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Main Authors: Wang, Xiaokai, Huang, Shaoyuan, Li, Yuting, Wang, Xiaofei
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.04162
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author Wang, Xiaokai
Huang, Shaoyuan
Li, Yuting
Wang, Xiaofei
author_facet Wang, Xiaokai
Huang, Shaoyuan
Li, Yuting
Wang, Xiaofei
contents Deep neural networks (DNNs) form the cornerstone of modern AI services, supporting a wide range of applications, including autonomous driving, chatbots, and recommendation systems. As models increase in size and complexity, DNN workloads such as training and inference tasks impose unprecedented demands on distributed computing resources, making accurate runtime prediction essential for optimizing development and resource allocation. Traditional methods rely on additive computational unit models, limiting their accuracy and generalizability. In contrast, graph-enhanced modeling improves performance but significantly increases data collection costs. Therefore, there is a critical need for a method that strikes a balance between accuracy, generalizability, and data collection costs. To address these challenges, we propose ScaleDL, a novel runtime prediction framework that combines nonlinear layer-wise modeling with graph neural network (GNN)-based cross-layer interaction mechanism, enabling accurate DNN runtime prediction and hierarchical generalizability across different network architectures. Additionally, we employ the D-optimal method to reduce data collection costs. Experiments on the workloads of five popular DNN models demonstrate that ScaleDL enhances runtime prediction accuracy and generalizability, achieving 6 times lower MRE and 5 times lower RMSE compared to baseline models.
format Preprint
id arxiv_https___arxiv_org_abs_2511_04162
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle ScaleDL: Towards Scalable and Efficient Runtime Prediction for Distributed Deep Learning Workloads
Wang, Xiaokai
Huang, Shaoyuan
Li, Yuting
Wang, Xiaofei
Machine Learning
Deep neural networks (DNNs) form the cornerstone of modern AI services, supporting a wide range of applications, including autonomous driving, chatbots, and recommendation systems. As models increase in size and complexity, DNN workloads such as training and inference tasks impose unprecedented demands on distributed computing resources, making accurate runtime prediction essential for optimizing development and resource allocation. Traditional methods rely on additive computational unit models, limiting their accuracy and generalizability. In contrast, graph-enhanced modeling improves performance but significantly increases data collection costs. Therefore, there is a critical need for a method that strikes a balance between accuracy, generalizability, and data collection costs. To address these challenges, we propose ScaleDL, a novel runtime prediction framework that combines nonlinear layer-wise modeling with graph neural network (GNN)-based cross-layer interaction mechanism, enabling accurate DNN runtime prediction and hierarchical generalizability across different network architectures. Additionally, we employ the D-optimal method to reduce data collection costs. Experiments on the workloads of five popular DNN models demonstrate that ScaleDL enhances runtime prediction accuracy and generalizability, achieving 6 times lower MRE and 5 times lower RMSE compared to baseline models.
title ScaleDL: Towards Scalable and Efficient Runtime Prediction for Distributed Deep Learning Workloads
topic Machine Learning
url https://arxiv.org/abs/2511.04162