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Autori principali: Pang, Renning, Lan, Tian, Liu, Leyuan, Tong, Piao, Cao, Sheng, Zhang, Xiaosong
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2605.15041
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author Pang, Renning
Lan, Tian
Liu, Leyuan
Tong, Piao
Cao, Sheng
Zhang, Xiaosong
author_facet Pang, Renning
Lan, Tian
Liu, Leyuan
Tong, Piao
Cao, Sheng
Zhang, Xiaosong
contents Tool use extends large language models beyond parametric knowledge, but reliable execution requires balancing appropriate reasoning depth with strict structural validity. We approach this problem from a case-based perspective to present CAST, a case-driven framework that treats historical execution trajectories as structured cases. Instead of reusing raw exemplar outputs, CAST extracts case-derived signals to identify complexity profiles for estimating optimal reasoning strategies, alongside failure profiles to map likely structural breakdowns. The framework translates this knowledge into a fine-grained reward design and adaptive reasoning, enabling the model to autonomously internalize case-based strategies during reinforcement learning. Experiments on BFCLv2 and ToolBench demonstrate that CAST improves both schema-faithful execution and task-level tool-use success while reducing unnecessary deliberation. The approach achieves up to 5.85 percentage points gain in overall execution accuracy and reduces average reasoning length by 26%, significantly mitigating high-impact structural errors. Ultimately, this demonstrates how historical execution cases can provide reusable adaptation knowledge for calibrated tool use.
format Preprint
id arxiv_https___arxiv_org_abs_2605_15041
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Case-Based Calibration of Adaptive Reasoning and Execution for LLM Tool Use
Pang, Renning
Lan, Tian
Liu, Leyuan
Tong, Piao
Cao, Sheng
Zhang, Xiaosong
Artificial Intelligence
Computation and Language
Tool use extends large language models beyond parametric knowledge, but reliable execution requires balancing appropriate reasoning depth with strict structural validity. We approach this problem from a case-based perspective to present CAST, a case-driven framework that treats historical execution trajectories as structured cases. Instead of reusing raw exemplar outputs, CAST extracts case-derived signals to identify complexity profiles for estimating optimal reasoning strategies, alongside failure profiles to map likely structural breakdowns. The framework translates this knowledge into a fine-grained reward design and adaptive reasoning, enabling the model to autonomously internalize case-based strategies during reinforcement learning. Experiments on BFCLv2 and ToolBench demonstrate that CAST improves both schema-faithful execution and task-level tool-use success while reducing unnecessary deliberation. The approach achieves up to 5.85 percentage points gain in overall execution accuracy and reduces average reasoning length by 26%, significantly mitigating high-impact structural errors. Ultimately, this demonstrates how historical execution cases can provide reusable adaptation knowledge for calibrated tool use.
title Case-Based Calibration of Adaptive Reasoning and Execution for LLM Tool Use
topic Artificial Intelligence
Computation and Language
url https://arxiv.org/abs/2605.15041