Universidad de Costa Rica

FIST: A feature-importance sampling and tree-based method for automatic design flow parameter tuning


Colaboradores:
Ing. Erick Carvajal Barboza, PhD.
Autores:
Zhiyao Xie, Guan-Qi Fang, Yu-Hung Huang, Haoxing Ren, Yanqing Zhang, Brucek Khailany, Shao-Yun Fang, Jiang Hu, Yiran Chen, Erick Carvajal Barboza
Revista:
IEEE Asia and South Pacific Design Automation Conference (ASP-DAC)
Editor:
URL:
https://ieeexplore.ieee.org/abstract/document/9045201?casa_token=fPyhAnSk0UoAAAAA:cOBvh4bTEH6bEiDmBZdD3x6OS1jn4HURD1H4jT0tG7ANeFjKiXRX9TmJqqmfr8Silr9g8ZiVeDcM
Laboratorios:
Laboratorio de Investigación en Microelectrónica y Arquitectura de computadores (LIMA)

Resumen:

Design flow parameters are of utmost importance to chip design quality and require a painfully long time to evaluate their effects. In reality, flow parameter tuning is usually performed manually based on designers' experience in an ad hoc manner. In this work, we introduce a machine learning-based automatic parameter tuning methodology that aims to find the best design quality with a limited number of trials. Instead of merely plugging in machine learning engines, we develop clustering and approximate sampling techniques for improving tuning efficiency. The feature extraction in this method can reuse knowledge from prior designs. Furthermore, we leverage a state-of-the-art XGBoost model and propose a novel dynamic tree technique to overcome overfitting. Experimental results on benchmark circuits show that our approach achieves 25% improvement in design quality or 37% reduction in sampling cost compared to random forest method, which is the kernel of a highly cited previous work. Our approach is further validated on two industrial designs. By sampling less than 0.02% of possible parameter sets, it reduces area by 1.83% and 1.43% compared to the best solutions hand-tuned by experienced designers.

© 2020 Escuela de Ingeniería Eléctrica, Universidad de Costa Rica.