A Comparison of the Performance Characteristics of Capability and Capacity Class HPC Systems
Abstract not provided.
Publications
An Investigation of Compiler Vectorization on Current and Next-generation Intel Processors using Benchmarks and Sandia?s SIERRA Applications
Abstract not provided.
Application Driven Analysis of Two Generations of Capability Computing Platforms: Purple and Cielo
Abstract not provided.
Application-Driven Acceptance of Cielo an XE6 Petascale Capability Platform
Abstract not provided.
Application-Driven Accpetance of Cielo an XE6 Petascale Capability Platform
Abstract not provided.
Application-driven analysis of two generations of capability computing platforms :
Abstract not provided.
Application-driven Analysis of Two Generations of Capability Computing Platforms: Purple and Cielo
Abstract not provided.
Application-Driven Analysis of Two Generations of Capability Computing Platforms: The Transition to Multicore Processors
Concurreny and Computation: Practice and Experience
Abstract not provided.
ASC L2 Trilab Codesign Milestone (Codesign at Sandia: LULESH and MiniAero)
Abstract not provided.
ASC Trilab L2 Codesign Milestone 2015
For the FY15 ASC L2 Trilab Codesign milestone Sandia National Laboratories performed two main studies. The first study investigated three topics (performance, cross-platform portability and programmer productivity) when using OpenMP directives and the RAJA and Kokkos programming models available from LLNL and SNL respectively. The focus of this first study was the LULESH mini-application developed and maintained by LLNL. In the coming sections of the report the reader will find performance comparisons (and a demonstration of portability) for a variety of mini-application implementations produced during this study with varying levels of optimization. Of note is that the implementations utilized including optimizations across a number of programming models to help ensure claims that Kokkos can provide native-class application performance are valid. The second study performed during FY15 is a performance assessment of the MiniAero mini-application developed by Sandia. This mini-application was developed by the SIERRA Thermal-Fluid team at Sandia for the purposes of learning the Kokkos programming model and so is available in only a single implementation. For this report we studied its performance and scaling on a number of machines with the intent of providing insight into potential performance issues that may be experienced when similar algorithms are deployed on the forthcoming Trinity ASC ATS platform.
Benchmarking Multicore Processors
Abstract not provided.
Capability vs Capacity; HPC Systems Application Performance Comparisons: Cielo vs. Red Sky
Abstract not provided.
Copy of Application-driven Analysis of Two Generations of Capability Computing Platforms: Purple and Cielo
Abstract not provided.
Copy of Predicting AMD Magny-Cours Performance for a Suite of NNSA/ASC Applications
Abstract not provided.
Early Experiences with Trinity - The First Advanced Technology Platform for the ASC Program
Abstract not provided.
Early Experiences with Trinity - The First Advanced Technology Platform for the ASC Program
Abstract not provided.
Experiences with Sandia National Laboratories HPC applications and MPI performance
Abstract not provided.
From Red Storm to Cielo: Performance Analysis of ASC Simulation Programs Across an Evolution of Multicore Architectures
Parallel Processing Letters
Abstract not provided.
HPC application performance and scaling : understanding trends and future challenges with application benchmarks on past, present and future Tri-Lab computing systems
Abstract not provided.
HPC top 10 InfiniBand Machine : a 3D Torus IB interconnect on Red Sky
This presentation discusses the following topics: (1) Red Sky Background; (2) 3D Torus Interconnect Concepts; (3) Difficulties of Torus in IB; (4) New Routing Code for IB a 3D Torus; (5) Red Sky 3D Torus Implementation; and (6) Managing a Large IB Machine. Computing at Sandia: (1) Capability Computing - Designed for scaling of single large runs, Usually proprietary for maximum performance, and Red Storm is Sandia's current capability machine; (2) Capacity Computing - Computing for the masses, 100s of jobs and 100s of users, Extreme reliability required, Flexibility for changing workload, Thunderbird will be decommissioned this quarter, Red Sky is our future capacity computing platform, and Red Mesa machine for National Renewable Energy Lab. Red Sky main themes are: (1) Cheaper - 5X capacity of Tbird at 2/3 the cost, Substantially cheaper per flop than our last large capacity machine purchase; (2) Leaner - Lower operational costs, Three security environments via modular fabric, Expandable, upgradeable, extensible, and Designed for 6yr. life cycle; and (3) Greener - 15% less power-1/6th power per flop, 40% less water-5M gallons saved annually, 10X better cooling efficiency, and 4x denser footprint.
Improving performance via mini-applications
Application performance is determined by a combination of many choices: hardware platform, runtime environment, languages and compilers used, algorithm choice and implementation, and more. In this complicated environment, we find that the use of mini-applications - small self-contained proxies for real applications - is an excellent approach for rapidly exploring the parameter space of all these choices. Furthermore, use of mini-applications enriches the interaction between application, library and computer system developers by providing explicit functioning software and concrete performance results that lead to detailed, focused discussions of design trade-offs, algorithm choices and runtime performance issues. In this paper we discuss a collection of mini-applications and demonstrate how we use them to analyze and improve application performance on new and future computer platforms.
Investigating the balance between capacity and capability workloads across large scale computing platforms
Abstract not provided.
Investigating the impact of the Cielo Cray XE6 architecture on scientific application codes
IEEE International Symposium on Parallel and Distributed Processing Workshops and Phd Forum
Cielo, a Cray XE6, is the Department of Energy NNSA Advanced Simulation and Computing (ASC) campaign's newest capability machine. Rated at 1.37 PFLOPS, it consists of 8,944 dual-socket oct-core AMD Magny-Cours compute nodes, linked using Cray's Gemini interconnect. Its primary mission objective is to enable a suite of the ASC applications implemented using MPI to scale to tens of thousands of cores. Cielo is an evolutionary improvement to a successful architecture previously available to many of our codes, thus enabling a basis for understanding the capabilities of this new architecture. Using three codes strategically important to the ASC campaign, and supplemented with some micro-benchmarks that expose the fundamental capabilities of the XE6, we report on the performance characteristics and capabilities of Cielo. © 2011 IEEE.
Investigating the impact of the cielo cray XE6 architecture on scientific application codes
Cielo, a Cray XE6, is the Department of Energy NNSA Advanced Simulation and Computing (ASC) campaign's newest capability machine. Rated at 1.37 PFLOPS, it consists of 8,944 dual-socket oct-core AMD Magny-Cours compute nodes, linked using Cray's Gemini interconnect. Its primary mission objective is to enable a suite of the ASC applications implemented using MPI to scale to tens of thousands of cores. Cielo is an evolutionary improvement to a successful architecture previously available to many of our codes, thus enabling a basis for understanding the capabilities of this new architecture. Using three codes strategically important to the ASC campaign, and supplemented with some micro-benchmarks that expose the fundamental capabilities of the XE6, we report on the performance characteristics and capabilities of Cielo.
Investigating the Impact of the Cielo Cray XT6 Architecture on Scientific Application Codes
Abstract not provided.
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