196

In my company there is a coding rule that says, after freeing any memory, reset the variable to NULL. For example ...

void some_func () 
{
    int *nPtr;

    nPtr = malloc (100);

    free (nPtr);
    nPtr = NULL;

    return;
}

I feel that, in cases like the code shown above, setting to NULL does not have any meaning. Or am I missing something?

If there is no meaning in such cases, I am going to take it up with the "quality team" to remove this coding rule. Please advice.

2
  • 6
    it is always useful to be able to check if ptr == NULL before doing anything with it. If you don't nullify your free'd pointers you'd get ptr != NULL but still unusable pointer.
    – Mouradif
    Aug 3, 2016 at 16:17
  • 1
    Dangling pointers can lead to exploitable vulnerabilities such as Use-After-Free. Jan 4, 2017 at 10:13

23 Answers 23

340

Setting unused pointers to NULL is a defensive style, protecting against dangling pointer bugs. If a dangling pointer is accessed after it is freed, you may read or overwrite random memory. If a null pointer is accessed, you get an immediate crash on most systems, telling you right away what the error is.

For local variables, it may be a little bit pointless if it is "obvious" that the pointer isn't accessed anymore after being freed, so this style is more appropriate for member data and global variables. Even for local variables, it may be a good approach if the function continues after the memory is released.

To complete the style, you should also initialize pointers to NULL before they get assigned a true pointer value.

7
  • 3
    I don't understand why you would "initialize pointers to NULL before they get assigned a true pointer value"? Sep 1, 2009 at 14:46
  • 36
    @Paul: In the specific case, the declaration could read int *nPtr=NULL;. Now, I would agree that this would be redundant, with a malloc following right in the next line. However, if there is code between the declaration and the first initialization, somebody might start using the variable even though it has no value yet. If you null-initialize, you get the segfault; without, you might again read or write random memory. Likewise, if the variable later gets initialized only conditionally, later faulty accesses should give you instant crashes if you remembered to null-initialize. Sep 1, 2009 at 15:43
  • 1
    I personally think that in any none-trivial codebase getting an error for dereferencing null is as vague as getting an error for dereferencing an address you don't own. I personally never bother. Dec 8, 2010 at 21:33
  • 13
    Wilhelm, the point is that with a null pointer dereference you get a determinate crash and the actual location of the problem. A bad access may or may not crash, and corrupt data or behavior in unexpected ways in unexpected places.
    – Amit Naidu
    Sep 2, 2011 at 22:15
  • 5
    Actually, initializing the pointer to NULL has at least one significant drawback: it can prevent the compiler from warning you about uninitialized variables. Unless the logic of your code actually explicitly handles that value for the pointer (i.e. if (nPtr==NULL) dosomething...) it's better to leave it as-is.
    – Eric
    Nov 15, 2012 at 21:18
46

Most of the responses have focused on preventing a double free, but setting the pointer to NULL has another benefit. Once you free a pointer, that memory is available to be reallocated by another call to malloc. If you still have the original pointer around you might end up with a bug where you attempt to use the pointer after free and corrupt some other variable, and then your program enters an unknown state and all kinds of bad things can happen (crash if you're lucky, data corruption if you're unlucky). If you had set the pointer to NULL after free, any attempt to read/write through that pointer later would result in a segfault, which is generally preferable to random memory corruption.

For both reasons, it can be a good idea to set the pointer to NULL after free(). It's not always necessary, though. For example, if the pointer variable goes out of scope immediately after free(), there's not much reason to set it to NULL.

