ExaHyPE: An engine for parallel dynamically adaptive simulations of wave problems

Reinarz, Anne; Charrier, Dominic Etienne; Bäder, Michael; Bovard, Luke; Dumbser, Michael; Duru, Kenneth; Fambri, Francesco; Gabriel, Alice‐Agnes; Gallard, Jean-Matthieu; Köppel, Sven; Krenz, Lukas; Rannabauer, Leonhard; Rezzolla, Luciano; Samfass, Philipp; Tavelli, Maurizio; Weinzierl, Tobias

doi:10.1016/j.cpc.2020.107251

Cited by 60 publications

(49 citation statements)

References 59 publications

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“…Furthermore, in order to increase the resolution in the areas of interest, the ADER-DG scheme described above has been implemented on space-time adaptive Cartesian meshes, with a cell-by-cell refinement approach; for all the details we refer to [44,38,141,47,46,13,140,113].…”

Section: Adaptive Mesh Refinement (Amr)mentioning

confidence: 99%

A simple diffuse interface approach for compressible flows around moving solids of arbitrary shape based on a reduced Baer–Nunziato model

et al. 2020

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In this paper we propose a new diffuse interface model for the numerical simulation of inviscid compressible flows around fixed and moving solid bodies of arbitrary shape. The solids are assumed to be moving rigid bodies, without any elastic properties. The mathematical model is a simplified case of the seven-equation Baer-Nunziato model of compressible multi-phase flows. The resulting governing PDE system is a nonlinear system of hyperbolic conservation laws with non-conservative products. The geometry of the solid bodies is simply specified via a scalar field that represents the volume fraction of the fluid present in each control volume. This allows the discretization of arbitrarily complex geometries on simple uniform or adaptive Cartesian meshes. Inside the solid bodies, the fluid volume fraction is zero, while it is unitary inside the fluid phase. Due to the diffuse interface nature of the model, the volume fraction function can assume any value between zero and one in mixed cells that are occupied by both, fluid and solid.We also prove that at the material interface, i.e. where the volume fraction jumps from unity to zero, the normal component of the fluid velocity assumes the value of the normal component of the solid velocity. This result can be directly derived from the governing equations, either via Riemann invariants or from the generalized Rankine Hugoniot conditions according to the theory of Dal Maso, Le Floch and Murat [89], which justifies the use of a path-conservative approach for treating the non-conservative products.The governing partial differential equations of our new model are solved on simple uniform Cartesian grids via a high order path-conservative ADER discontinuous Galerkin (DG) finite element method with a posteriori sub-cell finite volume (FV) limiter. Since the numerical method is of the shock capturing type, the fluid-solid boundary is never explicitly tracked by the numerical method, neither via interface reconstruction, nor via mesh motion.The effectiveness of the proposed approach is tested on a set of different numerical test problems, including 1D Riemann problems as well as supersonic flows over fixed and moving rigid bodies.Key words: diffuse interface model, compressible flows over fixed and moving solids, immersed boundary method for compressible flows, arbitrary high-order discontinuous Galerkin schemes, a posteriori sub-cell finite volume limiter (MOOD), path-conservative schemes for hyperbolic PDE with non-conservative products,

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Section: Adaptive Mesh Refinement (Amr)mentioning

confidence: 99%

A simple diffuse interface approach for compressible flows around moving solids of arbitrary shape based on a reduced Baer–Nunziato model

et al. 2020

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“…The ExaHyPE engine [1] can solve a large class of systems of first-order hyperbolic PDEs, which are expressed in the following canonical form:…”

Section: A a High-order Ader-dg Solver With A-posteriori Limitingmentioning

confidence: 99%

“…The ADER-DG method consists of two phases, a predictor step in which the weak formulation of (1) is solved locally in each cell, and a corrector step in which the contributions of neighboring cells are taken into account. To derive the weak solution of the problem we insert the DG ansatz function from the space of piecewise polynomials into equation (1) and multiply with a test function from the same space of piecewise polynomials. We then integrate over a space-time control volume.…”

Section: A a High-order Ader-dg Solver With A-posteriori Limitingmentioning

confidence: 99%

“…The canonical PDE system (1) can model a wide array of applications, including relativistic astrophysics [10], [11], seismic wave propagation [12], [13] or several variants of fluid equations (see [1] for an overview). All these problems can be formulated via Equation (1) via specific F(Q), B(Q) · ∇Q and S(Q).…”

Section: B Application-specific Programming Interfacementioning

confidence: 99%

“…exahype.eu) is an EU Horizon 2020 project to develop an exascale-ready general solver for hyperbolic systems of partial differential equations (PDEs). Intended as an engine (as in "game engine"), it concentrates on a dedicated numerical scheme and on a fixed mesh infrastructure, but provides flexibility in the PDE system to be solved [1]. Its mission statement is "to enable medium-sized interdisciplinary research teams to realize extreme-scale simulations of grand challenges modelled by hyperbolic conservation laws".…”

