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ORCID8. PGAS 2014: Eugene, OR, USA
- Allen D. Malony, Jeff R. Hammond:
Proceedings of the 8th International Conference on Partitioned Global Address Space Programming Models, PGAS 2014, Eugene, OR, USA, October 6-10, 2014. ACM 2014, ISBN 978-1-4503-3247-7
PGAS 2014
- Miao Luo, Kayla Seager, Karthik S. Murthy, Charles J. Archer, Sayantan Sur, Sean Hefty:
Early Evaluation of Scalable Fabric Interface for PGAS Programming Models. 1:1-1:13 - Ruediger Willenberg, Paul Chow:
A Heterogeneous GASNet Implementation for FPGA-accelerated Computing. 2:1-2:9 - Huan Zhou, Yousri Mhedheb, Kamran Idrees, Colin W. Glass, José Gracia
, Karl Fürlinger:
DART-MPI: An MPI-based Implementation of a PGAS Runtime System. 3:1-3:11 - Alessandro Fanfarillo, Tobias Burnus, Valeria Cardellini, Salvatore Filippone, Dan Nagle, Damian W. I. Rouson:
OpenCoarrays: Open-source Transport Layers Supporting Coarray Fortran Compilers. 4:1-4:11 - Vivek Kumar, Yili Zheng, Vincent Cavé, Zoran Budimlic, Vivek Sarkar:
HabaneroUPC++: a Compiler-free PGAS Library. 5:1-5:10 - Hartmut Kaiser, Thomas Heller, Bryce Adelstein-Lelbach, Adrian Serio, Dietmar Fey:
HPX: A Task Based Programming Model in a Global Address Space. 6:1-6:11 - Jithin Jose, Sreeram Potluri, Hari Subramoni, Xiaoyi Lu, Khaled Hamidouche, Karl W. Schulz, Hari Sundar, Dhabaleswar K. Panda:
Designing Scalable Out-of-core Sorting with Hybrid MPI+PGAS Programming Models. 7:1-7:9 - Hongzhang Shan, Amir Kamil, Samuel Williams, Yili Zheng, Katherine A. Yelick:
Evaluation of PGAS Communication Paradigms with Geometric Multigrid. 8:1-8:12 - A. C. Mallinson, Stephen A. Jarvis, W. P. Gaudin, J. A. Herdman:
Experiences at scale with PGAS versions of a Hydrodynamics application. 9:1-9:11 - James Dinan, Mario Flajslik:
Contexts: A Mechanism for High Throughput Communication in OpenSHMEM. 10:1-10:9 - Aaron Welch, Swaroop Pophale, Pavel Shamis, Oscar R. Hernandez, Stephen W. Poole, Barbara M. Chapman:
Extending the OpenSHMEM Memory Model to Support User-Defined Spaces. 11:1-11:10 - Naveen Namashivayam, Sayan Ghosh, Dounia Khaldi, Deepak Eachempati, Barbara M. Chapman:
Native Mode-Based Optimizations of Remote Memory Accesses in OpenSHMEM for Intel Xeon Phi. 12:1-12:11 - Aroon Sharma, Darren Smith, Joshua Koehler, Rajeev Barua, Michael Ferguson:
Affine Loop Optimization Based on Modulo Unrolling in Chapel. 13:1-13:12 - Tatsuya Abe, Toshiyuki Maeda:
Optimization of a General Model Checking Framework for Various Memory Consistency Models. 14:1-14:10 - Siddhartha Jana, Joseph Schuchart, Barbara M. Chapman:
Analysis of Energy and Performance of PGAS-based Data Access Patterns. 15:1-15:10
OpenSHMEM Users Group
- Aurélien Bouteiller, Thomas Hérault, George Bosilca:
A Multithreaded Communication Substrate for OpenSHMEM. 16:1-16:2 - Jeff R. Hammond:
Towards a matrix-oriented strided interface in OpenSHMEM. 17:1-17:3 - Tomislav Janjusic, Pavel Shamis, Manjunath Gorentla Venkata, Stephen W. Poole:
OpenSHMEM Reference Implementation using UCCS-uGNI Transport Layer. 18:1-18:4 - James Dinan, Mario Flajslik:
One-Sided Append: A New Communication Paradigm For PGAS Models. 19:1-19:5 - Pavel Shamis, Manjunath Gorentla Venkata, Stephen W. Poole, Swaroop Pophale, Michael Dubman, Richard L. Graham, Dror Goldenberg, Gilad Shainer:
Development and Extension of Atomic Memory Operations in OpenSHMEM. 20:1-20:4 - Gabriele Jost, Ulf R. Hanebutte, James Dinan:
Multi-Threaded OpenSHMEM: A Bad Idea? 21:1-21:4 - Latchesar Ionkov, Ginger Young:
Asymmetric Memory Extension for Openshmem. 22:1-22:2 - Pengfei Hao, Pavel Shamis, Manjunath Gorentla Venkata, Swaroop Pophale, Aaron Welch, Stephen W. Poole, Barbara M. Chapman:
Fault Tolerance for OpenSHMEM. 23:1-23:3 - Mingzhe Li, Jian Lin, Xiaoyi Lu, Khaled Hamidouche, Karen Tomko, Dhabaleswar K. Panda:
Scalable MiniMD Design with Hybrid MPI and OpenSHMEM. 24:1-24:4 - Khaled Z. Ibrahim:
Efficient Interoperability of OpenSHMEM on Multicore Architectures. 25:1-25:3
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