Deepfakes refer to content synthesized using deep generators, which, when \emph{misused}, have the potential to erode trust in digital media. Synthesizing high-quality deepfakes requires access to large and complex generators only few entities can train and provide. The threat are malicious users that exploit access to the provided model and generate harmful deepfakes without risking detection. Watermarking makes deepfakes detectable by embedding an identifiable code into the generator that is later extractable from its generated images. We propose Pivotal Tuning Watermarking (PTW), a method for watermarking pre-trained generators (i) three orders of magnitude faster than watermarking from scratch and (ii) without the need for any training data. We improve existing watermarking methods and scale to generators $4 \times$ larger than related work. PTW can embed longer codes than existing methods while better preserving the generator's image quality. We propose rigorous, game-based definitions for robustness and undetectability and our study reveals that watermarking is not robust against an adaptive white-box attacker who has control over the generator's parameters. We propose an adaptive attack that can successfully remove any watermarking with access to only $200$ non-watermarked images. Our work challenges the trustworthiness of watermarking for deepfake detection when the parameters of a generator are available.