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Auteurs principaux: Wang, Chen, Deng, Hexuan, Zhang, Yining, Zhang, Yuchen, Bai, Jionghao, Li, Zhaochun, Lan, Ge, Wang, Yue
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2605.07316
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author Wang, Chen
Deng, Hexuan
Zhang, Yining
Zhang, Yuchen
Bai, Jionghao
Li, Zhaochun
Lan, Ge
Wang, Yue
author_facet Wang, Chen
Deng, Hexuan
Zhang, Yining
Zhang, Yuchen
Bai, Jionghao
Li, Zhaochun
Lan, Ge
Wang, Yue
contents Reinforcement learning with verifiable rewards improves LLM reasoning but often induces overthinking, where models generate unnecessarily long reasoning traces. Existing methods mainly rely on length penalties or early-exit strategies; however, the former may degrade accuracy and induce underthinking, whereas the latter assumes that substantial portions of reasoning traces can be safely truncated. To obtain a compression signal without these limitations, we revisit the training dynamics of existing compression methods. We observe that the length--accuracy correlation is initially negative but continually increases during compression, indicating that shorter responses are initially more likely to be correct but gradually lose this property as the policy moves toward underthinking. Based on this observation, we formalize overthinking: a negative correlation indicates an overthinking regime, while a positive one indicates underthinking. When overthinking, the shortest correct responses are shorter than the group-average response length in expectation, making them natural compression targets already present in on-policy rollouts. We therefore propose \emph{Implicit Compression Regularization} (ICR), an on-policy regularization method whose compression signal comes from a virtual shorter distribution induced by the shortest correct responses in rollout groups, guiding the policy toward concise yet correct trajectories. Training dynamics show that ICR maintains a better length--accuracy correlation during compression, indicating that short responses remain better aligned with correctness instead of drifting toward underthinking. Experiments on three reasoning backbones and multiple mathematical and knowledge-intensive benchmarks show that ICR consistently shortens responses while preserving or improving accuracy, achieving a stronger accuracy--length Pareto frontier.
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spellingShingle Implicit Compression Regularization: Concise Reasoning via Internal Shorter Distributions in RL Post-Training
Wang, Chen
Deng, Hexuan
Zhang, Yining
Zhang, Yuchen
Bai, Jionghao
Li, Zhaochun
Lan, Ge
Wang, Yue
Artificial Intelligence
Reinforcement learning with verifiable rewards improves LLM reasoning but often induces overthinking, where models generate unnecessarily long reasoning traces. Existing methods mainly rely on length penalties or early-exit strategies; however, the former may degrade accuracy and induce underthinking, whereas the latter assumes that substantial portions of reasoning traces can be safely truncated. To obtain a compression signal without these limitations, we revisit the training dynamics of existing compression methods. We observe that the length--accuracy correlation is initially negative but continually increases during compression, indicating that shorter responses are initially more likely to be correct but gradually lose this property as the policy moves toward underthinking. Based on this observation, we formalize overthinking: a negative correlation indicates an overthinking regime, while a positive one indicates underthinking. When overthinking, the shortest correct responses are shorter than the group-average response length in expectation, making them natural compression targets already present in on-policy rollouts. We therefore propose \emph{Implicit Compression Regularization} (ICR), an on-policy regularization method whose compression signal comes from a virtual shorter distribution induced by the shortest correct responses in rollout groups, guiding the policy toward concise yet correct trajectories. Training dynamics show that ICR maintains a better length--accuracy correlation during compression, indicating that short responses remain better aligned with correctness instead of drifting toward underthinking. Experiments on three reasoning backbones and multiple mathematical and knowledge-intensive benchmarks show that ICR consistently shortens responses while preserving or improving accuracy, achieving a stronger accuracy--length Pareto frontier.
title Implicit Compression Regularization: Concise Reasoning via Internal Shorter Distributions in RL Post-Training
topic Artificial Intelligence
url https://arxiv.org/abs/2605.07316