How can I free a const char*? I allocated new memory using malloc, and when I'm trying to free it I always receive the error "incompatible pointer type"

The code that causes this is something like:

char* name="Arnold";
const char* str=(const char*)malloc(strlen(name)+1);

free(str); // error here
  • Is there a particular reason you need to do it this way? Usually, string constants are you know of ahead of time, so to be dynamically allocating space for a string constant seems strange. May 12 '10 at 14:20
  • 4
    Basically a C language problem. The signature of free() should have been void free(const void* p);. Fixed in C++ (with delete)
    – MSalters
    May 12 '10 at 14:26
  • 9
    @James Kingsbery: interned strings, maybe: once you've populated your char buffer initially, it makes sense to treat it thereafter as a const char*. Do questioners really need our permission to have problems? ;-) May 12 '10 at 15:16
  • 7
    However, it makes no sense whatsoever. Once the memory is allocated to str, it's impossible to change it through str, which means that it is permanently whatever was in the memory when malloc() grabbed it. It isn't possible to copy the name in without casting str. (Also, assigning a string literal to a char * is not good, as trying to modify a string literal is undefined behavior. I think you just got your consts mixed up.) May 12 '10 at 15:32
  • 4
    @DavidThornley: The const char * you get may have been converted from char * after the contents are filled; e.g. from const char* foo() { char* s = malloc(...); strcpy(s, ...); return s; }.
    – musiphil
    Mar 7 '14 at 1:06

12 Answers 12


Several people have posted the right answer, but they keep deleting it for some reason. You need to cast it to a non-const pointer; free takes a void*, not a const void*:

  • 24
    It will work, but casting const to non-const is a symptom of code smell.
    – el.pescado
    May 12 '10 at 14:17
  • 2
    @el. free() is something of an exception, because you may not want the pointer to be modified during its lifetime, but you still want to free it at the end May 12 '10 at 14:20
  • 13
    Why the cast to char * ? why not directly free((void *) str) ?
    – philant
    May 12 '10 at 14:30
  • 51
    I recall reading about a memory deallocation function in the linux kernel that took a const pointer, and someone asked Linus why, and he defended it as saying it doesn't actually modify the value pointed to, either conceptually or in practice, it merely looks up the memory block using the pointer and deallocates it. I concur with his assessment, and thus view the free() function's specification as incorrect. But alas, it is the standard.
    – rmeador
    May 12 '10 at 15:48
  • 13
    If "freeing" was conceptually changing, then is it OK to declare a const int and then leave the scope in which it was declared? That "frees" the automatic variable, in the sense of releasing the resource and making pointers to it no longer valid. It's just a quirk that free takes non-const, it's not a commandment from on high. In the rare case that there's only one thing you do with your pointer that's non-const, and that's free it, then pragmatically you probably get more benefit from a const pointer (which you cast to free) than a non-const pointer (which you might accidentally modify). May 12 '10 at 19:31

Your code is reversed.


char* name="Arnold";
const char* str=(const char*)malloc(strlen(name)+1);

Should look like this:

const char* name="Arnold";
char* str=(char*)malloc(strlen(name)+1);

The const storage type tells the compiler that you do not intend to modify a block of memory once allocated (dynamically, or statically). Freeing memory is modifying it. Note, you don't need to cast the return value of malloc(), but that's just an aside.

There is little use in dynamically allocating memory (which you are doing, based on the length of name) and telling the compiler you have no intention of using it. Note, using meaning writing something to it and then (optionally) freeing it later.

Casting to a different storage type does not fix the fact that you reversed the storage types to begin with :) It just makes a warning go away, which was trying to tell you something.

If the code is reversed (as it should be), free() will work as expected since you can actually modify the memory that you allocated.

  • 4
    The OP asked how to free a pointer to a const qualified type- the attached code sample reflects his question, where your interpretation contradicts it. As an aside, the const qualifier on the pointed-to type doesn't affect or express any intention as to what will be done to/with an allocated object itself, it only affects what will be done via this pointer. Once/if you discard the pointed-to const qualifier you may modify the allocated object.
    – Dror K.
    Mar 3 '17 at 22:38
  • 1
    @DrorK. nevertheless, this is the most useful answer, at least for me, as I have made the same mistake as the OP. Most people encountering this problem are likely similarly confused, so I posit that this is actually the best answer. Apr 12 '20 at 21:04

It makes no sense to malloc a pointer to const, since you will not be able to modify its contents (without ugly hacks).

