Non-Asymptotic Convergence of Discrete Diffusion Models: Masked and Random Walk dynamics (2512.00580v1)

Abstract: We investigate the theoretical underpinnings of Discrete Diffusion Models (DDMs) on discrete state spaces. Unlike in the continuous setting-where diffusion models are well understood both theoretically and empirically-the discrete case poses significant challenges due to its combinatorial structure and the lack of rigorous analysis. In this work, we establish convergence guarantees for DDMs on both the finite space $\mathbb{Z}^d_m={0,...,m-1}^d$ and the countably infinite space $\mathbb{N}^d$ under mild assumptions, focusing on forward masked and random walk dynamics. Similar to the continuous case, the backward process can be characterized by a discrete score function, whose monotonicity plays a central role in deriving the error bounds of the generated data. Notably, the complexity of our model scales linearly up to logarithmic factors, rather than exponentially, with the dimension, making it efficiently scalable to high-dimensional data. To the best of our knowledge, this study provides the first non-asymptotic convergence guarantees that do not rely on the boundedness of the estimated score-covering not only uniform noising processes on $\mathbb{Z}^d_m$ and on $\mathbb{N}^d$, but also masking-based noising dynamics.