大规模并行SIMD系统的网络设计与性能

[Proceedings 1992] The Fourth Symposium on the Frontiers of Massively Parallel Computation Pub Date : 1992-10-19 DOI:10.1109/FMPC.1992.234889

S. Darbha, E. Davis

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引用次数: 0

摘要

结果表明，最近邻通信网络可以与对数直径多级网络互补，以处理不同的通信模式。这在数据移动模式不统一时特别有用。对设计的网络进行了两种情况下的评价:一种是具有多个处理元素通信的密集情况，另一种是稀疏情况。对于32b数据，采用多级互连网络，阵列部分和的计算算法提高了2.7倍。在稀疏随机情况下，通信32b所需的周期数为4000(10%的节点通信)。因此，可以得出结论，像多级omega网络这样的网络对于SIMD(单指令多数据)大规模并行机非常有用。如果机器要用于需要长距离和非均匀路由模式的应用，则尤其如此。

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Network design and performance for a massively parallel SIMD system

It is shown that a nearest neighbor communication network can be complimented with a log-diameter multistage network to handle different communications patterns. This is especially useful when the pattern of data movement is not uniform. The designed network is evaluated for two cases: a dense case with many processing elements communicating and a sparse case. For 32-b data, the algorithm for computing partial sums of an array improves by 2.7 times with the multistage interconnection network. In a sparse random case, the number of cycles taken to communicate 32 b is 4000 (with 10% of the nodes communicating). Thus, it is concluded that a network like a multistage omega network is very useful for SIMD (single-instruction multiple-data) massively parallel machines. This is especially true if the machine is to be used for applications where long distance and nonuniform routing patterns are needed.<>

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[Proceedings 1992] The Fourth Symposium on the Frontiers of Massively Parallel Computation

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