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In the following code, why is the address held by pointer x changing after the delete? As I understand, the deletecall should free up allocated memory from heap, but it shouldn't change the pointer address.

using namespace std;
#include <iostream>
#include <cstdlib>

int main()
    int* x = new int;
    *x = 2;

    cout << x << endl << *x << endl ;

    delete x;

    cout << x << endl;

    return 0;


Observations: I'm using Visual Studio 2013 and Windows 8. Reportedly this doesn't work the same in other compilers. Also, I understand this is bad practice and that I should just reassign the pointer to NULL after it's deletion, I'm simply trying to understand what is driving this weird behaviour.

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Wierd behavior is sub-set of undefined behavior. –  Mahesh Dec 22 '13 at 0:43
@Mahesh (not to mention that it doesn't even require UB for delete to change the pointer's value.) –  user529758 Dec 22 '13 at 0:47

2 Answers 2

As I understand, the deletecall should free up allocated memory from heap, but it shouldn't change the pointer address.

Well, why not? It's perfectly legal output -- reading a pointer after having deleted it leads to undefined behavior. And that includes the pointer's value changing. (In fact, that doesn't even need UB; a deleted pointer can really point anywhere.)

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It's definitely the case that dereferencing a pointer after having deleted it provokes UB, but I am uncertain about examining the value of the pointer. In particular, I would have expected int *x, *y; x = new int(0); y = x; delete x; assert(x == y); to be strictly conforming and not trigger the assertion. Can you cite where the standard licenses delete to change the pointer value? –  zwol Dec 22 '13 at 0:50
@Zack Don't be uncertain about that, touching the pointer in any way (except assigning a new, valid address to it) after it has been invalidated is UB. –  user529758 Dec 22 '13 at 0:52
@H2CO3 Seriously, chapter and verse please. –  zwol Dec 22 '13 at 0:54
@Zack You seem to be way too sceptical. Why? C++11, p4 : "The effect of using an invalid pointer value (including passing it to a deallocation function) is undefined." –  user529758 Dec 22 '13 at 0:55
@BenjaminLindley Asserting that "but this is not UB because I assume XYZ" is. –  user529758 Dec 22 '13 at 0:57

Having read relevant bits of both C++98 and C++11 [N3485], and all the stuff H2CO3 pointed to:

Neither edition of the standard adequately describes what an "invalid pointer" is, under what circumstances they are created, or what their semantics are. Therefore, it is unclear to me whether or not the OP's code was intended to provoke undefined behavior, but de facto it does (since anything that the standard does not clearly define is, tautologically, undefined). The text is improved in C++11 but is still inadequate.

As a matter of language design, the following program certainly does exhibit unspecified behavior as marked, which is fine. It may, but should not also exhibit undefined behavior as marked; in other words, to the extent that this program exhibits undefined behavior, that is IMNSHO a defect in the standard. Concretely, copying the value of an "invalid" pointer, and performing equality comparisons on such pointers, should not be UB. I specifically reject the argument to the contrary from hypothetical hardware that traps on merely loading a pointer to unmapped memory into a register. (Note: I cannot find text in C++11 corresponding to C11 footnote 95, regarding the legitimacy of writing one union member and reading another; this program assumes that the result of this operation is unspecified but not undefined (except insofar as it might involve a trap representation), as it is in C.)

#include <string.h>
#include <stdio.h>

union ptr {
    int *val;
    unsigned char repr[sizeof(int *)];

int main(void)
    ptr a, b, c, d, e;

    a.val = new int(0);
    b.val = a.val;
    memcpy(c.repr, a.repr, sizeof(int *));

    delete a.val;
    d.val = a.val; // copy may, but should not, provoke UB
    memcpy(e.repr, a.repr, sizeof(int *));

    // accesses to b.val and d.val may, but should not, provoke UB
    // result of comparison is unspecified (may, but should not, be undefined)
    printf("b %c= d\n", b.val == d.val ? '=' : '!');

    // result of comparison is unspecified
    printf("c %c= e\n", memcmp(c.repr, e.repr, sizeof(int *)) ? '!' : '=');

This is all of the relevant text from C++98:

[] If the argument given to a deallocation function in the standard library is a pointer that is not the null pointer value (4.10), the deallocation function shall deallocate the storage referenced by the pointer, rendering invalid all pointers referring to any part of the deallocated storage. The effect of using an invalid pointer value (including passing it to a deallocation function) is undefined. [footnote: On some implementations, it causes a system-generated runtime fault.]

