Catnap: energy proportional multiple network-on-chip

Proceedings of the 40th Annual International Symposium on Computer Architecture Pub Date : 2013-06-23 DOI:10.1145/2485922.2485950

R. Das, S. Narayanasamy, Sudhir K. Satpathy, R. Dreslinski

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引用次数: 156

Abstract

Multiple networks have been used in several processor implementations to scale bandwidth and ensure protocol-level deadlock freedom for different message classes. In this paper, we observe that a multiple-network design is also attractive from a power perspective and can be leveraged to achieve energy proportionality by effective power gating. Unlike a single-network design, a multiple-network design is more amenable to power gating, as its subnetworks (subnets) can be power gated without compromising the connectivity of the network. To exploit this opportunity, we propose the Catnap architecture which consists of synergistic subnet selection and power-gating policies. Catnap maximizes the number of consecutive idle cycles in a router, while avoiding performance loss due to overloading a subnet. We evaluate a 256-core processor with a concentrated mesh topology using synthetic traffic and 35 applications. We show that the average network power of a power-gating optimized multiple-network design with four subnets could be 44% lower than a bandwidth equivalent single-network design for an average performance cost of about 5%.

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Catnap:能量成比例的多重片上网络

在多个处理器实现中使用了多个网络来扩展带宽并确保不同消息类的协议级死锁自由。在本文中，我们观察到从功率角度来看，多网络设计也很有吸引力，并且可以通过有效的功率门控来实现能量比例。与单网络设计不同，多网络设计更适合于电源门控，因为它的子网(子网)可以在不影响网络连接的情况下进行电源门控。为了利用这一机会，我们提出了由协同子网选择和功率门控制策略组成的Catnap架构。Catnap可以最大限度地提高路由器连续空闲周期的数量，同时避免子网过载导致的性能损失。我们使用合成流量和35个应用程序评估了具有集中网格拓扑的256核处理器。我们表明，具有四个子网的功率门控优化的多网络设计的平均网络功率可以比带宽等效的单网络设计低44%，平均性能成本约为5%。

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 40th Annual International Symposium on Computer Architecture

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