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FY18 L2 Milestone #8759 Report: Vanguard Astra and ATSE ? an ARM-based Advanced Architecture Prototype System and Software Environment

Laros, James H.; Pedretti, Kevin P.; Hammond, Simon D.; Aguilar, Michael J.; Curry, Matthew L.; Grant, Ryan E.; Hoekstra, Robert J.; Klundt, Ruth A.; Monk, Stephen T.; Ogden, Jeffry B.; Olivier, Stephen L.; Scott, Randall D.; Ward, Harry L.; Younge, Andrew J.

The Vanguard program informally began in January 2017 with the submission of a white pa- per entitled "Sandia's Vision for a 2019 Arm Testbed" to NNSA headquarters. The program proceeded in earnest in May 2017 with an announcement by Doug Wade (Director, Office of Advanced Simulation and Computing and Institutional R&D at NNSA) that Sandia Na- tional Laboratories (Sandia) would host the first Advanced Architecture Prototype platform based on the Arm architecture. In August 2017, Sandia formed a Tri-lab team chartered to develop a robust HPC software stack for Astra to support the Vanguard program goal of demonstrating the viability of Arm in supporting ASC production computing workloads. This document describes the high-level Vanguard program goals, the Vanguard-Astra project acquisition plan and procurement up to contract placement, the initial software stack environment planned for the Vanguard-Astra platform (Astra), a description of how the communities of users will utilize the platform during the transition from the open network to the classified network, and initial performance results.

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FY18 L2 Milestone #6360 Report: Initial Capability of an Arm-based Advanced Architecture Prototype System and Software Environment

Laros, James H.; Pedretti, Kevin P.; Hammond, Simon D.; Aguilar, Michael J.; Curry, Matthew L.; Grant, Ryan E.; Hoekstra, Robert J.; Klundt, Ruth A.; Monk, Stephen T.; Ogden, Jeffry B.; Olivier, Stephen L.; Scott, Randall D.; Ward, Harry L.; Younge, Andrew J.

The Vanguard program informally began in January 2017 with the submission of a white pa- per entitled "Sandia's Vision for a 2019 Arm Testbed" to NNSA headquarters. The program proceeded in earnest in May 2017 with an announcement by Doug Wade (Director, Office of Advanced Simulation and Computing and Institutional R&D at NNSA) that Sandia Na- tional Laboratories (Sandia) would host the first Advanced Architecture Prototype platform based on the Arm architecture. In August 2017, Sandia formed a Tri-lab team chartered to develop a robust HPC software stack for Astra to support the Vanguard program goal of demonstrating the viability of Arm in supporting ASC production computing workloads. This document describes the high-level Vanguard program goals, the Vanguard-Astra project acquisition plan and procurement up to contract placement, the initial software stack environment planned for the Vanguard-Astra platform (Astra), a description of how the communities of users will utilize the platform during the transition from the open network to the classified network, and initial performance results.

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Optimizing for KNL usage modes when data doesn’t fit in MCDRAM

ACM International Conference Proceeding Series

Butcher, Neil; Olivier, Stephen L.; Berry, Jonathan W.; Hammond, Simon D.; Kogge, Peter M.

Technologies such as Multi-Channel DRAM (MCDRAM) or High Bandwidth Memory (HBM) provide significantly more bandwidth than conventional memory. This trend has raised questions about how applications should manage data transfers between levels. This paper focuses on evaluating different usage modes of the MCDRAM in Intel Knights Landing (KNL) manycore processors. We evaluate these usage modes with a sorting kernel and a sorting-based streaming benchmark. We develop a performance model for the benchmark and use experimental evidence to demonstrate the correctness of the model. The model projects near-optimal numbers of copy threads for memory bandwidth bound computations. We demonstrate on KNL up to a 1.9X speedup for sort when the problem does not fit in MCDRAM over an OpenMP GNU sort that does not use MCDRAM.

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A comparison of power management mechanisms: P-States vs. node-level power cap control

Proceedings - 2018 IEEE 32nd International Parallel and Distributed Processing Symposium Workshops, IPDPSW 2018

Pedretti, Kevin P.; Grant, Ryan E.; Laros, James H.; Levenhagen, Michael J.; Olivier, Stephen L.; Ward, Harry L.; Younge, Andrew J.

Large-scale HPC systems increasingly incorporate sophisticated power management control mechanisms. While these mechanisms are potentially useful for performing energy and/or power-aware job scheduling and resource management (EPA JSRM), greater understanding of their operation and performance impact on real-world applications is required before they can be applied effectively in practice. In this paper, we compare static p-state control to static node-level power cap control on a Cray XC system. Empirical experiments are performed to evaluate node-to-node performance and power usage variability for the two mechanisms. We find that static p-state control produces more predictable and higher performance characteristics than static node-level power cap control at a given power level. However, this performance benefit is at the cost of less predictable power usage. Static node-level power cap control produces predictable power usage but with more variable performance characteristics. Our results are not intended to show that one mechanism is better than the other. Rather, our results demonstrate that the mechanisms are complementary to one another and highlight their potential for combined use in achieving effective EPA JSRM solutions.

