原理应该不用多讲了,自己百度就可以。
C++实现:
#include <iostream>
#include <string>
#include <memory.h>
#include <cstdlib>
#include <ctime>
#include <cstdio>
#include <cmath>
using namespace std; //定义一些常变量
const int M = ; //定义集合{a,b,...,z}的26个英文字母 //行和列均为5
const int ROW = ;
const int COL = ; //定义5*5的加密矩阵
int K[ROW][COL]; //定义5*5的解密矩阵
int D[ROW][COL]; int P[ROW]; //明文单元
int C[ROW]; //密文单元
int F[ROW]; //密文解密后的单元 //三元组gcd(a,b) = ax + by = d
struct GCD
{
int x;
int y;
int d;
}; class Hill_Cipher
{
public:
//产生随机矩阵
void random_Matrix();
//求矩阵的行列式
int Det(int matrix[ROW][ROW],int row); //求两个数的最大公约数
int gcd(int a,int b); /*
*判断矩阵K是否在模26的情况下可逆
*因为矩阵在模26的情形下存在可逆矩阵的充分必要条件是
*gcd(det K,26) = 1
*/
bool Inverse(int matrix[ROW][ROW]); //矩阵相乘
void multiphy(int matrix[ROW][ROW],int p[ROW],int row); //求出伴随矩阵
void adjoint_matrix(int matrix[ROW][ROW],int row); //将明文加密为密文
string encryption(string plaintext); //将密文解密为明文(为了辨识清楚,我们统一以小写字母作为明文,大写字母作为密文)
string deciphering(string ciphertext); //欧几里得算法求模的逆
GCD extended_Euclid(int a,int b); //模逆运算
int inverse(int a,int m); //由于C++不存在负数取模的内置函数,现在自己设定一个
//定义一个模M的值
int Mod(int a);
}; void Hill_Cipher::random_Matrix()
{
int i,j;
for(i = ;i < ROW;i++)
{
for(j = ;j < COL;j++)
{
K[i][j] = rand() % ; //产生一个5*5模26的矩阵
}
}
cout << "随机产生5*5的矩阵:" << endl;
for(i = ;i < ROW;i++)
{
for(j = ;j < COL;j++)
{
printf("%2d ",K[i][j]);
}
cout << endl;
}
} //求矩阵的行列式
int Hill_Cipher::Det(int matrix[ROW][ROW],int row)
{
int i,j;
int cofa[ROW][ROW]; //用于存放余子阵
int l; //l为所递归的余子阵的行
int p = ,q = ;
int sum=; //由于行和列相同(方阵),所以行列式的值一定存在,故不需要判断是否为方阵 //递归基
if(row == )
return matrix[][];
for(i = ;i < row; i++)
{
for(l = ;l < row - ;l++)
{
if(l < i)
p=;
else
p=;
for(j = ;j< row - ;j++)
{
cofa[l][j] = matrix[l + p][j + ];
}
}
//相当于(-1)^i
if(i % == )
q=;
else
q=(-);
sum = sum + matrix[i][] * q * Det(cofa,row - );
}
return sum;
} //求两个数的最大公约数
int Hill_Cipher::gcd(int a,int b)
{
int temp;
//交换两个数的大小,使得a为较大数
if(a < b)
{
temp = a;
a = b;
b = temp;
}
while(a % b)
{
temp = b;
b = a % b;
a = temp;
}
return b;
} /*
*判断矩阵K是否在模26的情况下可逆
*因为矩阵在模26的情形下存在可逆矩阵的充分必要条件是
*gcd(det K,26) = 1
*/
bool Hill_Cipher::Inverse(int matrix[ROW][ROW])
{
if(gcd(Det(matrix,ROW),M) == )
return true;
else
return false;
} void Hill_Cipher::multiphy(int matrix[ROW][ROW],int p[ROW],int row)
{
int i,j;
//先将密文单元清零
memset(C,,sizeof(C));
for(i = ;i < ROW;i++)
{
for(j = ;j < ROW;j++)
{
C[i] += P[j] * K[j][i];
}
}
} //将明文加密为密文
string Hill_Cipher::encryption(string plaintext)
{
int i;
string ciphertext;
//将字符串转化为明文数组
for(i = ;i < ROW;i++)
{
P[i] = plaintext[i] - 'a';
}
multiphy(K,P,ROW);
//将密文数组转化为密文
for(i = ;i < ROW;i++)
//这里先将其模26,再翻译为对应的字母
{
C[i] =Mod(C[i]);
ciphertext += C[i] + 'A';
}
return ciphertext;
} //求出伴随矩阵
void Hill_Cipher::adjoint_matrix(int matrix[ROW][ROW],int row)
{
int i,j,k,l;
int p,q;
p = q = ;
int temp[ROW][ROW];
for(i = ;i < ROW;i++)
{
for(j = ;j < ROW;j++)
{
for(k = ;k < ROW - ;k++)
{
if(k < i)
p = ;
else
p = ;
for(l = ;l < ROW - ;l++)
{
if(l < j)
q = ;
else
q = ;
temp[k][l] = matrix[k+p][l+q];
}
}
D[j][i] = (int)pow(-,(double)i+j)*Det(temp,ROW-);
D[j][i] = Mod(D[j][i]);
}
}
} //将密文解密为明文(为了辨识清楚,我们统一以小写字母作为明文,大写字母作为密文)
