C/C++使用openssl进行摘要和加密解密(md5, sha256, des, rsa)
openssl里面有很多用于摘要哈希、加密解密的算法,方便集成于工程项目,被广泛应用于网络报文中的安全传输和认证。下面以md5,sha256,des,rsa几个典型的api简单使用作为例子。
算法介绍
md5:https://en.wikipedia.org/wiki/MD5
sha256:https://en.wikipedia.org/wiki/SHA-2
des: https://en.wikipedia.org/wiki/Data_Encryption_Standard
rsa: https://en.wikipedia.org/wiki/RSA_(cryptosystem)
工程配置
以windows下为例
编译openssl库,得到头文件include和链接库lib和dll
配置包含头文件目录和库目录
工程中设置链接指定的lib:fenbieshlibssl.lib,libcrypto.lib
将对应的dll拷贝到exe执行目录:libcrypto-1_1.dll, libssl-1_1.dll
linux下同理
代码
[cpp] view plain copy
print?
#include <iostream>
#include <cassert>
#include <string>
#include <vector>
#include “openssl/md5.h”
#include “openssl/sha.h”
#include “openssl/des.h”
#include “openssl/rsa.h”
#include “openssl/pem.h”
// —- md5摘要哈希 —- //
void md5(const std::string &srcStr, std::string &encodedStr, std::string &encodedHexStr)
{
// 调用md5哈希
unsigned char mdStr[33] = {0};
MD5((const unsigned char *)srcStr.c_str(), srcStr.length(), mdStr);
// 哈希后的字符串
encodedStr = std::string((const char *)mdStr);
// 哈希后的十六进制串 32字节
char buf[65] = {0};
char tmp[3] = {0};
for (int i = 0; i < 32; i++)
{
sprintf(tmp, “%02x”, mdStr[i]);
strcat(buf, tmp);
}
buf[32] = ”; // 后面都是0,从32字节截断
encodedHexStr = std::string(buf);
}
// —- sha256摘要哈希 —- //
void sha256(const std::string &srcStr, std::string &encodedStr, std::string &encodedHexStr)
{
// 调用sha256哈希
unsigned char mdStr[33] = {0};
SHA256((const unsigned char *)srcStr.c_str(), srcStr.length(), mdStr);
// 哈希后的字符串
encodedStr = std::string((const char *)mdStr);
// 哈希后的十六进制串 32字节
char buf[65] = {0};
char tmp[3] = {0};
for (int i = 0; i < 32; i++)
{
sprintf(tmp, “%02x”, mdStr[i]);
strcat(buf, tmp);
}
buf[32] = ”; // 后面都是0,从32字节截断
encodedHexStr = std::string(buf);
}
// —- des对称加解密 —- //
// 加密 ecb模式
std::string des_encrypt(const std::string &clearText, const std::string &key)
{
std::string cipherText; // 密文
DES_cblock keyEncrypt;
memset(keyEncrypt, 0, 8);
// 构造补齐后的密钥
if (key.length() <= 8)
memcpy(keyEncrypt, key.c_str(), key.length());
else
memcpy(keyEncrypt, key.c_str(), 8);
// 密钥置换
DES_key_schedule keySchedule;
DES_set_key_unchecked(&keyEncrypt, &keySchedule);
// 循环加密,每8字节一次
const_DES_cblock inputText;
DES_cblock outputText;
std::vector<unsigned char> vecCiphertext;
unsigned char tmp[8];
for (int i = 0; i < clearText.length() / 8; i++)
{
memcpy(inputText, clearText.c_str() + i * 8, 8);
DES_ecb_encrypt(&inputText, &outputText, &keySchedule, DES_ENCRYPT);
memcpy(tmp, outputText, 8);
for (int j = 0; j < 8; j++)
vecCiphertext.push_back(tmp[j]);
}
if (clearText.length() % 8 != 0)
{
