Context-free language

Formal language generated by context-free grammar

In formal language theory, a context-free language (CFL), also called a Chomsky type-2 language, is a language generated by a context-free grammar (CFG).

Context-free languages have many applications in programming languages, in particular, most arithmetic expressions are generated by context-free grammars.

Background

Context-free grammar

Different context-free grammars can generate the same context-free language. Intrinsic properties of the language can be distinguished from extrinsic properties of a particular grammar by comparing multiple grammars that describe the language.

Automata

The set of all context-free languages is identical to the set of languages accepted by pushdown automata, which makes these languages amenable to parsing. Further, for a given CFG, there is a direct way to produce a pushdown automaton for the grammar (and thereby the corresponding language), though going the other way (producing a grammar given an automaton) is not as direct.

Examples

An example context-free language is L = { a n b n : n 1 } {\displaystyle L=\{a^{n}b^{n}:n\geq 1\}} , the language of all non-empty even-length strings, the entire first halves of which are a's, and the entire second halves of which are b's. L is generated by the grammar S a S b   |   a b {\displaystyle S\to aSb~|~ab} . This language is not regular. It is accepted by the pushdown automaton M = ( { q 0 , q 1 , q f } , { a , b } , { a , z } , δ , q 0 , z , { q f } ) {\displaystyle M=(\{q_{0},q_{1},q_{f}\},\{a,b\},\{a,z\},\delta ,q_{0},z,\{q_{f}\})} where δ {\displaystyle \delta } is defined as follows:[note 1]

δ ( q 0 , a , z ) = ( q 0 , a z ) δ ( q 0 , a , a ) = ( q 0 , a a ) δ ( q 0 , b , a ) = ( q 1 , ε ) δ ( q 1 , b , a ) = ( q 1 , ε ) δ ( q 1 , ε , z ) = ( q f , ε ) {\displaystyle {\begin{aligned}\delta (q_{0},a,z)&=(q_{0},az)\\\delta (q_{0},a,a)&=(q_{0},aa)\\\delta (q_{0},b,a)&=(q_{1},\varepsilon )\\\delta (q_{1},b,a)&=(q_{1},\varepsilon )\\\delta (q_{1},\varepsilon ,z)&=(q_{f},\varepsilon )\end{aligned}}}

Unambiguous CFLs are a proper subset of all CFLs: there are inherently ambiguous CFLs. An example of an inherently ambiguous CFL is the union of { a n b m c m d n | n , m > 0 } {\displaystyle \{a^{n}b^{m}c^{m}d^{n}|n,m>0\}} with { a n b n c m d m | n , m > 0 } {\displaystyle \{a^{n}b^{n}c^{m}d^{m}|n,m>0\}} . This set is context-free, since the union of two context-free languages is always context-free. But there is no way to unambiguously parse strings in the (non-context-free) subset { a n b n c n d n | n > 0 } {\displaystyle \{a^{n}b^{n}c^{n}d^{n}|n>0\}} which is the intersection of these two languages.[1]

Dyck language

The language of all properly matched parentheses is generated by the grammar S S S   |   ( S )   |   ε {\displaystyle S\to SS~|~(S)~|~\varepsilon } .

Properties

Context-free parsing

The context-free nature of the language makes it simple to parse with a pushdown automaton.

Determining an instance of the membership problem; i.e. given a string w {\displaystyle w} , determine whether w L ( G ) {\displaystyle w\in L(G)} where L {\displaystyle L} is the language generated by a given grammar G {\displaystyle G} ; is also known as recognition. Context-free recognition for Chomsky normal form grammars was shown by Leslie G. Valiant to be reducible to boolean matrix multiplication, thus inheriting its complexity upper bound of O(n2.3728596).[2][note 2] Conversely, Lillian Lee has shown O(n3−ε) boolean matrix multiplication to be reducible to O(n3−3ε) CFG parsing, thus establishing some kind of lower bound for the latter.[3]

Practical uses of context-free languages require also to produce a derivation tree that exhibits the structure that the grammar associates with the given string. The process of producing this tree is called parsing. Known parsers have a time complexity that is cubic in the size of the string that is parsed.

Formally, the set of all context-free languages is identical to the set of languages accepted by pushdown automata (PDA). Parser algorithms for context-free languages include the CYK algorithm and Earley's Algorithm.

A special subclass of context-free languages are the deterministic context-free languages which are defined as the set of languages accepted by a deterministic pushdown automaton and can be parsed by a LR(k) parser.[4]

See also parsing expression grammar as an alternative approach to grammar and parser.

