International Association
for Cryptologic Research

Private Simultaneous Messages (PSM) and Conditional Disclosure of Secrets (CDS) are two fundamental primitives in information-theoretic cryptography. In a PSM protocol, each party sends a single message to a referee, who can then compute a function $f$ of their private inputs but learns nothing else. A CDS protocol follows the same model as PSM, but the goal is to disclose a secret shared among all parties to the referee if and only if the function $f$ evaluates to $1$. Minimizing the communication complexity of these primitives is a central question in this area. Since the best known constructions for general functions require high communication complexity, recent studies have attempted to obtain more efficient constructions by focusing on symmetric functions, whose outputs are invariant under permutations of inputs. However, the extent to which exploiting symmetry can improve efficiency has remained unclear. In this work, we show upper and lower bounds that relate the optimal communication complexities of PSM and CDS for symmetric functions to those for general functions. When the number of parties is larger than the input domain size, our upper bound for PSM improves the best known communication complexity for symmetric functions. Furthermore, our upper bound for CDS demonstrates for the first time that symmetry can be exploited to reduce communication in CDS protocols. In contrast, when the number of parties is constant, our lower bounds show that focusing on symmetric functions yields only a constant-factor improvement. We also derive an analogous implication for PSM protocols under a plausible conjecture. In addition, our new constructions for symmetric functions lead to improvements over the state-of-the-art results in related models such as ad hoc PSM and secret sharing.