Understanding performance variability in standard and pipelined parallel Krylov solvers

Hannah Morgan; Patrick Sanan; Matthew Knepley; Richard Tran Mills

doi:10.1177/1094342020966835

Understanding performance variability in standard and pipelined parallel Krylov solvers

Hannah Morgan
, Patrick Sanan
, Matthew Knepley
, Richard Tran Mills

Department of Computer Science and Engineering

Argonne National Laboratory
Swiss Federal Institute of Technology Zurich

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

In this work, we collect data from runs of Krylov subspace methods and pipelined Krylov algorithms in an effort to understand and model the impact of machine noise and other sources of variability on performance. We find large variability of Krylov iterations between compute nodes for standard methods that is reduced in pipelined algorithms, directly supporting conjecture, as well as large variation between statistical distributions of runtimes across iterations. Based on these results, we improve upon a previously introduced nondeterministic performance model by allowing iterations to fluctuate over time. We present our data from runs of various Krylov algorithms across multiple platforms as well as our updated non-stationary model that provides good agreement with observations. We also suggest how it can be used as a predictive tool.

Original language	English
Pages (from-to)	47-59
Number of pages	13
Journal	International Journal of High Performance Computing Applications
Volume	35
Issue number	1
DOIs	https://doi.org/10.1177/1094342020966835
State	Published - Jan 2021

Keywords

BiCGStab
GMRES
Krylov
PGMRES
noise
performance model
pipelining

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10.1177/1094342020966835

Cite this

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title = "Understanding performance variability in standard and pipelined parallel Krylov solvers",

abstract = "In this work, we collect data from runs of Krylov subspace methods and pipelined Krylov algorithms in an effort to understand and model the impact of machine noise and other sources of variability on performance. We find large variability of Krylov iterations between compute nodes for standard methods that is reduced in pipelined algorithms, directly supporting conjecture, as well as large variation between statistical distributions of runtimes across iterations. Based on these results, we improve upon a previously introduced nondeterministic performance model by allowing iterations to fluctuate over time. We present our data from runs of various Krylov algorithms across multiple platforms as well as our updated non-stationary model that provides good agreement with observations. We also suggest how it can be used as a predictive tool.",

keywords = "BiCGStab, GMRES, Krylov, PGMRES, noise, performance model, pipelining",

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AU - Morgan, Hannah

AU - Sanan, Patrick

AU - Knepley, Matthew

AU - Mills, Richard Tran

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N2 - In this work, we collect data from runs of Krylov subspace methods and pipelined Krylov algorithms in an effort to understand and model the impact of machine noise and other sources of variability on performance. We find large variability of Krylov iterations between compute nodes for standard methods that is reduced in pipelined algorithms, directly supporting conjecture, as well as large variation between statistical distributions of runtimes across iterations. Based on these results, we improve upon a previously introduced nondeterministic performance model by allowing iterations to fluctuate over time. We present our data from runs of various Krylov algorithms across multiple platforms as well as our updated non-stationary model that provides good agreement with observations. We also suggest how it can be used as a predictive tool.

AB - In this work, we collect data from runs of Krylov subspace methods and pipelined Krylov algorithms in an effort to understand and model the impact of machine noise and other sources of variability on performance. We find large variability of Krylov iterations between compute nodes for standard methods that is reduced in pipelined algorithms, directly supporting conjecture, as well as large variation between statistical distributions of runtimes across iterations. Based on these results, we improve upon a previously introduced nondeterministic performance model by allowing iterations to fluctuate over time. We present our data from runs of various Krylov algorithms across multiple platforms as well as our updated non-stationary model that provides good agreement with observations. We also suggest how it can be used as a predictive tool.

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KW - performance model

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Understanding performance variability in standard and pipelined parallel Krylov solvers

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Keywords

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