C++实现对16进制字符串和字节数组的tea加密和解密算法

#include <stdint.h>

void encrypt (uint32_t v[2], uint32_t k[4]) {
    uint32_t v0=v[0], v1=v[1], sum=0, i;           /* set up */
    uint32_t delta=0x9E3779B9;                     /* a key schedule constant */
    uint32_t k0=k[0], k1=k[1], k2=k[2], k3=k[3];   /* cache key */
    for (i=0; i<32; i++) {                         /* basic cycle start */
        sum += delta;
        v0 += ((v1<<4) + k0) ^ (v1 + sum) ^ ((v1>>5) + k1);
        v1 += ((v0<<4) + k2) ^ (v0 + sum) ^ ((v0>>5) + k3);
    }                                              /* end cycle */
    v[0]=v0; v[1]=v1;
}

void decrypt (uint32_t v[2], uint32_t k[4]) {
    uint32_t v0=v[0], v1=v[1], sum=0xC6EF3720, i;  /* set up; sum is 32*delta */
    uint32_t delta=0x9E3779B9;                     /* a key schedule constant */
    uint32_t k0=k[0], k1=k[1], k2=k[2], k3=k[3];   /* cache key */
    for (i=0; i<32; i++) {                         /* basic cycle start */
        v1 -= ((v0<<4) + k2) ^ (v0 + sum) ^ ((v0>>5) + k3);
        v0 -= ((v1<<4) + k0) ^ (v1 + sum) ^ ((v1>>5) + k1);
        sum -= delta;
    }                                              /* end cycle */
    v[0]=v0; v[1]=v1;
}



/************************************************

The Tiny Encryption Algorithm (TEA) by 
David Wheeler and Roger Needham of the
Cambridge Computer Laboratory

**** ANSI C VERSION ****

Notes:

TEA is a Feistel cipher with XOR and
and addition as the non-linear mixing
functions. 

Takes 64 bits of data in v[0] and v[1].
Returns 64 bits of data in w[0] and w[1].
Takes 128 bits of key in k[0] - k[3].

TEA can be operated in any of the modes
of DES. Cipher Block Chaining is, for example,
simple to implement.

n is the number of iterations. 32 is ample,
16 is sufficient, as few as eight may be OK.
The algorithm achieves good dispersion after
six iterations. The iteration count can be
made variable if required.

Note this is optimised for 32-bit CPUs with
fast shift capabilities. It can very easily
be ported to assembly language on most CPUs.

delta is chosen to be the real part of (the
golden ratio Sqrt(5/4) - 1/2 ~ 0.618034
multiplied by 2^32). 

************************************************/

void encipher(unsigned long *const v,unsigned long *const w,
const unsigned long *const k)
{
   register unsigned long       y=v[0],z=v[1],sum=0,delta=0x9E3779B9,
				a=k[0],b=k[1],c=k[2],d=k[3],n=32;

   while(n-->0)
      {
      sum += delta;
      y += (z<<4)+a ^ z+sum ^ (z>>5)+b;
      z += (y<<4)+c ^ y+sum ^ (y>>5)+d;
      }

   w[0]=y; w[1]=z;
}

void decipher(unsigned long *const v,unsigned long *const w,
const unsigned long *const k)
{
   register unsigned long       y=v[0],z=v[1],sum=0xC6EF3720,
				delta=0x9E3779B9,a=k[0],b=k[1],c=k[2],
				d=k[3],n=32;

   /* sum = delta<<5, in general sum = delta * n */

   while(n-->0)
      {
      z -= (y<<4)+c ^ y+sum ^ (y>>5)+d;
      y -= (z<<4)+a ^ z+sum ^ (z>>5)+b;
      sum -= delta;
      }
   
   w[0]=y; w[1]=z;
}

#ifndef _TYPE_H_
#define _TYPE_H_

// 自定义
typedef unsigned char		uint8;
typedef unsigned short		uint16;
typedef unsigned int		uint32;
#ifdef WIN32
typedef unsigned __int64	uint64;
typedef __int64	 int64;
#else
typedef unsigned long long	uint64;
typedef long long	int64;
#endif
typedef char	int8;
typedef short	int16;
typedef int		int32;

#include <string.h>

// 数组
#include <string>
#include <vector>

typedef std::string	String;
typedef std::vector<uint8>		Uint8Array;
typedef std::vector<uint16>		Uint16Array;
typedef std::vector<uint32>		Uint32Array;
typedef std::vector<uint64>		Uint64Array;
typedef std::vector<int8>		Int8Array;
typedef std::vector<int16>		Int16Array;
typedef std::vector<int32>		Int32Array;
typedef std::vector<int64>		Int64Array;
typedef std::vector<float>		Float32Array;
typedef std::vector<double>		Float64Array;
typedef std::vector<std::string>	StringArray;

