LeetCode 1024. Video Stitching
原题链接在这里:https://leetcode.com/problems/video-stitching/
题目:
You are given a series of video clips from a sporting event that lasted T
seconds. These video clips can be overlapping with each other and have varied lengths.
Each video clip clips[i]
is an interval: it starts at time clips[i][0]
and ends at time clips[i][1]
. We can cut these clips into segments freely: for example, a clip [0, 7]
can be cut into segments [0, 1] + [1, 3] + [3, 7]
.
Return the minimum number of clips needed so that we can cut the clips into segments that cover the entire sporting event ([0, T]
). If the task is impossible, return -1
.
Example 1:
Input: clips = [[0,2],[4,6],[8,10],[1,9],[1,5],[5,9]], T = 10
Output: 3
Explanation:
We take the clips [0,2], [8,10], [1,9]; a total of 3 clips.
Then, we can reconstruct the sporting event as follows:
We cut [1,9] into segments [1,2] + [2,8] + [8,9].
Now we have segments [0,2] + [2,8] + [8,10] which cover the sporting event [0, 10].
Example 2:
Input: clips = [[0,1],[1,2]], T = 5
Output: -1
Explanation:
We can't cover [0,5] with only [0,1] and [0,2].
Example 3:
Input: clips = [[0,1],[6,8],[0,2],[5,6],[0,4],[0,3],[6,7],[1,3],[4,7],[1,4],[2,5],[2,6],[3,4],[4,5],[5,7],[6,9]], T = 9
Output: 3
Explanation:
We can take clips [0,4], [4,7], and [6,9].
Example 4:
Input: clips = [[0,4],[2,8]], T = 5
Output: 2
Explanation:
Notice you can have extra video after the event ends.
Note:
1 <= clips.length <= 100
0 <= clips[i][0], clips[i][1] <= 100
0 <= T <= 100
题解:
Could sort the clips based on starting time.
For each step, go through all the clips having starting time <= current start time, get to the furtherest.
if furtherest doesn't change, start == end, that means there is a gap. return -1.
Otherwise, update start to end and increment res.
End as soon as current furtherest reaches T.
Time Complexity: O(nlogn). n = clips.length.
Space: O(1).
AC Java:
1 class Solution { 2 public int videoStitching(int[][] clips, int T) { 3 if(clips == null || clips.length == 0 || clips[0].length != 2 || T <= 0){ 4 return -1; 5 } 6 7 Arrays.sort(clips, (a, b) -> a[0] - b[0]); 8 9 int start = 0; 10 int end = 0; 11 int res = 0; 12 int i = 0; 13 while(end < T){ 14 while(i<clips.length && clips[i][0] <= start){ 15 end = Math.max(end, clips[i][1]); 16 i++; 17 } 18 19 if(start == end){ 20 return -1; 21 } 22 23 start = end; 24 res++; 25 } 26 27 return res; 28 } 29 }
Let dp[i] denotes minimum number of clips needed to cover up to i.
For each clip, if clip[0] <= i <= clip[1], then i could be covered using minimum clips covered up to clip[0] plus this clip.
Update dp[i].
Check if dp[T] is never updated. If it is never updated, then return -1.
Time Complexity: O(nT). n = clips.length.
Space: O(T).
AC Java:
1 class Solution { 2 public int videoStitching(int[][] clips, int T) { 3 int [] dp = new int[T+1]; 4 dp[0] = 0; 5 6 for(int i = 1; i<=T; i++){ 7 dp[i] = T+1; 8 for(int [] clip : clips){ 9 if(clip[0]<=i && clip[1]>=i){ 10 dp[i] = Math.min(dp[i], dp[clip[0]]+1); 11 } 12 } 13 } 14 15 return dp[T] == T+1 ? -1 : dp[T]; 16 } 17 }