具有并行化的RSA加速的变体

IF 0.6 Q4 COMPUTER SCIENCE, THEORY & METHODS International Journal of Parallel Emergent and Distributed Systems Pub Date : 2021-11-23 DOI:10.1080/17445760.2021.2024535
Jun-jie Liu, Kang-Too Tsang, Y. Deng
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引用次数: 0

摘要

标准RSA依赖于多个大数模幂运算,并且需要更长的密钥长度以获得更好的保护。这对加密和解密造成了巨大的时间损失。在本研究中,我们分析并开发了一种改进的并行算法(PMKRSA),该算法基于将明文分成多个块并使用多个密钥对加密块的思想。我们的新方案中的算法对于并行化实现是如此自然,以至于我们还研究了它在GPU环境中的并行化。下面,概述了我们的新方案的结构,并用数学方法证明了它的正确性。然后,随着算法在CPU和CPU+GPU平台上的实现和优化,我们表明我们的算法大大缩短了计算时间,并且它比标准RSA具有安全优势,因为它不容易受到常见攻击。最后,通过仿真验证了该算法对大文件加密的可行性。结果表明,在1 MB、10 MB、25 MB、50 MB、100 MB的文件大小集合上,CPU版本的平均加解密时间分别为0.2476和9.4476 s, CPU+GPU版本的平均加解密时间分别为0.0009和0.0618 s。
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A variant RSA acceleration with parallelisation
The standard RSA relies on multiple big-number modular exponentiation operations and a longer key-length is required for better protection. This imposes a hefty time penalty for encryption and decryption. In this study, we analysed and developed an improved parallel algorithm (PMKRSA) based on the idea of splitting the plaintext into multiple chunks and encrypt the chunks using multiple key-pairs. The algorithm in our new scheme is so natural for parallelised implementation that we also investigated its parallelisation in a GPU environment. In the following, the structure of our new scheme is outlined and its correctness is proved mathematically. Then, with the algorithm implemented and optimised on both CPU and CPU+GPU platforms, we showed that our algorithm shortens the computational time considerably, and it has a security advantage over the standard RSA as it is invulnerable to the common attacks. Finally, we also proved the feasibility of using our algorithm to encrypt large files through simulation. The results show that over the set of file size: 1 MB, 10 MB, 25 MB, 50 MB, 100 MB, the average encryption and decryption time of the CPU version is 0.2476 and 9.4476 s, and for the CPU+GPU version, it is 0.0009 and 0.0618 s, respectively.
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来源期刊
CiteScore
2.30
自引率
0.00%
发文量
27
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