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Context-sensitive language

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In formal language theory, a context-sensitive language is a language that can be defined by a context-sensitive grammar (and equivalently by a noncontracting grammar). Context-sensitive is known as type-1 in the Chomsky hierarchy of formal languages.

Computational properties

Computationally, a context-sensitive language is equivalent to a linear bounded nondeterministic Turing machine, also called a linear bounded automaton. That is a non-deterministic Turing machine with a tape of only k n {\displaystyle kn} cells, where n {\displaystyle n} is the size of the input and k {\displaystyle k} is a constant associated with the machine. This means that every formal language that can be decided by such a machine is a context-sensitive language, and every context-sensitive language can be decided by such a machine.

This set of languages is also known as NLINSPACE or NSPACE(O(n)), because they can be accepted using linear space on a non-deterministic Turing machine. The class LINSPACE (or DSPACE(O(n))) is defined the same, except using a deterministic Turing machine. Clearly LINSPACE is a subset of NLINSPACE, but it is not known whether LINSPACE = NLINSPACE.

Examples

One of the simplest context-sensitive but not context-free languages is L = { a n b n c n : n 1 } {\displaystyle L=\{a^{n}b^{n}c^{n}:n\geq 1\}} : the language of all strings consisting of n occurrences of the symbol "a", then n "b"s, then n "c"s (abc, aabbcc, aaabbbccc, etc.). A superset of this language, called the Bach language, is defined as the set of all strings where "a", "b" and "c" (or any other set of three symbols) occurs equally often (aabccb, baabcaccb, etc.) and is also context-sensitive.

L can be shown to be a context-sensitive language by constructing a linear bounded automaton which accepts L. The language can easily be shown to be neither regular nor context-free by applying the respective pumping lemmas for each of the language classes to L.

Similarly:

L Cross = { a m b n c m d n : m 1 , n 1 } {\displaystyle L_{\textit {Cross}}=\{a^{m}b^{n}c^{m}d^{n}:m\geq 1,n\geq 1\}} is another context-sensitive language; the corresponding context-sensitive grammar can be easily projected starting with two context-free grammars generating sentential forms in the formats a m C m {\displaystyle a^{m}C^{m}} and B n d n {\displaystyle B^{n}d^{n}} and then supplementing them with a permutation production like C B B C {\displaystyle CB\rightarrow BC} , a new starting symbol and standard syntactic sugar.

L M U L 3 = { a m b n c m n : m 1 , n 1 } {\displaystyle L_{MUL3}=\{a^{m}b^{n}c^{mn}:m\geq 1,n\geq 1\}} is another context-sensitive language (the "3" in the name of this language is intended to mean a ternary alphabet); that is, the "product" operation defines a context-sensitive language (but the "sum" defines only a context-free language as the grammar S a S c | R {\displaystyle S\rightarrow aSc|R} and R b R c | b c {\displaystyle R\rightarrow bRc|bc} shows). Because of the commutative property of the product, the most intuitive grammar for L MUL3 {\displaystyle L_{\textit {MUL3}}} is ambiguous. This problem can be avoided considering a somehow more restrictive definition of the language, e.g. L ORDMUL3 = { a m b n c m n : 1 < m < n } {\displaystyle L_{\textit {ORDMUL3}}=\{a^{m}b^{n}c^{mn}:1<m<n\}} . This can be specialized to L MUL1 = { a m n : m > 1 , n > 1 } {\displaystyle L_{\textit {MUL1}}=\{a^{mn}:m>1,n>1\}} and, from this, to L m 2 = { a m 2 : m > 1 } {\displaystyle L_{m^{2}}=\{a^{m^{2}}:m>1\}} , L m 3 = { a m 3 : m > 1 } {\displaystyle L_{m^{3}}=\{a^{m^{3}}:m>1\}} , etc.

L R E P = { w | w | : w Σ } {\displaystyle L_{REP}=\{w^{|w|}:w\in \Sigma ^{*}\}} is a context-sensitive language. The corresponding context-sensitive grammar can be obtained as a generalization of the context-sensitive grammars for L Square = { w 2 : w Σ } {\displaystyle L_{\textit {Square}}=\{w^{2}:w\in \Sigma ^{*}\}} , L Cube = { w 3 : w Σ } {\displaystyle L_{\textit {Cube}}=\{w^{3}:w\in \Sigma ^{*}\}} , etc.

