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n2n/twofish.c

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Initial SVN import of n2n v2
2016-10-23 10:46:15 +02:00
/* $Id: twofish.c,v 2.0 2002/08/11 22:32:25 fknobbe Exp $
*
*
* Copyright (C) 1997-2000 The Cryptix Foundation Limited.
* Copyright (C) 2000 Farm9.
* Copyright (C) 2001 Frank Knobbe.
* All rights reserved.
*
* For Cryptix code:
* Use, modification, copying and distribution of this software is subject
* the terms and conditions of the Cryptix General Licence. You should have
* received a copy of the Cryptix General Licence along with this library;
* if not, you can download a copy from http://www.cryptix.org/ .
*
* For Farm9:
* --- jojo@farm9.com, August 2000, converted from Java to C++, added CBC mode and
* ciphertext stealing technique, added AsciiTwofish class for easy encryption
* decryption of text strings
*
* Frank Knobbe <frank@knobbe.us>:
* --- April 2001, converted from C++ to C, prefixed global variables
* with TwoFish, substituted some defines, changed functions to make use of
* variables supplied in a struct, modified and added routines for modular calls.
* Cleaned up the code so that defines are used instead of fixed 16's and 32's.
* Created two general purpose crypt routines for one block and multiple block
* encryption using Joh's CBC code.
* Added crypt routines that use a header (with a magic and data length).
* (Basically a major rewrite).
*
* Note: Routines labeled _TwoFish are private and should not be used
* (or with extreme caution).
*
*/
#ifndef __TWOFISH_LIBRARY_SOURCE__
#define __TWOFISH_LIBRARY_SOURCE__
#include <string.h>
#include <stdlib.h>
#include <time.h>
#include <ctype.h>
#include <sys/types.h>
#include "twofish.h"
bool TwoFish_srand=TRUE; /* if TRUE, first call of TwoFishInit will seed rand(); */
/* of TwoFishInit */
/* Fixed 8x8 permutation S-boxes */
static const uint8_t TwoFish_P[2][256] =
{
{ /* p0 */
0xA9, 0x67, 0xB3, 0xE8, 0x04, 0xFD, 0xA3, 0x76, 0x9A, 0x92, 0x80, 0x78,
0xE4, 0xDD, 0xD1, 0x38, 0x0D, 0xC6, 0x35, 0x98, 0x18, 0xF7, 0xEC, 0x6C,
0x43, 0x75, 0x37, 0x26, 0xFA, 0x13, 0x94, 0x48, 0xF2, 0xD0, 0x8B, 0x30,
0x84, 0x54, 0xDF, 0x23, 0x19, 0x5B, 0x3D, 0x59, 0xF3, 0xAE, 0xA2, 0x82,
0x63, 0x01, 0x83, 0x2E, 0xD9, 0x51, 0x9B, 0x7C, 0xA6, 0xEB, 0xA5, 0xBE,
0x16, 0x0C, 0xE3, 0x61, 0xC0, 0x8C, 0x3A, 0xF5, 0x73, 0x2C, 0x25, 0x0B,
0xBB, 0x4E, 0x89, 0x6B, 0x53, 0x6A, 0xB4, 0xF1, 0xE1, 0xE6, 0xBD, 0x45,
0xE2, 0xF4, 0xB6, 0x66, 0xCC, 0x95, 0x03, 0x56, 0xD4, 0x1C, 0x1E, 0xD7,
0xFB, 0xC3, 0x8E, 0xB5, 0xE9, 0xCF, 0xBF, 0xBA, 0xEA, 0x77, 0x39, 0xAF,
0x33, 0xC9, 0x62, 0x71, 0x81, 0x79, 0x09, 0xAD, 0x24, 0xCD, 0xF9, 0xD8,
0xE5, 0xC5, 0xB9, 0x4D, 0x44, 0x08, 0x86, 0xE7, 0xA1, 0x1D, 0xAA, 0xED,
0x06, 0x70, 0xB2, 0xD2, 0x41, 0x7B, 0xA0, 0x11, 0x31, 0xC2, 0x27, 0x90,
0x20, 0xF6, 0x60, 0xFF, 0x96, 0x5C, 0xB1, 0xAB, 0x9E, 0x9C, 0x52, 0x1B,
0x5F, 0x93, 0x0A, 0xEF, 0x91, 0x85, 0x49, 0xEE, 0x2D, 0x4F, 0x8F, 0x3B,
0x47, 0x87, 0x6D, 0x46, 0xD6, 0x3E, 0x69, 0x64, 0x2A, 0xCE, 0xCB, 0x2F,
0xFC, 0x97, 0x05, 0x7A, 0xAC, 0x7F, 0xD5, 0x1A, 0x4B, 0x0E, 0xA7, 0x5A,
0x28, 0x14, 0x3F, 0x29, 0x88, 0x3C, 0x4C, 0x02, 0xB8, 0xDA, 0xB0, 0x17,
0x55, 0x1F, 0x8A, 0x7D, 0x57, 0xC7, 0x8D, 0x74, 0xB7, 0xC4, 0x9F, 0x72,
0x7E, 0x15, 0x22, 0x12, 0x58, 0x07, 0x99, 0x34, 0x6E, 0x50, 0xDE, 0x68,
