A unified approach to the decomposition and re-decomposition of sequential machines

27th ACM/IEEE Design Automation Conference Pub Date : 1990-06-24 DOI:10.1109/DAC.1990.114925

P. Ashar, S. Devadas, A. Newton

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引用次数: 33

Abstract

A unified framework and associated algorithms are presented. This framework allows for a uniform treatment of arbitrary decomposition topologies operating at the state transition graph (STG) level, while targeting a cost function that is close to the eventual logic implementation. Previous work has targeted specific decomposition topologies via the formulation of decomposition as implicant covering with associated constraints. It is shown that this formulation can be used to target arbitrary desired topologies merely by customizing the constraints during implicant covering. It is also shown how this work relates to preserved partitions and covers traditionally used in parallel and cascade decompositions, and how this formulation establishes the relationship between state assignment and a finite state machine decomposition. Memory and CPU-time-efficient re-decomposition algorithms that operate on distributed-style specifications and which are more global than those presented in the past have been developed. These algorithms are implemented in the sequential logic synthesis system, FLAMES, that is being developed at UCB/MIT.<>

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对顺序机进行分解和再分解的统一方法

给出了一个统一的框架和相关算法。此框架允许在状态转换图(STG)级别上对任意分解拓扑进行统一处理，同时以接近最终逻辑实现的成本函数为目标。以前的工作是通过将分解表述为具有相关约束的隐含覆盖来针对特定的分解拓扑。结果表明，该公式仅通过在隐含覆盖期间自定义约束即可用于目标任意所需的拓扑。它还展示了这项工作如何与保留的分区和传统上用于并行和级联分解的覆盖相关，以及该公式如何建立状态分配和有限状态机分解之间的关系。已经开发出了基于分布式风格规范的内存和cpu时间效率高的重新分解算法，这些算法比过去提出的算法更具全局性。这些算法在UCB/MIT正在开发的顺序逻辑合成系统flame中实现。

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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27th ACM/IEEE Design Automation Conference

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