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I often hear claims that C++ is a context-sensitive language. Take the following example:

a b(c);

Is this a variable definition or a function declaration? That depends on the meaning of the symbol c. If c is a variable, then a b(c); defines a variable named b of type a. It is directly initialized with c. But if c is a type, then a b(c); declares a function named b that takes a c and returns an a.

If you look up the definition of context-free languages, it will basically tell you that all grammar rules must have left-hand sides that consist of exactly one non-terminal symbol. Context-sensitive grammars, on the other hand, allow arbitrary strings of terminal and non-terminal symbols on the left-hand side.

Browsing through Appendix A of "The C++ Programming Language", I couldn't find a single grammar rule that had anything else besides a single non-terminal symbol on its left-hand side. That would imply that C++ is context-free. (Of course, every context-free language is also context-sensitive in the sense that the context-free languages form a subset of the context-sensitive languages, but that is not the point.)

So, is C++ context-free or context-sensitive?

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@CarlNorum Please show me a single grammar rule of C++ that does not consist of a single non-terminal symbol on its left-hand side and I will immediately believe you. – fredoverflow Jan 29 '13 at 18:11
IIUC it depends a bit on where you draw the line for context-sensitivity. I think I've seen people argue that almost all statically typed programming languages are context-sensitive, not because you can't build a practical compiler for them with CFG parsing tools, but because such implementations "cheat" by parsing some invalid programs and only rejecting them later, during type checking. So if you consider ill-typed programs to be not in the language (in the CS sense, i.e. a set of strings) the parser should accept, more languages than C++ are context-sensitive. – delnan Jan 29 '13 at 18:12
@DeadMG: No, you are wrong. There is no "parsing" or "semantics" in formal language theory at all, just "language" which is a set of strings. – jpalecek Jan 29 '13 at 18:26
No answers so far have actually addressed your definition of "context-free grammar". To my mind, the correct answer to this question either cites a production in appendix A that does not fit your definition, or demonstrates that your definition is incorrect or insufficient. Stand your ground! – Lightness Races in Orbit Jan 29 '13 at 18:26
See Is D's grammar really context-free?. In fact, I think everybody here should read that question and its answers! – Lightness Races in Orbit Jan 29 '13 at 18:34

18 Answers 18

up vote 255 down vote accepted

Below is my (current) favorite demonstration of why parsing C++ is (probably) Turing-complete, since it shows a program which is syntactically correct if and only if a given integer is prime.

So I assert that C++ is neither context-free nor context-sensitive.

If you allow arbitrary symbol sequences on both sides of any production, you produce an Type-0 grammar ("unrestricted") in the Chomsky hierarchy, which is more powerful than a context-sensitive grammar; unrestricted grammars are Turing-complete. A context-sensitive (Type-1) grammar allows multiple symbols of context on the left hand side of a production, but the same context must appear on the right hand side of the production (hence the name "context-sensitive"). [1] Context-sensitive grammars are equivalent to linear-bounded Turing machines.

In the example program, the prime computation could be performed by a linear-bounded Turing machine, so it does not quite prove Turing equivalence, but the important part is that the parser needs to perform the computation in order to perform syntactic analysis. It could have been any computation expressible as a template instantiation and there is every reason to believe that C++ template instantiation is Turing-complete. See, for example, Todd L. Veldhuizen's 2003 paper.

Regardless, C++ can be parsed by a computer, so it could certainly be parsed by a Turing machine. Consequently, an unrestricted grammar could recognize it. Actually writing such a grammar would be impractical, which is why the standard doesn't try to do so. (See below.)

The issue with "ambiguity" of certain expressions is mostly a red herring. To start with, ambiguity is a feature of a particular grammar, not a language. Even if a language can be proven to have no unambiguous grammars, if it can be recognized by a context-free grammar, it's context-free. Similarly, if it cannot be recognized by a context-free grammar but it can be recognized by a context-sensitive grammar, it's context-sensitive. Ambiguity is not relevant.

But in any event, like line 21 (i.e. auto b = foo<IsPrime<234799>>::typen<1>();) in the program below, the expressions are not ambiguous at all; they are simply parsed differently depending on context. In the simplest expression of the issue, the syntactic category of certain identifiers is dependent on how they have been declared (types and functions, for example), which means that the formal language would have to recognize the fact that two arbitrary-length strings in the same program are identical (declaration and use). This can be modelled by the "copy" grammar, which is the grammar which recognizes two consecutive exact copies of the same word. It's easy to prove with the pumping lemma that this language is not context-free. A context-sensitive grammar for this language is possible, and a Type-0 grammar is provided in the answer to this question: .

