I'm working on an old code base and pretty much every invocation of free() uses a cast on its argument. For example,

free((float *)velocity);
free((float *)acceleration);
free((char *)label);

where each pointer is of the corresponding (and matching) type. I see no point in doing this at all. It's very old code, so I'm left wondering if it's a K&R thing. If so, I actually wish to support the old compilers that may have required this, so I don't want to remove them.

Is there a technical reason to use these casts? I don't even see much of a pragmatic reason to use them. What's the point of reminding ourselves of the data type right before freeing it?

EDIT: This question is not a duplicate of the other question. The other question is a special case of this question, which I think is obvious if the close voters would read all the answers.

Colophon: I'm giving the "const answer" the checkmark because it is a bonafide real reason why this might need to be done; however, the answer about it being a pre-ANSI C custom (at least among some programmers) seems to be the reason it was used in my case. Lots of good points by many people here. Thank you for your contributions.

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    "What's the point of reminding ourselves of the data type right before freeing it?" Maybe to know how much memory will be freed? – m0skit0 Dec 1 '15 at 12:03
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    @Codor The compiler doesn't do the deallocation, the operating system does. – m0skit0 Dec 1 '15 at 12:04
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    @m0skit0 "Maybe to know how much memory will be freed?" Type is not necessary to know how much to free. Cast for that reason only is bad coding. – user694733 Dec 1 '15 at 12:09
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    @m0skit0 Casting for readabilitys sake is always bad coding, because casting changes how types are interpreted and it may hide serious errors. When readability is needed, comments are better. – user694733 Dec 1 '15 at 12:14
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    In ancient days when dinosaurs walked the earth, and wrote programming books, I believe there was no void* in pre-standard C, but only char*. So if your archaeological findings reveal code casting the parameter to free(), I believe it must either be from that time period, or written by a creature from that time. I can't find any source for this though, so I'll refrain from answering. – Lundin Dec 1 '15 at 12:22

Casting may be required to resolve compiler warnings if the pointers are const. Here is an example of code that causes a warning without casting the argument of free:

const float* velocity = malloc(2*sizeof(float));

And the compiler (gcc 4.8.3) says:

main.c: In function ‘main’:
main.c:9:5: warning: passing argument 1 of ‘free’ discards ‘const’ qualifier from pointer target type [enabled by default]
In file included from main.c:2:0:
/usr/include/stdlib.h:482:13: note: expected ‘void *’ but argument is of type ‘const float *’
 extern void free (void *__ptr) __THROW;

If you use free((float*) velocity); the compiler stops complaining.

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    @m0skit0 that doesn't explain why someone would cast to float* before freeing. I tried free((void *)velocity); with gcc 4.8.3. Of course it wouldn't work with an ancient compiler – Manos Nikolaidis Dec 1 '15 at 12:40
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    But why would you need to dynamically allocate constant memory? You could never use it! – Nils_M Dec 1 '15 at 13:50
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    @Nils_M it's a simplified example to make a point. What I have done in actual code in a function is allocate non-const memory, assign values, cast to a const pointer and return it. Now, there is a pointer to preassigned const memory that someone has to free. – Manos Nikolaidis Dec 1 '15 at 14:19
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    Example:“These subroutines return the string in newly malloc'ed memory, pointed to by *stringValueP, that you must eventually free. Sometimes, the OS function you use to free memory is declared to take a pointer to something non-constant as its argument, so because *stringValueP is a pointer to a const.” – Carsten S Dec 1 '15 at 22:20
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    Erroneous, if a function takes const char *p as an argument and then frees it, the correct thing to do isn't to cast p to char* before calling free. It's to not declare it as taking const char *p in the first place, since it modifies *p and should be declared as accordingly. (And if it takes a const pointer instead of pointer to const, int *const p, you don't need to cast since it's actually legal and thus works fine without the cast.) – Ray Dec 3 '15 at 1:06

Pre-standard C had no void* but only char*, so you had to cast all parameters passed. If you come across ancient C code, you might therefore find such casts.

Similar question with references.

When the first C standard was released, the prototypes for malloc and free changed from having char* to the void* that they still have today.

And of course in standard C, such casts are superfluous and just harm readability.

