Forward-backward Contention Resolution Schemes for Fair Rationing
Abstract
We use contention resolution schemes (CRS) to derive algorithms for the fair rationing of a single resource when agents have stochastic demands. We aim to provide ex-ante guarantees on the level of service provided to each agent, who may measure service in different ways (Type-I, II, or III), calling for CRS under different feasibility constraints (rank-1 matroid or knapsack). We are particularly interested in two-order CRS where the agents are equally likely to arrive in a known forward order or its reverse, which is motivated by online rationing at food banks. In particular, we derive a two-order CRS for rank-1 matroids with guarantee 1/(1+e-1/2)≈ 0.622, which we prove is tight. This improves upon the 1/2 guarantee that is best-possible under a single order (Alaei, SIAM J. Comput. 2014), while achieving separation with the 1-1/e≈ 0.632 guarantee that is possible for random-order CRS (Lee and Singla, ESA 2018). Because CRS guarantees imply prophet inequalities, this also beats the two-order prophet inequality with ratio (5-1)/2≈ 0.618 from (Arsenis, SODA 2021), which was tight for single-threshold policies. Rank-1 matroids suffice to provide guarantees under Type-II or III service, but Type-I service requires knapsack. Accordingly, we derive a two-order CRS for knapsack with guarantee 1/3, improving upon the 1/(3+e-2)≈ 0.319 guarantee that is best-possible under a single order (Jiang et al., SODA 2022). To our knowledge, 1/3 provides the best-known guarantee for knapsack CRS even in the offline setting. Finally, we provide an upper bound of 1/(2+e-1)≈ 0.422 for two-order knapsack CRS, strictly smaller than the upper bound of (1-e-2)/2≈0.432 for random-order knapsack CRS.
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