If one were to attempt to write a context-sensitive (or unrestricted) grammar to parse C++, it would quite possibly fill the universe with scribblings. Writing a Turing machine to parse C++ would be an equally impossible undertaking. Even writing a C++ program is difficult, and as far as I know none have been proven correct. This is why the standard does not attempt to provide a complete formal grammar, and why it chooses to write some of the parsing rules in technical English.

What looks like a formal grammar in the C++ standard is not the complete formal definition of the syntax of the C++ language. It's not even the complete formal definition of the language after preprocessing, which might be easier to formalize. (That wouldn't be the language, though: the C++ language as defined by the standard includes the preprocessor, and the operation of the preprocessor is described algorithmically since it would be extremely hard to describe in any grammatical formalism. It is in that section of the standard where lexical decomposition is described, including the rules where it must be applied more than once.)

The various grammars (two overlapping grammars for lexical analysis, one which takes place before preprocessing and the other, if necessary, afterwards, plus the "syntactic" grammar) are collected in Appendix A, with this important note (emphasis added):

This summary of C++ syntax is intended to be an aid to comprehension. It is not an exact statement of the language. In particular, the grammar described here accepts a superset of valid C++ constructs. Disambiguation rules (6.8, 7.1, 10.2) must be applied to distinguish expressions from declarations. Further, access control, ambiguity, and type rules must be used to weed out syntactically valid but meaningless constructs.

Finally, here's the promised program. Line 21 is syntactically correct if and only if the N in IsPrime<N> is prime. Otherwise, typen is an integer, not a template, so typen<1>() is parsed as (typen<1)>() which is syntactically incorrect because () is not a syntactically valid expression.

template<bool V> struct answer { answer(int) {} bool operator()(){return V;}};

template<bool no, bool yes, int f, int p> struct IsPrimeHelper
  : IsPrimeHelper<p % f == 0, f * f >= p, f + 2, p> {};
template<bool yes, int f, int p> struct IsPrimeHelper<true, yes, f, p> { using type = answer<false>; };
template<int f, int p> struct IsPrimeHelper<false, true, f, p> { using type = answer<true>; };

template<int I> using IsPrime = typename IsPrimeHelper<!(I&1), false, 3, I>::type;
template<int I>
struct X { static const int i = I; int a[i]; }; 

template<typename A> struct foo;
template<>struct foo<answer<true>>{
  template<int I> using typen = X<I>;
template<> struct foo<answer<false>>{
  static const int typen = 0;

int main() {
  auto b = foo<IsPrime<234799>>::typen<1>(); // Syntax error if not prime
  return 0;

[1] To put it more technically, every production in a context-sensitive grammar must be of the form:

αAβ → αγβ

where A is a non-terminal and α, β are possibly empty sequences of grammar symbols, and γ is a non-empty sequence. (Grammar symbols may be either terminals or non-terminals).

This can be read as A → γ only in the context [α, β]. In a context-free (Type 2) grammar, α and β must be empty.

It turns out that you can also restrict grammars with the "monotonic" restriction, where every production must be of the form:

α → β where |α| ≥ |β| > 0  (|α| means "the length of α")

It's possible to prove that the set of languages recognized by monotonic grammars is exactly the same as the set of languages recognized by context-sensitive grammars, and it's often the case that it's easier to base proofs on monotonic grammars. Consequently, it's pretty common to see "context-sensitive" used as though it meant "monotonic".

