4

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?

6
  • 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
2

A requires expression is one big list of unevaluated operands.

[expr.prim.req]

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.

[expr.prim.id]

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{};
5
  • 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

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.