DesignX: Human-Competitive Algorithm Designer for Black-Box Optimization
Abstract
Designing effective black-box optimizers is hampered by limited problem-specific knowledge and manual control that spans months for almost every detail. In this paper, we present \textit{DesignX}, the first automated algorithm design framework that generates an effective optimizer specific to a given black-box optimization problem within seconds. Rooted in the first principles, we identify two key sub-tasks: 1) algorithm structure generation and 2) hyperparameter control. To enable systematic construction, a comprehensive modular algorithmic space is first built, embracing hundreds of algorithm components collected from decades of research. We then introduce a dual-agent reinforcement learning system that collaborates on structural and parametric design through a novel cooperative training objective, enabling large-scale meta-training across 10k diverse instances. Remarkably, through days of autonomous learning, the DesignX-generated optimizers continuously surpass human-crafted optimizers by orders of magnitude, either on synthetic testbed or on realistic optimization scenarios such as Protein-docking, AutoML and UAV path planning. Further in-depth analysis reveals DesignX's capability to discover non-trivial algorithm patterns beyond expert intuition, which, conversely, provides valuable design insights for the optimization community. We provide DesignX's Python project at~ https://github.com/MetaEvo/DesignX.
Keywords
Cite
@article{arxiv.2505.17866,
title = {DesignX: Human-Competitive Algorithm Designer for Black-Box Optimization},
author = {Hongshu Guo and Zeyuan Ma and Yining Ma and Xinglin Zhang and Wei-Neng Chen and Yue-Jiao Gong},
journal= {arXiv preprint arXiv:2505.17866},
year = {2025}
}
Comments
Accepted by NeurIPS 2025