I've just learnt from a video of a presentation by Saar Raz that the following constraints:

template <typename T>
concept C = sizeof(T) > 1;

template <typename T>
concept D = sizeof(T) > 1 && sizeof(T) >= 4;

are ambiguous for overloading because the atomic constraints sizeof(T) > 1 occurring at C and D, respectively, are not equivalent.

They aren't because the standard says [templ.constr]:

Two atomic constraints are identical if they are formed from the same expression [...]

The key is that expression is in italics, referring to the grammar term, which is defined as [expr.comma]:



expression , assignment-expression

I don't understand why an atomic constraint needs to involve an assignment. Why is so?

I must admit that the above code is best written by concept refinement, but I intuitively thought that that way of writing it was correct too.

  • 4
    The wording is indeed confusing, see github.com/cplusplus/draft/issues/2554 – cpplearner Aug 31 at 11:50
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    I'm wondering how sizeof(T) can be greater than or equal to 4, but not greater than 1. – Sam Varshavchik Aug 31 at 12:18
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    @SamVarshavchik I don't understand your comment. Are you familiar with concepts and the notion of most constrained? Check this out: wandbox.org/permlink/wLOl0CdelaigTfvs – Pilar Latiesa Aug 31 at 13:16
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    @SamVarshavchik Saar Raz is the responsible for the implementation of concepts in Clang: reviews.llvm.org/p/saar.raz. He's not a clown. template <typename T> concept D = C<T> && sizeof(T) >= 4 is perfectly valid and meaningful code. – Pilar Latiesa Sep 1 at 9:08
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    @SamVarshavchik Well C<T> && sizeof(T) >= 4 effectively does that, and yet you agree it is useful for overload resolution. I obviously realise that C is redundant, but it is necessary for the compiler to figure out that D is more constrained than C. You were insinting so badly on an obvious thing that I misunderstood you. – Pilar Latiesa Sep 1 at 16:04

I don't understand why an atomic constraint needs to involve an assignment. Why is so?

Emphasis mine.

It doesn't need to involve an assignment. It's just that expression is the top-level grammar term for expressions, that encompasses all the other kinds of expressions. sizeof(T) > 1 is an expression, as is sizeof(T) >= 4, as is sizeof(T) > 1 && sizeof(T) >= 4.

What this grammar definition means is that an expression is either an assignment-expression or another expression , assignment-expression. The grammar is hierarchically arranged based on what we consider to be operator precedence:

  • , has the lowest precedence, so the grammar pulls that one out first. That's what happens when we define expression recurisvely as expression , assignment-expression
  • = has the next lowest precedence, so we pull that one out next.
  • And then the grammar for assignment-expression takes us to logical-or-expression (next lowest precedence)
  • And then logical-and-expression, etc.

An assignment-expression need not actually involve an assignment. It's actually any kind of arbitrarily complex expression. All we know about it is that it definitely does not involve a , because we already pulled that one out.

Separately from all of that, the intent is that two atomic constraints are the same if they are literally the same expression in a source file. That is, constraint subsumption only applies to concepts.

  • So is sizeof(T) > 1 && sizeof(T) >= 4 an atomic constraint? If so, I don't understand the note in this paragraph: eel.is/c++draft/temp.constr#atomic-1. – Pilar Latiesa Aug 31 at 13:23
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    @PilarLatiesa No it's not, because after undergoing normalization you end up with sizeof(T) > 1 and sizeof(T) >= 4 (i.e. a conjunction of the two separate constraints). – Barry Aug 31 at 13:26
  • Your last sentence is what I wanted to know. The linked question is also very useful. I guess that the notion of atomic constraint is only useful for compiler implementers, while programmers work with concepts. Thanks – Pilar Latiesa Aug 31 at 13:42

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