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    std::ranges::prev

    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)
    (C++14)(C++14)  
    (C++11)(C++14)
    (C++14)(C++14)  
    (C++17)(C++20)
    (C++17)
    (C++17)
     
    Defined in header <iterator>
    Call signature
    template< std::bidirectional_iterator I > constexpr I prev( I i );
    		 (1) (since C++20)
    template< std::bidirectional_iterator I > constexpr I prev( I i, std::iter_difference_t<I> n );
    		 (2) (since C++20)
    template< std::bidirectional_iterator I > constexpr I prev( I i, std::iter_difference_t<I> n, I bound );
    		 (3) (since C++20)
    See More

    Return the nth predecessor of iterator i.

    The function-like entities described on this page are algorithm function objects (informally known as niebloids), that is:

    Parameters

    i - an iterator
    n - number of elements i should be descended
    bound - iterator denoting the beginning of the range i points to

    Return value

    1) The predecessor of i.
    2) The nth predecessor of iterator i.
    3) The nth predecessor of iterator i, or the first iterator that compares equal to bound, whichever is first.

    Complexity

    1) Constant.
    2,3) Constant if I models std::random_access_iterator<I>; otherwise linear.

    Possible implementation

    struct prev_fn
{
    template<std::bidirectional_iterator I>
    constexpr I operator()(I i) const
    {
        --i;
        return i;
    }

    template<std::bidirectional_iterator I>
    constexpr I operator()(I i, std::iter_difference_t<I> n) const
    {
        ranges::advance(i, -n);
        return i;
    }

    template<std::bidirectional_iterator I>
    constexpr I operator()(I i, std::iter_difference_t<I> n, I bound) const
    {
        ranges::advance(i, -n, bound);
        return i;
    }
};

inline constexpr auto prev = prev_fn();

    Notes

    Although the expression --r.end() often compiles for containers, it is not guaranteed to do so: r.end() is an rvalue expression, and there is no iterator requirement that specifies that decrement of an rvalue is guaranteed to work. In particular, when iterators are implemented as pointers or its operator-- is lvalue-ref-qualified, --r.end() does not compile, while ranges::prev(r.end()) does.

    This is further exacerbated by ranges that do not model ranges::common_range. For example, for some underlying ranges, ranges::transform_view::end doesn't have the same return type as ranges::transform_view::begin, and so --r.end() won't compile. This isn't something that ranges::prev can aid with, but there are workarounds.

    Example

    Run this code
    #include <iostream>
#include <iterator>
#include <vector>

int main() 
{
    std::vector<int> v{3, 1, 4};
    auto pv = std::ranges::prev(v.end(), 2);
    std::cout << *pv << '\n';

    pv = std::ranges::prev(pv, 42, v.begin());
    std::cout << *pv << '\n';
}

    Output: 

    1
3

    See also

    (C++20)
    		 increment an iterator by a given distance or to a bound
    (algorithm function object)[edit]
    (C++20)
    		 advances an iterator by given distance or to a given bound
    (algorithm function object)[edit]
    (C++11)
    		 decrement an iterator
    (function template) [edit]