A variable-pipeline on-chip router optimized to traffic pattern

Network on Chip Architectures Pub Date : 2010-12-04 DOI:10.1145/1921249.1921263

Yuto Hirata, Hiroki Matsutani, M. Koibuchi, H. Amano

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引用次数: 9

Abstract

Network-on-Chip (NoC) can be evaluated from various aspects, such as communication latency, throughput, and power consumption. The preference of these requirements depends on each application. An on-chip variable-pipeline (VP) router that can adapt to these requirements by dynamically reconfiguring its data path structure is proposed in this paper. In response to the communication pattern, it can change the pipeline structure, supply voltage, and operational frequency using the dynamic voltage and frequency scaling (DVFS). As the traffic load becomes high, the VP router uses a look-ahead two-cycle pipeline structure for exploiting the maximum frequency, while it behaves as a one-cycle router when a low latency is preferred. A three-cycle pipelined structure with an adaptive routing enables to dynamically avoid hotspots. Instead of a simple pipeline-stage unification which causes rapid decrease of the operating frequency, by speculatively executing multiple pipeline stages in parallel, the operating frequency gracefully decreases as the number of the pipeline stages increases. Simulation results show that the one-cycle mode offers the shortest communication latency, while the two-cycle mode achieves the highest throughput for SPLASH-2 benchmarks.

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可变管道片上路由器优化流量模式

片上网络(NoC)可以从多个方面进行评估，例如通信延迟、吞吐量和功耗。这些需求的优先级取决于每个应用程序。本文提出了一种片上可变管道路由器，通过动态地重新配置其数据路径结构来适应这些需求。针对通信模式，它可以利用动态电压频率缩放(DVFS)改变管道结构、电源电压和工作频率。当流量负载变大时，VP路由器使用前瞻性的两周期管道结构来利用最大频率，而当优先考虑低延迟时，它使用单周期路由器。采用三周期流水线结构和自适应路由，可以动态避开热点。通过推测并行执行多个管道级，而不是简单的管道级统一导致操作频率迅速降低，操作频率随着管道级数量的增加而优雅地降低。仿真结果表明，在SPLASH-2基准测试中，单周期模式提供了最短的通信延迟，而双周期模式实现了最高的吞吐量。

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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Network on Chip Architectures

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