A system level implementation of Rijndael on a memory-slot based FPGA card

2002 IEEE International Conference on Field-Programmable Technology, 2002. (FPT). Proceedings. Pub Date : 2002-12-16 DOI:10.1109/FPT.2002.1188670

Dennis K. Y. Tong, Pui Sze Lo, Kin-Hong Lee, P. Leong

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引用次数: 11

Abstract

This paper describes system level issues encountered in a high performance implementation of a Rijndael encryption core on a memory-slot based reconfigurable computing platform called Pilchard. The Rijndael algorithm was adopted in 2000 by the US National Institute of Standards and Technology (NIST) as the Advanced Encryption Standard (AES). In the implementation of Rijndael, changing the number of unrolled rounds in the encryption core can affect the performance of the system. It is shown that for the design presented, the highest performance of 755 Mbit/sec was achieved by implementing a core with a single round. Although it is relatively easy to implement a high performance core on an FPGA, due to I/O bottlenecks, achieving high system level performance is more difficult. In order to optimize the performance of the host/FPGA interface, special instructions from the Intel Pentium III streaming SIMD extensions (SSE) along with write-combining memory operations were used. These features enabled the measured throughput of the AES core to reach 445 Mbit/sec which, although still slower than the AES core, was double that of an unoptimized interface.

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Rijndael在基于内存插槽的FPGA卡上的系统级实现

本文描述了在基于内存槽的可重构计算平台Pilchard上实现Rijndael加密核时遇到的系统级问题。Rijndael算法于2000年被美国国家标准与技术研究所(NIST)采用为高级加密标准(AES)。在Rijndael的实现中，更改加密核心中展开的轮数可能会影响系统的性能。结果表明，在本设计中，单轮核心实现的最高性能为755 Mbit/sec。虽然在FPGA上实现高性能核心相对容易，但由于I/O瓶颈，实现高系统级性能更加困难。为了优化主机/FPGA接口的性能，使用了来自Intel Pentium III流SIMD扩展(SSE)的特殊指令以及写组合内存操作。这些特性使AES核心的测量吞吐量达到445 Mbit/sec，虽然仍然比AES核心慢，但是未优化接口的两倍。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2002 IEEE International Conference on Field-Programmable Technology, 2002. (FPT). Proceedings.

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