针对恶意对手优化的诚实多数MPC -打破每秒10亿个门的障碍

Toshinori Araki, A. Barak, Jun Furukawa, Tamar Lichter, Yehuda Lindell, Ariel Nof, Kazuma Ohara, Adi Watzman, Or Weinstein
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引用次数: 116

摘要

安全多方计算使一组各方能够安全地对他们的私有输入进行联合计算,而不透露除输出外的任何内容。在过去的几年中,安全计算协议的效率有了跳跃式的提高。然而,当考虑到存在恶意对手(可能任意偏离协议规范)的情况下的安全性时,我们离实现高效率还很遥远。在本文中,我们考虑了三方和诚实多数的具体情况。我们提供了提高乘法三元组切割选择协议效率的一般技术,并利用它们显著改进了Furukawa等人最近发表的协议(ePrint 2016/944)。我们将其协议的带宽从每个与门10位降低到每个与门7位,并展示了如何改进其协议中一些计算昂贵的部分。最值得注意的是,我们设计了缓存高效的洗牌技术来实现切割和选择,而不需要随机排列大数组(由于持续的缓存丢失,这是非常缓慢的)。我们提供了我们技术的组合分析,限制对手的作弊概率。我们的实现在一个由三台20核机器组成的集群上以10Gbps的网络实现了大约每秒11.5亿个AND门的速率。因此,我们可以安全地每秒计算212,000个AES加密(这比此设置的先前工作快了数百倍)。我们的结果表明,针对恶意对手的高吞吐量安全计算是可能的。
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Optimized Honest-Majority MPC for Malicious Adversaries — Breaking the 1 Billion-Gate Per Second Barrier
Secure multiparty computation enables a set of parties to securely carry out a joint computation of their private inputs without revealing anything but the output. In the past few years, the efficiency of secure computation protocols has increased in leaps and bounds. However, when considering the case of security in the presence of malicious adversaries (who may arbitrarily deviate from the protocol specification), we are still very far from achieving high efficiency. In this paper, we consider the specific case of three parties and an honest majority. We provide general techniques for improving efficiency of cut-and-choose protocols on multiplication triples and utilize them to significantly improve the recently published protocol of Furukawa et al. (ePrint 2016/944). We reduce the bandwidth of their protocol down from 10 bits per AND gate to 7 bits per AND gate, and show how to improve some computationally expensive parts of their protocol. Most notably, we design cache-efficient shuffling techniques for implementing cut-and-choose without randomly permuting large arrays (which is very slow due to continual cache misses). We provide a combinatorial analysis of our techniques, bounding the cheating probability of the adversary. Our implementation achieves a rate of approximately 1.15 billion AND gates per second on a cluster of three 20-core machines with a 10Gbps network. Thus, we can securely compute 212,000 AES encryptions per second (which is hundreds of times faster than previous work for this setting). Our results demonstrate that high-throughput secure computation for malicious adversaries is possible.
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