Writing a really generic solution for this is hard. The problem with checking an arbitrary type T
against std::vector
or std::array
is that the latter are not classes, they are class templates. Even worse, std::array
is a class template with a non-type template parameter, so you can't even have a parameter pack which will hold both std::vector
and std::array
.
You can get around this somewhat by explicitly wrapping non-type parameters up in types, but it gets ugly, fast.
Here is a solution I came up with that will support any class or template class with no non-type template parameters by default. Template classes with non-type template parameters can be supported by adding a wrapper type to map non-type parameters to type parameters.
namespace detail{
//checks if two types are instantiations of the same class template
template<typename T, typename U> struct same_template_as: std::false_type {};
template<template<typename...> class X, typename... Y, typename... Z>
struct same_template_as<X<Y...>, X<Z...>> : std::true_type {};
//this will be used to wrap template classes with non-type args
template <typename T>
struct wrapImpl { using type = T; };
//a wrapper for std::array
template <typename T, typename N> struct ArrayWrapper;
template <typename T, std::size_t N>
struct ArrayWrapper<T, std::integral_constant<std::size_t, N>> {
using type = std::array<T,N>;
};
//maps std::array to the ArrayWrapper
template <typename T, std::size_t N>
struct wrapImpl<std::array<T,N>> {
using type = ArrayWrapper<T,std::integral_constant<std::size_t,N>>;
};
template <typename T>
using wrap = typename wrapImpl<typename std::decay<T>::type>::type;
//checks if a type is the same is one of the types in TList,
//or is an instantiation of the same template as a type in TempTList
//default case for when this is false
template <typename T, typename TList, typename TempTList>
struct one_of {
using type = std::false_type;
};
//still types in the first list to check, but the first one doesn't match
template <typename T, typename First, typename... Ts, typename TempTList>
struct one_of<T, std::tuple<First, Ts...>, TempTList> {
using type = typename one_of<T, std::tuple<Ts...>, TempTList>::type;
};
//type matches one in first list, return true
template <typename T, typename... Ts, typename TempTList>
struct one_of<T, std::tuple<T, Ts...>, TempTList> {
using type = std::true_type;
};
//first list finished, check second list
template <typename T, typename FirstTemp, typename... TempTs>
struct one_of<T, std::tuple<>, std::tuple<FirstTemp, TempTs...>> {
//check if T is an instantiation of the same template as first in the list
using type =
typename std::conditional<same_template_as<wrap<FirstTemp>, T>::value,
std::true_type,
typename one_of<T, std::tuple<>, std::tuple<TempTs...>>::type>::type;
};
}
//top level usage
template <typename T, typename... Ts>
using one_of = typename detail::one_of<detail::wrap<T>,Ts...>::type;
struct Foo{};
struct Bar{};
template <class Type>
auto operator<< (std::ostream& stream, const Type subject)
//is Type one of Foo or Bar, or an instantiation of std::vector or std::array
-> typename std::enable_if<
? one_of<Type, std::tuple<Foo,Bar>, std::tuple<std::vector<int>,std::array<int,0>>
>::value, std::ostream&>::type
{
stream << "whatever, derived from subject
";
return stream;
}
Please don't use this, it's horrible.
Live Demo