SIESTA‐SIPs: Massively parallel spectrum‐slicing eigensolver for an <i>ab initio</i> molecular dynamics package

Keçeli, Murat; Corsetti, Fabiano; Campos, Carmen; Román, José E.; Zhang, Hong; Vázquez-Mayagoitia, Álvaro; Zapol, Peter; Wagner, Albert F.

doi:10.1002/jcc.25350

Cited by 13 publications

(23 citation statements)

References 38 publications

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“…As of its 2.4.1 release, ELSI supports shared-memory eigensolvers LA-PACK [27] and MAGMA [28,29], distributed-memory eigensolvers ELPA [21,22,23], SLEPc-SIPc [13,14,24,25], and EigenExa [26], and distributedmemory density matrix solvers PEXSI [8,9,10,11], libOMM [30], and NT-Poly [31]. In the following sections, we cover a few algorithmic and technical aspects of the upgraded PEXSI solver and the newly added NTPoly and SLEPc-SIPs solvers.…”

Section: Solver Updatesmentioning

confidence: 99%

ELSI: A unified software interface for Kohn–Sham electronic structure solvers

Corsetti

Garcı́a

et al. 2018

Computer Physics Communications

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111

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Solving the electronic structure from a generalized or standard eigenproblem is often the bottleneck in large scale calculations based on Kohn-Sham density-functional theory. This problem must be addressed by essentially all current electronic structure codes, based on similar matrix expressions, and by high-performance computation. We here present a unified software interface, ELSI, to access different strategies that address the Kohn-Sham eigenvalue problem. Currently supported algorithms include the dense generalized eigensolver library ELPA, the orbital minimization method implemented in libOMM, and the pole expansion and selected inversion (PEXSI) approach with lower computational complexity for semilocal density functionals. The ELSI interface aims to simplify the implementation and optimal use of the * Corresponding author.

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Section: Solver Updatesmentioning

confidence: 99%

ELSI: A unified software interface for Kohn–Sham electronic structure solvers

Corsetti

Garcı́a

et al. 2018

Computer Physics Communications

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111

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“…The SIESTA-SIPs method of [Keçeli et al 2018] adopts a similar k-means strategy for tracking the eigenvalue migration throughout the SCF procedure to avoid costly methods to perform shift selection every SCF iteration. The SIESTA-SIPs method is not as sensitive to changes in the definitions of spectral slice intervals between SCF iterations as long as they are distributed such to allow for similar convergence rates between slices due to their use of SI-Lanczos.…”

Section: Shift Refinement and Eigenvalue Clusteringmentioning

confidence: 99%

“…These distributed calculations for each spectral probe may take place on a subset of the total number of MPI ranks, allowing leverage of massive parallelism on large computing clusters. We do not treat this particular parallelism scheme in this work, but it has been discussed at length in other related work [Keçeli et al 2016[Keçeli et al , 2018Zhang et al 2007].…”

Section: Parallel Implementationmentioning

confidence: 99%

“…• The shift-invert Lanczos method (SI-Lanczos). Historically, this has been the method of choice for spectrum slicing methods [Aktulga et al 2014;Campos and Roman 2012;Grimes et al 1994;Keçeli et al 2016Keçeli et al , 2018Zhang et al 2007]. However, the dependency among the sequence of linear systems the method must solve makes it difficult to achieve good parallel scalability.…”

Section: Introductionmentioning

confidence: 99%

“…The dynamic shift selection within each subdomain is similar to the sequential shift selection scheme presented by Grimes et al [1994]. More recently, the SIPs method has been extended to a dynamically scheduled two-level parallel scheme targeting the SCF eigenvalue problem (SIESTA-SIPs [Keçeli et al 2018]), which processes non-overlapping spectral subdomains with an improved dynamic shift selection within each domain as developed in the SLEPc library [Campos and Roman 2012]. While robust, this shift selection strategy does not maximize the potential for concurrency viz independent slices as the dynamic shift selection within a spectral subdomain still occurs sequentially.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A Shift Selection Strategy for Parallel Shift-invert Spectrum Slicing in Symmetric Self-consistent Eigenvalue Computation

Williams‐Young

Beckman

Yang

2020

ACM Trans. Math. Softw.

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The central importance of large-scale eigenvalue problems in scientific computation necessitates the development of massively parallel algorithms for their solution. Recent advances in dense numerical linear algebra have enabled the routine treatment of eigenvalue problems with dimensions on the order of hundreds of thousands on the world's largest supercomputers. In cases where dense treatments are not feasible, Krylov subspace methods offer an attractive alternative due to the fact that they do not require storage of the problem matrices. However, demonstration of scalability of either of these classes of eigenvalue algorithms on computing architectures capable of expressing massive parallelism is non-trivial due to communication requirements and serial bottlenecks, respectively. In this work, we introduce the SISLICE method: a parallel shift-invert algorithm for the solution of the symmetric self-consistent field (SCF) eigenvalue problem. The SISLICE method drastically reduces the communication requirement of current parallel shift-invert eigenvalue algorithms through various shift selection and migration techniques based on density of states estimation and k-means clustering, respectively. This work demonstrates the robustness and parallel performance of the SISLICE method on a representative set of SCF eigenvalue problems and outlines research directions that will be explored in future work.

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Inertia‐based spectrum slicing for symmetric quadratic eigenvalue problems

Campos

Román

2020

Numerical Linear Algebra App

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In the quadratic eigenvalue problem with all coefficient matrices symmetric, there can be complex eigenvalues. However, some applications need to compute real eigenvalues only. We propose a Lanczos-based method for computing all real eigenvalues contained in a given interval of large scale symmetric quadratic eigenvalue problems. The method uses matrix inertias of the quadratic polynomial evaluated at different shift values. In this way, for hyperbolic problems, it is possible to make sure that all eigenvalues in the interval have been computed. We also discuss the general non-hyperbolic case. Our implementation is memory-efficient by representing the computed pseudo-Lanczos basis in a compact tensor product representation. We show results of computational experiments with a parallel implementation in the SLEPc library.

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SIESTA‐SIPs: Massively parallel spectrum‐slicing eigensolver for an ab initio molecular dynamics package

Cited by 13 publications

References 38 publications

ELSI: A unified software interface for Kohn–Sham electronic structure solvers

ELSI: A unified software interface for Kohn–Sham electronic structure solvers

A Shift Selection Strategy for Parallel Shift-invert Spectrum Slicing in Symmetric Self-consistent Eigenvalue Computation

Inertia‐based spectrum slicing for symmetric quadratic eigenvalue problems

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