Dynamic optical switching for latency sensitive applications

2015 ACM/IEEE Symposium on Architectures for Networking and Communications Systems (ANCS) Pub Date : 2015-05-07 DOI:10.1109/ANCS.2015.7110122

Henrique Rodrigues, Richard D. Strong, A. S. Akyurek, T. Simunic

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引用次数: 7

Abstract

Dynamic optical interconnects using fast Optical Circuit Switches (OCS) are emerging as a scalable and energy efficient alternative to increasing network demands. Initial concerns regarding slow switching speeds of OCSs were recently overcome, with prototypes enabling circuit setup in a few microseconds. This can potentially broaden the classes of traffic patterns that can be carried efficiently by an alloptical interconnect. However, application performance on such newer interconnects has not been fully understood yet. In this paper, we explore the the gap between advances in faster OCS hardware and the potential success of such newer technologies in terms of application performance and cluster energy efficiency. We evaluate the performance of latencysensitive distributed applications running on a fast OCS environment, analyzing its impact to overall server and network energy efficiency. We also discuss scheduling inefficiencies of current fast OCSs and evaluate ideas to solve them. We find that while some distributed applications suffer minimal performance penalty when running on fast OCSs, more flexible schedulers, like the ones outlined in this paper, improve application performance and OCS efficiency by up to 2.44 times compared to the strategies in the literature. Dynamic optical interconnects using fast Optical Circuit Switches (OCS) are emerging as a scalable and energy efficient alternative to increasing network demands. Initial concerns regarding slow switching speeds of OCSs were recently overcome, with prototypes enabling circuit setup in a few microseconds. This can potentially broaden the classes of traffic patterns that can be carried efficiently by an all-optical interconnect. However, application performance on such newer interconnects has not been fully understood yet. In this paper, we explore the the gap between advances in faster OCS hardware and the potential success of such newer technologies in terms of application performance and cluster energy efficiency. We evaluate the performance of latency-sensitive distributed applications running on a fast OCS environment, analyzing its impact to overall server and network energy efficiency. We also discuss scheduling inefficiencies of current fast OCSs and evaluate ideas to solve them. We find that while some distributed applications suffer minimal performance penalty when running on fast OCSs, more exible schedulers, like the ones outlined in this paper, improve application performance and OCS efficiency by up to 2.44 times compared to the strategies in the literature.

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动态光交换对延迟敏感的应用

使用快速光电路交换机(OCS)的动态光互连正在成为一种可扩展和节能的替代方案，以满足日益增长的网络需求。最初对ocs开关速度慢的担忧最近被克服了，原型电路可以在几微秒内完成设置。这可以潜在地扩大可由同位互连有效承载的流量模式的类别。然而，应用程序在这种较新的互连上的性能还没有完全了解。在本文中，我们探讨了更快OCS硬件的进步与这些新技术在应用性能和集群能效方面的潜在成功之间的差距。我们评估了运行在快速OCS环境上的延迟敏感分布式应用程序的性能，分析了其对整体服务器和网络能源效率的影响。我们还讨论了当前快速OCSs调度效率低下的问题，并评估了解决这些问题的思路。我们发现，虽然一些分布式应用程序在快速OCS上运行时遭受的性能损失最小，但与文献中的策略相比，更灵活的调度器(如本文中概述的调度器)可将应用程序性能和OCS效率提高2.44倍。使用快速光电路交换机(OCS)的动态光互连正在成为一种可扩展和节能的替代方案，以满足日益增长的网络需求。最初对ocs开关速度慢的担忧最近被克服了，原型电路可以在几微秒内完成设置。这可以潜在地扩大可由全光互连有效承载的流量模式的类别。然而，应用程序在这种较新的互连上的性能还没有完全了解。在本文中，我们探讨了更快OCS硬件的进步与这些新技术在应用性能和集群能效方面的潜在成功之间的差距。我们评估了运行在快速OCS环境上的延迟敏感分布式应用程序的性能，分析了其对整体服务器和网络能源效率的影响。我们还讨论了当前快速OCSs调度效率低下的问题，并评估了解决这些问题的思路。我们发现，虽然一些分布式应用程序在快速OCS上运行时遭受的性能损失最小，但与文献中的策略相比，更灵活的调度器(如本文中概述的调度器)可将应用程序性能和OCS效率提高2.44倍。

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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来源期刊

2015 ACM/IEEE Symposium on Architectures for Networking and Communications Systems (ANCS)

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