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Multi-Partner Project: Multi-GPU Performance Portability Analysis for CFD Simulations at Scale

Distributed, Parallel, and Cluster Computing 2026-01-21 v1 Hardware Architecture

Abstract

As heterogeneous supercomputing architectures leveraging GPUs become increasingly central to high-performance computing (HPC), it is crucial for computational fluid dynamics (CFD) simulations, a de-facto HPC workload, to efficiently utilize such hardware. One of the key challenges of HPC codes is performance portability, i.e. the ability to maintain near-optimal performance across different accelerators. In the context of the \textbf{REFMAP} project, which targets scalable, GPU-enabled multi-fidelity CFD for urban airflow prediction, this paper analyzes the performance portability of SOD2D, a state-of-the-art Spectral Elements simulation framework across AMD and NVIDIA GPU architectures. We first discuss the physical and numerical models underlying SOD2D, highlighting its computational hotspots. Then, we examine its performance and scalability in a multi-level manner, i.e. defining and characterizing an extensive full-stack design space spanning across application, software and hardware infrastructure related parameters. Single-GPU performance characterization across server-grade NVIDIA and AMD GPU architectures and vendor-specific compiler stacks, show the potential as well as the diverse effect of memory access optimizations, i.e. 0.69×\times - 3.91×\times deviations in acceleration speedup. Performance variability of SOD2D at scale is further examined on the LUMI multi-GPU cluster, where profiling reveals similar throughput variations, highlighting the limits of performance projections and the need for multi-level, informed tuning.

Keywords

Cite

@article{arxiv.2601.14159,
  title  = {Multi-Partner Project: Multi-GPU Performance Portability Analysis for CFD Simulations at Scale},
  author = {Panagiotis-Eleftherios Eleftherakis and George Anagnostopoulos and Anastassis Kapetanakis and Mohammad Umair and Jean-Yves Vet and Konstantinos Iliakis and Jonathan Vincent and Jing Gong and Akshay Patil and Clara García-Sánchez and Gerardo Zampino and Ricardo Vinuesa and Sotirios Xydis},
  journal= {arXiv preprint arXiv:2601.14159},
  year   = {2026}
}

Comments

DATE 26 conference Multi-Partner Project Paper

R2 v1 2026-07-01T09:12:46.273Z