组合数学 - 波利亚定理 --- poj : 2154 Color

时间:2023-03-08 18:04:58

Color

Time Limit: 2000MS   Memory Limit: 65536K
Total Submissions: 7873   Accepted: 2565

Description

Beads of N colors are connected together into a circular necklace of N beads (N<=1000000000). Your job is to calculate how many different kinds of the necklace can be produced. You should know that the necklace might not use up all the N colors, and the repetitions that are produced by rotation around the center of the circular necklace are all neglected.

You only need to output the answer module a given number P.

Input

The first line of the input is an integer X (X <= 3500) representing the number of test cases. The following X lines each contains two numbers N and P (1 <= N <= 1000000000, 1 <= P <= 30000), representing a test case.

Output

For each test case, output one line containing the answer.

Sample Input

5

1 30000

2 30000

3 30000

4 30000

5 30000

Sample Output

1

3

11

70

629

Source

POJ Monthly,Lou Tiancheng

Mean:

给你一个包含N个珠子的项链,现在有N种颜色,让你从这N种颜色中选择一些颜色来将这些珠子染色,问可以染出多少种不同的珠子。

analyse:

对于n比较小的情况我们可以直接暴力枚举置换群并统计其对应的C(f),考虑旋转i个珠子的循环群,我们可以证明其对应的不动的染色方案C(fi)=n^gcd(i,n)。为什么呢?我们可以这样考虑,假设珠子编号为0~n-1,对于旋转i个珠子的循环群,由于相邻间的珠子对应的旋转后位置还是相邻,所以这个循环群的环必然是大小相等的。假设其环的大小为T,那么就有(T*i)%n=0。假设T*i=k*n,i=g*x,n=g*y,其中g=gcd(i,n)。那么T=k*y/x,因为k为整数,x、y互质,所以使得T最小且为正整数的k=x,那么T=y,整个循环群中环的个数=n/T=g。所以我们可以得到C(fi)=n^gcd(i,n)。那么这个题目就转化为求sum{n^gcd(i,n)},1<=i<=n。

但是n<=10^9,这个数据范围太大,直接枚举必然超时,我们要考虑优化。观察上面的公式,我们发现虽然i的范围很大,但是gcd(i,n)的值却不多,最多为n的因子的个数。如果我们可以很快求出gcd(i,n)=g时i的个数,那么我们就能够得到一个很高效的算法。假设i=g*x,n=g*y,gcd(i,n)=g的条件为x、y互质,又因为1<=x<=y。所以满足条件的x的个数就是[1,y]里和y互质的数的个数,这就等于phi(y)。欧拉函数的值可以在O(n^(1/2))的复杂度内算出来,于是我们就得到了一个高效的算法。

Time complexity:O(n^(/12))

Source code:

#include <iostream>

#include <cstdio>

#include <cstring>

#include <cmath>

using namespace std;

int n, yu;

const int NN=10000000;

bool v[NN];

int p[NN];

int len=-1;

void make_p()

{

    int i,j;

    for(i=2; i<NN; ++i)

    {

        if(!v[i]) p[++len] = i;

        for(j=0; j<=len && i*p[j] < NN; ++j)

        {

            v[i*p[j]] =1;

            if(i%p[j] == 0) break;

        }

    }

}

int work(int n) {

    int temp = n;

    for (int i = 0; i < len && p[i]*p[i] <= temp; ++i)

    {

        if (temp % p[i] == 0) {

            n -= n/p[i];

            do {

                temp /= p[i];

            }while (temp % p[i] == 0);

        }

    }

    if (temp != 1) {

        n -= n/temp;

    }

    return n%yu;

}

int solve(int m) {

    int ans = 1;

    int s = n%yu;

    int temp = m;

    while (temp > 0) {

        if (temp&1) {

            ans = (ans * s) % yu;

        }

        s = (s*s)%yu;

        temp >>= 1;

    }

    return ans;

}

int main() {

    make_p();

    int t;

    scanf("%d", &t);

    while (t--) {

        scanf("%d %d", &n, &yu);

        int res = 0;

        for (int i = 1; i*i <= n; ++i) {

            if (i*i == n)

            {

                res = (res + work(i)*solve(i-1))%yu;

            }

            else if (n%i == 0)

            {

                res = (res + work(i)*solve(n/i-1) + work(n/i)*solve(i-1))%yu;

            }

        }

        printf("%d\n", res);

    }

    return 0;

}