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my problem is a simple one. I have a class template that holds a pointer to a dynamically allocated type. I want to overload the indirection operator so that referring to the class template instance with the -> operator I get redirected as if I use the pointer contained within directly.

template<class T>
class MyClass
 {
  T *ptr;
  ...
  // created dynamic resource for ptr in the constructor
 };

Create myclass of some type:

MyClass<SomeObject> instance;

So what I want is instead of having to type:

instance.ptr->someMemberMethod();

I simply type:

intance->someMemberMethod();

Even thou instance is not a pointer it behaves as if it is the pointer instance contains. How to bridge that gap by overloading the operator?

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Modern C++ Design (Andrei Alexandrescu) has some really good info on the subject if you would like more depth. – Tom Kerr Jan 12 at 19:25
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3 Answers

up vote 6 down vote accepted

You can just overload operator-> and operator*:

template<class T>
class MyClass
{
    T* ptr;

public:
    T* operator->() {
        return ptr;
    }

    // const version, returns a pointer-to-const instead of just a pointer to
    // enforce the idea of the logical constness of this object 
    const T* operator->() const {
        return ptr;
    }

    T& operator*() {
        return *ptr;
    }

    // const version, returns a const reference instead of just a reference
    // to enforce the idea of the logical constness of this object
    const T& operator*() const {
        return *ptr;
    }
};

Note that, due to a design decision by the creator of the language, you can't overload the . operator.

Also, you might think that operator* would overload the multiplication operator instead of the dereference operator. However, this is not the case, because the multiplication operator takes a single argument (while the dereference operator takes no arguments), and because of this, the compiler can tell which one is which.

Finally, note that operator-> returns a pointer but operator* returns a reference. It's easy to accidentally confuse them.

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up vote 4 down vote

Overload the -> operator:

template <typename T> class MyClass
{
    T * p;
public:
    T       * operator->()       { return p; }  // #1
    T const * operator->() const { return p; }
};

Note that both overloads don't mutate the object; nonetheless we decide to make #1 non-const, so that we bequeath constness of the object onto the pointee. This is sometimes called "deep constness propagation" or something of this sort. The language D takes this much further.

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"we decide to make #1 non-const" -- at least, we can if we want to. Standard smart pointers don't, essentially for the same reason that it's possible to modify an object of type T via a T *const. Which you do depends whether instance is "logically" an indirect reference to the other object (in which case imitate standard smart pointers) or not (in which case curse Bjarne that you can't overload operator.). – Steve Jessop Jan 12 at 19:36
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@SteveJessop: "We" as in "you and I, on this journey into C++", rather than "we the extant rulers of all opinion", I suppose. Sorry, old habits :-) – Kerrek SB Jan 12 at 19:38
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up vote 2 down vote

The member access operator can be overloaded to return a pointer to the object to be accessed:

T * operator->() {return ptr;}
T const * operator->() const {return ptr;}

You might also want the deference operator, to make it feel even more like a pointer; this returns a reference instead:

T & operator*() {return *ptr;}
T const & operator*() const {return *ptr;}
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