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I've posted this on the D newsgroup some months ago, but for some reason, the answer never really convinced me, so I thought I'd ask it here.


The grammar of D is apparently context-free.

The grammar of C++, however, isn't (even without macros). (Please read this carefully!)

Now granted, I know nothing (officially) about compilers, lexers, and parsers. All I know is from what I've learned on the web.
And here is what (I believe) I have understood regarding context, in not-so-technical lingo:

The grammar of a language is context-free if and only if you can always understand the meaning (though not necessarily the exact behavior) of a given piece of its code without needing to "look" anywhere else.

Or, in even less rigor:

The grammar cannot be context-free if I need I can't tell the type of an expression just by looking at it.

So, for example, C++ fails the context-free test because the meaning of confusing<sizeof(x)>::q < 3 > (2) depends on the value of q.

So far, so good.

Now my question is: Can the same thing be said of D?

In D, hashtables can be created through a Value[Key] declaration, for example

int[string] peoplesAges;   // Maps names to ages

Static arrays can be defined in a similar syntax:

int[3] ages;   // Array of 3 elements

And templates can be used to make them confusing:

template Test1(T...)
{
    alias int[T[0]] Test;
}

template Test2(U...)
{
    alias int[U] Test2;  // LGTM
}

Test1!(5) foo;
Test1!(int) bar;
Test2!(int) baz;  // Guess what? It's invalid code.

This means that I cannot tell the meaning of T[0] or U just by looking at it (i.e. it could be a number, it could be a data type, or it could be a tuple of God-knows-what). I can't even tell if the expression is grammatically valid (since int[U] certainly isn't -- you can't have a hashtable with tuples as keys or values).

Any parsing tree that I attempt to make for Test would fail to make any sense (since it would need to know whether the node contains a data type versus a literal or an identifier) unless it delays the result until the value of T is known (making it context-dependent).

Given this, is D actually context-free, or am I misunderstanding the concept?

Why/why not?


Update:

I just thought I'd comment: It's really interesting to see the answers, since:

  • Some answers claim that C++ and D can't be context-free
  • Some answers claim that C++ and D are both context-free
  • Some answers support the claim that C++ is context-sensitive while D isn't
  • No one has yet claimed that C++ is context-free while D is context-sensitive :-)

I can't tell if I'm learning or getting more confused, but either way, I'm kind of glad I asked this... thanks for taking the time to answer, everyone!

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3  
@VJo: It's comparing D's grammar to that of C++ (context-free vs. context-dependent). I tagged C++ instead of a different language because D's website compares itself to C++. –  Mehrdad Aug 8 '11 at 13:17
3  
Are we talking about templates, or the syntax in general? I think D has both pointers and multiplication, so what is a * b? –  Bo Persson Aug 8 '11 at 13:43
1  
@Cat Plus Plus: In D it's fully valid for a type to use any compile time evaluatable expressions. –  BCS Aug 8 '11 at 13:50
6  
fun how everyone presents his own theory of computer science in here. I'm eager to know who is right. I have no clue at all. I better not guess. –  Johannes Schaub - litb Aug 8 '11 at 20:30
4  
We need to get Walter to answer this question. –  Arlen Aug 9 '11 at 22:19

9 Answers 9

up vote 31 down vote accepted

Being context free is first a property of generative grammars. It means that what a non-terminal can generate will not depend on the context in which the non-terminal appears (in non context-free generative grammar, the very notion of "string generated by a given non-terminal" is in general difficult to define). This doesn't prevent the same string of symbols to be generated by two non-terminals (so for the same strings of symbols to appear in two different contexts with a different meaning) and has nothing to do with type checking.

It is common to extend the context-free definition from grammars to language by stating that a language is context-free if there is at least one context free grammar describing it.

