A Fortran 90-based multiprecision system

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A Fortran 90-based multiprecision system

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ACM Transactions on Mathematical Software (TOMS) archive
Volume 21 , Issue 4 (December 1995) table of contents

Pages: 379 - 387

Year of Publication: 1995

ISSN:0098-3500

Author

David H. Bailey

NASA Ames Research Center, Moffett Field, CA

Publisher

ACM New York, NY, USA

Bibliometrics

Downloads (6 Weeks): 6, Downloads (12 Months): 51, Citation Count: 9

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abstract references cited by index terms review collaborative colleagues

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ABSTRACT

A new version of a Fortran multiprecision computation system, based on the Fortran 90 language, is described. With this new approach, a translator program is not required—translation of Fortran code for multiprecision is accomplished by merely utilizing advanced features of Fortran 90, such as derived data types and operator extensions. This approach results in more-reliable translation and permits programmers of multiprecision applications to utilize the full power of Fortran 90. Three multiprecision data types are supported in this system: multiprecision integer, real, and complex. All the usual Fortran conventions for mixed-mode operations are supported, and many of the Fortran intrinsics, such as SIN, EXP, and MOD, are supported with multiprecision arguments. An interesting application of this software, wherein new number-theoretic identities have been discovered by means of multiprecision computations, is included also.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	D. H. Bailey, FFTs in external or hierarchical memory, The Journal of Supercomputing, v.4 n.1, p.23-35, Mar. 1990 [doi>10.1007/BF00162341]
	2	BAILEY, D.H. 1990b. A portable high performance multiprecision package. NASA Ames RNR Tech. Rep. RNR-90-022, NASA Ames Research Center, Moffett Field, Calif.
	3	David H. Bailey, Algorithm 719; Multiprecision translation and execution of FORTRAN programs, ACM Transactions on Mathematical Software (TOMS), v.19 n.3, p.288-319, Sept. 1993 [doi>10.1145/155743.155767]
	4	BAILEY, D. H., BORWEIN, J. M., AND GIRGENSOHN, R. 1994. Experimental evaluation of Euler sums. Exper. Math. 3, 1, 17-30.
	5	FERGUSON, H. e. P. AND BAILEY, D.H. 1991. A polynomial time, numerically stable integer relation algorithm. NASA Ames RNR Tech. Rep. RNR-91-032, NASA Ames Research Center, Moffett Field, Calif.
	6	J. Håstad , B. Just , J. C. Lagarias , C. P. Schnorr, Polynomial time algorithms for finding integer relations among real numbers, SIAM Journal on Computing, v.18 n.5, p.859-881, Oct. 1989 [doi>10.1137/0218059]
	7	David M. Smith, A multiple-precision division algorithm, Mathematics of Computation, v.65 n.213, p.157-163, Jan. 1996 [doi>10.1090/S0025-5718-96-00688-6]

CITED BY 9

	David M. Smith, Algorithm 786: multiple-precision complex arithmetic and functions, ACM Transactions on Mathematical Software (TOMS), v.24 n.4, p.359-367, Dec. 1998
	David H. Bailey , David Broadhurst , Yozo Hida , Xiaoye S. Li , Brandon Thompson, High performance computing meets experimental mathematics, Proceedings of the 2002 ACM/IEEE conference on Supercomputing, p.1-12, November 16, 2002, Baltimore, Maryland
	Bridgitte Verdonk , Annie Cuyt , Dennis Verschaeren, A precision- and range-independent tool for testing floating-point arithmetric I: basic operations, square root, and remainder, ACM Transactions on Mathematical Software (TOMS), v.27 n.1, p.92-118, March 2001
	David H. Bailey, Integer Relation Detection, Computing in Science and Engineering, v.2 n.1, p.24-28, January 2000
	Xiaoye S. Li , James W. Demmel , David H. Bailey , Greg Henry , Yozo Hida , Jimmy Iskandar , William Kahan , Suh Y. Kang , Anil Kapur , Michael C. Martin , Brandon J. Thompson , Teresa Tung , Daniel J. Yoo, Design, implementation and testing of extended and mixed precision BLAS, ACM Transactions on Mathematical Software (TOMS), v.28 n.2, p.152-205, June 2002
	Ronald Cools, An encyclopaedia of cubature formulas, Journal of Complexity, v.19 n.3, p.445-453, June 2003
	R. Barrio , S. Serrano, Generation and evaluation of orthogonal polynomials in discrete Sobolev spaces II: numerical stability, Journal of Computational and Applied Mathematics, v.181 n.2, p.299-320, 15 September 2005
	Fatih Celiker , Bernardo Cockburn, Element-by-Element Post-Processing of Discontinuous Galerkin Methods for Timoshenko Beams, Journal of Scientific Computing, v.27 n.1-3, p.177-187, June 2006
	Walter Schreppers , Annie Cuyt, Algorithm 871: A C/C++ precompiler for autogeneration of multiprecision programs, ACM Transactions on Mathematical Software (TOMS), v.34 n.1, p.1-20, January 2008

INDEX TERMS

Primary Classification:
D. Software
D.3 PROGRAMMING LANGUAGES
D.3.2 Language Classifications

Nouns: Fortran 90

Additional Classification:
D. Software
D.3 PROGRAMMING LANGUAGES

G. Mathematics of Computing
G.1 NUMERICAL ANALYSIS

General Terms:
Languages, Performance

Keywords:
Fortran 90, arithmetic, multiprecision

REVIEW

"Peter Turner : Reviewer"

Bailey presents a new version of a Fortran multiprecision computation system using Fortran 90. Unlike its predecessors, this new approach does not require a translator program. The translation of Fortran code is accomplished by using the advan more...

Collaborative Colleagues:

David H. Bailey: colleagues

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