3

When playing with libstdcxx's test_property:

template<template<typename...> class Property,
       typename Type1, typename... Types>
constexpr bool
test_property(typename Property<Type1, Types...>::value_type value)
{
    return (Property<Type1, Types...>::value == value
      && Property<Type1, Types...>::type::value == value);
 }

class Property accepts at least 1 template parameter(Type1).

Here is a use case:

static_assert(test_property<is_copy_assignable, ExceptMoveAssignClass>(false), "");

But I found clang doesn't work fine with this function:

prog.cc:29:3: error: no matching function for call to 'test_property'
                test_property<std::is_copy_assignable, DeletedMoveAssignClass>(false);
                ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
prog.cc:12:1: note: candidate template ignored: substitution failure [with Property = std::is_copy_assignable, Type1 = DeletedMoveAssignClass]: too many template arguments for class template 'is_copy_assignable'
test_property(typename Property<Type1, Types...>::value_type value)
^                      ~~~~~~~~
1 error generated.

The root cause is clang doesn't allow class Property to be class that only accepts one template parameter like template< class T > struct is_copy_assignable;. Once class Property is modified into Property<Type1>, it will compile successfully:

template<template<typename...> class Property, typename Type1>
constexpr bool
ya_test_property(typename Property<Type1>::value_type value)
{
    return (Property<Type1>::value == value
        && Property<Type1>::type::value == value);
}

here is demo https://wandbox.org/permlink/LlL1o57Yted5WZo5

Of course, this function is from libstdcxx, so gcc can pass compile. Is this clang's bug?

3

Looks like a Clang bug if I'm interpreting [temp.variadic]/7 correctly:

When N is zero, the instantiation of the expansion produces an empty list. Such an instantiation does not alter the syntactic interpretation of the enclosing construct, even in cases where omitting the list entirely would otherwise be ill-formed or would result in an ambiguity in the grammar. [ Example:

template<class... T> struct X : T... { };
template<class... T> void f(T... values) {
  X<T...> x(values...);
}

template void f<>();    // OK: X<> has no base classes
                        // x is a variable of type X<> that is value-initialized

 — end example ]

Similarly, while std::is_copy_assignable<ExceptMoveAssignClass , > is ill-formed, an empty pack should not put us in this state. It should be equivalent to std::is_copy_assignable<ExceptMoveAssignClass>, which is well-formed.

Of course, if the pack wasn't empty, then we'd be passing too many arguments, which is ill-formed. But that is not the case.

  • Is not it the concequence that Clang has not yet fully implemented C++17 template template argument/parameter matching? open-std.org/jtc1/sc22/wg21/docs/papers/2016/p0522r0.html – Oliv Jan 22 at 7:08
  • @Oliv - Good question. I am... unsure. – StoryTeller Jan 22 at 7:12
  • The Clang status page says about P0522: (10): Despite being the resolution to a Defect Report, this feature is disabled by default in all language versions, and can be enabled explicitly with the flag -frelaxed-template-template-args in Clang 4 onwards. The change to the standard lacks a corresponding change for template partial ordering, resulting in ambiguity errors for reasonable and previously-valid code. This issue is expected to be rectified soon. – Marshall Clow Jan 22 at 15:54

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