In practice, no programming language is context-free because things like "a variable must be declared before it is used" can't be checked by a context-free grammar (they can be checked by some other kinds of grammars). This isn't bad, in practice the rules to be checked are divided in two: those you want to check with the grammar and those you check in a semantic pass (and this division also allows for better error reporting and recovery, so you sometimes want to accept more in the grammar than what would be possible in order to give your users better diagnostics).

What people means by stating that C++ isn't context-free is that doing this division isn't possible in a convenient way (with convenient including as criteria "follows nearly the official language description" and "my parser generator tool support that kind of division"; allowing the grammar to be ambiguous and the ambiguity to be resolved by the semantic check is an relatively easy way to do the cut for C++ and follow quite will the C++ standard, but it is inconvenient when you are relying on tools which don't allow ambiguous grammars, when you have such tools, it is convenient).

I don't know enough about D to know if there is or not a convenient cut of the language rules in a context-free grammar with semantic checks, but what you show is far from proving the case there isn't.

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3  
+1 for the point that the dividing like between the pure syntax checks and the semantic check being a somewhat arbitrary choice. –  BCS Aug 8 '11 at 15:40
    
I'm sorry but I don't know what "terminal" and "generative" mean. But either way, I'm really confused by your statement: "In practice, no programming language is context-free because things like 'a variable must be declared before it is used' can't be checked by a context-free grammar." Isn't that a semantic issue (unresolved reference) vs. a syntactic issue ("I can't figure out that this is trying to multiply two things, even though one of them doens't exist")? –  Mehrdad Aug 8 '11 at 15:43
10  
Grammars are a way of describing set of strings of terminals (the set of terminals is the alphabet). Generative grammars are the kind of grammar you are familiar with. One of my points was that the division between lexical, syntactic and semantic leave a large part to the arbitrary and is mostly driven by ease of description and availability of tools. And my second main point was that context-free has a formal definition for grammar and without stating precisely what you are ready to push in the lexical and semantic phase, you are in a "you know what I mean" realm. –  AProgrammer Aug 8 '11 at 16:01
    
Not the kind of answer I was looking for, but looks like the best one so far, +1. –  Mehrdad Aug 8 '11 at 20:52
2  
While this answer is correct, some may find it confusing because AProgrammer uses the language of Chomsky, where a grammar "generates" a string (the string is produced by the grammar) instead of the more natural notion of parsing: in a compiler we don't care about generating strings, we only care about the reverse process of interpreting the string. –  Qwertie Jun 8 '12 at 20:40

The property of being context free is a very formal concept; you can find a definition here. Note that it applies to grammars: a language is said to be context free if there is at least one context free grammar that recognizes it. Note that there may be other grammars, possibly non context free, that recognize the same language.

Basically what it means is that the definition of a language element cannot change according to which elements surround it. By language elements I mean concepts like expressions and identifiers and not specific instances of these concepts inside programs, like a + b or count.

Let's try and build a concrete example. Consider this simple COBOL statement:

   01 my-field PICTURE 9.9 VALUE 9.9.

Here I'm defining a field, i.e. a variable, which is dimensioned to hold one integral digit, the decimal point, and one decimal digit, with initial value 9.9 . A very incomplete grammar for this could be:

field-declaration ::= level-number identifier 'PICTURE' expression 'VALUE' expression '.'
expression ::= digit+ ( '.' digit+ )

Unfortunately the valid expressions that can follow PICTURE are not the same valid expressions that can follow VALUE. I could rewrite the second production in my grammar as follows:

'PICTURE' expression ::= digit+ ( '.' digit+ ) | 'A'+ | 'X'+
'VALUE' expression ::= digit+ ( '.' digit+ )

This would make my grammar context-sensitive, because expression would be a different thing according to whether it was found after 'PICTURE' or after 'VALUE'. However, as it has been pointed out, this doesn't say anything about the underlying language. A better alternative would be:

field-declaration ::= level-number identifier 'PICTURE' format 'VALUE' expression '.'
format ::= digit+ ( '.' digit+ ) | 'A'+ | 'X'+
expression ::= digit+ ( '.' digit+ )

which is context-free.

