Recently, GPU-accelerated placers such as DREAMPlace and Xplace have demonstrated their superiority over traditional CPU-reliant placers by achieving orders of magnitude speed up in placement runtime. However, due to their limited focus in placement objectives (e.g., wirelength and density), the placement quality achieved by DREAMPlace or Xplace is not comparable to that of commercial tools. In this article, to bridge the gap between open source and commercial placers, we present a novel placement optimization framework named GAN-Place that employs generative adversarial learning to transfer the placement quality of the industry-leading commercial placer, Synopsys ICC2, to existing open source GPU-accelerated placers (DREAMPlace and Xplace). Without the knowledge of the underlying proprietary algorithms or constraints used by the commercial tools, our framework facilitates transfer learning to directly enhance the open source placers by optimizing the proposed differentiable loss that denotes the “similarity” between DREAMPlace- or Xplace-generated placements and those in commercial databases. Experimental results on seven industrial designs not only show that our GAN-Place immediately improves the Power, Performance, and Area metrics at the placement stage but also demonstrates that these improvements last firmly to the post-route stage, where we observe improvements by up to 8.3% in wirelength, 7.4% in power, and 37.6% in Total Negative Slack on a commercial CPU benchmark.