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So not only is it context-sensitive, but it can be made to depend on any context you can express in templates, which are Turing-complete. – Puppy Jan 29 '13 at 18:20
@mehrdad, the OP says "context-sensitive language", not context-sensitive grammar. Ambiguity is a feature of a grammar, not a language. The language is indeed context-sensitive, but not because a particular grammar for it is ambiguous. – rici Jan 29 '13 at 18:52
I have one doubt: As you show, the result of template evaluation can make the difference between a well-formed and an ill-formed program. Template evaluation is turing-complete. So wouldn't correctly determining whether a string is in the language (C++) require turing-completeness? As you say, a context-sensitive language is "just" a "linear bounded automaton", which is not turing-complete AFAIK. Or is your argument making use of the limits the C++ standard puts on some things including template evaluation depth? – delnan Jan 29 '13 at 19:18
@kaz, I made the definition of "context" in "context-sensitive" more precise. (I knew what I meant :), but I agree it wasn't sufficiently obvious.) There is no error in the template; the error (in those cases where there is one) is attempting to invoke a template which doesn't exist. Because of the way C++ parses <, >, and >> (sometimes as operators and sometimes as brackets), it is necessary to know whether a symbol which precedes a < is a template before it is possible to know what lexeme follows it. Once > is known to be an operator, value > () is a syntax error. – rici Jan 30 '13 at 14:42
@AntonGolov: My original version of that example did just that (you can achieve it by putting 0 inside of (), for a simple one), but I think it's more interesting this way, because it demonstrates that you need the template instantiation even to recognize if a string is a syntactically correct C++ program. If both branches compile, then I'd have to work harder to contest the argument that the difference is "semantic". Curiously, although I'm often challenged to define "syntactic", no-one has ever offered a definition of "semantic" other than "stuff I don't think is syntactic" :) – rici Jan 30 '13 at 20:14

First, you rightly observed there are no context sensitive rules in the grammar at the end of the C++ standard, so that grammar is context-free.

However, that grammar doesn't precisely describe the C++ language, because it produces non-C++ programs such as

int m() { m++; }


typedef static int int;

The C++ language defined as "the set of well-formed C++ programs" is not context-free (it's possible to show that merely demanding variables to be declared makes it so). Given you can theoretically write Turing-complete programs in templates and make a program ill-formed based on their result, it's not even context-sensitive.

Now, (ignorant) people (usually not language theorists, but parser designers) typically use "not context-free" in some of the following meanings

  • ambiguous
  • can't be parsed with Bison
  • not LL(k), LR(k), LALR(k) or whatever parser-defined language class they chose

The grammar at the back of the standard doesn't satisfies these categories (ie. it is ambiguous, not LL(k)...) so C++ grammar is "not context-free" for them. And in a sense, they're right it's damn well hard to produce a working C++ parser.

Note that the properties here used are only weakly connected to context-free languages - ambiguity doesn't have anything to do with context-sensitivity (in fact, context-sensitive rules typically help disambiguate productions), the other two are merely subsets of context-free languages. And parsing context-free languages is not a linear process (although parsing deterministic ones is).

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Hey, this is a great answer. I'm not qualified to say that it's correct, but I certainly buy the reasoning. – Lightness Races in Orbit Jan 29 '13 at 18:46
ambiguity doesn't have anything to do with context-sensitivity This was my intuition too, so I'm glad to see someone (a) agree, and (b) explain it where I could not. I believe it disqualifies all the arguments that are based on a b(c);, and partially satisfy the original question whose premise was "oft-heard" claims of context-sensitivity being due to ambiguity... especially when for the grammar there's actually no ambiguity even in the MVP. – Lightness Races in Orbit Jan 29 '13 at 18:53
@KonradRudolph: What the standard says is "There is an implementation-defined quantity that specifies the limit on the total depth of recursive instantiations, which could involve more than one template. The result of an infinite recursion in instantiation is undefined." (14.7.1p15) I interpret that to mean that an implementation is not required to understand every valid c++ program, not that programs with too large a recursion depth are invalid. The only ones which are marked as invalid are those with an infinite recursion depth. – rici Jan 29 '13 at 19:34
@KonradRudolph: I dispute that it's "general reference". The fact that I read that rather complex article and do not comprehend it sufficiently to piece out this little fact should be enough to demonstrate that. It's not as if you said something like "computers commonly use electricity", or "bits can be true or false". – Lightness Races in Orbit Jan 29 '13 at 20:23
As far as I can tell, @Konrad was mistaken when he said "Context sensitive is equivalent to Turing complete." (at least, he was if he was denoting "Recursively enumerable" by "Turing complete"), and has since been unable to recognize this mistake. Here is a reference for the proper set inclusion relationship involved here: – pnkfelix Jan 31 '13 at 10:56

Yes. The following expression has a different order of operations depending on type resolved context:

Edit: When the actual order of operation varies, it makes it incredibly difficult to use a "regular" compiler that parses to an undecorated AST before decorating it (propagating type information). Other context sensitive things mentioned are "rather easy" compared to this (not that template evaluation is at all easy).

