A cache‐oblivious self‐adaptive full multigrid method

Mehl, Miriam; Weinzierl, Tobias; Zenger, Christoph

doi:10.1002/nla.481

Cited by 40 publications

(35 citation statements)

References 9 publications

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“…Due to the single touch policy per unknown and the localised traversal, we can assume that each unknown is loaded into the cache exactly once. This insight mirrors previous reports on this algorithmic paradigm [Mehl et al 2006;Weinzierl 2009;Weinzierl and Mehl 2011]. We validate this at hands of the cache miss rate explaining the low bandwidth requirements.…”

Section: P = 2 Application Scenario and Grid Adaptivity Structuresupporting

confidence: 90%

“…The right-hand side is not required earlier throughout the solve process. The overall process is detailed in [Mehl et al 2006] and reiterated in Appendix B. It is completely matrix-free.…”

Section: Multigrid Realisationmentioning

confidence: 99%

“…in the grid, integrated. Similar techniques have been proposed for multilevel solvers [Adams et al 2016;Mehl et al 2006;Ghysels et al 2012;Ghysels and Vanroose 2015] or Krylov solvers [Chronopoulos and Gear 1989;Hoemmen 2010;Ghysels et al 2013;Ghysels and Vanroose 2014], but, to the best of our knowledge, no other approach offers a solution representation on all levels plus single touch. Multilevel solution representations simplify the handling of hanging nodes, non-linear problems and scale-dependent discretisations [Cools et al 2014b].…”

Section: Introductionmentioning

confidence: 99%

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Complex Additive Geometric Multilevel Solvers for Helmholtz Equations on Spacetrees

Reps

Weinzierl

2017

ACM Trans. Math. Softw.

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We introduce a family of implementations of low order, additive, geometric multilevel solvers for systems of Helmholtz equations arising from Schrödinger equations. Both grid spacing and arithmetics may comprise complex numbers and we thus can apply complex scaling to the indefinite Helmholtz operator. Our implementations are based upon the notion of a spacetree and work exclusively with a finite number of precomputed local element matrices. They are globally matrix-free.Combining various relaxation factors with two grid transfer operators allows us to switch from additive multigrid over a hierarchical basis method into a Bramble-Pasciak-Xu (BPX)-type solver, with several multiscale smoothing variants within one code base. Pipelining allows us to realise full approximation storage (FAS) within the additive environment where, amortised, each grid vertex carrying degrees of freedom is read/written only once per iteration. The codes realise a single-touch policy. Among the features facilitated by matrix-free FAS is arbitrary dynamic mesh refinement (AMR) for all solver variants. AMR as enabler for full multigrid (FMG) cycling-the grid unfolds throughout the computation-allows us to reduce the cost per unknown per order of accuracy.The present paper primary contributes towards software realisation and design questions. Our experiments show that the consolidation of single-touch FAS, dynamic AMR and vectorisation-friendly, complex scaled, matrix-free FMG cycles delivers a mature implementation blueprint for solvers of Helmholtz equations in general. For this blueprint, we put particular emphasis on a strict implementation formalism as well as some implementation correctness proofs.

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Section: P = 2 Application Scenario and Grid Adaptivity Structuresupporting

confidence: 90%

“…The right-hand side is not required earlier throughout the solve process. The overall process is detailed in [Mehl et al 2006] and reiterated in Appendix B. It is completely matrix-free.…”

Section: Multigrid Realisationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Complex Additive Geometric Multilevel Solvers for Helmholtz Equations on Spacetrees

Reps

Weinzierl

2017

ACM Trans. Math. Softw.

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“…The method described in this paper can only be applied to meshes created by hierarchical triangular bisection. A similar method for quadrilateral meshes, refined by edge bisection of the elements, has been proposed in Mehl et al (2006).…”

Section: Challengesmentioning

confidence: 99%

Efficiency considerations in triangular adaptive mesh refinement

Behrens

Bäder

2009

Phil. Trans. R. Soc. A.

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Locally or adaptively refined meshes have been successfully applied to simulation applications involving multi-scale phenomena in the geosciences. In particular, for situations with complex geometries or domain boundaries, meshes with triangular or tetrahedral cells demonstrate their superior ability to accurately represent relevant realistic features.On the other hand, these methods require more complex data structures and are therefore less easily implemented, maintained and optimized. Acceptance in the Earthsystem modelling community is still low. One of the major drawbacks is posed by indirect addressing due to unstructured or dynamically changing data structures and correspondingly lower efficiency of the related computations.In this paper, we will derive several strategies to circumvent the mentioned efficiency constraint. In particular, we will apply recent computational sciences methods in combination with results of classical mathematics (space-filling curves) in order to linearize the complex data and access structure.

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“…Recently, our research group have presented a family of methods based on recursively substructured grids (similar to octrees), which allow the implementation of iterative multigrid solvers on fully adaptive grids, but only require a marginal amount of memory-see Günther et al (2006) and Mehl et al (2006) for rectangular grids, and Bader and Zenger (2006) for triangular grids. For efficient processing on these grids, the presented schemes combine the use of space-filling curves (Peano curves or Sierpinski curves, respectively) and a sophisticated scheme of stacks, and thus implement iterative solvers in a way such that almost no topological information needs to be stored and that it is no longer necessary to explicitly store a system of equations.…”

Section: Introductionmentioning

confidence: 99%

Memory efficient adaptive mesh generation and implementation of multigrid algorithms using Sierpinski curves

Bäder¹,

Schraufstetter²,

Vigh³

et al. 2008

IJCSE

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Abstract:We will present an approach to numerical simulation on recursively structured adaptive discretisation grids. The respective grid generation process is based on recursive bisection of triangles along marked edges. The resulting refinement tree is sequentialised according to a Sierpinski space-filling curve, which leads to both minimal memory requirements and inherently cache-efficient processing schemes. The locality properties induced by the space-filling curve are even retained throughout adaptive refinement of the grid. We demonstrate the efficiency of the approach by implementing a multilevel-preconditioned conjugate gradient solver for a simple, yet adaptive, test problem: solving Poisson's equation on a re-entrant corner problem.Keywords: adaptive grid generation; space-filling curves; cache efficiency; simulation.Reference to this paper should be made as follows: Bader, M., Schraufstetter, S., Vigh, C.A. and Behrens, J. (2008) 'Memory efficient adaptive mesh generation and implementation of multigrid algorithms using Sierpinski curves', Int.

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A cache‐oblivious self‐adaptive full multigrid method

Cited by 40 publications

References 9 publications

Complex Additive Geometric Multilevel Solvers for Helmholtz Equations on Spacetrees

Complex Additive Geometric Multilevel Solvers for Helmholtz Equations on Spacetrees

Efficiency considerations in triangular adaptive mesh refinement

Memory efficient adaptive mesh generation and implementation of multigrid algorithms using Sierpinski curves

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