6
  • 1
    +1 This is actually a very good point. Not the reasoning about "double free" (which is completely bogus), but this. I'm not the fan of mechanical NULL-ing of pointers after free, but this actually makes sense. Dec 10, 2009 at 17:26
  • If you could access a pointer after freeing it through that same pointer, it's even more likely that you'd access a pointer after freeing the object it points to through some other pointer. So this doesn't help you at all -- you still have to use some other mechanism to ensure you don't access an object through one pointer after having freed it through another one. You might as well use that method to protect in the same pointer case too. May 19, 2012 at 10:41
  • 3
    @DavidSchwartz: I disagree with your comment. When I had to write a stack for an university exercise some weeks ago, I had a problem, I investigated a few hours. I accessed some already free'd memory at some point (the free was some lines too early). And sometimes it lead to very strange behaviour. If I would have set the pointer to NULL after freeing it, there would have been a "simple" segfault and I would have saved a couple of hours of work. So +1 for this answer!
    – mozzbozz
    May 31, 2014 at 21:04
  • 3
    @katze_sonne Even a stopped clock is right twice a day. It's much more likely that setting pointers to NULL will hide bugs by preventing erroneous accesses to already freed objects from segfaulting in code that checks for NULL and then silently fails to check an object it should have checked. (Perhaps setting pointers to NULL after free in specific debug builds might be helpful, or setting them to a value other than NULL that is guaranteed to segfault might make sense. But that this silliness happened to help you once is not an argument in its favor.) Jun 2, 2014 at 17:03
  • 1
    I always assign dead pointers to NULL since their addressed memory is no longer valid. I quite like the idea of using a replace value which is set to NULL in release mode, but something like (void*)0xdeadbeef in debug mode so you could detect any errant usage.
    – Den-Jason
    Oct 2, 2019 at 11:01
43

Setting a pointer to NULL after free is a dubious practice that is often popularized as a "good programming" rule on a patently false premise. It is one of those fake truths that belong to the "sounds right" category but in reality achieve absolutely nothing useful (and sometimes leads to negative consequences).

Allegedly, setting a pointer to NULL after free is supposed to prevent the dreaded "double free" problem when the same pointer value is passed to free more than once. In reality though, in 9 cases out of 10 the real "double free" problem occurs when different pointer objects holding the same pointer value are used as arguments for free. Needless to say, setting a pointer to NULL after free achieves absolutely nothing to prevent the problem in such cases.

Of course, it is possible to run into "double free" problem when using the same pointer object as an argument to free. However, in reality situations like that normally indicate a problem with the general logical structure of the code, not a mere accidental "double free". A proper way to deal with the problem in such cases is to review and rethink the structure of the code in order to avoid the situation when the same pointer is passed to free more than once. In such cases setting the pointer to NULL and considering the problem "fixed" is nothing more than an attempt to sweep the problem under the carpet. It simply won't work in general case, because the problem with the code structure will always find another way to manifest itself.

Finally, if your code is specifically designed to rely on the pointer value being NULL or not NULL, it is perfectly fine to set the pointer value to NULL after free. But as a general "good practice" rule (as in "always set your pointer to NULL after free") it is, once again, a well-known and pretty useless fake, often followed by some for purely religious, voodoo-like reasons.

5
  • 1
    Definitely. I don't remember ever causing a double-free that would be fixed by setting the pointer to NULL after freeing, but I've caused plenty that would not. Dec 10, 2009 at 19:36
  • 6
    @AnT "dubious" is a bit much. It all depends on the use case. If the value of the pointer is ever used in a true/false sense, it's not only a valid practice, it's a best practice.
    – Coder
    Jul 25, 2015 at 3:22
  • 1
    @Coder Completely wrong. If the value of the pointer is used in a true false sense to know whether or not it pointed to an object before the call to free, it's not only not best practice, it's wrong. For example: foo* bar=getFoo(); /*more_code*/ free(bar); /*more_code*/ return bar != NULL;. Here, setting bar to NULL after the call to free will cause the function to think it never had a bar and return the wrong value! Jan 19, 2017 at 3:50
  • 3
    I don't think the primary benefit is to protect against a double free, rather it's to catch dangling pointers earlier and more reliably. For example when freeing a struct that holds resources, pointers to allocated memory, file handles, etc., as I free the contained memory pointers and close the contained files, I NULL respective members. Then if one of the resources is accessed via a dangling pointer by mistake, the program tends to fault right there, every time. Otherwise, without NULLing, the freed data might not be overwritten yet and the bug might not be easily reproducible.
    – jimhark
    Sep 5, 2018 at 16:55
  • 2
    I agree that well structured code should not allow the case where a pointer is accessed after being freed or the case where it's freed two times. But in the real world my code will be modified and/or mantained by someone who probably doesn't know me and doesn't have the time and/or skills to do things properly (because the deadline is always yesterday). Therefore I tend to write bulletproof functions that don't crash the system even if misused.
    – mfloris
    Mar 26, 2019 at 9:06
21

This is considered good practice to avoid overwriting memory. In the above function, it is unnecessary, but oftentimes when it is done it can find application errors.

