The Honey Badger of BFT Protocols

Proceedings of the 2016 ACM SIGSAC Conference on Computer and Communications Security Pub Date : 2016-10-24 DOI:10.1145/2976749.2978399

Andrew K. Miller, Yuchong Xia, Kyle Croman, E. Shi, D. Song

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引用次数: 673

Abstract

The surprising success of cryptocurrencies has led to a surge of interest in deploying large scale, highly robust, Byzantine fault tolerant (BFT) protocols for mission-critical applications, such as financial transactions. Although the conventional wisdom is to build atop a (weakly) synchronous protocol such as PBFT (or a variation thereof), such protocols rely critically on network timing assumptions, and only guarantee liveness when the network behaves as expected. We argue these protocols are ill-suited for this deployment scenario. We present an alternative, HoneyBadgerBFT, the first practical asynchronous BFT protocol, which guarantees liveness without making any timing assumptions. We base our solution on a novel atomic broadcast protocol that achieves optimal asymptotic efficiency. We present an implementation and experimental results to show our system can achieve throughput of tens of thousands of transactions per second, and scales to over a hundred nodes on a wide area network. We even conduct BFT experiments over Tor, without needing to tune any parameters. Unlike the alternatives, HoneyBadgerBFT simply does not care about the underlying network.

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BFT协议中的蜜獾

加密货币的惊人成功导致人们对为关键任务应用(如金融交易)部署大规模、高度健壮的拜占庭容错(BFT)协议的兴趣激增。尽管传统观点是建立在(弱)同步协议(如PBFT)(或其变体)之上，但此类协议严重依赖于网络时序假设，并且仅在网络按预期运行时保证活动。我们认为这些协议不适合这种部署场景。我们提出了一个替代方案，HoneyBadgerBFT，这是第一个实用的异步BFT协议，它保证了活动性，而不需要做任何时间假设。我们的解决方案基于一种新的原子广播协议，该协议实现了最优的渐近效率。我们给出了一个实现和实验结果，表明我们的系统可以实现每秒数万个事务的吞吐量，并且可以在广域网上扩展到100多个节点。我们甚至在Tor上进行BFT实验，而不需要调整任何参数。与其他替代方案不同，HoneyBadgerBFT根本不关心底层网络。

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 2016 ACM SIGSAC Conference on Computer and Communications Security

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