Go to DBLP homepageApproximation Algorithms for Minimizing Congestion in Demand-Aware Networks
Abstract: Emerging reconfigurable optical communication technologies allow to enhance datacenter topologies with demand-aware links optimized towards traffic patterns. This paper studies the algorithmic problem of jointly optimizing topology and routing in such demand-aware networks to minimize congestion, along two dimensions: (1) splittable or unsplittable flows, and (2) whether routing is segregated, i.e., whether routes can or cannot combine both demand-aware and demand-oblivious (static) links.For splittable and segregated routing, we show that the problem is generally 2-approximable, but APX-hard even for uniform demands induced by a bipartite demand graph. For unsplittable and segregated routing, we establish upper and lower bounds of O (log m/ log log m) and Ω (log m/ log log m), respectively, for polynomial-time approximation algorithms, where m is the number of static links. We further reveal that under un-/splittable and non-segregated routing, even for demands of a single source (resp., d estina tion), the problem cannot be approximated better than $\Omega \left({\frac{{{c_{\max }}}}{{{c_{\min }}}}}\right)$ unless P=NP, where cmax (resp., cmin) denotes the maximum (resp., minimum) capacity. It remains NP-hard for uniform capacities, but is tractable for a single commodity and uniform capacities.Our trace-driven simulations show a significant reduction in network congestion compared to existing solutions.
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