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In Bjarne Stroustrup's home page (C++0x FAQ):

struct X { int foo(int); };

std::function<int(X*, int)> f;
f = &X::foo; //pointer to member

X x;
int v = f(&x, 5); //call X::foo() for x with 5

How does it work? How does std::function call a foo member function?

The template parameter is int(X*, int), is &X::foo converted from the member function pointer to a non-member function pointer?!

(int(*)(X*, int))&X::foo //casting (int(X::*)(int) to (int(*)(X*, int))

To clarify: I know that we don't need to cast any pointer to use std::function, but I don't know how the internals of std::function handle this incompatibility between a member function pointer and a non-member function pointer. I don't know how the standard allows us to implement something like std::function!

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1  
If you are referring to another web page. Please always provide the link. –  Loki Astari Aug 20 '10 at 20:59
1  
The page is here: www2.research.att.com/~bs/C++0xFAQ.html#std-function . Bjarne asserts that this is legal, but doesn't mention the mechanics of how it works (whether its clever templating, or some sort of new built-in conversion). –  Tyler McHenry Aug 20 '10 at 21:15

4 Answers 4

up vote 21 down vote accepted

Thanks for all answers.

I found a good example from section 14.8.2.5-21 of the standard:

template<class> struct X { };
template<class R, class ... ArgTypes> struct X<R(int, ArgTypes ...)> { };
template<class ... Types> struct Y { };
template<class T, class ... Types> struct Y<T, Types& ...> { };
template<class ... Types> int f(void (*)(Types ...));
void g(int, float);
// uses primary template
X<int> x1;
// uses partial specialization; ArgTypes contains float, double
X<int(int, float, double)> x2;
// uses primary template
X<int(float, int)> x3;
// use primary template; Types is empty
Y<> y1;
// uses partial specialization; T is int&, Types contains float, double
Y<int&, float&, double&> y2;
// uses primary template; Types contains int, float, double
Y<int, float, double> y3;
// OK; Types contains int, float
int fv = f(g);

It says that with template specialization, we can parse template parameters of a function type (awesome)! The following is a dirty/simple example about how std::function can work:

template<class T> struct Function { };

template<class T, class Obj, class... Args>
struct Function<T(Obj*, Args...)> // Parsing the function type
{
    enum FuncType
    {
        FuncTypeFunc,
        FuncTypeMemFunc
    };
    union FuncPtr
    {
        T(*func)(Obj*, Args...);
        T(Obj::*mem_func)(Args...);
    };

    FuncType m_flag;
    FuncPtr m_func_ptr;

    Function(T(*func)(Obj*, Args...)) // void(*)(Funny*, int, int)
    {
        m_flag = FuncTypeFunc;
        m_func_ptr.func = func;
    }
    Function(T(Obj::*mem_func)(Args...)) // void(Funny::*)(int, int)
    {
        m_flag = FuncTypeMemFunc;
        m_func_ptr.mem_func = mem_func;
    }

    void play(Obj* obj, Args... args)
    {
        switch(m_flag)
        {
          case FuncTypeFunc:
            (*m_func_ptr.func)(obj, args...);
            break;
          case FuncTypeMemFunc:
            (obj->*m_func_ptr.mem_func)(args...);
            break;
        }
    }
};

Usage:

#include <iostream>

struct Funny
{
    void done(int i, int j)
    {
        std::cout << "Member Function: " << i << ", " << j << std::endl;
    }
};

void done(Funny* funny, int i, int j)
{
    std::cout << "Function: " << i << ", " << j << std::endl;
}

int main(int argc, char** argv)
{
    Funny funny;
    Function<void(Funny*, int, int)> f = &Funny::done; // void(Funny::*)(int, int)
    Function<void(Funny*, int, int)> g = &done; // void(*)(Funny*, int, int)
    f.play(&funny, 5, 10); // void(Funny::*)(int, int)
    g.play(&funny, 5, 10); // void(*)(Funny*, int, int)
    return 0;
}

Edit: Thanks to Tomek for his good hint about unions, the above example is changed to hold the member/non-member function pointer in one (not two) variable.


Edit: Martin York is right, the switch statement wasn't a good idea in the above example, so i changed the example completely to work better, the following isn't dirty anymore :-)

template<class T> class Function { };

template<class Res, class Obj, class... ArgTypes>
class Function<Res (Obj*, ArgTypes...)> // Parsing the function type
{
    union Pointers // An union to hold different kind of pointers
    {
        Res (*func)(Obj*, ArgTypes...); // void (*)(Funny*, int)
        Res (Obj::*mem_func)(ArgTypes...); // void (Funny::*)(int)
    };
    typedef Res Callback(Pointers&, Obj&, ArgTypes...);

    Pointers ptrs;
    Callback* callback;

    static Res call_func(Pointers& ptrs, Obj& obj, ArgTypes... args)
    {
        return (*ptrs.func)(&obj, args...); // void (*)(Funny*, int)
    }
    static Res call_mem_func(Pointers& ptrs, Obj& obj, ArgTypes... args)
    {
        return (obj.*(ptrs.mem_func))(args...); // void (Funny::*)(int)
    }

  public:

