English

CircuitVAE: Efficient and Scalable Latent Circuit Optimization

Machine Learning 2024-06-17 v1 Hardware Architecture

Abstract

Automatically designing fast and space-efficient digital circuits is challenging because circuits are discrete, must exactly implement the desired logic, and are costly to simulate. We address these challenges with CircuitVAE, a search algorithm that embeds computation graphs in a continuous space and optimizes a learned surrogate of physical simulation by gradient descent. By carefully controlling overfitting of the simulation surrogate and ensuring diverse exploration, our algorithm is highly sample-efficient, yet gracefully scales to large problem instances and high sample budgets. We test CircuitVAE by designing binary adders across a large range of sizes, IO timing constraints, and sample budgets. Our method excels at designing large circuits, where other algorithms struggle: compared to reinforcement learning and genetic algorithms, CircuitVAE typically finds 64-bit adders which are smaller and faster using less than half the sample budget. We also find CircuitVAE can design state-of-the-art adders in a real-world chip, demonstrating that our method can outperform commercial tools in a realistic setting.

Keywords

Cite

@article{arxiv.2406.09535,
  title  = {CircuitVAE: Efficient and Scalable Latent Circuit Optimization},
  author = {Jialin Song and Aidan Swope and Robert Kirby and Rajarshi Roy and Saad Godil and Jonathan Raiman and Bryan Catanzaro},
  journal= {arXiv preprint arXiv:2406.09535},
  year   = {2024}
}

Comments

Design Automation Conference (DAC) 2024; the first two authors contributed equally

R2 v1 2026-06-28T17:05:14.335Z