Timing-Driven Global Placement by Efficient Critical Path Extraction
Abstract
Timing optimization during the global placement of integrated circuits has been a significant focus for decades, yet it remains a complex, unresolved issue. Recent analytical methods typically use pin-level timing information to adjust net weights, which is fast and simple but neglects the path-based nature of the timing graph. The existing path-based methods, however, cannot balance the accuracy and efficiency due to the exponential growth of number of critical paths. In this work, we propose a GPU-accelerated timing-driven global placement framework, integrating accurate path-level information into the efficient DREAMPlace infrastructure. It optimizes the fine-grained pin-to-pin attraction objective and is facilitated by efficient critical path extraction. We also design a quadratic distance loss function specifically to align with the RC timing model. Experimental results demonstrate that our method significantly outperforms the current leading timing-driven placers, achieving an average improvement of 40.5% in total negative slack (TNS) and 8.3% in worst negative slack (WNS), as well as an improvement in half-perimeter wirelength (HPWL).
Keywords
Cite
@article{arxiv.2503.11674,
title = {Timing-Driven Global Placement by Efficient Critical Path Extraction},
author = {Yunqi Shi and Siyuan Xu and Shixiong Kai and Xi Lin and Ke Xue and Mingxuan Yuan and Chao Qian},
journal= {arXiv preprint arXiv:2503.11674},
year = {2025}
}
Comments
Accepted by DATE'25 as a Best Paper Award