Fully-Asynchronous Cache-Efficient Simulation of Detailed Neural Networks (Magalhaes et al 2019)

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"Modern asynchronous runtime systems allow the re-thinking of large-scale scientific applications. With the example of a simulator of morphologically detailed neural networks, we show how detaching from the commonly used bulk-synchronous parallel (BSP) execution allows for the increase of prefetching capabilities, better cache locality, and a overlap of computation and communication, consequently leading to a lower time to solution. Our strategy removes the operation of collective synchronization of ODEs’ coupling information, and takes advantage of the pairwise time dependency between equations, leading to a fully-asynchronous exhaustive yet not speculative stepping model. Combined with fully linear data structures, communication reduce at compute node level, and an earliest equation steps first scheduler, we perform an acceleration at the cache level that reduces communication and time to solution by maximizing the number of timesteps taken per neuron at each iteration. Our methods were implemented on the core kernel of the NEURON scientific application. Asynchronicity and distributed memory space are provided by the HPX runtime system for the ParalleX execution model. Benchmark results demonstrate a superlinear speed-up that leads to a reduced runtime compared to the bulk synchronous execution, yielding a speed-up between 25% to 65% across different compute architectures, and in the order of 15% to 40% for distributed executions."
1 . Magalhães BR, Sterling T, Hines M, Schürmann F (2019) Fully-Asynchronous Cache-Efficient Simulation of Detailed Neural Networks Computational Science -- ICCS 2019, Rodrigues, João M. F. and Cardoso, Pedro J. S. and Monteiro, Jânio and Lam, Roberto and Krzhizhanovskaya, Valeria V. and Lees, Michael H. and Dongarra, Jack J. and Sloot, Peter M.A., ed. pp.421
2 . Magalhães BRC, Sterling T, Hines M, Schürmann F (2019) Asynchronous Branch-Parallel Simulation of Detailed Neuron Models. Front Neuroinform 13:54 [PubMed]
3 . Magalhães B, Hines M, Sterling T, Schüermann F (2019) Exploiting Flow Graph of System of ODEs to Accelerate the Simulation of Biologically-Detailed Neural Networks 2019 IEEE International Parallel and Distributed Processing Symposium (IPDPS) :176-187
4 . Magalhães B, Hines M, Sterling T, Schuermann F (2020) Fully-Asynchronous Fully-Implicit Variable-Order Variable-Timestep Simulation of Neural Networks INTERNATIONAL CONFERENCE ON COMPUTATIONAL SCIENCE (ICCS), accepted
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Model Information (Click on a link to find other models with that property)
Model Type: Realistic Network;
Brain Region(s)/Organism:
Cell Type(s):
Gap Junctions:
Simulation Environment: NEURON (web link to model);
Model Concept(s): Methods;
Implementer(s): Magalhães, Bruno [brunomaga at gmail.com];
(located via links below)