I'm trying to use C++20 concepts, to start familiarizing with them. I feel pretty comfortable with easy concepts, for example with the standard concept movable I can write something like this (in all examples I suppose I'm using namespace std and I included <concepts> and any other header needed):

template<movable T>
int foo (T obj);

And be sure that when this function is called the passed object obj can be moved. I can write this even in a longer form:

template<typename T>
requires movable<T>
int foo (T obj);

And the result would be the same (I think).

But now let's look at another concept such as same_as. same_as takes 2 templates parameter (the 2 types to compare), so I can write:

template<typename T>
requires same_as<T, string>
int bar (T obj);

And now T is string. But How can I write it in the shorter form? I tried, and I can write this (as I intuitively expected):

template<same_as<string> T>
int bar (T obj);

But what is the formal rule behind this form?

Is the name (T) of the function template parameter, entered as first argument of the concept template? Or maybe as last? I don't know, there is very little information about this topic. I mean, in this example it is irrelevant, because same_as<A, B> is semantically equivalent to same_as<B, A>, but there are for sure cases where the order matters.

I know there are questions with similiar titles, such as this one, but it asks a different thing.

These are the resources I tried to get information from, but failed: cppReference, cppModernes, open-std (I browsed years 2018, 2019 and 2020) and this post.


But what is the formal rule behind this form?

The rule (that you correctly guessed your way into) is described in [temp.param]/4:

A type-constraint Q that designates a concept C can be used to constrain a contextually-determined type or template type parameter pack T with a constraint-expression E defined as follows. If Q is of the form C<A1, ⋯, An>, then let E′ be C<T, A1, ⋯, An>. Otherwise, let E′ be C<T>. If T is not a pack, then E is E′, otherwise E is (E′ && ...). This constraint-expression E is called the immediately-declared constraint of Q for T. The concept designated by a type-constraint shall be a type concept ([temp.concept]).

With examples in the subsequent paragraph:

A type-parameter that starts with a type-constraint introduces the immediately-declared constraint of the type-constraint for the parameter. [ Example:

template<typename T> concept C1 = true;
template<typename... Ts> concept C2 = true;
template<typename T, typename U> concept C3 = true;

template<C1 T> struct s1;               // associates C1<T>
template<C1... T> struct s2;            // associates (C1<T> && ...)
template<C2... T> struct s3;            // associates (C2<T> && ...)
template<C3<int> T> struct s4;          // associates C3<T, int>
template<C3<int>... T> struct s5;       // associates (C3<T, int> && ...)

— end example ]

You can also think of template <C T> as being shorthand for template <C<> T>, and then the type parameter T just always slots into the first argument of the concept.

  • Perfect, thanks a lot, I've been struggling since yesterday to find the formal confirmation of this rule. So the name becomes the first parameter. I'll save the site you pointed me to, it's perfect and I never find it on my searches on Google. Thanks! – Lapo Apr 26 '20 at 16:24
  • 1
    @Lapo Yep, that site is the HTML version of the latest C++ working draft. Good thing to refer to when you want to look up what the standard says (plus it's all nice and linked and everything). – Barry Apr 26 '20 at 16:45
  • Yes indeed, it's very well done. It's a shame it's never on the first pages of Google search. Very interesting discovery! – Lapo Apr 26 '20 at 17:41

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