Path-Based Multicast Routing for Network-on-Chip of the Neuromorphic Processor

IF 1.2 3区计算机科学 Q4 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE Journal of Computer Science and Technology Pub Date : 2023-09-30 DOI:10.1007/s11390-022-1232-8

Zi-Yang Kang, Shi-Ming Li, Shi-Ying Wang, Lian-Hua Qu, Rui Gong, Wei Shi, Wei-Xia Xu, Lei Wang

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Abstract

Network-on-Chip (NoC) is widely adopted in neuromorphic processors to support communication between neurons in spiking neural networks (SNNs). However, SNNs generate enormous spiking packets due to the one-to-many traffic pattern. The spiking packets may cause communication pressure on NoC. We propose a path-based multicast routing method to alleviate the pressure. Firstly, all destination nodes of each source node on NoC are divided into several clusters. Secondly, multicast paths in the clusters are created based on the Hamiltonian path algorithm. The proposed routing can reduce the length of path and balance the communication load of each router. Lastly, we design a lightweight microarchitecture of NoC, which involves a customized multicast packet and a routing function. We use six datasets to verify the proposed multicast routing. Compared with unicast routing, the running time of path-based multicast routing achieves 5.1x speedup, and the number of hops and the maximum transmission latency of path-based multicast routing are reduced by 68.9% and 77.4%, respectively. The maximum length of path is reduced by 68.3% and 67.2% compared with the dual-path (DP) and multi-path (MP) multicast routing, respectively. Therefore, the proposed multicast routing has improved performance in terms of average latency and throughput compared with the DP or MP multicast routing.

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基于路径的神经形态处理器片上网络组播路由

片上网络(Network-on-Chip, NoC)被广泛应用于神经形态处理器中，以支持尖峰神经网络(snn)中神经元之间的通信。然而，由于一对多的流量模式，snn会产生大量的峰值数据包。尖峰报文可能对NoC造成通信压力。为了减轻这种压力，我们提出了一种基于路径的组播路由方法。首先，将NoC上每个源节点的所有目的节点划分为多个集群。其次，基于哈密顿路径算法在集群中创建组播路径;所提出的路由可以减少路径长度，平衡各路由器的通信负荷。最后，我们设计了一个轻量级的NoC微架构，包括自定义组播数据包和路由功能。我们使用六个数据集来验证所提出的组播路由。与单播路由相比，基于路径的组播路由运行时间加快5.1倍，跳数和最大传输时延分别降低68.9%和77.4%。与双路(DP)组播路由和多路(MP)组播路由相比，最大路径长度分别减少了68.3%和67.2%。因此，与DP或MP组播路由相比，所提出的组播路由在平均延迟和吞吐量方面具有更高的性能。

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来源期刊

Journal of Computer Science and Technology 工程技术-计算机：软件工程

CiteScore

4.00

自引率

0.00%

发文量

2255

审稿时长

9.8 months

期刊介绍： Journal of Computer Science and Technology (JCST), the first English language journal in the computer field published in China, is an international forum for scientists and engineers involved in all aspects of computer science and technology to publish high quality and refereed papers. Papers reporting original research and innovative applications from all parts of the world are welcome. Papers for publication in the journal are selected through rigorous peer review, to ensure originality, timeliness, relevance, and readability. While the journal emphasizes the publication of previously unpublished materials, selected conference papers with exceptional merit that require wider exposure are, at the discretion of the editors, also published, provided they meet the journal''s peer review standards. The journal also seeks clearly written survey and review articles from experts in the field, to promote insightful understanding of the state-of-the-art and technology trends. Topics covered by Journal of Computer Science and Technology include but are not limited to: -Computer Architecture and Systems -Artificial Intelligence and Pattern Recognition -Computer Networks and Distributed Computing -Computer Graphics and Multimedia -Software Systems -Data Management and Data Mining -Theory and Algorithms -Emerging Areas