Adaptive Precision in Block-Jacobi Preconditioning for Iterative Sparse Linear System Solvers

Hartwig Anzt, Jack Dongarra, Goran Flegar, Nicholas Higham, Enrique S Quintana-Orti

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Abstract

We propose an adaptive scheme to reduce communication overhead caused by data movement by selectively storing the diagonal blocks of a block Jacobi preconditioner in different precision formats (half, single, or double). This specialized preconditioner can then be combined with any Krylov subspace method for the solution of sparse linear systems to perform all arithmetic in double precision. We assess the effects of the adaptive precision preconditioner on the iteration count and data transfer cost of a preconditioned conjugate
gradient solver. A preconditioned conjugate gradient method is, in general, a memory bandwidth-bound algorithm, and therefore its execution time and energy consumption are largely dominated by the costs of accessing the problem’s data in memory. Given this observation, we propose a model that quantifies the time and energy savings of our approach based on the assumption that these two costs depend linearly on the bit length of a floating point number. Furthermore, we use a number of test problems from the SuiteSparse matrix collection to estimate the potential benefits of the adaptive block-Jacobi preconditioning scheme.
Original languageEnglish
JournalConcurrency and Computation: Practice and Experience
Early online date12 Mar 2018
DOIs
Publication statusPublished - 2018

Keywords

  • sparse linear systems
  • block-Jacobi preconditioning
  • adaptive precision
  • Krylov subspace methods
  • communication reduction
  • energy efficiency

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