Search citation statements
Paper Sections
Citation Types
Year Published
Publication Types
Relationship
Authors
Journals
A pumping lemma for a class of languages $$\varvec{\mathcal {C}}$$ C is often used to show particular languages are not in $$\varvec{\mathcal {C}}$$ C . In contrast, we show that a pumping lemma for a class of languages $$\varvec{\mathcal {C}}$$ C can be used to study the computational complexity of the predicate “$$\in \varvec{\mathcal {C}}$$ ∈ C ” via highly efficient many-one reductions. In this paper, we use extended regular expressions (EXREGs, introduced in Câmpeanu et al. (Int. J. Foundations Comput. Sci. 14(6), 1007–1018, 2003)) as an example to illustrate the proof technique and establish the complexity of the predicate “is an EXREG language” for several classes of languages. Due to the efficiency of the reductions, both productiveness (a stronger form of non-recursive enumerability) and complexity results can be obtained simultaneously. For example, we show that the predicate “is an EXREG language” is productive (hence, not recursively enumerable) for context-free grammars, and is Co-NEXPTIME-hard for context-free grammars generating bounded languages. The proof technique is easy to use and requires only a few conditions. This suggests that for any class of languages $$\varvec{\mathcal {C}}$$ C having a pumping lemma, the language class comparison problems (e.g., does a given context-free grammar generate a language in $$\varvec{\mathcal {C}}$$ C ?) are almost guaranteed to be hard. So, pumping lemmas sometimes could be “harmful” when studying computational complexity results.
A pumping lemma for a class of languages $$\varvec{\mathcal {C}}$$ C is often used to show particular languages are not in $$\varvec{\mathcal {C}}$$ C . In contrast, we show that a pumping lemma for a class of languages $$\varvec{\mathcal {C}}$$ C can be used to study the computational complexity of the predicate “$$\in \varvec{\mathcal {C}}$$ ∈ C ” via highly efficient many-one reductions. In this paper, we use extended regular expressions (EXREGs, introduced in Câmpeanu et al. (Int. J. Foundations Comput. Sci. 14(6), 1007–1018, 2003)) as an example to illustrate the proof technique and establish the complexity of the predicate “is an EXREG language” for several classes of languages. Due to the efficiency of the reductions, both productiveness (a stronger form of non-recursive enumerability) and complexity results can be obtained simultaneously. For example, we show that the predicate “is an EXREG language” is productive (hence, not recursively enumerable) for context-free grammars, and is Co-NEXPTIME-hard for context-free grammars generating bounded languages. The proof technique is easy to use and requires only a few conditions. This suggests that for any class of languages $$\varvec{\mathcal {C}}$$ C having a pumping lemma, the language class comparison problems (e.g., does a given context-free grammar generate a language in $$\varvec{\mathcal {C}}$$ C ?) are almost guaranteed to be hard. So, pumping lemmas sometimes could be “harmful” when studying computational complexity results.
No abstract
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.