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    std::bidirectional_iterator

    From cppreference.com
     
    C++
     
    Iterator library
    Iterator concepts
    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)
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    (C++17)(C++20)
    (C++17)
    (C++17)
     
    Defined in header <iterator>
    template< class I > concept bidirectional_iterator = std::forward_iterator<I> && std::derived_from</*ITER_CONCEPT*/<I>, std::bidirectional_iterator_tag> && requires(I i) { { --i } -> std::same_as<I&>; { i-- } -> std::same_as<I>; };
    		 (since C++20)
    See More

    The concept bidirectional_iterator refines forward_iterator by adding the ability to move an iterator backward.

    Iterator concept determination

    Definition of this concept is specified via an exposition-only alias template /*ITER_CONCEPT*/.

    In order to determine /*ITER_CONCEPT*/<I>, let ITER_TRAITS<I> denote I if the specialization std::iterator_traits<I> is generated from the primary template, or std::iterator_traits<I> otherwise:

    • If ITER_TRAITS<I>::iterator_concept is valid and names a type, /*ITER_CONCEPT*/<I> denotes the type.
    • Otherwise, if ITER_TRAITS<I>::iterator_category is valid and names a type, /*ITER_CONCEPT*/<I> denotes the type.
    • Otherwise, if std::iterator_traits<I> is generated from the primary template, /*ITER_CONCEPT*/<I> denotes std::random_access_iterator_tag.
      (That is, std::derived_from</*ITER_CONCEPT*/<I>, std::bidirectional_iterator_tag> is assumed to be true.)
    • Otherwise, /*ITER_CONCEPT*/<I> does not denote a type and results in a substitution failure.

    Semantic requirements

    A bidirectional iterator r is said to be decrementable if and only if there exists some s such that ++s == r.

    std::bidirectional_iterator<I> is modeled only if all the concepts it subsumes are modeled, and given two objects a and b of type I:

    • If a is decrementable, a is in the domain of the expressions --a and a--.
    • Pre-decrement yields an lvalue that refers to the operand: std::addressof(--a) == std::addressof(a).
    • Post-decrement yields the previous value of the operand: if bool(a == b), then bool(a-- == b).
    • Post-decrement and pre-decrement perform the same modification on its operand: If bool(a == b), then after evaluating both a-- and --b, bool(a == b) still holds.
    • Increment and decrement are inverses of each other:
    • If a is incrementable and bool(a == b), then bool(--(++a) == b).
    • If a is decrementable and bool(a == b), then bool(++(--a) == b).

    Equality preservation

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

    Notes

    Unlike the LegacyBidirectionalIterator requirements, the bidirectional_iterator concept does not require dereference to return an lvalue.

    Example

    A minimum bidirectional iterator. 

    #include <cstddef>
#include <iterator>

struct SimpleBidiIterator
{
    using difference_type = std::ptrdiff_t;
    using value_type = int;

    int operator*() const;

    SimpleBidiIterator& operator++();

    SimpleBidiIterator operator++(int)
    {
        auto tmp = *this;
        ++*this;
        return tmp;
    }

    SimpleBidiIterator& operator--();

    SimpleBidiIterator operator--(int)
    {
        auto tmp = *this;
        --*this;
        return tmp;
    }

    bool operator==(const SimpleBidiIterator&) const;
};

static_assert(std::bidirectional_iterator<SimpleBidiIterator>);

    See also

    (C++20)
    		 specifies that an input_iterator is a forward iterator, supporting equality comparison and multi-pass
    (concept) [edit]
    (C++20)
    		 specifies that a bidirectional_iterator is a random-access iterator, supporting advancement in constant time and subscripting
    (concept) [edit]