[Swift]LeetCode995. K 连续位的最小翻转次数 | Minimum Number of K Consecutive Bit Flips
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In an array A containing only 0s and 1s, a K-bit flip consists of choosing a (contiguous) subarray of length K and simultaneously changing every 0 in the subarray to 1, and every 1 in the subarray to 0.
Return the minimum number of K-bit flips required so that there is no 0 in the array. If it is not possible, return -1.
Example 1:
Input: A = [0,1,0], K = 1
Output: 2
Explanation: Flip A[0], then flip A[2].
Example 2:
Input: A = [1,1,0], K = 2
Output: -1
Explanation: No matter how we flip subarrays of size 2, we can't make the array become [1,1,1].
Example 3:
Input: A = [0,0,0,1,0,1,1,0], K = 3
Output: 3
Explanation:
Flip A[0],A[1],A[2]: A becomes [1,1,1,1,0,1,1,0]
Flip A[4],A[5],A[6]: A becomes [1,1,1,1,1,0,0,0]
Flip A[5],A[6],A[7]: A becomes [1,1,1,1,1,1,1,1]
Note:
1 <= A.length <= 300001 <= K <= A.length
在仅包含 0 和 1 的数组 A 中,一次 K 位翻转包括选择一个长度为 K的(连续)子数组,同时将子数组中的每个 0 更改为 1,而每个 1 更改为 0。
返回所需的 K 位翻转的次数,以便数组没有值为 0 的元素。如果不可能,返回 -1。
示例 1:
输入:A = [0,1,0], K = 1 输出:2 解释:先翻转 A[0],然后翻转 A[2]。
示例 2:
输入:A = [1,1,0], K = 2 输出:-1 解释:无论我们怎样翻转大小为 2 的子数组,我们都不能使数组变为 [1,1,1]。
示例 3:
输入:A = [0,0,0,1,0,1,1,0], K = 3 输出:3 解释: 翻转 A[0],A[1],A[2]: A变成 [1,1,1,1,0,1,1,0] 翻转 A[4],A[5],A[6]: A变成 [1,1,1,1,1,0,0,0] 翻转 A[5],A[6],A[7]: A变成 [1,1,1,1,1,1,1,1]
提示:
1 <= A.length <= 300001 <= K <= A.length
1 class Solution { 2 func minKBitFlips(_ A: [Int], _ K: Int) -> Int { 3 var ans:Int = 0 4 var n:Int = A.count 5 var f:[Bool] = [Bool](repeating:false,count:n + 1) 6 var sum:Bool = false 7 for i in 0..<n 8 { 9 //异或 10 sum = (sum == f[i]) ? false : true 11 if sum == (A[i] == 1) 12 { 13 if i + K > n {return -1} 14 f[i + K] = !f[i + K] 15 sum = !sum 16 ans += 1 17 } 18 } 19 return ans 20 } 21 }
744ms
1 class Solution { 2 func minKBitFlips(_ A: [Int], _ K: Int) -> Int { 3 var left = 0 4 var flips = 0 5 var totalFlips = 0 6 var a = A 7 8 while left < a.count { 9 totalFlips = left < K ? totalFlips : totalFlips - a[left - K ] 10 11 if totalFlips % 2 == 0 && a[left] == 0 { 12 if left > a.count - K { 13 return -1 14 } 15 flips += 1 16 totalFlips += 1 17 a[left] = 1 18 } else if totalFlips % 2 == 1 && a[left] == 1 { 19 if left > a.count - K { 20 return -1 21 } 22 23 flips += 1 24 totalFlips += 1 25 a[left] = 1 26 } else { 27 a[left] = 0 28 } 29 30 left += 1 31 } 32 33 return flips 34 } 35 }
748ms
1 class Solution { 2 func minKBitFlips(_ A: [Int], _ K: Int) -> Int { 3 var A = A 4 var count = 0 5 var i = 0 6 var flipHint = A.map { _ in false } 7 var flipped = false 8 while i < A.count { 9 if flipHint[i] == true { 10 flipped.toggle() 11 } 12 13 if A[i] == (flipped ? 1 : 0) { 14 flipped.toggle() 15 if i + K < A.count { 16 flipHint[i+K] = true 17 } else if i + K > A.count { 18 return -1 19 } 20 count += 1 21 } 22 i += 1 23 } 24 return count 25 } 26 }
900ms
1 class Solution { 2 func minKBitFlips(_ A: [Int], _ K: Int) -> Int { 3 var count = 0, firstIndex = 0, A = A 4 var lastFlip: [Int] = [] 5 6 while firstIndex < A.count { 7 defer { firstIndex += 1 } 8 9 if let first = lastFlip.first, 10 firstIndex >= first { 11 lastFlip.removeFirst() 12 } 13 14 guard (A[firstIndex] + lastFlip.count) % 2 == 0 else { 15 continue 16 } 17 if firstIndex + K > A.endIndex { 18 return -1 19 } else { 20 lastFlip.append(firstIndex + K) 21 count += 1 22 } 23 } 24 25 return count 26 } 27 }
