std::ranges::stable_partition
来自cppreference.com
| 在标头 <algorithm> 定义
|
||
| 调用签名 |
||
| (1) | (C++20 起) (C++26 起为 constexpr) |
|
| (2) | (C++20 起) (C++26 起为 constexpr) |
|
1) 重排序范围
[first, last) 中的元素,使得谓词 pred 对 proj 投影后返回 true 的所有元素处于谓词 pred 对 proj 投影后返回 false 的所有元素之前。算法是稳定的,即保持元素的相对顺序。2) 同 (1),但以
r 为范围,如同以 ranges::begin(r) 为 first 并以 ranges::end(r) 为 last。此页面上描述的函数式实体是算法函数对象(非正式地称为 niebloid),即:
参数
| first, last | - | 要重排元素范围的迭代器-哨位对 |
| r | - | 要重排的元素范围 |
| pred | - | 应用到投影后元素的谓词 |
| proj | - | 应用到元素的投影 |
返回值
1) 等于
{pivot, last} 的对象,其中 pivot 是指向第二组首个元素的迭代器。复杂度
给定 N = ranges::distance(first, last),复杂度最坏为交换 N·log(N) 次,而在使用额外内存时仅交换 𝓞(N) 次。恰好应用谓词 pred 和投影 proj N 次。
注解
此函数尝试分配临时缓冲区。若分配失败,则选择效率较低的算法。
| 功能特性测试宏 | 值 | 标准 | 功能特性 |
|---|---|---|---|
__cpp_lib_constexpr_algorithms |
202306L |
(C++26) | constexpr 稳定排序
|
可能的实现
此实现不使用额外内存缓冲区,而这样可能较为低效。参阅 MSVC STL 与 libstdc++ 中的实现。
struct stable_partition_fn
{
template<std::bidirectional_iterator I, std::sentinel_for<I> S,
class Proj = std::identity,
std::indirect_unary_predicate<std::projected<I, Proj>> Pred>
requires std::permutable<I>
constexpr ranges::subrange<I>
operator()(I first, S last, Pred pred, Proj proj = {}) const
{
first = ranges::find_if_not(first, last, pred, proj);
I mid = first;
while (mid != last)
{
mid = ranges::find_if(mid, last, pred, proj);
if (mid == last)
break;
I last2 = ranges::find_if_not(mid, last, pred, proj);
ranges::rotate(first, mid, last2);
first = ranges::next(first, ranges::distance(mid, last2));
mid = last2;
}
return {std::move(first), std::move(mid)};
}
template<ranges::bidirectional_range R, class Proj = std::identity,
std::indirect_unary_predicate<
std::projected<ranges::iterator_t<R>, Proj>> Pred>
requires std::permutable<ranges::iterator_t<R>>
constexpr ranges::borrowed_subrange_t<R>
operator()(R&& r, Pred pred, Proj proj = {}) const
{
return (*this)(ranges::begin(r), ranges::end(r), std::move(pred), std::move(proj));
}
};
inline constexpr stable_partition_fn stable_partition {};
|
示例
运行此代码
#include <algorithm>
#include <iostream>
#include <iterator>
#include <vector>
namespace rng = std::ranges;
template<std::permutable I, std::sentinel_for<I> S>
constexpr void stable_sort(I first, S last)
{
if (first == last)
return;
auto pivot = *rng::next(first, rng::distance(first, last) / 2, last);
auto left = [pivot](const auto& em) { return em < pivot; };
auto tail1 = rng::stable_partition(first, last, left);
auto right = [pivot](const auto& em) { return !(pivot < em); };
auto tail2 = rng::stable_partition(tail1, right);
stable_sort(first, tail1.begin());
stable_sort(tail2.begin(), tail2.end());
}
void print(const auto rem, auto first, auto last, bool end = true)
{
std::cout << rem;
for (; first != last; ++first)
std::cout << *first << ' ';
std::cout << (end ? "\n" : "");
}
int main()
{
const auto original = {9, 6, 5, 2, 3, 1, 7, 8};
std::vector<int> vi {};
auto even = [](int x) { return 0 == (x % 2); };
print("Original vector:\t", original.begin(), original.end(), "\n");
vi = original;
const auto ret1 = rng::stable_partition(vi, even);
print("Stable partitioned:\t", vi.begin(), ret1.begin(), 0);
print("│ ", ret1.begin(), ret1.end());
vi = original;
const auto ret2 = rng::partition(vi, even);
print("Partitioned:\t\t", vi.begin(), ret2.begin(), 0);
print("│ ", ret2.begin(), ret2.end());
vi = {16, 30, 44, 30, 15, 24, 10, 18, 12, 35};
print("Unsorted vector: ", vi.begin(), vi.end());
stable_sort(rng::begin(vi), rng::end(vi));
print("Sorted vector: ", vi.begin(), vi.end());
}
可能的输出:
Original vector: 9 6 5 2 3 1 7 8
Stable partitioned: 6 2 8 │ 9 5 3 1 7
Partitioned: 8 6 2 │ 5 3 1 7 9
Unsorted vector: 16 30 44 30 15 24 10 18 12 35
Sorted vector: 10 12 15 16 18 24 30 30 35 44