Consider the following code:

#include <iostream>

struct foo
    // (a):
    void bar() { std::cout << "gman was here" << std::endl; }

    // (b):
    void baz() { x = 5; }

    int x;

int main()
    foo* f = 0;

    f->bar(); // (a)
    f->baz(); // (b)

We expect (b) to crash, because there is no corresponding member x for the null pointer. In practice, (a) doesn't crash because the this pointer is never used.

Because (b) dereferences the this pointer ((*this).x = 5;), and this is null, the program enters undefined behavior, as dereferencing null is always said to be undefined behavior.

Does (a) result in undefined behavior? What about if both functions (and x) are static?

  • If both functions are static, how could x be referred inside baz? (x is a non-static member variable)
    – legends2k
    Sep 29, 2010 at 16:09
  • 4
    @legends2k: Pretend x was made static too. :)
    – GManNickG
    Sep 29, 2010 at 21:25
  • Surely, but for the case (a) it works the same in all cases, i.e, the function gets invoked. However, replacing the value of the pointer from 0 to 1 (say, through reinterpret_cast), it almost invariably always crashes. Does the value allocation of 0 and thus NULL, as in case a, represents something special to the compiler ? Why does it always crash with any other value allocated to it? Dec 28, 2010 at 12:18
  • 5
    Interesting: Come the next revision of C++, there shall be no more dereferencing of pointers at all. We shall now perform indirection through pointers. To find out more, please perform indirection through this link: N3362 Jun 5, 2012 at 21:08
  • 4
    Invoking a member function on a null pointer is always undefined behavior. Just by looking at your code, I can already feel the undefined behavior slowly crawling up my neck! Jul 27, 2012 at 9:02

2 Answers 2


Both (a) and (b) result in undefined behavior. It's always undefined behavior to call a member function through a null pointer. If the function is static, it's technically undefined as well, but there's some dispute.

The first thing to understand is why it's undefined behavior to dereference a null pointer. In C++03, there's actually a bit of ambiguity here.

Although "dereferencing a null pointer results in undefined behavior" is mentioned in notes in both §1.9/4 and §8.3.2/4, it's never explicitly stated. (Notes are non-normative.)

However, one can try to deduced it from §3.10/2:

An lvalue refers to an object or function.

When dereferencing, the result is an lvalue. A null pointer does not refer to an object, therefore when we use the lvalue we have undefined behavior. The problem is that the previous sentence is never stated, so what does it mean to "use" the lvalue? Just even generate it at all, or to use it in the more formal sense of perform lvalue-to-rvalue conversion?

Regardless, it definitely cannot be converted to an rvalue (§4.1/1):

If the object to which the lvalue refers is not an object of type T and is not an object of a type derived from T, or if the object is uninitialized, a program that necessitates this conversion has undefined behavior.

Here it's definitely undefined behavior.

The ambiguity comes from whether or not it's undefined behavior to deference but not use the value from an invalid pointer (that is, get an lvalue but not convert it to an rvalue). If not, then int *i = 0; *i; &(*i); is well-defined. This is an active issue.

So we have a strict "dereference a null pointer, get undefined behavior" view and a weak "use a dereferenced null pointer, get undefined behavior" view.

Now we consider the question.

Yes, (a) results in undefined behavior. In fact, if this is null then regardless of the contents of the function the result is undefined.

This follows from §5.2.5/3:

If E1 has the type “pointer to class X,” then the expression E1->E2 is converted to the equivalent form (*(E1)).E2;

*(E1) will result in undefined behavior with a strict interpretation, and .E2 converts it to an rvalue, making it undefined behavior for the weak interpretation.

It also follows that it's undefined behavior directly from (§9.3.1/1):

If a nonstatic member function of a class X is called for an object that is not of type X, or of a type derived from X, the behavior is undefined.

With static functions, the strict versus weak interpretation makes the difference. Strictly speaking, it is undefined:

A static member may be referred to using the class member access syntax, in which case the object-expression is evaluated.

That is, it's evaluated just as if it were non-static and we once again dereference a null pointer with (*(E1)).E2.

