2022-12-20：二狗买了一些小兵玩具，和大胖一起玩， 一共有n个小兵，这n个小兵拍成一列， 第i个小兵战斗力为hi，然后他们两个开始对小兵进行排列， 一共进行m次操作，二狗每次操作选择一个数k，

2022-12-20：二狗买了一些小兵玩具，和大胖一起玩，
一共有n个小兵，这n个小兵拍成一列，
第i个小兵战斗力为hi，然后他们两个开始对小兵进行排列，
一共进行m次操作，二狗每次操作选择一个数k，将前k个小兵战斗力从小到大排列，
大胖每次操作选择一个数k，将前k个小兵战斗力从大到小排列，
问所有操作结束后，排列顺序什么样，
给定一个长度为n的数组arr，表示每个小兵的战斗力，
给定一个长度为m的数组op,
op[i] = { k , 0 }, 表示对前k个士兵执行从小到大的操作，
op[i] = { k , 1 }, 表示对前k个士兵执行从大到小的操作。
返回数组ans，表示最终的排列。
1 <= n, m <= 2 * 10^5，
-10 ^ 9<= arr[i] <= + 10^9。
来自百度。

答案2022-12-20：

单调栈+有序表。
rust语言里结构体的有序表需要实现Ord的trait。
时间复杂度O(M) + O(N*logN)。

rust代码如下：

use rand::Rng;

use std::cmp::Ordering;

use std::collections::BTreeSet;

use std::iter::repeat;

fn main() {

    let mut arr = vec![3, 2, 6, 7, 5, 1];

    let mut op = vec![vec![3, 0], vec![4, 1], vec![2, 0]];

    let ans2 = game2(&mut arr, &mut op);

    println!("ans2 = {:?}", ans2);

    let nn: i32 = 200;

    let mm: i32 = 100;

    let vv: i32 = 200;

    let test_time: i32 = 5000;

    println!("测试开始");

    for i in 0..test_time {

        let n: i32 = rand::thread_rng().gen_range(0, nn) + 1;

        let m: i32 = rand::thread_rng().gen_range(0, mm) + 1;

        let mut arr = random_array(n, vv);

        let mut op = random_op(m, n);

        let ans1 = game1(&mut arr, &mut op);

        let ans2 = game2(&mut arr, &mut op);

        if ans1 != ans2 {

            println!("出错了!");

            println!("i = {}", i);

            println!("ans1 = {:?}", ans1);

            println!("ans2 = {:?}", ans2);

            break;

        }

    }

    println!("测试结束");

}

// 暴力方法

// 为了验证

fn game1(arr: &mut Vec<i32>, op: &mut Vec<Vec<i32>>) -> Vec<i32> {

    let n = arr.len() as i32;

    let mut help: Vec<i32> = repeat(0).take(n as usize).collect();

    for i in 0..n {

        help[i as usize] = arr[i as usize];

    }

    for o in op.iter() {

        if o[1] == 0 {

            help[0..o[0] as usize].sort_by(|a, b| a.cmp(b));

        } else {

            help[0..o[0] as usize].sort_by(|a, b| b.cmp(a));

        }

    }

    let mut ans: Vec<i32> = repeat(0).take(n as usize).collect();

    for i in 0..n {

        ans[i as usize] = help[i as usize];

    }

    return ans;

}

// 正式方法

// 时间复杂度O(M) + O(N*logN)

fn game2(arr: &mut Vec<i32>, op: &mut Vec<Vec<i32>>) -> Vec<i32> {

    let n = arr.len() as i32;

    let m = op.len() as i32;

    let mut stack: Vec<i32> = repeat(0).take(m as usize).collect();

    let mut r = 0;

    for i in 0..m {

        while r != 0 && op[stack[(r - 1) as usize] as usize][0] <= op[i as usize][0] {

            r -= 1;

        }

        stack[r as usize] = i;

        r += 1;

    }

    let mut ans: Vec<i32> = repeat(0).take(n as usize).collect();

    let mut ansi = n - 1;

    let mut l = 0;

    while ansi >= op[stack[l as usize] as usize][0] {

        ans[ansi as usize] = arr[ansi as usize];

        ansi -= 1;

    }

    let mut sorted: BTreeSet<Number> = BTreeSet::new();

    for i in 0..op[stack[l as usize] as usize][0] {

        sorted.insert(Number::new(arr[i as usize], i));

    }

    while l != r {

        // 当前处理的指令

        let cur = &op[stack[l as usize] as usize];

        l += 1;

        if l != r {

            let mut next = &op[stack[l as usize] as usize];

            let num = cur[0] - next[0];

            if cur[1] == 0 {

                for i in 0..num {

                    ans[ansi as usize] = sorted.pop_last().unwrap().value;

                    ansi -= 1;

                }

            } else {

                for i in 0..num {

                    ans[ansi as usize] = sorted.pop_first().unwrap().value;

                    ansi -= 1;

                }

            }

        } else {

            if cur[1] == 0 {

                while sorted.len() > 0 {

                    ans[ansi as usize] = sorted.pop_last().unwrap().value;

                    ansi -= 1;

                }

            } else {

                while sorted.len() > 0 {

                    ans[ansi as usize] = sorted.pop_first().unwrap().value;

                    ansi -= 1;

                }

            }

        }

    }

    return ans;

}

struct Number {

    value: i32,

    index: i32,

}

impl Number {

    fn new(v: i32, i: i32) -> Self {

        Self { value: v, index: i }

    }

}

impl Ord for Number {

    fn cmp(&self, other: &Self) -> Ordering {

        if self.value != other.value {

            self.value.cmp(&other.value)

        } else {

            self.index.cmp(&other.index)

        }

    }

}

impl PartialOrd for Number {

    fn partial_cmp(&self, other: &Self) -> Option<Ordering> {

        Some(self.cmp(other))

    }

}

impl PartialEq for Number {

    fn eq(&self, other: &Self) -> bool {

        (self.value, &self.index) == (other.value, &other.index)

    }

}

impl Eq for Number {}

// 为了测试

fn random_array(n: i32, v: i32) -> Vec<i32> {

    let mut ans: Vec<i32> = repeat(0).take(n as usize).collect();

    for i in 0..n {

        ans[i as usize] = rand::thread_rng().gen_range(0, v) + 1;

    }

    return ans;

}

// 为了测试

fn random_op(m: i32, n: i32) -> Vec<Vec<i32>> {

    let mut ans: Vec<Vec<i32>> = repeat(repeat(0).take(2).collect())

        .take(m as usize)

        .collect();

    for i in 0..m {

        ans[i as usize][0] = rand::thread_rng().gen_range(0, n + 1);

        ans[i as usize][1] = rand::thread_rng().gen_range(0, 2);

    }

    return ans;

}

// 为了测试

fn is_equal(arr1: &mut Vec<i32>, arr2: &mut Vec<i32>) -> bool {

    if arr1.len() != arr2.len() {

        return false;

    }

    for i in 0..arr1.len() {

        if arr1[i as usize] != arr2[i as usize] {

            return false;

        }

    }

    return true;

}

2022-12-20：二狗买了一些小兵玩具，和大胖一起玩， 一共有n个小兵，这n个小兵拍成一列， 第i个小兵战斗力为hi，然后他们两个开始对小兵进行排列， 一共进行m次操作，二狗每次操作选择一个数k，的相关教程结束。