As you can see this is very different from your understanding. Consider:

a = b + c;

There is very little you can say about this statement without looking up the declarations of a,b and c, in any of the languages for which this is a valid statement, however this by itself doesn't imply that any of those languages is not context free. Probably what is confusing you is the fact that context freedom is different from ambiguity. This a simplified version of your C++ example:

a < b > (c)

This is ambiguous in that by looking at it alone you cannot tell whether this is a function template call or a boolean expression. The previous example on the other hand is not ambiguous; From the point of view of grammars it can only be interpreted as:

identifier assignment identifier binary-operator identifier semi-colon

In some cases you can resolve ambiguities by introducing context sensitivity at the grammar level. I don't think this is the case with the ambiguous example above: in this case you cannot eliminate the ambiguity without knowing whether a is a template or not. Note that when such information is not available, for instance when it depends on a specific template specialization, the language provides ways to resolve ambiguities: that is why you sometimes have to use typename to refer to certain types within templates or to use template when you call member function templates.

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May I be informed about what earned me a downvote? –  Nicola Musatti Aug 8 '11 at 14:48
    
I don't see what in your cobol code isn't context free (what follow PICTURE is a picture clause, what follow VALUE is an arithmetic expression, but the relationship isn't long distance enough not to be possible in a context-free grammar). a<b>(c) on the other hand as to have a different parse tree depending on the declaration of a, that's the kind of thing painful when possible to put in a CFG. –  AProgrammer Aug 8 '11 at 14:54
1  
Your COBOL example is wrong. This is perfectly legal in a context-free grammar. Just because a syntactic element can have multiple interpretations, that does not mean the language is context-sensitive. Look up the definition or read some of the other answers here for more details. –  hammar Aug 8 '11 at 15:03
1  
@Mehrdad: Meaning (aka. semantics) has nothing to do with the context-sensitivity of a language, which is a purely syntactic concept. –  hammar Aug 8 '11 at 15:19
1  
@Mehrdad: A context-free grammar can indeed be ambiguous, in that a string like int[T[0]] can be parsed in multiple ways. You can determine that it is valid syntax without looking at the context, just not what it means. In a context-sensitive language, even the validity of such a syntactic element depends on its context. –  hammar Aug 8 '11 at 15:36

The grammar cannot be context-free if I need I can't tell the type of an expression just by looking at it.

No, that's flat out wrong. The grammar cannot be context-free if you can't tell if it is an expression just by looking at it and the parser's current state (am I in a function, in a namespace, etc).

The type of an expression, however, is a semantic meaning, not syntactic, and the parser and the grammar do not give a penny about types or semantic validity or whether or not you can have tuples as values or keys in hashmaps, or if you defined that identifier before using it.

The grammar doesn't care what it means, or if that makes sense. It only cares about what it is.

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1  
state == context –  Hans Passant Aug 8 '11 at 14:22
    
@Hans: Pretty sure that context is only things like "What identifiers have been declared so far?". LALR grammars are context-free, but they still use the parser state to determine meaning. –  Puppy Aug 8 '11 at 14:48
    
Nothing prevent a string to be generated by two different non-terminals in a CFG. So just looking at that string won't indicates from which non-terminal it is generated. You need some context. But the context to take into account is more localized in CFG than in more powerful grammar. –  AProgrammer Aug 8 '11 at 15:00
    
@DeadMG: The grammar doesn't care what it means, or if that makes sense. It only cares about what it is. --> I'm confused. So you mean omg(!) is follows D syntax? Everything in that string looks right, except that an exclamation point isn't an identifier or a number... –  Mehrdad Aug 8 '11 at 15:35
    
I wouldn't know enough about D's syntax to know about a given string. –  Puppy Aug 8 '11 at 16:32

To answer the question of if a programming language is context free you must first decide where to draw the line between syntax and semantics. As an extreme example, it is illegal in C for a program to use the value of some kinds of integers after they have been allowed to overflow. Clearly this can't be checked at compile time, let alone parse time:

void Fn() {
  int i = INT_MAX;
  FnThatMightNotReturn();  // halting problem?
  i++;
  if(Test(i)) printf("Weeee!\n");
}

As a less extreme example that others have pointed out, deceleration before use rules can't be enforced in a context free syntax so if you wish to keep your syntax pass context free, then that must be deferred to the next pass.

