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Integrating PGAS and MPI-based Graph Analysis

McCrary, Trevor M.; Devine, Karen D.; Younge, Andrew J.

This project demonstrates that Chapel programs can interface with MPI-based libraries written in C++ without storing multiple copies of shared data. Chapel is a language for productive parallel computing using global address spaces (PGAS). We identified two approaches to interface Chapel code with the MPI-based Grafiki and Trilinos libraries. The first uses a single Chapel executable to call a C function that interacts with the C++ libraries. The second uses the mmap function to allow separate executables to read and write to the same block of memory on a node. We also encapsulated the second approach in Docker/Singularity containers to maximize ease of use. Comparisons of the two approaches using shared and distributed memory installations of Chapel show that both approaches provide similar scalability and performance.

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Integrated System and Application Continuous Performance Monitoring and Analysis Capability

Aaziz, Omar R.; Allan, Benjamin A.; Brandt, James M.; Cook, Jeanine C.; Devine, Karen D.; Elliott, James E.; Gentile, Ann C.; Hammond, Simon D.; Kelley, Brian M.; Lopatina, Lena L.; Moore, Stan G.; Olivier, Stephen L.; Pedretti, Kevin P.; Poliakoff, David Z.; Pawlowski, Roger P.; Regier, Phillip A.; Schmitz, Mark E.; Schwaller, Benjamin S.; Surjadidjaja, Vanessa S.; Swan, Matthew S.; Tucker, Nick T.; Tucker, Tom T.; Vaughan, Courtenay T.; Walton, Sara P.

Scientific applications run on high-performance computing (HPC) systems are critical for many national security missions within Sandia and the NNSA complex. However, these applications often face performance degradation and even failures that are challenging to diagnose. To provide unprecedented insight into these issues, the HPC Development, HPC Systems, Computational Science, and Plasma Theory & Simulation departments at Sandia crafted and completed their FY21 ASC Level 2 milestone entitled "Integrated System and Application Continuous Performance Monitoring and Analysis Capability." The milestone created a novel integrated HPC system and application monitoring and analysis capability by extending Sandia's Kokkos application portability framework, Lightweight Distributed Metric Service (LDMS) monitoring tool, and scalable storage, analysis, and visualization pipeline. The extensions to Kokkos and LDMS enable collection and storage of application data during run time, as it is generated, with negligible overhead. This data is combined with HPC system data within the extended analysis pipeline to present relevant visualizations of derived system and application metrics that can be viewed at run time or post run. This new capability was evaluated using several week-long, 290-node runs of Sandia's ElectroMagnetic Plasma In Realistic Environments ( EMPIRE ) modeling and design tool and resulted in 1TB of application data and 50TB of system data. EMPIRE developers remarked this capability was incredibly helpful for quickly assessing application health and performance alongside system state. In short, this milestone work built the foundation for expansive HPC system and application data collection, storage, analysis, visualization, and feedback framework that will increase total scientific output of Sandia's HPC users.

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Integrated System and Application Continuous Performance Monitoring and Analysis Capability

Brandt, James M.; Cook, Jeanine C.; Aaziz, Omar R.; Allan, Benjamin A.; Devine, Karen D.; Elliott, James J.; Gentile, Ann C.; Hammond, Simon D.; Kelley, Brian M.; Lopatina, Lena L.; Moore, Stan G.; Olivier, Stephen L.; Pedretti, Kevin P.; Poliakoff, David Z.; Pawlowski, Roger P.; Regier, Phillip A.; Schmitz, Mark E.; Schwaller, Benjamin S.; Surjadidjaja, Vanessa S.; Swan, Matthew S.; Tucker, Tom T.; Tucker, Nick T.; Vaughan, Courtenay T.; Walton, Sara P.

Abstract not provided.