L EXP = { a 2 n : n 1 } {\displaystyle L_{\textit {EXP}}=\{a^{2^{n}}:n\geq 1\}} is a context-sensitive language.

L PRIMES2 = { w : | w |  is prime  } {\displaystyle L_{\textit {PRIMES2}}=\{w:|w|{\mbox{ is prime }}\}} is a context-sensitive language (the "2" in the name of this language is intended to mean a binary alphabet). This was proved by Hartmanis using pumping lemmas for regular and context-free languages over a binary alphabet and, after that, sketching a linear bounded multitape automaton accepting L P R I M E S 2 {\displaystyle L_{PRIMES2}} .

L PRIMES1 = { a p : p  is prime  } {\displaystyle L_{\textit {PRIMES1}}=\{a^{p}:p{\mbox{ is prime }}\}} is a context-sensitive language (the "1" in the name of this language is intended to mean a unary alphabet). This was credited by A. Salomaa to Matti Soittola by means of a linear bounded automaton over a unary alphabet (pages 213-214, exercise 6.8) and also to Marti Penttonen by means of a context-sensitive grammar also over a unary alphabet (See: Formal Languages by A. Salomaa, page 14, Example 2.5).

An example of recursive language that is not context-sensitive is any recursive language whose decision is an EXPSPACE-hard problem, say, the set of pairs of equivalent regular expressions with exponentiation.

Properties of context-sensitive languages

  • The union, intersection, concatenation of two context-sensitive languages is context-sensitive, also the Kleene plus of a context-sensitive language is context-sensitive.
  • The complement of a context-sensitive language is itself context-sensitive a result known as the Immerman–Szelepcsényi theorem.
  • Membership of a string in a language defined by an arbitrary context-sensitive grammar, or by an arbitrary deterministic context-sensitive grammar, is a PSPACE-complete problem.

See also

References

  1. Rothe, Jörg (2005), Complexity theory and cryptology, Texts in Theoretical Computer Science. An EATCS Series, Berlin: Springer-Verlag, p. 77, ISBN 978-3-540-22147-0, MR 2164257.
  2. Odifreddi, P. G. (1999), Classical recursion theory. Vol. II, Studies in Logic and the Foundations of Mathematics, vol. 143, Amsterdam: North-Holland Publishing Co., p. 236, ISBN 978-0-444-50205-6, MR 1718169.
  3. Pullum, Geoffrey K. (1983). Context-freeness and the computer processing of human languages. Proc. 21st Annual Meeting of the ACL.
  4. Bach, E. (1981). "Discontinuous constituents in generalized categorial grammars" Archived 2014-01-21 at the Wayback Machine. NELS, vol. 11, pp. 1–12.
  5. Joshi, A.; Vijay-Shanker, K.; and Weir, D. (1991). "The convergence of mildly context-sensitive grammar formalisms". In: Sells, P., Shieber, S.M. and Wasow, T. (Editors). Foundational Issues in Natural Language Processing. Cambridge MA: Bradford.
  6. Example 9.5 (p. 224) of Hopcroft, John E.; Ullman, Jeffrey D. (1979). Introduction to Automata Theory, Languages, and Computation. Addison-Wesley
  7. J. Hartmanis and H. Shank (Jul 1968). "On the Recognition of Primes by Automata" (PDF). Journal of the ACM. 15 (3): 382–389. doi:10.1145/321466.321470. hdl:1813/5864. S2CID 17998039.
  8. Salomaa, Arto (1969), Theory of Automata, ISBN 978-0-08-013376-8, Pergamon, 276 pages. doi:10.1016/C2013-0-02221-9
  9. John E. Hopcroft; Jeffrey D. Ullman (1979). Introduction to Automata Theory, Languages, and Computation. Addison-Wesley. ISBN 9780201029888.; Exercise 9.10, p.230. In the 2000 edition, the chapter on context-sensitive languages has been omitted.
  10. Immerman, Neil (1988). "Nondeterministic space is closed under complementation" (PDF). SIAM J. Comput. 17 (5): 935–938. CiteSeerX 10.1.1.54.5941. doi:10.1137/0217058. Archived (PDF) from the original on 2004-06-25.
  • Sipser, M. (1996), Introduction to the Theory of Computation, PWS Publishing Co.
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