效。在这项工作中，我们研究了一些多级存储器设计对应用程序的性能、功率和能耗的影响。为了实现这一目标并克服研究异构内存可用工具数量有限的问题，我们创建了HMsim，这是一种利用现有内存模拟器实现n级异构内存研究的基础设施。然后，我们提出HpMC，一种新的内存控制器设计，结合了现有管理策略的最佳方面，以提高性能和能源。我们的能量感知内存管理系统基于应用程序的时间局域性在PCache和HRank之间动态切换。我们的研究结果表明，与PCache和HRank相比，HpMC将能耗从13%降低到45%，同时提供与传统DRAM系统相同的带宽和更高的容量。

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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Proceedings of the 2015 International Symposium on Memory Systems

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