English

Evolving LLMs' Self-Refinement Capability via Synergistic Training-Inference Optimization

Computation and Language 2025-10-28 v6 Machine Learning

Abstract

Self-Refinement refers to a model's ability to revise its own responses to produce improved outputs. This capability can also serve as a fundamental mechanism for Self-Improvement, for example, by reconstructing datasets with refined results to enhance intrinsic model performance. However, our comprehensive experiments reveal that large language models (LLMs) show no clear evidence of inherent Self-Refinement and may even experience response quality degradation after Self-Refinement. To address this issue, we propose EVOLVE, a simple and effective framework for eliciting and tracking the evolution of Self-Refinement through iterative training. We first explore optimization methods during training to activate the model's Self-Refinement capability. Then, at inference, we investigate various generation strategies to further enhance and utilize Self-Refinement while supplying the necessary data for training. Through synergistic optimization of training and inference stages, we continually evolve the model's Self-Refinement ability, enabling it to better refine its own responses. Moreover, we demonstrate the potential of leveraging Self-Refinement to achieve broader Self-Improvement of intrinsic model abilities. Experiments show that the evolved Self-Refinement ability enables the Llama-3.1-8B base model to surpass GPT-4o, achieving 62.3% length-controlled and 63.3% raw win rates on AlpacaEval 2, and 50.3% on Arena-Hard. It also generalizes effectively to out-of-domain reasoning tasks, improving performance on mathematical reasoning benchmarks such as GSM8K and MATH.

Keywords

Cite

@article{arxiv.2502.05605,
  title  = {Evolving LLMs' Self-Refinement Capability via Synergistic Training-Inference Optimization},
  author = {Yongcheng Zeng and Xinyu Cui and Xuanfa Jin and Qirui Mi and Guoqing Liu and Zexu Sun and Mengyue Yang and Dong Li and Weiyu Ma and Ning Yang and Jian Zhao and Jianye Hao and Haifeng Zhang and Jun Wang},
  journal= {arXiv preprint arXiv:2502.05605},
  year   = {2025}
}
R2 v1 2026-06-28T21:37:19.333Z