Log-Lists and Their Applications to Sorting by Transpositions, Reversals and Block-Interchanges
July 06, 2015 Β· Declared Dead Β· π Theoretical Computer Science
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Authors
Irena Rusu
arXiv ID
1507.01512
Category
cs.DS: Data Structures & Algorithms
Citations
5
Venue
Theoretical Computer Science
Last Checked
4 months ago
Abstract
Link-cut trees have been introduced by D.D. Sleator and R.E. Tarjan (Journal of Computer and System Sciences, 1983) with the aim of efficiently maintaining a forest of vertex-disjoint dynamic rooted trees under cut and link operations. These operations respectively disconnect a subtree from a tree, and join two trees by an edge. Additionally, link-cut trees allow to change the root of a tree and to perform a number of updates and queries on cost values defined on the arcs of the trees. All these operations are performed in $O(\log\, n)$ amortized or worst-case time, depending on the implementation, where $n$ is the total size of the forest. In this paper, we show that a list of elements implemented using link-cut trees (we call it a $\log$-list) allows us to obtain a common running time of $O(\log\, n)$ for the classical operations on lists, but also for some other essential operations that usually take linear time on lists. Such operations require to find the minimum/maximum element in a sublist defined by its endpoints, the position of a given element in the list or the element placed at a given position in the list; or they require to add a value $a$, or to multiply by $-1$, all the elements in a sublist. Furthermore, we use $\log$-lists to implement several existing algorithms for sorting permutations by transpositions and/or reversals and/or block-interchanges, and obtain $O(n\,\log\, n)$ running time for all of them. In this way, the running time of several algorithms is improved, whereas in other cases our algorithms perform as well as the best existing implementations.
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