FWIW though, gcc just gives a warning for the following:

// const.c

#include <stdio.h>
#include <stdlib.h>

int main(void)
    const char *p = malloc(100);

    return 0;

$ gcc -Wall const.c -o const
const.c: In function ‘main’:
const.c:8: warning: passing argument 1 of ‘free’ discards qualifiers from pointer target type

What compiler are you using ?

  • 13
    Here is one case where you might like to free a pointer-to-const: char const* s = strdup("hello"); free(s);.
    – bobbogo
    Jul 19 '12 at 9:44
  • 2
    @bobbogo: yes, although it's hard to imagine why you'd want to make a const copy of a string literal in the first place.
    – Paul R
    Jul 19 '12 at 10:46
  • 10
    You may wish to take a copy of a string which is about to be freed() or otherwise changed by library code. You are not going to modify your copy, so you mark it const.
    – bobbogo
    Aug 27 '12 at 11:44

There are cases you want to free a const*. However you don't want to do it unless you allocate/asign it in the same function. Else you are likely to break things. See the code below for a real world example. I use const in the function declarations to show that I am not changing the content of the arguments. However it is reassigned with a lowercased duplicate (strdup) that needs to be freed.

char* tolowerstring(const char *to_lower)
    char* workstring = strdup(to_lower);
    for(;workstring != '\0'; workstring++)
        *workstring = tolower(workstring);
    return workstring;

int extension_checker(const char* extension, const char* to_check)
    char* tail = tolowerstring(to_check);
    extension = tolowerstring(extension);

    while ( (tail = strstr( tail+1, extension)) ) { /* The +1 prevents infinite loop on multiple matches */
        if ( (*extension != '.' ) && ( tail[-1] != '.'))
        if ( tail[strlen(extension)] == '\0') {
            free( (char*) extension);
            return 1;
    free( (char *) extension);
    return 0;

There's no purpose in casting a malloc'd pointer to const. Any function that takes a const pointer should not be responsible for freeing the memory that was passed to it.

  • What about code like struct foo { const char *bar; ... }? This expresses the fact that the memory pointed to by foo->bar should be treated as immutable (whereas other members of struct foo may be variable). This is useful for ensuring correctness of a program. Still bar may need to be malloc'd when the object is first initialized. If you want to free such an object, you need a way to free bar, too.
    – uncleremus
    Oct 27 '20 at 9:12
  • @uncleremus This is a matter of from whose perspective you're operating. The memory pointed to by foo->bar should be treated as immutable by the recipient. The memory pointed to by foo->bar should not be treated as immutable by whoever owns it, because they need to deallocate that memory, which definitely constitutes a mutation. So you need to show other people an immutable interface whilst retaining a mutable version for yourself.
    – Puppy
    Oct 28 '20 at 10:27
  • Are you suggesting using a union? struct foo { union { const char *bar; char *__bar; }; } would work, I guess.
    – uncleremus
    Oct 29 '20 at 13:19
  • @uncleremus I'm suggesting that you should have two completely different structs, one for internal use and one for external use.
    – Puppy
    Oct 30 '20 at 14:33
  • Even the "owner" code may need to modify the bar element only in one single place (the destructor), whereas it might pass around foo objects a lot and possibly modify other members. Even in the code owning the struct, protecting bar against mistaken modification with const is desirable. The const just needs to be cast away in the destructor.
    – uncleremus
    Jan 15 '21 at 13:34

Several answers have suggested simply casting to char*. But as el.pescado wrote above,

casting const to non-const is a symptom of code smell.

There are compiler warnings that guard against this, such as -Wcast-qual in gcc, which I find very useful. If you really have a valid case for freeing a const pointer (contrary to what many have written here, there are valid cases, as pointed out by nlstd), you could define a macro for that purpose like this:

#define free_const(x) free((void*)(long)(x))

This works at least for gcc. The double cast makes the logic -Wcast-qual not detect this as "casting const away". Needless to say, this macro should be used with care. Actually it should only be used for pointers allocated in the same function.

  • 4
    long should be replaced with intptr_t Jun 3 '18 at 22:31

I could be wrong but I think the problem lies in const. Cast the pointer to non-const like:

free((char *) p);

Because with const you say: Don't change the data this pointer points to.

