Cerberus

Proceedings of the ACM on Measurement and Analysis of Computing Systems Pub Date : 2021-12-14 DOI:10.1145/3491050

Chen Griner, Johannes Zerwas, Andreas Blenk, M. Ghobadi, S. Schmid, C. Avin

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引用次数: 8

Abstract

The bandwidth and latency requirements of modern datacenter applications have led researchers to propose various topology designs using static, dynamic demand-oblivious (rotor), and/or dynamic demand-aware switches. However, given the diverse nature of datacenter traffic, there is little consensus about how these designs would fare against each other. In this work, we analyze the throughput of existing topology designs under different traffic patterns and study their unique advantages and potential costs in terms of bandwidth and latency ''tax''. To overcome the identified inefficiencies, we propose Cerberus, a unified, two-layer leaf-spine optical datacenter design with three topology types. Cerberus systematically matches different traffic patterns with their most suitable topology type: e.g., latency-sensitive flows are transmitted via a static topology, all-to-all traffic via a rotor topology, and elephant flows via a demand-aware topology. We show analytically and in simulations that Cerberus can improve throughput significantly compared to alternative approaches and operate datacenters at higher loads while being throughput-proportional.

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冥府守门狗

现代数据中心应用的带宽和延迟要求使得研究人员提出了使用静态、动态需求无关(转子)和/或动态需求感知开关的各种拓扑设计。然而，考虑到数据中心流量的多样性，对于这些设计如何相互竞争，几乎没有达成共识。在这项工作中，我们分析了现有拓扑设计在不同流量模式下的吞吐量，并研究了它们在带宽和延迟“税”方面的独特优势和潜在成本。为了克服所发现的低效率，我们提出了Cerberus，一种统一的双层叶脊光学数据中心设计，具有三种拓扑类型。Cerberus系统地将不同的流量模式与最合适的拓扑类型相匹配:例如，延迟敏感的流量通过静态拓扑传输，所有对所有的流量通过转子拓扑传输，大象流通过需求感知拓扑传输。我们通过分析和模拟表明，与其他方法相比，Cerberus可以显著提高吞吐量，并在吞吐量成比例的情况下在更高的负载下运行数据中心。

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

Proceedings of the ACM on Measurement and Analysis of Computing Systems

CiteScore

3.20

自引率

0.00%

发文量