Your search keyword '"Dewing, Mark"' showing total 37 results

1. Software engineering to sustain a high-performance computing scientific application: QMCPACK

Author

Godoy, William F., Hahn, Steven E., Walsh, Michael M., Fackler, Philip W., Krogel, Jaron T., Doak, Peter W., Kent, Paul R. C., Correa, Alfredo A., Luo, Ye, and Dewing, Mark

Subjects

Computer Science - Software Engineering, Computer Science - Distributed, Parallel, and Cluster Computing, Physics - Computational Physics

Abstract

We provide an overview of the software engineering efforts and their impact in QMCPACK, a production-level ab-initio Quantum Monte Carlo open-source code targeting high-performance computing (HPC) systems. Aspects included are: (i) strategic expansion of continuous integration (CI) targeting CPUs, using GitHub Actions runners, and NVIDIA and AMD GPUs in pre-exascale systems, using self-hosted hardware; (ii) incremental reduction of memory leaks using sanitizers, (iii) incorporation of Docker containers for CI and reproducibility, and (iv) refactoring efforts to improve maintainability, testing coverage, and memory lifetime management. We quantify the value of these improvements by providing metrics to illustrate the shift towards a predictive, rather than reactive, sustainable maintenance approach. Our goal, in documenting the impact of these efforts on QMCPACK, is to contribute to the body of knowledge on the importance of research software engineering (RSE) for the sustainability of community HPC codes and scientific discovery at scale., Comment: Accepted at the first US-RSE Conference, USRSE2023, https://us-rse.org/usrse23/, 8 pages, 3 figures, 4 tables

Published

2023

2. Evaluating Portable Parallelization Strategies for Heterogeneous Architectures in High Energy Physics

Author

Atif, Mohammad, Battacharya, Meghna, Calafiura, Paolo, Childers, Taylor, Dewing, Mark, Dong, Zhihua, Gutsche, Oliver, Habib, Salman, Knoepfel, Kyle, Kortelainen, Matti, Kwok, Ka Hei Martin, Leggett, Charles, Lin, Meifeng, Pascuzzi, Vincent, Strelchenko, Alexei, Tsulaia, Vakhtang, Viren, Brett, Wang, Tianle, Yeo, Beomki, and Yu, Haiwang

Subjects

High Energy Physics - Experiment, Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

High-energy physics (HEP) experiments have developed millions of lines of code over decades that are optimized to run on traditional x86 CPU systems. However, we are seeing a rapidly increasing fraction of floating point computing power in leadership-class computing facilities and traditional data centers coming from new accelerator architectures, such as GPUs. HEP experiments are now faced with the untenable prospect of rewriting millions of lines of x86 CPU code, for the increasingly dominant architectures found in these computational accelerators. This task is made more challenging by the architecture-specific languages and APIs promoted by manufacturers such as NVIDIA, Intel and AMD. Producing multiple, architecture-specific implementations is not a viable scenario, given the available person power and code maintenance issues. The Portable Parallelization Strategies team of the HEP Center for Computational Excellence is investigating the use of Kokkos, SYCL, OpenMP, std::execution::parallel and alpaka as potential portability solutions that promise to execute on multiple architectures from the same source code, using representative use cases from major HEP experiments, including the DUNE experiment of the Long Baseline Neutrino Facility, and the ATLAS and CMS experiments of the Large Hadron Collider. This cross-cutting evaluation of portability solutions using real applications will help inform and guide the HEP community when choosing their software and hardware suites for the next generation of experimental frameworks. We present the outcomes of our studies, including performance metrics, porting challenges, API evaluations, and build system integration., Comment: 18 pages, 9 Figures, 2 Tables

Published

2023

3. Portability: A Necessary Approach for Future Scientific Software

Author

Bhattacharya, Meghna, Calafiura, Paolo, Childers, Taylor, Dewing, Mark, Dong, Zhihua, Gutsche, Oliver, Habib, Salman, Ju, Xiangyang, Kirby, Michael, Knoepfel, Kyle, Kortelainen, Matti, Kwok, Martin, Leggett, Charles, Lin, Meifeng, Pascuzzi, Vincent R., Strelchenko, Alexei, Viren, Brett, Yeo, Beomki, and Yu, Haiwang

Subjects

Physics - Computational Physics, High Energy Physics - Experiment, Physics - Data Analysis, Statistics and Probability, Physics - Instrumentation and Detectors

