所有对的绝对差之和 K 次幂

给定一个由N 个整数组成的数组 arr[]和一个数字K ，任务是找到给定数组中所有对的 K 次幂的绝对差之和，即， $\sum_{i=1}^{N} \sum_{j=1}^{N} \ |arr[i]-arr[j]|^K$ .
例子：

Input: arr[] = {1, 2, 3}, K = 1
Output: 8
Explanation:
Sum of |1-1|+|1-2|+|1-3|+|2-1|+|2-2|+|2-3|+|3-1|+|3-2|+|3-3| = 8
Input: arr[] = {1, 2, 3}, K = 3
Output: 20
Explanation:
Sum of |1 – 1| ³ + |1 – 2| ³ + |1 – 3| ³ + |2 – 1| ³ + |2 – 2|³ + |2 – 3|³ + |3 – 1|³ + |3 – 2|³ + |3 – 3|³ = 20

编程需要懂一点英语

朴素方法：这个想法是生成所有可能的对，并找到每对的绝对差值的K 次幂，然后将它们相加。
时间复杂度： O((log K)*N ² )
辅助空间： O(1)
高效方法：我们可以通过以下计算来提高朴素方法的时间复杂度：
对于所有可能的对，我们必须找到

$Sum = \sum_{i=1}^{N} \sum_{j=1}^{N} |arr[i] - arr[j]|^{K}$

编程需要懂一点英语

由于对 (arr[i], arr[j]) 的值 $|arr[i]-arr[j]|^{K}$ 被计算两次。所以上面的方程也可以写成：

$Sum = 2 * \sum_{i=1}^{N} \sum_{j=1}^{i-1} |arr[i] - arr[j]|^{K}$

编程需要懂一点英语

写作 $|arr[i]-arr[j]|^{K}$ 在二项式方程方面：

$Sum = 2 * \sum_{i=1}^{N} \sum_{j=1}^{i-1} \sum_{a=0}^{K} \binom{K}{a}arr[i]^{K}*(-arr[j])^{K - a}$ (Equation 1)

编程需要懂一点英语

让 Pre[i][a] = $\sum_{j=1}^{i-1}(-arr[j])^{K - a}$ (等式 2)
从方程 1 和方程 2，我们有

$Sum = 2 * \sum_{i=1}^{N} \sum_{a=0}^{K} \binom{K}{a}Pre[i][a]*arr[i]^{K}$

编程需要懂一点英语

Pre[i][a] 的值可以计算为：

Pre[i][a] = {(-arr[1])^{K – a} + (-arr[2])^{K – a} … . . +(-arr[i – 1])^{K – a}}.
So, Pre[i+1][a] = Pre[i][a]+(-arr[i])^{K – a}

编程需要懂一点英语

下面是上述方法的实现：

C++

// C++ program for the above approach
 
#include 
#define ll long long
using namespace std;
 
class Solution {
 
public:
    // Since K can be 100 max
    ll ncr[101][101];
    int n, k;
    vector A;
 
    // Constructor
    Solution(int N, int K, vector B)
    {
        // Initializing with -1
        memset(ncr, -1, sizeof(ncr));
 
        n = N;
        k = K;
        A = B;
 
        // Making vector A as 1-Indexing
        A.insert(A.begin(), 0);
    }
 
    ll f(int N, int K);
 
    ll pairsPower();
};
 
// To Calculate the value nCk
ll Solution::f(int n, int k)
{
    if (k == 0)
        return 1LL;
 
    if (n == k)
        return 1LL;
 
    if (n < k)
        return 0;
 
    if (ncr[n][k] != -1)
        return ncr[n][k];
 
    // Since nCj = (n-1)Cj + (n-1)C(j-1);
    return ncr[n][k] = f(n - 1, k)
                       + f(n - 1, k - 1);
}
 
// Function that summation of absolute
// differences of all pairs raised
// to the power k
ll Solution::pairsPower()
{
    ll pre[n + 1][k + 1];
    ll ans = 0;
 
