Selective MPC: Distributed Computation of Differentially Private Key Value Statistics.

An increasingly popular method for computing aggregate statistics while preserving users' privacy is local differential privacy (LDP). Under this model, users perturb their data before sending it to an untrusted central party to be processed. Key value data is a naturally occurring data type that has not been thoroughly investigated in the local trust model. Existing LDP solutions for computing statistics over key value data suffer from the inherent accuracy limitations of each user adding their own noise. Multi-party computation (MPC) is a common alternative to LDP that removes the requirement for a trusted central party while maintaining accuracy; however, naively applying MPC to key value data results in prohibitively expensive computation costs. In this work, we present selective multi-party computation, a novel approach to distributed computation that leverages DP leakage to efficiently and accurately compute statistics over key value data. We show that our protocol satisfies pure DP and is provably secure in the combined DP/MPC model. Our empirical evaluation demonstrates that we can compute statistics over 10,000 keys in 20 seconds and can scale up to 30 servers while obtaining results for a single key in under a second.