openssl之aes加密(源码分析 AES_encrypt 与 AES_cbc_encrypt ,加密模式)

首先要了解AES加密是什么,以及几种加密模式的区别。之后才是编程。具体的编程案例,在下面的链接。

openssl之aes加密(AES_cbc_encrypt 与 AES_encrypt 的编程案例)

下面这个链接有详细图解。

http://www.cnblogs.com/adylee/archive/2007/09/14/893438.html

AES加密算法 加密模式

ECB模式    优点:    1.简单;    2.有利于并行计算;    3.误差不会被传送;    缺点:    1.不能隐藏明文的模式;    2.可能对明文进行主动攻击;  CBC模式:    优点:    1.不容易主动攻击,安全性好于ECB,适合传输长度长的报文,是SSL、IPSec的标准。    缺点:    1.不利于并行计算;    2.误差传递;    3.
需要初始化向量IV  CFB模式:    优点:    1.隐藏了明文模式;    2.分组密码转化为流模式;    3.可以及时加密传送小于分组的数据;    缺点:    1.不利于并行计算;    2.误差传送:一个明文单元损坏影响多个单元;    3.唯一的IV;  ofb模式:    优点:    1.隐藏了明文模式;    2.分组密码转化为流模式;    3.可以及时加密传送小于分组的数据;    缺点:    1.不利于并行计算;    2.对明文的主动攻击是可能的;    3.误差传送:一个明文单元损坏影响多个单元; 

了解这些加密模式之后,再看openssl提供的接口就好理解了。

openssl提供的aes加密接口

以下接口来自“crypto/aes/aes.h”,有openssl源码。 //设置加密和解密器 int AES_set_encrypt_key(const unsigned char *userKey, const int bits,
AES_KEY *key); int AES_set_decrypt_key(const unsigned char *userKey, const int bits,
AES_KEY *key);

//默认的加密解密方式,参数好理解
void AES_encrypt(const unsigned char *in, unsigned char *out,
const AES_KEY *key);
void AES_decrypt(const unsigned char *in, unsigned char *out,
const AES_KEY *key);

//下面这些也是常用的加密方式,但是参数很多,而源码对于参数使用介绍不多,只能摸索 void AES_ecb_encrypt(const unsigned char *in, unsigned char *out,
const AES_KEY *key, const int enc);
void AES_cbc_encrypt(const unsigned char *in, unsigned char *out,
size_t length, const AES_KEY *key,
unsigned char *ivec, const int enc); //参数相对复杂 void AES_cfb128_encrypt(const unsigned char *in, unsigned char *out,
size_t length, const AES_KEY *key,
unsigned char *ivec, int *num, const int enc); void AES_cfb1_encrypt(const unsigned char *in, unsigned char *out,
size_t length, const AES_KEY *key,
unsigned char *ivec, int *num, const int enc); void AES_cfb8_encrypt(const unsigned char *in, unsigned char *out,
size_t length, const AES_KEY *key,
unsigned char *ivec, int *num, const int enc); void AES_ofb128_encrypt(const unsigned char *in, unsigned char *out,
size_t length, const AES_KEY *key,
unsigned char *ivec, int *num); void AES_ctr128_encrypt(const unsigned char *in, unsigned char *out,
size_t length, const AES_KEY *key,
unsigned char ivec[AES_BLOCK_SIZE],
unsigned char ecount_buf[AES_BLOCK_SIZE],
unsigned int *num);

从下面这个文件可以看出,
AES_encrypt
就是ecb加密的方式。而AES_set_encrypt_key和
AES_encrypt,它们的实现在”crypto/aes/aes_x86core.c”和
“crypto/aes/aes_core.c”,也就是有两个版本,根据平台选择。看源码。


crypto/aes/
aes_ecb.c”
void

AES_ecb_encrypt
(
const

unsigned

char

*
in
,

unsigned

char

*
out
,

   
const
AES_KEY
*
key
,

const

int
enc
)

{
       
assert
(
in

&&

out

&&
key
);

assert
((
AES_ENCRYPT
==
enc
)||(
AES_DECRYPT
==
enc
));

if

(
AES_ENCRYPT
==
enc
)