Abstract

Today's world of scientific software for High Energy Physics (HEP) is powered by x86 code, while the future will be much more reliant on accelerators like GPUs and FPGAs. The portable parallelization strategies (PPS) project of the High Energy Physics Center for Computational Excellence (HEP/CCE) is investigating solutions for portability techniques that will allow the coding of an algorithm once, and the ability to execute it on a variety of hardware products from many vendors, especially including accelerators. We think without these solutions, the scientific success of our experiments and endeavors is in danger, as software development could be expert driven and costly to be able to run on available hardware infrastructure. We think the best solution for the community would be an extension to the C++ standard with a very low entry bar for users, supporting all hardware forms and vendors. We are very far from that ideal though. We argue that in the future, as a community, we need to request and work on portability solutions and strive to reach this ideal., Comment: 13 pages, 1 figure. Contribution to Snowmass 2021

Published

2022

4. Evaluating Performance Portability with the CMS Heterogeneous Pixel Reconstruction code

Author

Andriotis Nikolaos, Bocci Andrea, Cano Eric, Cappelli Laura, Di Pilato Tony, Ferragina Luca, Hugo Gabrielle, Kortelainen Matti J., Kwok Martin, Olivera Loyola Juan Jose, Pantaleo Felice, Perego Aurora, Redjeb Wahid, Dewing Mark, and Esseiva Julien

Subjects

Physics, QC1-999

Abstract

In the past years the landscape of tools for expressing parallel algorithms in a portable way across various compute accelerators has continued to evolve significantly. There are many technologies on the market that provide portability between CPU, GPUs from several vendors, and in some cases even FPGAs. These technologies include C++ libraries such as Alpaka and Kokkos, compiler directives such as OpenMP, the SYCL open specification that can be implemented as a library or in a compiler, and standard C++ where the compiler is solely responsible for the offloading. Given this developing landscape, users have to choose the technology that best fits their applications and constraints. For example, in the CMS experiment the experience so far in heterogeneous reconstruction algorithms suggests that the full application contains a large number of relatively short computational kernels and memory transfer operations. In this work we use a stand-alone version of the CMS heterogeneous pixel reconstruction code as a realistic use case of HEP reconstruction software that is capable of leveraging GPUs effectively. We summarize the experience of porting this code base from CUDA to Alpaka, Kokkos, SYCL, std::par, and OpenMP offloading. We compare the event processing throughput achieved by each version on NVIDIA and AMD GPUs as well as on a CPU, and compare those to what a native version of the code achieves on each platform.

Published

2024

5. QMCPACK : An open source ab initio Quantum Monte Carlo package for the electronic structure of atoms, molecules, and solids

Author

Kim, Jeongnim, Baczewski, Andrew, Beaudet, Todd D., Benali, Anouar, Bennett, M. Chandler, Berrill, Mark A., Blunt, Nick S., Borda, Edgar Josue Landinez, Casula, Michele, Ceperley, David M., Chiesa, Simone, Clark, Bryan K., Clay III, Raymond C., Delaney, Kris T., Dewing, Mark, Esler, Kenneth P., Hao, Hongxia, Heinonen, Olle, Kent, Paul R. C., Krogel, Jaron T., Kylanpaa, Ilkka, Li, Ying Wai, Lopez, M. Graham, Luo, Ye, Malone, Fionn D., Martin, Richard M., Mathuriya, Amrita, McMinis, Jeremy, Melton, Cody A., Mitas, Lubos, Morales, Miguel A., Neuscamman, Eric, Parker, William D., Flores, Sergio D. Pineda, Romero, Nichols A., Rubenstein, Brenda M., Shea, Jacqueline A. R., Shin, Hyeondeok, Shulenburger, Luke, Tillack, Andreas, Townsend, Joshua P., Tubman, Norm M., Van Der Goetz, Brett, Vincent, Jordan E., Yang, D. ChangMo, Yang, Yubo, Zhang, Shuai, and Zhao, Luning

Subjects

Physics - Computational Physics, Physics - Chemical Physics

Abstract

QMCPACK is an open source quantum Monte Carlo package for ab-initio electronic structure calculations. It supports calculations of metallic and insulating solids, molecules, atoms, and some model Hamiltonians. Implemented real space quantum Monte Carlo algorithms include variational, diffusion, and reptation Monte Carlo. QMCPACK uses Slater-Jastrow type trial wave functions in conjunction with a sophisticated optimizer capable of optimizing tens of thousands of parameters. The orbital space auxiliary field quantum Monte Carlo method is also implemented, enabling cross validation between different highly accurate methods. The code is specifically optimized for calculations with large numbers of electrons on the latest high performance computing architectures, including multicore central processing unit (CPU) and graphical processing unit (GPU) systems. We detail the program's capabilities, outline its structure, and give examples of its use in current research calculations. The package is available at http://www.qmcpack.org .

