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Here's a random problem in C black magic I just came up with:

Write a function that returns 1 if malloc has been prototyped to return a pointer type and 0 if malloc has a return type of int (either implicitly or due to wrong prototype), without invoking any implementation-defined or undefined behavior.

I believe it's solvable, but I haven't worked out the solution. Note that calling the function cannot be necessary and in fact is not possible since calling a function with the incorrect prototype is undefined behavior. I have some ideas for ingredients but I think it makes for a better puzzle (and possibly more diverse ideas) if I leave them out for now.

I don't need the solution for any immediate use, but it could be handy in configure scripts and such.

Update: A better example of the usefulness (with strdup instead of malloc):

#undef strdup
#define strdup(x) (strdup_has_proto ? strdup((x)) : my_strdup((x)))

i.e. being able to implement X_has_proto as an expression at the source level could be a portable way to use functions which a system might or might not have, and fall back on a local replacement, without needing any separate configure step.

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@R.. So it's a function outside of C that's to determine the prototyping? –  Linus Kleen Dec 19 '10 at 16:06
    
I mean internally in the same translation unit context, not from the outside by running the preprocessor and parsing or looking for compiler warnings. –  R.. Dec 19 '10 at 16:24
    
If you're on a system where an int and a pointer are different sizes, you could compare the sizeof() the return value of malloc with that of int and void*, but that's as far as I've got so far. –  jstanley Dec 19 '10 at 16:52
    
Yeah, sadly that fails on 32-bit machines, but perhaps it's still useful since on most 32-bit implementations, the missing prototype will not actually affect code generation. The method I'm looking at involves ?: magic but I'm beginning to doubt whether it can be made to work. –  R.. Dec 19 '10 at 17:08
    
@R. the implicit function declaration part is easy :) C99 removes this feature from the language. So using any symbol in a context that implies that this is a function symbol is undefined behavior, I think. –  Jens Gustedt Dec 19 '10 at 17:24

4 Answers 4

How about some gloriously bad hacks?

char has_malloc = 0;
#define malloc(x) \
     has_malloc = 1; \
     malloc((x))
//.. run includes here
#undef malloc

But then, you could just #include <malloc.h> for the guarantee.

Edit: Why not just define an int malloc()? If anyone tries to call an int malloc, it should call your version instead.

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This answer has nothing to do with my question and is full of incorrect information. #include <malloc.h> is a nonstandard header, defining int malloc() with external linkage results in undefined behavior, and nowhere did I indicate any desire to do such a think in this question. –  R.. Dec 19 '10 at 22:34
    
Yeah, this is wrong. –  james woodyatt Dec 22 '10 at 17:35

There is no solution given the assumptions. What you need is a function whose body has free variables that represent the intermediate type information in the compiler that isn't ever lowered into the target language except in implementation-defined ways, e.g. debugger information. Relax the requirements so that you allow certain prescribed kinds of implementation-defined behavior, and you might find a solution.

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(1?0:malloc(1)) is an expression that evaluates to 0 ((int)0) if malloc has return type int and to a null pointer constant if malloc has return type void *, but I haven't yet found any way to detect whether the type of an expression is an integer or a pointer... –  R.. Dec 22 '10 at 18:24
    
You can't detect at runtime without using an implementation-dependent method, e.g. invoking the compiler with system() on a source text that attempts to evaluate the constant expression sizeof strdup(1)[0], which sadly won't work with any function that returns void*. See what I mean? No solution. –  james woodyatt Dec 22 '10 at 22:44
up vote 0 down vote accepted

Some partial answers and answers to related questions:

If the function in question is supposed to return a floating point type, the test is easy:

#define HAS_PROTO_FP_RET_1_ARG(f) !!((1?1:(f)(0))/2)

The 1 gets promoted to a floating point type if and only if f is declared to return a floating point type, and division by 2 results in a nonzero value if and only if 1 has floating point type.

This test could be useful for checking for the presence of C99 math functions.

With pointers, the expression (1?0:(f)(0)) is potentially useful - it evaluates to either 0 (an int) or (void *)0) (a null pointer constant) depending on the return type of f. But I have yet to find any devious way to test whether an expression has integer or pointer type.

The big problem I'm running into is that void * cannot participate in pointer arithmetic and does not implicitly convert to other pointer types in arithmetic contexts. For example, if it did, this would work (slightly breaking my rules about UB/IDB too):

#define HAS_PROTO_PTR_RET_1_ARG(f) ((int)((char (*)[2])2 - (1?0:(f)(0))) == 1)

Any ideas for getting around this problem?

Update: I have a solution that depends on nothing more than intmax_t being larger than int:

#define HAS_PROTO_PTR_RET_1_ARG(f) ( \
    sizeof(int)!=sizeof(void *) ? sizeof ((f)(0)) == sizeof(void *) : \
    sizeof (1?(intmax_t)0:(f)(0)) == sizeof(void *) )

There are two cases. If int and void * have different sizes, we simply check the size of the return value. Otherwise, int and void * are the same size, so (by the big assumption) intmax_t and void * are not the same size. We construct an expression whose type is intmax_t if the return type is int, and void * if the return type is void *, and test its size.

This macro fails only on machines where int, intmax_t, and void * all have the same size. Practically speaking, that means only on DSPs with 64-bit or larger int. Since pretty much all real POSIX and POSIX-like systems have fixed-size 32-bit int and intmax_t is required to be at least 64-bit, this is portable enough to make me happy.

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nope, for any pointer to a type with sizeof > 1 this could be done. But char* (and derivates) is not distinguishable from integers and void* can't do arithmetic. But your trick for float is cute. –  Jens Gustedt Dec 22 '10 at 19:05
    
@Jens: I've gotten pretty close to making a universal solution. Close enough for my needs anyway. –  R.. Dec 30 '10 at 0:51
    
Nice. Indeed a quite reasonable assumption. The other implicit assumption that you carry along is that pointer types all have the same width as void*. So your solution is a valid test for void*. Maybe on weird archs there are data pointers that are narrower. And then, you don't capture function pointers. They are not even conversion compatible with void*. But yeah, you solved the "missing prototype for malloc problem". Great! –  Jens Gustedt Dec 30 '10 at 8:18
    
@Jens: Indeed all pointer types can be different, but if you know the correct type you expect, you can just replace void * with that type and it works. And of course for anything but char types and void, the other trick usually works anyway. –  R.. Dec 30 '10 at 14:15

Since void * and int can be added I was thinking of other operators to try, such as comparison. The results, especially with R's ?: trick are oddly inconsistent:

int f() { return 0; }

void *g() { return 0; }

#define T(x)  (1?0:x())   /* R's trick from a comment */

void h()
{
    void *n = 0;
    int i = 0;

    f() > n;  /* m.c:12: warning: comparison between pointer and integer */
    g() > n;
    T(f) > n;
    T(g) > n;

    f() > i;
    g() > i;  /* m.c:18: warning: comparison between pointer and integer */
    T(f) > i;
    T(g) > i; /* m.c:20: warning: comparison between pointer and integer */
}
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