UVA 10090 Marbles(扩展欧几里得)

时间:2024-06-11 11:34:50

Marbles

Input: standard input

Output: standard output

I have some (say, n) marbles (small glass balls) and I am going to buy some boxes to store them. The boxes are of two types:

Type 1: each box costs c1 Taka and can hold exactly
n1 marbles

Type 2: each box costs c2 Taka and can hold exactly
n2 marbles

I want each of the used boxes to be filled to its capacity and also to minimize the total cost of buying them. Since I find it difficult for me to figure out how to distribute my marbles among the boxes, I seek your help. I want your program to be efficient
also.

Input

The input file may contain multiple test cases. Each test case begins with a line containing the integer n (1 <= n <= 2,000,000,000). The second line contains
c1and n1, and the third line contains
c
2 and n2. Here, c1,
c
2, n1and n2 are all positive integers having values smaller than 2,000,000,000.

A test case containing a zero forn in the first line terminates the input.

Output

For each test case in the input print a line containing the minimum cost solution (two nonnegative integers
m1 and m2, where mi= number of
Type i boxes required) if one exists, print "failed" otherwise.

If a solution exists, you may assume that it is unique.

Sample Input

43

1 3

2 4

40

5 9

5 12

0

Sample Output

13 1

failed

题意:一个人有n个弹球。如今要把这些弹球所有装进盒子里。第一种盒子每一个盒子c1美元,能够恰好装n1个弹球。另外一种盒子每一个盒子c2元。能够恰好装n2个弹球。找出一种方法把这n个弹球装进盒子,每一个盒子都装满,而且花费最少的钱。

分析:如果第一种盒子买m1个,另外一种盒子买m2个,则n1*m1 + n2*m2 = n。由扩展欧几里得 ax+by=gcd(a,b)= g,如果n%g!=0。则方程无解。

联立两个方程。能够解出m1=nx/g, m2=ny/g,所以通解为m1=nx/g + bk/g, m2=ny/g - ak/g,

又由于m1和m2不能是负数,所以m1>=0, m2>=0,所以k的范围是 -nx/b <= k <= ny/a。且k必须是整数。

如果

k1=ceil(-nx/b)

k2=floor(ny/b)

假设k1>k2的话则k就没有一个可行的解。于是也是无解的情况。

设花费为cost,则cost = c1*m1 + c2*m2,

把m1和m2的表达式代入得

cost=c1*(-xn/g+bk/g)+c2*(yn/g-ak/g) = ((b*c1-a*c2)/g)*k+(c1*x*n+c2*y*n)/g

这是关于k的一次函数。单调性由b*c1-a*c2决定。

若b*c1-a*c2 >= 0,k取最小值(k1)时花费最少;否则,k取最大值(k2)时花费最少。

#include<iostream>
#include<cmath>
using namespace std;
typedef long long LL; LL extend_gcd(LL a, LL b, LL *x, LL *y)
{
LL xx, yy, g;
if(a < b) return extend_gcd(b, a, y, x);
if(b == 0) {
*x = 1;
*y = 0;
return a;
}
else {
g = extend_gcd(b, a%b, &xx, &yy);
*x = yy;
*y = (xx - a/b*yy);
return g;
}
} int main()
{
LL n, c1, n1, c2, n2, x, y;
while(cin >> n && n) {
cin >> c1 >> n1 >> c2 >> n2;
LL g = extend_gcd(n1, n2, &x, &y);
if(n % g != 0) {
cout << "failed" << endl;
continue;
}
LL mink = ceil(-n * x / (double)n2);
LL maxk = floor(n*y / (double)n1); // mink <= k <= maxk
if(mink > maxk) {
cout << "failed" << endl;
continue;
}
if(c1 * n2 <= c2 * n1) {
x = n2 / g * maxk + n / g * x;
y = n / g * y - n1 / g * maxk;
}
else {
x = n2 / g * mink + n / g * x;
y = n / g * y - n1 / g * mink;
}
cout << x << " " << y << endl;
}
return 0;
}