This is a spin off of the question How to check if object is const or not?.

I was surprised to see the following program

#include <iostream>
#include <type_traits>

int main() 
   std::cout << std::boolalpha;
   std::cout << std::is_const<const int&>::value << "\n";

produced this output


In what context does it make sense to think of const int& as a non-const type?

  • 9
    is_const<T> is defined as "T is const-qualified". References can't be cv-qualified, so it makes sense from a language perspective. – Mat Jun 4 '14 at 6:08
  • See also stackoverflow.com/questions/6217453/… – MSalters Jun 4 '14 at 6:44
  • @Mat, would you mind converting your comment to an answer? That seems to contain the best answer. – R Sahu Jun 12 '15 at 16:19

Perhaps it'll be easier to understand with this example

std::cout << std::is_const<int const *>::value << "\n";  // pointer to const int
std::cout << std::is_const<int * const>::value << "\n";  // const pointer to int



The first type is a pointer to a const int, while in the second the int * itself is const. Hence it results in true while the former is false. Similarly, what you have a reference to a const int. If int& const were valid it'd result in true.

  • Since a variable of type reference cannot be made to refer to another object after its initialization, it makes more sense for std::is_const<int&>::value as well as std::is_const<const int&>::value to evaluate to 'true` than false. – R Sahu Jun 4 '14 at 15:31
  • @RSahu I don't get why you think that. As I'm sure you understand, the const in int const& indicates the int cannot be modified. The purpose of is_const is to indicate whether T is const-qualified (quoted from In both cases you've listed T = int&; clearly T is not const. It would be counter-intuitive for it to return true in either case. – Praetorian Jun 4 '14 at 15:46
  • I understand that. Perhaps I am finding it hard to justify its specified behavior. It makes more sense to me to think of the const-ness of a reference variable to be the same as the const-ness of the type it references. – R Sahu Jun 4 '14 at 16:22
  • @RSahu I can see where you're coming from, but you'd agree that that sort of const because the other option is ill-formed behavior would only apply to reference types. It wouldn't even make sense for cases where T = U*. It'd be yet another special case everyone needs to remember. – Praetorian Jun 4 '14 at 17:22
  • Yes. I agree. It would apply only to reference types. Please understand that I am speaking from a language user's point of view. From a language developer's point of view, the behavior of is_const perhaps makes more sense. – R Sahu Jun 4 '14 at 17:33

A const qualifier on a reference just means that the value can't be modified via the reference. It can still be modified by other means. For example:

int a = 1;
const int &b = a;

std::cout << b << std::endl;  // Prints 1

a = 2;

std::cout << b << std::endl;  // Prints 2

Thus, you can't assume that the value of a const reference is actually constant.

  • 2
    Don't know why this attracted a downvote. It correctly states that the const here only applies to the type of expressions involving b. Neither a nor b are const themselves. (That said, Praetorian's answer is a lot clearer) – MSalters Jun 4 '14 at 6:43
  • 3
    This is true but nothing to do with the question – M.M Jun 4 '14 at 6:46

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