Achieving constant regret for dynamic matching via state-independent policies

We study a centralized discrete-time dynamic two-way matching model with finitely many agent types. Agents arrive stochastically over time and join their type-dedicated queues waiting to be matched. We focus on state-independent greedy policies that achieve constant regret at all times by making matching decisions based solely on agent availability across types, rather than requiring complete queue-length information. Such policies are particularly appealing for life-saving applications such as kidney exchange, as they require less information and provide more transparency compared to state-dependent policies. First, for acyclic matching networks, we analyze a deterministic priority policy proposed by Kerimov et al. [2023] that follows a static priority order over matches. We derive the first explicit regret bound in terms of the general position gap (GPG) parameter $\epsilon$, which measures the distance of the fluid relaxation from degeneracy. Second, for general two-way matching networks, we design a randomized state-independent greedy policy that achieves constant regret with optimal scaling $O(\epsilon^{-1})$, matching the existing lower bound established by Kerimov et al. [2024].