Phastlane: a rapid transit optical routing network

Proceedings. International Symposium on Computer Architecture Pub Date : 2009-06-15 DOI:10.1145/1555754.1555809

Mark J. Cianchetti, Joseph C. Kerekes, D. Albonesi

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引用次数: 186

Abstract

Tens and eventually hundreds of processing cores are projected to be integrated onto future microprocessors, making the global interconnect a key component to achieving scalable chip performance within a given power envelope. While CMOS-compatible nanophotonics has emerged as a leading candidate for replacing global wires beyond the 22nm timeframe, on-chip optical interconnect architectures proposed thus far are either limited in scalability or are dependent on comparatively slow electrical control networks. In this paper, we present Phastlane, a hybrid electrical/optical routing network for future large scale, cache coherent multicore microprocessors. The heart of the Phastlane network is a low-latency optical crossbar that uses simple predecoded source routing to transmit cache-line-sized packets several hops in a single clock cycle under contentionless conditions. When contention exists, the router makes use of electrical buffers and, if necessary, a high speed drop signaling network. Overall, Phastlane achieve 2X better network performance than a state-of-the-art electrical baseline while consuming 80% less network power.

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相位网:一种快速传输的光路由网络

未来的微处理器预计将集成数十甚至数百个处理核心，使全球互连成为在给定功率范围内实现可扩展芯片性能的关键组件。虽然兼容cmos的纳米光子学已经成为取代22nm时间框架之外的全球电线的主要候选，但迄今为止提出的片上光学互连架构要么在可扩展性方面受到限制，要么依赖于相对较慢的电气控制网络。在本文中，我们提出了phaslane，一种用于未来大规模高速缓存相干多核微处理器的混合电/光路由网络。phaslane网络的核心是一个低延迟的光交叉棒，它使用简单的前置源路由在一个时钟周期内传输缓存行大小的数据包，在无争议的条件下传输几跳。当存在争用时，路由器使用电缓冲器，如果有必要，还使用高速下降信令网络。总体而言，phaslane的网络性能比最先进的电气基准提高了2倍，同时消耗的网络功率减少了80%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings. International Symposium on Computer Architecture

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