Closure properties

The class of context-free languages is closed under the following operations. That is, if L and P are context-free languages, the following languages are context-free as well:

  • the union L P {\displaystyle L\cup P} of L and P[5]
  • the reversal of L[6]
  • the concatenation L P {\displaystyle L\cdot P} of L and P[5]
  • the Kleene star L {\displaystyle L^{*}} of L[5]
  • the image φ ( L ) {\displaystyle \varphi (L)} of L under a homomorphism φ {\displaystyle \varphi } [7]
  • the image φ 1 ( L ) {\displaystyle \varphi ^{-1}(L)} of L under an inverse homomorphism φ 1 {\displaystyle \varphi ^{-1}} [8]
  • the circular shift of L (the language { v u : u v L } {\displaystyle \{vu:uv\in L\}} )[9]
  • the prefix closure of L (the set of all prefixes of strings from L)[10]
  • the quotient L/R of L by a regular language R[11]

Nonclosure under intersection, complement, and difference

The context-free languages are not closed under intersection. This can be seen by taking the languages A = { a n b n c m m , n 0 } {\displaystyle A=\{a^{n}b^{n}c^{m}\mid m,n\geq 0\}} and B = { a m b n c n m , n 0 } {\displaystyle B=\{a^{m}b^{n}c^{n}\mid m,n\geq 0\}} , which are both context-free.[note 3] Their intersection is A B = { a n b n c n n 0 } {\displaystyle A\cap B=\{a^{n}b^{n}c^{n}\mid n\geq 0\}} , which can be shown to be non-context-free by the pumping lemma for context-free languages. As a consequence, context-free languages cannot be closed under complementation, as for any languages A and B, their intersection can be expressed by union and complement: A B = A ¯ B ¯ ¯ {\displaystyle A\cap B={\overline {{\overline {A}}\cup {\overline {B}}}}} . In particular, context-free language cannot be closed under difference, since complement can be expressed by difference: L ¯ = Σ L {\displaystyle {\overline {L}}=\Sigma ^{*}\setminus L} .[12]

However, if L is a context-free language and D is a regular language then both their intersection L D {\displaystyle L\cap D} and their difference L D {\displaystyle L\setminus D} are context-free languages.[13]

Decidability

In formal language theory, questions about regular languages are usually decidable, but ones about context-free languages are often not. It is decidable whether such a language is finite, but not whether it contains every possible string, is regular, is unambiguous, or is equivalent to a language with a different grammar.

The following problems are undecidable for arbitrarily given context-free grammars A and B:

  • Equivalence: is L ( A ) = L ( B ) {\displaystyle L(A)=L(B)} ?[14]
  • Disjointness: is L ( A ) L ( B ) = {\displaystyle L(A)\cap L(B)=\emptyset }  ?[15] However, the intersection of a context-free language and a regular language is context-free,[16][17] hence the variant of the problem where B is a regular grammar is decidable (see "Emptiness" below).
  • Containment: is L ( A ) L ( B ) {\displaystyle L(A)\subseteq L(B)}  ?[18] Again, the variant of the problem where B is a regular grammar is decidable,[citation needed] while that where A is regular is generally not.[19]
  • Universality: is L ( A ) = Σ {\displaystyle L(A)=\Sigma ^{*}} ?[20]
  • Regularity: is L ( A ) {\displaystyle L(A)} a regular language?[21]
  • Ambiguity: is every grammar for L ( A ) {\displaystyle L(A)} ambiguous?[22]

The following problems are decidable for arbitrary context-free languages:

  • Emptiness: Given a context-free grammar A, is L ( A ) = {\displaystyle L(A)=\emptyset }  ?[23]
  • Finiteness: Given a context-free grammar A, is L ( A ) {\displaystyle L(A)} finite?[24]
  • Membership: Given a context-free grammar G, and a word w {\displaystyle w} , does w L ( G ) {\displaystyle w\in L(G)}  ? Efficient polynomial-time algorithms for the membership problem are the CYK algorithm and Earley's Algorithm.

According to Hopcroft, Motwani, Ullman (2003),[25] many of the fundamental closure and (un)decidability properties of context-free languages were shown in the 1961 paper of Bar-Hillel, Perles, and Shamir[26]

Languages that are not context-free

The set { a n b n c n d n | n > 0 } {\displaystyle \{a^{n}b^{n}c^{n}d^{n}|n>0\}} is a context-sensitive language, but there does not exist a context-free grammar generating this language.[27] So there exist context-sensitive languages which are not context-free. To prove that a given language is not context-free, one may employ the pumping lemma for context-free languages[26] or a number of other methods, such as Ogden's lemma or Parikh's theorem.[28]

Notes

  1. ^ meaning of δ {\displaystyle \delta } 's arguments and results: δ ( s t a t e 1 , r e a d , p o p ) = ( s t a t e 2 , p u s h ) {\displaystyle \delta (\mathrm {state} _{1},\mathrm {read} ,\mathrm {pop} )=(\mathrm {state} _{2},\mathrm {push} )}
  2. ^ In Valiant's paper, O(n2.81) was the then-best known upper bound. See Matrix multiplication#Computational complexity for bound improvements since then.
  3. ^ A context-free grammar for the language A is given by the following production rules, taking S as the start symbol: SSc | aTb | ε; TaTb | ε. The grammar for B is analogous.

