Lower Bounds for PIR with Preprocessing from Blackbox Cryptography
摘要
(shortened for arXiv metadata) We study the limits of single-server private information retrieval (PIR) with preprocessing. Prior work has shown that single-server PIR with sublinear communication requires a linear number of (public-key) server operations per query [DMO00, DH24]. Recent breakthrough works, including [CHK22, ZPZS24, LMW23], circumvent these lower bounds by critically leveraging preprocessing to construct single-server PIR with sublinear query computation. Our work presents computation lower bounds for any single-server PIR with preprocessing that makes blackbox usage of {\em any} cryptography (such as random oracles and virtual blackbox obfuscation). For any client preprocessing scheme where the client stores bits about an -bit database, we prove the online amortized computation must be across queries (even if performed in a single batch query). In more detail, we prove that they must have either amortized online communication or the server must perform cryptographic operations. Our lower bounds are optimal as there exist PIRs with client preprocessing matching exactly one of the above requirements while outperforming the other. Furthermore, our lower bounds also rule out the existence of doubly efficient PIR from blackbox cryptography with sublinear query computation. Our proof framework also supports communication lower bounds for three mildly restricted classes of single-server PIR. We also prove lower bounds for symmetric private information retrieval (SPIR) with client preprocessing in the random oracle model and present a matching SPIR construction with client preprocessing using only OWFs during queries.
引用
@article{arxiv.2607.06451,
title = {Lower Bounds for PIR with Preprocessing from Blackbox Cryptography},
author = {Alexander Hoover and Giuseppe Persiano and Kevin Yeo},
journal= {arXiv preprint arXiv:2607.06451},
year = {2026}
}
备注
To appear in STOC 2026