Chronus+: Minimizing Switch Buffer Size during Network Updates in Timed SDNs

2020 IEEE 40th International Conference on Distributed Computing Systems (ICDCS) Pub Date : 2020-11-01 DOI:10.1109/ICDCS47774.2020.00042

Xin He, Jiaqi Zheng, Haipeng Dai, Yuhu Sun, Wanchun Dou, Guihai Chen

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Abstract

Although the logically-centralized perspective is offered in Software-Defined Networks (SDNs), the data plane is still distributed in nature. Update commands sent by the centralized controller are executed asynchronously and independently in each switch. The timed SDNs enable synchronous and coordinate update operations as each update command can be triggered by a pre-defined time point. Prior work on timed update mainly focuses on how to produce a congestion-free update sequence, whereas finding a congestion-free timed update sequence may be too long to be applied in practice, even worse, such an update order may not exist. In this paper, we propose Chronus+, a timed update system that utilizes switch buffer to shorten the update time while minimizing the switch buffer size during updates. We formulate the Minimum Switch Buffer Size Problem (MSBSP) as an optimization program and show its hardness. A set of efficient algorithms is proposed to determine a timed update sequence in polynomial time. Extensive evaluations in Mininet and large-scale simulations show that Chronus+ can reduce the update time by at least 17% and the switch buffer by at least 27% compared with state-of-the-art approaches.

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Chronus+:在定时sdn中，在网络更新期间最小化交换机缓冲区大小

尽管在软件定义网络(sdn)中提供了逻辑上集中的透视图，但数据平面在本质上仍然是分布式的。集中控制器发送的更新命令在每台交换机上异步独立执行。定时sdn允许同步和协调更新操作，因为每个更新命令可以由预定义的时间点触发。之前关于定时更新的工作主要集中在如何产生一个无拥塞的更新序列，而找到一个无拥塞的定时更新序列可能太长而无法在实践中应用，甚至可能不存在这样的更新顺序。在本文中，我们提出了Chronus+，一个定时更新系统，利用开关缓冲区来缩短更新时间，同时最小化更新过程中的开关缓冲区大小。我们将最小开关缓冲区大小问题(MSBSP)表述为一个优化程序，并证明了它的硬度。提出了一套有效的算法来确定多项式时间内的定时更新序列。Mininet的广泛评估和大规模模拟表明，与最先进的方法相比，Chronus+可以将更新时间减少至少17%，开关缓冲区减少至少27%。

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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2020 IEEE 40th International Conference on Distributed Computing Systems (ICDCS)

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