The implementation of polynomial multiplication for lattice-based cryptography: A survey

IF 3.8 2区 计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS
Chenkai Zeng , Debiao He , Qi Feng , Cong Peng , Min Luo
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引用次数: 0

Abstract

The advent of quantum computing threatens the security of traditional public-key cryptography. Algorithms for quantum computing have the ability to solve the large prime factorization and the discrete logarithm problem in polynomial time. To deal with the threat, post-quantum cryptography (PQC) primitives and protocols were proposed. Lattice-based cryptography (LBC) is the promising post-quantum cryptography, both in traditional and emerging security scenarios such as public-key encryption, homomorphic encryption and oblivious transfer. Theoretically, the algebraic structure of the lattice provides a secure fundamental for LBC. In contrast, the implementation should consider the balance of time, space, and resources for realization on various programmable platforms. In the implementation of lattice-based cryptography, polynomial multiplication is the primary operation accounting for about 30% of the execution. To improve the performance of LBC schemes, various efficient algorithms have been proposed over decades. This work focuses on approaches to accelerate polynomial multiplication used in LBC schemes. First, we review and compare three polynomial multiplication algorithms, Number Theory Transform (NTT), Karatsuba algorithm and Toom–Cook algorithm. Then we present a comprehensive survey of implementation on programmable platforms such as Graphics Processing Unit (GPU) and Field-Programmable Gate Array (FPGA). At last, we summarize the future trend of implementing polynomial multiplication and provide recommendations.

基于网格的密码学多项式乘法的实现:调查
量子计算的出现威胁着传统公钥密码学的安全性。量子计算的算法有能力在多项式时间内解决大素数因式分解和离散对数问题。为了应对这一威胁,人们提出了后量子密码学(PQC)基元和协议。基于晶格的密码学(LBC)是一种前景广阔的后量子密码学,可用于公钥加密、同态加密和遗忘传输等传统和新兴安全场景。从理论上讲,晶格的代数结构为 LBC 提供了安全的基础。相比之下,实现时应考虑时间、空间和资源的平衡,以便在各种可编程平台上实现。在基于网格的加密技术的实现过程中,多项式乘法是主要的操作,约占执行量的 30%。为了提高 LBC 方案的性能,几十年来人们提出了各种高效算法。这项工作的重点是加速 LBC 方案中使用的多项式乘法的方法。首先,我们回顾并比较了三种多项式乘法算法:数论变换(NTT)、Karatsuba 算法和 Toom-Cook 算法。然后,我们全面介绍了在图形处理器(GPU)和现场可编程门阵列(FPGA)等可编程平台上的实施情况。最后,我们总结了实现多项式乘法的未来趋势并提出了建议。
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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来源期刊
Journal of Information Security and Applications
Journal of Information Security and Applications Computer Science-Computer Networks and Communications
CiteScore
10.90
自引率
5.40%
发文量
206
审稿时长
56 days
期刊介绍: Journal of Information Security and Applications (JISA) focuses on the original research and practice-driven applications with relevance to information security and applications. JISA provides a common linkage between a vibrant scientific and research community and industry professionals by offering a clear view on modern problems and challenges in information security, as well as identifying promising scientific and "best-practice" solutions. JISA issues offer a balance between original research work and innovative industrial approaches by internationally renowned information security experts and researchers.
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