Plug-and-Hide: Provable and Adjustable Diffusion Generative Steganography

Abstract: Generative Steganography (GS) is a novel technique that utilizes generative models to conceal messages without relying on cover images. Contemporary GS algorithms leverage the powerful generative capabilities of Diffusion Models (DMs) to create high-fidelity stego images. However, these algorithms, while yielding relatively satisfactory generation outcomes and message extraction accuracy, significantly alter modifications to the initial Gaussian noise of DMs, thereby compromising steganographic security. In this paper, we rethink the trade-off among image quality, steganographic security, and message extraction accuracy within Diffusion Generative Steganography (DGS) settings. Our findings reveal that the normality of initial noise of DMs is crucial to these factors and can offer theoretically grounded guidance for DGS design. Based on this insight, we propose a Provable and Adjustable Message Mapping (PA-B2G) approach. It can, on one hand, theoretically guarantee reversible encoding of bit messages from arbitrary distributions into standard Gaussian noise for DMs. On the other hand, its adjustability provides a more natural and fine-grained way to trade off image quality, steganographic security, and message extraction accuracy. By integrating PA-B2G with a probability flow ordinary differential equation, we establish an invertible mapping between secret messages and stego images. PA-B2G can be seamlessly incorporated with most mainstream DMs, such as the Stable Diffusion, without necessitating additional training or fine-tuning. Comprehensive experiments corroborate our theoretical insights regarding the trade-off in DGS settings and demonstrate the effectiveness of our DGS algorithm in producing high-quality stego images while preserving desired levels of steganographic security and extraction accuracy.