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I am new in C, trying to figure out about memory allocation in C that I kinda confused

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

typedef struct
    int a;
} struct1_t;

int main()
    funct1(); //init pointer
    return 1;

int funct2(struct1_t *ptr2struct)
    printf("print a is %d\n",ptr2struct->a);
    printf("value of ptr in funct2 is %p\n", ptr2struct);
    return 1; //success

int funct1(){

    struct1_t *ptr2struct = NULL;
    ptr2struct = malloc(sizeof(*ptr2struct));
    ptr2struct->a = 5;
    printf("value of ptr before used is %p", ptr2struct);
    if (funct2(ptr2struct) == 0) {
        goto error;

    printf("value of ptr in funct1 after freed is is %p\n", ptr2struct);
    return 1;

    if(ptr2struct) free(ptr2struct);
    return 0;

I have funct 1 that calls funct 2, and after using the allocated pointer in funct1, I try to free the pointer. And I create a case where if the return value in funct2 is not 1, then try again to free the pointer.

My question is below

which practice is better, if I should free the memory in funct2 (after I pass it) or in funct1 (after I finish getting the return value of funct1) The second thing is whether this is correct to make a goto error, and error:

if(ptr2struct) free(ptr2struct); 

My third question is , how do I check if the allocated value is already freed or not? because after getting the return value, I free the pointer, but if I print it, it shows the same location with the allocated one (so not a null pointer).

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4 Answers 4

up vote 7 down vote accepted

1) Should I free it in the calling function or in the called function?

I try to do the free-ing in the same function that does the malloc-ing. This keeps the memory-management concerns in one place and also gives better separation of concerns, since the called function in this case can also work with pointers that have not been malloc-ed or use the same pointer twice (if you want to do that).

2) Is it correct to do a "goto error"?

Yes! By jumping to a single place at the end of the function you avoid having to duplicate the resource-releasing code. This is a common pattern and isn't that bad since the "goto" is just serving as a kind of "return" statement and isn't doing any of its really tricky and evil stuff it is more known for.

//in the middle of the function, whenever you would have a return statement
// instead do
return_value = something;
goto DONE;


    //resorce management code all in one spot
    return return_value;

C++, on the other hand, has a neat way to do this kind of resource management. Since destructors are deterministically called right before a function exits they can be used to neatly package this king of resource management. They call this technique RAII

Another way other languages have to deal with this is finally blocks.

3) Can I see if a pointer has already been freed?

Sadly, you can't. What some people do is setting the pointer variable value to NULL after freeing it. It doesn't hurt (since its old value shouldn't be used after being freed anyway) and it has the nice property that freeing a null pointer is specified to be a no-op.

However, doing so is not foolproof. Be careful about having other variables aliasing the same pointer since they will still contain the old value, that is now a dangerous dangling pointer.

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If you can allocate and free in the same function, perhaps you should just keep it on the stack. –  MK. Nov 12 '11 at 3:52
@missingno : for this go to, is it correct : "if(ptr2struct) free(ptr2struct);" or I should just write " free(ptrstruct). because I think that ptr2struct is a pointer, so not a bool value, can I use this notation inside the goto if the return value is not correct? Thank you –  xambo Nov 12 '11 at 4:04
@MK: Some things (like variable-length arrays before C99) still need to be malloc-ed. Even then, trying to keep allocation and deallocation near each other (conceptually - it doesn't strictly need to be in the same function) is usually better. –  hugomg Nov 12 '11 at 4:12
@xambo: Those two versions are equivalent. if(ptr2struct) means if(ptr2struct != NULL); and free has no effect if you pass it the null pointer, anyway. And it's a bad sign if you have to call free on a pointer that may actually be null: it suggests that you're not calling free in the right place. But if your code is such that it's really possible that the pointer is null, I'd use the version with if, just so it's obvious to someone reading the code that that's expected to be a possibility. –  ruakh Nov 12 '11 at 4:13
@xambo: if you only free the pointer once, in the last bit of the function, you don't need to test to see if it was freed already or something like that so just free it (also,as ruakh pointed out it shouldn't really matter in this case) –  hugomg Nov 12 '11 at 4:14

Calling free() on a pointer doesn't change it, only marks memory as free. Your pointer will still point to the same location which will contain the same value, but that vluae can now get overwritten at any time, so you should never use a pointer after it is freed. To ensure that it is a good idea to always set the pointer to NULL after free'ing it.

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I know this is a C question but also setting it to 0 (zero) is good too - 0 and NULL are pretty much the same thing except for some language sematics –  Adrian Cornish Nov 12 '11 at 4:10

My question is below

which practice is better, if I should free the memory in funct2 (after I pass it) or in funct1 (after I finish getting the return value of funct1)

This is an "ownership" question. Who owns the allocated memory. Typically, this has to be decided based on the design of your program. For example, the only purpose of func1() could be to only allocate memory. That is, in your implementation, func1() is the function for memory allocation and then the "calling" function uses the memory. In that case, the ownership to free the memory is with the caller of func1 and NOT with func1().

