English

Chip Placement with Deep Reinforcement Learning

Machine Learning 2020-04-23 v1 Artificial Intelligence

Abstract

In this work, we present a learning-based approach to chip placement, one of the most complex and time-consuming stages of the chip design process. Unlike prior methods, our approach has the ability to learn from past experience and improve over time. In particular, as we train over a greater number of chip blocks, our method becomes better at rapidly generating optimized placements for previously unseen chip blocks. To achieve these results, we pose placement as a Reinforcement Learning (RL) problem and train an agent to place the nodes of a chip netlist onto a chip canvas. To enable our RL policy to generalize to unseen blocks, we ground representation learning in the supervised task of predicting placement quality. By designing a neural architecture that can accurately predict reward across a wide variety of netlists and their placements, we are able to generate rich feature embeddings of the input netlists. We then use this architecture as the encoder of our policy and value networks to enable transfer learning. Our objective is to minimize PPA (power, performance, and area), and we show that, in under 6 hours, our method can generate placements that are superhuman or comparable on modern accelerator netlists, whereas existing baselines require human experts in the loop and take several weeks.

Keywords

Cite

@article{arxiv.2004.10746,
  title  = {Chip Placement with Deep Reinforcement Learning},
  author = {Azalia Mirhoseini and Anna Goldie and Mustafa Yazgan and Joe Jiang and Ebrahim Songhori and Shen Wang and Young-Joon Lee and Eric Johnson and Omkar Pathak and Sungmin Bae and Azade Nazi and Jiwoo Pak and Andy Tong and Kavya Srinivasa and William Hang and Emre Tuncer and Anand Babu and Quoc V. Le and James Laudon and Richard Ho and Roger Carpenter and Jeff Dean},
  journal= {arXiv preprint arXiv:2004.10746},
  year   = {2020}
}
R2 v1 2026-06-23T15:02:04.652Z