std::ranges::partition_point
Defined in header <algorithm> | ||
Call signature | ||
template<std::forward_iterator I, std::sentinel_for<I> S, class Proj =std::identity, | (1) | (since C++20) |
template<ranges::forward_range R, class Proj =std::identity, | (2) | (since C++20) |
Examines the partitioned (as if by ranges::partition) range [first, last) or r and locates the end of the first partition, that is, the projected element that does not satisfy pred or last if all projected elements satisfy pred.
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.
Contents |
[edit]Parameters
| first, last | - | the iterator-sentinel pair defining the partially-ordered range of elements to examine |
| r | - | the partially-ordered range to examine |
| pred | - | predicate to apply to the projected elements |
| proj | - | projection to apply to the elements |
[edit]Return value
The iterator past the end of the first partition within [first, last) or the iterator equal to last if all projected elements satisfy pred.
[edit]Complexity
Given N =ranges::distance(first, last), performs O(log N) applications of the predicate pred and projection proj.
However, if sentinels don't model std::sized_sentinel_for<I>, the number of iterator increments is O(N).
[edit]Notes
This algorithm is a more general form of ranges::lower_bound, which can be expressed in terms of ranges::partition_point with the predicate [&](autoconst& e){returnstd::invoke(pred, e, value);});.
[edit]Example
#include <algorithm>#include <array>#include <iostream>#include <iterator> auto print_seq =[](auto rem, auto first, auto last){for(std::cout<< rem; first != last;std::cout<<*first++<<' '){}std::cout<<'\n';}; int main(){std::array v {1, 2, 3, 4, 5, 6, 7, 8, 9}; auto is_even =[](int i){return i %2==0;}; std::ranges::partition(v, is_even); print_seq("After partitioning, v: ", v.cbegin(), v.cend()); constauto pp = std::ranges::partition_point(v, is_even);constauto i = std::ranges::distance(v.cbegin(), pp);std::cout<<"Partition point is at "<< i <<"; v["<< i <<"] = "<<*pp <<'\n'; print_seq("First partition (all even elements): ", v.cbegin(), pp); print_seq("Second partition (all odd elements): ", pp, v.cend());}
Possible output:
After partitioning, v: 2 4 6 8 5 3 7 1 9 Partition point is at 4; v[4] = 5 First partition (all even elements): 2 4 6 8 Second partition (all odd elements): 5 3 7 1 9
[edit]See also
(C++20) | checks whether a range is sorted into ascending order (algorithm function object) |
(C++20) | returns an iterator to the first element not less than the given value (algorithm function object) |
(C++11) | locates the partition point of a partitioned range (function template) |
