Controllable Image Generation with Composed Parallel Token Prediction

TL;DR

This paper introduces a theoretically-grounded method for composing multiple input conditions in discrete generative models, improving accuracy, speed, and control in image generation tasks.

Contribution

The authors propose a novel formulation for composing discrete probabilistic processes, enabling flexible combination of conditions outside training data and enhancing generative quality.

Findings

Achieved a 63.4% relative error reduction across three datasets.

Obtained an average FID improvement of -9.58.

Provided 2.3x to 12x faster generation speeds.

Abstract

Conditional discrete generative models struggle to faithfully compose multiple input conditions. To address this, we derive a theoretically-grounded formulation for composing discrete probabilistic generative processes, with masked generation (absorbing diffusion) as a special case. Our formulation enables precise specification of novel combinations and numbers of input conditions that lie outside the training data, with concept weighting enabling emphasis or negation of individual conditions. In synergy with the richly compositional learned vocabulary of VQ-VAE and VQ-GAN, our method attains a $63.4\%$ relative reduction in error rate compared to the previous state-of-the-art, averaged across 3 datasets (positional CLEVR, relational CLEVR and FFHQ), simultaneously obtaining an average absolute FID improvement of $-9.58$. Meanwhile, our method offers a $2.3\times$ to $12\times$ real-time speed-up over comparable methods, and is readily applied to an open pre-trained discrete text-to-image model for fine-grained control of text-to-image generation.