Paper 2017/568

Towards Doubly Efficient Private Information Retrieval

Ran Canetti and Justin Holmgren and Silas Richelson

Abstract

Private Information Retrieval (PIR) allows a client to obtain data from a public database without disclosing the locations accessed. Traditionally, the stress is on preserving sublinear work for the client, while the server's work is taken to inevitably be at least linear in the database size. Beimel, Ishai and Malkin (JoC 2004) show PIR schemes where, following a linear-work preprocessing stage, the server's work per query is sublinear in the database size. However, that work only addresses the case of multiple non-colluding servers; the existence of single-server PIR with sublinear server work remained unaddressed. We consider single-server PIR schemes where, following a preprocessing stage in which the server obtains an encoded version of the database and the client obtains a short key, the per-query work of both server and client is polylogarithmic in the database size. We call such schemes {\em doubly efficient}. Concentrating on the case where the client's key is secret, we show: - A scheme, based on one-way functions, that works for a bounded number of queries, and where the server storage is linear in the number of queries plus the database size. - A scheme for an unbounded number of queries, whose security follows from a new hardness assumption that is related to the hardness of solving a system of noisy linear equations. We also show the insufficiency of a natural approach for obtaining doubly efficient PIR in the setting where the preprocessing is public.