Universally composable security with local adversaries

Abstract

The traditional approach to formalizing ideal-model based definitions of security for multi-party protocols models adversaries (both real and ideal) as centralized entities that control all parties that deviate from the protocol. While this centralized-adversary modeling suffices for capturing basic security properties such as secrecy of local inputs and correctness of outputs against coordinated attacks, it turns out to be inadequate for capturing security properties that involve restricting the sharing of information between separate adversarial entities. Indeed, to capture collusion-freeness and game-theoretic solution concepts, Alwen et al. [Crypto, 2012] propose a new ideal-model based definitional framework that involves a de-centralized adversary. We propose an alternative framework to that of Alwen et al. We then observe that our framework allows capturing not only collusion-freeness and game-theoretic solution concepts, but also several other properties that involve the restriction of information flow among adversarial entities. These include some natural flavors of anonymity, deniability, timing separation, and information-confinement. We also demonstrate the inability of existing formalisms to capture these properties. We then prove strong composition properties for the proposed framework, and use these properties to demonstrate the security, within the new framework, of two very different protocols for securely evaluating any function of the parties' inputs. © 2012 Springer-Verlag.