Few Batches or Little Memory, But Not Both: Simultaneous Space and Adaptivity Constraints in Stochastic Bandits

Abstract

We study stochastic multi-armed bandits under simultaneous constraints on space and adaptivity: the learner interacts with the environment in B batches and has only W bits of persistent memory. Prior work shows that each constraint alone is surprisingly mild: near-minimax regret O(KT) is achievable with O( T) bits of memory under fully adaptive interaction, and with a K-independent O( T)-type number of batches when memory is unrestricted. We show that this picture breaks down in the simultaneously constrained regime. We prove that any algorithm with a W-bit memory constraint must use at least (K/W) batches to achieve near-minimax regret O(KT), even under adaptive grids. In particular, logarithmic memory rules out O(K1-) batch complexity. Our proof is based on an information bottleneck. We show that near-minimax regret forces the learner to acquire (K) bits of information about the hidden set of good arms under a suitable hard prior, whereas an algorithm with B batches and W bits of memory allows only O(BW) bits of information. A key ingredient is a localized change-of-measure lemma that yields probability-level arm exploration guarantees, which is of independent interest. We also give an algorithm that, for any bit budget W with ( T) W O(K T), uses at most W bits of memory and O(K/W) batches while achieving regret O(KT), nearly matching our lower bound up to polylogarithmic factors.

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