AES_encrypt
(
in
,

out
,
key
);

else

AES_decrypt
(
in
,

out
,
key
);
}
从这里可以看出,ecb方式的加密,是由AES_encrypt接口实现的。

而cbc的加密方式在另外的地方实现了,下面给出目录以及源代码。

"crypto/aes/aes_cbc.c"

void AES_cbc_encrypt(const unsigned char *in, unsigned char *out, size_t len, const AES_KEY *key, unsigned char *ivec, const int enc) { if (enc) CRYPTO_cbc128_encrypt(in,out,len,key,ivec,(block128_f)AES_encrypt); else CRYPTO_cbc128_decrypt(in,out,len,key,ivec,(block128_f)AES_decrypt); }

从这里看出,cbc加密方式,调用接口CRYPTO_cbc128_decrypt,而它又将AES_encrypt作为参数传入

“crypto/modes/
cbc128.c”
void

CRYPTO_cbc128_encrypt
(
const

unsigned

char

*
in
,

unsigned

char

*
out
,

size_t
len
,

const

void

*
key
,

unsigned

char
ivec
[
16
],
block128_f block
)
{
//这里的block就是AES_encrypt

size_t n;

const unsigned char *iv = ivec;

assert(in && out && key && ivec);
#if !defined(OPENSSL_SMALL_FOOTPRINT)

if (STRICT_ALIGNMENT &&

   ((size_t)in|(size_t)out|(size_t)ivec)%sizeof(size_t) != 0) {

while (len>=16) {

for(n=0; n<16; ++n)

out[n] = in[n] ^ iv[n];
//输入与初始化向量进行异或,保存在out

(*block)(out, out, key);
//调用AES_encrypt进行加密,异或结果out作为加密输入
//加密输出结果也保存在out里面,

iv = out;
//将前一次密文,作为后一次的初始化向量,从而完成加密

len -= 16;

in  += 16;

out += 16;

}

} else {

while (len>=16) {

for(n=0; n<16; n+=sizeof(size_t))

*(size_t*)(out+n) =

*(size_t*)(in+n) ^ *(size_t*)(iv+n);

(*block)(out, out, key);

iv = out;

len -= 16;

in  += 16;

out += 16;

}

}
#endif

while (len) {

for(n=0; n<16 && n<len; ++n)

out[n] = in[n] ^ iv[n];
//in和iv异或

for(; n<16; ++n)
//如果in长度不是16的整数倍

out[n] = iv[n];
//最后的out直接用iv初始化,其实也就相当于out与0进行异或

(*block)(out, out, key);

iv = out;

if (len<=16) break;
//加密结束

len -= 16;

in  += 16;

out += 16;

}

memcpy(ivec,iv,16);
}
//从上面的源码可以看出,cbc本质上和ecb差别不大,唯一区别是将前一次加密结果,与要加密的内容异或。因此,cbc的并行性较差,因为每次都要等待前一次的结果,而ecb则不用,速度较快。其主要区别仍然看文章开头,原理图看参考链接。

调用实例:

int aes_encrypt(char* in, char* key, char* out)//, int olen)
{
    if(!in || !key || !out) return 0;
    AES_KEY aes;
    if(AES_set_encrypt_key((unsigned char*)key, 128, &aes) < 0)
    {
        return 0;
    }
    int len=strlen(in)/<span style="font-family: 'Hiragino Sans GB W3', 'Hiragino Sans GB', Arial, Helvetica, simsun, u5b8bu4f53;">AES_BLOCK_SIZE*</span><span style="font-family: 'Hiragino Sans GB W3', 'Hiragino Sans GB', Arial, Helvetica, simsun, u5b8bu4f53;">AES_BLOCK_SIZE</span><span style="font-family: 'Hiragino Sans GB W3', 'Hiragino Sans GB', Arial, Helvetica, simsun, u5b8bu4f53;">, en_len=0;</span><span style="font-family: 'Hiragino Sans GB W3', 'Hiragino Sans GB', Arial, Helvetica, simsun, u5b8bu4f53;">
</span>    while(en_len<len)//输入输出字符串够长,并且是AES_BLOCK_SIZE的整数倍,需要严格限制
    {
    	AES_encrypt((unsigned char*)in, (unsigned char*)out, &aes);
    	in+=AES_BLOCK_SIZE;
    	out+=AES_BLOCK_SIZE;
    	en_len+=AES_BLOCK_SIZE;
    }
    return 1;
}
int aes_decrypt(char* in, char* key, char* out)
{
    if(!in || !key || !out) return 0;
    AES_KEY aes;
    if(AES_set_decrypt_key((unsigned char*)key, 128, &aes) < 0)
    {
        return 0;
    }
    int len=strlen(in), en_len=0;
    while(en_len<len)
    {
    	AES_decrypt((unsigned char*)in, (unsigned char*)out, &aes);
    	in+=AES_BLOCK_SIZE;
    	out+=AES_BLOCK_SIZE;
    	en_len+=AES_BLOCK_SIZE;
    }
    return 1;
}

