A High-Efficiency Modular Multiplication Digital Signal Processing for Lattice-Based Post-Quantum Cryptography-Reference-Cited by-同舟云学术

A High-Efficiency Modular Multiplication Digital Signal Processing for Lattice-Based Post-Quantum Cryptography

Published:2023-09-25 Issue:4 Volume:7 Page:46
ISSN:2410-387X
Container-title:Cryptography
language:en
Short-container-title:Cryptography

Author:

Nguyen Trong-Hung¹^ORCID,Pham Cong-Kha¹^ORCID,Hoang Trong-Thuc¹^ORCID

Affiliation:

1. Department of Computer and Network Engineering, University of Electro-Communications (UEC), 1-5-1 Chofugaoka, Tokyo 182-8585, Japan

Abstract

The Number Theoretic Transform (NTT) has been widely used to speed up polynomial multiplication in lattice-based post-quantum algorithms. All NTT operands use modular arithmetic, especially modular multiplication, which significantly influences NTT hardware implementation efficiency. Until now, most hardware implementations used Digital Signal Processing (DSP) to multiply two integers and optimally perform modulo computations from the multiplication product. This paper presents a customized Lattice-DSP (L-DSP) for modular multiplication based on the Karatsuba algorithm, Vedic multiplier, and modular reduction methods. The proposed L-DSP performs both integer multiplication and modular reduction simultaneously for lattice-based cryptography. As a result, the speed and area efficiency of the L-DSPs are 283 MHz for 77 SLICEs, 272 MHz for 87 SLICEs, and 256 MHz for 101 SLICEs with the parameters q of 3329, 7681, and 12,289, respectively. In addition, the N−1 multiplier in the Inverse-NTT (INTT) calculation is also eliminated, reducing the size of the Butterfly Unit (BU) in CRYSTAL-Kyber to about 104 SLICEs, equivalent to a conventional multiplication in the other studies. Based on the proposed DSP, a Point-Wise Matrix Multiplication (PWMM) architecture for CRYSTAL-Kyber is designed on a hardware footprint equivalent to 386 SLICEs. Furthermore, this research is the first DSP designed for lattice-based Post-quantum Cryptography (PQC) modular multiplication.

Publisher

MDPI AG

Subject

Applied Mathematics,Computational Theory and Mathematics,Computer Networks and Communications,Computer Science Applications,Software

Link

https://www.mdpi.com/2410-387X/7/4/46/pdf

Reference51 articles.

1. Alagic, G., Apon, D., Cooper, D., Dang, Q., Dang, T., Kelsey, J., Lichtinger, J., Liu, Y.K., Miller, C., and Moody, D. (2022). Status Report on the Third Round of the NIST Post-Quantum Cryptography Standardization Process.

2. Avanzi, R., Bos, J., Ducas, L., Kiltz, E., Lepoint, T., Lyubashevsky, V., Schanck, J.M., Schwabe, P., Seiler, G., and Stehlé, D. (2023, September 15). CRYSTALS-Kyber: Algorithm Specifications And Supporting Documentation (Version 3.01). January 2021. Available online: https://pq-crystals.org/kyber/data/kyber-specification-round3-20210131.pdf.

3. Bai, S., Ducas, L., Kiltz, E., Lepoint, T., Lyubashevsky, V., Schwabe, P., Seiler, G., and Stehlé, D. (2023, September 15). CRYSTALS-Dilithium: Algorithm Specifications And Supporting Documentation (Version 3.01). February 2021. Available online: https://pq-crystals.org/dilithium/data/dilithium-specification-round3-20210208.pdf.

4. Fouque, P.-A., Hoffstein, J., Kirchner, P., Lyubashevsky, V., Pornin, T., Prest, T., Ricosset, T., Seiler, G., Whyte, W., and Zhang, Z. (2023, September 15). Falcon: Fast-Fourier Lattice-Based Compact Signatures over NTRU (v1.2). October 2020. Available online: https://falcon-sign.info/falcon.pdf.

5. Modular Multiplication Without Trial Division;Montgomery;Math. Comput.,1985