    Function() : callback(0) { }
    Function(Res (*func)(Obj*, ArgTypes...)) // void (*)(Funny*, int)
    {
        ptrs.func = func;
        callback = &call_func;
    }
    Function(Res (Obj::*mem_func)(ArgTypes...)) // void (Funny::*)(int)
    {
        ptrs.mem_func = mem_func;
        callback = &call_mem_func;
    }
    Function(const Function& function)
    {
        ptrs = function.ptrs;
        callback = function.callback;
    }
    Function& operator=(const Function& function)
    {
        ptrs = function.ptrs;
        callback = function.callback;
        return *this;
    }
    Res operator()(Obj& obj, ArgTypes... args)
    {
        if(callback == 0) throw 0; // throw an exception
        return (*callback)(ptrs, obj, args...);
    }
};

Usage:

#include <iostream>

struct Funny
{
    void print(int i)
    {
        std::cout << "void (Funny::*)(int): " << i << std::endl;
    }
};

void print(Funny* funny, int i)
{
    std::cout << "void (*)(Funny*, int): " << i << std::endl;
}

int main(int argc, char** argv)
{
    Funny funny;
    Function<void(Funny*, int)> wmw;

    wmw = &Funny::print; // void (Funny::*)(int)
    wmw(funny, 10); // void (Funny::*)(int)

    wmw = &print; // void (*)(Funny*, int)
    wmw(funny, 8); // void (*)(Funny*, int)

    return 0;
}
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2  
One would hate to think there was a switch statement buried inside this code. –  Loki Astari Aug 21 '10 at 15:13
    
@Martin York: Thanks, i changed it. –  ccSadegh Aug 21 '10 at 23:53
2  
std::function also accepts function objects, in addition to function pointers and member function pointers –  user102008 Sep 27 '11 at 20:46

How it does it (I believe) is left undefined (but I don't have a copy of the standard here).

But given all the different possibilities that need to be covered I have the feeling that deciphering the exact definition of how it works would be really hard: So I am not going to try.

But I think you would like to know how functors work and they are relatively simple. So here is a quick example.

Functors:

These are objects that act like functions.
They are very useful in template code as they often allow you to use objects or functions interchangeably. The great thing about functors though is that they can hold state (a sort of poor man's closure).

struct X
{
     int operator()(int x) { return doStuff(x+1);}
     int doStuff(int x)    { return x+1;}
};

X   x;  // You can now use x like a function
int  a = x(5);

You can use the fact that functor hold state to hold things like parameters or the objects or the pointer to member methods (or any combination thereof).

struct Y // Hold a member function pointer
{
    int (X::*member)(int x);
    int operator(X* obj, int param) { return (obj->*member)(param);}
};
X  x;
Y  y;
y.member = &X::doStuff;
int a = y(&x,5);

Or even go further and bind parameters. So now all you need to provide is one of the parameters.

struct Z
{
    int (X::*member)(int x);
    int  param;
    Z(int (X::*m)(int), int p) : member(m), param(p) {}

    int operator()(X* obj)  { return (obj->*member)(param);}
    int operator()(X& obj)  { return (obj.*member)(param);}
};

Z z(&X::doStuff,5);

X x;
int a = z(x);
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Thanks for the info, although i know what a functor (function object) is, and i tried to know : "How the std::function holds/calls a member/non-member function pointer?" and i couldn't. –  ccSadegh Aug 20 '10 at 21:41
    
It probably uses a whole host of template specializations. But holding a function pointer is no different to holding a method pointer it is just the types that are different. –  Loki Astari Aug 20 '10 at 21:45

They're not function pointers. That's what std::function exists for. It wraps whatever callable types you give it. You should check out boost::bind- it's often used to make member function pointers callable as (this, args).

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4  
His question is still valid, though. The std::function instantiation is parametrized with int (X*, int), which is not the same type as the type of &X::foo, which is assigned to it. Although it's clear how you could invoke the latter given the arguments to the former, from the compiler's perspective, these types are not inherently related, so it's not obvious how this is allowed. –  Tyler McHenry Aug 20 '10 at 21:13
    
boost::bind not good enough? –  Puppy Aug 20 '10 at 21:31

g++ seems to have an union which may keep either function pointer, member pointer or void pointer which probably points to a functor. Add overloads which appropriately flag which union member is valid and heavy casting to a soup and then it works...

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Thanks, i believe that casting member function pointer to non-member function pointer is left undefined behavior! and by using an union, no cast is needed. i should test it. but how the members of this union is detectable by only one template parameter (we just specify one function type for std::function)? –  ccSadegh Aug 20 '10 at 21:54
    
"void pointer which probably pointer which probably points to a functor" then it would also need to somehow memory-manage this functor? –  user102008 Sep 27 '11 at 20:48

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