Shortcutting Fast Failover Routes in the Data Plane

Proceedings of the Symposium on Architectures for Networking and Communications Systems Pub Date : 2021-11-29 DOI:10.1145/3493425.3502751

Apoorv Shukla, Klaus-Tycho Foerster

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引用次数: 10

Abstract

In networks, availability is of paramount importance. As link failures are disruptive, modern networks in turn provide Fast ReRoute (FRR) mechanisms to rapidly restore connectivity. However, existing FRR approaches heavily impact performance until the slower convergence protocols kick in. The fast failover routes commonly involve unnecessary loops and detours, disturbing other traffic while causing costly packet loss. In this paper, we make a case for augmenting FRR mechanisms to avoid such inefficiencies. We introduce ShortCut that routes the packets in a loop free fashion, avoiding costly detours and decreasing link load. ShortCut achieves this by leveraging data plane programmability: when a loop is locally observed, it can be removed by short-cutting the respective route parts. As such, ShortCut is topology-independent and agnostic to the type of FRR currently deployed. Our first experimental simulations show that ShortCut can outperform control plane convergence mechanisms; moreover avoiding loops and keeping packet loss minimal opposed to existing FRR mechanisms.

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数据平面快速故障切换路由

在网络中，可用性是最重要的。由于链路故障具有破坏性，现代网络反过来提供快速路由(FRR)机制来快速恢复连接。然而，现有的FRR方法严重影响性能，直到较慢的收敛协议开始发挥作用。快速故障转移路由通常涉及不必要的环路和绕路，在干扰其他流量的同时造成代价高昂的数据包丢失。在本文中，我们提出了增加FRR机制以避免这种低效率的案例。我们引入了以无环路方式路由数据包的捷径，避免了昂贵的弯路并减少了链路负载。ShortCut通过利用数据平面可编程性实现了这一点:当局部观察到一个循环时，可以通过缩短各自的路由部分来删除它。因此，ShortCut与拓扑无关，与当前部署的FRR类型无关。我们的第一个实验仿真表明，ShortCut优于控制平面收敛机制;此外，与现有的FRR机制相比，避免了环路并保持了最小的数据包丢失。

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 of the Symposium on Architectures for Networking and Communications Systems

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