Almost-Surely Terminating Asynchronous Byzantine Agreement Revisited

Laasya Bangalore, Ashish Choudhury, A. Patra
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引用次数: 10

Abstract

The problem of Byzantine Agreement (BA) is of interest to both distributed computing and cryptography community. Following well-known results from the distributed computing literature, BA problem in the asynchronous network setting encounters inevitable non-termination issues. The impasse is overcome via randomization that allows construction of BA protocols in two flavours of termination guarantee - with overwhelming probability and with probability one. The latter type termed as almost-surely terminating BAs are the focus of this paper. An eluding problem in the domain of almost-surely terminating BAs is achieving a constant expected running time. Our work makes progress in this direction. In a setting with n parties and an adversary with unbounded computing power controlling at most t parties in Byzantine fashion, we present two asynchronous almost-surely terminating BA protocols: With the optimal resilience of t < n3 , our first protocol runs for expected O(n) time. The existing protocols in the same setting either runs for expected O(n2) time (Abraham et al, PODC 2008) or requires exponential computing power from the honest parties (Wang, CoRR 2015). In terms of communication complexity, our construction outperforms all the known constructions that offer almost-surely terminating feature. With the resilience of t < n/3+ε for any ε > 0, our second protocol runs for expected O( 1 ε ) time. The expected running time of our protocol turns constant when ε is a constant fraction. The known constructions with constant expected running time either require ε to be at least 1 (Feldman-Micali, STOC 1988), implying t < n/4, or calls for exponential computing power from the honest parties (Wang, CoRR 2015). We follow the traditional route of building BA via common coin protocol that in turn reduces to asynchronous verifiable secretsharing (AVSS). Our constructions are built on a variant of AVSS that is termed as shunning. A shunning AVSS fails to offer the properties of AVSS when the corrupt parties strike, but allows the honest parties to locally detect and shun a set of corrupt parties for any future communication. Our shunning AVSS with t < n/3 and t < n 3+ε guarantee Ω(n) and respectively Ω(εt 2) conflicts to be revealed when failure occurs. Turning this shunning AVSS to a common coin protocol constitutes another contribution of our paper.
几乎可以肯定终止异步拜占庭协议
拜占庭协议(Byzantine Agreement, BA)问题是分布式计算界和密码学界都感兴趣的问题。根据分布式计算文献中众所周知的结果,异步网络设置中的BA问题遇到不可避免的非终止问题。这个僵局可以通过随机化来克服,随机化允许构建两种终止保证风格的BA协议——具有压倒性的概率和概率一。后一种类型被称为几乎肯定终止ba是本文的重点。在几乎肯定会终止ba的领域中,一个难以回避的问题是实现恒定的预期运行时间。我们的工作在这个方向上取得了进展。在一个有n个参与方和一个以拜占庭方式控制最多t个参与方的具有无限计算能力的对手的设置中,我们提出了两个几乎肯定会终止的异步BA协议:具有t < n3的最优弹性,我们的第一个协议运行预期的O(n)时间。相同设置下的现有协议要么运行预期的O(n2)时间(Abraham等人,PODC 2008),要么需要诚实各方的指数级计算能力(Wang, CoRR 2015)。就通信复杂性而言,我们的结构优于所有提供几乎肯定终止功能的已知结构。对于任何ε > 0,具有t < n/3+ε的弹性,我们的第二个协议运行预期的O(1 ε)时间。当ε为常数分数时,协议的期望运行时间变为常数。已知的具有恒定预期运行时间的结构要么要求ε至少为1 (Feldman-Micali, STOC 1988),意味着t < n/4,要么要求诚实各方的指数计算能力(Wang, CoRR 2015)。我们遵循通过公共硬币协议构建BA的传统路线,从而减少到异步可验证秘密共享(AVSS)。我们的结构是建立在AVSS的变体,被称为回避。当腐败方罢工时,回避的AVSS无法提供AVSS的属性,但允许诚实方在本地发现并回避一组腐败方,以便进行任何未来的通信。我们在t < n/3和t < n 3+ε的回避AVSS中分别保证了在发生故障时能够揭示Ω(n)和Ω(εt 2)冲突。将这种回避AVSS转变为共同的硬币协议是我们论文的另一个贡献。
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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