0x65, 0xBC, 0xDB, 0xF8, 0xC8, 0xA8, 0x2B, 0x40, 0xDC, 0xFE, 0x32, 0xA4,
0xCA, 0x10, 0x21, 0xF0, 0xD3, 0x5D, 0x0F, 0x00, 0x6F, 0x9D, 0x36, 0x42,
0x4A, 0x5E, 0xC1, 0xE0
},
{ /* p1 */
0x75, 0xF3, 0xC6, 0xF4, 0xDB, 0x7B, 0xFB, 0xC8, 0x4A, 0xD3, 0xE6, 0x6B,
0x45, 0x7D, 0xE8, 0x4B, 0xD6, 0x32, 0xD8, 0xFD, 0x37, 0x71, 0xF1, 0xE1,
0x30, 0x0F, 0xF8, 0x1B, 0x87, 0xFA, 0x06, 0x3F, 0x5E, 0xBA, 0xAE, 0x5B,
0x8A, 0x00, 0xBC, 0x9D, 0x6D, 0xC1, 0xB1, 0x0E, 0x80, 0x5D, 0xD2, 0xD5,
0xA0, 0x84, 0x07, 0x14, 0xB5, 0x90, 0x2C, 0xA3, 0xB2, 0x73, 0x4C, 0x54,
0x92, 0x74, 0x36, 0x51, 0x38, 0xB0, 0xBD, 0x5A, 0xFC, 0x60, 0x62, 0x96,
0x6C, 0x42, 0xF7, 0x10, 0x7C, 0x28, 0x27, 0x8C, 0x13, 0x95, 0x9C, 0xC7,
0x24, 0x46, 0x3B, 0x70, 0xCA, 0xE3, 0x85, 0xCB, 0x11, 0xD0, 0x93, 0xB8,
0xA6, 0x83, 0x20, 0xFF, 0x9F, 0x77, 0xC3, 0xCC, 0x03, 0x6F, 0x08, 0xBF,
0x40, 0xE7, 0x2B, 0xE2, 0x79, 0x0C, 0xAA, 0x82, 0x41, 0x3A, 0xEA, 0xB9,
0xE4, 0x9A, 0xA4, 0x97, 0x7E, 0xDA, 0x7A, 0x17, 0x66, 0x94, 0xA1, 0x1D,
0x3D, 0xF0, 0xDE, 0xB3, 0x0B, 0x72, 0xA7, 0x1C, 0xEF, 0xD1, 0x53, 0x3E,
0x8F, 0x33, 0x26, 0x5F, 0xEC, 0x76, 0x2A, 0x49, 0x81, 0x88, 0xEE, 0x21,
0xC4, 0x1A, 0xEB, 0xD9, 0xC5, 0x39, 0x99, 0xCD, 0xAD, 0x31, 0x8B, 0x01,
0x18, 0x23, 0xDD, 0x1F, 0x4E, 0x2D, 0xF9, 0x48, 0x4F, 0xF2, 0x65, 0x8E,
0x78, 0x5C, 0x58, 0x19, 0x8D, 0xE5, 0x98, 0x57, 0x67, 0x7F, 0x05, 0x64,
0xAF, 0x63, 0xB6, 0xFE, 0xF5, 0xB7, 0x3C, 0xA5, 0xCE, 0xE9, 0x68, 0x44,
0xE0, 0x4D, 0x43, 0x69, 0x29, 0x2E, 0xAC, 0x15, 0x59, 0xA8, 0x0A, 0x9E,
0x6E, 0x47, 0xDF, 0x34, 0x35, 0x6A, 0xCF, 0xDC, 0x22, 0xC9, 0xC0, 0x9B,
0x89, 0xD4, 0xED, 0xAB, 0x12, 0xA2, 0x0D, 0x52, 0xBB, 0x02, 0x2F, 0xA9,
0xD7, 0x61, 0x1E, 0xB4, 0x50, 0x04, 0xF6, 0xC2, 0x16, 0x25, 0x86, 0x56,
0x55, 0x09, 0xBE, 0x91
}
};
static bool TwoFish_MDSready=FALSE;
static uint32_t TwoFish_MDS[4][256]; /* TwoFish_MDS matrix */
#define TwoFish_LFSR1(x) (((x)>>1)^(((x)&0x01)?TwoFish_MDS_GF_FDBK/2:0))
#define TwoFish_LFSR2(x) (((x)>>2)^(((x)&0x02)?TwoFish_MDS_GF_FDBK/2:0)^(((x)&0x01)?TwoFish_MDS_GF_FDBK/4:0))
#define TwoFish_Mx_1(x) ((uint32_t)(x)) /* force result to dword so << will work */
#define TwoFish_Mx_X(x) ((uint32_t)((x)^TwoFish_LFSR2(x))) /* 5B */
#define TwoFish_Mx_Y(x) ((uint32_t)((x)^TwoFish_LFSR1(x)^TwoFish_LFSR2(x))) /* EF */
#define TwoFish_RS_rem(x) { uint8_t b=(uint8_t)(x>>24); uint32_t g2=((b<<1)^((b&0x80)?TwoFish_RS_GF_FDBK:0))&0xFF; uint32_t g3=((b>>1)&0x7F)^((b&1)?TwoFish_RS_GF_FDBK>>1:0)^g2; x=(x<<8)^(g3<<24)^(g2<<16)^(g3<<8)^b; }
/*#define TwoFish__b(x,N) (((uint8_t *)&x)[((N)&3)^TwoFish_ADDR_XOR])*/ /* pick bytes out of a dword */
#define TwoFish_b0(x) TwoFish__b(x,0) /* extract LSB of uint32_t */
#define TwoFish_b1(x) TwoFish__b(x,1)
#define TwoFish_b2(x) TwoFish__b(x,2)
#define TwoFish_b3(x) TwoFish__b(x,3) /* extract MSB of uint32_t */
uint8_t TwoFish__b(uint32_t x,int n)
{ n&=3;
while(n-->0)
x>>=8;
return (uint8_t)x;
}
/* TwoFish Initialization
*
* This routine generates a global data structure for use with TwoFish,
* initializes important values (such as subkeys, sBoxes), generates subkeys
* and precomputes the MDS matrix if not already done.
*
* Input: User supplied password (will be appended by default password of 'SnortHas2FishEncryptionRoutines!')
*
* Output: Pointer to TWOFISH structure. This data structure contains key dependent data.
* This pointer is used with all other crypt functions.
