This is from a 'magic' array library that I'm using.

sort(magic_list *l, int (*compare)(const void **a, const void **b))
    qsort(l->list, l->num_used, sizeof(void*),
         (int (*)(const void *,const void *))compare);

My question is: what on earth is the last argument to qsort doing?

(int (*)(const void *, const void*))compare) 

qsort takes int (*comp_fn)(const void *,const void *) as it's comparator argument, but this sort function takes a comparator with double pointers. Somehow, the line above converts the double pointer version to a single pointer version. Can someone help explain?

  • 4
    That C syntax means undefined behavior. – Joe Sep 8 '11 at 20:52
  • How the heck is someone supposed to make this work? If I were shown the prototype of that sort function and asked to write a compare function for it, I'd cast the arguments to int ** and double dereference them to get to the value, which would, in all likelihood, crash the program. Or give incorrect results. – Praetorian Sep 8 '11 at 21:03
  • something looks strange. the compare function might end up doing (**a > **b) but qsort will call compare with only pointers to elements. so it may dereference it one time too much. or maybe the elements in the array are pointers. and sort is sorting pointers. in that case a typedef would have been nice. – alvin Sep 8 '11 at 21:15

On most hardware you can assume that pointers all look the same at the hardware level. For example, in a system with flat 64bit addressing pointers will always be a 64bit integer quantity. The same is true of pointers to pointers or pointers to pointers to pointers to pointers.

Therefore, whatever method is used to invoke a function with two pointers will work with any function that takes two pointers. The specific type of the pointers doesn't matter.

qsort treats pointers generically, as though each is opaque. So it doesn't know or care how they're dereferenced. It knows what order they're currently in and uses the compare argument to work out what order they should be in.

The library you're using presumably keeps lists of pointers to pointers about. It has a compare function that can compare two pointers to pointers. So it casts that across to pass to qsort. It's just syntactically nicer than, e.g.

qsort(l->list, l->num_used, sizeof(void*), compare);

/* elsewhere */

int compare(const void *ptr1, const void *ptr2)
    // these are really pointers to pointers, so cast them across
    const void **real_ptr1 = (const void **)ptr1;
    const void **real_ptr2 = (const void **)ptr2;

    // do whatever with real_ptr1 and 2 here, e.g.
    return (*real_ptr2)->sort_key - (*real_ptr1)->sort_key;
  • 1
    There are lots of things that happen to "look the same at hardware level" at some specific platform. In general, however, this is not true. On top of that, the language does not care about things looking "the same at hardware level". Language clearly states that this is a hack leading to undefined behavior. – AnT Sep 8 '11 at 21:32
  • The language specification doesn't state anything of the sort — it's not the place of language specifications to make value judgments about code. If the C specification clearly stated that was "a hack leading to undefined behaviour" then the C specification would explicitly rule out the possibility of anyone creating a strict superset of the language. – Tommy Sep 8 '11 at 22:00
  • 1
    "it's not the place of language specifications to make value judgments about code" Yes, it is! Language specifications are designed to divide language implementations (and the specific details of those implementations) into two categories: conformant (or "good") and non-conformant (or "bad"). Non-conformant code is sometimes useful (for when you can rely on that particular implementation), but in general is bad, and should not be recommended. Anyway, -1 for "The specific type of the pointers doesn't matter." It clearly does. – Chris Lutz Sep 8 '11 at 22:09
  • No, a language specification defines somethings and leaves other things undefined, either implicitly or explicitly. That allows, for example, Objective-C to be a strict superset of C — it follows all the C rules and adds some new ideas where C leaves things undefined. But per your claim, that means that every time someone writes an Objective-C method call, that's a hack per the C99 specification rather than simply a concept it doesn't define. – Tommy Sep 8 '11 at 22:17
  • 1
    @Tommy: A hack takes place when someone relies on a specific manifestation of undefined behavior in a C program. So, that is a folded form of two-part statement: 1. Language says it's UB. 2 Relying on specific form of UB in the code is a hack. That way within the context on the original code one can draw the line from "language" to "hack". That's what I meant, no more no less. – AnT Sep 8 '11 at 22:40

That's exactly what the cast you quoted does: it converts a pointer of type

int (*)(const void **, const void **)

to a pointer of type

int (*)(const void *, const void *)

The latter is what is expected by qsort.

