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Given two integers n and k, find how many different arrays consist of numbers from 1 to n such that there are exactly k inverse pairs.
n
k
1
We define an inverse pair as following: For ith and jth element in the array, if i < j and a[i] > a[j] then it's an inverse pair; Otherwise, it's not.
ith
jth
i
j
a[i]
a[j]
Since the answer may very large, the answer should be modulo 109 + 7.
Example 1:
Input: n = 3, k = 0 Output: 1 Explanation: Only the array [1,2,3] which consists of numbers from 1 to 3 has exactly 0 inverse pair.
Example 2:
Input: n = 3, k = 1 Output: 2 Explanation: The array [1,3,2] and [2,1,3] have exactly 1 inverse pair.
Note:
这道题给了我们1到n总共n个数字,让我们任意排列数组的顺序,使其刚好存在k个翻转对,所谓的翻转对,就是位置在前面的数字值大,而且题目中表明了结果会很大很大,要我们对一个很大的数字取余。对于这种结果巨大的题目,劝君放弃暴力破解或者是无脑递归,想都不用想,那么最先应该考虑的就是DP的解法了。我们需要一个二维的DP数组,其中dp[i][j]表示1到i的数字中有j个翻转对的排列总数,那么我们要求的就是dp[n][k]了,即1到n的数字中有k个翻转对的排列总数。现在难点就是要求递推公式了。我们想如果我们已经知道dp[n][k]了,怎么求dp[n+1][k],先来看dp[n+1][k]的含义,是1到n+1点数字中有k个翻转对的个数,那么实际上在1到n的数字中的某个位置加上了n+1这个数,为了简单起见,我们先让n=4,那么实际上相当于要在某个位置加上5,那么加5的位置就有如下几种情况:
xxxx5
xxx5x
xx5xx
x5xxx
5xxxx
这里xxxx表示1到4的任意排列,那么第一种情况xxxx5不会增加任何新的翻转对,因为xxxx中没有比5大的数字,而 xxx5x会新增加1个翻转对,xx5xx,x5xxx,5xxxx分别会增加2,3,4个翻转对。那么xxxx5就相当于dp[n][k],即dp[4][k],那么依次往前类推,就是dp[n][k-1], dp[n][k-2]...dp[n][k-n],这样我们就可以得出dp[n+1][k]的求法了:
dp[n+1][k] = dp[n][k] + dp[n][k-1] + ... + dp[n][k - n]
那么dp[n][k]的求法也就一目了然了:
dp[n][k] = dp[n - 1][k] + dp[n - 1][k-1] + ... + dp[n - 1][k - n + 1]
那么我们就可以写出代码如下了:
解法一:
class Solution { public: int kInversePairs(int n, int k) { int M = 1000000007; vector<vector<int>> dp(n + 1, vector<int>(k + 1, 0)); dp[0][0] = 1; for (int i = 0; i <= n; ++i) { for (int j = 0; j < i; ++j) { for (int m = 0; m <= k; ++m) { if (m - j >= 0 && m - j <= k) { dp[i][m] = (dp[i][m] + dp[i - 1][m - j]) % M; } } } } return dp[n][k]; } };
我们可以对上面的解法进行时间上的优化,还是来看我们的递推公式:
我们可以用k+1代替k,得到:
dp[n][k+1] = dp[n - 1][k+1] + dp[n - 1][k] + ... + dp[n - 1][k + 1 - n + 1]
用第二个等式减去第一个等式可以得到:
dp[n][k+1] = dp[n][k] + dp[n - 1][k+1] - dp[n - 1][k - n + 1]
将k+1换回成k,可以得到:
dp[n][k] = dp[n][k-1] + dp[n - 1][k] - dp[n - 1][k - n]
我们可以发现当k>=n的时候,最后一项的数组坐标才能为非负数,从而最后一项才有值,所以我们再更新的时候只需要判断一下k和n的关系,如果k>=n的话,就要减去最后一项,这种递推式算起来更高效,减少了一个循环,参见代码如下:
解法二:
class Solution { public: int kInversePairs(int n, int k) { int M = 1000000007; vector<vector<int>> dp(n + 1, vector<int>(k + 1, 0)); dp[0][0] = 1; for (int i = 1; i <= n; ++i) { dp[i][0] = 1; for (int j = 1; j <= k; ++j) { dp[i][j] = (dp[i - 1][j] + dp[i][j - 1]) % M; if (j >= i) { dp[i][j] = (dp[i][j] - dp[i - 1][j - i] + M) % M; } } } return dp[n][k]; } };
参考资料:
https://discuss.leetcode.com/topic/93815/java-dp-o-nk-solution/2
https://discuss.leetcode.com/topic/93765/shared-my-c-o-n-k-solution-with-explanation
LeetCode All in One 题目讲解汇总(持续更新中...)
