Saved in:
Bibliographic Details
Main Authors: Gui, Shuangchun, Liu, Suyu, Wang, Xuehe, Cao, Zhiguang
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.01667
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866908860208381952
author Gui, Shuangchun
Liu, Suyu
Wang, Xuehe
Cao, Zhiguang
author_facet Gui, Shuangchun
Liu, Suyu
Wang, Xuehe
Cao, Zhiguang
contents Multi-task Vehicle Routing Problems (VRPs) aim to minimize routing costs while satisfying diverse constraints. Existing solvers typically adopt a unified reinforcement learning (RL) framework to learn generalizable patterns across tasks. However, they often overlook the constraint and node dynamics during the decision process, making the model fail to accurately react to the current context. To address this limitation, we propose Chain-of-Context Learning (CCL), a novel framework that progressively captures the evolving context to guide fine-grained node adaptation. Specifically, CCL constructs step-wise contextual information via a Relevance-Guided Context Reformulation (RGCR) module, which adaptively prioritizes salient constraints. This context then guides node updates through a Trajectory-Shared Node Re-embedding (TSNR) module, which aggregates shared node features from all trajectories' contexts and uses them to update inputs for the next step. By modeling evolving preferences of the RL agent, CCL captures step-by-step dependencies in sequential decision-making. We evaluate CCL on 48 diverse VRP variants, including 16 in-distribution and 32 out-of-distribution (with unseen constraints) tasks. Experimental results show that CCL performs favorably against the state-of-the-art baselines, achieving the best performance on all in-distribution tasks and the majority of out-of-distribution tasks.
format Preprint
id arxiv_https___arxiv_org_abs_2603_01667
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Chain-of-Context Learning: Dynamic Constraint Understanding for Multi-Task VRPs
Gui, Shuangchun
Liu, Suyu
Wang, Xuehe
Cao, Zhiguang
Artificial Intelligence
Multi-task Vehicle Routing Problems (VRPs) aim to minimize routing costs while satisfying diverse constraints. Existing solvers typically adopt a unified reinforcement learning (RL) framework to learn generalizable patterns across tasks. However, they often overlook the constraint and node dynamics during the decision process, making the model fail to accurately react to the current context. To address this limitation, we propose Chain-of-Context Learning (CCL), a novel framework that progressively captures the evolving context to guide fine-grained node adaptation. Specifically, CCL constructs step-wise contextual information via a Relevance-Guided Context Reformulation (RGCR) module, which adaptively prioritizes salient constraints. This context then guides node updates through a Trajectory-Shared Node Re-embedding (TSNR) module, which aggregates shared node features from all trajectories' contexts and uses them to update inputs for the next step. By modeling evolving preferences of the RL agent, CCL captures step-by-step dependencies in sequential decision-making. We evaluate CCL on 48 diverse VRP variants, including 16 in-distribution and 32 out-of-distribution (with unseen constraints) tasks. Experimental results show that CCL performs favorably against the state-of-the-art baselines, achieving the best performance on all in-distribution tasks and the majority of out-of-distribution tasks.
title Chain-of-Context Learning: Dynamic Constraint Understanding for Multi-Task VRPs
topic Artificial Intelligence
url https://arxiv.org/abs/2603.01667