Workflow-Driven Modeling for the Compute Continuum: An Optimization Approach to Automated System and Workload Scheduling
Abstract
The convergence of IoT, Edge, Cloud, and HPC technologies creates a compute continuum that merges cloud scalability and flexibility with HPC's computational power and specialized optimizations. However, integrating cloud and HPC resources often introduces latency and communication overhead, which can hinder the performance of tightly coupled parallel applications. Additionally, achieving seamless interoperability between cloud and on-premises HPC systems requires advanced scheduling, resource management, and data transfer protocols. Consequently, users must manually allocate complex workloads across heterogeneous resources, leading to suboptimal task placement and reduced efficiency due to the absence of an automated scheduling mechanism. To overcome these challenges, we introduce a comprehensive framework based on rigorous system and workload modeling for the compute continuum. Our method employs established tools and techniques to optimize workload mapping and scheduling, enabling the automatic orchestration of tasks across both cloud and HPC infrastructures. Experimental evaluations reveal that our approach could optimally improve scheduling efficiency, reducing execution times, and enhancing resource utilization. Specifically, our MILP-based solution achieves optimal scheduling and makespan for small-scale workflows, while heuristic methods offer up to 99% faster estimations for large-scale workflows, albeit with a 5-10% deviation from optimal results. Our primary contribution is a robust system and workload modeling framework that addresses critical gaps in existing tools, paving the way for fully automated orchestration in HPC-compute continuum environments.
Keywords
Cite
@article{arxiv.2505.12184,
title = {Workflow-Driven Modeling for the Compute Continuum: An Optimization Approach to Automated System and Workload Scheduling},
author = {Aasish Kumar Sharma and Christian Boehme and Patrick Gelß and Ramin Yahyapour and Julian Kunkel},
journal= {arXiv preprint arXiv:2505.12184},
year = {2025}
}
Comments
The paper is accepted in "13th IEEE International Workshop on Modeling and Verifying Distributed-Embedded Applications (MVDA 2025)" under main conference symposia of the "IEEE Computers, Software, and Applications Conference (COMPSAC 2025)" on May 6 2025, with Paper ID: 3418