#ifndef __MD5_H__
#define __MD5_H__
#include
#include
#include
#include
#include "stdint.h"
#define SINGLE_ONE_BIT 0x80
#define BLOCK_SIZE 512
#define MOD_SIZE 448
#define APP_SIZE 64
#define BITS 8
// MD5 Chaining Variable
#define A 0x67452301UL
#define B 0xEFCDAB89UL
#define C 0x98BADCFEUL
#define D 0x10325476UL
typedef struct
{
char *str;
uint32_t len;
}MD5String;
int32_t md5 ( char *argv, uint8_t *md5_32);
#endif
/*
* modified by anqiren 2014/12/10 V1.0bat
*/
#include
#include
#include
#include "md5.h"
const uint32_t X[4][2] = {{0, 1}, {1, 5}, {5, 3}, {0, 7}};
const uint32_t S[4][4] = {{ 7, 12, 17, 22 },{ 5, 9 , 14, 20 },{ 4, 11, 16, 23 },{ 6, 10, 15, 21 }};
uint32_t F( uint32_t X, uint32_t Y, uint32_t Z )
{
return ( X & Y ) | ( ~X & Z );
}uint32_t G( uint32_t X, uint32_t Y, uint32_t Z )
{
return ( X & Z ) | ( Y & ~Z );
}
uint32_t H( uint32_t X, uint32_t Y, uint32_t Z )
{
return X ^ Y ^ Z;
}
uint32_t I( uint32_t X, uint32_t Y, uint32_t Z )
{
return Y ^ ( X | ~Z );
} // rotates x left s bits.
uint32_t rotate_left( uint32_t x, uint32_t s )
{
return ( x << s ) | ( x >> ( 32 - s ) );
}
// Pre-processin
uint32_t count_padding_bits ( uint32_t length )
{
// uint32_t div = length * BITS / BLOCK_SIZE;
uint32_t mod = length * BITS % BLOCK_SIZE;
uint32_t c_bits;
if ( mod == 0 )
{
c_bits = MOD_SIZE;
}
else
{
c_bits = ( MOD_SIZE + BLOCK_SIZE - mod ) % BLOCK_SIZE;
}
return c_bits / BITS;
}MD5String append_padding_bits ( char * argv )
{
uint32_t msg_length = strlen ( argv );
uint32_t bit_length = count_padding_bits ( msg_length );
uint64_t app_length = msg_length * BITS;
MD5String string;
string.str = (char *)malloc(msg_length + bit_length + APP_SIZE / BITS);
strncpy ( string.str, argv, msg_length );
memset ( string.str + msg_length, 0, bit_length );
string.str [ msg_length ] = SINGLE_ONE_BIT;
memmove ( string.str + msg_length + bit_length, (char *)&app_length, sizeof( uint64_t ) );
string.len = msg_length + bit_length + sizeof( uint64_t );
return string;
}int32_t md5 (char *argv, uint8_t *md5_32)
{
MD5String string;
uint32_t w[16];
uint32_t chain[4];
uint32_t state[4];
// uint8_t r[16];
uint32_t ( *auxi[ 4 ])( uint32_t, uint32_t, uint32_t ) = { F, G, H, I };
int sIdx;
int wIdx;
string = append_padding_bits ( argv );
chain[0] = A;
chain[1] = B;
chain[2] = C;
chain[3] = D;
for (uint32_t j = 0; j < string.len; j += BLOCK_SIZE / BITS)
{
memmove ( (char *)w, string.str + j, BLOCK_SIZE / BITS );
memmove ( state, chain, sizeof(chain) );
for ( uint8_t roundIdx = 0; roundIdx < 4; roundIdx++ )
{
wIdx = X[ roundIdx ][ 0 ];
sIdx = 0; for (uint8_t i = 0; i < 16; i++ )
{
state[sIdx] = state [(sIdx + 1)%4] + rotate_left( state[sIdx] +(*auxi[ roundIdx])( state[(sIdx+1) % 4],
state[(sIdx+2) % 4],
state[(sIdx+3) % 4]) + w[ wIdx ] + (uint32_t)floor((1ULL << 32) * fabs(sin( roundIdx * 16 + i + 1 )) ),
S[ roundIdx ][ i % 4 ]);
sIdx = ( sIdx + 3 ) % 4;
wIdx = ( wIdx + X[ roundIdx ][ 1 ] ) & 0xF;
}
}
chain[ 0 ] += state[ 0 ];
chain[ 1 ] += state[ 1 ];
chain[ 2 ] += state[ 2 ];
chain[ 3 ] += state[ 3 ];
}
memmove ( md5_32 + 0, (char *)&chain[0], sizeof(uint32_t) );
memmove ( md5_32 + 4, (char *)&chain[1], sizeof(uint32_t) );
memmove ( md5_32 + 8, (char *)&chain[2], sizeof(uint32_t) );
memmove ( md5_32 + 12, (char *)&chain[3], sizeof(uint32_t) );
free(string.str);
string.str = NULL;
return EXIT_SUCCESS;
}