多维时间硬件合成

Proceedings IEEE International Conference on Application-Specific Systems, Architectures, and Processors. ASAP 2003 Pub Date : 2003-06-24 DOI:10.1109/ASAP.2003.1212828

A. Guillou, P. Quinton, T. Risset

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引用次数: 31

摘要

我们介绍了将经典的收缩综合方法扩展到多维时间的一些基本原理。多维调度支持不允许并行化线性调度的复杂算法，但它也需要在体系结构中使用内存。我们解释了如何为VLSI(或类似simd的代码)生成获得兼容的分配和内存函数。我们还提出了一种控制具有多维调度的VLSI架构的原始机制。利用这些系统设计原则，推导和合成了一个结构化的VHDL代码(用于在FPGA平台上实现)。这些结果是多维时间硬件综合的初步步骤。

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Hardware synthesis for multi-dimensional time

We introduce some basic principles for extending the classical systolic synthesis methodology to multidimensional time. Multidimensional scheduling enables complex algorithms that do not admit linear schedules to be parallelized, but it also requires the use of memories in the architecture. We explain how to obtain compatible allocation and memory functions for VLSI (or SIMD-like code) generation. We also present an original mechanism for controlling a VLSI architecture that has a multidimensional schedule. A structural VHDL code has been derived and synthesized (for implementation on FPGA platforms) using these systematic design principles. These results are preliminary steps to the hardware synthesis for multidimensional time.

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Proceedings IEEE International Conference on Application-Specific Systems, Architectures, and Processors. ASAP 2003

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