*/
TWOFISH *TwoFishInit(const uint8_t *userkey, uint32_t keysize)
{ TWOFISH *tfdata;
int i,x,m;
uint8_t tkey[TwoFish_KEY_LENGTH+40];
memset( tkey, 0, TwoFish_KEY_LENGTH+40 );
tfdata=(TWOFISH *)malloc(sizeof(TWOFISH)); /* allocate the TwoFish structure */
if(tfdata!=NULL)
{
/* Changes here prevented a dangerous random key segment for keys of length < TwoFish_KEY_LENGTH */
if(keysize > 0)
{
memcpy( tkey, userkey, keysize ); /* The rest will be zeros */
}
else
{
memcpy( tkey, TwoFish_DEFAULT_PW, TwoFish_DEFAULT_PW_LEN ); /* if no key defined, use default password */
}
/* This loop is awful - surely a loop on memcpy() would be clearer and more efficient */
for(i=0,x=0,m=keysize;i<TwoFish_KEY_LENGTH;i++) /* copy into data structure */
{
tfdata->key[i]=tkey[x++]; /* fill the whole keyspace with repeating key. */
if(x==m)
x=0;
}
if(!TwoFish_MDSready)
_TwoFish_PrecomputeMDSmatrix(); /* "Wake Up, Neo" */
_TwoFish_MakeSubKeys(tfdata); /* generate subkeys */
_TwoFish_ResetCBC(tfdata); /* reset the CBC */
tfdata->output=NULL; /* nothing to output yet */
tfdata->dontflush=FALSE; /* reset decrypt skip block flag */
if(TwoFish_srand)
{
TwoFish_srand=FALSE;
/* REVISIT: BbMaj7 : Should choose something with less predictability
* particularly for embedded targets with no real-time clock. */
srand((unsigned int)time(NULL));
}
}
return tfdata; /* return the data pointer */
}
void TwoFishDestroy(TWOFISH *tfdata)
{ if(tfdata!=NULL)
free(tfdata);
}
/* en/decryption with CBC mode */
uint32_t _TwoFish_CryptRawCBC(uint8_t *in,uint8_t *out,uint32_t len,bool decrypt,TWOFISH *tfdata)
{ uint32_t rl;
rl=len; /* remember how much data to crypt. */
while(len>TwoFish_BLOCK_SIZE) /* and now we process block by block. */
{ _TwoFish_BlockCrypt(in,out,TwoFish_BLOCK_SIZE,decrypt,tfdata); /* de/encrypt it. */
in+=TwoFish_BLOCK_SIZE; /* adjust pointers. */
out+=TwoFish_BLOCK_SIZE;
len-=TwoFish_BLOCK_SIZE;
}
if(len>0) /* if we have less than a block left... */
_TwoFish_BlockCrypt(in,out,len,decrypt,tfdata); /* ...then we de/encrypt that too. */
if(tfdata->qBlockDefined && !tfdata->dontflush) /* in case len was exactly one block... */
_TwoFish_FlushOutput(tfdata->qBlockCrypt,TwoFish_BLOCK_SIZE,tfdata); /* ...we need to write the... */
/* ...remaining bytes of the buffer */
return rl;
}
/* en/decryption on one block only */
uint32_t _TwoFish_CryptRaw16(uint8_t *in,uint8_t *out,uint32_t len,bool decrypt,TWOFISH *tfdata)
{ /* qBlockPlain already zero'ed through ResetCBC */
memcpy(tfdata->qBlockPlain,in,len); /* toss the data into it. */
_TwoFish_BlockCrypt16(tfdata->qBlockPlain,tfdata->qBlockCrypt,decrypt,tfdata); /* encrypt just that block without CBC. */
memcpy(out,tfdata->qBlockCrypt,TwoFish_BLOCK_SIZE); /* and return what we got */
return TwoFish_BLOCK_SIZE;
}
/* en/decryption without reset of CBC and output assignment */
uint32_t _TwoFish_CryptRaw(uint8_t *in,uint8_t *out,uint32_t len,bool decrypt,TWOFISH *tfdata)
{
if(in!=NULL && out!=NULL && len>0 && tfdata!=NULL) /* if we have valid data, then... */
{ if(len>TwoFish_BLOCK_SIZE) /* ...check if we have more than one block. */
return _TwoFish_CryptRawCBC(in,out,len,decrypt,tfdata); /* if so, use the CBC routines... */
else
return _TwoFish_CryptRaw16(in,out,len,decrypt,tfdata); /* ...otherwise just do one block. */
}
return 0;
}
/* TwoFish Raw Encryption
*
* Does not use header, but does use CBC (if more than one block has to be encrypted).
*
* Input: Pointer to the buffer of the plaintext to be encrypted.
* Pointer to the buffer receiving the ciphertext.
* The length of the plaintext buffer.
* The TwoFish structure.
*
* Output: The amount of bytes encrypted if successful, otherwise 0.
*/
uint32_t TwoFishEncryptRaw(uint8_t *in,
uint8_t *out,
uint32_t len,
TWOFISH *tfdata)
{ _TwoFish_ResetCBC(tfdata); /* reset CBC flag. */
tfdata->output=out; /* output straight into output buffer. */
return _TwoFish_CryptRaw(in,out,len,FALSE,tfdata); /* and go for it. */
}
/* TwoFish Raw Decryption
*
* Does not use header, but does use CBC (if more than one block has to be decrypted).
*
* Input: Pointer to the buffer of the ciphertext to be decrypted.
* Pointer to the buffer receiving the plaintext.
* The length of the ciphertext buffer (at least one cipher block).
* The TwoFish structure.
*
* Output: The amount of bytes decrypted if successful, otherwise 0.
*/
uint32_t TwoFishDecryptRaw(uint8_t *in,
uint8_t *out,
uint32_t len,
TWOFISH *tfdata)
{ _TwoFish_ResetCBC(tfdata); /* reset CBC flag. */
tfdata->output=out; /* output straight into output buffer. */
return _TwoFish_CryptRaw(in,out,len,TRUE,tfdata); /* and go for it. */
}
/* TwoFish Free
*
* Free's the allocated buffer.
*
* Input: Pointer to the TwoFish structure
*
* Output: (none)
*/
void TwoFishFree(TWOFISH *tfdata)
{ if(tfdata->output!=NULL) /* if a valid buffer is present... */
{ free(tfdata->output); /* ...then we free it for you... */
tfdata->output=NULL; /* ...and mark as such. */
}
}
/* TwoFish Set Output
*
* If you want to allocate the output buffer yourself,
* then you can set it with this function.
*
* Input: Pointer to your output buffer
* Pointer to the TwoFish structure
*
* Output: (none)
*/
void TwoFishSetOutput(uint8_t *outp,TWOFISH *tfdata)
{ tfdata->output=outp; /* (do we really need a function for this?) */
}
/* TwoFish Alloc
*
* Allocates enough memory for the output buffer that would be required
*
* Input: Length of the plaintext.
* Boolean flag for BinHex Output.
* Pointer to the TwoFish structure.
*
* Output: Returns a pointer to the memory allocated.