#ifdef WIN32
#ifndef snprintf
#define snprintf sprintf_s
#endif
#endif

#endif

#ifndef _FUNC_H_
#define _FUNC_H_

#include "type.h"

#if _MSC_VER
#define snprintf _snprintf
#endif

// 字符串工具处理类
class StringTools
{
public:
	static inline StringArray split(const std::string& s, const std::string& sep, const bool compress = false)
	{
		StringArray out;
		int pos = 0;
		int index = -1;
		while ((index = s.find(sep, pos)) != s.npos)
		{
			if (index - pos == 0)
			{

			}
			// s.substr(pos, index - pos == 0 ? 1 : index - pos);
			std::string it = index - pos == 0 ? "" : s.substr(pos, index - pos);
			if (compress && it == "") // 压缩 index - pos == sep.size() && 
			{

			}
			else // 不用压缩
			{
				out.push_back(it);
			}

			pos = index + sep.size();
		}
		if (pos < (int)s.size())
		{
			out.push_back(s.substr(pos));
		}
		return out;
	}

	// 转换hex到字符串显示
	static inline String hex2str(const char* buff, const size_t buffsize, const char* sep = "", bool is_case = false) {
		String out;
		char ch[4];
		const char* fmt = is_case ? "%02x" : "%02X";
		for (size_t i = 0; i < buffsize; i++) {
			sprintf(ch, fmt, buff[i] & 0xFF);
			if (out.empty()) {
				out = ch;
			}
			else {
				out += sep;
				out += ch;
			}
		}
		return out;
	}

	// 转换字符串显示到hex数组
	static inline String str2hex(const String& buff, const String& sep = "") {
		String out;
		size_t buffsize = buff.size();
		StringArray items;
		if (sep.empty() && buffsize % 2 == 0) {
			for (size_t i = 0; i < buffsize / 2; i++) {
				items.emplace_back(buff.substr(i * 2, 2));
			}
		}
		else if (sep.size()) {
			items = split(buff, sep, true);
		}
		for (auto& i : items) {
			int ch;
			if (!to_int(ch, i, 16)) {
				return out;
			}
			out.push_back(ch & 0xff);
		}
		return out;
	}

	// 获取字符串中数字
	static inline bool to_int(int& _return, const std::string& buff, int base = 10, size_t offset = 0, size_t count = String::npos)
	{
		_return = 0;
		if (buff.empty())
			return false;
		try {
			_return = std::stoi(buff.substr(offset, count), 0, base);
		}
		catch (...) {
			return false;
		}
		return true;
	}
};

#endif

#ifndef _TEA_H_
#define _TEA_H_


#include "type.h"

/*******************************加密解密函数************************************/
// 加密核心函数
// v为需要加密的数据
// k为加密的密钥
// round为加密的轮数，和解密相对应
void tea_encode(int32 * v, const int32 * k, int round);

// 少于64为数据加密函数
void tea_encode_byte(char * v, const int32 * k, int32 p, const char* y);

void tea_decode_byte(char * v, const int32 * k, int32 p, const char* y);

// 解密核心函数
// v为需要解密的数据
// k为解密的密钥
// round为解密的轮数，和加密相对应
void tea_decode(int32 * v, const int32 * k, int round);


//加密数据分组运算
void tea_encode_buffer(char * in_buffer, uint32 in_size, const int32 * key,
	int32 cipherRemains, int round, const char* y);


//解密数据分组运算
void tea_decode_buffer(char * in_buffer, uint32 in_size, const int32 * key,
	int cipherRemains, int round, const char* y);

// 加密(传入的是16进制的字符串，输出的也是16进制的字符串)
int tea_encrypt_hexstr(char *buffer_in, int nlen, int32 key[], int round, const char* y);
 
// 解密(传入的是16进制的字符串，输出的也是16进制的字符串)
int tea_decrypt_hexstr(char *buffer_in, int nlen, int32 key[], int round, const char* y);

// 加密(传入的是16进制的字节数组，输出的也是16进制的字节数组)
int tea_encrypt_hexbytes(char *buffer_in, int nlen, int32 key[], int round, const char* y);

// 解密(传入的是16进制的字节数组，输出的也是16进制的字节数组)
int tea_decrypt_hexbytes(char *buffer_in, int nlen, int32 key[], int round, const char* y);

#endif

#include <string.h>

#include "tea.h"

