高基数交叉开关启用近距离通信

2008 SC - International Conference for High Performance Computing, Networking, Storage and Analysis Pub Date : 2008-11-15 DOI:10.1109/SC.2008.5219754

H. Eberle, P. García, J. Flich, J. Duato, R. Drost, N. Gura, D. Hopkins, W. Olesinski

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引用次数: 12

摘要

我们描述了一种实现高基数交叉开关的新方法。我们的工作是通过一种新的芯片互连技术，称为接近通信(PxC)，提供无与伦比的芯片IO密度。首先，我们展示了如何将横杆架构拓扑映射到支持pxc的多芯片模块(MCM)上。然后，我们描述了基于PxC MCM的小型开关的第一个原型实现。最后，我们对288端口和1728端口的两种大型交换机配置进行了性能分析，对比了1级pxc交换机和使用传统技术的多级交换机。我们的仿真结果表明(a)大型一级交换机的仲裁延迟可能相当大，(b)多级交换机在非均匀流量下极易受到饱和的影响，这个问题在更高的基数下变得更糟(相比之下，一级交换机不受此问题的影响)。

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High-radix crossbar switches enabled by Proximity Communication

We describe a novel way to implement high-radix crossbar switches. Our work is enabled by a new chip interconnect technology called proximity communication (PxC) that offers unparalleled chip IO density. First, we show how a crossbar architecture is topologically mapped onto a PxC-enabled multi-chip module (MCM). Then, we describe a first prototype implementation of a small-scale switch based on a PxC MCM. Finally, we present a performance analysis of two large-scale switch configurations with 288 ports and 1,728 ports, respectively, contrasting a 1-stage PxC-enabled switch and a multi-stage switch using conventional technology. Our simulation results show that (a) arbitration delays in a large 1-stage switch can be considerable, (b) multi-stage switches are extremely susceptible to saturation under non-uniform traffic, a problem that becomes worse for higher radices (1-stage switches, in contrast, are not affected by this problem).

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来源期刊

2008 SC - International Conference for High Performance Computing, Networking, Storage and Analysis

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