Problem:
Given an array of non-negative integers, you are initially positioned at the first index of the array.
Each element in the array represents your maximum jump length at that position.
Your goal is to reach the last index in the minimum number of jumps.
For example:
Given array A = [2,3,1,1,4]
The minimum number of jumps to reach the last index is 2. (Jump 1 step from index 0 to 1, then 3 steps to the last index.)
Anaslysis:
This is also a dynamic problem. It reminds you there could be good and bad dynamic algorithm. Once you feel like something was repeatedly done. Yous should try a better solution to solve it. Solution 1: This idea is instant, and suitable for my thinking habit, but it is really not efficient. Basic idea: Use a array to record the minimum steps required to reach a element. Then we use following function to update on it. ------------------------------------------------------------- for (int j = 1; j <= nums[i]; j++) { if (i+j < len) { nums[i+j] = Math.min(nums[i]+1, nums[i+j]); } } -------------------------------------------------------------
Solution 1:
public class Solution { public int jump(int[] nums) { if (nums == null) throw new IllegalArgumentException("nums is null!"); int len = nums.length; if (len <= 1) return 0; int[] min = new int[len]; Arrays.fill(min, Integer.MAX_VALUE); min[0] = 0; for (int i = 0; i < len; i++) { for (int j = 1; j <= nums[i]; j++) { if (i+j < len) { min[i+j] = Math.min(min[i]+1, min[i+j]); } } } return min[len - 1]; } }
Upgraded analysis:
Time Limit Exceeded Even the idea of above solution is right, but there are repeates in computing. We know: iff i < j, the steps to reach i must no greater than j. step[i] <= step[j] Reason: once we could reach step[j], we must be able to reach step[i] (just fewer steps) Thus if we have already reached step[j] from step[i], we should we test iff we could use step[i+1] to reach step[j]. The only thing we should take care, iff step[i+1] could help us to reach further elements! The update solution: We should two window for this problem, latest reach: the maximum element we could reach from previous window's elements.(previous step) reach: the maimum element we could reach from current window. (current step) {[1]}, {[2]}, { [1] [3] }, {[2] [4] [5]} 0 1 2 3 4 5 6 For example: at step 0, our latest reach is 0 (the current element), after scan the [1] element in the window, the reach becomes 1, which means we can reach element nums[1]. We Keep the above invariant to update our next reach window throw latest reach window(current). reach = Math.max(reach, nums[i] + i); But reach is for next window, once we enter the elements at reach window, it means we have to use one step to achieve it. Thus we have following code for this purpose. for (int i = 0; i <= reach && i < len; i++) { if (i > last_reach) { step ++; last_reach = reach; } ... } Note: we count the step, only when we need to enter the window. (reach nums[i]) Also Note: the checking codition for the for loop, if i exceed the maximum range of reach, it means there is no path. We should stop at here.
Solution 2:
public class Solution { public int jump(int[] nums) { if (nums == null) throw new IllegalArgumentException("nums is null!"); int len = nums.length; if (len <= 1) return 0; int last_reach = 0; int step = 0; int reach = 0; for (int i = 0; i <= reach && i < len; i++) { if (i > last_reach) { step ++; last_reach = reach; } reach = Math.max(reach, nums[i] + i); } return (reach >= nums.length - 1) ? step : 0; } }