DeepGate: Learning Neural Representations of Logic Gates
Abstract
Applying deep learning (DL) techniques in the electronic design automation (EDA) field has become a trending topic. Most solutions apply well-developed DL models to solve specific EDA problems. While demonstrating promising results, they require careful model tuning for every problem. The fundamental question on "How to obtain a general and effective neural representation of circuits?" has not been answered yet. In this work, we take the first step towards solving this problem. We propose DeepGate, a novel representation learning solution that effectively embeds both logic function and structural information of a circuit as vectors on each gate. Specifically, we propose transforming circuits into unified and-inverter graph format for learning and using signal probabilities as the supervision task in DeepGate. We then introduce a novel graph neural network that uses strong inductive biases in practical circuits as learning priors for signal probability prediction. Our experimental results show the efficacy and generalization capability of DeepGate.
Cite
@article{arxiv.2111.14616,
title = {DeepGate: Learning Neural Representations of Logic Gates},
author = {Min Li and Sadaf Khan and Zhengyuan Shi and Naixing Wang and Yu Huang and Qiang Xu},
journal= {arXiv preprint arXiv:2111.14616},
year = {2022}
}
Comments
Accepted by DAC2022