利用gpu的整数和浮点运算能力实现更快的全同态加密

Guang Fan, Fangyu Zheng, Lipeng Wan, Lili Gao, Yuan Zhao, Jiankuo Dong, Yixuan Song, Yuewu Wang, Jingqiang Lin
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引用次数: 0

摘要

完全同态加密(FHE)允许在不知道明文消息的情况下对加密数据进行计算,目前已成为学术界和工业界关注的焦点。然而,性能问题阻碍了其大规模应用,凸显了高性能FHE实现的迫切需求。注意到gpu在加密加速领域的巨大潜力,本文全面研究了如何将gpu中可用的计算资源转换为FHE工作马,并基于两种算术单元(即INT32和FP64单元)实现了一套基于三种数据精度(即INT32, INT64和FP64)的低级和中级FHE原语。本文在各路线图的基础上进行了综合评价和比较。我们的基本函数实现比同一平台上的实现性能高1.7到16.7倍。以CKKS FHE方案为例,即使考虑到平台的差异,我们的同态乘法实现也比最先进的基于gpu的实现实现提高了3.2倍的速度。本文的详细评价和比较将为后续基于gpu的FHE实现中选择合适的底层运算单元和重要的原语优化提供重要的参考。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Towards Faster Fully Homomorphic Encryption Implementation with Integer and Floating-point Computing Power of GPUs
Fully Homomorphic Encryption (FHE) allows computations on encrypted data without knowledge of the plaintext message and currently has been the focus of both academia and industry. However, the performance issue hinders its large-scale application, highlighting the urgent requirements of high-performance FHE implementations.With noticing the tremendous potential of GPUs in the field of cryptographic acceleration, this paper comprehensively investigates how to convert the available computing resources residing in GPUs into FHE workhorses, and implement a full set of low-level and middle-level FHE primitives based on two arithmetic units (i.e., INT32 and FP64 units) with three types of data precision (i.e., INT32, INT64 and FP64). This paper gives a comprehensive evaluation and comparison based on each road-map. Our implementations of fundamental functions outperform the implementations on the same platform by 1.7× to 16.7×. Taking CKKS FHE schemes as a case study, our implementation of homomorphic multiplication achieves 3.2× speedup over the state-of-the-art GPU-based implementation, even considering the difference of platforms. The detailed evaluation and comparison of this paper would offer a vital reference for the follow-up work to choose appropriate underlying arithmetic units and important primitive optimizations in GPU-based FHE implementations.
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