Try something like this instead:

#if DEBUG_VERSION
void myfree(void **ptr)
{
    free(*ptr);
    *ptr = NULL;
}
#else
#define myfree(p) do { void ** p_tmp = (p); free(*(p_tmp)); *(p_tmp) = NULL; } while (0)
#endif

The DEBUG_VERSION lets you profile frees in debugging code, but both are functionally the same.

Edit: Added do ... while as suggested below, thanks.

5
  • 3
    The macro version has a subtle bug if you use it after an if statement without brackets. Jun 23, 2009 at 22:11
  • What's with the (void) 0? This code do: if (x) myfree(&x); else do_foo(); becomes if (x) { free(*(&x)); *(&x) = null; } void 0; else do_foo(); The else is an error. Jun 25, 2009 at 15:11
  • That macro is a perfect place for the comma operator: free((p)), *(p) = null. Of course the next problem is it evaluates *(p) twice. It should be { void* _pp = (p); free(*_pp); *_pp = null; } Isn't the preprocessor fun. Jun 25, 2009 at 15:13
  • 6
    The macro shouldn't be in bare brackets, it should be in a do { } while(0) block so that if(x) myfree(x); else dostuff(); doesn't break.
    – Chris Lutz
    Dec 10, 2009 at 8:01
  • 3
    As Lutz said, the macro body do {X} while (0) is IMO the best way to make a macro body that "feels like and works like" a function. Most compilers optimize out the loop anyway.
    – Mike Clark
    Nov 13, 2010 at 7:57
8

Setting the pointer to the free'd memory means that any attempt to access that memory through the pointer will immediately crash, instead of causing undefined behavior. It makes it much easier to determine where things went wrong.

I can see your argument: since nPtr is going out of scope right after nPtr = NULL, there doesn't seem to be a reason to set it to NULL. However, in the case of a struct member or somewhere else where the pointer is not immediately going out of scope, it makes more sense. It's not immediately apparent whether or not that pointer will be used again by code that shouldn't be using it.

It's likely the rule is stated without making a distinction between these two cases, because it's much more difficult to automatically enforce the rule, let alone for the developers to follow it. It doesn't hurt to set pointers to NULL after every free, but it has the potential of pointing out big problems.

7

If you reach pointer that has been free()d, it might break or not. That memory might be reallocated to another part of your program and then you get memory corruption,

If you set the pointer to NULL, then if you access it, the program always crashes with a segfault. No more ,,sometimes it works'', no more ,,crashes in unpredictible way''. It's way easier to debug.

1
  • 5
    The program does not always crash with a segfault. If the way you access the pointer means that a large enough offset is applied to it before dereferencing, then it may reach addressable memory: ((MyHugeStruct *)0)->fieldNearTheEnd. And that's even before you deal with hardware that doesn't segfault on 0 access at all. However, the program is more likely to crash with a segfault. Aug 17, 2009 at 11:54
7

the most common bug in c is the double free. Basically you do something like that

free(foobar);
/* lot of code */
free(foobar);

and it end up pretty bad, the OS try to free some already freed memory and generally it segfault. So the good practice is to set to NULL, so you can make test and check if you really need to free this memory

if(foobar != null){
  free(foobar);
}

also to be noted that free(NULL) won't do anything so you don't have to write the if statement. I am not really an OS guru but I am pretty even now most OSes would crash on double free.

That's also a main reason why all languages with garbage collection (Java, dotnet) was so proud of not having this problem and also not having to leave to developers the memory management as a whole.

14
  • 12
    You can actually just call free() without checking - free(NULL) is defined as doing nothing.
    – Amber
    Dec 10, 2009 at 7:16
  • 6
    Doesn't that hide bugs? (Like freeing too much.) Dec 10, 2009 at 7:17
  • 1
    thanx, I got it. i tried : p = (char *)malloc(.....); free(p); if(p!=null) //p!=null is true, p is not null although freed { free(p); //Note: checking doesnot prevent error here }
    – StevenWang
    Dec 10, 2009 at 7:29
  • 6
    As I said, free(void *ptr) cannot change the value of the pointer it is passed. It can change the contents of the pointer, the data stored at that address, but not the address itself, or the value of the pointer. That would require free(void **ptr) (which is apparently not allowed by the standard) or a macro (which is allowed and perfectly portable but people don't like macros). Also, C isn't about convenience, it's about giving programmers as much control as they want. If they don't want the added overhead of setting pointers to NULL, it shouldn't be forced on them.
    – Chris Lutz
    Dec 10, 2009 at 7:51
  • 2
    There are few things in the world that give away the lack of professionalism on part of the C code author. But they include "checking the pointer for NULL before calling free" (along with such things as "casting the result of memory allocation functions" or "thoughtless using of type names with sizeof"). Dec 10, 2009 at 17:29
6

The idea behind this, is to stop accidental reuse of the freed pointer.

