系统方式的 AES：Celator 处理器的实现和结果

2008 15th IEEE International Conference on Electronics, Circuits and Systems Pub Date : 2008-11-17 DOI:10.1109/ICECS.2008.4674870

Daniele Fronte, A. Pérez, Eric Payrat

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引用次数: 3

摘要

本文介绍了一种名为 Celator 的多算法加密协处理器。Celator 的架构基于一个 4 倍于 4 个处理元件的收缩阵列、一个带有有限状态机（FSM）的序列器和一个本地存储器 Celator RAM（CRAM）。数据由 PE 阵列进行加密或解密。围绕 Celator 的整个系统架构包括一个中央处理器（CPU）和 CPU 与 Celator 之间的接口单元。定序器控制 PE 阵列，并管理 PE 阵列与 CPU 之间的所有数据传输。每个 PE 有三个多路复用器，可对数据路径进行重新配置。FSM 指令存储在 CRAM 中，可由 CPU 更改：因此，FSM 也是可重新配置的。本文的重点是在 Celator 上实现高级加密标准（AES）转换。在电子密码本模式下，Celator 可以在 580 个时钟周期内完成 AES 加密，这比使用通用处理器的时间要短。最后，我们报告了 Celator、ARM 7 TDMI、ARM 9 和 AVR 微处理器以及一些 AES 专用和动态可重构电路的性能比较。

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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The AES in a systolic fashion: Implementation and results of Celator processor

A multi-algorithm Crypto-Co-Processor called Celator is presented. Celator architecture is based on a 4times4 Processing Elements systolic array, a Sequencer with a Finite State Machine (FSM) and a local memory, the Celator RAM (CRAM). Data are encrypted or decrypted by the PE array. The whole system architecture around Celator includes a Central Processing Unit (CPU) and an Interface unit between the CPU and Celator. The Sequencer controls the PE array and manages all the data transfers between the PE array and the CPU. Three multiplexers per PE allow the reconfigurability of the data path. The FSM instructions are stored in the CRAM and can be changed by the CPU: therefore the FSM is also reconfigurable. This paper focuses on the implementation of the Advanced Encryption Standard (AES) transformations on Celator. Celator can perform an AES encryption in 580 clock cycles in Electronic Codebook mode, which is less than with a general purpose processor. Finally we report performance comparisons among Celator, ARM 7 TDMI, ARM 9 and AVR microprocessors, as well as with some AES dedicated and dynamically reconfigurable circuits.

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2008 15th IEEE International Conference on Electronics, Circuits and Systems

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