Runtime Environment for Conducting Methodical Applied Tests to Numerically Investigate of HPC Systems Parameters
https://doi.org/10.15514/ISPRAS-2024-36(5)-6
Abstract
An integral part of the process of creating high-performance computing systems designed to solve problems of numerical modeling of various physical processes is to check their compliance with the characteristics stated during their design. The article discusses a script-based runtime environment developed by the authors for using methodical applied tests to numerically investigate parameters of high-performance computing systems. This environment enables efficient analysis of the results of applying tests and provides an assessment of the performance and reliability of high-performance computing systems.
About the Authors
Alexey Olegovich IGNATYEV
Russian Federal Nuclear Center –
Zababakhin All-Russian Research Institute of Technical Physics
Russian Federation
Russian Federation
Head of the Laboratory of Russian Federal Nuclear Center E. I. Zababakhin «All-Russian Scientific Research Institute of Technical Physics» since 1998. Research interests: design of supercomputer systems, parallel numerical simulation programs development, operating systems development, methods and means of information security.
Sergey Yurievich MOKSHIN
Russian Federal Nuclear Center –
Zababakhin All-Russian Research Institute of Technical Physics
Russian Federation
Russian Federation
Head of the Department of Russian Federal Nuclear Center E. I. Zababakhin «All-Russian Scientific Research Institute of Technical Physics» since 2016. Research interests: design of supercomputer systems, development of functional subsystems for high performance supercomputing systems, operating systems development, methods and means for protecting information.
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Review
For citations:
IGNATYEV A.O., MOKSHIN S.Yu. Runtime Environment for Conducting Methodical Applied Tests to Numerically Investigate of HPC Systems Parameters. Proceedings of the Institute for System Programming of the RAS (Proceedings of ISP RAS). 2024;36(5):81-92. (In Russ.) https://doi.org/10.15514/ISPRAS-2024-36(5)-6
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