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Dynamic Delayed Tree Expansion For Improved Multi-Path Speculative Decoding

Machine Learning 2026-02-20 v1

Abstract

Multi-path speculative decoding accelerates lossless sampling from a target model by using a cheaper draft model to generate a draft tree of tokens, and then applies a verification algorithm that accepts a subset of these. While prior work has proposed various verification algorithms for i.i.d rollouts, their relative performance under matched settings remains unclear. In this work, we firstly present a systematic evaluation of verification strategies across model families, tasks, and sampling regimes, and find that Traversal Verification dominates consistently, with OT-based methods lagging far behind. Our analysis uncovers that this occurs because OT-based methods achieve high multi-token acceptance near the root of the draft tree, while multi-token gains are most impactful deeper in the draft tree, where draft and target distributions diverge. Based on this insight, we propose delayed tree expansion, which drafts a partial single path, delaying the i.i.d. branching point. We show that delayed tree expansion preserves the target distribution and improves on root-node i.i.d rollouts. Further, we develop a dynamic neural selector that estimates the expected block efficiency of optimal-transport-based verification methods from draft and target features, enabling context-dependent expansion decisions. Our neural selector allows OT-based methods like SpecInfer to outperform Traversal Verification for the first time, achieving 5% higher average throughput across a wide range of models, datasets, and sampling settings.

Keywords

Cite

@article{arxiv.2602.16994,
  title  = {Dynamic Delayed Tree Expansion For Improved Multi-Path Speculative Decoding},
  author = {Rahul Thomas and Teo Kitanovski and Micah Goldblum and Arka Pal},
  journal= {arXiv preprint arXiv:2602.16994},
  year   = {2026}
}
R2 v1 2026-07-01T10:42:19.604Z