English

SOLAR: A Highly Optimized Data Loading Framework for Distributed Training of CNN-based Scientific Surrogates

Distributed, Parallel, and Cluster Computing 2022-11-07 v2 Machine Learning

Abstract

CNN-based surrogates have become prevalent in scientific applications to replace conventional time-consuming physical approaches. Although these surrogates can yield satisfactory results with significantly lower computation costs over small training datasets, our benchmarking results show that data-loading overhead becomes the major performance bottleneck when training surrogates with large datasets. In practice, surrogates are usually trained with high-resolution scientific data, which can easily reach the terabyte scale. Several state-of-the-art data loaders are proposed to improve the loading throughput in general CNN training; however, they are sub-optimal when applied to the surrogate training. In this work, we propose SOLAR, a surrogate data loader, that can ultimately increase loading throughput during the training. It leverages our three key observations during the benchmarking and contains three novel designs. Specifically, SOLAR first generates a pre-determined shuffled index list and accordingly optimizes the global access order and the buffer eviction scheme to maximize the data reuse and the buffer hit rate. It then proposes a tradeoff between lightweight computational imbalance and heavyweight loading workload imbalance to speed up the overall training. It finally optimizes its data access pattern with HDF5 to achieve a better parallel I/O throughput. Our evaluation with three scientific surrogates and 32 GPUs illustrates that SOLAR can achieve up to 24.4X speedup over PyTorch Data Loader and 3.52X speedup over state-of-the-art data loaders.

Keywords

Cite

@article{arxiv.2211.00224,
  title  = {SOLAR: A Highly Optimized Data Loading Framework for Distributed Training of CNN-based Scientific Surrogates},
  author = {Baixi Sun and Xiaodong Yu and Chengming Zhang and Jiannan Tian and Sian Jin and Kamil Iskra and Tao Zhou and Tekin Bicer and Pete Beckman and Dingwen Tao},
  journal= {arXiv preprint arXiv:2211.00224},
  year   = {2022}
}

Comments

14 pages, 15 figures, 5 tables, submitted to VLDB '23

R2 v1 2026-06-28T04:54:07.174Z