I was experimenting with functors, and unintentionally discovered something about decltype
that I found interesting: As far as I can tell, there's no way to use it to generate a function pointer to an overloaded function, or supply it with the information needed to resolve said overload when attempting to do so.
// Simple test code.
// Please ignore the possibility of attempting to dereference a nullptr function pointer,
// proper checking was omitted for brevity.
template<typename... Ts> struct Functor;
template<typename F, typename R, typename... Ts>
struct Functor<F, R(*)(Ts...)> {
Functor() : func(nullptr) { }
Functor(F f) : func(f) { }
R operator()(F f, Ts... ts) { return 2 * f(ts...); }
R operator()(Ts... ts) { return 2 * func(ts...); }
private:
F func;
};
template<typename F>
decltype(auto) functorReturner(F f = nullptr) {
return ((f) ? Functor<F, F>{f} : Functor<F, F>{});
}
int example(int a, int b, int c) {
return (8 * a) * ((b ^ c) - (c ^ b));
}
float example(float a, float b, float c) {
return (4.2 / a) * ((b + c) * (c - b));
}
// Wrappers to avoid overload when using decltype.
auto example_i(int a, int b, int c) { return example(a, b, c); }
auto example_f(float a, float b, float c) { return example(a, b, c); }
int main() {
// Valid:
// Automatic template deduction, no overloads.
std::cout << functorReturner(example_f)(1., 2.8, 0.6) << std::endl; // Outputs -62.832.
// Explicit template specification, no overloads.
std::cout << functorReturner<decltype(&example_f)>()(example_f, 1., 2.8, 0.6)
<< std::endl;
// Explicit template specification, determines correct overload.
std::cout << functorReturner<decltype(&example_f)>(example)(1., 2.8, 0.6)
<< std::endl;
// Explicit template specification, determines correct overload.
std::cout << functorReturner<decltype(&example_f)>()(example, 1., 2.8, 0.6)
<< std::endl;
// Invalid:
// Attempting to pass proper version of overloaded function to decltype, without using
// a non-overloaded function with an identical signature.
// Explicit template specification, could theoretically determine correct overload.
std::cout << functorReturner<decltype(&example(float, float, float))>(example)(1., 2.8, 0.6)
<< std::endl;
// Valid:
// Determine type from non-overloaded function.
decltype(example_f(1., 2.8, 0.6)) ex;
// Determine type from overloaded function, with arguments explicitly specified.
decltype(example(1.f, 2.8f, 0.6f)) ex2;
// Determine type from overloaded function, with Rvalues to aid in resolution.
decltype(example(float{}, float{}, float{})) ex3;
std::cout << typeid(ex).name() << " "
<< typeid(ex2).name() << " "
<< typeid(ex3).name()
<< std::endl;
// Output is:
// MSVC: "float float float"
// GCC: "f f f"
// Return type deduced correctly in all three examples, even when overload resolution
// is required.
// Valid:
// Determine function type via decltype.
// Automatically resolves overload, as only one version of example() is the same type
// as example_f():
// "float (*)(float, float, float)".
decltype(&example_f) exfp = example;
std::cout << (2 * example(1., 2.8, 0.6)) << std::endl;
// Invalid:
// Explicitly specify which version of overloaded function we mean.
decltype(&example(float, float, float)) exfp_inv = example;
// or...
decltype(&example(1.f, 2.8f, 0.6f) exfp_inv2 = example;
// or...
decltype(&example(float{}, float{}, float{})) exfp_inv3 = example;
}
Considering the above, my question is this: In the case of using decltype
to obtain the signature of an overloaded function, why can't the function parameters, or at least the types thereof, be specified to allow for overload resolution?
As per the standard, quoting cppreference:
1) If the argument is an unparenthesized id-expression or an unparenthesized class member access, then decltype yields the type of the entity named by this expression. If there is no such entity, or if the argument names a set of overloaded functions, the program is ill-formed.
I feel that in this case, where the argument names a set of overloaded functions, syntax that allows the programmer to specify parameter types would allow programs to be properly formed even when using decltype
with overloaded functions, and I'm honestly curious as to why it isn't allowed. I don't see it being of much use (it's easy enough to use templates to create a valid function pointer or to strip one down to determine the return and parameter types, which would account for overloads and allow mostly the same functionality as being able to use decltype
on overloaded functions directly; in situations where you can't easily determine said information, something was likely coded poorly, rendering the point moot), but with how easy it should be to implement, I'm surprised it wasn't.
A possible implementation:
// Currently legal syntax, which will be used as a basis.
decltype(example(1.f, 2.8f, 0.6f)) e;
// decltype properly deduces that we want the return type of
// "float example(float, float, float)".
// Possible implementation, based on the above.
decltype(&example(1.f, 2.8f, 0.6f)) ep;
// decltype is currently unable to deduce that we want a function pointer with a signature of
// "float example(float, float, float)".
// However, this syntax would allow it to deduce this if the standard allowed it.
...If there is a method to allow decltype
to correctly resolve overloads when creating a function pointer that I'm not aware of, I'd also be interested in learning about it, now that my curiosity is piqued. It just seems weird that it was omitted.
[My apologies if this is a duplicate. Most similar questions that I've seen appear to be on how to work around this, while mine is about the logic behind it.]
Edit: For clarification, the question is this: For any given overloaded function, why is decltype(function_name(appropriate_parameters))
able to successfully resolve the overload to the correct version of the function and evaluate to its return type, while decltype(&function_name(appropriate_parameters))
, or a similar syntax, is unable to successfully resolve the overload to the correct version of the function and evaluate to its signature? It seems inconsistent to me, especially since it would, in theory, be trivial to implement.
Using int example(int, int, int)
and float example(float, float, float)
as an example, if decltype(example(1.f, 2.8f, 0.6f))
is able to successfully resolve the overload to float example(float, float, float)
and evaluate to float
, why is decltype(&example(1.f, 2.8f, 0.6f))
unable to successfully resolve the overload to float example(float, float, float)
and evaluate to float (*)(float, float, float)
?
decltype()
on overloaded functions?