int tmp1 = clearText.length() / 8 * 8;
int tmp2 = clearText.length() – tmp1;
memset(inputText, 0, 8);
memcpy(inputText, clearText.c_str() + tmp1, tmp2);
// 加密函数
DES_ecb_encrypt(&inputText, &outputText, &keySchedule, DES_ENCRYPT);
memcpy(tmp, outputText, 8);
for (int j = 0; j < 8; j++)
vecCiphertext.push_back(tmp[j]);
}
cipherText.clear();
cipherText.assign(vecCiphertext.begin(), vecCiphertext.end());
return cipherText;
}
// 解密 ecb模式
std::string des_decrypt(const std::string &cipherText, const std::string &key)
{
std::string clearText; // 明文
DES_cblock keyEncrypt;
memset(keyEncrypt, 0, 8);
if (key.length() <= 8)
memcpy(keyEncrypt, key.c_str(), key.length());
else
memcpy(keyEncrypt, key.c_str(), 8);
DES_key_schedule keySchedule;
DES_set_key_unchecked(&keyEncrypt, &keySchedule);
const_DES_cblock inputText;
DES_cblock outputText;
std::vector<unsigned char> vecCleartext;
unsigned char tmp[8];
for (int i = 0; i < cipherText.length() / 8; i++)
{
memcpy(inputText, cipherText.c_str() + i * 8, 8);
DES_ecb_encrypt(&inputText, &outputText, &keySchedule, DES_DECRYPT);
memcpy(tmp, outputText, 8);
for (int j = 0; j < 8; j++)
vecCleartext.push_back(tmp[j]);
}
if (cipherText.length() % 8 != 0)
{
int tmp1 = cipherText.length() / 8 * 8;
int tmp2 = cipherText.length() – tmp1;
memset(inputText, 0, 8);
memcpy(inputText, cipherText.c_str() + tmp1, tmp2);
// 解密函数
DES_ecb_encrypt(&inputText, &outputText, &keySchedule, DES_DECRYPT);
memcpy(tmp, outputText, 8);
for (int j = 0; j < 8; j++)
vecCleartext.push_back(tmp[j]);
}
clearText.clear();
clearText.assign(vecCleartext.begin(), vecCleartext.end());
return clearText;
}
// —- rsa非对称加解密 —- //
#define KEY_LENGTH 2048 // 密钥长度
#define PUB_KEY_FILE “pubkey.pem” // 公钥路径
#define PRI_KEY_FILE “prikey.pem” // 私钥路径
// 函数方法生成密钥对
void generateRSAKey(std::string strKey[2])
{
// 公私密钥对
size_t pri_len;
size_t pub_len;
char *pri_key = NULL;
char *pub_key = NULL;
// 生成密钥对
RSA *keypair = RSA_generate_key(KEY_LENGTH, RSA_3, NULL, NULL);
BIO *pri = BIO_new(BIO_s_mem());
BIO *pub = BIO_new(BIO_s_mem());
PEM_write_bio_RSAPrivateKey(pri, keypair, NULL, NULL, 0, NULL, NULL);
PEM_write_bio_RSAPublicKey(pub, keypair);
// 获取长度
pri_len = BIO_pending(pri);
pub_len = BIO_pending(pub);
// 密钥对读取到字符串
pri_key = (char *)malloc(pri_len + 1);
pub_key = (char *)malloc(pub_len + 1);
BIO_read(pri, pri_key, pri_len);
BIO_read(pub, pub_key, pub_len);
pri_key[pri_len] = ”;
pub_key[pub_len] = ”;
// 存储密钥对
strKey[0] = pub_key;
strKey[1] = pri_key;
// 存储到磁盘(这种方式存储的是begin rsa public key/ begin rsa private key开头的)
FILE *pubFile = fopen(PUB_KEY_FILE, “w”);
