Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Am I able to implement the following function in C++? I would like to keep the myInstance variable unspecified until the callback method is called, instead of containing it in a boost::bind instance.

MyClass *myInstance;

void call(/* boost::mem_fn */ callback)
{
    // Somewhere in this function, the operator()() method
    // is called on the callback instance

    callback(myInstance);
}

call(boost::mem_fn(&MyClass::myMethod));

I understand that boost::mem_fn is a function which returns a particular object, but I'm unsure of its type. The documentation says unspecified as its return type. One of the boost::bind constructors takes this type as a parameter, but I'm unable to find the actual declaration in its implementation. Also, am I even allowed to store my own instance of this particular type, or is this strictly for use by boost functions?

share|improve this question

3 Answers 3

up vote 4 down vote accepted

This is one of those cases where it seems that the compiler is doing some very magic stuff.

The reason there isn't really a well defined type is that the type returned from bosst::mem_fn is always assumed to be a template parameter of the function it's passed to. Let me show you an example:

std::for_each has a signature like this:

template <class InputIterator, class Function>
Function for_each (InputIterator first, InputIterator last, Function f);

This little slice of magic has two template parameters, an InputIterator and a Function. These could have been called anything, but the names given to them describe how they will be used, really, are more self-documenting names than a real type. The type of InputIterator may well be something like std::vector<foo>::iterator - the point is that the compiler will automatically resolve what an "InputIterator" is at compile time. It can figure this type out for you.

The same is true of Function. As long as you pass it something that can be called - that is, has a version of operator() that is compatible with what gets called in for_each, then you never need to know what Function is.

So the short answer is, make your call function take a template parameter:

template<typename SomeSortOfFunction>
void call(SomeSortOfFunction callback)

and then the compiler should resolve SomeSortOfFunction to be whatever the type is that is returned from boost::mem_fn

share|improve this answer
    
"This is one of those cases where it seems that the compiler is doing some very magic stuff." Indeed... Because of this, am I not allowed to store callback as a field in a class for later use without templating the class? How then, am I able to hold an instance of boost::bind without declaring its templated types? Thanks for your answer, Matt! –  Vortico Nov 8 '12 at 18:17

The return type of boost::mem_fn is unspecified. You should use either Matt's approach (i.e. pass it as a template), or if separate compilation is important to you, use type erasure:

MyClass *myInstance;

void call(boost::function<void(MyClass*)> callback)
{
    callback(myInstance);
}

call(boost::mem_fn(&MyClass::myMethod));
share|improve this answer

The return type of mem_fn is not something you should ever explicitly type or store. It is generated at compile time via the types of the arguments.

It can, however, be stored via std::function (or boost::function).

The operator() signature of men_fn is the original method arguments with a possibly const pointer to the class prepended, and the same return value type. Just create a std::function with that signature, and it can take the men_fn type and store it.

In short if you have a zero argument method for class foo that returns void try storing the men_fun in a std::function<void(foo *)>.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

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