A Direct $\tilde{O}(1/\epsilon)$ Iteration Parallel Algorithm for Optimal Transport
Abstract
Optimal transportation, or computing the Wasserstein or ``earth mover's'' distance between two distributions, is a fundamental primitive which arises in many learning and statistical settings. We give an algorithm which solves this problem to additive with parallel depth, and work. Barring a breakthrough on a long-standing algorithmic open problem, this is optimal for first-order methods. Blanchet et. al. '18, Quanrud '19 obtained similar runtimes through reductions to positive linear programming and matrix scaling. However, these reduction-based algorithms use complicated subroutines which may be deemed impractical due to requiring solvers for second-order iterations (matrix scaling) or non-parallelizability (positive LP). The fastest practical algorithms run in time (Dvurechensky et. al. '18, Lin et. al. '19). We bridge this gap by providing a parallel, first-order, iteration algorithm without worse dependence on dimension, and provide preliminary experimental evidence that our algorithm may enjoy improved practical performance. We obtain this runtime via a primal-dual extragradient method, motivated by recent theoretical improvements to maximum flow (Sherman '17).
Cite
@article{arxiv.1906.00618,
title = {A Direct $\tilde{O}(1/\epsilon)$ Iteration Parallel Algorithm for Optimal Transport},
author = {Arun Jambulapati and Aaron Sidford and Kevin Tian},
journal= {arXiv preprint arXiv:1906.00618},
year = {2019}
}
Comments
23 pages, 2 figures