   template<bool B>
   class foo
   { };
   static const int foo = 0;
   static const int bar = 15;

Followed by:

static int foobar( foo < 2 ? 1 < 1 : 0 > & bar );
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Why can that problem not be solved like for C, by remembering which type definitions are in scope? – Blaisorblade Jan 6 '12 at 3:13
@Blaisorblade: One way to make a compiler "clean" is to separate tasks into independent steps in a chain, such as creating a parse tree from the input followed by a step that does the type analysis. C++ forces you to either 1) merge these steps into one or 2) parse the document according to both/all possible interpretations, and allowing the type resolution stages to narrow it down to the correct interpretation. – Sam Harwell Jan 17 '12 at 16:04
@280Z28: agreed, but that's the case for C, too; I think a good answer to this question should show why C++ is worse than C. The PhD thesis linked here does that: – Blaisorblade Jan 19 '12 at 10:41

To answer your question, you need to distinguish two different questions.

  1. The mere syntax of almost every programming language is context-free. Typically, it is given as an extended Backus-Naur form or context-free gramar.

  2. However, even if a program conforms with the context-free gramar defined by the programming language, it is not necessarily a valid program. There are many non-context-free poperties that a program has to satisfy in order to be a valid program. E.g., the most simple such property is the scope of variables.

To conclude, whether or not C++ is context-free depends on the question you ask.

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It's interesting to note that you often have to place the "mere syntax" level lower than you'd expect, in order to get a CFG for your programming language. Take C, for instance. You might think that the grammar rule for a simple variable declaration in C would be VARDECL : TYPENAME IDENTIFIER, but you cannot have that, because you cannot distinguish type names from other identifiers at a CF level. Another example: at a CF level, you cannot decide whether to parse a*b as a variable declaration (b of type pointer to a) or as a multiplication. – LaC Jan 30 '13 at 0:33
@LaC: Yes, thanks for pointing this out! By the way, I'm sure that there is a more commonly used technical term for mere syntax. Does anyone the correct term? – Dan Jan 30 '13 at 9:11
@Dan: what you're talking about is an approximation of the language given by some context-free grammar. Of course such an approximation is coontext-free by definition. This is the sense in which "syntax" is often use when discussing programming languages. – reinierpost Jan 30 '13 at 11:43

C++ is parsed with GLR parser. That means during parsing the source code, the parser may encounter ambiguity but it should continue and decide which grammar rule to use later.

look also,

Why C++ cannot be parsed with a LR(1) parser?

Remember that context-free grammar can not describe ALL the rules of a programming language syntax. For example, Attribute grammar is used to check the validity of an expression type.

int x;
x = 9 + 1.0;

You can not describe the following rule with context-free grammar : The Right Side of the assignment should be of the same type of the Left Hand side.

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Most C++ parsers do not use GLR parsing technology. GCC doesn't. Some do. See for one that does. – Ira Baxter Jul 25 '09 at 10:33

You might want to take a look at The Design & Evolution of C++, by Bjarne Stroustrup. In it he describes his problems trying to use yacc (or similar) to parse an early version of C++, and wishing he had used recursive descent instead.

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Wow... Thanks. I wonder if it really makes sense to think about using anything more powerful than a CFG to parse any artificial language. – Dervin Thunk Jul 23 '09 at 17:16
Great book for understanding the whys of C++. I recommend that and Lippman's Inside the C++ Object Model for understanding how C++ works. Though both are a bit dated they are still a good read. – Matt Price Jul 23 '09 at 17:29
"Meta-S" is a context-sensitive parsing engine by Quinn Tyler Jackson. I've not used it, but he tells an impressive story. Check out his comments in comp.compilers, and see – Ira Baxter Jul 25 '09 at 10:42
@IraBaxter: your x-ref is MIA today - and solid references to the software seem to be elusive (Google search doesn't provide any good leads, either with ' meta-s' or 'quinn jackson meta-s'; there are bits and pieces, but leads to a non-informative web-site, for example). – Jonathan Leffler Sep 18 '09 at 11:49
@Jonathan: been awhile, just noticed your complaint. Dunno why the link is bad, I thought it was good when I wrote it. Quinn used to be pretty active in comp.compilers. Google seems to be getting flaky, this is all I can find:… IIRC, he signed over rights to MetaS to some outfit in Hawaii to re-market. Given how tecnically odd this was, IMHO this is signing its death warrant. Sounded like a very clever scheme. – Ira Baxter Sep 8 '11 at 5:50

Yeah C++ is context sensitive, very context sensitive. You cannot build the syntax tree by simply parsing through the file using a context free parser because in some cases you need to know the symbol from previous knowledge to decide (ie. build a symbol table while parsing).

