Future scaling of processor-memory interfaces

Proceedings of the Conference on High Performance Computing Networking, Storage and Analysis Pub Date : 2009-11-14 DOI:10.1145/1654059.1654102

Jung Ho Ahn, N. Jouppi, C. Kozyrakis, J. Leverich, R. Schreiber

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引用次数: 121

Abstract

Continuous evolution in process technology brings energy-efficiency and reliability challenges, which are harder for memory system designs since chip multiprocessors demand high bandwidth and capacity, global wires improve slowly, and more cells are susceptible to hard and soft errors. Recently, there are proposals aiming at better main-memory energy efficiency by dividing a memory rank into subsets. We holistically assess the effectiveness of rank subsetting in the context of system-wide performance, energy-efficiency, and reliability perspectives. We identify the impact of rank subsetting on memory power and processor performance analytically, then verify the analyses by simulating a chip-multiprocessor system using multithreaded and consolidated workloads. We extend the design of Multicore DIMM, one proposal embodying rank subsetting, for high-reliability systems and show that compared with conventional chipkill approaches, it can lead to much higher system-level energy efficiency and performance at the cost of additional DRAM devices.

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处理器-内存接口的未来扩展

工艺技术的不断发展带来了能效和可靠性方面的挑战，这对存储系统设计来说更加困难，因为芯片多处理器需要高带宽和容量，全局线路改善缓慢，并且更多的单元容易受到硬错误和软错误的影响。最近，有一些建议旨在通过将内存等级划分为子集来提高主存的能量效率。我们全面评估等级子集在全系统性能、能源效率和可靠性方面的有效性。我们分析了等级子集对内存功率和处理器性能的影响，然后通过使用多线程和合并工作负载模拟芯片多处理器系统来验证分析。我们扩展了多核DIMM的设计，其中一个提案体现了等级子集，用于高可靠性系统，并表明与传统的芯片杀死方法相比，它可以带来更高的系统级能源效率和性能，而代价是额外的DRAM设备。

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 Conference on High Performance Computing Networking, Storage and Analysis

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