HDU4869 Turn the pokers(费马小定理+快速幂)
Turn the pokers
Time Limit: 2000/1000 MS (Java/Others) Memory Limit: 32768/32768 K (Java/Others)Total Submission(s): 1847 Accepted Submission(s): 653
Problem Description
During summer vacation,Alice stay at home for a long time, with nothing to do. She went out and bought m pokers, tending to play poker. But she hated the traditional gameplay. She wants to change. She puts these pokers face down, she decided to flip poker n times, and each time she can flip Xi pokers. She wanted to know how many the results does she get. Can you help her solve this problem?
Input
The input consists of multiple test cases.
Each test case begins with a line containing two non-negative integers n and m(0<n,m<=100000).
The next line contains n integers Xi(0<=Xi<=m).
Each test case begins with a line containing two non-negative integers n and m(0<n,m<=100000).
The next line contains n integers Xi(0<=Xi<=m).
Output
Output the required answer modulo 1000000009 for each test case, one per line.
Sample Input
3 4 3 2 3 3 3 3 2 3
Sample Output
8 3HintFor the second example: 0 express face down,1 express face up Initial state 000 The first result:000->111->001->110 The second result:000->111->100->011 The third result:000->111->010->101 So, there are three kinds of results(110,011,101)
Author
FZU
Source
题意:对于m张牌给出n个操作,每次操作选择a[i]张牌进行翻转,问最终得到几个不同的状态。
思路:在n张牌选k张,很容易想到组合数,但是关键是怎么进行组合数计算呢?我们可以发现,在牌数固定的情况下,总共进行了sum次操作的话,其实有很多牌是经过了多次翻转,而每次翻转只有0和1两种状态,那么,奇偶性就出来了,也就是说,无论怎么进行翻牌,最终态无论有几个1,这些1的总数的奇偶性是固定的。
那么我们现在只需要找到最大的1的个数和最小的1的个数,然后再这个区间内进行组合数的求解即可
但是又有一个问题出来了,数据很大,进行除法是一个不明智的选择,但是组合数公式必定有除法
C(n,m) = n! / (m!*(n-m)!)
但是我们知道费马小定理a^(p-1) = 1%p
那么a^(p-1)/a = 1/a%p 得到 a^(p-2) = 1/a%p
发现了吧?这样就把一个整数变成了一个分母!
于是便得到sum+=((f[m]%mod)*(quickmod((f[i]*f[m-i])%mod,mod-2)%mod))%mod
代码 :
#include <iostream>
#include <stdio.h>
#include <string.h>
#include <algorithm>
using namespace std;
#define mod 1000000009
#define LL __int64
#define maxn 100000+5
LL f[maxn];
void set()
{
int i;
f[0] = 1;
for(i = 1; i<maxn; i++)
f[i] = (f[i-1]*i)%mod;
}
LL quickmod(LL a,LL b)
{
LL ans = 1;
while(b)
{
if(b&1)
{
ans = (ans*a)%mod;
b--;
}
b/=2;
a = ((a%mod)*(a%mod))%mod;
}
return ans;
}
int main()
{
int n,m,i,j,k,l,r,x,ll,rr;
set();
while(~scanf("%d%d",&n,&m))
{
l = r = 0;
for(i = 0; i<n; i++)
{
scanf("%d",&x);
//计算最小的1的个数,尽可能多的让1->0
if(l>=x) ll = l-x;//当最小的1个数大于x,把x个1全部翻转
else if(r>=x) ll = ((l%2)==(x%2))?0:1;//当l<x<=r,由于无论怎么翻,其奇偶性必定相等,所以看l的奇偶性与x是否相同,相同那么知道最小必定变为0,否则变为1
else ll = x-r;//当x>r,那么在把1全部变为0的同时,还有x-r个0变为1
//计算最大的1的个数,尽可能多的让0->1
if(r+x<=m) rr = r+x;//当r+x<=m的情况下,全部变为1
else if(l+x<=m) rr = (((l+x)%2) == (m%2)?m:m-1);//在r+x>m但是l+x<=m的情况下,也是判断奇偶,同态那么必定在中间有一种能全部变为1,否则至少有一张必定为0
else rr = 2*m-(l+x);//在l+x>m的情况下,等于我首先把m个1变为了0,那么我还要翻(l+x-m)张,所以最终得到m-(l+x-m)个1
l = ll,r = rr;
printf("l=%d , r=%d\n",l,r);
}
printf("l=%d , r=%d\n",l,r);
LL sum = 0;
for(i = l; i<=r; i+=2)//使用费马小定理和快速幂的方法求和
sum+=((f[m]%mod)*(quickmod((f[i]*f[m-i])%mod,mod-2)%mod))%mod;
printf("%I64d\n",sum%mod);
}
return 0;
}
#include <stdio.h>
#include <string.h>
#include <algorithm>
using namespace std;
#define mod 1000000009
#define LL __int64
#define maxn 100000+5
LL f[maxn];
void set()
{
int i;
f[0] = 1;
for(i = 1; i<maxn; i++)
f[i] = (f[i-1]*i)%mod;
}
LL quickmod(LL a,LL b)
{
LL ans = 1;
while(b)
{
if(b&1)
{
ans = (ans*a)%mod;
b--;
}
b/=2;
a = ((a%mod)*(a%mod))%mod;
}
return ans;
}
int main()
{
int n,m,i,j,k,l,r,x,ll,rr;
set();
while(~scanf("%d%d",&n,&m))
{
l = r = 0;
for(i = 0; i<n; i++)
{
scanf("%d",&x);
//计算最小的1的个数,尽可能多的让1->0
if(l>=x) ll = l-x;//当最小的1个数大于x,把x个1全部翻转
else if(r>=x) ll = ((l%2)==(x%2))?0:1;//当l<x<=r,由于无论怎么翻,其奇偶性必定相等,所以看l的奇偶性与x是否相同,相同那么知道最小必定变为0,否则变为1
else ll = x-r;//当x>r,那么在把1全部变为0的同时,还有x-r个0变为1
//计算最大的1的个数,尽可能多的让0->1
if(r+x<=m) rr = r+x;//当r+x<=m的情况下,全部变为1
else if(l+x<=m) rr = (((l+x)%2) == (m%2)?m:m-1);//在r+x>m但是l+x<=m的情况下,也是判断奇偶,同态那么必定在中间有一种能全部变为1,否则至少有一张必定为0
else rr = 2*m-(l+x);//在l+x>m的情况下,等于我首先把m个1变为了0,那么我还要翻(l+x-m)张,所以最终得到m-(l+x-m)个1
l = ll,r = rr;
printf("l=%d , r=%d\n",l,r);
}
printf("l=%d , r=%d\n",l,r);
LL sum = 0;
for(i = l; i<=r; i+=2)//使用费马小定理和快速幂的方法求和
sum+=((f[m]%mod)*(quickmod((f[i]*f[m-i])%mod,mod-2)%mod))%mod;
printf("%I64d\n",sum%mod);
}
return 0;
}