Section: Introductionmentioning

confidence: 99%

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Role-Oriented Code Generation in an Engine for Solving Hyperbolic PDE Systems

Gallard

Krenz

Rannabauer

et al. 2020

Communications in Computer and Information Science

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The development of a high performance PDE solver requires the combined expertise of interdisciplinary teams w.r.t. application domain, numerical scheme and low-level optimization. In this paper, we present how the ExaHyPE engine facilitates the collaboration of such teams by isolating three rolesapplication, algorithms, and optimization expert -thus allowing team members to focus on their own area of expertise, while integrating their contributions into an HPC production code.Inspired by web application development practices ExaHyPE relies on two custom code generation modules, the Toolkit and the Kernel Generator, which follow a Model-View-Controller architectural pattern on top of the Jinja2 template engine library. Using Jinja2's templates to abstract the critical components of the engine and generated glue code, we isolate the application development from the engine. The template language also allows us to define and use custom macros that isolate low-level optimizations from the numerical scheme described in the templates.We present three use cases, each focusing on one of our user roles, showcasing how the design of the code generation modules allows to easily expand the solver schemes to support novel demands from applications, to add optimized algorithmic schemes (with reduced memory footprint, e.g.), or provide improved lowlevel SIMD vectorization support.

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Lightweight task offloading exploiting MPI wait times for parallel adaptive mesh refinement

Samfass

Weinzierl

Charrier

et al. 2020

Concurrency and Computation

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Balancing the workload of sophisticated simulations is inherently difficult, since we have to balance both computational workload and memory footprint over meshes that can change any time or yield unpredictable cost per mesh entity, while modern supercomputers and their interconnects start to exhibit fluctuating performance. We propose a novel lightweight balancing technique for MPI+X to accompany traditional, prediction-based load balancing. It is a reactive diffusion approach that uses online measurements of MPI idle time to migrate tasks temporarily from overloaded to underemployed ranks. Tasks are deployed to ranks which otherwise would wait, processed with high priority, and made available to the overloaded ranks again. This migration is nonpersistent. Our approach hijacks idle time to do meaningful work and is totally nonblocking, asynchronous and distributed without a global data view. Tests with a seismic simulation code developed in the ExaHyPE engine uncover the method's potential. We found speed-ups of up to 2-3 for ill-balanced scenarios without logical modifications of the code base and show that the strategy is capable to react quickly to temporarily changing workload or node performance. K E Y W O R D S adaptive mesh refinement, MPI+X, reactive load balancing, task-based parallelism 1 INTRODUCTION Load balancing that decomposes work prior to a certain compute phase-a time step or iteration of an equation system solver-is doomed to underperform in many sophisticated simulation codes. There are multiple reasons for this: The clock frequency of processors changes over runtime, 1-3 the network speed is subject to noise due to other applications 4,5 or IO, and task-based multicore parallelization (MPI+X) tends to yield fluttering throughput due to effects of the memory hierarchy, 6 work stealing and nondeterminism in the MPI progression. While this list is not comprehensive, notably modern numerics drive the nonpredictability: They build atop of dynamic adaptive mesh refinement (AMR) that changes the mesh throughout a time step or mesh sweep, 7 combine different physical models, 7-9 or solve nonlinear equation systems with iterative solvers in substeps. 10 It becomes hard or even impossible to predict a step's computational load. As adjusting parallel partitions and respective data migration is often costly, many AMR codes consequently repartition only every 10th or 100th time step and tolerate certain load imbalances in-between. We propose a novel, lightweight load redistribution scheme that acts on top of traditional load balancing. It, first, assumes that parts of the underlying simulation code are phrased in terms of many expensive tasks. It, second, assumes that good AMR codes manage to hide data exchange behind computations yet cannot keep all cores busy all the time. In every solver step, some cores on some ranks have to wait for MPI data to drop in. Our idea is to offload tasks from overbooked to waiting ranks to make these work productively rather than being idle. 11 The code plugs into the Thi...

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ExaHyPE: An engine for parallel dynamically adaptive simulations of wave problems

Cited by 60 publications

References 59 publications

A simple diffuse interface approach for compressible flows around moving solids of arbitrary shape based on a reduced Baer–Nunziato model

A simple diffuse interface approach for compressible flows around moving solids of arbitrary shape based on a reduced Baer–Nunziato model

Role-Oriented Code Generation in an Engine for Solving Hyperbolic PDE Systems

Lightweight task offloading exploiting MPI wait times for parallel adaptive mesh refinement

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