Template | Comments |
The value of default-alignment shall be the most
stringent alignment requirement for any object type whose size
is no greater than Len ([basic.types]). The member typedef type shall be a trivial standard-layout type
suitable for use as uninitialized storage for any object whose size
is at most Len and whose alignment is a divisor of Align. | |
The member typedef type shall be a trivial standard-layout type suitable for use as
uninitialized storage for any object whose type is listed in Types;
its size shall be at least Len. The static member alignment_value
shall be an integral constant of type size_t whose value is the
strictest alignment of all types listed in Types. Each type in the template parameter pack Types
is a complete object type. | |
[Note : ]This behavior is similar to the lvalue-to-rvalue ([conv.lval]),
array-to-pointer ([conv.array]), and function-to-pointer ([conv.func])
conversions applied when an lvalue is used as an rvalue, but also
strips cv-qualifiers from class types in order to more closely model by-value
argument passing. — end note | |
template<bool B, class T,
class F> struct conditional; | |
template<class... T> struct common_type; | Unless this trait is specialized (as specified in Note B, below),
the member type is defined or omitted as specified in Note A, below. If it is omitted, there shall be no member type. Each type in the template parameter pack T shall be
complete, cv void, or an array of unknown bound. |
Unless this trait is specialized (as specified in Note D, below),
there shall be no member type. | |
If T is an enumeration type, the member typedef type names
the underlying type of T ([dcl.enum]);
otherwise, there is no member type. | |
template<class Fn, class... ArgTypes> struct invoke_result; | If the expression INVOKE(declval<Fn>(), declval<ArgTypes>()...)
is well-formed when treated as an unevaluated operand,
the member typedef type names the type
decltype(INVOKE(declval<Fn>(), declval<ArgTypes>()...));
otherwise, there shall be no member type. Only the validity of the immediate context of the
expression is considered. [Note : ]The compilation of the expression can result in side effects such as
the instantiation of class template specializations and function
template specializations, the generation of implicitly-defined
functions, and so on. Such side effects are not in the “immediate
context” and can result in the program being ill-formed. — end notePreconditions: Fn and all types in the template parameter pack ArgTypes are complete types, cv void, or arrays of unknown bound. |
If T is
a specialization reference_wrapper<X> for some type X,
the member typedef type of unwrap_reference<T> is X&,
otherwise it is T. | |
The member typedef type of unwrap_ref_decay<T>
denotes the type unwrap_reference_t<decay_t<T>>. |
template<size_t Len, size_t Alignment> struct aligned_storage { typedef struct { alignas(Alignment) unsigned char __data[Len]; } type; };
decay_t<decltype(false ? declval<D1>() : declval<D2>())>denotes a valid type, let C denote that type.
using PF1 = bool (&)(); using PF2 = short (*)(long); struct S { operator PF2() const; double operator()(char, int&); void fn(long) const; char data; }; using PMF = void (S::*)(long) const; using PMD = char S::*;the following assertions will hold:
static_assert(is_same_v<invoke_result_t<S, int>, short>); static_assert(is_same_v<invoke_result_t<S&, unsigned char, int&>, double>); static_assert(is_same_v<invoke_result_t<PF1>, bool>); static_assert(is_same_v<invoke_result_t<PMF, unique_ptr<S>, int>, void>); static_assert(is_same_v<invoke_result_t<PMD, S>, char&&>); static_assert(is_same_v<invoke_result_t<PMD, const S*>, const char&>);