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Evaluating energy and power profiling techniques for HPC workloads

2017 8th International Green and Sustainable Computing Conference, IGSC 2017

Grant, Ryan E.; Laros, James H.; Levenhagen, Michael J.; Olivier, Stephen L.; Pedretti, Kevin P.; Ward, Harry L.; Younge, Andrew J.

Advanced power measurement capabilities are becoming available on large scale High Performance Computing (HPC) deployments. There exist several approaches to providing power measurements today, primarily through in-band (e.g. RAPL) and out-of-band measurements (e.g. power meters). Both types of measurement can be augmented with application-level profiling, however it can be difficult to assess the type and detail of measurement needed to obtain insight from the application power profile. This paper presents a taxonomy for classifying power profiling techniques on modern HPC platforms. Three HPC mini-applications are analyzed across three production HPC systems to examine the level of detail, scope, and complexity of these power profiles. We demonstrate that a combination of out-of-band measurement with in-band application region profiling can provide an accurate, detailed view of power usage without introducing overhead. This work also provides a set of recommendations for how to best profile HPC workloads.

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Assessing task-to-data affinity in the LLVM OpenMP runtime

Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)

Klinkenberg, Jannis; Samfass, Philipp; Terboven, Christian; Duran, Alejandro; Klemm, Michael; Teruel, Xavier; Mateo, Sergi; Olivier, Stephen L.; Müller, Matthias S.

In modern shared-memory NUMA systems which typically consist of two or more multi-core processor packages with local memory, affinity of data to computation is crucial for achieving high performance with an OpenMP program. OpenMP* 3.0 introduced support for task-parallel programs in 2008 and has continued to extend its applicability and expressiveness. However, the ability to support data affinity of tasks is missing. In this paper, we investigate several approaches for task-to-data affinity that combine locality-aware task distribution and task stealing. We introduce the task affinity clause that will be part of OpenMP 5.0 and provide the reasoning behind its design. Evaluation with our experimental implementation in the LLVM OpenMP runtime shows that task affinity improves execution performance up to 4.5x on an 8-socket NUMA machine and significantly reduces runtime variability of OpenMP tasks. Our results demonstrate that a variety of applications can benefit from task affinity and that the presented clause is closing the gap of task-to-data affinity in OpenMP 5.0.

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OpenMPIR: Implementing OpenMP tasks with tapir

Proceedings of LLVM-HPC 2017: 4th Workshop on the LLVM Compiler Infrastructure in HPC - Held in conjunction with SC 2017: The International Conference for High Performance Computing, Networking, Storage and Analysis

Stelle, George; Moses, William S.; Olivier, Stephen L.; McCormick, Patrick

Optimizing compilers for task-level parallelism are still in their infancy. This work explores a compiler front end that translates OpenMP tasking semantics to Tapir, an extension to LLVM IR that represents fork-join parallelism. This enables analyses and optimizations that were previously inaccessible to OpenMP codes, as well as the ability to target additional runtimes at code generation. Using a Cilk runtime back end, we compare results to existing OpenMP implementations. Initial performance results for the Barcelona OpenMP task suite show performance improvements over existing implementations.

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Improving energy efficiency in memory-constrained applications using core-specific power control

Proceedings of E2SC 2017: 5th International Workshop on Energy Efficient Supercomputing - Held in conjunction with SC 2017: The International Conference for High Performance Computing, Networking, Storage and Analysis

Bhalachandra, Sridutt; Porterfield, Allan; Olivier, Stephen L.; Prins, Jan F.; Fowler, Robert J.

Power is increasingly the limiting factor in High Performance Computing (HPC) at Exascale and will continue to influence future advancements in supercomputing. Recent processors equipped with on-board hardware counters allow real time monitoring of operating conditions such as energy and temperature, in addition to performance measures such as instructions retired and memory accesses. An experimental memory study presented on modern CPU architectures, Intel Sandybridge and Haswell, identifies a metric, TORo_core, that detects bandwidth saturation and increased latency. TORo_core is used to construct a dynamic policy applied at coarse and fine-grained levels to modulate per-core power controls on Haswell machines. The coarse and fine-grained application of dynamic policy shows best energy savings of 32.1% and 19.5% with a 2% slowdown in both cases. On average for six MPI applications, the fine-grained dynamic policy speeds execution by 1% while the coarse-grained application results in a 3% slowdown. Energy savings through frequency reduction not only provide cost advantages, they also reduce resource contention and create additional thermal headroom for non-throttled cores improving performance.

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Results 26–50 of 113
Results 26–50 of 113