StML: Bridging the gap between FPGA design and HDL circuit description

2013 International Conference on Field-Programmable Technology (FPT) Pub Date : 2013-12-01 DOI:10.1109/FPT.2013.6718366

Dustin Peterson, O. Bringmann, Thomas Schweizer, W. Rosenstiel

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引用次数: 7

Abstract

FPGA circuit implementation is a unidirectional and time-consuming process. Existing approaches like the incremental synthesis try to shorten it, but still need to execute the whole flow for a changed circuit partition. Other approaches circumvent process stages by providing bidirectional mappings between their results. In this paper we propose an approach to provide a bidirectional link between an FPGA design and its HDL code. This link enables the circumvention of the most time-consuming stages (synthesis, mapping, placing, routing) of the FPGA circuit implementation. We implemented our approach in a Java-based EDA tool library, called Static Mapping Library (StML). We demonstrate its applicability by means of hardware debugging and an RTL-based injection of permanent faults, built on top of the StML. Experimental results illustrate that a mapping coverage between 98.5%-100.0% can be obtained, which substantiates the feasibility of this approach. Further experiments illustrate a controllable tradeoff between area overhead, circuit granularity and mapping granularity. With the finest mapping granularity, the area overhead has been between 1.8% and 60.2% for RTL-based circuits. The speedup of the proposed fault injection method has been estimated to be up to 6x for the tested circuits.

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弥合FPGA设计和HDL电路描述之间的差距

FPGA电路的实现是一个单向且耗时的过程。现有的方法，如增量合成，试图缩短它，但仍然需要执行整个流程的改变电路分区。其他方法通过提供结果之间的双向映射来绕过过程阶段。在本文中，我们提出了一种在FPGA设计和其HDL代码之间提供双向链接的方法。这个链接可以绕过FPGA电路实现中最耗时的阶段(合成、映射、放置、路由)。我们在一个称为静态映射库(StML)的基于java的EDA工具库中实现了我们的方法。我们通过硬件调试和基于rtl的永久故障注入(构建在StML之上)来证明其适用性。实验结果表明，该方法的映射覆盖率在98.5% ~ 100.0%之间，验证了该方法的可行性。进一步的实验证明了面积开销、电路粒度和映射粒度之间的可控权衡。使用最精细的映射粒度，基于rtl的电路的面积开销在1.8%到60.2%之间。所提出的故障注入方法对测试电路的加速可达6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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2013 International Conference on Field-Programmable Technology (FPT)

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