I’m new to writing template metaprogramming code (vs. just reading it). So I’m running afoul of some noob issues. One of which is pretty well summarized by this non-SO post called “What happened to my SFINAE?”, which I will C++11-ize as this:
(Note: I gave the methods different names only to help with my error diagnosis in this “thought experiment” example. See @R.MartinhoFernandes’s notes on why you wouldn’t actually choose this approach in practice for non-overloads.)
#include <type_traits>
using namespace std;
template <typename T>
struct Foo {
typename enable_if<is_pointer<T>::value, void>::type
valid_if_pointer(T) const { }
typename disable_if<is_pointer<T>::value, void>::type
valid_if_not_pointer(T) const { }
};
int main(int argc, char * argv[])
{
int someInt = 1020;
Foo<int*>().valid_if_pointer(&someInt);
Foo<int>().valid_if_not_pointer(304);
return 0;
}
@Alf says what happened to the SFINAE is “It wasn’t there in the first place”, and gives a suggestion that compiles, but templates the functions instead of the class. That might be right for some situations, but not all. (For instance: I’m specifically trying to write a container that can hold types that may or may not be copy-constructible, and I need to flip methods on and off based on that.)
As a workaround, I gave this a shot…which appears to work correctly.
#include <type_traits>
using namespace std;
template <typename T>
struct FooPointerBase {
void valid_if_pointer(T) const { }
};
template <typename T>
struct FooNonPointerBase {
void valid_if_not_pointer(T) const { }
};
template <typename T>
struct Foo : public conditional<
is_pointer<T>::value,
FooPointerBase<T>,
FooNonPointerBase<T> >::type {
};
int main(int argc, char * argv[])
{
int someInt = 1020;
#if DEMONSTRATE_ERROR_CASES
Foo<int*>().valid_if_not_pointer(&someInt);
Foo<int>().valid_if_pointer(304);
#else
Foo<int*>().valid_if_pointer(&someInt);
Foo<int>().valid_if_not_pointer(304);
#endif
return 0;
}
But if this is not broken (is it?), it’s certainly not following a good general methodology for how to turn on and off methods in a templated class based on sniffing the type for traits. Is there a better solution?
Firstly, C++11 did not carry forward boost’s
disable_if. So if you’re going to transition boost code, you’ll need to useenable_ifwith a negated condition (or redefine your owndisable_ifconstruct).Secondly, for SFINAE to reach in and apply to the method level, those methods must be templates themselves. Yet your tests have to be done against those templates’ parameters…so code like
enable_if<is_pointer<T>will not work. You can finesse this by making some template argument (let’s say X) default to be equal to T, and then throw in a static assertion that the caller has not explicitly specialized it to something else.This means that instead of writing:
…you would write:
Both are now templates and the
enable_ifuses the template parameter X, rather than T which is for the whole class. It’s specifically about the substitution that happens whilst creating the candidate set for overload resolution–in your initial version there’s no template substitution happening during the overload resolution.Note that the static assert is there to preserve the intent of the original problem, and prevent someone being able to compile things like: