13 Templates [temp]

13.2 Template parameters [temp.param]

type-parameter-key:
class
typename
The component names of a type-constraint are its concept-name and those of its nested-name-specifier (if any).
[Note 1: 
The > token following the template-parameter-list of a type-parameter can be the product of replacing a >> token by two consecutive > tokens ([temp.names]).
— end note]
There is no semantic difference between class and typename in a type-parameter-key.
typename followed by an unqualified-id names a template type parameter.
typename followed by a qualified-id denotes the type in a non-type115 parameter-declaration.
[Example 1: class T { /* ... */ }; int i; template<class T, T i> void f(T t) { T t1 = i; // template-parameters T and i ::T t2 = ::i; // global namespace members T and i }
Here, the template f has a type-parameter called T, rather than an unnamed non-type template-parameter of class T.
— end example]
A storage class shall not be specified in a template-parameter declaration.
Types shall not be defined in a template-parameter declaration.
The identifier in a type-parameter is not looked up.
A type-parameter whose identifier does not follow an ellipsis defines its identifier to be a typedef-name (if declared without template) or template-name (if declared with template) in the scope of the template declaration.
[Note 2: 
A template argument can be a class template or alias template.
For example,
template<class T> class myarray { /* ... */ }; template<class K, class V, template<class T> class C = myarray> class Map { C<K> key; C<V> value; }; — end note]
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<A, , A>, then let E be C<T, A, , A>.
Otherwise, let E be C<T>.
If T is not a pack, then E is E, otherwise E is (E && ...).
The concept designated by a type-constraint shall be a type concept ([temp.concept]).
A type-parameter that starts with a type-constraint introduces the immediately-declared constraint of the type-constraint for the parameter.
[Example 2: 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]
A non-type template-parameter shall have one of the following (possibly cv-qualified) types:
The top-level cv-qualifiers on the template-parameter are ignored when determining its type.
A structural type is one of the following:
  • a scalar type, or
  • an lvalue reference type, or
  • a literal class type with the following properties:
    • all base classes and non-static data members are public and non-mutable and
    • the types of all bases classes and non-static data members are structural types or (possibly multidimensional) array thereof.
An id-expression naming a non-type template-parameter of class type T denotes a static storage duration object of type const T, known as a template parameter object, whose value is that of the corresponding template argument after it has been converted to the type of the template-parameter.
All such template parameters in the program of the same type with the same value denote the same template parameter object.
A template parameter object shall have constant destruction ([expr.const]).
[Note 3: 
If an id-expression names a non-type non-reference template-parameter, then it is a prvalue if it has non-class type.
Otherwise, if it is of class type T, it is an lvalue and has type const T ([expr.prim.id.unqual]).
— end note]
[Example 3: using X = int; struct A {}; template<const X& x, int i, A a> void f() { i++; // error: change of template-parameter value &x; // OK &i; // error: address of non-reference template-parameter &a; // OK int& ri = i; // error: attempt to bind non-const reference to temporary const int& cri = i; // OK, const reference binds to temporary const A& ra = a; // OK, const reference binds to a template parameter object } — end example]
[Note 4: 
A non-type template-parameter cannot be declared to have type cv void.
[Example 4: template<void v> class X; // error template<void* pv> class Y; // OK — end example]
— end note]
A non-type template-parameter of type “array of T” or of function type T is adjusted to be of type “pointer to T.
[Example 5: template<int* a> struct R { /* ... */ }; template<int b[5]> struct S { /* ... */ }; int p; R<&p> w; // OK S<&p> x; // OK due to parameter adjustment int v[5]; R<v> y; // OK due to implicit argument conversion S<v> z; // OK due to both adjustment and conversion — end example]
A non-type template parameter declared with a type that contains a placeholder type with a type-constraint introduces the immediately-declared constraint of the type-constraint for the invented type corresponding to the placeholder ([dcl.fct]).
A default template-argument may be specified for any kind of template-parameter (type, non-type, template) that is not a template parameter pack.
A default template-argument may be specified in a template declaration.
A default template-argument shall not be specified in the template-parameter-lists of the definition of a member of a class template that appears outside of the member's class.
A default template-argument shall not be specified in a friend class template declaration.
If a friend function template declaration D specifies a default template-argument, that declaration shall be a definition and there shall be no other declaration of the function template which is reachable from D or from which D is reachable.
The set of default template-arguments available for use is obtained by merging the default arguments from all prior declarations of the template in the same way default function arguments are ([dcl.fct.default]).
[Example 6: 
template<class T1, class T2 = int> class A; template<class T1 = int, class T2> class A; is equivalent to template<class T1 = int, class T2 = int> class A;
— end example]
If a template-parameter of a class template, variable template, or alias template has a default template-argument, each subsequent template-parameter shall either have a default template-argument supplied or be a template parameter pack.
If a template-parameter of a primary class template, primary variable template, or alias template is a template parameter pack, it shall be the last template-parameter.
A template parameter pack of a function template shall not be followed by another template parameter unless that template parameter can be deduced from the parameter-type-list ([dcl.fct]) of the function template or has a default argument ([temp.deduct]).
A template parameter of a deduction guide template ([temp.deduct.guide]) that does not have a default argument shall be deducible from the parameter-type-list of the deduction guide template.
[Example 7: template<class T1 = int, class T2> class B; // error // U can be neither deduced from the parameter-type-list nor specified template<class... T, class... U> void f() { } // error template<class... T, class U> void g() { } // error — end example]
When parsing a default template-argument for a non-type template-parameter, the first non-nested > is taken as the end of the template-parameter-list rather than a greater-than operator.
[Example 8: template<int i = 3 > 4 > // syntax error class X { /* ... */ }; template<int i = (3 > 4) > // OK class Y { /* ... */ }; — end example]
A template-parameter of a template template-parameter is permitted to have a default template-argument.
When such default arguments are specified, they apply to the template template-parameter in the scope of the template template-parameter.
[Example 9: template <template <class TT = float> class T> struct A { inline void f(); inline void g(); }; template <template <class TT> class T> void A<T>::f() { T<> t; // error: TT has no default template argument } template <template <class TT = char> class T> void A<T>::g() { T<> t; // OK, T<char> } — end example]
If a template-parameter is a type-parameter with an ellipsis prior to its optional identifier or is a parameter-declaration that declares a pack ([dcl.fct]), then the template-parameter is a template parameter pack.
A template parameter pack that is a parameter-declaration whose type contains one or more unexpanded packs is a pack expansion.
Similarly, a template parameter pack that is a type-parameter with a template-parameter-list containing one or more unexpanded packs is a pack expansion.
A type parameter pack with a type-constraint that contains an unexpanded parameter pack is a pack expansion.
A template parameter pack that is a pack expansion shall not expand a template parameter pack declared in the same template-parameter-list.
[Example 10: template <class... Types> // Types is a template type parameter pack class Tuple; // but not a pack expansion template <class T, int... Dims> // Dims is a non-type template parameter pack struct multi_array; // but not a pack expansion template <class... T> struct value_holder { template <T... Values> struct apply { }; // Values is a non-type template parameter pack }; // and a pack expansion template <class... T, T... Values> // error: Values expands template type parameter struct static_array; // pack T within the same template parameter list — end example]
115)115)
Since template template-parameters and template template-arguments are treated as types for descriptive purposes, the terms non-type parameter and non-type argument are used to refer to non-type, non-template parameters and arguments.