*/
void *TwoFishAlloc(uint32_t len,bool binhex,bool decrypt,TWOFISH *tfdata)
{
/* TwoFishFree(tfdata); */ /* (don't for now) discard whatever was allocated earlier. */
if(decrypt) /* if decrypting... */
{ if(binhex) /* ...and input is binhex encoded... */
len/=2; /* ...use half as much for output. */
len-=TwoFish_BLOCK_SIZE; /* Also, subtract the size of the header. */
}
else
{ len+=TwoFish_BLOCK_SIZE; /* the size is just increased by the header... */
if(binhex)
len*=2; /* ...and doubled if output is to be binhexed. */
}
tfdata->output=malloc(len+TwoFish_BLOCK_SIZE);/* grab some memory...plus some extra (it's running over somewhere, crashes without extra padding) */
return tfdata->output; /* ...and return to caller. */
}
/* bin2hex and hex2bin conversion */
void _TwoFish_BinHex(uint8_t *buf,uint32_t len,bool bintohex)
{ uint8_t *pi,*po,c;
if(bintohex)
{ for(pi=buf+len-1,po=buf+(2*len)-1;len>0;pi--,po--,len--) /* let's start from the end of the bin block. */
{ c=*pi; /* grab value. */
c&=15; /* use lower 4 bits. */
if(c>9) /* convert to ascii. */
c+=('a'-10);
else
c+='0';
*po--=c; /* set the lower nibble. */
c=*pi; /* grab value again. */
c>>=4; /* right shift 4 bits. */
c&=15; /* make sure we only have 4 bits. */
if(c>9) /* convert to ascii. */
c+=('a'-10);
else
c+='0';
*po=c; /* set the higher nibble. */
} /* and keep going. */
}
else
{ for(pi=buf,po=buf;len>0;pi++,po++,len-=2) /* let's start from the beginning of the hex block. */
{ c=tolower(*pi++)-'0'; /* grab higher nibble. */
if(c>9) /* convert to value. */
c-=('0'-9);
*po=c<<4; /* left shit 4 bits. */
c=tolower(*pi)-'0'; /* grab lower nibble. */
if(c>9) /* convert to value. */
c-=('0'-9);
*po|=c; /* and add to value. */
}
}
}
/* TwoFish Encryption
*
* Uses header and CBC. If the output area has not been intialized with TwoFishAlloc,
* this routine will alloc the memory. In addition, it will include a small 'header'
* containing the magic and some salt. That way the decrypt routine can check if the
* packet got decrypted successfully, and return 0 instead of garbage.
*
* Input: Pointer to the buffer of the plaintext to be encrypted.
* Pointer to the pointer to the buffer receiving the ciphertext.
* The pointer either points to user allocated output buffer space, or to NULL, in which case
* this routine will set the pointer to the buffer allocated through the struct.
* The length of the plaintext buffer.
* Can be -1 if the input is a null terminated string, in which case we'll count for you.
* Boolean flag for BinHex Output (if used, output will be twice as large as input).
* Note: BinHex conversion overwrites (converts) input buffer!
* The TwoFish structure.
*
* Output: The amount of bytes encrypted if successful, otherwise 0.
*/
uint32_t TwoFishEncrypt(uint8_t *in,
uint8_t **out,
signed long len,
bool binhex,
TWOFISH *tfdata)
{ uint32_t ilen,olen;
#if 0
/* This is so broken it doesn't deserve to live. */
if(len== -1) /* if we got -1 for len, we'll assume IN is a... */
ilen=strlen(in); /* ...\0 terminated string and figure len out ourselves... */
else
ilen=len; /* ...otherwise we trust you supply a correct length. */
#endif
ilen = len;
if(in!=NULL && out!=NULL && ilen>0 && tfdata!=NULL) /* if we got usable stuff, we'll do it. */
{ if(*out==NULL) /* if OUT points to a NULL pointer... */
*out=TwoFishAlloc(ilen,binhex,FALSE,tfdata); /* ...we'll (re-)allocate buffer space. */
if(*out!=NULL)
{ tfdata->output=*out; /* set output buffer. */
tfdata->header.salt=rand()*65536+rand(); /* toss in some salt. */
tfdata->header.length[0]= (uint8_t)(ilen);
tfdata->header.length[1]= (uint8_t)(ilen>>8);
tfdata->header.length[2]= (uint8_t)(ilen>>16);
tfdata->header.length[3]= (uint8_t)(ilen>>24);
memcpy(tfdata->header.magic,TwoFish_MAGIC,TwoFish_MAGIC_LEN); /* set the magic. */
olen=TwoFish_BLOCK_SIZE; /* set output counter. */
_TwoFish_ResetCBC(tfdata); /* reset the CBC flag */
_TwoFish_BlockCrypt((uint8_t *)&(tfdata->header),*out,olen,FALSE,tfdata); /* encrypt first block (without flush on 16 byte boundary). */
olen+=_TwoFish_CryptRawCBC(in,*out+TwoFish_BLOCK_SIZE,ilen,FALSE,tfdata); /* and encrypt the rest (we do not reset the CBC flag). */
if(binhex) /* if binhex... */
{ _TwoFish_BinHex(*out,olen,TRUE); /* ...convert output to binhex... */
olen*=2; /* ...and size twice as large. */
}
tfdata->output=*out;
return olen;
}
}
return 0;
}
/* TwoFish Decryption
*
* Uses header and CBC. If the output area has not been intialized with TwoFishAlloc,
* this routine will alloc the memory. In addition, it will check the small 'header'
* containing the magic. If magic does not match we return 0. Otherwise we return the
* amount of bytes decrypted (should be the same as the length in the header).
*
* Input: Pointer to the buffer of the ciphertext to be decrypted.
* Pointer to the pointer to the buffer receiving the plaintext.
* The pointer either points to user allocated output buffer space, or to NULL, in which case
* this routine will set the pointer to the buffer allocated through the struct.
* The length of the ciphertext buffer.
* Can be -1 if the input is a null terminated binhex string, in which case we'll count for you.
* Boolean flag for BinHex Input (if used, plaintext will be half as large as input).
* Note: BinHex conversion overwrites (converts) input buffer!
* The TwoFish structure.
*
* Output: The amount of bytes decrypted if successful, otherwise 0.
