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Main Authors: Witzke, Joel, Lößer, Ansgar, Bountris, Vasilis, Schintke, Florian, Scheuermann, Björn
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.00411
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author Witzke, Joel
Lößer, Ansgar
Bountris, Vasilis
Schintke, Florian
Scheuermann, Björn
author_facet Witzke, Joel
Lößer, Ansgar
Bountris, Vasilis
Schintke, Florian
Scheuermann, Björn
contents While detailed resource usage monitoring is possible on the low-level using proper tools, associating such usage with higher-level abstractions in the application layer that actually cause the resource usage in the first place presents a number of challenges. Suppose a large-scale scientific data analysis workflow is run using a distributed execution environment such as a compute cluster or cloud environment and we want to analyze the I/O behaviour of it to find and alleviate potential bottlenecks. Different tasks of the workflow can be assigned to arbitrary compute nodes and may even share the same compute nodes. Thus, locally observed resource usage is not directly associated with the individual workflow tasks. By acquiring resource usage profiles of the involved nodes, we seek to correlate the trace data to the workflow and its individual tasks. To accomplish that, we select the proper set of metadata associated with low-level traces that let us associate them with higher-level task information obtained from log files of the workflow execution as well as the job management using a task orchestrator such as Kubernetes with its container management. Ensuring a proper information chain allows the classification of observed I/O on a logical task level and may reveal the most costly or inefficient tasks of a scientific workflow that are most promising for optimization.
format Preprint
id arxiv_https___arxiv_org_abs_2408_00411
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Low-level I/O Monitoring for Scientific Workflows
Witzke, Joel
Lößer, Ansgar
Bountris, Vasilis
Schintke, Florian
Scheuermann, Björn
Distributed, Parallel, and Cluster Computing
While detailed resource usage monitoring is possible on the low-level using proper tools, associating such usage with higher-level abstractions in the application layer that actually cause the resource usage in the first place presents a number of challenges. Suppose a large-scale scientific data analysis workflow is run using a distributed execution environment such as a compute cluster or cloud environment and we want to analyze the I/O behaviour of it to find and alleviate potential bottlenecks. Different tasks of the workflow can be assigned to arbitrary compute nodes and may even share the same compute nodes. Thus, locally observed resource usage is not directly associated with the individual workflow tasks. By acquiring resource usage profiles of the involved nodes, we seek to correlate the trace data to the workflow and its individual tasks. To accomplish that, we select the proper set of metadata associated with low-level traces that let us associate them with higher-level task information obtained from log files of the workflow execution as well as the job management using a task orchestrator such as Kubernetes with its container management. Ensuring a proper information chain allows the classification of observed I/O on a logical task level and may reveal the most costly or inefficient tasks of a scientific workflow that are most promising for optimization.
title Low-level I/O Monitoring for Scientific Workflows
topic Distributed, Parallel, and Cluster Computing
url https://arxiv.org/abs/2408.00411