The second thing is whether this is correct to make a goto error, and error: The use of "goto" is generally frowned about. It causes mess in the code that could just be easily avoided. However, I say "generally". There are cases where goto can be quiet handy and useful. For example, in big systems, configuration of the system is a big step. Now, imagine you call a single Config() function for the system which allocates memory for its different data structures at different points in the function like

       ...some config code...
       if ( a specific feature is enabled)
         f1 = allocateMemory();
         level = 1;
       ....some more code....
       if ( another feature is enabled)
         f2 = allocateMemory();
         level = 2;

       ....some more codee....
      if ( another feature is enabled)
        f3 = allocateMemor();
        level =3;

      /*some error happens */
       goto level_3;


In this case, you can use goto and elegantly free only that much memory that was allocated till the point the configuration failed.

However, suffice to say in your example goto is easily avoidable and should be avoided.

My third question is , how do I check if the allocated value is already freed or not? because after getting the return value, I free the pointer, but if I print it, it shows the same location with the allocated one (so not a null pointer).

Easy. Set the freed memory as NULL. The other advantage, apart from the one mentioned by MK, is that passing NULL pointer to free will cause a NOP i.e. no operation is performed. This will also help you avoid any double delete problems.

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so what if in the go to i write level_3: if(f3) free(f3) . So assume that if f3 has a value, then free it. or? –  xambo Nov 12 '11 at 4:14
xambo: yes that is correct though unnecessary. The idea, in the example, is that if you are at level 3, f3 would have been allocated successfully. –  Aditya Sehgal Nov 12 '11 at 4:23
If you goto level_3, you will free all three of them. If you goto level_2, you only free f2 and f1, etc. Works like switch cases that don't have breaks where execution falls through to the next case. –  gone Mar 26 '14 at 13:51

What i am about to share are my own development practices in C. They are by NO mean the ONLY way to organize yourself. I am just outlining a way not the way.

Okay, so, in many ways "C" is a loose language, so a lot of discipline and strictness comes from oneself as a developer. I've been developing in "C" for more than 20 years professionally, I've only very rarely have I had to fix any production-grade software that I have developed. While quite a bit of the success may be attributed to experience, a fair chunk of it is rooted in consistent practice.

I follow a set of development practices, which are quite extensive, and deal with everything as trivial as tabs to naming conventions and what not. I will limit my self to what I do about dealing with structures in general and there memory management in particular.

  • If I have a structure that's used throughout the software, I write create/destroy; init/done type functions for it:

     struct foo * init_foo(); 
     void done_foo(struct foo *);

    and allocate and de-allocate the structure in these functions.

  • If I manipulate a structure elements directly all over the program then don't typedef it. I take the pain of using the struct keyword in each declaration so that I know it's a structure. This is sufficient where the pain threshold is NOT so much that I would get annoyed by it. :-)

  • If I find that the structure is acting VERY much like an object then I choose to manipulate the structure elements STRICTLY through an opaque API; then I define its interface through set/get type functions for each element, I create a 'forward declaration' in the header file used by every other part of the program, create a an opaque typedef to the pointer of the structure, and only declare the actual structure in the structure API implementation file.


struct foo;
typedef struct foo foo_t;

void set_e1(foo_t f, int e1);
int  get_ei(foo_t f);

int  set_buf(foo_t f, const char *buf);
char * get_buf_byref(foo_t f)
char * get_buf_byval(foo_t f, char *dest, size_t *dlen);


#include <foo.h>

struct foo {
     int e1; 
     char *buf;

void set_e1(foo_t f, int e1) { 
        f->e1 = e1;

int  get_ei(foo_t f) { return f->e1; } 

void set_buf(foo_t f, const char *buf) {
     if ( f->buf ) free ( f->buf );
     f->buf = strdup(buf);

char *get_buf_byref(foo_t f) { return f->buf; } 
char *get_buf_byval(foo_t f, char **dest, size_t *dlen) {
    *dlen = snprintf(*dest, (*dlen) - 1, "%s", f->buf); /* copy at most dlen-1 bytes */ 
    return *dest;
  • If the related structures are very complicated you may even want to implement function pointers right into a base structure and then provide actual manipulators in particular extensions of that structure.

You will see a strong similarity between the approach i've outlined above and object oriented programming. It is meant to be that ...

If you keep your interfaces clean like this, whether or not you have to set instance variables to NULL all over the place won't matter. The code will, hopefully, yield itself to a tighter structure where silly mistakes are less likely.

Hope this helps.

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I prefer sticking to the "UpperCase for structs" convention in order to avoif typing the struct –  hugomg Nov 12 '11 at 4:41
:-) that's a perfectly valid way of doing it too. Consistency is the way to go. I avoid the TitleCasing approach because that is typically used in C++ or Java; and quite often I end up writing C code that is used in either of those languages so i use the foo_t convention for typedefs or struct foo for non-type defs. Again it's personal preference and your way is definitely easier on the eyes :-). –  Ahmed Masud Nov 12 '11 at 5:14

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