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Given the following code, what is the reason behind the ambiguity? Can I circumvent it or will I have to keep the (annoying) explicit casts?

#include <functional>

using namespace std;

int a(const function<int ()>& f)
{
    return f();
}

int a(const function<int (int)>& f)
{
    return f(0);
}

int x() { return 22; }

int y(int) { return 44; }

int main()
{
    a(x);  // Call is ambiguous.
    a(y);  // Call is ambiguous.

    a((function<int ()>)x);    // Works.
    a((function<int (int)>)y); // Works.

    return 0;
}

Interestingly, if I comment out the a() function with the function<int ()> parameter and call a(x) in my main, the compilation correctly fails because of the type mismatch between x and the argument function<int (int)> of the only a() function available. If the compiler fails in that case, why would there be any ambiguity when the two a() functions are present?

I've tried with VS2010 and g++ v. 4.5. Both give me the exact same ambiguity.

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Added an edit on solutions to your problem. :) –  Xeo May 15 '11 at 13:49

4 Answers 4

up vote 31 down vote accepted

The problem is that both function<int()> and function<int(int)> are constructible from the same function. This is what the constructor declaration of std::function looks like in VS2010:

template<class _Fx>
function(_Fx _Func, typename _Not_integral<!_Is_integral<_Fx>::value, int>::_Type = 0);

Ignoring the SFINAE part, it is constructible from pretty much anything.
std::/boost::function employ a technique called type erasure, to allow arbitary objects/functions to be passed in, so long they satisfy the signature when being called. One drawback from that is, that you get an error in the deepest part of the implementation (where the saved function is being called) when supplying an object which can't be called like the signature wants it to, instead of in the constructor.


The problem can be illustrated with this little class:

template<class Signature>
class myfunc{
public:
    template<class Func>
    myfunc(Func a_func){
        // ...
    }
};

Now, when the compiler searches for valid functions for the overload set, it tries to convert the arguments if no perfect fitting function exists. The conversion can happen through the constructor of the parameter of the function, or through a conversion operator of the argument given to the function. In our case, it's the former.
The compiler tries the first overload of a. To make it viable, it needs to make a conversion. To convert a int(*)() to a myfunc<int()>, it tries the constructor of myfunc. Being a template that takes anything, the conversion naturally succeeds.
Now it tries the same with the second overload. The constructor still being the same and still taking anything given to it, the conversion works too.
Being left with 2 functions in the overload set, the compiler is a sad panda and doesn't know what to do, so it simply says the call is ambigious.


So in the end, the Signature part of the template does belong to the type when making declarations/definitions, but doesn't when you want to construct an object.


Edit:
With all my attention on answering the title-question, I totally forgot about your second question. :(

Can I circumvent it or will I have to keep the (annoying) explicit casts?

Afaik, you have 3 options.

  • Keep the cast
  • Make a function object of the appropriate type and pass that

    function<int()> fx = x; function<int(int)> fy = y; a(fx); a(fy);

  • Hide the tedious casting in a function and use TMP to get the right signature

The TMP (template metaprogramming) version is quite verbose and with boilerplate code, but it hides the casting from the client. An example version can be found here, which relies on the get_signature metafunction that is partially specialized on function pointer types (and provides a nice example how pattern matching can work in C++):

template<class F>
struct get_signature;

template<class R>
struct get_signature<R(*)()>{
  typedef R type();
};

template<class R, class A1>
struct get_signature<R(*)(A1)>{
  typedef R type(A1);
};

Of course, this needs to be extended for the number of arguments you want to support, but that is done once and then buried in a "get_signature.h" header. :)

Another option I consider but immediatly discarded was SFINAE, which would introduce even more boilerplate code than the TMP version.

So, yeah, that are the options that I know of. Hope one of them works for you. :)

share|improve this answer
2  
This is why I hate C++. –  nightcracker Jan 16 '12 at 21:48
5  
@nightcracker: Err... you hate C++ because it's so powerful? :x –  Xeo Jan 16 '12 at 21:52
1  
No, I hate C++ because of the shitload of boilerplate and hacks like SFINEA. The way C++ implements OOP in a statically typed language is such a productivity drain. Now I'll be honest with you, I don't grok C++ like I do Python, and ofcourse most things take longer to make in a statically typed, compiled language, but C++ is just pushing it. I mean, just look at the Boost source code... </endrant> ;) –  nightcracker Jan 17 '12 at 13:31
8  
@nightcracker: has it occurred to you that your problem might be the assumption that C++ is an OOP language? I fail to see how you can criticize C++ for being too verbose when you ask it to do something that isn't possible at all in other languages. If other languages allowed you to use SFINAE, then sure, you could argue that C++'s version of it was too verbose. –  jalf Jan 17 '12 at 14:00
4  
@nightcracker: TBH, I know no other way to criticize C++, but I nevertheless hate the way you do it. –  sbi Jan 17 '12 at 14:27