6

Recently I come across the same question after I was looking for the answer. I reached this conclusion:

It is best practice, and one must follow this to make it portable on all (embedded) systems.

free() is a library function, which varies as one changes the platform, so you should not expect that after passing pointer to this function and after freeing memory, this pointer will be set to NULL. This may not be the case for some library implemented for the platform.

so always go for

free(ptr);
ptr = NULL;
5

This (can) actually be important. Although you free the memory, a later part of the program could allocate something new that happens to land in the space. Your old pointer would now point to a valid chunk of memory. It is then possible that someone would use the pointer, resulting in invalid program state.

If you NULL out the pointer, then any attempt to use it is going to dereference 0x0 and crash right there, which is easy to debug. Random pointers pointing to random memory is hard to debug. It's obviously not necessary but then that's why it's in a best practices document.

2
  • On Windows, at least, debug builds will set the memory to 0xdddddddd so when you use a pointer to deleted memory you know right away. There should be similar mechanisms on all platforms.
    – i_am_jorf
    Jun 22, 2009 at 5:43
  • 2
    jeffamaphone, deleted memory block might have get reallocated and assigned to another object by the time you use the pointer again.
    – Constantin
    Jul 11, 2009 at 11:12
5

From the ANSI C standard:

void free(void *ptr);

The free function causes the space pointed to by ptr to be deallocated, that is, made available for further allocation. If ptr is a null pointer, no action occurs. Otherwise, if the argument does not match a pointer earlier returned by the calloc , malloc , or realloc function, or if the space has been deallocated by a call to free or realloc , the behavior is undefined.

"the undefined behavior" is almost always a program crash. So as to avoid this it is safe to reset the pointer to NULL. free() itself cannot do this as it is passed only a pointer, not a pointer to a pointer. You can also write a safer version of free() that NULLs the pointer:

void safe_free(void** ptr)
{
  free(*ptr);
  *ptr = NULL;
}
8
  • @DrPizza - An error (in my opinion) is something that causes your program not to work as it's supposed to. If a hidden double free breaks your program, it's an error. If it works exactly how it was intended to, it's not an error.
    – Chris Lutz
    Dec 10, 2009 at 7:32
  • @DrPizza: I've just found an argument why one should set it to NULL to avoid masking errors. stackoverflow.com/questions/1025589/… It seems like in either case some errors get hidden. Dec 10, 2009 at 7:41
  • 1
    Be aware that a void pointer-to-pointer has its problems: c-faq.com/ptrs/genericpp.html
    – Secure
    Dec 10, 2009 at 7:41
  • 3
    @Chris, no, the best approach is code structure. Don't throw random mallocs and frees all over your codebase, keep related things together. The "module" that allocates a resource (memory, file, ...) is responsible for freeing it and has to provide a function for doing so that keeps care for the pointers, too. For any specific resource, you then have exactly one place where it is allocated and one place where it is released, both close together.
    – Secure
    Dec 10, 2009 at 8:00
  • 4
    @Chris Lutz: Hogwash. If you write code that frees the same pointer twice, your program has a logical error in it. Masking that logical error by making it not crash doesn't mean that the program is correct: it's still doing something nonsensical. There is no scenario in which writing a double free is justified.
    – DrPizza
    Dec 10, 2009 at 15:45
4

I find this to be little help as in my experience when people access a freed memory allocation it's almost always because they have another pointer to it somewhere. And then it conflicts with another personal coding standard which is "Avoid useless clutter", so I don't do it as I think it rarely helps and makes the code slightly less readable.

However - I won't set the variable to null if the pointer isn't supposed to be used again, but often the higher level design gives me a reason to set it to null anyway. For example if the pointer is a member of a class and I've deleted what it points to then the "contract" if you like of the class is that that member will point to something valid at any time so it must be set to null for that reason. A small distinction but I think an important one.

