Stitching Inter-Domain Paths over IXPs

TL;DR

This paper explores using IXPs as central points for stitching inter-domain paths to improve network performance and diversity, leveraging SDN principles and measurements from 229 IXPs worldwide.

Contribution

It introduces a novel approach of using IXPs as stitching points for inter-domain routing, supported by measurements and algorithms for scalable path embedding.

Findings

Up to 91% IPv4 address space can be served by IXP-based brokers.

Path diversity increases by up to 29 times compared to BGP.

Algorithms scale well and support diverse path requests.

Abstract

Modern Internet applications, from HD video-conferencing to health monitoring and remote control of power-plants, pose stringent demands on network latency, bandwidth and availability. An approach to support such applications and provide inter-domain guarantees, enabling new avenues for innovation, is using centralized inter-domain routing brokers. These entities centralize routing control for mission-critical traffic across domains, working in parallel to BGP. In this work, we propose using IXPs as natural points for stitching inter-domain paths under the control of inter-domain routing brokers. To evaluate the potential of this approach, we first map the global substrate of inter-IXP pathlets that IXP members could offer, based on measurements for 229 IXPs worldwide. We show that using IXPs as stitching points has two useful properties. Up to 91 % of the total IPv4 address space can be served by such inter-domain routing brokers when working in concert with just a handful of large IXPs and their associated ISP members. Second, path diversity on the inter-IXP graph increases by up to 29 times, as compared to current BGP valley-free routing. To exploit the rich path diversity, we introduce algorithms that inter-domain routing brokers can use to embed paths, subject to bandwidth and latency constraints. We show that our algorithms scale to the sizes of the measured graphs and can serve diverse simulated path request mixes. Our work highlights a novel direction for SDN innovation across domains, based on logically centralized control and programmable IXP fabrics.