#include <func.h>

/*******************************加密解密函数************************************/
// 加密核心函数
// v为需要加密的数据
// k为加密的密钥
// round为加密的轮数，和解密相对应
void tea_encode(int32 * v, const int32 * k, int round)
{
	uint32 y = 0, z = 0, sum = 0;
	uint32 delta = 0x9e3779b9;
	// uint8_t n = 2, *DataP1;
	uint8_t n = round, *DataP1;
	DataP1 = (uint8_t *)v;
	y = *DataP1;
	DataP1++;
	y = y + ((uint32)*DataP1 << 8);
	DataP1++;
	y = y + ((uint32)*DataP1 << 16);
	DataP1++;
	y = y + ((uint32)*DataP1 << 24);

	DataP1++;
	z = *DataP1;
	DataP1++;
	z = z + ((uint32)*DataP1 << 8);
	DataP1++;
	z = z + ((uint32)*DataP1 << 16);
	DataP1++;
	z = z + ((uint32)*DataP1 << 24);

	while (n-- > 0)
	{
		sum += delta;
		y += ((z << 4) + k[0]) ^ (z + sum) ^ ((z >> 5) + k[1]);
		z += ((y << 4) + k[2]) ^ (y + sum) ^ ((y >> 5) + k[3]);
	}
	DataP1 = (uint8_t *)v;
	*DataP1 = y;
	DataP1++;
	*DataP1 = y >> 8;
	DataP1++;
	*DataP1 = y >> 16;
	DataP1++;
	*DataP1 = y >> 24;


	DataP1++;
	*DataP1 = z;
	DataP1++;
	*DataP1 = z >> 8;
	DataP1++;
	*DataP1 = z >> 16;
	DataP1++;
	*DataP1 = z >> 24;
}
/******************************************************************************/

// 少于64为数据加密函数
void tea_encode_byte(char * v, const int32 * k, int32 p, const char* y)
{
	//char y[] = "Wu&Tian"; //固定写的一个字符串，只要与解密相同即可，7字节长度
	if (y != NULL)
	{
		*v = *v ^ y[p] ^ (char)(k[p % 4] % 0xff);
	}
}

/******************************************************************************/
void tea_decode_byte(char * v, const int32 * k, int32 p, const char* y)
{
	//char y[] = "Wu&Tian";
	if (y != NULL)
	{
		*v = *v ^ (char)(k[p % 4] % 0xff) ^ y[p];
	}
}
/******************************************************************************/

// 解密核心函数
// v为需要解密的数据
// k为解密的密钥
// round为解密的轮数，和加密相对应
void tea_decode(int32 * v, const int32 * k, int round)
{
	uint32 y = 0, z = 0, sum = 0, delta = 0x9e3779b9;
	// uint8_t n = 2, *DataP1;
	uint8_t n = round, *DataP1;

	DataP1 = (uint8_t *)v;
	y = *DataP1;
	DataP1++;
	y = y + ((uint32)*DataP1 << 8);
	DataP1++;
	y = y + ((uint32)*DataP1 << 16);
	DataP1++;
	y = y + ((uint32)*DataP1 << 24);

	DataP1++;
	z = *DataP1;
	DataP1++;
	z = z + ((uint32)*DataP1 << 8);
	DataP1++;
	z = z + ((uint32)*DataP1 << 16);
	DataP1++;
	z = z + ((uint32)*DataP1 << 24);

	sum = delta << 1;
	while (n-- > 0)
	{
		z -= ((y << 4) + k[2]) ^ (y + sum) ^ ((y >> 5) + k[3]);
		y -= ((z << 4) + k[0]) ^ (z + sum) ^ ((z >> 5) + k[1]);
		sum -= delta;
	}
	DataP1 = (uint8_t *)v;
	*DataP1 = y;
	DataP1++;
	*DataP1 = y >> 8;
	DataP1++;
	*DataP1 = y >> 16;
	DataP1++;
	*DataP1 = y >> 24;


	DataP1++;
	*DataP1 = z;
	DataP1++;
	*DataP1 = z >> 8;
	DataP1++;
	*DataP1 = z >> 16;
	DataP1++;
	*DataP1 = z >> 24;
}
/******************************************************************************/

//加密数据分组运算
void tea_encode_buffer(char * in_buffer, uint32 in_size, const int32 * key,
	int32 cipherRemains, int round, const char* y)
{
	char * p;
	uint32 remain = in_size % 8;//计算出数据8字节整数倍之外的数据

	uint32 align_size = in_size - remain;

	for (p = in_buffer; p < in_buffer + align_size; p += 8)
		tea_encode((int32 *)p, key, round);
	if (remain > 0 && cipherRemains)
		for (p = in_buffer + align_size; p < in_buffer + in_size; p += 1)
			tea_encode_byte(p, key, --remain, y);
}
/******************************************************************************/

