1057.Campus-Bikes

1057. Campus Bikes

题目地址

题目描述

On a campus represented as a 2D grid, there are N workers and M bikes, with N <= M. Each worker and bike is a 2D coordinate on this grid.

Our goal is to assign a bike to each worker. Among the available bikes and workers, we choose the (worker, bike) pair with the shortest Manhattan distance between each other, and assign the bike to that worker. (If there are multiple (worker, bike) pairs with the same shortest Manhattan distance, we choose the pair with the smallest worker index; if there are multiple ways to do that, we choose the pair with the smallest bike index). We repeat this process until there are no available workers.

The Manhattan distance between two points p1 and p2 is Manhattan(p1, p2) = |p1.x - p2.x| + |p1.y - p2.y|.

Return a vector ans of length N, where ans[i] is the index (0-indexed) of the bike that the i-th worker is assigned to.

Example 1:
Input: workers = [[0,0],[2,1]], bikes = [[1,2],[3,3]]
Output: [1,0]
Explanation: 
Worker 1 grabs Bike 0 as they are closest (without ties), and Worker 0 is assigned Bike 1. So the output is [1, 0].

Example 2:
Input: workers = [[0,0],[1,1],[2,0]], bikes = [[1,0],[2,2],[2,1]]
Output: [0,2,1]
Explanation: 
Worker 0 grabs Bike 0 at first. Worker 1 and Worker 2 share the same distance to Bike 2, thus Worker 1 is assigned to Bike 2, and Worker 2 will take Bike 1. So the output is [0,2,1].

Note:
0 <= workers[i][j], bikes[i][j] < 1000
All worker and bike locations are distinct.
1 <= workers.length <= bikes.length <= 1000

代码

Approach #1

class Solution {
  public int[] assignBikes(int[][] workers, int[][] bikes) {
        int n = workers.length;
    PriorityQueue<int[]> q = new PriorityQueue<int[]>((a, b) -> {
      if (a[0] == b[0]) {
        if (a[1] == b[1]) {
          return a[2] - b[2];
        } else {
          return a[1] - b[1];
        }
      } else {
        return a[0] - b[0];
      }
    });

    for (int i = 0; i < workers.length; i++) {
      int[] worker = workers[i];
      for (int j = 0; j < bikes.length; j++) {
        int[] bike = bikes[j];
        int dist = Math.abs(bike[0] - worker[0]) + Math.abs(bike[1] - worker[1]);
        q.add(new int[]{dist, i, j});
      }
    }

    int[] res = new int[n];
    Arrays.fill(res, -1);

    Set<Integer> bikeAssigned = new HashSet<>();
    while (bikeAssigned.size() < n) {
      int[] workerAndBikePair = q.poll();
      int workerId = workerAndBikePair[1];
      int bikeId = workerAndBikePair[2];
      if (res[workerId] == -1
         && !bikeAssigned.contains(bikeId)) {
        res[workerId] = bikeId;
        bikeAssigned.add(bikeId);
      }
    }

    return res;
  }
}

PreviousSort Algorithm Next969.Pancake-Sorting

Last updated 4 years ago

Was this helpful?

题目描述

On a campus represented as a 2D grid, there are N workers and M bikes, with N <= M. Each worker and bike is a 2D coordinate on this grid.

Our goal is to assign a bike to each worker. Among the available bikes and workers, we choose the (worker, bike) pair with the shortest Manhattan distance between each other, and assign the bike to that worker. (If there are multiple (worker, bike) pairs with the same shortest Manhattan distance, we choose the pair with the smallest worker index; if there are multiple ways to do that, we choose the pair with the smallest bike index). We repeat this process until there are no available workers.

The Manhattan distance between two points p1 and p2 is Manhattan(p1, p2) = |p1.x - p2.x| + |p1.y - p2.y|.

Return a vector ans of length N, where ans[i] is the index (0-indexed) of the bike that the i-th worker is assigned to.

Example 1:
Input: workers = [[0,0],[2,1]], bikes = [[1,2],[3,3]]
Output: [1,0]
Explanation: 
Worker 1 grabs Bike 0 as they are closest (without ties), and Worker 0 is assigned Bike 1. So the output is [1, 0].

Example 2:
Input: workers = [[0,0],[1,1],[2,0]], bikes = [[1,0],[2,2],[2,1]]
Output: [0,2,1]
Explanation: 
Worker 0 grabs Bike 0 at first. Worker 1 and Worker 2 share the same distance to Bike 2, thus Worker 1 is assigned to Bike 2, and Worker 2 will take Bike 1. So the output is [0,2,1].

Note:
0 <= workers[i][j], bikes[i][j] < 1000
All worker and bike locations are distinct.
1 <= workers.length <= bikes.length <= 1000

代码

Approach #1

class Solution {
  public int[] assignBikes(int[][] workers, int[][] bikes) {
        int n = workers.length;
    PriorityQueue<int[]> q = new PriorityQueue<int[]>((a, b) -> {
      if (a[0] == b[0]) {
        if (a[1] == b[1]) {
          return a[2] - b[2];
        } else {
          return a[1] - b[1];
        }
      } else {
        return a[0] - b[0];
      }
    });

    for (int i = 0; i < workers.length; i++) {
      int[] worker = workers[i];
      for (int j = 0; j < bikes.length; j++) {
        int[] bike = bikes[j];
        int dist = Math.abs(bike[0] - worker[0]) + Math.abs(bike[1] - worker[1]);
        q.add(new int[]{dist, i, j});
      }
    }

    int[] res = new int[n];
    Arrays.fill(res, -1);

    Set<Integer> bikeAssigned = new HashSet<>();
    while (bikeAssigned.size() < n) {
      int[] workerAndBikePair = q.poll();
      int workerId = workerAndBikePair[1];
      int bikeId = workerAndBikePair[2];
      if (res[workerId] == -1
         && !bikeAssigned.contains(bikeId)) {
        res[workerId] = bikeId;
        bikeAssigned.add(bikeId);
      }
    }

    return res;
  }
}