The text was updated successfully, but these errors were encountered:
No branches or pull requests
Given two integers
n
andk
, find how many different arrays consist of numbers from1
ton
such that there are exactlyk
inverse pairs.We define an inverse pair as following: For
ith
andjth
element in the array, ifi
<j
anda[i]
>a[j]
then it's an inverse pair; Otherwise, it's not.Since the answer may very large, the answer should be modulo 109 + 7.
Example 1:
Example 2:
Note:
n
is in the range [1, 1000] andk
is in the range [0, 1000].这道题给了我们1到n总共n个数字,让我们任意排列数组的顺序,使其刚好存在k个翻转对,所谓的翻转对,就是位置在前面的数字值大,而且题目中表明了结果会很大很大,要我们对一个很大的数字取余。对于这种结果巨大的题目,劝君放弃暴力破解或者是无脑递归,想都不用想,那么最先应该考虑的就是DP的解法了。我们需要一个二维的DP数组,其中dp[i][j]表示1到i的数字中有j个翻转对的排列总数,那么我们要求的就是dp[n][k]了,即1到n的数字中有k个翻转对的排列总数。现在难点就是要求递推公式了。我们想如果我们已经知道dp[n][k]了,怎么求dp[n+1][k],先来看dp[n+1][k]的含义,是1到n+1点数字中有k个翻转对的个数,那么实际上在1到n的数字中的某个位置加上了n+1这个数,为了简单起见,我们先让n=4,那么实际上相当于要在某个位置加上5,那么加5的位置就有如下几种情况:
xxxx5
xxx5x
xx5xx
x5xxx
5xxxx
这里xxxx表示1到4的任意排列,那么第一种情况xxxx5不会增加任何新的翻转对,因为xxxx中没有比5大的数字,而 xxx5x会新增加1个翻转对,xx5xx,x5xxx,5xxxx分别会增加2,3,4个翻转对。那么xxxx5就相当于dp[n][k],即dp[4][k],那么依次往前类推,就是dp[n][k-1], dp[n][k-2]...dp[n][k-n],这样我们就可以得出dp[n+1][k]的求法了:
dp[n+1][k] = dp[n][k] + dp[n][k-1] + ... + dp[n][k - n]
那么dp[n][k]的求法也就一目了然了:
dp[n][k] = dp[n - 1][k] + dp[n - 1][k-1] + ... + dp[n - 1][k - n + 1]
那么我们就可以写出代码如下了:
解法一:
我们可以对上面的解法进行时间上的优化,还是来看我们的递推公式:
dp[n][k] = dp[n - 1][k] + dp[n - 1][k-1] + ... + dp[n - 1][k - n + 1]
我们可以用k+1代替k,得到:
dp[n][k+1] = dp[n - 1][k+1] + dp[n - 1][k] + ... + dp[n - 1][k + 1 - n + 1]
用第二个等式减去第一个等式可以得到:
dp[n][k+1] = dp[n][k] + dp[n - 1][k+1] - dp[n - 1][k - n + 1]
将k+1换回成k,可以得到:
dp[n][k] = dp[n][k-1] + dp[n - 1][k] - dp[n - 1][k - n]
我们可以发现当k>=n的时候,最后一项的数组坐标才能为非负数,从而最后一项才有值,所以我们再更新的时候只需要判断一下k和n的关系,如果k>=n的话,就要减去最后一项,这种递推式算起来更高效,减少了一个循环,参见代码如下:
解法二:
参考资料:
https://discuss.leetcode.com/topic/93815/java-dp-o-nk-solution/2
https://discuss.leetcode.com/topic/93765/shared-my-c-o-n-k-solution-with-explanation
LeetCode All in One 题目讲解汇总(持续更新中...)
The text was updated successfully, but these errors were encountered: