Parallelizing Strassen's method for matrix multiplication on distributed-memory MIMD architectures

C. C. Chou; Y. F. Deng; G. Li; Y. Wang

doi:10.1016/0898-1221(95)00077-C

Parallelizing Strassen's method for matrix multiplication on distributed-memory MIMD architectures

C. C. Chou
, Y. F. Deng
, G. Li
, Y. Wang

Applied Mathematics and Statistics

Stony Brook University

Stony Brook University

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

We present a parallel method for matrix multiplication on distributed-memory MIMD architectures based on Strassen's method. Our timing tests, performed on a 56-node Intel Paragon, demonstrate the realization of the potential of the Strassen's method with a complexity of 4.7 M^2.807 at the system level rather than the node level at which several earlier works have been focused. The parallel efficiency is nearly perfect when the processor number is the power of 7. The parallelized Strassen's method seems always faster than the traditional matrix multiplication methods whose complexity is 2M³ coupled with the BMR method and the Ring method at the system level. The speed gain depends on matrix order M: 20% for M ≈ 1000 and more than 100% for M ≈ 5000.

Original language	English
Pages (from-to)	49-69
Number of pages	21
Journal	Computers and Mathematics with Applications
Volume	30
Issue number	2
DOIs	https://doi.org/10.1016/0898-1221(95)00077-C
State	Published - Jul 1995

Keywords

Matrix multiplication
Parallel computation
Strassen's method

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10.1016/0898-1221(95)00077-C

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abstract = "We present a parallel method for matrix multiplication on distributed-memory MIMD architectures based on Strassen's method. Our timing tests, performed on a 56-node Intel Paragon, demonstrate the realization of the potential of the Strassen's method with a complexity of 4.7 M2.807 at the system level rather than the node level at which several earlier works have been focused. The parallel efficiency is nearly perfect when the processor number is the power of 7. The parallelized Strassen's method seems always faster than the traditional matrix multiplication methods whose complexity is 2M3 coupled with the BMR method and the Ring method at the system level. The speed gain depends on matrix order M: 20\% for M ≈ 1000 and more than 100\% for M ≈ 5000.",

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AU - Chou, C. C.

AU - Deng, Y. F.

AU - Li, G.

AU - Wang, Y.

PY - 1995/7

Y1 - 1995/7

N2 - We present a parallel method for matrix multiplication on distributed-memory MIMD architectures based on Strassen's method. Our timing tests, performed on a 56-node Intel Paragon, demonstrate the realization of the potential of the Strassen's method with a complexity of 4.7 M2.807 at the system level rather than the node level at which several earlier works have been focused. The parallel efficiency is nearly perfect when the processor number is the power of 7. The parallelized Strassen's method seems always faster than the traditional matrix multiplication methods whose complexity is 2M3 coupled with the BMR method and the Ring method at the system level. The speed gain depends on matrix order M: 20% for M ≈ 1000 and more than 100% for M ≈ 5000.

AB - We present a parallel method for matrix multiplication on distributed-memory MIMD architectures based on Strassen's method. Our timing tests, performed on a 56-node Intel Paragon, demonstrate the realization of the potential of the Strassen's method with a complexity of 4.7 M2.807 at the system level rather than the node level at which several earlier works have been focused. The parallel efficiency is nearly perfect when the processor number is the power of 7. The parallelized Strassen's method seems always faster than the traditional matrix multiplication methods whose complexity is 2M3 coupled with the BMR method and the Ring method at the system level. The speed gain depends on matrix order M: 20% for M ≈ 1000 and more than 100% for M ≈ 5000.

KW - Matrix multiplication

KW - Parallel computation

KW - Strassen's method

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DO - 10.1016/0898-1221(95)00077-C

M3 - Article

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SP - 49

EP - 69

JO - Computers and Mathematics with Applications

JF - Computers and Mathematics with Applications

IS - 2

ER -

Parallelizing Strassen's method for matrix multiplication on distributed-memory MIMD architectures

Abstract

Keywords

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