I don't really understand why are those pointer accessible ... any help appreciated

#include <iostream>

class Wicked{
    Wicked() {};
    virtual ~Wicked() {};

    int a;
    int b;

class Test
    Test() {};
    virtual ~Test() {};

    int c;

    Wicked * TestFunc()
        Wicked * z;
        c = 9;
        z = new Wicked;
        z->a = 1;
        z->b = 5;
        return z;

int main()
    Wicked *z;

    Test *t = new Test();
    z = t->TestFunc();

    delete z;
    delete t;

    // why can I set 'z' when pointer is already destroyed?
    z->a = 10;

    // why does z->a print 10?
    std::cout << z->a << std::endl;

    // why does t->c exist and print correct value?
    std::cout << t->c << std::endl;


    int * p = new int;
    *p = 4;

    // this prints '4' as expected
    std::cout << *p << std::endl;

    delete p;

    // this prints memory address as expected
    std::cout << *p << std::endl;

    return 0;

closed as not a real question by Gregory Pakosz, Raymond Chen, TMS, Kate Gregory, user207421 Oct 19 '11 at 21:44

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center. If this question can be reworded to fit the rules in the help center, please edit the question.

  • 1
    I don't really understand what is the question. – TMS Oct 19 '11 at 20:11
  • Unless you rephrase your question, it's my guess it's going to be closed very soon. – xtofl Oct 19 '11 at 20:12
  • after 'z' and 't' pointers are deleted they still print value – user1003948 Oct 19 '11 at 20:14
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    OP is asking how come after deleting the pointer he gets the old values i.e. the memory is accesible.I don't see a problem with the question – Cratylus Oct 19 '11 at 20:15
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Deleting a pointer doesn't zero out any memory because to do so would take CPU cycles and that's not what C++ is about. What you have there is a dangling pointer, and potentially a subtle error. Code like this can sometimes work for years only to crash at some point in the future when some minor change is made somewhere else in the program.

This is a good reason why you should NULL out pointers when you've deleted the memory they point to, that way you'll get an immediate error if you try to dereference the pointer. It's also sometimes a good idea to clear the memory pointed to using a function like memset(). This is particularly true if the memory pointed to contains something confidential (e.g. a plaintext password) which you don't want other, possibly user facing, parts of your program from having access to.

  • 2
    NULL'ing the pointer can lead to other types of error being hidden (potentially for long periods). Best to just use smart pointers and not even get into this situation. Also there is no guarantee that de-referencing a NULL pointer will generate an error (any more than other locations) best not to rely on this to detect errors. – Martin York Oct 19 '11 at 20:50
  • Dereferencing a NULL pointer is undefined behavior and so yes I guess it could do anything, but have you ever known an implmentation which won't perform an immediate segmentation fault? I don't think I've ever seen this. Also much as I love smart pointers, some of these can have their pitfalls as well. Circular reference issues with smart_ptr for example can be a nightmare to debug. Although I grant you, uniq_ptr is reasonably fail safe if it's suitable for your usage. – Benj Oct 19 '11 at 21:38
  • Yes several. There are actually several questions on SO that ask "why is it not crashing when I de-reference NULL". how-can-dereferencing-a-null-pointer-in-c-not-crash-a-program – Martin York Oct 19 '11 at 21:41
  • I guess you didn't actually read that question you linked to, the OP says in his "solution" section that "The pointer in question is not NULL", it turned out that he was expecting the delete to NULL the pointer. – Benj Oct 19 '11 at 21:47
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    Opps. You are write I did not read it I just assumed people were smart enough to write a good title. I suppose people are stupider than I like to believe (including myself). – Martin York Oct 19 '11 at 23:28

That's undefined behaviour. Anything can happen.You were lucky this time. Or perhaps unlucky since it would be preferable to get a runtime error! Next time round maybe you'll get a runtime error.

It's not really very useful to reason about why you see a particular manifestation of undefined behaviour. It's best to stick to the well-defined behaviour about which you can reason.


C++ won't stop you from writing to an arbitrary location in memory. When you allocate memory with new or malloc, C++ finds some unused space in memory, marks it as allocated (so that it doesn't accidentally get handed out again), and gives you its address.

Once you delete that memory however, C++ marks it as free and may hand it out to anyone that asks for it. You can still write to it and read from it, but at this point, someone else might be using it. When you write to that place in memory, you may be overwriting some value you have allocated elsewhere.



// why can I set 'z' when pointer is already destroyed?
z->a = 10;

z still points at a memory location.
But it no longer blongs to you. You have passed it to delete and said take care of this pointer. What it does is no longer your concern. Its like when you sell your car; it still exists but its not yours so opening the door and looking in may be possible, but it may result in the police arresting you.

Same with deleted pointers the memory exists but does not belong to you.
If you look inside it may work, but it may also cause a segmentation fault as the library has flushed the page (you never know).


delete z; just deallocates the memory z was pointing to, it does not destroy the pointer itself.

So z becomes a wild pointer.


Because deleting a block of memory does not zero the value of all pointers that point to it. Deleting memory merely makes a note that the memory is available to be allocated for some other purpose. Until that happens, the memory may appear to be intact -- but you can't count on it, and on some compiler/runtime/architecture combinations, your program will behave differently -- it may even crash.

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