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Revision as of 18:02, 11 September 2006

A recursive language in mathematics, logic and computer science, is a type of formal language which is also called recursive, decidable or Turing-decidable. The class of all recursive languages is often called R, although this name is also used for the class RP.

This type of language is conspicuously missing from the Chomsky hierarchy.

Definitions

There are two equivalent major definitions for the concept of a recursive language:

  1. A recursive formal language is a recursive subset in the set of all possible words over the alphabet of the language.
  2. A recursive language is a formal language for which there exists a Turing machine which will, when presented with any input string, halt and accept if the string is in the language, and halt and reject otherwise. The Turing machine always halts; it is known as a decider and is said to decide the recursive language.

All recursive languages are also recursively enumerable. All regular, context-free and context-sensitive languages are recursive.

Closure Properties

Recursive languages are closed under the following operations. That is, if L and P are two recursive languages, then the following languages are recursive as well:

  • the Kleene star L* of L
  • the non-erasing homomorphism φ(L) of L
  • the concatenation LP of L and P
  • the union LP
  • the intersection LP
  • the complement of L
  • the set difference L\P

The last property follows from the fact that the set difference can be expressed in terms of intersection and complement.

References

  • Michael Sipser (1997). Introduction to the Theory of Computation. PWS Publishing. ISBN 0-534-94728-X. Chapter 4: Decidability, pp.151–170.

See also