TROD: Evolving From Electrical Data Center to Optical Data Center

Peirui Cao, Shizhen Zhao, Min Yee Teh, Yunzhuo Liu, Xinbing Wang
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引用次数: 6

Abstract

Despite the bandwidth scaling limit of electrical switching and the high cost of building Clos data center networks (DCNs), the adoption of optical DCNs is still limited. There are two reasons. First, existing optical DCN designs usually face tremendous deployment complexity. Second, these designs are not full-optical and the performance benefit against the non-blocking Clos DCN is not clear.After exploring the design tradeoffs of the existing optical DCN designs, we propose TROD (Threshold Routing based Optical Datacenter), a low-complexity optical DCN with superior performance than other optical DCNs. There are two novel designs in TROD that contribute to its success. First, TROD performs robust topology optimization based on the recurring traffic patterns and thus does not need to react to every traffic change, which lowers deployment and management complexity. Second, TROD introduces tVLB (threshold-based VLB), which can avoid network congestion as much as possible even under unexpected traffic bursts. We conduct simulation based on both Facebook’s real DCN traces and our synthesized highly bursty DCN traces. TROD reduces flow completion time (FCT) by at least 2× compared with the existing optical DCN designs, and by approximately 2.4-3.2× compared with expander graph DCN. Compared with the non-blocking Clos, TROD reduces the hop count of the majority packets by one, and could even outperform the non-blocking Clos with proper bandwidth over-provision at the optical layer. Note that TROD can be built with commercially available hardware and does not require host modifications.
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TROD:从电气数据中心到光学数据中心的演变
尽管存在电交换的带宽扩展限制和建设Clos数据中心网络(DCNs)的高成本,但光DCNs的采用仍然受到限制。有两个原因。首先,现有的光DCN设计通常面临巨大的部署复杂性。其次,这些设计不是全光学的,相对于非阻塞Clos DCN的性能优势尚不清楚。在研究了现有光DCN设计的设计权衡之后,我们提出了基于阈值路由的光数据中心(TROD),这是一种低复杂度的光DCN,具有优于其他光DCN的性能。在TROD中有两个新颖的设计促成了它的成功。首先,TROD基于重复出现的流量模式执行健壮的拓扑优化,因此不需要对每个流量变化做出反应,从而降低了部署和管理的复杂性。其次,TROD引入了tVLB(基于阈值的负载均衡),即使在意外的流量突发情况下,也可以尽可能地避免网络拥塞。我们基于Facebook的真实DCN轨迹和我们合成的高度突发DCN轨迹进行了模拟。与现有的光学DCN设计相比,TROD将流动完井时间(FCT)减少了至少2倍,与扩展图DCN设计相比减少了大约2.4-3.2倍。与非阻塞Clos相比,TROD将大多数数据包的跳数减少了1,并且在光层适当的带宽过剩下甚至可以优于非阻塞Clos。注意,TROD可以用商用硬件构建,不需要修改主机。
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