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Main Authors: Cheng, Mingyue, Yu, Shuo, Jiang, Chuang, Tao, Xiaoyu, Mao, Qingyang, Ouyang, Jie, Liu, Qi, Chen, Enhong
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.07528
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author Cheng, Mingyue
Yu, Shuo
Jiang, Chuang
Tao, Xiaoyu
Mao, Qingyang
Ouyang, Jie
Liu, Qi
Chen, Enhong
author_facet Cheng, Mingyue
Yu, Shuo
Jiang, Chuang
Tao, Xiaoyu
Mao, Qingyang
Ouyang, Jie
Liu, Qi
Chen, Enhong
contents Table reasoning requires models to jointly perform semantic understanding and precise numerical operations. Most existing methods rely on a single-turn reasoning paradigm over tables which suffers from context overflow and weak numerical sensitivity. To address these limitations, we previously proposed TableMind as a tuning-based autonomous programmatic agent that simulates human-like interaction within a lightweight large language model (LLM). TableMind internalizes planning, action, and reflection through a two-stage training strategy involving supervised fine-tuning (SFT) on filtered high-quality data and reinforcement learning (RL) via a multi-perspective reward and the Rank-Aware Policy Optimization (RAPO) algorithm. While TableMind establishes a solid foundation for programmatic agents, the inherent stochasticity of LLMs remains a critical challenge that leads to hallucinations. In this paper, we extend this foundation to TableMind++ by introducing a novel uncertainty-aware inference framework to mitigate hallucinations. Specifically, we propose memory-guided plan pruning to retrieve historical trajectories for validating and filtering out logically flawed plans to address epistemic uncertainty. To ensure execution precision, we introduce confidence-based action refinement which monitors token-level probabilities to detect and self-correct syntactic noise for aleatoric uncertainty mitigation. Finally, we employ dual-weighted trajectory aggregation to synthesize a robust consensus from multiple reasoning paths. Extensive experiments on diverse benchmarks demonstrate that TableMind++ consistently outperforms previous baselines and proprietary models to validate the effectiveness of integrating autonomous training with uncertainty quantification. Our code is available.
format Preprint
id arxiv_https___arxiv_org_abs_2603_07528
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle TableMind++: An Uncertainty-Aware Programmatic Agent for Tool-Augmented Table Reasoning
Cheng, Mingyue
Yu, Shuo
Jiang, Chuang
Tao, Xiaoyu
Mao, Qingyang
Ouyang, Jie
Liu, Qi
Chen, Enhong
Computation and Language
Table reasoning requires models to jointly perform semantic understanding and precise numerical operations. Most existing methods rely on a single-turn reasoning paradigm over tables which suffers from context overflow and weak numerical sensitivity. To address these limitations, we previously proposed TableMind as a tuning-based autonomous programmatic agent that simulates human-like interaction within a lightweight large language model (LLM). TableMind internalizes planning, action, and reflection through a two-stage training strategy involving supervised fine-tuning (SFT) on filtered high-quality data and reinforcement learning (RL) via a multi-perspective reward and the Rank-Aware Policy Optimization (RAPO) algorithm. While TableMind establishes a solid foundation for programmatic agents, the inherent stochasticity of LLMs remains a critical challenge that leads to hallucinations. In this paper, we extend this foundation to TableMind++ by introducing a novel uncertainty-aware inference framework to mitigate hallucinations. Specifically, we propose memory-guided plan pruning to retrieve historical trajectories for validating and filtering out logically flawed plans to address epistemic uncertainty. To ensure execution precision, we introduce confidence-based action refinement which monitors token-level probabilities to detect and self-correct syntactic noise for aleatoric uncertainty mitigation. Finally, we employ dual-weighted trajectory aggregation to synthesize a robust consensus from multiple reasoning paths. Extensive experiments on diverse benchmarks demonstrate that TableMind++ consistently outperforms previous baselines and proprietary models to validate the effectiveness of integrating autonomous training with uncertainty quantification. Our code is available.
title TableMind++: An Uncertainty-Aware Programmatic Agent for Tool-Augmented Table Reasoning
topic Computation and Language
url https://arxiv.org/abs/2603.07528