LeetCode-in-Java

1654. Minimum Jumps to Reach Home

Medium

A certain bug’s home is on the x-axis at position x. Help them get there from position 0.

The bug jumps according to the following rules:

The bug may jump forward beyond its home, but it cannot jump to positions numbered with negative integers.

Given an array of integers forbidden, where forbidden[i] means that the bug cannot jump to the position forbidden[i], and integers a, b, and x, return the minimum number of jumps needed for the bug to reach its home. If there is no possible sequence of jumps that lands the bug on position x, return -1.

Example 1:

Input: forbidden = [14,4,18,1,15], a = 3, b = 15, x = 9

Output: 3

Explanation: 3 jumps forward (0 -> 3 -> 6 -> 9) will get the bug home.

Example 2:

Input: forbidden = [8,3,16,6,12,20], a = 15, b = 13, x = 11

Output: -1

Example 3:

Input: forbidden = [1,6,2,14,5,17,4], a = 16, b = 9, x = 7

Output: 2

Explanation: One jump forward (0 -> 16) then one jump backward (16 -> 7) will get the bug home.

Constraints:

Solution

import java.util.LinkedList;
import java.util.Queue;

public class Solution {
    private static class Pair {
        int i;
        boolean backward;

        public Pair(int i, boolean b) {
            this.i = i;
            this.backward = b;
        }
    }

    public int minimumJumps(int[] forbidden, int a, int b, int x) {
        int limit = 2000 + 2 * b + 1;
        boolean[] v = new boolean[limit];
        for (int num : forbidden) {
            v[num] = true;
        }
        int step = 0;
        Queue<Pair> q = new LinkedList<>();
        q.add(new Pair(0, false));
        v[0] = true;
        while (!q.isEmpty()) {
            int size = q.size();
            for (int i = 0; i < size; i++) {
                Pair c = q.poll();
                if (c.i == x) {
                    return step;
                }
                if (!c.backward) {
                    int backward = c.i - b;
                    if (backward == x) {
                        return step + 1;
                    }
                    if (backward > 0 && !v[backward]) {
                        q.offer(new Pair(backward, true));
                        v[backward] = true;
                    }
                }
                int forward = c.i + a;
                if (forward == x) {
                    return step + 1;
                }
                if (forward < limit && !v[forward]) {
                    q.offer(new Pair(forward, false));
                    v[forward] = true;
                }
            }
            step++;
        }
        return -1;
    }
}