In c++ it's important to always be thinking who owns this data when you allocate some memory (unless you are using smart pointers but even then some thought is required). And this process tends to lead to pointers generally being a member of some class and generally you want a class to be in a valid state at all times, and the easiest way to do that is to set the member variable to NULL to indicate it points to nothing now.

A common pattern is to set all the member pointers to NULL in the constructor and have the destructor call delete on any pointers to data that your design says that class owns. Clearly in this case you have to set the pointer to NULL when you delete something to indicate that you don't own any data before.

So to summarise, yes i often set the pointer to NULL after deleting something, but it's as part of a larger design and thoughts on who owns the data rather than due to blindly following a coding standard rule. I wouldn't do so in your example as I think there is no benefit to doing so and it adds "clutter" which in my experience is just as responsible for bugs and bad code as this kind of thing.

4

It is always advisable to declare a pointer variable with NULL such as,

int *ptr = NULL;

Let's say, ptr is pointing to 0x1000 memory address. After using free(ptr), it's always advisable to nullify the pointer variable by declaring again to NULL. e.g.:

free(ptr);
ptr = NULL;

If not re-declared to NULL, the pointer variable still keeps on pointing to the same address (0x1000), this pointer variable is called a dangling pointer. If you define another pointer variable (let's say, q) and dynamically allocate address to the new pointer, there is a chance of taking the same address (0x1000) by new pointer variable. If in case, you use the same pointer (ptr) and update the value at the address pointed by the same pointer (ptr), then the program will end up writing a value to the place where q is pointing (since p and q are pointing to the same address (0x1000)).

e.g.

*ptr = 20; //Points to 0x1000
free(ptr);
int *q = (int *)malloc(sizeof(int) * 2); //Points to 0x1000
*ptr = 30; //Since ptr and q are pointing to the same address, so the value of the address to which q is pointing would also change.
3

This rule is useful when you're trying to avoid the following scenarios:

1) You have a really long function with complicated logic and memory management and you don't want to accidentally reuse the pointer to deleted memory later in the function.

2) The pointer is a member variable of a class that has fairly complex behavior and you don't want to accidentally reuse the pointer to deleted memory in other functions.

In your scenario, it doesn't make a whole lot of sense, but if the function were to get longer, it might matter.

You may argue that setting it to NULL may actually mask logic errors later on, or in the case where you assume it is valid, you still crash on NULL, so it doesn't matter.

In general, I would advise you to set it to NULL when you think it is a good idea, and not bother when you think it isn't worth it. Focus instead on writing short functions and well designed classes.

3

This might be more an argument to initialize all pointers to NULL, but something like this can be a very sneaky bug:

void other_func() {
  int *p; // forgot to initialize
  // some unrelated mallocs and stuff
  // ...
  if (p) {
    *p = 1; // hm...
  }
}

void caller() {
  some_func();
  other_func();
}

p ends up in the same place on the stack as the former nPtr, so it might still contain a seemingly valid pointer. Assigning to *p might overwrite all kinds of unrelated things and lead to ugly bugs. Especially if the compiler initializes local variables with zero in debug mode but doesn't once optimizations are turned on. So the debug builds don't show any signs of the bug while release builds blow up randomly...

3

Set the pointer that has just been freed to NULL is not mandatory but a good practice. In this way , you can avoid 1) using a freed pointed 2)free it towice

3

There are two reasons:

Avoid crashes when double-freeing

Written by RageZ in a duplicate question.

The most common bug in c is the double free. Basically you do something like that

free(foobar);
/* lot of code */
free(foobar);

and it end up pretty bad, the OS try to free some already freed memory and generally it segfault. So the good practice is to set to NULL, so you can make test and check if you really need to free this memory

if(foobar != NULL){
  free(foobar);
}

also to be noted that free(NULL) won't do anything so you don't have to write the if statement. I am not really an OS guru but I am pretty even now most OSes would crash on double free.

That's also a main reason why all languages with garbage collection (Java, dotnet) was so proud of not having this problem and also not having to leave to developer the memory management as a whole.

Avoid using already freed pointers

Written by Martin v. Löwis in a another answer.

Setting unused pointers to NULL is a defensive style, protecting against dangling pointer bugs. If a dangling pointer is accessed after it is freed, you may read or overwrite random memory. If a null pointer is accessed, you get an immediate crash on most systems, telling you right away what the error is.

