Computing covers using prefix tables

Ali Alatabbi; M. Sohel Rahman; W. F. Smyth

doi:10.1016/j.dam.2015.05.019

Computing covers using prefix tables

Ali Alatabbi^*, M. Sohel Rahman, W. F. Smyth

^*Corresponding author for this work

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

8 Citations (Scopus)

Abstract

An indeterminate string x=x[1..n] on an alphabet σ is a sequence of nonempty subsets of σ; x is said to be regular if every subset is of size one. A proper substring u of regular x is said to be a cover of x iff for every i∈1..n, an occurrence of u in x includes x[i]. The cover array γ=γ[1..n] of x is an integer array such that γ[i] is the longest cover of x[1..i]. Fifteen years ago a complex, though nevertheless linear-time, algorithm was proposed to compute the cover array of regular x based on prior computation of the border array of x. In this paper we first describe a linear-time algorithm to compute the cover array of regular x based on the prefix table of x. We then extend this result to indeterminate strings.

Original language	English
Journal	DISCRETE APPLIED MATHEMATICS
DOIs	https://doi.org/10.1016/j.dam.2015.05.019
Publication status	Accepted/In press - 6 Jun 2015

Keywords

Algorithm
Cover array
Covers
Indeterminate strings
Linear time
Prefix tables
Strings

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10.1016/j.dam.2015.05.019

Cite this

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title = "Computing covers using prefix tables",

abstract = "An indeterminate string x=x[1..n] on an alphabet σ is a sequence of nonempty subsets of σ; x is said to be regular if every subset is of size one. A proper substring u of regular x is said to be a cover of x iff for every i∈1..n, an occurrence of u in x includes x[i]. The cover array γ=γ[1..n] of x is an integer array such that γ[i] is the longest cover of x[1..i]. Fifteen years ago a complex, though nevertheless linear-time, algorithm was proposed to compute the cover array of regular x based on prior computation of the border array of x. In this paper we first describe a linear-time algorithm to compute the cover array of regular x based on the prefix table of x. We then extend this result to indeterminate strings.",

keywords = "Algorithm, Cover array, Covers, Indeterminate strings, Linear time, Prefix tables, Strings",

author = "Ali Alatabbi and {Sohel Rahman}, M. and Smyth, {W. F.}",

note = "Not freely accessible but may have access through institution",

year = "2015",

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doi = "10.1016/j.dam.2015.05.019",

language = "English",

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T1 - Computing covers using prefix tables

AU - Alatabbi, Ali

AU - Sohel Rahman, M.

AU - Smyth, W. F.

N1 - Not freely accessible but may have access through institution

PY - 2015/6/6

Y1 - 2015/6/6

N2 - An indeterminate string x=x[1..n] on an alphabet σ is a sequence of nonempty subsets of σ; x is said to be regular if every subset is of size one. A proper substring u of regular x is said to be a cover of x iff for every i∈1..n, an occurrence of u in x includes x[i]. The cover array γ=γ[1..n] of x is an integer array such that γ[i] is the longest cover of x[1..i]. Fifteen years ago a complex, though nevertheless linear-time, algorithm was proposed to compute the cover array of regular x based on prior computation of the border array of x. In this paper we first describe a linear-time algorithm to compute the cover array of regular x based on the prefix table of x. We then extend this result to indeterminate strings.

AB - An indeterminate string x=x[1..n] on an alphabet σ is a sequence of nonempty subsets of σ; x is said to be regular if every subset is of size one. A proper substring u of regular x is said to be a cover of x iff for every i∈1..n, an occurrence of u in x includes x[i]. The cover array γ=γ[1..n] of x is an integer array such that γ[i] is the longest cover of x[1..i]. Fifteen years ago a complex, though nevertheless linear-time, algorithm was proposed to compute the cover array of regular x based on prior computation of the border array of x. In this paper we first describe a linear-time algorithm to compute the cover array of regular x based on the prefix table of x. We then extend this result to indeterminate strings.

KW - Algorithm

KW - Cover array

KW - Covers

KW - Indeterminate strings

KW - Linear time

KW - Prefix tables

KW - Strings

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DO - 10.1016/j.dam.2015.05.019

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SN - 0166-218X

JO - DISCRETE APPLIED MATHEMATICS

JF - DISCRETE APPLIED MATHEMATICS

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Computing covers using prefix tables

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Keywords

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