大规模异构fpga的时钟感知布局

2017 IEEE/ACM International Conference on Computer-Aided Design (ICCAD) Pub Date : 2017-11-13 DOI:10.1109/ICCAD.2017.8203821

Yun-Chih Kuo, Chau-Chin Huang, Shih-Chun Chen, Chun-Han Chiang, Yao-Wen Chang, S. Kuo

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引用次数: 20

摘要

现代FPGA通常包含类似asic的时钟架构，这对于实现更好的倾斜和性能至关重要。现有的传统FPGA布局算法很少考虑时钟资源，因此可能导致时钟路由失败。针对FPGA特殊的时钟结构，提出了一种新的大规模异构FPGA的时钟感知放置算法。该算法包括三个主要阶段:(1)具有时钟栅栏区域构造的非线性全局布局框架;(2)时钟感知的打包方案;(3)时钟感知的合法化和详细布局。我们根据2017年ISPD时钟感知安置竞赛基准套件评估我们的结果。与前三名算法进行比较，结果表明本文算法实现了最佳的总路由长度。平均而言，我们的算法在路由长度上分别比前三名的算法高出3.6%、7.5%和12.9%。

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Clock-aware placement for large-scale heterogeneous FPGAs

A modern FPGA often contains an ASIC-like clocking architecture which is crucial to achieve better skew and performance. Existing conventional FPGA placement algorithms seldom consider clocking resources, and thus may lead to clock routing failures. To address the special FPGA clocking architecture, this paper presents a novel clock-aware placement algorithm for large-scale heterogeneous FPGAs. Our algorithm consists of three major stages: (1) a nonlinear global placement framework with clock fence region construction, (2) a clock-aware packing scheme, and (3) clock-aware legalization and detailed placement. We evaluate our results based on the 2017 ISPD Clock-Aware Placement Contest benchmark suite. Compared with the top three winners, the results show that our algorithm achieves the best overall routed wirelength. On average, our algorithm outperforms the top-3 winners by 3.6%, 7.5%, and 12.9% in routed wirelength, respectively.

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2017 IEEE/ACM International Conference on Computer-Aided Design (ICCAD)

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