Your search keyword '"Lakhotia, Kartik"' showing total 2 results

1. PolarStar: Expanding the Scalability Horizon of Diameter-3 Networks

Author

Lakhotia, Kartik, Monroe, Laura, Isham, Kelly, Besta, Maciej, Blach, Nils, Hoefler, Torsten, and Petrini, Fabrizio

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Distributed, Parallel, and Cluster Computing, Mathematics - Combinatorics, B.4.3, B.4.4, G.2.2

Abstract

We present PolarStar, a novel family of diameter-3 network topologies derived from the star product of low-diameter factor graphs. PolarStar gives the largest known diameter-3 network topologies for almost all radixes, thus providing the best known scalable diameter-$3$ network. Compared to current state-of-the-art diameter-$3$ networks, PolarStar achieves $1.3\times$ geometric mean increase in scale over Bundlefly, $1.9\times$ over Dragonfly, and $6.7\times$ over {3-D} HyperX. PolarStar has many other desirable properties, including a modular layout, large bisection, high resilience to link failures and a large number of feasible configurations for every radix. We give a detailed evaluation with simulations of synthetic and real-world traffic patterns and show that PolarStar exhibits comparable or better performance than current diameter-3 networks., Comment: 13 pages, published in SPAA 2024

Published

2023

2. PolarFly: A Cost-Effective and Flexible Low-Diameter Topology

Author

Lakhotia, Kartik, Besta, Maciej, Monroe, Laura, Isham, Kelly, Iff, Patrick, Hoefler, Torsten, and Petrini, Fabrizio

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Distributed, Parallel, and Cluster Computing, B.4.3, B.4.4

Abstract

In this paper we present PolarFly, a diameter-2 network topology based on the Erdos-Renyi family of polarity graphs from finite geometry. This is a highly scalable low-diameter topology that asymptotically reaches the Moore bound on the number of nodes for a given network degree and diameter PolarFly achieves high Moore bound efficiency even for the moderate radixes commonly seen in current and near-future routers, reaching more than 96% of the theoretical peak. It also offers more feasible router degrees than the state-of-the-art solutions, greatly adding to the selection of scalable diameter-2 networks. PolarFly enjoys many other topological properties highly relevant in practice, such as a modular design and expandability that allow incremental growth in network size without rewiring the whole network. Our evaluation shows that PolarFly outperforms competitive networks in terms of scalability, cost and performance for various traffic patterns., Comment: In Proceedings of International Conference for High Performance Computing, Networking, Storage, and Analysis (SC) 2022

Published

2022