Optimising Bundled-Data Balsa Circuits

2016 22nd IEEE International Symposium on Asynchronous Circuits and Systems (ASYNC) Pub Date : 2016-05-08 DOI:10.1109/ASYNC.2016.11

Norman Kluge, Ralf Wollowski

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引用次数: 1

Abstract

Balsa provides a design flow where asynchronous circuits are created from high-level specifications, but the syntax-driven translation often results in performance overhead. To improve this, we exploit the fact that bundled-data circuits can be divided into data and control path. Hence, tailored optimisation techniques can be applied to both paths separately. For control path optimisation, STG-based resynthesis has been introduced (applying logic minimisation). However, solid results are missing so far due to problems with state explosion and the reliable insertion of reset logic. To tackle this, we use an adjusted STG decomposition algorithm and started to develop a new logic synthesizer (based on ideas of petrify) with proper reset insertion. Adding the adapted data path, we are now able to get first promising post synthesis simulation results using an industrial technology library (with a performance improvement of up to 23%). First experiments show additional potential for performance improvements (of up to 56%) when standard tools for synchronous design are applied to the data path.

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优化捆绑数据Balsa电路

Balsa提供了一个设计流程，其中异步电路是根据高级规范创建的，但是语法驱动的转换通常会导致性能开销。为了改进这一点，我们利用了数据电路可以分为数据路径和控制路径的事实。因此，量身定制的优化技术可以分别应用于两条路径。对于控制路径优化，引入了基于stg的再合成(应用逻辑最小化)。然而，由于状态爆炸和复位逻辑的可靠插入问题，目前还没有可靠的结果。为了解决这个问题，我们使用了一种调整后的STG分解算法，并开始开发一种新的逻辑合成器(基于石化的思想)，具有适当的复位插入。添加适应的数据路径，我们现在能够使用工业技术库获得第一个有希望的合成后仿真结果(性能提高高达23%)。第一个实验表明，当同步设计的标准工具应用于数据路径时，性能改进的额外潜力(高达56%)。

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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来源期刊

2016 22nd IEEE International Symposium on Asynchronous Circuits and Systems (ASYNC)

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