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FalconSign: An Efficient and High-Throughput Hardware Architecture for Falcon Signature Generation

Yi Ouyang, Yihong Zhu, Wenping Zhu, Bohan Yang, Zirui Zhang, Hanning Wang, Qichao Tao, Min Zhu, Shaojun Wei, Leibo Liu

2024IACR Transactions on Cryptographic Hardware and Embedded Systems12 citationsDOIOpen Access PDF

Abstract

Falcon is a lattice-based quantum-resistant digital signature scheme renowned for its high signature generation/verification speed and compact signature size. The scheme has been selected to be drafted in the third round of the post-quantum cryptography (PQC) standardization process due to its unique attributes and robust security features. Despite its strengths, there has been a lack of research on hardware acceleration, primarily due to its complex calculation flow and floating-point operations, which hinders its widespread adoption. To address this issue, we propose FalconSign, a high-performance, configurable crypto-processor designed to accelerate Falcon signature generation on FPGA/ASIC through algorithmhardware co-design. Our approach involves a new scheduling flow and architecture for Fast-Fourier Sampling to enhance computing unit reuse and reduce processing time. Additionally, we introduce several optimized modules, including configurable randomness generation units, parallel floating-point processing units, and an optimized SamplerZ module, to improve execution efficiency. Furthermore, this paper presents a finely optimized hardware accelerator for the Falcon scheme. Our FPGA implementation results demonstrate a throughput improvement of approximately 5.1 x compared to state-of-the-art designs, with 2.8x/4.5x/4.2x/3.2x fewer in the area (LUTs/FFs/DSPs/BRAMs)-time product, for NIST security level V. The crypto-processor occupies an area of 0.71 mm2 and achieves 5.2k OPS at throughput on the TSMC 28nm process for NIST security level I.

Topics & Concepts

ThroughputSignature (topology)FalconComputer scienceArchitectureComputer architectureComputer hardwareEmbedded systemOperating systemGeographyProgramming languageMathematicsArchaeologyGeometryWirelessParallel Computing and Optimization TechniquesDistributed systems and fault toleranceSecurity and Verification in Computing
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