基于双向信道的片上网络的细粒度带宽自适应

R. Hesse, J. Nicholls, Natalie D. Enright Jerger
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引用次数: 53

摘要

片上网络(NoC)是多核架构中高效、可扩展的通信基板。目前,noc提供的带宽对于其典型使用情况来说是过度供应的。在实际的多核应用程序中,平均只有不到5%的通道被利用。大带宽资源可以在通信需求高峰期保持较低的网络延迟。通过更窄的信道增加平均信道利用率可以提高NoC在面积和功率方面的效率,然而,在当前的NoC架构中,这会降低整体系统性能。基于对实际工作负载动态行为的深入分析,我们设计了一种新的NoC架构,以适应不断变化的应用程序需求。我们的架构使用细粒度的带宽自适应双向通道来提高通道利用率,而不会对网络延迟产生负面影响。在周期精确的全系统模拟器上运行PARSEC基准测试,我们发现,与基线网络相比,细粒度带宽自适应可以节省高达75%的信道资源,同时实现92%的整体系统性能,在我们的网络设计中配置了基线中使用的50%的信道资源,没有性能牺牲。
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Fine-Grained Bandwidth Adaptivity in Networks-on-Chip Using Bidirectional Channels
Networks-on-Chip (NoC) serve as efficient and scalable communication substrates for many-core architectures. Currently, the bandwidth provided in NoCs is over provisioned for their typical usage case. In real-world multi-core applications, less than 5% of channels are utilized on average. Large bandwidth resources serve to keep network latency low during periods of peak communication demands. Increasing the average channel utilization through narrower channels could improve the efficiency of NoCs in terms of area and power, however, in current NoC architectures this degrades overall system performance. Based on thorough analysis of the dynamic behaviour of real workloads, we design a novel NoC architecture that adapts to changing application demands. Our architecture uses fine-grained bandwidth-adaptive bidirectional channels to improve channel utilization without negatively affecting network latency. Running PARSEC benchmarks on a cycle-accurate full-system simulator, we show that fine-grained bandwidth adaptivity can save up to 75% of channel resources while achieving 92% of overall system performance compared to the baseline network, no performance is sacrificed in our network design configured with 50% of the channel resources used in the baseline.
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