English

Harnesses for Inference-Time Alignment over Execution Trajectories

Machine Learning 2026-05-22 v1 Artificial Intelligence

Abstract

Harness engineering has emerged as an important inference-time technique for large language model (LLM) agents, aiming to improve long-term performance through task decomposition and guided execution. However, more elaborate harnesses are not uniformly better: increasing decomposition or guidance can sometimes improve execution, but can also reduce final task success. We study harness design through the lens of inference-time trajectory alignment. This perspective separates harness into two mechanisms: task decomposition, which structures a task into sub-goals, and guided execution, which reshapes local action distributions during execution. This decomposition allows us to quantify how workflow granularity, retry budgets, and guidance-induced action reweighting shape the performance limits of harness design. It further reveals concrete failure modes, including over-decomposition, over-pruning, and hallucinated execution. We validate these predictions through controlled synthetic experiments and real terminal agent benchmarks. Inspired by the theory, we further show that effective harnesses can be partial: specifying only the initial steps and leaving the remaining execution to agent can achieve higher pass rate than fully structured workflows.

Keywords

Cite

@article{arxiv.2605.21516,
  title  = {Harnesses for Inference-Time Alignment over Execution Trajectories},
  author = {Boyuan Wang and Bochao Li and Minghan Wang and Yuxin Tao and Fang Kong},
  journal= {arXiv preprint arXiv:2605.21516},
  year   = {2026}
}