//解密数据分组运算
void tea_decode_buffer(char * in_buffer, uint32 in_size, const int32 * key,
	int cipherRemains, int round, const char* y)
{
	char * p;
	uint32 remain = in_size % 8;
	uint32 align_size = in_size - remain;

	for (p = in_buffer; p < in_buffer + align_size; p += 8)
		tea_decode((int32 *)p, key, round);//8字节分组加密
	//处理超出8字节整数倍数据的加密运算
	if (remain > 0 && cipherRemains)
		for (p = in_buffer + align_size; p < in_buffer + in_size; p += 1)
			tea_decode_byte(p, key, --remain, y);
}
// 加密(传入的是16进制的字符串，输出的也是16进制的字符串)
int tea_encrypt_hexstr(char *buffer_in, int nlen, int32 key[], int round, const char* y)
{
	if (buffer_in == NULL || nlen <= 0)
	{
		return -1;
	}

	// 先将16进制字符串转换成16进制字节数组
	string strHexTemp = Math::Tools::str2hex(buffer_in);

	// 加密数据块，加密后的数据存入pData中
	tea_encode_buffer((char*)strHexTemp.data(), strHexTemp.length(), key, 1, round, y);

	// 加密后将16进制字节数组转换成16进制字符串
	strHexTemp = Math::Tools::hex2str(strHexTemp.data(), strHexTemp.length());

	memcpy(buffer_in, strHexTemp.data(), strHexTemp.length());

	return 0;
}

// 解密(传入的是16进制的字符串，输出的也是16进制的字符串)
int tea_decrypt_hexstr(char *buffer_in, int nlen, int32 key[], int round, const char* y)
{
	if (buffer_in == NULL || nlen <= 0)
	{
		return -1;
	}

	// 先将16进制字符串转换成16进制字节数组
	string strHexTemp = Math::Tools::str2hex(buffer_in);

	// 解密数据块，解密后的数据存入pData中
	tea_decode_buffer((char*)strHexTemp.data(), strHexTemp.length(), key, 1, round, y);

	// 解密后将16进制字节数组转换成16进制字符串
	strHexTemp = Math::Tools::hex2str(strHexTemp.data(), strHexTemp.length());

	memcpy(buffer_in, strHexTemp.data(), strHexTemp.length());

	return 0;
}

// 加密(传入的是16进制的字节数组，输出的也是16进制的字节数组)
int tea_encrypt_hexbytes(char *buffer_in, int nlen, int32 key[], int round, const char* y)
{
	if (buffer_in == NULL || nlen <= 0)
	{
		return -1;
	}

	// 解密数据块，解密后的数据存入pData中
	tea_encode_buffer(buffer_in, nlen, key, 1, round, y);

	return 0;
}

// 解密(传入的是16进制的字节数组，输出的也是16进制的字节数组)
int tea_decrypt_hexbytes(char *buffer_in, int nlen, int32 key[], int round, const char* y)
{
	if (buffer_in == NULL || nlen <= 0)
	{
		return -1;
	}

	// 解密数据块，解密后的数据存入pData中
	tea_decode_buffer(buffer_in, nlen, key, 1, round, y);

	return 0;
}

#include <iostream>
#include <string>

#include "tea.h"
#include <func.h>

using namespace std;

int main(int argc, char* argv[])
{
	// 测试1: 输入的是16进制的字符串
	string strBuf = "E2DDFA5D00E0FF6880B0924100000000000000002D48190080A2190030000000000040004CFF000000000000000000000000000000000000750200000000";

	int keys[] = { 0x37777931, 0x73444148, 0x4148314F, 0x59484170 };

	// 加密
	tea_encrypt_hexstr((char*)strBuf.c_str(), strBuf.length(), keys, 2, "Wu&Tian");

	cout << "加密后的16进制数据为：" << strBuf << endl;

	// 解密
	tea_decrypt_hexstr((char*)strBuf.c_str(), strBuf.length(), keys, 2, "Wu&Tian");

	cout << "解密后的16进制数据为：" << strBuf << endl;

	cout << "-------------------------------------------------------------------------------------------------" << endl;

	// 测试数据2：输入的是16进制字节数组
	string strBuf2 = "E2DDFA5D00E0FF6880B0924100000000000000002D48190080A2190030000000000040004CFF000000000000000000000000000000000000750200000000";
	// 将16进制字符串转换成16进制字节数组
	string strHexTemp = Math::Tools::str2hex(strBuf2);
	// 对16进制的字节数组进行加密
	tea_encrypt_hexbytes((char*)strHexTemp.c_str(), strHexTemp.length(), keys, 2, "Wu&Tian");
	cout << "加密后的16进制字节数组为：" << strHexTemp << endl;

	tea_decrypt_hexbytes((char*)strHexTemp.c_str(), strHexTemp.length(), keys, 2, "Wu&Tian");

	cout << "解密后的16进制字节数组为：" << strHexTemp << endl;
	
	getchar();

	return 0;
}