if (pubFile == NULL)
{
assert(false);
return;
}
fputs(pub_key, pubFile);
fclose(pubFile);
FILE *priFile = fopen(PRI_KEY_FILE, “w”);
if (priFile == NULL)
{
assert(false);
return;
}
fputs(pri_key, priFile);
fclose(priFile);
// 内存释放
RSA_free(keypair);
BIO_free_all(pub);
BIO_free_all(pri);
free(pri_key);
free(pub_key);
}
// 命令行方法生成公私钥对(begin public key/ begin private key)
// 找到openssl命令行工具,运行以下
// openssl genrsa -out prikey.pem 1024
// openssl rsa – in privkey.pem – pubout – out pubkey.pem
// 公钥加密
std::string rsa_pub_encrypt(const std::string &clearText, const std::string &pubKey)
{
std::string strRet;
RSA *rsa = NULL;
BIO *keybio = BIO_new_mem_buf((unsigned char *)pubKey.c_str(), -1);
// 此处有三种方法
// 1, 读取内存里生成的密钥对,再从内存生成rsa
// 2, 读取磁盘里生成的密钥对文本文件,在从内存生成rsa
// 3,直接从读取文件指针生成rsa
RSA* pRSAPublicKey = RSA_new();
rsa = PEM_read_bio_RSAPublicKey(keybio, &rsa, NULL, NULL);
int len = RSA_size(rsa);
char *encryptedText = (char *)malloc(len + 1);
memset(encryptedText, 0, len + 1);
// 加密函数
int ret = RSA_public_encrypt(clearText.length(), (const unsigned char*)clearText.c_str(), (unsigned char*)encryptedText, rsa, RSA_PKCS1_PADDING);
if (ret >= 0)
strRet = std::string(encryptedText, ret);
// 释放内存
free(encryptedText);
BIO_free_all(keybio);
RSA_free(rsa);
return strRet;
}
// 私钥解密
std::string rsa_pri_decrypt(const std::string &cipherText, const std::string &priKey)
{
std::string strRet;
RSA *rsa = RSA_new();
BIO *keybio;
keybio = BIO_new_mem_buf((unsigned char *)priKey.c_str(), -1);
// 此处有三种方法
// 1, 读取内存里生成的密钥对,再从内存生成rsa
// 2, 读取磁盘里生成的密钥对文本文件,在从内存生成rsa
// 3,直接从读取文件指针生成rsa
rsa = PEM_read_bio_RSAPrivateKey(keybio, &rsa, NULL, NULL);
int len = RSA_size(rsa);
char *decryptedText = (char *)malloc(len + 1);
memset(decryptedText, 0, len + 1);
// 解密函数
int ret = RSA_private_decrypt(cipherText.length(), (const unsigned char*)cipherText.c_str(), (unsigned char*)decryptedText, rsa, RSA_PKCS1_PADDING);
if (ret >= 0)
strRet = std::string(decryptedText, ret);
// 释放内存
free(decryptedText);
BIO_free_all(keybio);
RSA_free(rsa);
return strRet;
}
int main(int argc, char **argv)
{
// 原始明文
std::string srcText = “this is an example”;
std::string encryptText;
std::string encryptHexText;
std::string decryptText;
std::cout << “=== 原始明文 ===” << std::endl;
std::cout << srcText << std::endl;
// md5
std::cout << “=== md5哈希 ===” << std::endl;
md5(srcText, encryptText, encryptHexText);
std::cout << “摘要字符: ” << encryptText << std::endl;
std::cout << “摘要串: ” << encryptHexText << std::endl;
// sha256
std::cout << “=== sha256哈希 ===” << std::endl;