  • 4
    free doesn't change the pointer. It frees the memory block the pointer is pointing to. This is a mistake in the language specification. free should clearly take a const pointer. May 12 '10 at 14:45
  • 6
    @Axel const means that you cannot change the contents of the storage object, not the actual value of the pointer... and freeing the pointed memory is a quite dramatic change I'd say! (BTW It seems a little bit pretentious to think that the specification is wrong [and has been wrong for more than 30 years] and suddenly you discover that you're right and all the review board members weren't, isn't it?)
    – fortran
    May 12 '10 at 14:56
  • 9
    @fortran: it's not at all pretentious, it's a common difference of opinion. delete in C++ can be used on a const char*, so if it's a big controversy then one or the other set of standard authors must be wrong. Actually I don't think it really matters - casting away const to free a pointer is hardly a crisis. May 12 '10 at 15:31
  • 3
    const char* says that what is being pointed to is a constant and cannot be changed. It is not saying that the pointer itself cannot be changed.
    – JeremyP
    May 12 '10 at 15:55
  • 4
    @Axel Gneiting: I never said that the pointer is changed. const indicates that the data at this location should not be changed. But if you free the memory, the data at this location can be overwritten and therefore changed. May 12 '10 at 18:41

If you are talking about pure C and you are in complete control of the memory allocation you can use the following trick to cast (const char *) to (char *) which will not give you any warning in compiler:

const char *const_str = (const char *)malloc(...);
char *str = NULL;

union {
  char *mutable_field_p;
  const char *const_field_p;
} u;

u.const_field_p = const_str;
str = u.mutable_field_p;

Now you can use free(str); to free the memory.

But BEWARE that this is evil beyond words and should be only used in strictly controlled environment (e.g. library which allocates and frees strings, but doesn't want to allow user to modify them) Otherwise you will end up with your program crashing when someone provides compile time "STRING" to your free function.

  • 1
    Why on Earth would you use this ugly hack with a pointless union when a plain cast can alter constness just fine on its own? May 24 '17 at 10:09

I think the real answer is that free should take a const pointer argument and NULL should be defined as a const pointer. This seems to be a bug in the standards. Freeing a const pointer should be implemented as follows:

p = NULL;

I don't see how a compiler could generate incorrect code in this case, the const pointer p is no longer accessible, so it doesn't matter if the object it pointed to is const, valid, whatever else. Its const so there can't be any dirty copies in registers or anywhere else. It is valid to set a const pointer to another value, and the fact that that value is NULL doesn't matter because the previous value is no longer accessible.


If you take a look at the signature of free function , free always takes void* ptr as an argument therefore you need to cast it to the appropriate type i.e. free((void *)str); free does not allow const pointers to be deallocated directly therefore you need to cast it to non const type


You cannot free const char * because it is const. Store pointers received from malloc in non-const pointer variables, so that you can pass them to free. You can pass char * arguments to functions taking const char * arguments but opposite is not always true.

void foo (const char *x);
char *ptr = malloc (...);
foo (ptr);
free (ptr);
  • 5
    In C++, you can delete a const char*. And why shouldn't you? The fact that the pointer prevents the characters from being modified shouldn't disallow to delete the string once it isn't needed anymore. I don't know C well enough, though. Anyone with a quote from the std here?
    – sbi
    May 12 '10 at 14:19
  • 3
    -1, the constness of a pointer doesn't affect your ability to free it in any way.
    – Hasturkun
    May 12 '10 at 14:24
  • 2
    @JeremyP: The answer is Undefined Behavior (or possibly nasal demons), but that's not caused by the const so much as by trying to free a string constant.
    – Hasturkun
    May 12 '10 at 16:29
  • 2
    @JeremyP That example is specious; it's wrong, but not because the string is const, it's just a special case of string literals May 12 '10 at 17:02
  • 2
    @JeremyP: "You should never free a const char*." I disagree. If that was true, you should never have const strings that are dynamically allocated, because you couldn't delete them. And that's just stupid. Whether something is allocated dynamically and whether it should not be altered are orthogonal questions. I can have dynamically allocated strings which I don't want to have altered, but which have to be freed at some point. I consider this a bug in the C std lib, probably stemming from the fact that C adopted const from C++ only later and it's now somewhat like a red-haired step child.
    – sbi
    May 14 '10 at 16:08

I think even if you cast the pointer to a non-const, the result of free will depends on the implementation. Normally const was designed for variable that you don't want to modify !!

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