6073 Math Magic
Yesterday, my teacher taught us about math: +, -, *, /, GCD, LCM... As you know, LCM (Least
common multiple) of two positive numbers can be solved easily because of
a ∗ b = GCD(a, b) ∗ LCM(a, b)
In class, I raised a new idea: ”how to calculate the LCM of K numbers”. It’s also an easy problem
indeed, which only cost me 1 minute to solve it. I raised my hand and told teacher about my outstanding
algorithm. Teacher just smiled and smiled ...
After class, my teacher gave me a new problem and he wanted me solve it in 1 minute, too. If we
know three parameters N, M, K, and two equations:
1. SUM(A1, A2, . . . , Ai, Ai+1, . . . , AK) = N
2. LCM(A1, A2, . . . , Ai, Ai+1, . . . , AK) = M
Can you calculate how many kinds of solutions are there for Ai (Ai are all positive numbers). I
began to roll cold sweat but teacher just smiled and smiled.
Can you solve this problem in 1 minute?
Input
There are multiple test cases.
Each test case contains three integers N, M, K. (1 ≤ N, M ≤ 1, 000, 1 ≤ K ≤ 100)
Output
For each test case, output an integer indicating the number of solution modulo 1,000,000,007(1e9 + 7).
You can get more details in the sample and hint below.
Hint:
The first test case: the only solution is (2, 2).
The second test case: the solution are (1, 2) and (2, 1).
Sample Input
4 2 2
3 2 2
Sample Output
1
2
//今天算是长见识了,纠结,看了大神的代码,才知道用dp
//dp[k][n][m]表示由k个数组成的和为n,最小公倍数为m的情况总数 #include <iostream>
#include <cstdio>
#include <cstring>
#include <algorithm>
using namespace std;
const int maxn = ;
const int mod = ;
int n, m, k;
int lcm[maxn][maxn];
int dp[][maxn][maxn];
int fact[maxn], cnt; int GCD(int a, int b)
{
return b==?a:GCD(b, a%b);
} int LCM(int a, int b)
{
return a / GCD(a,b) * b;
} void init()
{
for(int i = ; i <=; i++)
for(int j = ; j<=i; j++)
lcm[j][i] = lcm[i][j] = LCM(i, j);
} void solve()
{
cnt = ;
for(int i = ; i<=m; i++)
if(m%i==) fact[cnt++] = i; int now = ;
memset(dp[now], , sizeof(dp[now]));
for(int i = ; i<cnt; i++)
dp[now][fact[i]][fact[i]] = ; for(int i = ; i<k; i++)
{
now ^= ;
for(int p=; p<=n; p++)
for(int q=; q<cnt; q++)
{
dp[now][p][fact[q]] = ;
} for(int p=; p<=n; p++)
{
for(int q=; q<cnt; q++)
{
if(dp[now^][p][fact[q]]==) continue;
for(int j=; j<cnt; j++)
{
int now_sum = p + fact[j];
if(now_sum>n) continue;
int now_lcm = lcm[fact[q]][fact[j]];
dp[now][now_sum][now_lcm] += dp[now^][p][fact[q]];//
dp[now][now_sum][now_lcm] %= mod;//
}
}
}
}
printf("%d\n",dp[now][n][m]);
} int main()
{
init();
while(scanf("%d%d%d", &n, &m, &k)>)
solve();
return ;
}