    // Sort the given array
    sort(A.begin() + 1, A.end());
 
    // Precomputation part, O(n*k)
    for (int i = 1; i <= n; ++i) {
        pre[i][0] = 1LL;
 
        for (int j = 1; j <= k; j++) {
            pre[i][j] = A[i]
                        * pre[i][j - 1];
        }
 
        if (i != 1) {
            for (int j = 0; j <= k; ++j)
                pre[i][j] = pre[i][j]
                            + pre[i - 1][j];
        }
    }
 
    // Traverse the array arr[]
    for (int i = n; i >= 2; --i) {
 
        // For each K
        for (int j = 0; j <= k; j++) {
 
            ll val = f(k, j);
 
            ll val1 = pow(A[i], k - j)
                      * pre[i - 1][j];
 
            val = val * val1;
 
            if (j % 2 == 0)
                ans = (ans + val);
 
            else
                ans = (ans - val);
        }
    }
 
    ans = 2LL * ans;
 
    // Return the final answer
    return ans;
}
 
// Driver Code
int main()
{
    // Given N and K
    int N = 3;
    int K = 3;
 
    // Given array
    vector arr = { 1, 2, 3 };
 
    // Creation of Object of class
    Solution obj(N, K, arr);
 
    // Function Call
    cout << obj.pairsPower() << endl;
    return 0;
}

Python3

# Python3 program for the above approach
class Solution:
     
    def __init__(self, N, K, B):
 
        self.ncr = []
         
        # Since K can be 100 max
        for i in range(101):
            temp = []
            for j in range(101):
                 
                # Initializing with -1
                temp.append(-1)
                 
            self.ncr.append(temp)
 
        self.n = N
        self.k = K
 
        # Making vector A as 1-Indexing
        self.A = [0] + B
 
    # To Calculate the value nCk
    def f(self, n, k):
         
        if k == 0:
            return 1
        if n == k:
            return 1
        if n < k:
            return 0
             
        if self.ncr[n][k] != -1:
            return self.ncr[n][k]
 
        # Since nCj = (n-1)Cj + (n-1)C(j-1);
        self.ncr[n][k] = (self.f(n - 1, k) +
                          self.f(n - 1, k - 1))
                           
        return self.ncr[n][k]
 
    # Function that summation of absolute
    # differences of all pairs raised
    # to the power k
    def pairsPower(self):
         
        pre = []
         
        for i in range(self.n + 1):
            temp = []
            for j in range(self.k + 1):
                temp.append(0)
                 
            pre.append(temp)
 
        ans = 0
 
        # Sort the given array
        self.A.sort()
 
        # Precomputation part, O(n*k)
        for i in range(1, self.n + 1):
            pre[i][0] = 1
 
            for j in range(1, self.k + 1):
                pre[i][j] = (self.A[i] *
                                pre[i][j - 1])
 
            if i != 1:
                for j in range(self.k + 1):
                    pre[i][j] = (pre[i][j] +
                                 pre[i - 1][j])
 
        # Traverse the array arr[]
        for i in range(self.n, 1, -1):
             
            # For each K
            for j in range(self.k + 1):
                val = self.f(self.k, j)
                val1 = (pow(self.A[i],
                            self.k - j) *
                             pre[i - 1][j])
 
                val = val * val1
 
                if j % 2 == 0:
                    ans = ans + val
                else:
                    ans = ans - val
 
        ans = 2 * ans
 
        # Return the final answer
        return ans
 
# Driver code
if __name__ == '__main__':
 
    # Given N and K
    N = 3
    K = 3
     
    # Given array
    arr = [ 1, 2, 3 ]
 
    # Creation of object of class
    obj = Solution(N, K, arr)
     
    # Function call
    print(obj.pairsPower())
 
# This code is contributed by Shivam Singh

输出：

时间复杂度： O(N*K)
辅助空间： O(N*K)