Optimizing Reconfigurable Optical Datacenters: The Power of Randomization

Optimizing Reconfigurable Optical Datacenters: The Power of Randomization

Reconfigurable optical topologies are a promising new technology to improve datacenter network performance and cope with the explosive growth of traffic. In particular, these networks allow to directly and adaptively connect racks between which there is currently much traffic, hence making an optima...

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Bibliographic Details
Published in:SC23: International Conference for High Performance Computing, Networking, Storage and Analysis pp. 1 - 11
Main Authors: Bienkowski, Marcin, Fuchssteiner, David, Schmid, Stefan
Format: Conference Proceeding
Language:English
Published: ACM 11-11-2023
Subjects:
demand-aware networks
High performance computing
Network topology
online algorithms
optical datacenter networks
Optical fiber networks
Optical switches
optimization
Prediction algorithms
randomization
Schedules
Spread spectrum communication
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Summary:Reconfigurable optical topologies are a promising new technology to improve datacenter network performance and cope with the explosive growth of traffic. In particular, these networks allow to directly and adaptively connect racks between which there is currently much traffic, hence making an optimal use of the bandwidth capacity by avoiding multi-hop forwarding. This paper studies the dynamic optimization of such reconfigurable topologies, by adapting the network to the traffic in an online manner. The underlying algorithmic problem can be described as an online maximum weight b-matching problem, a generalization of maximum weight matching where each node has at most b\geq 1 incident matching edges. We make the case for a randomized approach for matching optimization. Our main contribution is a O(\log b) -competitive algorithm and we show that it is asymptotically optimal. This algorithm is hence exponentially better than the best possible deterministic online algorithm. We complement our theoretical results with extensive trace-driven simulations, based on real-world datacenter workloads.
ISSN:2167-4337
DOI:10.1145/3581784.3607057