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In C99, we have compound literals, and they can be passed to functions as in:

f((int[2]){ 1, 2 });

However, if f is not a function but rather a function-like macro, gcc barfs on this due to the preprocessor parsing it not as one argument but as two arguments, "(int[2]){ 1" and "2 }".

Is this a bug in gcc or in the C standard? If it's the latter, that pretty much rules out all transparent use of function-like macros, which seems like a huge defect...

Edit: As an example, one would expect the following to be a conforming program fragment:

fgetc((FILE *[2]){ f1, f2 }[i]);

But since fgetc could be implemented as a macro (albeit being required to protect its argument and not evaluate it more than once), this code would actually be incorrect. That seems surprising to me.

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1  
It's normal and standard. Don't forget, macros have existed since long before any of this other gubbins, and they are not as intelligent. –  Lightness Races in Orbit Apr 5 '11 at 20:36
    
gcc 4.5.2 with the -std=c99 option accepts MACRO_FX( ( (int[2]){1, 2} ) ) to group the expression in your example into one argument. –  pmg Apr 5 '11 at 20:39
    
I'm aware of the workaround. But this means function-like macros cannot truly be "function-like" in C99. Prior to compound literals, I don't think the language had any construct where this issue mattered. –  R.. Apr 5 '11 at 21:04
    
...and Steve goes and proves me wrong! –  R.. Apr 5 '11 at 23:06
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3 Answers

up vote 5 down vote accepted

This "bug" has existed in the standard since C89:

#include <stdio.h>

void function(int a) {
    printf("%d\n", a);
}

#define macro(a) do { printf("%d\n", a); } while (0)

int main() {
    function(1 ? 1, 2: 3); /* comma operator */
    macro(1 ? 1, 2: 3);    /* macro argument separator - invalid code */
    return 0;
}

I haven't actually looked through the standard to check this parse, I've taken gcc's word for it, but informally the need for a matching : to each ? trumps both operator precedence and argument list syntax to make the first statement work. No such luck with the second.

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+1 excellent find for a case where this issue exists pre-C99. I suppose extra parentheses are just needed wherever a function could actually be defined as a function-like macro... –  R.. Apr 5 '11 at 23:05
    
@R..: yes, macros and code generators probably already put extra parentheses around anything they treat as an expression, out of paranoia, concern over operator precedence and silly semi-colons, etc. Real humans in practice will add them when the compiler tells them to, which I think it always will barring variadic function-like macro. –  Steve Jessop Apr 5 '11 at 23:38
    
Hmm, I suppose a variadic function-like macro is actually a solution to this problem! That is, an implementation could do #define fgets(...) __inline_fgets(__VA_ARGS__) and have it work in all cases. (#define fgets __inline_fgets on the other hand is not valid for an implementation to do because it will make the lone function name with no function-call operator evaluate to the wrong function pointer, i.e. different pointers in different translation units.) –  R.. Apr 6 '11 at 4:10
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This is per the C Standard, similar to how in C++, the following is a problem:

f(ClassTemplate<X, Y>) // f gets two arguments:  'ClassTemplate<X' and 'Y>'

If it is legal to add some extra parentheses there in C99, you can use:

f(((int[2]){ 1, 2 }));
  ^                ^

The rule specifying this behavior, from C99 §6.10.3/11, is as follows:

The sequence of preprocessing tokens bounded by the outside-most matching parentheses forms the list of arguments for the function-like macro.

The individual arguments within the list are separated by comma preprocessing tokens, but comma preprocessing tokens between matching inner parentheses do not separate arguments.

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To the extent that it's a bug at all, it's with the standard, not gcc (i.e., in this respect I believe gcc is doing what the standard requires).

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