/*
*/
#include <iostream>
using namespace std;
/*
注意到對于gcd(a,b) = d 我們對(a, b)用歐幾里德輾轉(zhuǎn)相除會最終得到
(d, 0)此時對于把a =d, b = 0 帶入a*x + b*y = d����,顯然x = 1,y可以為任意值��,
這里y可以為任意值就意味著解會有無數(shù)個。我們可以用a = d, b = 0的情況逆推出來
任何gcd(a, b) = d 滿足a*x + b*y = d的解�����。如果x0, y0是b*x + (a%b)*y = d 的解�����,
那么對于a*x + b*y = d的解呢����?
b*x0 + (a%b)*y0 = d => b*x0 + (a - [a/b]*b)*y0 = a*y0 + b*(x0 - [a/b]*y0)����,
所以a*x + b*y = d的解x1 = y0����, y1 = x0 - [a/b]*y0; 這樣我們可以程序迭帶了。
*/
int extEuclid(int a, int b, int &x, int &y)
{
if (b == 0)
{
x = 1;
y = 0;
return a;
}
int d = extEuclid(b, a % b, x, y);
int iTemp = x;
x = y;
y = iTemp - (a / b)* y;
return d;
}
//解同余方程ax = b(mod n) (返回最小的正數(shù)x)
int modularLinearEquation(int a, int b, int n)
{
//等價于求ax + cn = b;
//先求a*x1 + c1*n = gcd(a, n)
int x, y, d;
d = extEuclid(a, n, x, y);
if (b % d != 0)
return -1;
x = x * (b / d);
x = (( x % n) + n) % n;
return x;
}
//中國剩余定理,推導(dǎo)都是數(shù)學(xué)
int solModularEquations(int b[], int m[], int k)
{
int iTemp;
int y;
int result;
int M = 1;
for (int i = 0; i < k; i++)
M *= m[i];
result = 0;
for (int i = 0; i < k; i++)
{
iTemp = M / m[i];
y = modularLinearEquation(iTemp, 1, m[i]);
result = (result + b[i] * iTemp * y) % M;
}
return result;
}
int main()
{
int x, y , d;
d = extEuclid(1001, 767, x, y);
cout << x << endl;
cout << y << endl;
cout << d << endl;
cout << "1001 * x + 767 * y = " << (1001 * x + 767 * y) << endl;
cout << modularLinearEquation(3, 2, 100) << endl;
return 0;
}
posted on 2012-06-02 14:31
nk_ysg 閱讀(483)
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