Improving scalability of Earth system models through coarse-grained component concurrency – a case study with the ICON v2.6.5 modelling system

In the era of exascale computing, machines with unprecedented computing power are available. Making efficient use of these massively parallel machines, with millions of cores, presents a new challenge. Multi-level and multi-dimensional parallelism will be needed to meet this challenge. Coarse-graine...

Full description

Bibliographic Details
Published in:Geoscientific Model Development
Main Authors: Linardakis, Leonidas, Stemmler, Irene, Hanke, Moritz, Ramme, Lennart, Chegini, Fatemeh, Ilyina, Tatiana, Korn, Peter
Format: Text
Language:English
Published: 2022
Subjects:
Ice Sheet
Online Access:https://doi.org/10.5194/gmd-15-9157-2022
https://gmd.copernicus.org/articles/15/9157/2022/
id ftcopernicus:oai:publications.copernicus.org:gmd106087
record_format openpolar
spelling ftcopernicus:oai:publications.copernicus.org:gmd106087 2023-05-15T16:41:18+02:00 Improving scalability of Earth system models through coarse-grained component concurrency – a case study with the ICON v2.6.5 modelling system Linardakis, Leonidas Stemmler, Irene Hanke, Moritz Ramme, Lennart Chegini, Fatemeh Ilyina, Tatiana Korn, Peter 2022-12-21 application/pdf https://doi.org/10.5194/gmd-15-9157-2022 https://gmd.copernicus.org/articles/15/9157/2022/ eng eng doi:10.5194/gmd-15-9157-2022 https://gmd.copernicus.org/articles/15/9157/2022/ eISSN: 1991-9603 Text 2022 ftcopernicus https://doi.org/10.5194/gmd-15-9157-2022 2022-12-26T17:22:42Z In the era of exascale computing, machines with unprecedented computing power are available. Making efficient use of these massively parallel machines, with millions of cores, presents a new challenge. Multi-level and multi-dimensional parallelism will be needed to meet this challenge. Coarse-grained component concurrency provides an additional parallelism dimension that complements typically used parallelization methods such as domain decomposition and loop-level shared-memory approaches. While these parallelization methods are data-parallel techniques, and they decompose the data space, component concurrency is a function-parallel technique, and it decomposes the algorithmic space. This additional dimension of parallelism allows us to extend scalability beyond the limits set by established parallelization techniques. It also offers a way to maintain performance (by using more compute power) when the model complexity is increased by adding components, such as biogeochemistry or ice sheet models. Furthermore, concurrency allows each component to run on different hardware, thus leveraging the usage of heterogeneous hardware configurations. In this work we study the characteristics of component concurrency and analyse its behaviour in a general context. The analysis shows that component concurrency increases the “parallel workload”, improving the scalability under certain conditions. These generic considerations are complemented by an analysis of a specific case, namely the coarse-grained concurrency in the multi-level parallelism context of two components of the ICON modelling system: the ICON ocean model ICON-O and the marine biogeochemistry model HAMOCC. The additional computational cost incurred by the biogeochemistry module is about 3 times that of the ICON-O ocean stand alone model, and data parallelization techniques (domain decomposition and loop-level shared-memory parallelization) present a scaling limit that impedes the computational performance of the combined ICON-O–HAMOCC model. Scaling experiments, ... Text Ice Sheet Copernicus Publications: E-Journals Geoscientific Model Development 15 24 9157 9176
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description In the era of exascale computing, machines with unprecedented computing power are available. Making efficient use of these massively parallel machines, with millions of cores, presents a new challenge. Multi-level and multi-dimensional parallelism will be needed to meet this challenge. Coarse-grained component concurrency provides an additional parallelism dimension that complements typically used parallelization methods such as domain decomposition and loop-level shared-memory approaches. While these parallelization methods are data-parallel techniques, and they decompose the data space, component concurrency is a function-parallel technique, and it decomposes the algorithmic space. This additional dimension of parallelism allows us to extend scalability beyond the limits set by established parallelization techniques. It also offers a way to maintain performance (by using more compute power) when the model complexity is increased by adding components, such as biogeochemistry or ice sheet models. Furthermore, concurrency allows each component to run on different hardware, thus leveraging the usage of heterogeneous hardware configurations. In this work we study the characteristics of component concurrency and analyse its behaviour in a general context. The analysis shows that component concurrency increases the “parallel workload”, improving the scalability under certain conditions. These generic considerations are complemented by an analysis of a specific case, namely the coarse-grained concurrency in the multi-level parallelism context of two components of the ICON modelling system: the ICON ocean model ICON-O and the marine biogeochemistry model HAMOCC. The additional computational cost incurred by the biogeochemistry module is about 3 times that of the ICON-O ocean stand alone model, and data parallelization techniques (domain decomposition and loop-level shared-memory parallelization) present a scaling limit that impedes the computational performance of the combined ICON-O–HAMOCC model. Scaling experiments, ...
format Text
author Linardakis, Leonidas
Stemmler, Irene
Hanke, Moritz
Ramme, Lennart
Chegini, Fatemeh
Ilyina, Tatiana
Korn, Peter
spellingShingle Linardakis, Leonidas
Stemmler, Irene
Hanke, Moritz
Ramme, Lennart
Chegini, Fatemeh
Ilyina, Tatiana
Korn, Peter
Improving scalability of Earth system models through coarse-grained component concurrency – a case study with the ICON v2.6.5 modelling system
author_facet Linardakis, Leonidas
Stemmler, Irene
Hanke, Moritz
Ramme, Lennart
Chegini, Fatemeh
Ilyina, Tatiana
Korn, Peter
author_sort Linardakis, Leonidas
title Improving scalability of Earth system models through coarse-grained component concurrency – a case study with the ICON v2.6.5 modelling system
title_short Improving scalability of Earth system models through coarse-grained component concurrency – a case study with the ICON v2.6.5 modelling system
title_full Improving scalability of Earth system models through coarse-grained component concurrency – a case study with the ICON v2.6.5 modelling system
title_fullStr Improving scalability of Earth system models through coarse-grained component concurrency – a case study with the ICON v2.6.5 modelling system
title_full_unstemmed Improving scalability of Earth system models through coarse-grained component concurrency – a case study with the ICON v2.6.5 modelling system
title_sort improving scalability of earth system models through coarse-grained component concurrency – a case study with the icon v2.6.5 modelling system
publishDate 2022
url https://doi.org/10.5194/gmd-15-9157-2022
https://gmd.copernicus.org/articles/15/9157/2022/
genre Ice Sheet
genre_facet Ice Sheet
op_source eISSN: 1991-9603
op_relation doi:10.5194/gmd-15-9157-2022
https://gmd.copernicus.org/articles/15/9157/2022/
op_doi https://doi.org/10.5194/gmd-15-9157-2022
container_title Geoscientific Model Development
container_volume 15
container_issue 24
container_start_page 9157
op_container_end_page 9176
_version_ 1766031741110190080

Similar Items