基于带误差环学习的多方同态加密

C. Mouchet, J. Troncoso-Pastoriza, Jean-Philippe Bossuat, J. Hubaux
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引用次数: 65

摘要

摘要我们提出并评估了一种基于多方同态加密(MHE)的具有不诚实多数的半诚实模型中的安全多方计算(MPC)解决方案。为了支持我们的解决方案,我们引入了Brakerski Fan-Vercauteren同态密码系统的多方版本,并在开源库中实现了它。基于MHE的MPC解决方案有几个优点:它们的文字记录是公开的,它们的o~ine相位是紧凑的,并且它们的电路评估程序是非交互的。通过利用这些特性,MPC任务的通信复杂性从参与方数量的二次型降低到线性,从而在潜在的数千个参与方之间以及从传统的对等环境到云外包和智能合约技术的各种计算范式中实现安全计算。基于MHE的方法也可以优于最先进的解决方案,即使对少数各方来说也是如此。我们在三个电路中证明了这一点:应用于私有信息检索的私有输入选择,应用于私有集交集的分量向量乘法,以及Beaver乘法三元组生成。对于第一个电路,在八千方(每个32KB)中私下选择一个输入,每方只需要1.31MB的通信,并在61.7秒内完成。对于第二个有八方的电路,我们的方法比目前的方法快8.6倍,需要的通信量减少39.3倍。对于第三电路和十方,我们的方法每秒产生20倍多的三元组,而每三元组所需的通信量是基于遗忘传输的方法的136倍。我们在Lattigo库中实现了我们的方案,并在github.com/ldsec/Lattigo上开源了代码。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Multiparty Homomorphic Encryption from Ring-Learning-with-Errors
Abstract We propose and evaluate a secure-multiparty-computation (MPC) solution in the semi-honest model with dishonest majority that is based on multiparty homomorphic encryption (MHE). To support our solution, we introduce a multiparty version of the Brakerski-Fan-Vercauteren homomorphic cryptosystem and implement it in an open-source library. MHE-based MPC solutions have several advantages: Their transcript is public, their o~ine phase is compact, and their circuit-evaluation procedure is noninteractive. By exploiting these properties, the communication complexity of MPC tasks is reduced from quadratic to linear in the number of parties, thus enabling secure computation among potentially thousands of parties and in a broad variety of computing paradigms, from the traditional peer-to-peer setting to cloud-outsourcing and smart-contract technologies. MHE-based approaches can also outperform the state-of-the-art solutions, even for a small number of parties. We demonstrate this for three circuits: private input selection with application to private-information retrieval, component-wise vector multiplication with application to private-set intersection, and Beaver multiplication triples generation. For the first circuit, privately selecting one input among eight thousand parties’ (of 32 KB each) requires only 1.31 MB of communication per party and completes in 61.7 seconds. For the second circuit with eight parties, our approach is 8.6 times faster and requires 39.3 times less communication than the current methods. For the third circuit and ten parties, our approach generates 20 times more triples per second while requiring 136 times less communication per-triple than an approach based on oblivious transfer. We implemented our scheme in the Lattigo library and open-sourced the code at github.com/ldsec/lattigo.
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