As a practical definition, I would start with the question of: Can you correctly and unambiguously determine the parse tree of all correct programs using a context free grammar and, for all incorrect programs (that the language requires be rejected), either reject them as syntactically invalid or produce a parse tree that the later passes can identify as invalid and reject?

Given that the most correct spec for the D syntax is a parser (IIRC an LL parser) I strongly suspect that it is in fact context free by the definition I suggested.


Note: the above says nothing about what grammar the language documentation or a given parser uses, only if a context free grammar exists. Also, the only full documentation on the D language is the source code of the compiler DMD.

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+1 interesting point about syntax vs. semantics. However: "Can you correctly and unambiguously determine the parse tree of all correct programs using a context free grammar" --> Since associative arrays and statically sized arrays aren't part of the same parse tree (they're defined with a different syntax), they require potential transformations when used in a template, depending on context. Of course, the compiler compiles everything correctly, but the initial parse tree isn't correct. Is that context-free? Not to me, but I'm not sure. –  Mehrdad Aug 8 '11 at 16:10
    
Concerning my overflow example; I'd have to check but it might even be illegal to allow an overflow even if its result is never used. OTOH that doesn't change the point of the example. –  BCS Aug 8 '11 at 16:13
    
@Mehrdad: all that implies is that the document grammar (which is know to be wrong: e.g. a*b=c; is ambiguous in that grammar but unambiguously parsed by DMD) is not context free. With some trivial adjustments to the grammar, you can merge the productions so that it is unambiguous. You won't necessarily know know what the thing in the [] is but you will have correctly parsed it. –  BCS Aug 8 '11 at 16:18

There is a construct in D's lexer:

string ::= q" Delim1 Chars newline Delim2 "

where Delim1 and Delim2 are matching identifiers, and Chars does not contain newline Delim2.

This construct is context sensitive, therefore D's lexer grammar is context sensitive.

It's been a few years since I've worked with D's grammar much, so I can't remember all the trouble spots off the top of my head, or even if any of them make D's parser grammar context sensitive, but I believe they do not. From recall, I would say D's grammar is context free, not LL(k) for any k, and it has an obnoxious amount of ambiguity.

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A fact I remember from language theory is that identifier stuff sameidentifier in general is not context free. Before I posted, I ran the above production rule through the pumping lemma just to be sure. –  Ellery Newcomer Aug 16 '11 at 19:09
1  
Voted up because this is the only actual attempt to answer the question. –  johncip Jun 5 '13 at 21:59

These answers are making my head hurt.

First of all, the complications with low level languages and figuring out whether they are context-free or not, is that the language you write in is often processed in many steps.

In C++ (order may be off, but that shouldn't invalidate my point):

  1. it has to process macros and other preprocessor stuffs
  2. it has to interpret templates
  3. it finally interprets your code.

Because the first step can change the context of the second step and the second step can change the context of the third step, the language YOU write in (including all of these steps) is context sensitive.

The reason people will try and defend a language (stating it is context-free) is, because the only exceptions that adds context are the traceable preprocessor statements and template calls. You only have to follow two restricted exceptions to the rules to pretend the language is context-free.

Most languages are context-sensitive overall, but most languages only have these minor exceptions to being context-free.

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I wish I saw this question 3 years ago after taking courses on compilers, etc. I remember understanding this stuff well in school, but without any huge interest in compilers, I'm afraid I haven't studied them in many years. –  Jason McCarrell Aug 8 '11 at 17:35

There are already a lot of good answers, but since you are uninformed about grammars, parsers and compilers etc, let me demonstrate this by an example.

