Solving Matrix Games with Near-Optimal Matvec Complexity

Abstract

We study the problem of computing an ε-approximate Nash equilibrium of a two-player, bilinear game with a bounded payoff matrix A ∈ Rm × n, when the players' strategies are constrained to lie in simple sets. We provide algorithms which solve this problem in O(ε-2/3) matrix-vector multiplies (matvecs) in two well-studied cases: 1-1 (or zero-sum) games, where the players' strategies are both in the probability simplex, and 2-1 games (encompassing hard-margin SVMs), where the players' strategies are in the unit Euclidean ball and probability simplex respectively. These results improve upon the previous state-of-the-art complexities of O(ε-8/9) for 1-1 and O(ε-7/9) for 2-1 due to [KOS '25]. In both settings our results are nearly-optimal as they match lower bounds of [KS '25] up to polylogarithmic factors.