sha256(srcText, encryptText, encryptHexText);
std::cout << “摘要字符: ” << encryptText << std::endl;
std::cout << “摘要串: ” << encryptHexText << std::endl;
// des
std::cout << “=== des加解密 ===” << std::endl;
std::string desKey = “12345”;
encryptText = des_encrypt(srcText, desKey);
std::cout << “加密字符: ” << std::endl;
std::cout << encryptText << std::endl;
decryptText = des_decrypt(encryptText, desKey);
std::cout << “解密字符: ” << std::endl;
std::cout << decryptText << std::endl;
// rsa
std::cout << “=== rsa加解密 ===” << std::endl;
std::string key[2];
generateRSAKey(key);
std::cout << “公钥: ” << std::endl;
std::cout << key[0] << std::endl;
std::cout << “私钥: ” << std::endl;
std::cout << key[1] << std::endl;
encryptText = rsa_pub_encrypt(srcText, key[0]);
std::cout << “加密字符: ” << std::endl;
std::cout << encryptText << std::endl;
decryptText = rsa_pri_decrypt(encryptText, key[1]);
std::cout << “解密字符: ” << std::endl;
std::cout << decryptText << std::endl;
system(“pause”);
return 0;
}
运行结果
[plain] view plain copy
=== 原始明文 ===
this is an example
=== md5哈希 ===
摘要字符: 乵�驥!範
摘要串: 9202816dabaaf34bb106a10421b9a0d0
=== sha256哈希 ===
摘要字符: 訪X5衽鄁媫j/醢?17?P?4膡zD
摘要串: d44c035835f1c5e0668b7d186a2ff5b0
=== des加解密 ===
加密字符:
?/灲�取鮋t8:夽U錺?说
解密字符:
this is an example
=== rsa加解密 ===
公钥:
—–BEGIN RSA PUBLIC KEY—–
MIIBCAKCAQEA59WESdYbPsD6cYATooC4ebClTpvbTsu3X29Ha0g31kW3AmLR2zLj
hMvdWjUhhVuM7xBoh3Ufoyj4jTGHVhunFfbzxNrt1Nb64N95bZH8e9u6LjJYqh4e
sNoFknG+McjoSLNqGW9Yd8ejKH1Ju6C9SBUcC43XbB3XdC2matgV1zTsKhqjuywm
gVN9DZdo2TlZkqsvOHC23rbQ+lP09rpQJ/RI4NQSnCUBqQxErCN85trcWRj1zyJA
WaBZSvKh7J5RJcrC2ByMDmL7jrDDZl7YEolyW93SSc4xTE9Dr20OXznXNDsfQc9r
RQHBri8Aqsu4WW3tHSBRmjW5kxFMxS4qxwIBAw==
—–END RSA PUBLIC KEY—–
私钥:
—–BEGIN RSA PRIVATE KEY—–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—–END RSA PRIVATE KEY—–
加密字符:
佷篒?z_�&欗霐嗪K赸;J╄[i9?S絑?て晄p?[hD∞51鱠,k|1裡郿 犓鈪鑒?饞w2?`vlu
L<萿囂?圖L潥?O0�佲y▃飕E堿^桮??�,e鉀煯A�CsJ挈R聡-鳊帔!eQC乥+1(齀
я盈Xj饮[o6覾羂≯傁澓
解密字符:
this is an example
注:
(1)在读取公钥文件时,PEM_read_RSA_PUBKEY()函数和PEM_read_RSAPublicKEY()的疑惑。有时候为什么读取私钥文件用的PEM_read_RSAPrivateKey(),针对上述openssl命令生成的公钥文件,在读取其内容时用对称的PEM_read_RSAPublicKEY()接口却会报错,必须要用PEM_read_RSA_PUBKEY()才可以。
RSA PUBLIC KEY和PUBLIC KEY的两种公钥文件其存储方式是不一样的,PEM_read_RSAPublicKEY()只能读取RSA PUBLIC KEY开头形式的公钥文件(用函数生成的);而PEM_read_RSA_PUBKEY()只能读取PUBLIC KEY开头格式的公钥文件(用命令行生成),所以公钥私钥读取函数一定要跟生成的密钥对的格式对应起来。
(2)公钥加密和私钥解密, 私钥加密公钥解密 这两种都可以使用
(3)一般加密之后的字符串因为编码跟中文对应不上所以是乱码,在很多场合选择用十六进制串输出
(4)实际的工程应用中读取密钥对需要加安全验证
(5)用纯代码不依赖openssl库也是可以自己实现这些加解密算法的,搞清楚原理就行
http://blog.csdn.net/u012234115/article/details/72762045
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