A High-Performance Hardware Architecture for Spectral Hash Algorithm

2009 20th IEEE International Conference on Application-specific Systems, Architectures and Processors Pub Date : 2009-07-07 DOI:10.1109/ASAP.2009.31

R. Cheung, Ç. Koç, J. Villasenor

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引用次数: 2

Abstract

The Spectral Hash algorithm is one of the Round 1 candidates for the SHA-3 family, and is based on spectral arithmetic over a finite field, involving multidimensional discrete Fourier transformations over a finite field, data dependent permutations, Rubic-type rotations, and affine and nonlinear functions. The underlying mathematical structures and operations pose interesting and challenging tasks for computer architects and hardware designers to create fast, efficient, and compact ASIC and FPGA realizations. In this paper, we present an efficient hardware architecture for the full 512-bit hash computation using the spectral hash algorithm. We have created a pipelined implementation on a Xilinx Virtex-4 XC4VLX200-11 FPGA which yields 100 MHz and occupies 38,328 slices, generating a throughput of 51.2 Gbps. Our fully parallel synthesized implementation shows that the spectral hash algorithm is about 100 times faster than the fastest SHA-1 implementation, while requiring only about 13 times as many logic slices.

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谱哈希算法的高性能硬件架构

谱哈希算法是SHA-3家族的第一轮候选算法之一，它基于有限域上的谱算法，涉及有限域上的多维离散傅里叶变换、数据依赖排列、rubic型旋转以及仿射和非线性函数。底层的数学结构和运算为计算机架构师和硬件设计人员创建快速、高效和紧凑的ASIC和FPGA实现提出了有趣而具有挑战性的任务。在本文中，我们提出了一个高效的硬件架构，用于使用谱哈希算法进行完整的512位哈希计算。我们在Xilinx Virtex-4 XC4VLX200-11 FPGA上创建了一个流水线实现，产生100 MHz，占用38,328片，产生51.2 Gbps的吞吐量。我们的全并行合成实现表明，谱哈希算法比最快的SHA-1实现快100倍，而只需要大约13倍的逻辑切片。

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2009 20th IEEE International Conference on Application-specific Systems, Architectures and Processors

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