How to prove any NP statement jointly? Efficient Distributed-prover Zero-Knowledge Protocols

Pankaj Dayama, A. Patra, Protik Paul, Nitin Singh, Dhinakaran Vinayagamurthy
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引用次数: 3

Abstract

Abstract Traditional zero-knowledge protocols have been studied and optimized for the setting where a single prover holds the complete witness and tries to convince a verifier about a predicate on the witness, without revealing any additional information to the verifier. In this work, we study the notion of distributed-prover zero knowledge (DPZK) for arbitrary predicates where the witness is shared among multiple mutually distrusting provers and they want to convince a verifier that their shares together satisfy the predicate. We make the following contributions to the notion of distributed proof generation: (i) we propose a new MPC-style security definition to capture the adversarial settings possible for different collusion models between the provers and the verifier, (ii) we discuss new efficiency parameters for distributed proof generation such as the number of rounds of interaction and the amount of communication among the provers, and (iii) we propose a compiler that realizes distributed proof generation from the zero-knowledge protocols in the Interactive Oracle Proofs (IOP) paradigm. Our compiler can be used to obtain DPZK from arbitrary IOP protocols, but the concrete efficiency overheads are substantial in general. To this end, we contribute (iv) a new zero-knowledge IOP Graphene which can be compiled into an efficient DPZK protocol. The (D + 1)-DPZK protocol D-Graphene, with D provers and one verifier, admits O(N1/c) proof size with a communication complexity of O(D2 ·(N1−2/c+Ns)), where N is the number of gates in the arithmetic circuit representing the predicate and Ns is the number of wires that depends on inputs from two or more parties. Significantly, only the distributed proof generation in D-Graphene requires interaction among the provers. D-Graphene compares favourably with the DPZK protocols obtained from the state-of-art zero-knowledge protocols, even those not modelled as IOPs.
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如何联合证明任何NP命题?高效的分布式证明者零知识协议
传统的零知识协议已经被研究和优化,用于单个证明者持有完整的见证,并试图说服验证者关于见证上的谓词,而不向验证者透露任何额外的信息。在这项工作中,我们研究了任意谓词的分布式证明者零知识(DPZK)的概念,其中见证人在多个相互不信任的证明者之间共享,并且他们想要说服验证者他们的共享共同满足谓词。我们对分布式证明生成的概念做出了以下贡献:(i)我们提出了一个新的mpc风格的安全定义,以捕获证明者和验证者之间不同串合模型可能的对抗性设置,(ii)我们讨论了分布式证明生成的新效率参数,如交互的轮数和证明者之间的通信量,以及(iii)我们提出了一个编译器,该编译器在交互式Oracle证明(IOP)范式中实现了零知识协议的分布式证明生成。我们的编译器可用于从任意IOP协议中获得DPZK,但通常具体的效率开销是很大的。为此,我们贡献了(iv)一个新的零知识IOP石墨烯,它可以编译成一个有效的DPZK协议。(D + 1)-DPZK协议D-石墨烯,具有D个证明者和一个验证者,承认O(N1/c)证明大小,通信复杂度为O(D2·(N1−2/c+Ns)),其中N是表示谓词的算术电路中的门数,N是依赖于两个或更多方输入的线数。值得注意的是,只有d -石墨烯中的分布式证明生成需要证明者之间的相互作用。d -石墨烯优于从最先进的零知识协议中获得的DPZK协议,即使是那些没有建模为IOPs的协议。
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