Resiliency in Numerical Algorithm Design for Extreme Scale Simulations
Abstract
This work is based on the seminar titled ``Resiliency in Numerical Algorithm Design for Extreme Scale Simulations'' held March 1-6, 2020 at Schloss Dagstuhl, that was attended by all the authors. Naive versions of conventional resilience techniques will not scale to the exascale regime: with a main memory footprint of tens of Petabytes, synchronously writing checkpoint data all the way to background storage at frequent intervals will create intolerable overheads in runtime and energy consumption. Forecasts show that the mean time between failures could be lower than the time to recover from such a checkpoint, so that large calculations at scale might not make any progress if robust alternatives are not investigated. More advanced resilience techniques must be devised. The key may lie in exploiting both advanced system features as well as specific application knowledge. Research will face two essential questions: (1) what are the reliability requirements for a particular computation and (2) how do we best design the algorithms and software to meet these requirements? One avenue would be to refine and improve on system- or application-level checkpointing and rollback strategies in the case an error is detected. Developers might use fault notification interfaces and flexible runtime systems to respond to node failures in an application-dependent fashion. Novel numerical algorithms or more stochastic computational approaches may be required to meet accuracy requirements in the face of undetectable soft errors. The goal of this Dagstuhl Seminar was to bring together a diverse group of scientists with expertise in exascale computing to discuss novel ways to make applications resilient against detected and undetected faults. In particular, participants explored the role that algorithms and applications play in the holistic approach needed to tackle this challenge.
Keywords
Cite
@article{arxiv.2010.13342,
title = {Resiliency in Numerical Algorithm Design for Extreme Scale Simulations},
author = {Emmanuel Agullo and Mirco Altenbernd and Hartwig Anzt and Leonardo Bautista-Gomez and Tommaso Benacchio and Luca Bonaventura and Hans-Joachim Bungartz and Sanjay Chatterjee and Florina M. Ciorba and Nathan DeBardeleben and Daniel Drzisga and Sebastian Eibl and Christian Engelmann and Wilfried N. Gansterer and Luc Giraud and Dominik Goeddeke and Marco Heisig and Fabienne Jezequel and Nils Kohl and Xiaoye Sherry Li and Romain Lion and Miriam Mehl and Paul Mycek and Michael Obersteiner and Enrique S. Quintana-Orti and Francesco Rizzi and Ulrich Ruede and Martin Schulz and Fred Fung and Robert Speck and Linda Stals and Keita Teranishi and Samuel Thibault and Dominik Thoennes and Andreas Wagner and Barbara Wohlmuth},
journal= {arXiv preprint arXiv:2010.13342},
year = {2020}
}
Comments
45 pages, 3 figures, submitted to The International Journal of High Performance Computing Applications