#include <type_traits>

struct foo;
int main()
    const foo *bar;

                  "expected const but this is non-const!");

This results in a failing static_assert which is unexpected. This is somewhat similar to this question on const references but not quite the same.

In my case, dereferencing bar should give an instance of const foo as its type but yet std::is_const is saying otherwise.

  • 1
    const foo *bar makes a const pointer, but the value it points to is not const. – Aganju Feb 2 '17 at 7:33
  • 17
    @Aganju no it doesn't, that's foo *const bar; – greatwolf Feb 2 '17 at 7:34
  • 7
    const foo *bar same as foo const *bar But different from foo *const bar – O'Neil Feb 2 '17 at 7:38

Shortly that's because a reference or a pointer to a const type is not a const type.
Note that decltype(*bar) isn't const foo, it's const foo & and they are really different beasts.

Consider the example given here:

std::cout << std::is_const<const int *>::value << '\n'; // false
std::cout << std::is_const<int * const>::value << '\n'; // true

We see that std::is_const<const int *>::value is false and std::is_const<int * const>::value is true.
That's because in const int * the type is pointer to something const, that is not a const type as intended by is_const (and the standard actually). In int * const the const qualifier applies to the pointer type and not to the pointed one, thus the type is a const one, no matter to what it points.
Something similar applies for const foo &, that is a reference to something const.

You can solve using this instead:

static_assert(std::is_const<std::remove_reference_t<decltype(*bar)>>::value, "expected const but this is non-const!");

Or even this, for you don't need to do *bar actually:

static_assert(std::is_const<std::remove_pointer_t<decltype(bar)>>::value, "expected const but this is non-const!");

In this case, by removing the pointer/reference with remove_pointer_t/remove_reference_t your type becomes const foo, that is actually a const type.

As a side note, the example above uses the C++14-ish std::remove_reference_t and std::remove_pointer_t type traits.
You can easily turn those lines of code to C++11 as it follows:

static_assert(std::is_const<typename std::remove_pointer<decltype(bar)>:: type>::value, "expected const but this is non-const!");

It's worth mentioning a few comments to the answer to give more details:

  • Thanks to @DanielFischer for the question:

    Is there a short explanation why decltype(*bar) is const foo& rather than const foo?

    I'm not a language-lawyer, but I guess it can be deduced from [expr.unary.op]/1 (emphasis mine):

    The unary * operator performs indirection: the expression to which it is applied shall be a pointer to an object type, or a pointer to a function type and the result is an lvalue referring to the object or function to which the expression points.

    And [dcl.type.simple]/4.4 (emphasis mine):

    otherwise, if e is an lvalue, decltype(e) is T&, where T is the type of e;

    Both referring to the working draft.

  • Thanks to @LightnessRacesInOrbit for the comment. Note that decltype(*bar) being const foo & is a funny C++ quirk of decltype, since *bar is not const foo &.

  • 11
    Worth mentioning explicitly imo: decltype(*bar) isn't const foo it is const foo& – Ryan Haining Feb 2 '17 at 7:49
  • 1
    @RyanHaining that's good to know, that's the piece I was missing. – greatwolf Feb 2 '17 at 7:51
  • 1
    @RyanHaining Added to the first line. – skypjack Feb 2 '17 at 7:53
  • 2
    @RyanHaining Is there a short explanation why decltype(*bar) is const foo& rather than const foo? – Daniel Fischer Feb 2 '17 at 15:03
  • 2
    @skypjack: Yes, your quotes were correct. I just wanted to remind everyone in simple language that dereferencing a pointer doesn't produce a reference ;) – Lightness Races in Orbit Feb 2 '17 at 16:39

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