*/
uint32_t TwoFishDecrypt(uint8_t *in,
uint8_t **out,
signed long len,
bool binhex,
TWOFISH *tfdata)
{ uint32_t ilen,elen,olen;
const uint8_t cmagic[TwoFish_MAGIC_LEN]=TwoFish_MAGIC;
uint8_t *tbuf;
#if 0
/* This is so broken it doesn't deserve to live. */
if(len== -1) /* if we got -1 for len, we'll assume IN is a... */
ilen=strlen(in); /* ...\0 terminated string and figure len out ourselves... */
else
ilen=len; /* ...otherwise we trust you supply a correct length. */
#endif
ilen = len;
if(in!=NULL && out!=NULL && ilen>0 && tfdata!=NULL) /* if we got usable stuff, we'll do it. */
{ if(*out==NULL) /* if OUT points to a NULL pointer... */
*out=TwoFishAlloc(ilen,binhex,TRUE,tfdata); /* ...we'll (re-)allocate buffer space. */
if(*out!=NULL)
{ if(binhex) /* if binhex... */
{ _TwoFish_BinHex(in,ilen,FALSE); /* ...convert input to values... */
ilen/=2; /* ...and size half as much. */
}
_TwoFish_ResetCBC(tfdata); /* reset the CBC flag. */
tbuf=(uint8_t *)malloc(ilen+TwoFish_BLOCK_SIZE); /* get memory for data and header. */
if(tbuf==NULL)
return 0;
tfdata->output=tbuf; /* set output to temp buffer. */
olen=_TwoFish_CryptRawCBC(in,tbuf,ilen,TRUE,tfdata)-TwoFish_BLOCK_SIZE; /* decrypt the whole thing. */
memcpy(&(tfdata->header),tbuf,TwoFish_BLOCK_SIZE); /* copy first block into header. */
tfdata->output=*out;
for(elen=0;elen<TwoFish_MAGIC_LEN;elen++) /* compare magic. */
if(tfdata->header.magic[elen]!=cmagic[elen])
break;
if(elen==TwoFish_MAGIC_LEN) /* if magic matches then... */
{ elen=(tfdata->header.length[0]) |
(tfdata->header.length[1])<<8 |
(tfdata->header.length[2])<<16 |
(tfdata->header.length[3])<<24; /* .. we know how much to expect. */
if(elen>olen) /* adjust if necessary. */
elen=olen;
memcpy(*out,tbuf+TwoFish_BLOCK_SIZE,elen); /* copy data into intended output. */
free(tbuf);
return elen;
}
free(tbuf);
}
}
return 0;
}
void _TwoFish_PrecomputeMDSmatrix(void) /* precompute the TwoFish_MDS matrix */
{ uint32_t m1[2];
uint32_t mX[2];
uint32_t mY[2];
uint32_t i, j;
for (i = 0; i < 256; i++)
{ j = TwoFish_P[0][i] & 0xFF; /* compute all the matrix elements */
m1[0] = j;
mX[0] = TwoFish_Mx_X( j ) & 0xFF;
mY[0] = TwoFish_Mx_Y( j ) & 0xFF;
j = TwoFish_P[1][i] & 0xFF;
m1[1] = j;
mX[1] = TwoFish_Mx_X( j ) & 0xFF;
mY[1] = TwoFish_Mx_Y( j ) & 0xFF;
TwoFish_MDS[0][i] = m1[TwoFish_P_00] | /* fill matrix w/ above elements */
mX[TwoFish_P_00] << 8 |
mY[TwoFish_P_00] << 16 |
mY[TwoFish_P_00] << 24;
TwoFish_MDS[1][i] = mY[TwoFish_P_10] |
mY[TwoFish_P_10] << 8 |
mX[TwoFish_P_10] << 16 |
m1[TwoFish_P_10] << 24;
TwoFish_MDS[2][i] = mX[TwoFish_P_20] |
mY[TwoFish_P_20] << 8 |
m1[TwoFish_P_20] << 16 |
mY[TwoFish_P_20] << 24;
TwoFish_MDS[3][i] = mX[TwoFish_P_30] |
m1[TwoFish_P_30] << 8 |
mY[TwoFish_P_30] << 16 |
mX[TwoFish_P_30] << 24;
}
TwoFish_MDSready=TRUE;
}
void _TwoFish_MakeSubKeys(TWOFISH *tfdata) /* Expand a user-supplied key material into a session key. */
{ uint32_t k64Cnt = TwoFish_KEY_LENGTH / 8;
uint32_t k32e[4]; /* even 32-bit entities */
uint32_t k32o[4]; /* odd 32-bit entities */
uint32_t sBoxKey[4];
uint32_t offset,i,j;
uint32_t A, B, q=0;
uint32_t k0,k1,k2,k3;
uint32_t b0,b1,b2,b3;
/* split user key material into even and odd 32-bit entities and */
/* compute S-box keys using (12, 8) Reed-Solomon code over GF(256) */
for (offset=0,i=0,j=k64Cnt-1;i<4 && offset<TwoFish_KEY_LENGTH;i++,j--)
{ k32e[i] = tfdata->key[offset++];
k32e[i]|= tfdata->key[offset++]<<8;
k32e[i]|= tfdata->key[offset++]<<16;
k32e[i]|= tfdata->key[offset++]<<24;
k32o[i] = tfdata->key[offset++];
k32o[i]|= tfdata->key[offset++]<<8;
k32o[i]|= tfdata->key[offset++]<<16;
k32o[i]|= tfdata->key[offset++]<<24;
sBoxKey[j] = _TwoFish_RS_MDS_Encode( k32e[i], k32o[i] ); /* reverse order */
}
/* compute the round decryption subkeys for PHT. these same subkeys */
/* will be used in encryption but will be applied in reverse order. */
i=0;
while(i < TwoFish_TOTAL_SUBKEYS)
{ A = _TwoFish_F32( k64Cnt, q, k32e ); /* A uses even key entities */
q += TwoFish_SK_BUMP;
B = _TwoFish_F32( k64Cnt, q, k32o ); /* B uses odd key entities */
q += TwoFish_SK_BUMP;
B = B << 8 | B >> 24;
A += B;
tfdata->subKeys[i++] = A; /* combine with a PHT */
A += B;
tfdata->subKeys[i++] = A << TwoFish_SK_ROTL | A >> (32-TwoFish_SK_ROTL);
}
/* fully expand the table for speed */
k0 = sBoxKey[0];
k1 = sBoxKey[1];
k2 = sBoxKey[2];
k3 = sBoxKey[3];
for (i = 0; i < 256; i++)
{ b0 = b1 = b2 = b3 = i;
switch (k64Cnt & 3)
{ case 1: /* 64-bit keys */
tfdata->sBox[ 2*i ] = TwoFish_MDS[0][(TwoFish_P[TwoFish_P_01][b0]) ^ TwoFish_b0(k0)];
tfdata->sBox[ 2*i+1] = TwoFish_MDS[1][(TwoFish_P[TwoFish_P_11][b1]) ^ TwoFish_b1(k0)];
tfdata->sBox[0x200+2*i ] = TwoFish_MDS[2][(TwoFish_P[TwoFish_P_21][b2]) ^ TwoFish_b2(k0)];
tfdata->sBox[0x200+2*i+1] = TwoFish_MDS[3][(TwoFish_P[TwoFish_P_31][b3]) ^ TwoFish_b3(k0)];
break;
case 0: /* 256-bit keys (same as 4) */
b0 = (TwoFish_P[TwoFish_P_04][b0]) ^ TwoFish_b0(k3);
b1 = (TwoFish_P[TwoFish_P_14][b1]) ^ TwoFish_b1(k3);
b2 = (TwoFish_P[TwoFish_P_24][b2]) ^ TwoFish_b2(k3);
b3 = (TwoFish_P[TwoFish_P_34][b3]) ^ TwoFish_b3(k3);
case 3: /* 192-bit keys */
b0 = (TwoFish_P[TwoFish_P_03][b0]) ^ TwoFish_b0(k2);
b1 = (TwoFish_P[TwoFish_P_13][b1]) ^ TwoFish_b1(k2);
b2 = (TwoFish_P[TwoFish_P_23][b2]) ^ TwoFish_b2(k2);
b3 = (TwoFish_P[TwoFish_P_33][b3]) ^ TwoFish_b3(k2);
case 2: /* 128-bit keys */
tfdata->sBox[ 2*i ]=
TwoFish_MDS[0][(TwoFish_P[TwoFish_P_01][(TwoFish_P[TwoFish_P_02][b0]) ^
TwoFish_b0(k1)]) ^ TwoFish_b0(k0)];
tfdata->sBox[ 2*i+1]=
TwoFish_MDS[1][(TwoFish_P[TwoFish_P_11][(TwoFish_P[TwoFish_P_12][b1]) ^
TwoFish_b1(k1)]) ^ TwoFish_b1(k0)];
tfdata->sBox[0x200+2*i ]=
TwoFish_MDS[2][(TwoFish_P[TwoFish_P_21][(TwoFish_P[TwoFish_P_22][b2]) ^
TwoFish_b2(k1)]) ^ TwoFish_b2(k0)];
tfdata->sBox[0x200+2*i+1]=
TwoFish_MDS[3][(TwoFish_P[TwoFish_P_31][(TwoFish_P[TwoFish_P_32][b3]) ^
TwoFish_b3(k1)]) ^ TwoFish_b3(k0)];
}
}
}
/**
* Encrypt or decrypt exactly one block of plaintext in CBC mode.
