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Main Authors: Machado, David, González-García, Jonathan, Mulet, Roberto
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.06757
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author Machado, David
González-García, Jonathan
Mulet, Roberto
author_facet Machado, David
González-García, Jonathan
Mulet, Roberto
contents Despite significant advances in characterizing the highly nonconvex landscapes of constraint satisfaction problems, the good performance of certain algorithms in solving hard combinatorial optimization tasks remains poorly understood. This gap in understanding stems largely from the lack of theoretical tools for analyzing their out-of-equilibrium dynamics. To address this challenge, we develop a system of approximate master equations that capture the behavior of local search algorithms in constraint satisfaction problems. Our framework shows excellent qualitative agreement with the phase diagrams of two paradigmatic algorithms: Focused Metropolis Search (FMS) and greedy-WalkSAT (G-WalkSAT) for random 3-SAT. The equations not only confirm the numerical observation that G-WalkSAT's algorithmic threshold is nearly parameter-independent, but also successfully predict FMS's threshold beyond the clustering transition. We also exploit these equations in a decimation scheme, demonstrating that the computed marginals encode valuable information about the local structure of the solution space explored by stochastic algorithms. Notably, our decimation approach achieves a threshold that surpasses the clustering transition, outperforming conventional methods like Belief Propagation-guided decimation. These results challenge the prevailing assumption that long-range correlations are always necessary to describe efficient local search dynamics and open a new path to designing efficient algorithms to solve combinatorial optimization problems.
format Preprint
id arxiv_https___arxiv_org_abs_2504_06757
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Local equations describe unreasonably efficient stochastic algorithms in random K-SAT
Machado, David
González-García, Jonathan
Mulet, Roberto
Disordered Systems and Neural Networks
Despite significant advances in characterizing the highly nonconvex landscapes of constraint satisfaction problems, the good performance of certain algorithms in solving hard combinatorial optimization tasks remains poorly understood. This gap in understanding stems largely from the lack of theoretical tools for analyzing their out-of-equilibrium dynamics. To address this challenge, we develop a system of approximate master equations that capture the behavior of local search algorithms in constraint satisfaction problems. Our framework shows excellent qualitative agreement with the phase diagrams of two paradigmatic algorithms: Focused Metropolis Search (FMS) and greedy-WalkSAT (G-WalkSAT) for random 3-SAT. The equations not only confirm the numerical observation that G-WalkSAT's algorithmic threshold is nearly parameter-independent, but also successfully predict FMS's threshold beyond the clustering transition. We also exploit these equations in a decimation scheme, demonstrating that the computed marginals encode valuable information about the local structure of the solution space explored by stochastic algorithms. Notably, our decimation approach achieves a threshold that surpasses the clustering transition, outperforming conventional methods like Belief Propagation-guided decimation. These results challenge the prevailing assumption that long-range correlations are always necessary to describe efficient local search dynamics and open a new path to designing efficient algorithms to solve combinatorial optimization problems.
title Local equations describe unreasonably efficient stochastic algorithms in random K-SAT
topic Disordered Systems and Neural Networks
url https://arxiv.org/abs/2504.06757