Reusing Combinatorial Structure: Faster Iterative Projections over Submodular Base Polytopes

Published in NeurIPS, 2021

Recommended citation: Jai Moondra, Hassan Mortagy, Swati Gupta. (2021). "Reusing Combinatorial Structure: Faster Iterative Projections over Submodular Base Polytopes." In proceedings of the 34th conference on Neural Information Processing Systems (NeurIPS). https://proceedings.neurips.cc/paper/2021/file/d58f36f7679f85784d8b010ff248f898-Paper.pdf

Abstract: Optimization algorithms such as projected Newton’s method, FISTA, mirror descent and its variants enjoy near-optimal regret bounds and convergence rates, but suffer from a computational bottleneck of computing “projections’’ in potentially each iteration (e.g., $O(T^{1/2})$ regret of online mirror descent). On the other hand, conditional gradient variants solve a linear optimization in each iteration, but result in suboptimal rates (e.g., $O(T^{3/4})$ regret of online Frank-Wolfe). Motivated by this trade-off in runtime v/s convergence rates, we consider iterative projections of close-by points over widely-prevalent submodular base polytopes $B(f)$. We develop a toolkit to speed up the computation of projections using both discrete and continuous perspectives. We subsequently adapt the away-step Frank-Wolfe algorithm to use this information and enable early termination. For the special case of cardinality based submodular polytopes, we improve the runtime of computing certain Bregman projections by a factor of $\Omega(n/\log(n))$. Our theoretical results show orders of magnitude reduction in runtime in preliminary computational experiments.

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