English

Language Modeling with Hyperspherical Flows

Machine Learning 2026-05-19 v2

Abstract

Discrete Diffusion Language Models progressed rapidly as an alternative to autoregressive (AR) models, motivated by their parallel generation abilities. However, for tractability, discrete diffusion models sample from a factorized distribution, which is less expressive than AR. Recent Flow Language Models (FLMs) apply continuous flows to language, transporting noise to data with a deterministic ODE that avoids factorized sampling. FLMs operate on one-hot vectors whose dimension scales with the vocabulary size, making FLMs costly to train. Moreover, since all distinct one-hot embeddings are equidistant in 2\ell_2, adding Gaussian noise does not have a clear semantic interpretation (unlike images, where Gaussian noise progressively degrades structure). We introduce S\mathbb{S}-FLM, a latent FLM in the hypersphere. S\mathbb{S}-FLM generates sequences by rotating vectors in Sd1\mathbb{S}^{d-1} along a velocity field learned with cross-entropy, avoiding the overhead of materializing one-hot vectors. Previous FLMs match AR in Generative Perplexity (Gen.\ PPL), but samples with high likelihood are not necessarily correct in verifiable domains such as math and code. S\mathbb{S}-FLM substantially improves continuous flow language models on large-vocabulary reasoning and closes the gap to masked diffusion under standard-temperature sampling (T=1T=1), while a gap remains under optimized low-temperature (T=0.1T=0.1) decoding.

Keywords

Cite

@article{arxiv.2605.11125,
  title  = {Language Modeling with Hyperspherical Flows},
  author = {Justin Deschenaux and Caglar Gulcehre},
  journal= {arXiv preprint arXiv:2605.11125},
  year   = {2026}
}