Reducing instruction fetch energy with backwards branch control information and buffering

Proceedings of the 2003 International Symposium on Low Power Electronics and Design, 2003. ISLPED '03. Pub Date : 2003-08-25 DOI:10.1145/871506.871586

J. Rivers, S. Asaad, J. Wellman, J. Moreno

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引用次数: 4

Abstract

Many emerging applications, e.g. in the embedded and DSP space, are often characterized by their loopy nature where a substantial part of the execution time is spent within a few program phases. Loop buffering techniques have been proposed for capturing and processing these loops in small buffers to reduce the processor's instruction fetch energy. However, these schemes are limited to straight-line or innermost loops and fail to adequately handle complex loops. In this paper, we propose a dynamic loop buffering mechanism that uses backwards branch control information to identify, capture and process complex loop structures. The DLB controller has been fully implemented in VHDL, synthesized and timed with the IBM Booledozer and Einstimer Synthesis tools, and analyzed for power with the Sequence PowerTheater tool. Our experiments show that the DLB approach, on average, results in a factor of 3 reduction in energy consumption compared to a traditional instruction memory design at an area overhead of about 9%.

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利用反向支路控制信息和缓冲减少指令提取能量

许多新兴的应用程序，例如在嵌入式和DSP领域，通常以其循环特性为特征，其中大部分执行时间都花在几个程序阶段中。为了减少处理器的指令获取能量，已经提出了在小缓冲区中捕获和处理这些循环的循环缓冲技术。然而，这些方案仅限于直线或最内层循环，不能充分处理复杂的循环。在本文中，我们提出了一种动态循环缓冲机制，该机制使用向后分支控制信息来识别，捕获和处理复杂的循环结构。采用VHDL语言对DLB控制器进行了全面实现，利用IBM Booledozer和einmer合成工具进行了合成和定时，并利用Sequence PowerTheater工具进行了功率分析。我们的实验表明，平均而言，与传统的指令存储器设计相比，DLB方法的能耗降低了3倍，而面积开销约为9%。

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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Proceedings of the 2003 International Symposium on Low Power Electronics and Design, 2003. ISLPED '03.

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