std::ranges::fold_right_last

Right-folds the elements of given range, that is, returns the result of evaluation of the chain expression:
f(x1, f(x2, ...f(xn-1, xn))), where x1, x2, ..., xn are elements of the range.

Informally, ranges::fold_right_last behaves like ranges::fold_left(views::reverse(r), *--last, /*flipped*/(f)) (assuming the range is not empty).

The behavior is undefined if [first, last) is not a valid range.

if(first == last)returnstd::optional<U>(); I tail =ranges::prev(ranges::next(first, std::move(last)));returnstd::optional<U>(std::in_place, ranges::fold_right(std::move(first), tail, std::iter_value_t<I>(*tail), std::move(f)));

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

• Explicit template argument lists cannot be specified when calling any of them.
• None of them are visible to argument-dependent lookup.
• When any of them are found by normal unqualified lookup as the name to the left of the function-call operator, argument-dependent lookup is inhibited.

[edit]Parameters

[edit]Return value

An object of type std::optional<U> that contains the result of right-fold of the given range over f.

If the range is empty, std::optional<U>() is returned.

[edit]Possible implementations

struct fold_right_last_fn {template<std::bidirectional_iterator I, std::sentinel_for<I> S, /*indirectly-binary-right-foldable*/<std::iter_value_t<I>, I> F> requires std::constructible_from<std::iter_value_t<I>, std::iter_reference_t<I>>constexprauto operator()(I first, S last, F f)const{using U = decltype(ranges::fold_right(first, last, std::iter_value_t<I>(*first), f));   if(first == last)returnstd::optional<U>(); I tail =ranges::prev(ranges::next(first, std::move(last)));returnstd::optional<U>(std::in_place, ranges::fold_right(std::move(first), tail, std::iter_value_t<I>(*tail), std::move(f)));}   template<ranges::bidirectional_range R, /*indirectly_binary_right_foldable*/<ranges::range_value_t<R>, ranges::iterator_t<R>> F> requires std::constructible_from<ranges::range_value_t<R>, ranges::range_reference_t<R>>constexprauto operator()(R&& r, F f)const{return(*this)(ranges::begin(r), ranges::end(r), std::ref(f));}};   inlineconstexpr fold_right_last_fn fold_right_last;

[edit]Complexity

Exactly ranges::distance(first, last) applications of the function object f.

[edit]Notes

The following table compares all constrained folding algorithms:

[edit]Example

#include <algorithm>#include <functional>#include <iostream>#include <ranges>#include <utility>#include <vector>   int main(){auto v ={1, 2, 3, 4, 5, 6, 7, 8};std::vector<std::string> vs {"A", "B", "C", "D"};   auto r1 = std::ranges::fold_right_last(v.begin(), v.end(), std::plus<>());// (1)std::cout<<"*r1: "<<*r1 <<'\n';   auto r2 = std::ranges::fold_right_last(vs, std::plus<>());// (2)std::cout<<"*r2: "<<*r2 <<'\n';   // Use a program defined function object (lambda-expression):auto r3 = std::ranges::fold_right_last(v, [](int x, int y){return x + y +99;});std::cout<<"*r3: "<<*r3 <<'\n';   // Get the product of the std::pair::second of all pairs in the vector:std::vector<std::pair<char, float>> data {{'A', 3.f}, {'B', 3.5f}, {'C', 4.f}};auto r4 = std::ranges::fold_right_last( data | std::ranges::views::values, std::multiplies<>());std::cout<<"*r4: "<<*r4 <<'\n';}

*r1: 36 *r2: ABCD *r3: 729 *r4: 42

[edit]References

[edit]See also