First example:


Is this a multiplication expression?


Is this a declaration of B variable to be a pointer of type A?

If A is a variable, then it's an expression, if A is type, it's a pointer declaration.

Second example:

A B(bar);

Is this a function prototype taking an argument of bar type?


Is this declare variable B of type A and calls A's constructor with bar constant as an initializer?

You need to know again whether bar is a variable or a type from symbol table.

Third example:

class Foo
    void fn(){x*y;}
    int x, y;

This is the case when building symbol table while parsing does not help because the declaration of x and y comes after the function definition. So you need to scan through the class definition first, and look at the method definitions in a second pass, to tell x*y is an expression, and not a pointer declaration or whatever.

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A B(); is a function declaration even in a function definition. Look for most vexing parse... – AProgrammer Jun 30 '12 at 10:53

I have a feeling that there's some confusion between the formal definition of "context-sensitive" and the informal use of "context-sensitive". The former has a well-defined meaning. The latter is used for saying "you need context in order to parse the input".

This is also asked here: Context-sensitivity vs Ambiguity.

Here's a context-free grammar:

<a> ::= <b> | <c>
<b> ::= "x"
<c> ::= "x"

It's ambiguous, so in order to parse the input "x" you need some context (or live with the ambiguity, or emit "Warning: E8271 - Input is ambiguous in line 115"). But it's certainly not a context-sensitive grammar.

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How does having multiple symbols on the left hand side of a production solve this problem? I don't think this answer is answering the question. – Mehrdad Jan 29 '13 at 18:40
My answer is in response to the first sentence: "I often hear claims that C++ is a context-sensitive language." If those claims use the expression "context-sensitive" informally, then there's no problem. I don't think that C++ is formally context-sensitive. – Omri Barel Jan 29 '13 at 18:46
I think C++ is formally context-sensitive, but the problem I'm having is that I don't understand how a context-sensitive grammar would have any more success at parsing C++ than a CFG would. – Mehrdad Jan 29 '13 at 19:10

No Algol-like language is context-free, because they have rules that constrain expressions and statements that identifiers can appear in based on their type, and because there's no limit on the number of statements that can occur between declaration and use.

The usual solution is to write a context-free parser that actually accepts a superset of valid programs and put the context-sensitive portions in ad hoc "semantic" code attached to rules.

C++ goes well beyond this, thanks to its Turing-complete template system. See Stack Overflow Question 794015.

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True :)

J. Stanley Warford. Computer systems. Pages 341-346.

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It is context-sensitive, as a b(c); has two valid parses- declaration and variable. When you say "If c is a type", that's context, right there, and you've described exactly how C++ is sensitive to it. If you didn't have that context of "What is c?" you could not parse this unambiguously.

Here, the context is expressed in the choice of tokens- the parser reads an identifier as a typename token if it names a type. This is the simplest resolution, and avoids much of the complexity of being context-sensitive (in this case).

Edit: There are, of course, more issues of context sensitivity, I have merely focused on the one you've shown. Templates are especially nasty for this.

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Also a<b<c>>d, right? (Your example is actually a classic from C, where it is the only obstruction to being context-free.) – Kerrek SB Jan 29 '13 at 18:11
That's more of a lexing issue, I think. But is certainly in the same category, yes. – Puppy Jan 29 '13 at 18:12
Hm, good point. – Kerrek SB Jan 29 '13 at 18:12
The questioner doesn't ask how it's more context-sensitive than C, only to show that it is context-sensitive. – Puppy Jan 29 '13 at 18:13
@DeadMG I don't think you're answering the question (I don't think I was either). How does having terminals on the left hand side of a production solve this problem? – Mehrdad Jan 29 '13 at 18:38

The simplest case of non-context-free grammar involves parsing expressions involving templates.


This can parse as either

   a < expr > ()
      /   \
     b     c


 /   \
a   template
     b < expr > ()

The two ASTs can only be disambiguated by examining the declaration of 'a' -- the former AST if 'a' is a template, or the latter if not.

