@inproceedings{752f05ec41614db9abf1fbec6e5e2502,
title = "Scalable tile communication-avoiding QR factorization on multicore cluster systems",
abstract = "As tile linear algebra algorithms continue achieving high performance on shared-memory multicore architectures, it is a challenging task to make them scalable on distributed-memory multicore cluster machines. The main contribution of this paper is the extension to the distributed-memory environment of the previous work done by Hadri et al. on Communication-Avoiding QR (CA-QR) factorizations for tall and skinny matrices (initially done on shared-memory multicore systems). The fine granularity of tile algorithms associated with communication-avoiding techniques for the QR factorization presents a high degree of parallelism where multiple tasks can be concurrently executed, computation and communication largely overlapped, and computation steps fully pipelined. A decentralized dynamic scheduler has then been integrated as a runtime system to efficiently schedule tasks across the distributed resources. Our experimental results performed on two clusters (with dual-core and 8-core nodes, respectively) and a Cray XT5 system with 12-core nodes show that the tile CA-QR factorization is able to outperform the de facto ScaLAPACK library by up to 4 times for tall and skinny matrices, and has good scalability on up to 3,072 cores.",
author = "Fengguang Song and Hatem Ltaief and Bilel Hadri and Jack Dongarra",
year = "2010",
doi = "10.1109/SC.2010.48",
language = "English (US)",
isbn = "9781424475575",
series = "2010 ACM/IEEE International Conference for High Performance Computing, Networking, Storage and Analysis, SC 2010",
booktitle = "2010 ACM/IEEE International Conference for High Performance Computing, Networking, Storage and Analysis, SC 2010",
note = "2010 ACM/IEEE International Conference for High Performance Computing, Networking, Storage and Analysis, SC 2010 ; Conference date: 13-11-2010 Through 19-11-2010",
}