In-network Monitoring and Control Policy for DVFS of CMP Networks-on-Chip and Last Level Caches

2012 IEEE/ACM Sixth International Symposium on Networks-on-Chip Pub Date : 2012-05-09 DOI:10.1145/2504905

X. Chen, Zheng Xu, Hyungjun Kim, Paul V. Gratz, Jiang Hu, M. Kishinevsky, Ümit Y. Ogras

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引用次数: 61

Abstract

In chip design today and for a foreseeable future, on-chip communication is not only a performance bottleneck but also a substantial power consumer. This work focuses on employing dynamic voltage and frequency scaling (DVFS) policies for networks-on-chip (NoC) and shared, distributed last-level caches (LLC). In particular, we consider a practical system architecture where the distributed LLC and the NoC share a voltage/frequency domain which is separate from the core domain. This architecture enables controlling the relative speed between the cores and memory hierarchy without introducing synchronization delays within the NoC. DVFS for this architecture is more difficult than individual link/core-based DVFS since it involves spatially distributed monitoring and control. We propose an average memory access time (AMAT)-based monitoring technique and integrate it with DVFS based on PID control theory. Simulations on PARSEC benchmarks yield a 33% dynamic energy savings with a negligible impact on system performance.

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CMP片上网络和末级缓存DVFS的网内监控策略

在当今和可预见的未来，芯片上的通信不仅是性能瓶颈，也是一个巨大的功耗消耗。这项工作的重点是在片上网络(NoC)和共享、分布式最后一级缓存(LLC)中采用动态电压和频率缩放(DVFS)策略。特别是，我们考虑了一种实用的系统架构，其中分布式LLC和NoC共享与核心域分离的电压/频率域。这种体系结构可以控制内核和内存层次之间的相对速度，而不会在NoC中引入同步延迟。这种体系结构的DVFS比基于单个链接/核心的DVFS更困难，因为它涉及空间分布的监视和控制。提出了一种基于平均存储器访问时间(AMAT)的监控技术，并将其与基于PID控制理论的DVFS相结合。在PARSEC基准测试上的模拟产生了33%的动态节能，对系统性能的影响可以忽略不计。

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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2012 IEEE/ACM Sixth International Symposium on Networks-on-Chip

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