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I believe C++11 mandates the latter interpretation, and you have to add parens to opt-in to the former. – Joseph Garvin Jan 31 '13 at 19:12
@JosephGarvin, no. C++ mandates that < must be a bracket if it could be (eg., it follows an identifier which names a template). C++11 added the requirement that > and the first character of >> be interpreted as close brackets if that use is plausible. This affects the parsing of a<b>c> where a is a template but has no effect on a<b<c>. – rici Jan 31 '13 at 19:25
@aaron: how is that simpler than a(); (which is either or expr.type.conv)? – rici Jan 31 '13 at 19:32
@rici: Oops, I didn't realize it was asymmetric. – Joseph Garvin Feb 1 '13 at 14:51
Are you describing ambiguity, or context sensitivity? – jcora Mar 8 '14 at 18:37

C++ templates have been shown to be Turing Powerful. Although not a formal reference, here's a place to look in that regard:

I will venture a guess (as old as a folkoric and concise CACM proof showing that ALGOL in the 60's could not be reprsented by a CFG) and say that C++ cannot therefore be correctly parsed only by a CFG. CFGs, in conjunction with various TP mechanisms in either a tree pass or during reduction events -- this is another story. In a general sense, due to the Halting Problem, there exists some C++ program that cannot be shown to be correct/incorrect but is nonetheless correct/incorrect.

{PS- As the author of Meta-S (mentioned by several people above) -- I can most assuredly say that Thothic is neither defunct, nor is the software available for free. Perhaps I have worded this version of my response such that I do not get deleted or voted down to -3.}

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He seems to be referring to – Ira Baxter Sep 9 '11 at 3:32

C++ is not context free. I learned it some time ago in compilers lecture. A quick search gave this link, where the "Syntax or semantics" section explains why C and C++ are not context free:

Wikipedia Talk: Context-Free grammar


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The productions in the C++ standard are written context-free, but as we all know don't really define the language precisely. Some of what most people see as ambiguity in the current language could (I believe) be resolved unambiguously with a context sensitive grammar.

For the most obvious example, let's consider the Most Vexing Parse: int f(X);. If X is a value, then this defines f as a variable that will be initialized with X. If X is a type, it defines f as a function taking a single parameter of type X.

Looking at that from a grammatical viewpoint, we could view it like this:

A variable_decl ::= <type> <identifier> '(' initializer ')' ';'

B function_decl ::= <type> <identifier> '(' param_decl ')' ';'

A ::= [declaration of X as value]
B ::= [declaration of X as type]

Of course, to be entirely correct we'd need to add some extra "stuff" to account for the possibility of intervening declarations of other types (i.e., A and B should both really be "declarations including declaration of X as...", or something on that order).

This is still rather different from a typical CSG though (or at least what I recall of them). This depends on a symbol table being constructed -- the part that specifically recognizes X as a type or value, not just some type of statement preceding this, but the correct type of statement for the right symbol/identifier.

As such, I'd have to do some looking to be sure, but my immediate guess is that this doesn't really qualify as a CSG, at least as the term is normally used.

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Obviously, if you take the question verbatim, nearly all languages with identifiers are context sensitive.

One need to know if an identifier is a type name (a class name, a name introduced by typedef, a typename template parameter), a template name or some other name to be able to correctly some of the use of identifier. For instance:

x = (name)(expression);

is a cast if name is a type name and a function call if name is a function name. Another case is the so called "most vexing parse" where it isn't possible to differentiate variable definition and function declaration (there is a rule saying it is a function declaration).

That difficulty has introduced the need of typename and template with dependent names. The rest of C++ isn't context sensitive as far as I know (i.e. it is possible to write a context free grammar for it).

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Meta-S" is a context-sensitive parsing engine by Quinn Tyler Jackson. I've not used it, but he tells an impressive story. Check out his comments in comp.compilers, and see – Ira Baxter Jul 25 at 10:42

The correct link is parsing enigines

Meta-S was the property of a defunct company called Thothic. I can send a free copy of the Meta-S to anyone interested and I've used it in rna parsing research. Please note the "pseudoknot grammar" included in the examples folders was written by an non-bioinformatics, amature programmer and basically doesn't work. My grammars take a different approach and work quite well.

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This is actually an interesting find. – Dervin Thunk Sep 18 '09 at 15:11

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