zoj 3673 1729

1729


Time Limit: 3 Seconds      Memory Limit: 65536 KB

1729 is the natural number following 1728 and preceding 1730. It is also known as the Hardy-Ramanujan number after a famous anecdote of the British mathematician G. H. Hardy regarding a hospital visit to the Indian mathematician Srinivasa Ramanujan. In Hardy's words:

I remember once going to see him when he was ill at Putney. I had ridden in taxi cab number 1729 and remarked that the number seemed to me rather a dull one, and that I hoped it was not an unfavorable omen. "No," he replied, "it is a very interesting number; it is the smallest number expressible as the sum of two (positive) cubes in two different ways."

The two different ways are these: 1729 = 13 + 123 = 93 + 103

Now your task is to count how many ways a positive number can be expressible as the sum of two positive cubes in. All the numbers in this task can be expressible as the sum of two positive cubes in at least one way.

Input

There're nearly 20,000 cases. Each case is a positive integer in a single line. And all these numbers are greater than 1 and less than 264.

Output

Please refer to the sample output. For each case, you should output a line. First the number of ways n. Then followed by n pairs of integer, (ai,bi), indicating a way the given number can be expressible as the sum of ai's cube and bi's. (aibi, and a1< a2< ...< an)

Sample Input

9
4104
2622104000
21131226514944
48988659276962496

Sample Output

1 (1,2)
2 (2,16) (9,15)
3 (600,1340) (678,1322) (1020,1160)
4 (1539,27645) (8664,27360) (11772,26916) (17176,25232)
5 (38787,365757) (107839,362753) (205292,342952) (221424,336588) (231518,331954)

Hint

Although most numbers cannot be expressible as the sum of two positive cubes, the vast majority of numbers in this task can be expressible as the sum of two positive cubes in two or more ways.

题意:给一个数字N,问有多少中方法组成 a^3+b^3 = N,把每一种情况输出来。

思路:a^3+b^3 = (a^2+b^2-ab)*(a+b) 那么我们就知道(a+b)是N的一个因子。

由此枚举每一个因子。

 #include<iostream>
#include<stdio.h>
#include<cstring>
#include<math.h>
#include<cstdlib>
#include<algorithm>
using namespace std;
typedef unsigned long long LL;
const int maxn = +; struct node
{
LL x,y;
} tom[];
int tlen;
LL prime[];
int len;
bool s[maxn];
void init()
{
memset(s,false,sizeof(s));
len = ;
for(int i=; i<maxn; i++)
if(s[i]==false)
{
prime[++len]=i;
for(int j=i+i; j<maxn; j=j+i)
s[j]=true;
}
}
LL fac[],num[];
int flen;
void Euler(LL n)
{
int i,count;
flen = ;
for(i=; prime[i]*prime[i]<=n; i++)
{
if(n%prime[i]==)
{
count = ;
while(n%prime[i]==)
{
n=n/prime[i];
count++;
}
fac[++flen]=prime[i];
num[flen]=count;
}
}
if(n!=)
{
fac[++flen]=n;
num[flen]=;
}
} LL Q[];
int qlen;
void solve()
{
Q[]=;
qlen = ;
for(int i=; i<=flen; i++)
{
int k;
int s=;
for(int j=; j<=num[i]; j++)
{
k = qlen;
for(; s<=k; s++)
Q[++qlen]=Q[s]*fac[i];
}
}
}
int main()
{
LL n;
int T=;
init();
while(scanf("%llu",&n)>)
{
Euler(n);
solve();
sort(Q+,Q++qlen);
tlen=;
int NUM=;
for(int i=; i<=qlen; i++)
{
LL y = (Q[i]*Q[i]-n/Q[i])/;
LL x = Q[i];
if(x*x>=*y)
{
LL ss = (LL)sqrt((x*x-*y)*1.0);
LL ans1 = (x-ss)/;
LL ans2 = (x+ss)/;
if(ans1==||ans2==)continue;
if(ans1*ans1*ans1+ans2*ans2*ans2==n)
{
tom[++tlen].x=ans1;
tom[tlen].y=ans2;
NUM++;
}
}
}
printf("%d",NUM);
for(int i=; i<=tlen; i++)
printf(" (%llu,%llu)",tom[i].x,tom[i].y);
printf("\n");
}
return ;
}
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