最近遇到一个坑,

AES_encrypt <pre code_snippet_id="232583" snippet_file_name="blog_20140312_1_226454" name="code" class="cpp" style="color: rgb(55, 42, 24); font-size: 16px; line-height: 28px;">AES_decrypt

就是这两个函数让我折腾了四五天,心力憔悴,几近崩溃,也许是走火入魔了,因为遇到了挑战,非要干掉它,而不是绕过!

int aes_encrypt(char* in, char* key, char* out)//, int olen)
{
    if(!in || !key || !out) return 0;
    AES_KEY aes;
    if(AES_set_encrypt_key((unsigned char*)key, 128, &aes) < 0)
    {
        return 0;
    }
    <pre code_snippet_id="232583" snippet_file_name="blog_20140312_1_226454" name="code" class="cpp" style="color: rgb(55, 42, 24); font-size: 16px; line-height: 28px;">    int len=strlen(in)/<span style="font-family: 'Hiragino Sans GB W3', 'Hiragino Sans GB', Arial, Helvetica, simsun, u5b8bu4f53;">AES_BLOCK_SIZE*</span><span style="font-family: 'Hiragino Sans GB W3', 'Hiragino Sans GB', Arial, Helvetica, simsun, u5b8bu4f53;">AES_BLOCK_SIZE</span><span style="font-family: 'Hiragino Sans GB W3', 'Hiragino Sans GB', Arial, Helvetica, simsun, u5b8bu4f53;">, en_len=0;</span>
    char *lptmp = new char[len+1];
     memset(lptmp, '\0', len+1);
    while(en_len<len)//输入输出字符串够长,并且是AES_BLOCK_SIZE的整数倍,需要严格限制
    {
    	AES_encrypt((unsigned char*)in, (unsigned char*)lptmp, &aes);
    	in+=AES_BLOCK_SIZE;
    	<span style="font-family: 'Hiragino Sans GB W3', 'Hiragino Sans GB', Arial, Helvetica, simsun, u5b8bu4f53;">lptmp</span><span style="font-family: 'Hiragino Sans GB W3', 'Hiragino Sans GB', Arial, Helvetica, simsun, u5b8bu4f53;">+=AES_BLOCK_SIZE;</span>
    	en_len+=AES_BLOCK_SIZE;
<span style="color:#372a18;">        //hex(lptmp)  </span><strong><span style="color:#ff0000;">那么就发现第一个数据块加密的结果是对的,后面就错误了,加密后的数据很多是0,查了openssl的</span></strong>
<strong><span style="color:#ff0000;">        //源代码这个aes这块的加解密是线程安全的,有谁知道原因?</span></strong>
    }
    if(lptmp)
    {
       delete []lptmp;
       lptmp = NULL;
    }
    return 1;
}

最后给出一个链接,利用openssl的AES接口进行编程。
openssl之aes编程(AES_cbc_encrypt 与 AES_encrypt)   参考资料:
http://www.baike.com/wiki/AES%E5%8A%A0%E5%AF%86%E7%AE%97%E6%B3%95 (互动百科)

分组对称加密模式:ECB/CBC/CFB/OFB缺CTR

AES CBC和CTR加解密实例
http://fossies.org/dox/openssl-1.0.1f/index.html
 (详细源码)

    原文作者:TensorFlow群469331966
    原文地址: https://blog.csdn.net/chary8088/article/details/21124495
    本文转自网络文章,转载此文章仅为分享知识,如有侵权,请联系博主进行删除。
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