Improving the Resilience of Fast Failover Routing: TREE (Tree Routing to Extend Edge disjoint paths)

Proceedings of the Symposium on Architectures for Networking and Communications Systems Pub Date : 2021-11-28 DOI:10.1145/3493425.3502747

O. Schweiger, Klaus-Tycho Foerster, S. Schmid

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引用次数: 5

Abstract

Today's communication networks have stringent availability requirements and hence need to rapidly restore connectivity after failures. Modern networks thus implement various forms of fast reroute mechanisms in the data plane, to bridge the gap to slow global control plane convergence. State-of-the-art fast reroute commonly relies on disjoint route structures, to offer multiple independent paths to the destination. We propose to leverage the network's path diversity to extend edge disjoint path mechanisms to tree routing, in order to improve the performance of fast rerouting. We present two such tree-mechanisms in detail and show that they boost resilience by up to 12% and 25% respectively on real-world, synthetic, and data center topologies. Whereas the first method retains the stretch of edge disjoint path mechanisms, our second method increases it depending on the use case, just below 8% for networks from Topology Zoo on average, but by up to 56% for random graphs in the Erdős-Rényi model.

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提高快速故障转移路由的弹性:TREE(扩展边缘不相交路径的树路由)

当今的通信网络具有严格的可用性要求，因此需要在故障后快速恢复连接。因此，现代网络在数据平面上实现了各种形式的快速路由机制，以弥补缓慢的全局控制平面收敛的差距。最先进的快速重路由通常依赖于不相交的路由结构，以提供多条独立的路径到达目的地。我们建议利用网络的路径多样性将边缘不相交路径机制扩展到树路由，以提高快速重路由的性能。我们详细介绍了两种这样的树机制，并表明它们分别在实际拓扑、合成拓扑和数据中心拓扑上提高了12%和25%的弹性。虽然第一种方法保留了边缘不相交路径机制的拉伸，但我们的第二种方法根据用例增加了它，对于拓扑动物园的网络平均略低于8%，但对于Erdős-Rényi模型中的随机图高达56%。

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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