PyPOD-GP: Using PyTorch for accelerated chip-level thermal simulation of the GPU

IF 2.4 4区计算机科学 Q2 COMPUTER SCIENCE, SOFTWARE ENGINEERING

SoftwareX Pub Date : 2025-04-11 DOI:10.1016/j.softx.2025.102147

Neil He , Ming-Cheng Cheng , Yu Liu

引用次数: 0

Abstract

The rising demand for high-performance computing (HPC) has made full-chip dynamic thermal simulation in many-core GPUs critical for optimizing performance and extending device lifespans. Proper orthogonal decomposition (POD) with Galerkin projection (GP) has shown to offer high accuracy and massive runtime improvements over direct numerical simulation (DNS). However, previous implementations of POD-GP use MPI-based libraries like PETSc and FEniCS and face significant runtime bottlenecks. We propose a PyTorch-based POD-GP library (PyPOD-GP), a GPU-optimized library for chip-level thermal simulation. PyPOD-GP achieves over

23.4 \times

speedup in training and over

10 \times

speedup in inference on a GPU with over 13,000 cores, with just 1.2% error over the device layer.

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PyPOD-GP：使用 PyTorch 加速 GPU 芯片级热仿真

高性能计算（HPC）的需求日益增长，使得多核gpu的全芯片动态热模拟对于优化性能和延长设备寿命至关重要。与直接数值模拟（DNS）相比，具有Galerkin投影（GP）的适当正交分解（POD）具有更高的精度和大量的运行时间改进。然而，先前的POD-GP实现使用基于mpi的库，如PETSc和fenic，并且面临严重的运行时瓶颈。我们提出了一个基于pytorch的POD-GP库（PyPOD-GP），一个gpu优化的芯片级热模拟库。PyPOD-GP在超过13,000核的GPU上实现了超过23.4倍的训练加速和超过10倍的推理加速，在设备层上只有1.2%的误差。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

SoftwareX COMPUTER SCIENCE, SOFTWARE ENGINEERING-

CiteScore

5.50

自引率

2.90%

发文量

184

审稿时长

9 weeks

期刊介绍： SoftwareX aims to acknowledge the impact of software on today''s research practice, and on new scientific discoveries in almost all research domains. SoftwareX also aims to stress the importance of the software developers who are, in part, responsible for this impact. To this end, SoftwareX aims to support publication of research software in such a way that: The software is given a stamp of scientific relevance, and provided with a peer-reviewed recognition of scientific impact; The software developers are given the credits they deserve; The software is citable, allowing traditional metrics of scientific excellence to apply; The academic career paths of software developers are supported rather than hindered; The software is publicly available for inspection, validation, and re-use. Above all, SoftwareX aims to inform researchers about software applications, tools and libraries with a (proven) potential to impact the process of scientific discovery in various domains. The journal is multidisciplinary and accepts submissions from within and across subject domains such as those represented within the broad thematic areas below: Mathematical and Physical Sciences; Environmental Sciences; Medical and Biological Sciences; Humanities, Arts and Social Sciences. Originating from these broad thematic areas, the journal also welcomes submissions of software that works in cross cutting thematic areas, such as citizen science, cybersecurity, digital economy, energy, global resource stewardship, health and wellbeing, etcetera. SoftwareX specifically aims to accept submissions representing domain-independent software that may impact more than one research domain.