Distributed Memory Graph Coloring Algorithms for Multiple GPUs

Proceedings of IA3 2020: 10th Workshop on Irregular Applications: Architectures and Algorithms, Held in conjunction with SC 2020: The International Conference for High Performance Computing, Networking, Storage and Analysis

Bogle, Ian; Boman, Erik G.; Devine, Karen D.; Rajamanickam, Sivasankaran R.; Slota, George M.

Graph coloring is often used in parallelizing scientific computations that run in distributed and multi-GPU environments; it identifies sets of independent data that can be updated in parallel. Many algorithms exist for graph coloring on a single GPU or in distributed memory, but hybrid MPI+GPU algorithms have been unexplored until this work, to the best of our knowledge. We present several MPI+GPU coloring approaches that use implementations of the distributed coloring algorithms of Gebremedhin et al. and the shared-memory algorithms of Deveci et al. The on-node parallel coloring uses implementations in KokkosKernels, which provide parallelization for both multicore CPUs and GPUs. We further extend our approaches to solve for distance-2 coloring, giving the first known distributed and multi-GPU algorithm for this problem. In addition, we propose novel methods to reduce communication in distributed graph coloring. Our experiments show that our approaches operate efficiently on inputs too large to fit on a single GPU and scale up to graphs with 76.7 billion edges running on 128 GPUs.

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Geometric mapping of tasks to processors on parallel computers with mesh or torus networks

IEEE Transactions on Parallel and Distributed Systems

Deveci, Mehmet; Devine, Karen D.; Pedretti, Kevin P.; Taylor, Mark A.; Rajamanickam, Sivasankaran R.; Çatalyurek, Umit V.

We present a new method for reducing parallel applications’ communication time by mapping their MPI tasks to processors in a way that lowers the distance messages travel and the amount of congestion in the network. Assuming geometric proximity among the tasks is a good approximation of their communication interdependence, we use a geometric partitioning algorithm to order both the tasks and the processors, assigning task parts to the corresponding processor parts. In this way, interdependent tasks are assigned to “nearby” cores in the network. We also present a number of algorithmic optimizations that exploit specific features of the network or application to further improve the quality of the mapping. We specifically address the case of sparse node allocation, where the nodes assigned to a job are not necessarily located in a contiguous block nor within close proximity to each other in the network. However, our methods generalize to contiguous allocations as well, and results are shown for both contiguous and non-contiguous allocations. We show that, for the structured finite difference mini-application MiniGhost, our mapping methods reduced communication time up to 75 percent relative to MiniGhost’s default mapping on 128K cores of a Cray XK7 with sparse allocation. For the atmospheric modeling code E3SM/HOMME, our methods reduced communication time up to 31% on 16K cores of an IBM BlueGene/Q with contiguous allocation.

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A parallel graph algorithm for detecting mesh singularities in distributed memory ice sheet simulations

ACM International Conference Proceeding Series

Bogle, Ian; Devine, Karen D.; Perego, Mauro P.; Rajamanickam, Sivasankaran R.; Slota, George M.

We present a new, distributed-memory parallel algorithm for detection of degenerate mesh features that can cause singularities in ice sheet mesh simulations. Identifying and removing mesh features such as disconnected components (icebergs) or hinge vertices (peninsulas of ice detached from the land) can significantly improve the convergence of iterative solvers. Because the ice sheet evolves during the course of a simulation, it is important that the detection algorithm can run in situ with the simulation - - running in parallel and taking a negligible amount of computation time - - so that degenerate features (e.g., calving icebergs) can be detected as they develop. We present a distributed memory, BFS-based label-propagation approach to degenerate feature detection that is efficient enough to be called at each step of an ice sheet simulation, while correctly identifying all degenerate features of an ice sheet mesh. Our method finds all degenerate features in a mesh with 13 million vertices in 0.0561 seconds on 1536 cores in the MPAS Albany Land Ice (MALI) model. Compared to the previously used serial pre-processing approach, we observe a 46,000x speedup for our algorithm, and provide additional capability to do dynamic detection of degenerate features in the simulation.

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Results 1–25 of 119
Results 1–25 of 119

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