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Main Authors: Li, Ziwei, Niu, Shuzi, Li, Huiyuan, Yuan, Tao, Wu, Wenjia
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.17362
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author Li, Ziwei
Niu, Shuzi
Li, Huiyuan
Yuan, Tao
Wu, Wenjia
author_facet Li, Ziwei
Niu, Shuzi
Li, Huiyuan
Yuan, Tao
Wu, Wenjia
contents Matrix reordering in large sparse solvers seeks a permutation that minimizes factorization fill-in to reduce memory and computation. Because the minimum fill-in ordering problem is NP-complete and fill-in is implicit in the sparsity pattern, graph-theoretic heuristics are used. Existing reinforcement learning methods either ignore sparsity patterns--missing the global fill-in--or lack local exact fill-in feedback. We propose a graph policy optimization method, modeling fill-ins from global and local views: both the policy and value networks use a multi-hop graph neural backbone to embed global fill-in; the policy further interacts with symbolic factorization over graphs to extract local, step-level fill-ins, and the resulting feedback is aligned with the value network via an adaptive saturation function to improve convergence. On the SuiteSparse Matrix Collection, our method achieves mean reductions of 29.3 in fill-ins and 31.3 in peak memory usage over state-of-the-art baselines.
format Preprint
id arxiv_https___arxiv_org_abs_2605_17362
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Learning Fill-in Reduction Ordering via Graph Policy Optimization for Sparse Matrices
Li, Ziwei
Niu, Shuzi
Li, Huiyuan
Yuan, Tao
Wu, Wenjia
Machine Learning
Matrix reordering in large sparse solvers seeks a permutation that minimizes factorization fill-in to reduce memory and computation. Because the minimum fill-in ordering problem is NP-complete and fill-in is implicit in the sparsity pattern, graph-theoretic heuristics are used. Existing reinforcement learning methods either ignore sparsity patterns--missing the global fill-in--or lack local exact fill-in feedback. We propose a graph policy optimization method, modeling fill-ins from global and local views: both the policy and value networks use a multi-hop graph neural backbone to embed global fill-in; the policy further interacts with symbolic factorization over graphs to extract local, step-level fill-ins, and the resulting feedback is aligned with the value network via an adaptive saturation function to improve convergence. On the SuiteSparse Matrix Collection, our method achieves mean reductions of 29.3 in fill-ins and 31.3 in peak memory usage over state-of-the-art baselines.
title Learning Fill-in Reduction Ordering via Graph Policy Optimization for Sparse Matrices
topic Machine Learning
url https://arxiv.org/abs/2605.17362