* Use "ciphertext stealing" technique described on pg. 196
* of "Applied Cryptography" to encrypt the final partial
* (i.e. <16 byte) block if necessary.
*
* jojo: the "ciphertext stealing" requires we read ahead and have
* special handling for the last two blocks. Because of this, the
* output from the TwoFish algorithm is handled internally here.
* It would be better to have a higher level handle this as well as
* CBC mode. Unfortunately, I've mixed the two together, which is
* pretty crappy... The Java version separates these out correctly.
*
* fknobbe: I have reduced the CBC mode to work on memory buffer only.
* Higher routines should use an intermediate buffer and handle
* their output seperately (mainly so the data can be flushed
* in one chunk, not seperate 16 byte blocks...)
*
* @param in The plaintext.
* @param out The ciphertext
* @param size how much to encrypt
* @param tfdata: Pointer to the global data structure containing session keys.
* @return none
*/
void _TwoFish_BlockCrypt(uint8_t *in,uint8_t *out,uint32_t size,int decrypt,TWOFISH *tfdata)
{ uint8_t PnMinusOne[TwoFish_BLOCK_SIZE];
uint8_t CnMinusOne[TwoFish_BLOCK_SIZE];
uint8_t CBCplusCprime[TwoFish_BLOCK_SIZE];
uint8_t Pn[TwoFish_BLOCK_SIZE];
uint8_t *p,*pout;
uint32_t i;
/* here is where we implement CBC mode and cipher block stealing */
if(size==TwoFish_BLOCK_SIZE)
{ /* if we are encrypting, CBC means we XOR the plain text block with the */
/* previous cipher text block before encrypting */
if(!decrypt && tfdata->qBlockDefined)
{ for(p=in,i=0;i<TwoFish_BLOCK_SIZE;i++,p++)
Pn[i]=*p ^ tfdata->qBlockCrypt[i]; /* FK: I'm copying the xor'ed input into Pn... */
}
else
memcpy(Pn,in,TwoFish_BLOCK_SIZE); /* FK: same here. we work of Pn all the time. */
/* TwoFish block level encryption or decryption */
_TwoFish_BlockCrypt16(Pn,out,decrypt,tfdata);
/* if we are decrypting, CBC means we XOR the result of the decryption */
/* with the previous cipher text block to get the resulting plain text */
if(decrypt && tfdata->qBlockDefined)
{ for (p=out,i=0;i<TwoFish_BLOCK_SIZE;i++,p++)
*p^=tfdata->qBlockPlain[i];
}
/* save the input and output blocks, since CBC needs these for XOR */
/* operations */
_TwoFish_qBlockPush(Pn,out,tfdata);
}
else
{ /* cipher block stealing, we are at Pn, */
/* but since Cn-1 must now be replaced with CnC' */
/* we pop it off, and recalculate Cn-1 */
if(decrypt)
{ /* We are on an odd block, and had to do cipher block stealing, */
/* so the PnMinusOne has to be derived differently. */
/* First we decrypt it into CBC and C' */
_TwoFish_qBlockPop(CnMinusOne,PnMinusOne,tfdata);
_TwoFish_BlockCrypt16(CnMinusOne,CBCplusCprime,decrypt,tfdata);
/* we then xor the first few bytes with the "in" bytes (Cn) */
/* to recover Pn, which we put in out */
for(p=in,pout=out,i=0;i<size;i++,p++,pout++)
*pout=*p ^ CBCplusCprime[i];
/* We now recover the original CnMinusOne, which consists of */
/* the first "size" bytes of "in" data, followed by the */
/* "Cprime" portion of CBCplusCprime */
for(p=in,i=0;i<size;i++,p++)
CnMinusOne[i]=*p;
for(;i<TwoFish_BLOCK_SIZE;i++)
CnMinusOne[i]=CBCplusCprime[i];
/* we now decrypt CnMinusOne to get PnMinusOne xored with Cn-2 */
_TwoFish_BlockCrypt16(CnMinusOne,PnMinusOne,decrypt,tfdata);
for(i=0;i<TwoFish_BLOCK_SIZE;i++)
PnMinusOne[i]=PnMinusOne[i] ^ tfdata->prevCipher[i];
/* So at this point, out has PnMinusOne */
_TwoFish_qBlockPush(CnMinusOne,PnMinusOne,tfdata);
_TwoFish_FlushOutput(tfdata->qBlockCrypt,TwoFish_BLOCK_SIZE,tfdata);
_TwoFish_FlushOutput(out,size,tfdata);
}
else
{ _TwoFish_qBlockPop(PnMinusOne,CnMinusOne,tfdata);
memset(Pn,0,TwoFish_BLOCK_SIZE);
memcpy(Pn,in,size);
for(i=0;i<TwoFish_BLOCK_SIZE;i++)
Pn[i]^=CnMinusOne[i];
