Online Algorithms via Minimax and Posterior Matching

FOCS 2026 |

Competitive analysis is central to the study of online algorithms, but upper bounds are often highly problem-specific. We develop a more unifying methodology via the minimax viewpoint. Guided by Yao’s principle, we reduce worst-case competitive analysis to Bayesian online design under an arbitrary correlated prior over arrival sequences. For such a prior, let Xem> be the hindsight-optimal fractional solution for the realized instance, and let X^{(t)}=mathbb E[X^mid mathcal F_t]X^{(t)}=mathbb E[X^mid mathcal F_t] be its posterior process. Our guiding rule is emph{posterior matching}: at each time t, choose the feasible online action that tracks the current posterior X(t) as closely as the online constraints permit.

We show that this single principle yields optimal or near-optimal guarantees for several classical online fractional problems, including set cover, load balancing, matching and more general resource-allocation problems, recovering or improving state-of-the-art bounds in these settings with norm/concave objectives. Via known rounding reductions, it also yields randomized integral guarantees for weighted paging, MTS on star metrics, and ski-rental. At a technical level, our analysis reduces competitive guarantees to key probabilistic inequalities for the vector martingales generated by the posterior of the offline optimum. The resulting framework gives a reusable route from Bayesian online design under arbitrary correlated priors to information-theoretic worst-case competitive guarantees.