ILC: a calculus for composable, computational cryptography

Proceedings of the 40th ACM SIGPLAN Conference on Programming Language Design and Implementation Pub Date : 2019-06-08 DOI:10.1145/3314221.3314607

Kevin Liao, Matthew A. Hammer, Andrew K. Miller

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引用次数: 19

Abstract

The universal composability (UC) framework is the established standard for analyzing cryptographic protocols in a modular way, such that security is preserved under concurrent composition with arbitrary other protocols. However, although UC is widely used for on-paper proofs, prior attempts at systemizing it have fallen short, either by using a symbolic model (thereby ruling out computational reduction proofs), or by limiting its expressiveness. In this paper, we lay the groundwork for building a concrete, executable implementation of the UC framework. Our main contribution is a process calculus, dubbed the Interactive Lambda Calculus (ILC). ILC faithfully captures the computational model underlying UC—interactive Turing machines (ITMs)—by adapting ITMs to a subset of the π-calculus through an affine typing discipline. In other words, well-typed ILC programs are expressible as ITMs. In turn, ILC’s strong confluence property enables reasoning about cryptographic security reductions. We use ILC to develop a simplified implementation of UC called SaUCy.

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可组合的计算密码学的微积分

通用可组合性(UC)框架是以模块化的方式分析加密协议的标准，从而在与任意其他协议并发组合的情况下保持安全性。然而，尽管UC被广泛用于纸上证明，但之前试图将其系统化的尝试已经失败，要么是通过使用符号模型(从而排除计算约简证明)，要么是通过限制其表达性。在本文中，我们为构建一个具体的、可执行的UC框架实现奠定了基础。我们的主要贡献是一个过程演算，称为交互式Lambda演算(ILC)。ILC忠实地捕获了uc -交互图灵机(itm)的计算模型，通过仿射类型化使itm适应π微积分的子集。换句话说，类型良好的ILC程序可以表示为itm。反过来，ILC的强合流特性使得可以对加密安全性降低进行推理。我们使用ILC开发了一个简化的UC实现，称为SaUCy。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the 40th ACM SIGPLAN Conference on Programming Language Design and Implementation

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