_TwoFish_BlockCrypt16(Pn,out,decrypt,tfdata);
_TwoFish_qBlockPush(Pn,out,tfdata); /* now we officially have Cn-1 */
_TwoFish_FlushOutput(tfdata->qBlockCrypt,TwoFish_BLOCK_SIZE,tfdata);
_TwoFish_FlushOutput(CnMinusOne,size,tfdata); /* old Cn-1 becomes new partial Cn */
}
tfdata->qBlockDefined=FALSE;
}
}
void _TwoFish_qBlockPush(uint8_t *p,uint8_t *c,TWOFISH *tfdata)
{ if(tfdata->qBlockDefined)
_TwoFish_FlushOutput(tfdata->qBlockCrypt,TwoFish_BLOCK_SIZE,tfdata);
memcpy(tfdata->prevCipher,tfdata->qBlockPlain,TwoFish_BLOCK_SIZE);
memcpy(tfdata->qBlockPlain,p,TwoFish_BLOCK_SIZE);
memcpy(tfdata->qBlockCrypt,c,TwoFish_BLOCK_SIZE);
tfdata->qBlockDefined=TRUE;
}
void _TwoFish_qBlockPop(uint8_t *p,uint8_t *c,TWOFISH *tfdata)
{ memcpy(p,tfdata->qBlockPlain,TwoFish_BLOCK_SIZE );
memcpy(c,tfdata->qBlockCrypt,TwoFish_BLOCK_SIZE );
tfdata->qBlockDefined=FALSE;
}
/* Reset's the CBC flag and zero's PrevCipher (through qBlockPlain) (important) */
void _TwoFish_ResetCBC(TWOFISH *tfdata)
{ tfdata->qBlockDefined=FALSE;
memset(tfdata->qBlockPlain,0,TwoFish_BLOCK_SIZE);
}
void _TwoFish_FlushOutput(uint8_t *b,uint32_t len,TWOFISH *tfdata)
{ uint32_t i;
for(i=0;i<len && !tfdata->dontflush;i++)
*tfdata->output++ = *b++;
tfdata->dontflush=FALSE;
}
void _TwoFish_BlockCrypt16(uint8_t *in,uint8_t *out,bool decrypt,TWOFISH *tfdata)
{ uint32_t x0,x1,x2,x3;
uint32_t k,t0,t1,R;
x0=*in++;
x0|=(*in++ << 8 );
x0|=(*in++ << 16);
x0|=(*in++ << 24);
x1=*in++;
x1|=(*in++ << 8 );
x1|=(*in++ << 16);
x1|=(*in++ << 24);
x2=*in++;
x2|=(*in++ << 8 );
x2|=(*in++ << 16);
x2|=(*in++ << 24);
x3=*in++;
x3|=(*in++ << 8 );
x3|=(*in++ << 16);
x3|=(*in++ << 24);
if(decrypt)
{ x0 ^= tfdata->subKeys[4]; /* swap input and output whitening keys when decrypting */
x1 ^= tfdata->subKeys[5];
x2 ^= tfdata->subKeys[6];
x3 ^= tfdata->subKeys[7];
k = 7+(TwoFish_ROUNDS*2);
for (R = 0; R < TwoFish_ROUNDS; R += 2)
{ t0 = _TwoFish_Fe320( tfdata->sBox, x0);
t1 = _TwoFish_Fe323( tfdata->sBox, x1);
x3 ^= t0 + (t1<<1) + tfdata->subKeys[k--];
x3 = x3 >> 1 | x3 << 31;
x2 = x2 << 1 | x2 >> 31;
x2 ^= t0 + t1 + tfdata->subKeys[k--];
t0 = _TwoFish_Fe320( tfdata->sBox, x2);
t1 = _TwoFish_Fe323( tfdata->sBox, x3);
x1 ^= t0 + (t1<<1) + tfdata->subKeys[k--];
x1 = x1 >> 1 | x1 << 31;
x0 = x0 << 1 | x0 >> 31;
x0 ^= t0 + t1 + tfdata->subKeys[k--];
}
x2 ^= tfdata->subKeys[0];
x3 ^= tfdata->subKeys[1];
x0 ^= tfdata->subKeys[2];
x1 ^= tfdata->subKeys[3];
}
else
{ x0 ^= tfdata->subKeys[0];
x1 ^= tfdata->subKeys[1];
x2 ^= tfdata->subKeys[2];
x3 ^= tfdata->subKeys[3];
k = 8;
for (R = 0; R < TwoFish_ROUNDS; R += 2)
{ t0 = _TwoFish_Fe320( tfdata->sBox, x0);
t1 = _TwoFish_Fe323( tfdata->sBox, x1);
x2 ^= t0 + t1 + tfdata->subKeys[k++];
x2 = x2 >> 1 | x2 << 31;
x3 = x3 << 1 | x3 >> 31;
x3 ^= t0 + (t1<<1) + tfdata->subKeys[k++];
t0 = _TwoFish_Fe320( tfdata->sBox, x2);
t1 = _TwoFish_Fe323( tfdata->sBox, x3);
x0 ^= t0 + t1 + tfdata->subKeys[k++];
x0 = x0 >> 1 | x0 << 31;
x1 = x1 << 1 | x1 >> 31;
x1 ^= t0 + (t1<<1) + tfdata->subKeys[k++];
}
x2 ^= tfdata->subKeys[4];
x3 ^= tfdata->subKeys[5];
x0 ^= tfdata->subKeys[6];
x1 ^= tfdata->subKeys[7];
}
*out++ = (uint8_t)(x2 );
*out++ = (uint8_t)(x2 >> 8);
*out++ = (uint8_t)(x2 >> 16);
*out++ = (uint8_t)(x2 >> 24);
*out++ = (uint8_t)(x3 );
*out++ = (uint8_t)(x3 >> 8);
*out++ = (uint8_t)(x3 >> 16);
*out++ = (uint8_t)(x3 >> 24);
*out++ = (uint8_t)(x0 );
*out++ = (uint8_t)(x0 >> 8);
*out++ = (uint8_t)(x0 >> 16);
*out++ = (uint8_t)(x0 >> 24);
*out++ = (uint8_t)(x1 );
*out++ = (uint8_t)(x1 >> 8);
*out++ = (uint8_t)(x1 >> 16);
*out++ = (uint8_t)(x1 >> 24);
}
/**
* Use (12, 8) Reed-Solomon code over GF(256) to produce a key S-box
* 32-bit entity from two key material 32-bit entities.
