Haofan Yang, J. Tripathi, Natalie D. Enright Jerger, Dan Gibson
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引用次数: 17
摘要
网络拓扑结构在芯片设计中起着至关重要的作用,它在很大程度上决定了网络成本(功耗和面积),并对多核架构中的通信性能产生重大影响。传统的拓扑结构(如2D网格)存在一些缺点,包括随着网络规模的扩大,直径会变大,中心节点的负载平衡也会变差。我们提出了一种设计片上网络随机拓扑的方法。随机拓扑在网络直径方面提供了更好的可伸缩性,并提供了固有的负载平衡。作为随机片上拓扑的概念验证,我们探索了一组新颖的网络- do decs -并说明了它们如何通过随机低基数路由器连接减小网络直径。虽然4 × 4网格的直径为6,但我们的dodec的直径为4,成本较低。通过引入随机性,十二编网络表现出更均匀的消息延迟。通过使用低基数路由器,dodec网络简化了路由器的微架构,与网状路由器相比,可以减少20%的面积和22%的功耗,同时为PARSEC提供相同的整体应用性能。
Network topology plays a vital role in chip design, it largely determines network cost (power and area) and significantly impacts communication performance in many-core architectures. Conventional topologies such as a 2D mesh have drawbacks including high diameter as the network scales and poor load balancing for the center nodes. We propose a methodology to design random topologies for on-chip networks. Random topologies provide better scalability in terms of network diameter and provide inherent load balancing. As a proof-of-concept for random on-chip topologies, we explore a novel set of networks -- do decs -- and illustrate how they reduce network diameter with randomized low-radix router connections. While a 4 × 4 mesh has a diameter of 6, our dodec has a diameter of 4 with lower cost. By introducing randomness, dodec networks exhibit more uniform message latency. By using low-radix routers, dodec networks simplify the router micro architecture and attain 20% area and 22% power reduction compared to mesh routers while delivering the same overall application performance for PARSEC.
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