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A context-sensitive grammar is a formal grammar in which the left-hand sides and right-hand sides of any production rules may be surrounded by a context of terminal and nonterminal symbols. Context-sensitive grammars are more general than context-free grammars but still regular enough to be parsed by a linear bounded automaton. The concept of context-sensitive grammar was introduced by Noam Chomsky in the 1950s as a way to describe the syntax of natural language where it is indeed often the case that a word may or may not be appropriate in a certain place depending upon the context. A formal language that can be described by a context-sensitive grammar is called a context-sensitive language.
Formal definition A formal grammar G = (N, Σ, P, S) is context-sensitive if all rules in P are of the form αAβ → αγβ where A ∈ N (i.e., A is a single nonterminal), α,β ∈ (N U Σ) S → ε where ε represents the empty string is permitted if S does not appear on the right side of any rule. The name context-sensitive is explained by the α and β that form the context of A and determine whether A can be replaced with γ or not. This is different from a context-free grammar where the context of a nonterminal is not taken into consideration. Alternative definition Another definition of context-sensitive grammars defines them as formal grammars with the restriction that for all rules α -> β in P it holds that |α| ≤ |β| where |α| is the length of α. Such a grammar is also called a monotonic or noncontracting grammar because none of the rules decreases the size of the string that is being rewritten. While the noncontracting grammars are different from the context-sensitive ones, the two are almost equivalent in the sense that they define the same class of languages (except that noncontracting grammars cannot generate any language that contains the empty string ε). But if a formal language L can be described by a grammar of the first definition then there is a noncontracting grammar that describes L - , and vice versa. Example A simple monotonic grammar (which is not context-sensitive by the first definition) is S → abc | aSBc cB → Bc bB → bb where | is used to separate different options for the same non-terminal. This grammar generates the language , which is not context-free. Context-sensitive grammars can match an unlimited number of symbols to their partners, unlike context-free grammars, which can only match one symbol to its partner, so there is also a context-sensitive grammar for the language , but it's much more complex than the grammar above. Normal forms Every context-sensitive grammar which does not generate the empty string can be transformed into an equivalent one in Kuroda normal form. "Equivalent" here means that the two grammars generate the same language. Computational properties and Uses The decision problem that asks whether a certain string s belongs to the language of a certain context-sensitive grammar G, is PSPACE-complete. Indeed, there are even some context-sensitive grammars whose fixed grammar recognition problem is PSPACE-complete. It has been shown that nearly all natural languages may in general be characterized by context-sensitive grammars, however the whole class of CSG's seems to be much bigger than natural languages. Worse yet, since the aforementioned decision problem for CSG's is PSPACE-complete, that makes them totally unworkable for practical use, as the general algorithm would take exponential time. Ongoing research on computational linguistics has focused on formulating other classes of languages that are "mildly context-sensitive" whose decision problems are feasible, such as tree-adjoining grammars, coupled context-free languages, and linear context-free rewriting systems. The languages generated by these formalisms properly lie between the context-free and context-sensitive languages. See also | ||||||||
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