First, the concept of grammars are quite intuitive. Imagine a set of rules:

S -> a T
T -> b G t
T -> Y d
b G -> a Y b
Y -> c
Y -> lambda (nothing)

And imagine you start with S. The capital letters are non-terminals and the small letters are terminals. This means that if you get a sentence of all terminals, you can say the grammar generated that sentence as a "word" in the language. Imagine such substitutions with the above grammar (The phrase between *phrase* is the one being replaced):

*S* -> a *T* -> a *b G* t -> a a *Y* b t -> a a b t

So, I could create aabt with this grammar.

Ok, back to main line.

Let us assume a simple language. You have numbers, two types (int and string) and variables. You can do multiplication on integers and addition on strings but not the other way around.

First thing you need, is a lexer. That is usually a regular grammar (or equal to it, a DFA, or equally a regular expression) that matches the program tokens. It is common to express them in regular expressions. In our example:

(I'm making these syntaxes up)

number: [1-9][0-9]*    // One digit from 1 to 9, followed by any number
                       // of digits from 0-9
variable: [a-zA-Z_][a-zA-Z_0-9]*  // You get the idea. First a-z or A-Z or _
                                  // then as many a-z or A-Z or _ or 0-9
                                  // this is similar to C
int: 'i' 'n' 't'
string: 's' 't' 'r' 'i' 'n' 'g'
equal: '='
plus: '+'
multiply: '*'

whitespace: (' ' or '\n' or '\t' or '\r')*   // to ignore this type of token

So, now you got a regular grammar, tokenizing your input, but it understands nothing of the structure.

Then you need a parser. The parser, is usually a context free grammar. A context free grammar means, in the grammar you only have single nonterminals on the left side of grammar rules. In the example in the beginning of this answer, the rule

b G -> a Y b

makes the grammar context-sensitive because on the left you have b G and not just G. What does this mean?

Well, when you write a grammar, each of the nonterminals have a meaning. Let's write a context-free grammar for our example (| means or. As if writing many rules in the same line):

program -> statement program | lambda
statement -> declaration | executable
declaration -> int variable | string variable
executable -> variable equal expression
expression -> integer_type | string_type
integer_type -> variable multiply variable |
                variable multiply number |
                number multiply variable |
                number multiply number
string_type -> variable plus variable

Now this grammar can accept this code:

x = 1*y
int x
string y
z = x+y

Grammatically, this code is correct. So, let's get back to what context-free means. As you can see in the example above, when you expand executable, you generate one statement of the form variable = operand operator operand without any consideration which part of code you are at. Whether the very beginning or middle, whether the variables are defined or not, or whether the types match, you don't know and you don't care.

Next, you need semantics. This is were context-sensitive grammars come into play. First, let me tell you that in reality, no one actually writes a context sensitive grammar (because parsing it is too difficult), but rather bit pieces of code that the parser calls when parsing the input (called action routines. Although this is not the only way). Formally, however, you can define all you need. For example, to make sure you define a variable before using it, instead of this

executable -> variable equal expression

you have to have something like:

declaration some_code executable -> declaration some_code variable equal expression

more complex though, to make sure the variable in declaration matches the one being calculated.

Anyway, I just wanted to give you the idea. So, all these things are context-sensitive:

  • Type checking
  • Number of arguments to function
  • default value to function
  • if member exists in obj in code: obj.member
  • Almost anything that's not like: missing ; or }

I hope you got an idea what are the differences (If you didn't, I'd be more than happy to explain).

So in summary:

  • Lexer uses a regular grammar to tokenize input
  • Parser uses a context-free grammar to make sure the program is in correct structure
  • Semantic analyzer uses a context-sensitive grammar to do type-checking, parameter matching etc etc

It is not necessarily always like that though. This just shows you how each level needs to get more powerful to be able to do more stuff. However, each of the mentioned compiler levels could in fact be more powerful.

