通过因果变换器进行预测性自我监督的逻辑合成优化

Raika Karimi, Faezeh Faez, Yingxue Zhang, Xing Li, Lei Chen, Mingxuan Yuan, Mahdi Biparva
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引用次数: 0

摘要

逻辑合成优化(LSO)在电子设计自动化(EDA)工作流程中的一个抽象层次上运行,目标是在最终布局的尺寸和速度等性能指标方面改进逻辑电路。该领域的最新趋势表明,人们对将机器学习(ML)应用于 EDA 的兴趣与日俱增,特别是通过利用基于策略的强化学习(RL)方法进行 ML 引导的逻辑合成。尽管取得了这些进步,但现有模型仍面临过度拟合和泛化受限等挑战,这归因于受限的公共电路和图编码器的可执行性限制。为了克服这些障碍并解决数据稀缺问题,我们引入了 LSOformer,这是一种利用自回归变压器模型和预测性 SSL 来预测结果质量(QoR)轨迹的新方法。LSOformer 集成了交叉注意模块,将电路图和优化序列中的见解融合在一起,从而提高了 QoR 指标的预测精度。实验研究验证了 LSOformer 的有效性,展示了它在 QoR 预测任务中优于基线架构的性能,在归纳设置中,LSOformer 在 EPFL、OABCD 和 proprietarycircuits 数据集上的性能分别提高了 5.74%、4.35% 和 17.06%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Logic Synthesis Optimization with Predictive Self-Supervision via Causal Transformers
Contemporary hardware design benefits from the abstraction provided by high-level logic gates, streamlining the implementation of logic circuits. Logic Synthesis Optimization (LSO) operates at one level of abstraction within the Electronic Design Automation (EDA) workflow, targeting improvements in logic circuits with respect to performance metrics such as size and speed in the final layout. Recent trends in the field show a growing interest in leveraging Machine Learning (ML) for EDA, notably through ML-guided logic synthesis utilizing policy-based Reinforcement Learning (RL) methods.Despite these advancements, existing models face challenges such as overfitting and limited generalization, attributed to constrained public circuits and the expressiveness limitations of graph encoders. To address these hurdles, and tackle data scarcity issues, we introduce LSOformer, a novel approach harnessing Autoregressive transformer models and predictive SSL to predict the trajectory of Quality of Results (QoR). LSOformer integrates cross-attention modules to merge insights from circuit graphs and optimization sequences, thereby enhancing prediction accuracy for QoR metrics. Experimental studies validate the effectiveness of LSOformer, showcasing its superior performance over baseline architectures in QoR prediction tasks, where it achieves improvements of 5.74%, 4.35%, and 17.06% on the EPFL, OABCD, and proprietary circuits datasets, respectively, in inductive setup.
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