English

Toward Robust and Efficient ML-Based GPU Caching for Modern Inference

Machine Learning 2026-04-27 v2

Abstract

In modern GPU inference, cache efficiency remains a major bottleneck, and heuristic policies such as \textsc{LRU} can perform far worse than the offline optimum. Existing learning-based caching systems improve hit rates mainly through predictor design, but often follow learned predictions blindly, making performance unreliable when predictions are inaccurate. In contrast, emerging learning-augmented caching algorithms~\cite{pmlr-v80-lykouris18a,mitzenmacher2022algorithms} provide performance guarantees by carefully integrating predictions into caching policies, achieving both \emph{consistency} (near-optimality under perfect predictions) and \emph{robustness} (bounded worst-case performance under prediction errors). However, deployment remains challenging. A practical algorithm should satisfy strict time and space efficiency constraints, which some theoretical work overlooks, while also incurring low deployment overhead. We propose learning-augmented LRU, a deployment-oriented learning-augmented caching algorithm that guarantees \emph{1-consistency} and \emph{O(k)O(k)-robustness}, incurs low time and space overhead, and maintains strong compatibility. We further build a GPU cache, called \textsc{LCR}, on top of learning-augmented LRU to benefit from its theoretical guarantees and translate them into practical performance. In experiments, \textsc{LCR} reduces P99 time-to-first-token (TTFT) by up to 28.3\% on LLM workloads and increases throughput by up to 24.2\% on deep learning recommendation (DLRM) workloads. Even with poor predictions, performance degrades gracefully and remains close to \textsc{LRU}, demonstrating robustness with practical value.

Keywords

Cite

@article{arxiv.2509.20979,
  title  = {Toward Robust and Efficient ML-Based GPU Caching for Modern Inference},
  author = {Peng Chen and Jiaji Zhang and Hailiang Zhao and Yirong Zhang and Shenyao Chen and Jiahong Yu and Xueyan Tang and Yixuan Wang and Hao Li and Jianping Zou and Gang Xiong and Kingsum Chow and Shuibing He and Shuiguang Deng},
  journal= {arXiv preprint arXiv:2509.20979},
  year   = {2026}
}
R2 v1 2026-07-01T05:55:48.416Z