English

EntropyCache: Decoded Token Entropy Guided KV Caching for Diffusion Language Models

Computation and Language 2026-03-20 v1

Abstract

Diffusion-based large language models (dLLMs) rely on bidirectional attention, which prevents lossless KV caching and requires a full forward pass at every denoising step. Existing approximate KV caching methods reduce this cost by selectively updating cached states, but their decision overhead scales with context length or model depth. We propose EntropyCache, a training-free KV caching method that uses the maximum entropy of newly decoded token distributions as a constant-cost signal for deciding when to recompute. Our design is grounded in two empirical observations: (1) decoded token entropy correlates with KV cache drift, providing a cheap proxy for cache staleness, and (2) feature volatility of decoded tokens persists for multiple steps after unmasking, motivating recomputation of the kk most recently decoded tokens. The skip-or-recompute decision requires only O(V)O(V) computation per step, independent of context length and model scale. Experiments on LLaDA-8B-Instruct and Dream-7B-Instruct show that EntropyCache achieves 15.2×15.2\times-26.4×26.4\times speedup on standard benchmarks and 22.4×22.4\times-24.1×24.1\times on chain-of-thought benchmarks, with competitive accuracy and decision overhead accounting for only 0.5%0.5\% of inference time. Code is available at https://github.com/mscheong01/EntropyCache.

Keywords

Cite

@article{arxiv.2603.18489,
  title  = {EntropyCache: Decoded Token Entropy Guided KV Caching for Diffusion Language Models},
  author = {Minsoo Cheong and Donghyun Son and Woosang Lim and Sungjoo Yoo},
  journal= {arXiv preprint arXiv:2603.18489},
  year   = {2026}
}
R2 v1 2026-07-01T11:27:28.255Z