k-Universality of Regular Languages
Abstract
A subsequence of a word w is a word u such that u = w[i1] w[i2] … w[ik], for some set of indices 1 ≤ i1 < i2 < … < ik ≤ w. A word w is k-subsequence universal over an alphabet if every word in k appears in w as a subsequence. In this paper, we study the intersection between the set of k-subsequence universal words over some alphabet and regular languages over . We call a regular language L k-∃-subsequence universal if there exists a k-subsequence universal word in L, and k-∀-subsequence universal if every word of L is k-subsequence universal. We give algorithms solving the problems of deciding if a given regular language, represented by a finite automaton recognising it, is k-∃-subsequence universal and, respectively, if it is k-∀-subsequence universal, for a given k. The algorithms are FPT w.r.t.~the size of the input alphabet, and their run-time does not depend on k; they run in polynomial time in the number n of states of the input automaton when the size of the input alphabet is O( n). Moreover, we show that the problem of deciding if a given regular language is k-∃-subsequence universal is NP-complete, when the language is over a large alphabet. Further, we provide algorithms for counting the number of k-subsequence universal words (paths) accepted by a given deterministic (respectively, nondeterministic) finite automaton, and ranking an input word (path) within the set of k-subsequence universal words accepted by a given finite automaton.
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