I've seen this question come up one too many times. libc++ now compiles this code without ambiguity (as a conforming extension).

share|improve this answer
    
Nice, SFINAE'd I take? (Can't seem to find the <functional> head in the SVN repo on-site.) –  Xeo Jun 1 '11 at 0:57
    
Yes, with SFINAE (the world's most unpronounceable acronym). Here's <functional>: llvm.org/svn/llvm-project/libcxx/trunk/include/functional –  Howard Hinnant Jun 1 '11 at 2:38
    
I like the way Stephan Lavavej pronounces it. :) "esfiney". Also, SBRM. ;) –  Xeo Jun 1 '11 at 2:40
    
Wow, I took a look at (the deeply hidden) __invokable SFINAE construct in <type_traits> .. just how the hell does the __invoke part of it work? I can understand the version under // bullet 5, for functors and free / static functions. The other seem to be for member functions, but how does that meta function differentiate between the 5 versions? Especially, how does it choose between 1 & 2 and 3 & 4 respectively, as they look exactly the same too me w.r.t. the signature. –  Xeo Jun 1 '11 at 3:15
    
Quite honestly, I'm not sure how this works. I was pretty amazed when my code evolved into this and was still passing my tests. The code started out a lot more complicated. This is a brand new language and I have yet to master it. My limited understanding is that the trailing return type is the SFINAE trigger. If that expression is valid, you've got an overload, else you don't. I'm hoping this is valid C++11, and that I'm not accidentally taking advantage of a clang bug or extension. –  Howard Hinnant Jun 1 '11 at 12:23

Here's an example of how to wrap std::function in a class that checks invokability of its constructor parameters:

template<typename> struct check_function;
template<typename R, typename... Args>
struct check_function<R(Args...)>: public std::function<R(Args...)> {
    template<typename T,
        class = typename std::enable_if<
            std::is_same<R, void>::value
            || std::is_convertible<
                decltype(std::declval<T>()(std::declval<Args>()...)),
                R>::value>::type>
        check_function(T &&t): std::function<R(Args...)>(std::forward<T>(t)) { }
};

Use like this:

int a(check_function<int ()> f) { return f(); }
int a(check_function<int (int)> f) { return f(0); }

int x() { return 22; }
int y(int) { return 44; }

int main() {
    a(x);
    a(y);
}

Note that this isn't quite the same as overloading on function signature, as it treats convertible argument (and return) types as equivalent. For exact overloading, this should work:

template<typename> struct check_function_exact;
template<typename R, typename... Args>
struct check_function_exact<R(Args...)>: public std::function<R(Args...)> {
    template<typename T,
        class = typename std::enable_if<
            std::is_convertible<T, R(*)(Args...)>::value>::type>
        check_function_exact(T &&t): std::function<R(Args...)>(std::forward<T>(t)) { }
};
share|improve this answer
    
Note that your t is not a universal reference, therefore std::forward will always move it. –  Xeo Aug 21 '12 at 12:21
    
@Xeo oops. Fixed, thanks. –  ecatmur Aug 21 '12 at 12:39
    
And I'd use is_convertible instead of is_same, then you don't need the remove_cv. You should also account for void(Args...), which just swallows the returned value. –  Xeo Aug 21 '12 at 12:41
    
@Xeo thanks, that's more consistent. As far as I can tell my code works fine with void return, though. –  ecatmur Aug 21 '12 at 13:05
2  
If decltype(std::declval<T>()(std::declval<Args>()...)) evaluates to something other than void and R is void, std::convertible<not_void, void>::value will yield false, though std::function allows that to swallow the return value. –  Xeo Aug 21 '12 at 13:25

std::function<T> has a conversion ctor that takes an arbitrary type (i.e., something other than a T). Sure, in this case, that ctor would result in a type mismatch error, but the compiler doesn't get that far -- the call is ambiguous simply because the ctor exists.

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1  
The constructor doesn't result in a type mismatch error, it's in the operator() where it happens (okay, not directly, but in a subroutine). Try constructing a std::function with any function that doesn't satisfy the signature, you'll see where the error message leads you. –  Xeo May 9 '11 at 0:47

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