Consider the following code:

#include <iostream>

constexpr int fun(int const&) { return 5; }
struct T { int x; };

int main() {
  std::cout << fun(T::x) << std::endl;                   // Line A
  std::cout << requires { fun(T::x); } << std::endl;     // Line B

If I only comment Line B, then the code cannot be compiled (as expected, since x is not static in T). But when I only comment Line A, the code compiles just fine with both Clang 11.0.0 and GCC 10.2.0 (both output 1). What it is that I am missing about requires? shouldn't it return false?

  • Any particular reason you're using fun in the example? Seems unnecessary to me. – cigien Nov 12 '20 at 5:45
  • What is the alternative? T::x is valid. So requires should return true. I want to make it fail because x is not static in T. – Koosha Nov 12 '20 at 6:00
  • T::x isn't valid, unless its address is taken or used in an unevaluated context. – Passer By Nov 12 '20 at 6:02
  • I don't see any problem with T::x. Of course you cannot expect to pass T::x to a function since x is not static. But for example, using A = decltype(T::x); compiles just fine. – Koosha Nov 12 '20 at 6:06
  • Oops, that was a typo. See this. You're not allowed to access T::x generally, there's nothing special about it being a function argument. – cigien Nov 12 '20 at 6:13

A requires expression is one big list of unevaluated operands.


2 A requires-expression is a prvalue of type bool whose value is described below. Expressions appearing within a requirement-body are unevaluated operands.

And a qualified-id naming a non-static data member always could appear in an unevaluated operand.


2 An id-expression that denotes a non-static data member or non-static member function of a class can only be used:

  • as part of a class member access in which the object expression refers to the member's class or a class derived from that class, or

  • to form a pointer to member ([expr.unary.op]), or

  • if that id-expression denotes a non-static data member and it appears in an unevaluated operand. [ Example:

struct S {
  int m;
int i = sizeof(S::m);           // OK
int j = sizeof(S::m + 42);      // OK

— end example ]

The unevaluated operand where T::x may appear can be any expression. So even pre-C++20 you could for example write

decltype(fun(T::x)) i{};
  • Thanks for your answer. So is there any concept that can decide if x is static in T or a member? Assuming either x is a static variable or x is a non-static variable (if it is of any help, we also know type of x is U, which could be a reference). – Koosha Nov 12 '20 at 6:50
  • @Koosha - Well... you can always leverage the fact that decltype(&T::x) will be different for the two. For a static member, it will be a pointer, and for a non-static member it will be a pointer-to-member. Examine that with the help of std::is_pointer or std::is_member_pointer and you can differentiate. – StoryTeller - Unslander Monica Nov 12 '20 at 6:53
  • Ah... references make this more complex. If U can be a reference, I have nothing. I'm not sure how decltype(&T::x) would need to behave. – StoryTeller - Unslander Monica Nov 12 '20 at 6:54
  • Yes, if U is a reference, I get the error cannot create pointer to reference member T::x (even when I do &T::x within Line B). – Koosha Nov 12 '20 at 6:58
  • 1
    So, to summarise, a common, intuitive understanding that you can check whether a piece of code will compile with requires is incorrect. – Fureeish Nov 12 '20 at 18:30

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