For example, one language that I don't remember, used array subscription and function call both with parentheses and therefore it required the parser to go look up the type (context-sensitive related stuff) of the variable and determine which rule (function_call or array_substitution) to take.

If you design a language with lexer that has regular expressions that overlap, then you would need to also look up the context to determine which type of token you are matching.

To get to your question! With the example you mentioned, it is clear that the c++ grammar is not context-free. The language D, I have absolutely no idea, but you should be able to reason about it now. Think of it this way: In a context free grammar, a nonterminal can expand without taking into consideration anything, BUT the structure of the language. Similar to what you said, it expands, without "looking" anywhere else.

A familiar example would be natural languages. For example in English, you say:

sentence -> subject verb object clause
clause -> .... | lambda

Well, sentence and clause are nonterminals here. With this grammar you can create these sentences:

I go there because I want to

or

I jump you that I is air

As you can see, the second one has the correct structure, but is meaningless. As long as a context free grammar is concerned, the meaning doesn't matter. It just expands verb to whatever verb without "looking" at the rest of the sentence.

So if you think D has to at some point check how something was defined elsewhere, just to say the program is structurally correct, then it's grammar is not context-free. If you isolate any part of the code and it still can say that it is structurally correct, then it is context-free.

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C++ was context-free before C++11. Now it is not anymore.

Why? Because we got contextual keywords: final and override.

Simple example to prove that:

struct Father {
  virtual void override();
};
struct Child: public Father {
  virtual void override() override;
};

You see? We need to see what's around override to identifiy if it is an identifier or a keyword.

Aside of that, C++ is context-free, even with turing-complete templates and stuff.

D, as far as I remember, is still context-free.

As a rule of thumb, I'd say that you can check if a language is context-free if you can highlight it properly using only simple regexes... you'd have trouble to properly contextual keywords.

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I don't think recognizing these particular contextual keywords requires a context-free grammar any more than the rest of the language does... –  Mehrdad Nov 20 '13 at 7:08
    
By experience I say it does... I've built a compiler for both languages. Most of the "contextualized" features of the language are pretty ok to handle during semantic analysis, later, but the override and final keywords are trickier. I've found out that, indeed, context-free languages are easy to highlight on an editor, while context-sensitive are not that easy (although doable). Of course I may be wrong, but... I think it was valid to point out that those new keywords add some context sensitivity to the parser itself. :) –  Paulo Torrens Nov 20 '13 at 16:17
    
I don't get it though. It's easy enough to just make a context-free production that says ReturnType FunctionName '(' Params ')' Qualifiers where Qualifiers can be either override or final or whatever, but FunctionName is just an identifier. Nothing here needs context-sensitivity, due to the parentheses. What am I missing? –  Mehrdad Nov 20 '13 at 17:14
    
You're missing that override can be both identifier and keyword_override. If FunctionName expands to identifier, it could be override to, that's why on my example there the function name is override too. In that case, to make it context-free again, Qualifiers would need to match identifier, any identifier, and then semantic analysis would reject anything but override/final. The problem arrives that when the lexer finds override or final it will need the context to know if it will be an identifier or a keyword. :) –  Paulo Torrens Nov 20 '13 at 19:10
    
I don't see how that causes a problem. You can have the FunctionName nonterminal defined as override | Identifier, problem solved. –  Mehrdad Nov 21 '13 at 4:33

I think of D as context free because it doesn't matter where I write a statement, it will always have the same or similar behavior everywhere (as long as it is allowed there ;) ).

For instance, in C++ Type something(); Might be a function prototype declaration. But if you write this inside a function, it creates a new object something and initializes it. I am not aware of anything like this in D.

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1  
-1: You're wrong about C++: Type something() declares function something, even inside a function. –  milleniumbug May 11 at 12:00

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