English

Optimal Single-Pass Streaming Lower Bounds for Approximating CSPs

Computational Complexity 2026-04-13 v1 Data Structures and Algorithms

Abstract

For an arbitrary family of predicates F{0,1}[q]k\mathcal{F} \subseteq \{0,1\}^{[q]^k} and any ϵ>0\epsilon > 0, we prove a single-pass, linear-space streaming lower bound against the gap promise problem of distinguishing instances of Max-CSP(F)({\mathcal{F}}) with at most β+ϵ\beta+\epsilon fraction of satisfiable constraints from instances of with at least γϵ\gamma-\epsilon fraction of satisfiable constraints, whenever Max-CSP(F)({\mathcal{F}}) admits a (γ,β)(\gamma,\beta)-integrality gap instance for the basic LP. This subsumes the linear-space lower bound of Chou, Golovnev, Sudan, Velingker, and Velusamy (STOC 2022), which applies only to a special subclass of CSPs with linear-algebraic structure. (Their result itself generalizes work of Kapralov and Krachun (STOC 2019) for Max-CUT.) Our approach identifies the right ``analytic'' analogues of previously-used linear-algebraic conditions; this yields substantial simplifications while capturing a much larger class of problems. Our lower bound is essentially optimal for single-pass streaming, since: (1) All CSPs admit (1ϵ)(1-\epsilon)-approximations in quasilinear space, and (2) sublinear-space streaming algorithms can simulate the LP (on bounded-degree instances), giving approximation algorithms when integrality gap instances do not exist. The starting point for our lower bound is a reduction from a "distributional implicit hidden partition'' problem defined by Fei, Minzer, and Wang (STOC 2026) in the context of multi-pass streaming. Our result is an analogue of theirs in the single-pass setting, where we obtain a much stronger (and tight) space lower bound.

Keywords

Cite

@article{arxiv.2604.08731,
  title  = {Optimal Single-Pass Streaming Lower Bounds for Approximating CSPs},
  author = {Noah G. Singer and Madhur Tulsiani and Santhoshini Velusamy},
  journal= {arXiv preprint arXiv:2604.08731},
  year   = {2026}
}

Comments

52 pages

R2 v1 2026-07-01T12:02:02.907Z