For local variables, it may be a little bit pointless if it is "obvious" that the pointer isn't accessed anymore after being freed, so this style is more appropriate for member data and global variables. Even for local variables, it may be a good approach if the function continues after the memory is released.

To complete the style, you should also initialize pointers to NULL before they get assigned a true pointer value.

0
2

To add to what other have said, one good method of pointer usage is to always check whether it is a valid pointer or not. Something like:


if(ptr)
   ptr->CallSomeMethod();

Explicitly marking the pointer as NULL after freeing it allows for this kind of usage in C/C++.

1
  • 5
    In many cases, where a NULL pointer makes no sense, it would be preferable to write an assertion instead. Jun 22, 2009 at 6:44
2

Settings a pointer to NULL is to protect agains so-called double-free - a situation when free() is called more than once for the same address without reallocating the block at that address.

Double-free leads to undefined behaviour - usually heap corruption or immediately crashing the program. Calling free() for a NULL pointer does nothing and is therefore guaranteed to be safe.

So the best practice unless you now for sure that the pointer leaves scope immediately or very soon after free() is to set that pointer to NULL so that even if free() is called again it is now called for a NULL pointer and undefined behaviour is evaded.

2

The idea is that if you try to dereference the no-longer-valid pointer after freeing it, you want to fail hard (segfault) rather than silently and mysteriously.

But... be careful. Not all systems cause a segfault if you dereference NULL. On (at least some versions of) AIX, *(int *)0 == 0, and Solaris has optional compatibility with this AIX "feature."

2

To the original question: Setting the pointer to NULL directly after freeing the contents is a complete waste of time, provided the code meets all requirements, is fully debugged and will never be modified again. On the other hand, defensively NULLing a pointer that has been freed can be quite useful when someone thoughtlessly adds a new block of code beneath the free(), when the design of the original module isn't correct, and in the case of it-compiles-but-doesn't-do-what-I-want bugs.

In any system, there is an unobtainable goal of making it easiest to the right thing, and the irreducible cost of inaccurate measurements. In C we're offered a set of very sharp, very strong tools, which can create many things in the hands of a skilled worker, and inflict all sorts of metaphoric injuries when handled improperly. Some are hard to understand or use correctly. And people, being naturally risk averse, do irrational things like checking a pointer for NULL value before calling free with it…

The measurement problem is that whenever you attempt to divide good from less good, the more complex the case, the more likely you get an ambiguous measurement. If the goal is do keep only good practices, then some ambiguous ones get tossed out with the actually not good. IF your goal is to eliminate the not good, then the ambiguities may stay with the good. The two goals, keep only good or eliminate clearly bad, would seem to be diametrically opposed, but there is usually a third group that's neither one nor the other, some of both.

Before you make a case with the quality department, try looking through the bug data base to see how often, if ever, invalid pointer values caused problems that had to be written down. If you want to make real difference, identify the most common problem in your production code and propose three ways to prevent it

1
  • Good answer. I'd like to add one thing. Reviewing the bug database is good to do for a variety of reasons. But in the context of the original question, keep in mind it would be hard to know how many invalid pointer problems were prevented, or at least caught so early as to not have made it into the bug database. Bug history provides better evidence for adding coding rules.
    – jimhark
    Sep 5, 2018 at 16:38
1

As you have a quality assurance team in place, let me add a minor point about QA. Some automated QA tools for C will flag assignments to freed pointers as "useless assignment to ptr". For example PC-lint/FlexeLint from Gimpel Software says tst.c 8 Warning 438: Last value assigned to variable 'nPtr' (defined at line 5) not used

There are ways to selectively suppress messages, so you can still satisfy both QA requirements, should your team decide so.

1

Long story short: You do not want to accidentally (by mistake) access the address that you have freed. Because, when you free the address, you allow that address in the heap to be allocated to some other application.

However, if you do not set the pointer to NULL, and by mistake try to de-reference the pointer, or change the value of that address; YOU CAN STILL DO IT. BUT NOT SOMETHING THAT YOU WOULD LOGICALLY WANT TO DO.

Why can I still access the memory location that I have freed? Because: You may have free the memory, but the pointer variable still had information about the heap memory address. So, as a defensive strategy, please set it to NULL.

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