References

  1. ^ Hopcroft & Ullman 1979, p. 100, Theorem 4.7.
  2. ^ Valiant, Leslie G. (April 1975). "General context-free recognition in less than cubic time" (PDF). Journal of Computer and System Sciences. 10 (2): 308–315. doi:10.1016/s0022-0000(75)80046-8.
  3. ^ Lee, Lillian (January 2002). "Fast Context-Free Grammar Parsing Requires Fast Boolean Matrix Multiplication" (PDF). J ACM. 49 (1): 1–15. arXiv:cs/0112018. doi:10.1145/505241.505242. S2CID 1243491. Archived (PDF) from the original on 2003-04-27.
  4. ^ Knuth, D. E. (July 1965). "On the translation of languages from left to right". Information and Control. 8 (6): 607–639. doi:10.1016/S0019-9958(65)90426-2.
  5. ^ a b c Hopcroft & Ullman 1979, p. 131, Corollary of Theorem 6.1.
  6. ^ Hopcroft & Ullman 1979, p. 142, Exercise 6.4d.
  7. ^ Hopcroft & Ullman 1979, p. 131-132, Corollary of Theorem 6.2.
  8. ^ Hopcroft & Ullman 1979, p. 132, Theorem 6.3.
  9. ^ Hopcroft & Ullman 1979, p. 142-144, Exercise 6.4c.
  10. ^ Hopcroft & Ullman 1979, p. 142, Exercise 6.4b.
  11. ^ Hopcroft & Ullman 1979, p. 142, Exercise 6.4a.
  12. ^ Stephen Scheinberg (1960). "Note on the Boolean Properties of Context Free Languages" (PDF). Information and Control. 3 (4): 372–375. doi:10.1016/s0019-9958(60)90965-7. Archived (PDF) from the original on 2018-11-26.
  13. ^ Beigel, Richard; Gasarch, William. "A Proof that if L = L1 ∩ L2 where L1 is CFL and L2 is Regular then L is Context Free Which Does Not use PDA's" (PDF). University of Maryland Department of Computer Science. Archived (PDF) from the original on 2014-12-12. Retrieved June 6, 2020.
  14. ^ Hopcroft & Ullman 1979, p. 203, Theorem 8.12(1).
  15. ^ Hopcroft & Ullman 1979, p. 202, Theorem 8.10.
  16. ^ Salomaa (1973), p. 59, Theorem 6.7
  17. ^ Hopcroft & Ullman 1979, p. 135, Theorem 6.5.
  18. ^ Hopcroft & Ullman 1979, p. 203, Theorem 8.12(2).
  19. ^ Hopcroft & Ullman 1979, p. 203, Theorem 8.12(4).
  20. ^ Hopcroft & Ullman 1979, p. 203, Theorem 8.11.
  21. ^ Hopcroft & Ullman 1979, p. 205, Theorem 8.15.
  22. ^ Hopcroft & Ullman 1979, p. 206, Theorem 8.16.
  23. ^ Hopcroft & Ullman 1979, p. 137, Theorem 6.6(a).
  24. ^ Hopcroft & Ullman 1979, p. 137, Theorem 6.6(b).
  25. ^ John E. Hopcroft; Rajeev Motwani; Jeffrey D. Ullman (2003). Introduction to Automata Theory, Languages, and Computation. Addison Wesley. Here: Sect.7.6, p.304, and Sect.9.7, p.411
  26. ^ a b Yehoshua Bar-Hillel; Micha Asher Perles; Eli Shamir (1961). "On Formal Properties of Simple Phrase-Structure Grammars". Zeitschrift für Phonetik, Sprachwissenschaft und Kommunikationsforschung. 14 (2): 143–172.
  27. ^ Hopcroft & Ullman 1979.
  28. ^ "How to prove that a language is not context-free?".

Works cited

  • Hopcroft, John E.; Ullman, Jeffrey D. (1979). Introduction to Automata Theory, Languages, and Computation (1st ed.). Addison-Wesley. ISBN 9780201029888.
  • Salomaa, Arto (1973). Formal Languages. ACM Monograph Series.

Further reading

  • Autebert, Jean-Michel; Berstel, Jean; Boasson, Luc (1997). "Context-Free Languages and Push-Down Automata". In G. Rozenberg; A. Salomaa (eds.). Handbook of Formal Languages (PDF). Vol. 1. Springer-Verlag. pp. 111–174. Archived (PDF) from the original on 2011-05-16.
  • Ginsburg, Seymour (1966). The Mathematical Theory of Context-Free Languages. New York, NY, USA: McGraw-Hill.
  • Sipser, Michael (1997). "2: Context-Free Languages". Introduction to the Theory of Computation. PWS Publishing. pp. 91–122. ISBN 0-534-94728-X.
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