On the Capacity of Single-Server Multi-Message Private Information Retrieval with Side Information

TL;DR

This paper characterizes the maximum download rate for multi-message private information retrieval with side information in a single-server setting, extending previous single-message results to multiple messages and proposing new coding schemes.

Contribution

It extends PIR-SI capacity results to multiple demanded messages, providing new capacity formulas and coding schemes for different scenarios of side information and demand sizes.

Findings

For D > M, capacity is D/(K-M) with GRS code scheme.

For D ≤ M, capacity can be higher, with a new lower bound established.

The schemes enable efficient private retrieval leveraging side information.

Abstract

We study Private Information Retrieval with Side Information (PIR-SI) in the single-server multi-message setting. In this setting, a user wants to download $D$ messages from a database of $K\geq D$ messages, stored on a single server, without revealing any information about the identities of the demanded messages to the server. The goal of the user is to achieve information-theoretic privacy by leveraging the side information about the database. The side information consists of a random subset of $M$ messages in the database which could have been obtained in advance from other users or from previous interactions with the server. The identities of the messages forming the side information are initially unknown to the server. Our goal is to characterize the capacity of this setting, i.e., the maximum achievable download rate. In our previous work, we have established the PIR-SI capacity for the special case in which the user wants a single message, i.e., $D=1$ and showed that the capacity can be achieved through the Partition and Code (PC) scheme. In this paper, we focus on the case when the user wants multiple messages, i.e., $D>1$. Our first result is that if the user wants more messages than what they have as side information, i.e., $D>M$, then the capacity is $\frac{D}{K-M}$, and it can be achieved using a scheme based on the Generalized Reed-Solomon (GRS) codes. In this case, the user must learn all the messages in the database in order to obtain the desired messages. Our second result shows that this may not be necessary when $D\leq M$, and the capacity in this case can be higher. We present a lower bound on the capacity based on an achievability scheme which we call Generalized Partition and Code (GPC).