The problem is that there is no definition of "using an invalid pointer value", so we get to argue about what qualifies. There is a clue to the committee's intent in the discussion of iterators (a category which is defined to include bare pointers):

[24.1p5] ... Iterators can also have singular values that are not associated with any container. [Example: After the declaration of an uninitialized pointer x (as with int* x; [sic]), x must always be assumed to have a singular value of a pointer.] Results of most expressions are undefined for singular values; the only exception is an assignment of a non-singular value to an iterator that holds a singular value. In this case the singular value is overwritten the same way as any other value. Dereferenceable and past-the-end values are always non-singular.

It seems at least plausible to assume that an "invalid pointer" is also meant to be an example of a "singular iterator", but there is no text to back this up; going in the opposite direction, there is no text confirming the (equally plausible) assumption that an uninitialized pointer value is meant to be an "invalid pointer" as well s a "singular iterator". So the hair-splitters among us might not accept "results of most expressions are undefined" as clarifying what qualifies as use of an invalid pointer.

C++11 has changed the text corresponding to somewhat:

[] ... Indirection through an invalid pointer value and passing an invalid pointer value to a deallocation function have undefined behavior. Any other use of an invalid pointer value has implementation-defined behavior. [footnote: Some implementations might define that copying an invalid pointer value causes a system-generated runtime fault.]

(the text elided by the ellipsis is unchanged) We now have somewhat more clarity as to what is meant by "use of an invalid pointer value", and we can now say that the OP's code's semantics are definitely implementation-defined (but might be implementation-defined to be undefined). There is also a new paragraph in the discussion of iterators:

[24.2.1p10] An invalid iterator is an iterator that may be singular.

which confirms that "invalid pointer" and "singular iterator" are effectively the same thing. The remaining confusion in C++11 is largely about the exact circumstances that produce invalid/singular pointers/iterators; there should be a detailed chart of pointer/iterator lifecycle transitions (like there is for *values). And, as with C++98, the standard is defective to the extent it does not guarantee that copying-from and equality comparison upon such values are valid (not undefined).

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"copying the value of an "invalid" pointer, and performing equality comparisons on such pointers, should not be UB" - You can always make your own language if you don't like C++. The reason this is in the standard is that the "hypothetical" hardware you were addressing isn't hypothetical. Also, the pointers being invalid is the very same issue which is reading an uninitialized variable (trap representations, anyone?). –  user529758 Dec 22 '13 at 16:04
@H2CO3 You may have guessed that I don't much care for trap representations either ;-) Anyhow, no, I do not have to just take or leave the language, I am allowed to think the standard is buggy and to point out the bugs. I have good and solid reasons for objecting to the language as it is -- largely the difficulty of being certain that one never copies or compares such values. Your own citations included an observation that given some vector<T*> x, assigning to x[n] (n in range, invalid pointer in slot) might trigger a read from x[n] and therefore be UB. –  zwol Dec 22 '13 at 16:12
I have guessed that, but the thing is, if you are going to write code that relies on UB, that's still not good until the standard disagrees with you (in particular, you will be regarded as an uninformed programmer). You are free to think this and that, and you are free to share your opinion with the committee, but you can't deny the current state of the standard. Nevertheless, I'm not arguing that I like this being UB, and in fact, I think that C++ has quite a few serious flaws which should be amended. –  user529758 Dec 22 '13 at 16:20
@H2CO3: As Zack shows here, the behavior is implementation-defined, not undefined, in C++11. (And no, Zack, the implementation can not define the behavior as "undefined". "Undefined behavior" means it can vary from run to run, the compiler can assume you NEVER do that and optimize accordingly, and so on. Implementation-defined means it must do something specific and the documentation for your compiler must say what that is. Otherwise the distinction would be meaningless.) Very good discussion. +1 –  Nemo Dec 23 '13 at 1:50
@Nemo The C++11 footnote I quoted gives the implementation license to define this specific situation as runtime-undefined behavior. –  zwol Dec 23 '13 at 2:10

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