65

Yes, I've seen this question and this FAQ (wrong link) this FAQ, but I still don't understand what ->* and .* mean in C++.
Those pages provide information about the operators (such as overloading), but don't seem to explain well what they are.

What are ->* and .* in C++, and when do you need to use them as compared to -> and .?

  • 4
    I think this FAQ explains it fairly well. – Robᵩ Jul 5 '11 at 17:36
  • @Rob: I can't believe I posted the wrong link. X___X that's the one I meant to post, not MSDN! -- I've looked at it, but I didn't understand much from it. All they say is that "the type is different" but I found that kind of confusing... – user541686 Jul 5 '11 at 17:39
72
0

I hope this example will clear things for you

//we have a class
struct X
{
   void f() {}
   void g() {}
};

typedef void (X::*pointer)();
//ok, let's take a pointer and assign f to it.
pointer somePointer = &X::f;
//now I want to call somePointer. But for that, I need an object
X x;
//now I call the member function on x like this
(x.*somePointer)(); //will call x.f()
//now, suppose x is not an object but a pointer to object
X* px = new X;
//I want to call the memfun pointer on px. I use ->*
(px ->* somePointer)(); //will call px->f();

Now, you can't use x.somePointer(), or px->somePointer() because there is no such member in class X. For that the special member function pointer call syntax is used... just try a few examples yourself ,you'll get used to it

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  • 2
    Add the required extra braces to compensate for operator precedence. – Martin York Jul 5 '11 at 17:33
  • 2
    @Armen: Ohh I see what's happening now... I've never seen or needed something like that before. It's cool (+1), but I guess the question now is: How is pointer different from a normal function pointer that it requires a different syntax? (e.g. Is it bigger?) – user541686 Jul 5 '11 at 17:43
  • @Mehrdad: The point is that to call a normal function, you just provide the arguments. But in case of nonstatic member functions you also need an object on which you want to call the function. Hence the new syntax. – Armen Tsirunyan Jul 5 '11 at 17:45
  • 1
    A pointer-to-member-function may be bigger than a regular pointer-to-function: specifically to cope with inheritance iirc – Useless Jul 5 '11 at 18:05
  • Can anyone explain how the &X::f works? See this question. – user2141130 Jul 19 '13 at 22:41
20
0

EDIT: By the way, it gets weird for virtual member functions pointers.

For member variables:

struct Foo {
   int a;
   int b;
};


int main ()
{
    Foo foo;
    int (Foo :: * ptr);

    ptr = & Foo :: a;
    foo .*ptr = 123; // foo.a = 123;

    ptr = & Foo :: b;
    foo .*ptr = 234; // foo.b = 234;
}

Member functions are almost the same.

struct Foo {
   int a ();
   int b ();
};


int main ()
{
    Foo foo;
    int (Foo :: * ptr) ();

    ptr = & Foo :: a;
    (foo .*ptr) (); // foo.a ();

    ptr = & Foo :: b;
    (foo .*ptr) (); // foo.b ();
}
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  • 3
    +1 for showing that the syntax applies to all members, not just member functions. I find that pointers to member variables are very rarely used, though, despite their many rather interesting potential applications. – Jon Purdy Jul 5 '11 at 17:18
15
0

In a nutshell: You use -> and . if you know what member you want to access. And you use ->* and .* if you don't know what member you want to access.

Example with a simple intrusive list

template<typename ItemType>
struct List {
  List(ItemType *head, ItemType * ItemType::*nextMemPointer)
  :m_head(head), m_nextMemPointer(nextMemPointer) { }

  void addHead(ItemType *item) {
    (item ->* m_nextMemPointer) = m_head;
    m_head = item;
  }

private:
  ItemType *m_head;

  // this stores the member pointer denoting the 
  // "next" pointer of an item
  ItemType * ItemType::*m_nextMemPointer;
};
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  • 6
    +1 for the first sentence, though never in my life have I not known which member I want to access, haha. :) – user541686 Jul 5 '11 at 17:45
7
0

So called "pointers" to members in C++ are more like offsets, internally. You need both such a member "pointer", and an object, to reference the member in the object. But member "pointers" are used with pointer syntax, hence the name.

There are two ways you can have an object at hand: you have a reference to the object, or you have a pointer to the object.

For the reference, use .* to combine it with a member pointer, and for the pointer, use ->* to combine it with a member pointer.

However, as a rule, don't use member pointers if you can avoid it.

They obey pretty counter-intuitive rules, and they make it possible to circumvent protected access without any explicit casting, that is, inadvertently…

Cheers & hth.,

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  • +1 for explaining it well without code. :) Question: Why can't we just take the address of the function like that of a normal function? Is the pointer to a member function different from a pointer to some other function? (e.g. is it bigger?) – user541686 Jul 5 '11 at 17:44
  • 1
    @Mehrdad: If you could have a pointer to member function that was restricted to non-virtual member functions, then it could indeed just be the address. However, the virtual-ness or not is not part of the member function pointer type. And so its representation needs to include some information about whether the current value refers to a virtual function or not, and if virtual, for a vtable-based implementation information that determines an offset in the vtable of the class the pointer type is associated with. – Cheers and hth. - Alf Oct 21 '14 at 17:51
5
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You cannot dereference pointer to members as normal pointers — because member functions require this pointer, and you have to pass it somehow. So, you need to use these two operators, with object on one side, and pointer on another, e.g. (object.*ptr)().

Consider using function and bind (std:: or boost::, depending on whether you write C++03 or 0x) instead of those, though.

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  • I think this may be the best explanation here. – Marcin Jul 5 '11 at 18:57
5
0

When you have a normal pointer (to an object or a basic type), you would use * to dereference it:

int a;
int* b = a;
*b = 5;     // we use *b to dereference b, to access the thing it points to

Conceptually, we're doing the same thing with a member function pointer:

class SomeClass
{
   public:  void func() {}
};

// typedefs make function pointers much easier.
// this is a pointer to a member function of SomeClass, which takes no parameters and returns void
typedef void (SomeClass::*memfunc)();

memfunc myPointer = &SomeClass::func;

SomeClass foo;

// to call func(), we could do:
foo.func();

// to call func() using our pointer, we need to dereference the pointer:
foo.*myPointer();
// this is conceptually just:    foo  .  *myPointer  ();


// likewise with a pointer to the object itself:
SomeClass* p = new SomeClass;

// normal call func()
p->func();

// calling func() by dereferencing our pointer:
p->*myPointer();
// this is conceptually just:    p  ->  *myPointer  ();

I hope that helps explain the concept. We're effectively dereferencing our pointer to the member function. It's a little more complicated than that -- it's not an absolute pointer to a function in memory, but just an offset, which is applied to foo or p above. But conceptually, we're dereferencing it, much like we would dereference a normal object pointer.

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