TY - GEN
T1 - Leveraging Task-Based Polar Decomposition Using PARSEC on Massively Parallel Systems
AU - Sukkari, Dalal E.
AU - Ltaief, Hatem
AU - Keyes, David E.
AU - Faverge, Mathieu
N1 - KAUST Repository Item: Exported on 2020-10-01
Acknowledgements: The authors would like also to thank Cray Inc. and Intel in the context of the Cray Center of Excellence and Intel Parallel Computing Center awarded to the Extreme Computing Research Center at KAUST. For computer time, this research used Shaheen-2 supercomputer hosted at the Supercomputing Laboratory at KAUST, a remote system hosted by our Cray partners, and by the PlaFRIM experimental testbed, supported by Inria, CNRS (LABRI and IMB), Universite de Bordeaux, Bordeaux INP and Conseil Regional d’Aquitaine.
PY - 2019/11/13
Y1 - 2019/11/13
N2 - This paper describes how to leverage a task-based implementation of the polar decomposition on massively parallel systems using the PaRSEC dynamic runtime system. Based on a formulation of the iterative QR Dynamically-Weighted Halley (QDWH) algorithm, our novel implementation reduces data traffic while exploiting high concurrency from the underlying hardware architecture. First, we replace the most time-consuming classical QR factorization phase with a new hierarchical variant, customized for the specific structure of the matrix during the QDWH iterations. The newly developed hierarchical QR for QDWH exploits not only the matrix structure, but also shortens the length of the critical path to maximize hardware occupancy. We then deploy Pa RSEC to seamlessly orchestrate, pipeline, and track the data dependencies of the various linear algebra building blocks involved during the iterative QDWH algorithm. PaRSEC enables to overlap communications with computations thanks to its asynchronous scheduling of fine-grained computational tasks. It employs look-ahead techniques to further expose parallelism, while actively pursuing the critical path. In addition, we identify synergistic opportunities between the task-based QDWH algorithm and the PaRSEC framework. We exploit them during the hierarchical QR factorization to enforce a locality-aware task execution. The latter feature permits to minimize the expensive inter-node communication, which represents one of the main bottlenecks for scaling up applications on challenging distributed-memory systems. We report numerical accuracy and performance results using well and ill-conditioned matrices. The benchmarking campaign reveals up to 2X performance speedup against the existing state-of-the-art implementation for the polar decomposition on 36, 864 cores.
AB - This paper describes how to leverage a task-based implementation of the polar decomposition on massively parallel systems using the PaRSEC dynamic runtime system. Based on a formulation of the iterative QR Dynamically-Weighted Halley (QDWH) algorithm, our novel implementation reduces data traffic while exploiting high concurrency from the underlying hardware architecture. First, we replace the most time-consuming classical QR factorization phase with a new hierarchical variant, customized for the specific structure of the matrix during the QDWH iterations. The newly developed hierarchical QR for QDWH exploits not only the matrix structure, but also shortens the length of the critical path to maximize hardware occupancy. We then deploy Pa RSEC to seamlessly orchestrate, pipeline, and track the data dependencies of the various linear algebra building blocks involved during the iterative QDWH algorithm. PaRSEC enables to overlap communications with computations thanks to its asynchronous scheduling of fine-grained computational tasks. It employs look-ahead techniques to further expose parallelism, while actively pursuing the critical path. In addition, we identify synergistic opportunities between the task-based QDWH algorithm and the PaRSEC framework. We exploit them during the hierarchical QR factorization to enforce a locality-aware task execution. The latter feature permits to minimize the expensive inter-node communication, which represents one of the main bottlenecks for scaling up applications on challenging distributed-memory systems. We report numerical accuracy and performance results using well and ill-conditioned matrices. The benchmarking campaign reveals up to 2X performance speedup against the existing state-of-the-art implementation for the polar decomposition on 36, 864 cores.
UR - http://hdl.handle.net/10754/660619
UR - https://ieeexplore.ieee.org/document/8891024/
UR - http://www.scopus.com/inward/record.url?scp=85075267554&partnerID=8YFLogxK
U2 - 10.1109/CLUSTER.2019.8891024
DO - 10.1109/CLUSTER.2019.8891024
M3 - Conference contribution
SN - 9781728147345
BT - 2019 IEEE International Conference on Cluster Computing (CLUSTER)
PB - IEEE
ER -