std::indirectly_readable

From cppreference.com
< cpp‎ | iterator
 
 
Iterator library
Iterator concepts
indirectly_readable
(C++20)
Iterator primitives
Algorithm concepts and utilities
Indirect callable concepts
Common algorithm requirements
(C++20)
(C++20)
(C++20)
Utilities
(C++20)
Iterator adaptors
Range access
(C++11)(C++14)
(C++14)(C++14)  
(C++11)(C++14)
(C++14)(C++14)  
(C++17)(C++20)
(C++17)
(C++17)
 
Defined in header <iterator>
template< class In >

    concept __IndirectlyReadableImpl =
        requires(const In in) {
            typename std::iter_value_t<In>;
            typename std::iter_reference_t<In>;
            typename std::iter_rvalue_reference_t<In>;
            { *in } -> std::same_as<std::iter_reference_t<In>>;
            { ranges::iter_move(in) } -> std::same_as<std::iter_rvalue_reference_t<In>>;
        } &&
        std::common_reference_with<
            std::iter_reference_t<In>&&, std::iter_value_t<In>&
        > &&
        std::common_reference_with<
            std::iter_reference_t<In>&&, std::iter_rvalue_reference_t<In>&&
        > &&
        std::common_reference_with<
            std::iter_rvalue_reference_t<In>&&, const std::iter_value_t<In>&

        >;
(exposition only*)
template< class In >

    concept indirectly_readable =

        __IndirectlyReadableImpl<std::remove_cvref_t<In>>;
(since C++20)

The concept indirectly_readable is modeled by types that are readable by applying operator*, such as pointers, smart pointers, and input iterators.

Semantic requirements

Given a value i of type I, I models indirectly_readable only if all concepts it subsumes are modeled and the expression *i is equality-preserving.

Equality preservation

Expressions declared in requires expressions of the standard library concepts are required to be equality-preserving (except where stated otherwise).