For a parametric class C, I want to get always the "primitive" type irrespective of pointer, const or reference modifiers.

template<typename __T>
class C
    typedef std::some_magic_remove_all<__T>::type T;

int main()
    C<some_type>::type a;

For example, for some_type equal to:

  • int&
  • int**
  • int*&
  • int const &&
  • int const * const
  • and so on

I want a is always of type int. How can I achieve it?

  • Look at how the standard library implements remove_reference, remove_pointer, etc (partial specialization) and simply do the same for all the things you want to strip, making sure it is recursive (remove_all_extents should be a recursion example). – Marc Glisse Jan 25 '13 at 13:16
  • @vonbrand Because I want to force C is always instantiated with a plain type, without modifiers, and my class use then a pointer to this "plain type". Other approach is to make use of conditions or static_assert, but perhaps removing all modifiers and adding textual preconditions is a more comfortable approach. – Peregring-lk Jan 25 '13 at 13:20
  • 1
    int const & const is invalid. :) – GManNickG Jan 26 '13 at 0:05
template<class T> struct remove_all { typedef T type; };
template<class T> struct remove_all<T*> : remove_all<T> {};
template<class T> struct remove_all<T&> : remove_all<T> {};
template<class T> struct remove_all<T&&> : remove_all<T> {};
template<class T> struct remove_all<T const> : remove_all<T> {};
template<class T> struct remove_all<T volatile> : remove_all<T> {};
template<class T> struct remove_all<T const volatile> : remove_all<T> {};
//template<class T> struct remove_all<T[]> : remove_all<T> {};
//template<class T, int n> struct remove_all<T[n]> : remove_all<T> {};

I originally also stripped extents (arrays), but Johannes noticed that this causes ambiguities for const char[], and the question doesn't mention them. If we also want to strip arrays (see also ideas mentioned in the comments), the following doesn't complicate things too much:

#include <type_traits>
template<class U, class T = typename std::remove_cv<U>::type>
struct remove_all { typedef T type; };
template<class U, class T> struct remove_all<U,T*> : remove_all<T> {};
template<class U, class T> struct remove_all<U,T&> : remove_all<T> {};
template<class U, class T> struct remove_all<U,T&&> : remove_all<T> {};
template<class U, class T> struct remove_all<U,T[]> : remove_all<T> {};
template<class U, class T, int n> struct remove_all<U,T[n]> : remove_all<T> {};

or with a helper class but a single template parameter:

#include <type_traits>
template<class T> struct remove_all_impl { typedef T type; };
template<class T> using remove_all =
  remove_all_impl<typename std::remove_cv<T>::type>;
template<class T> struct remove_all_impl<T*> : remove_all<T> {};
template<class T> struct remove_all_impl<T&> : remove_all<T> {};
template<class T> struct remove_all_impl<T&&> : remove_all<T> {};
template<class T> struct remove_all_impl<T[]> : remove_all<T> {};
template<class T, int n> struct remove_all_impl<T[n]> : remove_all<T> {};

It is normal if all the variants start looking about the same ;-)

  • Is it neccesary the line T const volatile? Recursion should also works fine here. – Peregring-lk Jan 25 '13 at 13:27
  • 1
    Try removing it... (yes, it is, otherwise it is ambiguous for a type that is both const and volatile) – Marc Glisse Jan 25 '13 at 13:29
  • @AndyT yes, I answered the question exactly as asked, but I agree with vonbrand that needing to do such a thing is suspicious. – Marc Glisse Jan 25 '13 at 13:53
  • 2
    Bad news. char const[] matches both <T[]> and <T const>. – Johannes Schaub - litb Jan 25 '13 at 22:47
  • Ah, thanks for the warning, I had missed that issue. Writing all 11 combinations of const, volatile and [] or [n] looks painful. I could use mutually recursive templates where one strips const and a different one strips [] to avoid that, but again that's not so nice. – Marc Glisse Jan 25 '13 at 23:18

If you want to use the standard library more, you can do:

#include <type_traits>
template<class T, class U=
  typename std::remove_cv<
  typename std::remove_pointer<
  typename std::remove_reference<
  typename std::remove_extent<
  > struct remove_all : remove_all<U> {};
template<class T> struct remove_all<T, T> { typedef T type; };

which removes stuff until that doesn't change the type anymore. With a more recent standard, this can be shortened to

template<class T, class U=
  T >>>>
  struct remove_all : remove_all<U> {};
template<class T> struct remove_all<T, T> { typedef T type; };
template<class T> using remove_all_t = typename remove_all<T>::type;

Also you can use the remove_cvref_t function, it has been available since c++20

#include <iostream>
#include <type_traits>

int main()
    std::cout << std::boolalpha
              << std::is_same_v<std::remove_cvref_t<int>, int> << '\n'
              << std::is_same_v<std::remove_cvref_t<int&>, int> << '\n'
              << std::is_same_v<std::remove_cvref_t<int&&>, int> << '\n'
              << std::is_same_v<std::remove_cvref_t<const int&>, int> << '\n'
              << std::is_same_v<std::remove_cvref_t<const int[2]>, int[2]> << '\n'
              << std::is_same_v<std::remove_cvref_t<const int(&)[2]>, int[2]> << '\n'
              << std::is_same_v<std::remove_cvref_t<int(int)>, int(int)> << '\n';

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