SSProve: Coq中模块化密码证明的基本框架

IF 1.5 2区 计算机科学 Q3 COMPUTER SCIENCE, SOFTWARE ENGINEERING ACM Transactions on Programming Languages and Systems Pub Date : 2023-07-20 DOI:https://dl.acm.org/doi/10.1145/3594735
Philipp G. Haselwarter, Exequiel Rivas, Antoine Van Muylder, Théo Winterhalter, Carmine Abate, Nikolaj Sidorenco, Cătălin Hriţcu, Kenji Maillard, Bas Spitters
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引用次数: 0

摘要

状态分离证明(SSP)是一种最新的方法,通过使用代数定律来利用组合协议的模块化结构,以模块化的方式构建基于游戏的密码证明。虽然很有希望,但这种方法以前并没有完全形式化,并且只有很少的工具支持。我们通过引入SSProve来解决这个问题,SSProve是第一个用于机器检查的状态分离证明的通用验证框架。SSProve结合了SSP中提出的关于组合协议的高级模块化证明,以及用于形式化低级细节的概率关系程序逻辑,它们一起能够在Coq证明助手中构造机器检查的加密证明。此外,SSProve本身在Coq中是完全形式化的,包括SSP的代数定律、程序逻辑的健全性以及这两种验证风格之间的联系。为了说明SSProve,我们使用它来机械化ElGamal和基于伪随机函数的加密的简单安全证明。我们还通过进行两个更实质性的案例研究来验证SSProve方法:首先,我们机械化了密钥封装机制-数据加密机制(kemm - dem)公钥加密方案的SSP安全证明,这导致在原始论文证明中发现了一个错误,该错误已被修复。其次,我们使用SSProve对sigma协议零知识构造的安全性进行了形式化证明,并从sigma协议构造了一个承诺方案,与CryptHOL中的类似发展进行了比较。我们实例化了σ -协议的安全性证明,给出了Schnorr σ -协议的具体安全界。
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SSProve: A Foundational Framework for Modular Cryptographic Proofs in Coq

State-separating proofs (SSP) is a recent methodology for structuring game-based cryptographic proofs in a modular way, by using algebraic laws to exploit the modular structure of composed protocols. While promising, this methodology was previously not fully formalized and came with little tool support. We address this by introducing SSProve, the first general verification framework for machine-checked state-separating proofs. SSProve combines high-level modular proofs about composed protocols, as proposed in SSP, with a probabilistic relational program logic for formalizing the lower-level details, which together enable constructing machine-checked cryptographic proofs in the Coq proof assistant. Moreover, SSProve is itself fully formalized in Coq, including the algebraic laws of SSP, the soundness of the program logic, and the connection between these two verification styles.

To illustrate SSProve, we use it to mechanize the simple security proofs of ElGamal and pseudo-random-function–based encryption. We also validate the SSProve approach by conducting two more substantial case studies: First, we mechanize an SSP security proof of the key encapsulation mechanism–data encryption mechanism (KEM-DEM) public key encryption scheme, which led to the discovery of an error in the original paper proof that has since been fixed. Second, we use SSProve to formally prove security of the sigma-protocol zero-knowledge construction, and we moreover construct a commitment scheme from a sigma-protocol to compare with a similar development in CryptHOL. We instantiate the security proof for sigma-protocols to give concrete security bounds for Schnorr’s sigma-protocol.

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来源期刊
ACM Transactions on Programming Languages and Systems
ACM Transactions on Programming Languages and Systems 工程技术-计算机:软件工程
CiteScore
3.10
自引率
7.70%
发文量
28
审稿时长
>12 weeks
期刊介绍: ACM Transactions on Programming Languages and Systems (TOPLAS) is the premier journal for reporting recent research advances in the areas of programming languages, and systems to assist the task of programming. Papers can be either theoretical or experimental in style, but in either case, they must contain innovative and novel content that advances the state of the art of programming languages and systems. We also invite strictly experimental papers that compare existing approaches, as well as tutorial and survey papers. The scope of TOPLAS includes, but is not limited to, the following subjects: language design for sequential and parallel programming programming language implementation programming language semantics compilers and interpreters runtime systems for program execution storage allocation and garbage collection languages and methods for writing program specifications languages and methods for secure and reliable programs testing and verification of programs
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