However, because E1 is not used in a static member-function call, if we use the weak interpretation the call is well-defined. *(E1) results in an lvalue, the static function is resolved, *(E1) is discarded, and the function is called. There is no lvalue-to-rvalue conversion, so there's no undefined behavior.

In C++0x, as of n3126, the ambiguity remains. For now, be safe: use the strict interpretation.

  • 5
    +1. Continuing the pedantry, under the "weak definition" the nonstatic member function hasn't been called "for an object that is not of type X". It has been called for an lvalue which is not an object at all. So the proposed solution adds the text "or if the lvalue is an empty lvalue" to the clause you quote. Mar 18, 2010 at 23:28
  • Could you clarify a little? In particular, with your "closed issue" and "active issue" links, what are the issue numbers? Also, if this is a closed issue, what exactly is the yes/no answer for static functions? I feel like I'm missing the final step in trying to understand your answer. Mar 18, 2010 at 23:30
  • 4
    I don't think CWG defect 315 is as "closed" as its presence on the "closed issues" page implies. The rationale says that it should be allowed because "*p is not an error when p is null unless the lvalue is converted to an rvalue." However, that relies on the concept of an "empty lvalue," which is part of the proposed resolution to CWG defect 232, but which has not been adopted. So, with the language in both C++03 and C++0x, dereferencing the null pointer is still undefined, even if there is no lvalue-to-rvalue conversion. Jun 8, 2010 at 3:42
  • 1
    @JamesMcNellis: By my understanding, if p were a hardware address which would trigger some action when read, but were not declared volatile, the statement *p; would not be required, but would be allowed, to actually read that address; the statement &(*p);, however, would be forbidden from doing so. If *p were volatile, the read would be required. In either case, if the pointer is invalid, I can't see how the first statement wouldn't be Undefined Behavior, but I also can't see why the second statement would be.
    – supercat
    Jan 22, 2014 at 0:20
  • 2
    ".E2 converts it to an rvalue, " - Uh, no it doesn't
    – M.M
    Jan 3, 2018 at 2:44

Obviously undefined means it's not defined, but sometimes it can be predictable. The information I'm about to provide should never be relied on for working code since it certainly isn't guaranteed, but it might come in useful when debugging.

You might think that calling a function on an object pointer will dereference the pointer and cause UB. In practice if the function isn't virtual, the compiler will have converted it to a plain function call passing the pointer as the first parameter this, bypassing the dereference and creating a time bomb for the called member function. If the member function doesn't reference any member variables or virtual functions, it might actually succeed without error. Remember that succeeding falls within the universe of "undefined"!

Microsoft's MFC function GetSafeHwnd actually relies on this behavior. I don't know what they were smoking.

If you're calling a virtual function, the pointer must be dereferenced to get to the vtable, and for sure you're going to get UB (probably a crash but remember that there are no guarantees).

  • 2
    GetSafeHwnd first does a !this check and if true, returns NULL. Then it begins a SEH frame and dereferences the pointer. if there is Memory Access Violation (0xc0000005) this is caught and NULL is returned to caller :) Else the HWND is returned. Oct 8, 2014 at 2:18
  • 2
    @ПетърПетров it's been quite a few years since I looked at the code for GetSafeHwnd, it's possible that they've enhanced it since then. And don't forget that they have insider knowledge on the compiler workings! Oct 8, 2014 at 2:44
  • I am stating a sample possible implementation that have the same effect, what does it really do is to be reverse-engineered using a debugger :) Oct 8, 2014 at 16:40
  • 1
    "they have insider knowledge on the compiler workings!" - the cause of eternal trouble for projects like MinGW that attempt to allow g++ to compile code that calls the Windows API
    – M.M
    Dec 10, 2015 at 11:15
  • 1
    @AnOccasionalCashew yes I'm aware, and it was irresponsible on my part to not bring it up. My favorite post on the subject is Undefined behavior can result in time travel (among other things, but time travel is the funkiest). Dec 10, 2020 at 4:22

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.