Template:Heap Running Times/doc

This is a documentation subpage for Template:Heap Running Times. It may contain usage information, categories and other content that is not part of the original template page.

Objective

{{Heap Running Times}} provides time complexity information for operations across different types of heaps.

Usage

{{Heap Running Times |mode = min}}

where

mode

optional parameter. If present and set to "max", present information for max heap; otherwise present for min heap

Examples

Here are time complexities^[1] of various heap data structures. Function names assume a min-heap. For the meaning of "O(f)" and "Θ(f)" see Big O notation.

Operation	find-min	delete-min	insert	decrease-key	meld
Binary[1]	Θ(1)	Θ(log n)	O(log n)	O(log n)	Θ(n)
Leftist	Θ(1)	Θ(log n)	Θ(log n)	O(log n)	Θ(log n)
Binomial[1][2]	Θ(1)	Θ(log n)	Θ(1)[a]	Θ(log n)	O(log n)
Skew binomial[3]	Θ(1)	Θ(log n)	Θ(1)	Θ(log n)	O(log n)[b]
Pairing[4]	Θ(1)	O(log n)[a]	Θ(1)	o(log n)[a][c]	Θ(1)
Rank-pairing[7]	Θ(1)	O(log n)[a]	Θ(1)	Θ(1)[a]	Θ(1)
Fibonacci[1][8]	Θ(1)	O(log n)[a]	Θ(1)	Θ(1)[a]	Θ(1)
Strict Fibonacci[9]	Θ(1)	O(log n)	Θ(1)	Θ(1)	Θ(1)
Brodal[10][d]	Θ(1)	O(log n)	Θ(1)	Θ(1)	Θ(1)
2–3 heap[12]	Θ(1)	O(log n)[a]	Θ(1)[a]	Θ(1)	O(log n)

1. Amortized time.
2. Brodal and Okasaki describe a technique to reduce the worst-case complexity of meld to Θ(1); this technique applies to any heap datastructure that has insert in Θ(1) and find-min, delete-min, meld in O(log n).
3. Lower bound of ${\displaystyle \Omega (\log \log n),}$^[5] upper bound of ${\displaystyle O(2^{2{\sqrt {\log \log n}}}).}$^[6]
4. Brodal and Okasaki later describe a persistent variant with the same bounds except for decrease-key, which is not supported. Heaps with n elements can be constructed bottom-up in O(n).^[11]

1. Cormen, Thomas H.; Leiserson, Charles E.; Rivest, Ronald L. (1990). Introduction to Algorithms (1st ed.). MIT Press and McGraw-Hill. ISBN 0-262-03141-8.
2. "Binomial Heap | Brilliant Math & Science Wiki". brilliant.org. Retrieved 2019-09-30.
3. Brodal, Gerth Stølting; Okasaki, Chris (November 1996), "Optimal purely functional priority queues", Journal of Functional Programming, 6 (6): 839–857, doi:10.1017/s095679680000201x
4. Iacono, John (2000), "Improved upper bounds for pairing heaps", Proc. 7th Scandinavian Workshop on Algorithm Theory (PDF), Lecture Notes in Computer Science, vol. 1851, Springer-Verlag, pp. 63–77, arXiv:1110.4428, CiteSeerX 10.1.1.748.7812, doi:10.1007/3-540-44985-X_5, ISBN 3-540-67690-2
5. Fredman, Michael Lawrence (July 1999). "On the Efficiency of Pairing Heaps and Related Data Structures" (PDF). Journal of the Association for Computing Machinery. 46 (4): 473–501. doi:10.1145/320211.320214.
6. Pettie, Seth (2005). Towards a Final Analysis of Pairing Heaps (PDF). FOCS '05 Proceedings of the 46th Annual IEEE Symposium on Foundations of Computer Science. pp. 174–183. CiteSeerX 10.1.1.549.471. doi:10.1109/SFCS.2005.75. ISBN 0-7695-2468-0.
7. Haeupler, Bernhard; Sen, Siddhartha; Tarjan, Robert E. (November 2011). "Rank-pairing heaps" (PDF). SIAM J. Computing. 40 (6): 1463–1485. doi:10.1137/100785351.
8. Fredman, Michael Lawrence; Tarjan, Robert E. (July 1987). "Fibonacci heaps and their uses in improved network optimization algorithms" (PDF). Journal of the Association for Computing Machinery. 34 (3): 596–615. CiteSeerX 10.1.1.309.8927. doi:10.1145/28869.28874.
9. Brodal, Gerth Stølting; Lagogiannis, George; Tarjan, Robert E. (2012). Strict Fibonacci heaps (PDF). Proceedings of the 44th symposium on Theory of Computing - STOC '12. pp. 1177–1184. CiteSeerX 10.1.1.233.1740. doi:10.1145/2213977.2214082. ISBN 978-1-4503-1245-5.
10. Brodal, Gerth S. (1996), "Worst-Case Efficient Priority Queues" (PDF), Proc. 7th Annual ACM-SIAM Symposium on Discrete Algorithms, pp. 52–58
11. Goodrich, Michael T.; Tamassia, Roberto (2004). "7.3.6. Bottom-Up Heap Construction". Data Structures and Algorithms in Java (3rd ed.). pp. 338–341. ISBN 0-471-46983-1.
12. Takaoka, Tadao (1999), Theory of 2–3 Heaps (PDF), p. 12