Efficient Recovery of a Shared Secret via Cooperation: Applications to SDMM and PIR

This work considers the problem of privately outsourcing the computation of a matrix product over a finite field \(\mathbb{F}_q\) to \(N\) helper servers. These servers are considered to be honest but curious, i.e., they behave according to the protocol but will try to deduce information about the u...

Full description

Saved in:
Bibliographic Details
Published in:arXiv.org 2022-01
Main Authors: Li, Jie, Makkonen, Okko, Hollanti, Camilla, Gnilke, Oliver
Format: Article
Language:English
Subjects:
Computing costs
Cooperation
Downloading
Fields (mathematics)
Information retrieval
Matrices (mathematics)
Multiplication
Outsourcing
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This work considers the problem of privately outsourcing the computation of a matrix product over a finite field \(\mathbb{F}_q\) to \(N\) helper servers. These servers are considered to be honest but curious, i.e., they behave according to the protocol but will try to deduce information about the user's data. Furthermore, any set of up to \(X\) servers is allowed to share their data. Previous works considered this collusion a hindrance and the download cost of the schemes increases with growing \(X\). We propose to utilize such linkage between servers to the user's advantage by allowing servers to cooperate in the computational task. This leads to a significant gain in the download cost for the proposed schemes. The gain naturally comes at the cost of increased communication load between the servers. Hence, the proposed cooperative schemes can be understood as outsourcing both computational cost and communication cost. Both information--theoretically secure and computationally secure schemes are considered, showing that allowing information leakage that is computationally hard to utilize will lead to further gains. The proposed server cooperation is then exemplified for specific secure distributed matrix multiplication (SDMM) schemes and linear private information retrieval (PIR). Similar ideas naturally apply to many other use cases as well, but not necessarily always with lowered costs.
ISSN:2331-8422
DOI:10.48550/arxiv.2106.05785