Why can't C++ infer the template type?

Question

Why can't the compiler figure out these template parameters? Is there a way to make it do so?

(I'm using Visual Studio 2010.)

template<typename T, typename TFunc>
void call(TFunc func) { func(T()); }

void myfunc(void *) { }

int main() { call(myfunc); }

Answer 1

T appears nowhere in the parameter list so T cannot be deduced from the function arguments. All types to be deduced must appear in deduced contexts in the parameter list. For example,

template <typename TReturn, typename TParameter>
void call(TReturn (*f)(TParameter))
{
    f(TParameter());
}

Answer 2

Template parameter deduction for function templates only works based on function arguments, nothing else. The function definition is never looked at for the purpose of determining the template parameters, so your parameter T cannot possibly be deduced.

You could remedy your situation by incorporating the type into the function signature: Since you expect the outer function to be called with a function itself, make that explicit:

template <typename T> void foo(void(*f)(T))
{
  T x;
  f(x);
  // ...
}

Answer 3

Combine function overloading with functors, and it becomes impossible in the general case to determine what arguments can be passed to a callable entity.

Consider, for example

struct FunctorExample {
    void operator()(int x) {...}
    std::string operator()(const std::string& ) {...}
};

If there were some way to coax the compiler to pattern match on arguments, it would have to have undefined or error behavior when applied to FunctorExample.

Instead, the trend seems to be that when you want to template metaprogram with functors, you specify the functor and argument list. Examples (off the top of my head) being boost::result_of and boost::fusion.

Edit: That said, if you're willing to restrict your attention somewhat, and you can use some C++11 syntax (decltype), you can arrange to introspect a bit more:

// Support functors with a very simple operator():
template <typename T> struct argument :
    public argument<decltype(&T::operator())> {};

// Pointers to member functions
template <typename C, typename R, typename A> struct argument<R(C::*)(A)>
    {typedef A type;};

// Function types
template <typename R, typename A> struct argument<R(A)> {typedef A type;};

// Function pointer types.
template <typename R, typename A> struct argument<R(*)(A)> {typedef A type;};

// Now for call:
template <typename FuncType>
void call(FuncType func) { 
    typedef typename argument<FuncType>::type Arg;
    func(Arg());
}

// example:
class FunctorInt {public: int operator()(int ) {return 0;};};
void myfunc(void *) {}

int main() {
    call(myfunc);
    call(FunctorInt());
}

Variadic templates could be used to expand this stuff to support more than one argument.