Samplesort: A Sampling Approach to Minimal Storage Tree Sorting

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Samplesort: A Sampling Approach to Minimal Storage Tree Sorting

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Journal of the ACM (JACM) archive
Volume 17 , Issue 3 (July 1970) table of contents

Pages: 496 - 507

Year of Publication: 1970

ISSN:0004-5411

Authors

W. D. Frazer	IBM Corporation, Department of Electrical Engineering, Princeton University, Princeton, N.J and IBM Corporation, Thomas J. Watson Research Center, Yorktown Heights, New York
A. C. McKellar	Polytechnic Institute of Brooklyn, Brooklyn, N.Y and Princeton University, Department of Electrical Engineering, Princeton, New Jersey

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ACM New York, NY, USA

Bibliometrics

Downloads (6 Weeks): 15, Downloads (12 Months): 56, Citation Count: 19

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ABSTRACT

The methods currently in use and previously proposed for the choice of a root in minimal storage tree sorting are in reality methods for making inefficient statistical estimates of the median of the sequence to be sorted. By making efficient use of the information in a random sample chosen during input of the sequence to be sorted, significant improvements over ordinary minimal storage tree sorting can be made. A procedure is proposed which is a generalization of minimal storage tree sorting and which has the following three properties: (a) There is a significant improvement (over ordinary minimal storage tree sorting) in the expected number of comparisons required to sort the input sequence. (b) The procedure is statistically insensitive to bias in the input sequence. (c) The expected number of comparisons required by the procedure approaches (slowly) the information-theoretic lower bound on the number of comparisons required. The procedure is, therefore, “asymptotically optimal.”

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	BELL, D.A. The principles of sorting. Computer J . 1, 1 (1958), 71-77.
	2	C. C. Gotlieb, Sorting on computers, Communications of the ACM, v.6 n.5, p.194-201, May 1963 [doi>10.1145/366552.366555]
	3	R. M. Frank , R. B. Lazarus, A high-speed sorting procedure, Communications of the ACM, v.3 n.1, p.20-22, Jan. 1960 [doi>10.1145/366947.366957]
	4	Thomas N. Hibbard, Some Combinatorial Properties of Certain Trees With Applications to Searching and Sorting, Journal of the ACM (JACM), v.9 n.1, p.13-28, Jan. 1962 [doi>10.1145/321105.321108]
	5	Thomas N. Hibbard, An empirical study of minimal storage sorting, Communications of the ACM, v.6 n.5, p.206-213, May 1963 [doi>10.1145/366552.366557]
	6	HOARE, C. A.R. Quicksort. Computer J. 5 (1962), 10-15.
	7	KNUTH, D .E . Personal communication.
	8	MORRIS, R. Some theorems on sorting. SIAM J. Appl. Math. 17, 1 (Jan. 1969), 1-6.
	9	D. L. Shell, A high-speed sorting procedure, Communications of the ACM, v.2 n.7, p.30-32, July 1959 [doi>10.1145/368370.368387]
	10	SIEGEL, S. Nonparametric Statistics. McGraw-Hill, New York, 1956. 11. WINDLEY, P .F . Trees, forests and rearranging. Computer J . 3, 2 (1960), 84-88.

CITED BY 19

	W. A. Martin, Sorting, ACM Computing Surveys (CSUR), v.3 n.4, p.147-174, Dec. 1971
	Michael T. Goodrich, Communication-efficient parallel sorting (preliminary version), Proceedings of the twenty-eighth annual ACM symposium on Theory of computing, p.247-256, May 22-24, 1996, Philadelphia, Pennsylvania, United States
	William L. Hightower , Jan F. Prins , John H. Reif, Implementations of randomized sorting on large parallel machines, Proceedings of the fourth annual ACM symposium on Parallel algorithms and architectures, p.158-167, June 29-July 01, 1992, San Diego, California, United States
	Rudolf Loeser, Some performance tests of “quicksort” and descendants, Communications of the ACM, v.17 n.3, p.143-152, March 1974
	Guy E. Blelloch , Charles E. Leiserson , Bruce M. Maggs , C. Greg Plaxton , Stephen J. Smith , Marco Zagha, A comparison of sorting algorithms for the connection machine CM-2, Proceedings of the third annual ACM symposium on Parallel algorithms and architectures, p.3-16, July 21-24, 1991, Hilton Head, South Carolina, United States
	Theodore Brown, Remark on “Algorithm 489: The Algorithm SELECT—for Finding the ith Smallest of n Elements [M1]”, ACM Transactions on Mathematical Software (TOMS), v.2 n.3, p.301-304, Sept. 1976
	Robert Sedgewick, Implementing Quicksort programs, Communications of the ACM, v.21 n.10, p.847-857, Oct. 1978
	H. Hurwitz, Jr., On the probability distribution of the values of binary trees, Communications of the ACM, v.14 n.2, p.99-102, Feb. 1971
	Rudolf Loeser, Survey on Algorithms 347, 426, and Quicksort, ACM Transactions on Mathematical Software (TOMS), v.2 n.3, p.290-299, Sept. 1976
	Jop F. Sibeyn, Faster deterministic sorting through better sampling, Theoretical Computer Science, v.290 n.3, p.1829-1850, 3 January 2003
	Vladmir Estivill-Castro , Derick Wood, A survey of adaptive sorting algorithms, ACM Computing Surveys (CSUR), v.24 n.4, p.441-476, Dec. 1992
	Andrew Sohn , Yuetsu Kodama, Load balanced parallel radix sort, Proceedings of the 12th international conference on Supercomputing, p.305-312, July 1998, Melbourne, Australia
	Sanguthevar Rajasekaran , Sartaj Sahni, Randomized Routing, Selection, and Sorting on the OTIS-Mesh, IEEE Transactions on Parallel and Distributed Systems, v.9 n.9, p.833-840, September 1998
	Joseph JaJa, A Perspective on Quicksort, Computing in Science and Engineering, v.2 n.1, p.43-49, January 2000
	Vijaya Ramachandran , Brian Grayson , Michael Dahlin, Emulations between QSM, BSP and LogP: a framework for general-purpose parallel algorithm design, Journal of Parallel and Distributed Computing, v.63 n.12, p.1175-1192, December 2003
	Jing-Chao Chen, Efficient sample sort and the average case analysis or PEsort, Theoretical Computer Science, v.369 n.1, p.44-66, 15 December 2006
	Qi Yang , Son Dao , Clement Yu , Naphtali Rishe, A Parallel Scheme Using the Divide-and-Conquer Method, Distributed and Parallel Databases, v.5 n.4, p.405-438, Oct. 1997
	W. D. Frazer, Analysis of combinatory algorithms: a sample of current methodology, Proceedings of the November 16-18, 1971, fall joint computer conference, November 16-18, 1971, Las Vegas, Nevada
	Guy E. Blelloch , Phillip B. Gibbons , Harsha Vardhan Simhadri, Brief announcement: low depth cache-oblivious sorting, Proceedings of the twenty-first annual symposium on Parallelism in algorithms and architectures, August 11-13, 2009, Calgary, AB, Canada