Published

2018

6. The Coupled Electronic-Ionic Monte Carlo Simulation Method

Author

Ceperley, David, Dewing, Mark, and Pierleoni, Carlo

Subjects

Physics - Computational Physics, Physics - Chemical Physics

Abstract

Quantum Monte Carlo (QMC) methods such as Variational Monte Carlo, Diffusion Monte Carlo or Path Integral Monte Carlo are the most accurate and general methods for computing total electronic energies. We will review methods we have developed to perform QMC for the electrons coupled to a classical Monte Carlo simulation of the ions. In this method, one estimates the Born-Oppenheimer energy E(Z) where Z represents the ionic degrees of freedom. That estimate of the energy is used in a Metropolis simulation of the ionic degrees of freedom. Important aspects of this method are how to deal with the noise, which QMC method and which trial function to use, how to deal with generalized boundary conditions on the wave function so as to reduce the finite size effects. We discuss some advantages of the CEIMC method concerning how the quantum effects of the ionic degrees of freedom can be included and how the boundary conditions can be integrated over. Using these methods, we have performed simulations of liquid H2 and metallic H on a parallel computer., Comment: 27 pages, 10 figures

Published

2002

7. Monte Carlo methods: Application to hydrogen gas and hard spheres

Author

Dewing, Mark

Subjects

Physics - Computational Physics, Physics - Chemical Physics

Abstract

Quantum Monte Carlo (QMC) methods can very accurately compute ground state properties of quantum systems. We applied these methods to a system of boson hard spheres to get exact, infinite system size results for the ground state at several densities. Variational Monte Carlo (VMC) requires optimizing a parameterized wave function to find the minimum energy. We examine several techniques for optimizing VMC wave functions, focusing on the ability to optimize parameters appearing in the Slater determinant. The kinds of problems that can be simulated with Monte Carlo methods are expanded through the development of new algorithms for combining a QMC simulation of the electrons with a classical Monte Carlo simulation for the nuclei, which we call Coupled Electronic-Ionic Monte Carlo (CEIMC). The new CEIMC method is applied to a system of molecular hydrogen at temperatures ranging from 2800K to 4500K and densities from 0.25 to 0.46 g/cm**3. The challenges in constructing an efficient CEIMC simulation center mostly around the noisy results generated from the QMC computations of the electronic energy. The penalty method is a modification of the Metropolis method that can tolerate noise. An improved correlated sampling method, the two-sided energy difference method, is also presented as a method for reducing the noise., Comment: 97 pages, Ph. D. thesis, see also http://www.ncsa.uiuc.edu/Apps/CMP/dewing/thesis/index.html

Published

2000

8. Improved efficiency with variational Monte Carlo using two level sampling

Author

Dewing, Mark

Subjects

Physics - Computational Physics

Abstract

A two level sampling method is applied to variational Monte Carlo (VMC) that samples the one and two body parts of the wave function separately. The method is demonstrated on a single Li_2 molecule in free space and 32 H_2 molecules in a periodic box. This simple modification increases the efficiency of a VMC simulation by up to 72%.

Published

2000

9. Intel® Thread Profiler

Author

Dewing, Mark, Armstrong, Douglas, and Padua, David, editor

Published

2011

10. Development of QMCPACK for Exascale Scientific Computing

Author

Benali, Anouar, primary, Ceperley, David M., additional, D'Azevedo, Eduardo, additional, Dewing, Mark, additional, Kent, Paul R. C., additional, Kim, Jeongnim, additional, Krogel, Jaron T., additional, Li, Ying Wai, additional, Luo, Ye, additional, McDaniel, Tyler, additional, Morales, Miguel A., additional, Mathuriya, Amrita, additional, Shulenburger, Luke, additional, and Tubman, Norm M., additional