Thing like this are encountered rather often in bad quality code. For example, when someone wants to sort an array of ints, they often write a comparison function that accepts pointers to int *

int compare_ints(const int *a, const int *b) {
  return (*a > *b) - (*a < *b);

and when the time comes to actually call qsort they forcefully cast it to the proper type to suppress the compiler's complaints

qsort(array, n, sizeof *array, (int (*)(const void *,const void *)) compare_ints);

This is a "hack", which leads to undefined behavior. It is, obviously, a bad practice. What you see in your example is just a less direct version of the same "hack".

The proper approach in such cases would be to declare the comparison function as

int compare_ints(const void *a, const void *b) {
  int a = *(const int *) a;
  int b = *(const int *) b;
  return (a > b) - (a < b);

and then use it without any casts

qsort(array, n, sizeof *array, compare_ints);

In general, if one expects their comparison functions to be used as comparators in qsort (and similar functions), one should implemnent them with const void * parameters.

  • Can you comment a bit more on why that gives undefined behaviour? It sounds like there may be a subtlety here that I've missed and which renders answers including mine inaccurate. – Tommy Sep 8 '11 at 20:54
  • That's not undefined behavior in C, is it? And is it in C++? I'm interested, would you shed some light on it? – K-ballo Sep 8 '11 at 20:55
  • @K-ballo: That is undefined behavior in C. Type int(const void*, const void*) is not compatible with type int(const int*, const int*), which means that calling the function through a forcefully converted pointer leads to undefined behavior. – AnT Sep 8 '11 at 21:10
  • 1
    @Tommy: Converting one function pointer type to another and then calling the function through the converted value is only allowed when the function types are compatible. The full definition of compatibility is given in And the types above is not compatible, since const int * is not compatible with const void *. – AnT Sep 8 '11 at 21:14
  • IMHO there is nothing wrong with it. The program wants to sort an array of pointers. The cast could have been put inside the callback function: (a void*) can be cast to any pointer, including (void**). This is more-or-less a member function, containing the glue logic (including casts) between the std library and the stuff that is inside the magic_list thing. – wildplasser Sep 8 '11 at 21:45

The last argument to qsort is casting a function pointer taking double pointers, to one taking single pointers that qsort will accept. It's simply a cast.

  • Seems odd, though; why not cast it in sort's declaration? – Tom Zych Sep 8 '11 at 20:50
  • @Tom because the one in sort's declaration allows you to change the pointers so you can use them in the cast, that's why they're double pointers – Tony The Lion Sep 8 '11 at 20:52
  • @Tom To cast it in sort's declaration would burden the user of the function with the warning about the cast. Tony, good point, I'd overlooked the (in)convenience of just dereferencing with & – John Sep 8 '11 at 20:52
  • I would guess that cast has to do with the fact that sort is using qsort as an implementation detail. If it were to use the single pointer version in the declaration of sort, then its consumers would have to be the ones doing the cast when calling it. – K-ballo Sep 8 '11 at 20:53
  • @Tom_Zych, because the caller may be using a different type of args(the current arg type in sort()) which if directly passed to qsort() will generate a warning/error. which would mean fix every caller with a cast. that means ugly code. maybe the compare() function is part of legacy code. or too many callers. – alvin Sep 8 '11 at 20:57

It is casting a function pointer. I imagine that the reason is so that compare can be applied to the pointers that are dereferenced rather than whatever they are pointing to.


(int (*)(const void *,const void *))compare is a C style cast to cast the function pointer compare to a function pointer with two const void * args.


The last argument is a function pointer. It specifies that it takes a pointer to a function that returns an int and takes two const void ** arguments.

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