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    But why would you cast the argument to free to the same type that it already is? – jwodder Dec 1 '15 at 13:49
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    @chux The problem with pre-standard is just that: there are no obligations for anything. People just pointed at the K&R book for canon because that was the only thing they had. And as we can see from several examples in K&R 2nd edition, K&R themselves are confused about how casts of the parameter to free work in standard C (you don't need to cast). I haven't read the 1st edition so I can't tell if they were confused in the 80s pre-standard times as well. – Lundin Dec 1 '15 at 15:38
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    Pre-standard C didn't have void*, but it didn't have function prototypes either, so casting the argument of free was still unnecessary even in K&R (assuming all data pointer types used the same representation). – Ian Abbott Dec 1 '15 at 16:04
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    For multiple reasons stated in the comments already, I don't think this answer makes sense. – R.. Dec 1 '15 at 17:07
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    I don't see how this answer would really answer anything relevant. The original question involves casts to other types, not only to char *. What sense would it make in old compilers without void? What would such casts achieve? – AnT Dec 1 '15 at 20:56

Here's an example where free would fail without a cast:

volatile int* p = (volatile int*)malloc(5 * sizeof(int));
free(p);        // fail: warning C4090: 'function' : different 'volatile' qualifiers
free((int*)p);  // success :)
free((void*)p); // success :)

In C you can get a warning (got one in VS2012). In C++ you'll get an error.

Rare cases aside, the casting just bloats the code...

Edit: I casted to void* not int* to demo the failure. It will work the same as int* will be converted to void* implicitly. Added int* code.

  • Note that in the code posted in the question, the casts are not to void *, but to float * and char *. Those casts are not just extraneous, they're wrong. – Andrew Henle Dec 1 '15 at 12:18
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    The question is actually about the opposite. – m0skit0 Dec 1 '15 at 12:18
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    I don't understand the answer; in what sense would free(p) fail? Would it give a compiler error? – Codor Dec 1 '15 at 12:35
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    These are good points. Same goes with const qualifier pointers, obviously. – Lundin Dec 1 '15 at 12:58
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    volatile has existed since C was standardized if not longer. It was not added in C99. – R.. Dec 1 '15 at 17:08

Old reason: 1. By using free((sometype*) ptr), code is explicit about the type the pointer should be considered as part of the free() call. The explicit cast is useful when free() is replaced with a (do-it-yourself) DIY_free().

#define free(ptr) DIY_free(ptr, sizeof (*ptr))

A DIY_free() was (is) a way, especially in debug mode, to do run-time analysis of the pointer being freed. This is often paired with a DIY_malloc() to add sententials, global memory usage counts, etc. My group used this technique for years before more modern tools appear. It obliged that the item being free'd was cast to the type is was originally allocated.

  1. Given the many hours spent tracking down memory issues, etc., little tricks like casting the type free'd would aid in searching and narrowing the debugging.

Modern: Avoiding const and volatile warnings as addressed by Manos Nikolaidis@ and @egur. Thought I would note the effects of the 3 qualifiers: const, volatile, and restrict.

[edit] Added char * restrict *rp2 per @R.. comment

void free_test(const char *cp, volatile char *vp, char * restrict rp, 
    char * restrict *rp2) {
  free(cp);  // warning
  free(vp);  // warning
  free(rp);  // OK
  free(rp2);  // warning

int main(void) {
  return 0;
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    restrict is only a non-issue because of where it's placed -- it affects the object rp not the pointed-to type. If you instead had char *restrict *rp, then it would matter. – R.. Dec 1 '15 at 17:10

Here is another alternative hypothesis.

We are told that the program was written pre-C89, which means it can't be working around some kind of mismatch with the prototype of free, because not only was there no such thing as const nor void * prior to C89, there was no such thing as a function prototype prior to C89. stdlib.h itself was an invention of the committee. If the system headers bothered to declare free at all, they would have done it like this:

extern free();  /* no `void` return type either! */

Now, the key point here is that the absence of function prototypes meant the compiler did no argument type checking. It applied the default argument promotions (the same ones that still apply to variadic function calls) and that was it. Responsibility for making the arguments at each callsite line up with the callee's expectations lay entirely with the programmer.

However, this still doesn't mean it was necessary to cast the argument to free on most K&R compilers. A function like

free_stuff(a, b, c)
    float *a;
    char *b;
    int *c;

should have been compiled correctly. So I think what we've got here is a program written to cope with a buggy compiler for an unusual environment: for instance, an environment where sizeof(float *) > sizeof(int) and the compiler wouldn't use the appropriate calling convention for pointers unless you cast them at the point of the call.

I am not aware of any such environment, but that doesn't mean there wasn't one. The most probable candidates that come to mind are cut-down "tiny C" compilers for 8- and 16-bit micros in the early 1980s. I also wouldn't be surprised to learn that early Crays had problems like this.

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    The first half I fully agree with. And the 2nd half is an intriguing and plausible conjecture. – chux Dec 3 '15 at 3:59

free takes in only non-const pointers as parameter. So in case of const pointers, explicit casting to a non-const pointer is required.

Unable to free const pointers in C

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