Published

2017

11. Towards QMCPACK Performance Portability.

Author

Kent, Paul, primary, Doak, Peter, additional, Krogel, Jaron, additional, Clay, III, Raymond, additional, Melton, Cody, additional, Shulenburger, Luke, additional, Correa, Alfredo, additional, Morales-Silva, Miguel, additional, Benali, Anouar, additional, Dewing, Mark, additional, Luo, Ye, additional, Shin, Hyeondeok, additional, Briggs, Emil, additional, Lu, Wengcheng, additional, and Bernholc, Jerry, additional

Published

2021

12. iPSC

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

13. IBM SP2

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

14. IBM PowerPC

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

15. IBM RS/6000 SP

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

16. Intel Celeron

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

17. IBM System/360 Model 91

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

18. Interconnection Networks

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

19. Intel® Thread Profiler

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

20. Internet Data Centers

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

21. IEEE 802.3

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

22. IBM Blue Gene Supercomputer

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

23. Intel® Parallel Studio

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

24. Inter-Process Communication

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

25. Illegal Memory Access

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

26. Instruction Systolic Arrays

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

27. Intel®Parallel Inspector

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

28. Intel Core Microarchitecture, x86 Processor Family

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

29. Instruction-Level Parallelism

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

30. IBM Power Architecture

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

31. Implementations of Shared Memory in Software

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

32. Instant Replay

Author

Gara, Alan, primary, Moreira, José E., additional, Karkhanis, Tejas S., additional, Flynn, Michael, additional, Muraoka, Yoichi, additional, Bollhöfer, Matthias, additional, Aliaga, José I., additional, Martı́n, Alberto F., additional, Quintana-Ortí, Enrique S., additional, Panda, Dhabaleswar K., additional, Sur, Sayantan, additional, Weidendorfer, Josef, additional, Petersen, Paul, additional, Dewing, Mark, additional, Armstrong, Douglas, additional, Robison, Arch D., additional, Yalamanchili, Sudhakar, additional, Ma, Xiaosong, additional, and Padua, David, additional

Published

2011

33. METHODS FOR COUPLED ELECTRONIC-IONIC MONTE CARLO

Author

DEWING, MARK, primary and CEPERLEY, DAVID, additional

Published

2002

34. The Coupled Electronic-Ionic Monte Carlo Simulation Method

Author

Ceperley, David, primary, Dewing, Mark, additional, and Pierleoni, Carlo, additional

Published

2002

35. QMCPACK: an open sourceab initioquantum Monte Carlo package for the electronic structure of atoms, molecules and solids

Author

Kim, Jeongnim, primary, Baczewski, Andrew D, additional, Beaudet, Todd D, additional, Benali, Anouar, additional, Bennett, M Chandler, additional, Berrill, Mark A, additional, Blunt, Nick S, additional, Borda, Edgar Josué Landinez, additional, Casula, Michele, additional, Ceperley, David M, additional, Chiesa, Simone, additional, Clark, Bryan K, additional, Clay, Raymond C, additional, Delaney, Kris T, additional, Dewing, Mark, additional, Esler, Kenneth P, additional, Hao, Hongxia, additional, Heinonen, Olle, additional, Kent, Paul R C, additional, Krogel, Jaron T, additional, Kylänpää, Ilkka, additional, Li, Ying Wai, additional, Lopez, M Graham, additional, Luo, Ye, additional, Malone, Fionn D, additional, Martin, Richard M, additional, Mathuriya, Amrita, additional, McMinis, Jeremy, additional, Melton, Cody A, additional, Mitas, Lubos, additional, Morales, Miguel A, additional, Neuscamman, Eric, additional, Parker, William D, additional, Pineda Flores, Sergio D, additional, Romero, Nichols A, additional, Rubenstein, Brenda M, additional, Shea, Jacqueline A R, additional, Shin, Hyeondeok, additional, Shulenburger, Luke, additional, Tillack, Andreas F, additional, Townsend, Joshua P, additional, Tubman, Norm M, additional, Van Der Goetz, Brett, additional, Vincent, Jordan E, additional, Yang, D ChangMo, additional, Yang, Yubo, additional, Zhang, Shuai, additional, and Zhao, Luning, additional

Published

2018

36. Constructing scientific programs using SymPy

Author

Dewing, Mark, primary

Published

2011

37. Metropolis with noise: The penalty method

Author

Dewing, Mark, primary

Published

2003