string Hill_Cipher::deciphering(string ciphertext)
{
//求出矩阵的逆
string text;
int determinant = Det(K,ROW);
int inver = inverse(determinant,);
adjoint_matrix(K,ROW); //伴随矩阵
cout << "行列式的值: " << determinant << endl;
int i,j;
memset(F,,sizeof(F));
for(i = ;i < ROW;i++)
{
for(j = ;j < ROW;j++)
{
F[i] += C[j] * D[j][i];
}
F[i] *= inver;
F[i] = Mod(F[i]); //算到的结果要模去26
}
for(i = ;i < ROW;i++)
text += F[i] + 'a';
return text;
} GCD Hill_Cipher::extended_Euclid(int a,int b)
{
GCD aa,bb;
if(b == )
{
aa.x = ;
aa.y = ;
aa.d = a;
return aa;
}
else
{
bb = extended_Euclid(b,a%b);
aa.x = bb.y;
aa.y = bb.x - (a / b) * bb.y;
aa.d = bb.d;
}
return aa;
} int Hill_Cipher::inverse(int a,int m)
{
GCD aa;
aa = extended_Euclid(a,m);
return aa.x;
} int Hill_Cipher::Mod(int a)
{
return a >= ? a % M : (M + a % M);
} int main()
{
int i,j;
Hill_Cipher hh;
cout << "使用希尔密码进行消息的加解密:" << endl; //srand()函数产生一个以当前时间开始的随机种子.以保证每次产生的随机数矩阵都不相同
srand((unsigned)time());
hh.random_Matrix();
while(!hh.Inverse(K))
{
cout << "该矩阵模26不可逆,不可以作为密钥!" << endl;
cout << endl;
hh.random_Matrix();
}
cout << "该矩阵模26可逆,因此可以作为密钥." << endl;
cout << endl; //利用所选密钥,对给定的5元明文信息进行加解密
string plaintext,ciphertext;
cout << "请输入5元明文信息:" << endl;
cin >> plaintext;
ciphertext = hh.encryption(plaintext);
cout << endl;
cout << "该明文通过希尔密码法加密过后,输出的密文消息为:" << endl;
cout << ciphertext << endl;
cout << endl; cout << "***输入0:退出 ***" << endl;
cout << "***输入1:查看明文空间对***" << endl;
cout << "***输入2:查看密文空间对***" << endl;
cout << "***输入3:查看密钥 ***" << endl;
cout << "***输入4:将消息解密 ***" << endl;
cout << "***输入5:查看菜单 ***" << endl; char c;
while(cin >> c)
{
if(c == '')
{
cout << endl;
cout << "退出" << endl;
break;
}
else if(c == '')
{
cout << "明文空间:" << endl;
for(i = ;i < ROW;i++)
cout << P[i] << " ";
cout << endl;
cout << endl;
}
else if(c == '')
{
cout << "密文空间:" << endl;
for(i = ;i < ROW;i++)
cout << C[i] << " ";
cout << endl;
cout << endl;
}
else if(c == '')
{
cout << "密钥:" << endl;
for(i = ;i < ROW;i++)
{
for(j = ;j < ROW;j++)
{
printf("%2d ",K[i][j]);
}
cout << endl;
}
cout << endl;
}
else if(c == '')
{
hh.adjoint_matrix(K,ROW);
string ss;
ss = hh.deciphering(ciphertext);
cout << "该密文解密过后,显示的原来的明文消息:" << endl;
cout << ss << endl;
cout << endl;
}
else
{
cout << "***输入0:退出 ***" << endl;
cout << "***输入1:查看明文空间对***" << endl;
cout << "***输入2:查看密文空间对***" << endl;
cout << "***输入3:查看密钥 ***" << endl;
cout << "***输入4:将消息解密 ***" << endl;
cout << "***输入5:查看菜单 ***" << endl;
}
}
return ;
}
Mathematica 9.0实现:
Print["请输入你要输入的5元明文数组:"];
A = {}
For[i = 0, i < 5, i++, AppendTo[A, Input[]]]
请输入你要输入的5元明文数组:
{}
Print["请输入你要输入的5元明文数组:"];
A = {}
For[i = 0, i < 5, i++, AppendTo[A, Input[]]]
Print["产生5*5的随机数组"];
While[True, B = RandomInteger[{0, 25}, {5, 5}];
If[Det[B] != 0, Break[]];]
Print["A=", A]
Print["B=", B]
请输入你要输入的5元明文数组:
{}
产生5*5的随机数组
A={1,2,3,4,5}
B={{0,10,0,3,9},{22,18,0,17,4},{5,1,1,10,11},{8,8,13,16,15},{10,9,23,21,5}}
d = A.B
{141, 126, 170, 236, 135}
Print["d=", d]
d={141,126,170,236,135}
e = Mod[d, 26]
Print["加密后的密文为:", e]
{11, 22, 14, 2, 5}
加密后的密文为:{11,22,14,2,5}
f = d.Inverse[B]
Print["解密后的密文为:", f]
{1, 2, 3, 4, 5}
解密后的密文为:{1,2,3,4,5}