*
* @param k0 1st 32-bit entity.
* @param k1 2nd 32-bit entity.
* @return Remainder polynomial generated using RS code
*/
uint32_t _TwoFish_RS_MDS_Encode(uint32_t k0,uint32_t k1)
{ uint32_t i,r;
for(r=k1,i=0;i<4;i++) /* shift 1 byte at a time */
TwoFish_RS_rem(r);
r ^= k0;
for(i=0;i<4;i++)
TwoFish_RS_rem(r);
return r;
}
uint32_t _TwoFish_F32(uint32_t k64Cnt,uint32_t x,uint32_t *k32)
{ uint8_t b0,b1,b2,b3;
uint32_t k0,k1,k2,k3,result = 0;
b0=TwoFish_b0(x);
b1=TwoFish_b1(x);
b2=TwoFish_b2(x);
b3=TwoFish_b3(x);
k0=k32[0];
k1=k32[1];
k2=k32[2];
k3=k32[3];
switch (k64Cnt & 3)
{ case 1: /* 64-bit keys */
result =
TwoFish_MDS[0][(TwoFish_P[TwoFish_P_01][b0] & 0xFF) ^ TwoFish_b0(k0)] ^
TwoFish_MDS[1][(TwoFish_P[TwoFish_P_11][b1] & 0xFF) ^ TwoFish_b1(k0)] ^
TwoFish_MDS[2][(TwoFish_P[TwoFish_P_21][b2] & 0xFF) ^ TwoFish_b2(k0)] ^
TwoFish_MDS[3][(TwoFish_P[TwoFish_P_31][b3] & 0xFF) ^ TwoFish_b3(k0)];
break;
case 0: /* 256-bit keys (same as 4) */
b0 = (TwoFish_P[TwoFish_P_04][b0] & 0xFF) ^ TwoFish_b0(k3);
b1 = (TwoFish_P[TwoFish_P_14][b1] & 0xFF) ^ TwoFish_b1(k3);
b2 = (TwoFish_P[TwoFish_P_24][b2] & 0xFF) ^ TwoFish_b2(k3);
b3 = (TwoFish_P[TwoFish_P_34][b3] & 0xFF) ^ TwoFish_b3(k3);
case 3: /* 192-bit keys */
b0 = (TwoFish_P[TwoFish_P_03][b0] & 0xFF) ^ TwoFish_b0(k2);
b1 = (TwoFish_P[TwoFish_P_13][b1] & 0xFF) ^ TwoFish_b1(k2);
b2 = (TwoFish_P[TwoFish_P_23][b2] & 0xFF) ^ TwoFish_b2(k2);
b3 = (TwoFish_P[TwoFish_P_33][b3] & 0xFF) ^ TwoFish_b3(k2);
case 2: /* 128-bit keys (optimize for this case) */
result =
TwoFish_MDS[0][(TwoFish_P[TwoFish_P_01][(TwoFish_P[TwoFish_P_02][b0] & 0xFF) ^ TwoFish_b0(k1)] & 0xFF) ^ TwoFish_b0(k0)] ^
TwoFish_MDS[1][(TwoFish_P[TwoFish_P_11][(TwoFish_P[TwoFish_P_12][b1] & 0xFF) ^ TwoFish_b1(k1)] & 0xFF) ^ TwoFish_b1(k0)] ^
TwoFish_MDS[2][(TwoFish_P[TwoFish_P_21][(TwoFish_P[TwoFish_P_22][b2] & 0xFF) ^ TwoFish_b2(k1)] & 0xFF) ^ TwoFish_b2(k0)] ^
TwoFish_MDS[3][(TwoFish_P[TwoFish_P_31][(TwoFish_P[TwoFish_P_32][b3] & 0xFF) ^ TwoFish_b3(k1)] & 0xFF) ^ TwoFish_b3(k0)];
break;
}
return result;
}
uint32_t _TwoFish_Fe320(uint32_t *lsBox,uint32_t x)
{ return lsBox[ TwoFish_b0(x)<<1 ]^
lsBox[ ((TwoFish_b1(x)<<1)|1)]^
lsBox[0x200+ (TwoFish_b2(x)<<1) ]^
lsBox[0x200+((TwoFish_b3(x)<<1)|1)];
}
uint32_t _TwoFish_Fe323(uint32_t *lsBox,uint32_t x)
{ return lsBox[ (TwoFish_b3(x)<<1) ]^
lsBox[ ((TwoFish_b0(x)<<1)|1)]^
lsBox[0x200+ (TwoFish_b1(x)<<1) ]^
lsBox[0x200+((TwoFish_b2(x)<<1)|1)];
}
uint32_t _TwoFish_Fe32(uint32_t *lsBox,uint32_t x,uint32_t R)
{ return lsBox[ 2*TwoFish__b(x,R ) ]^
lsBox[ 2*TwoFish__b(x,R+1)+1]^
lsBox[0x200+2*TwoFish__b(x,R+2) ]^
lsBox[0x200+2*TwoFish__b(x,R+3)+1];
}
#endif
/* ******************************************* */
#if defined TWOFISH_UNIT_TEST
#include <stdio.h>
#define TEST_DATA_SIZE 327
int main(int argc, char* argv[])
{
int i;
int n;
char outbuf[4096];
char * outp = outbuf;
uint8_t key[] = { 0xfc, 0x77, 0x1a, 0xda, 0xaa };
TWOFISH *tfa = TwoFishInit( key, 5 );
TWOFISH *tfb = TwoFishInit( key, 5 );
uint8_t out[2048], out2[2048];
uint8_t in[TEST_DATA_SIZE];
for ( i=0; i<TEST_DATA_SIZE; ++i )
{
in[i] = rand() & 0xff;
}
outp=outbuf;
for ( i=0; i<TEST_DATA_SIZE; ++i )
{
n = snprintf( outp, 10, "0x%02x ", (in[i]) );
outp += n;
}
printf("in = [%d] %s\n", TEST_DATA_SIZE, outbuf);
int len = TwoFishEncryptRaw(in, out, TEST_DATA_SIZE, tfa);
outp=outbuf;
for ( i=0; i<len; ++i )
{
n = snprintf( outp, 10, "0x%02x ", (out[i]) );
outp += n;
}
printf("enc = [%d] %s\n", len, outbuf);
len = TwoFishDecryptRaw(out, out2, len, tfb);
printf("dec len = %d \n", len);
if ( 0 != memcmp( out2, in, TEST_DATA_SIZE ) )
{
printf( "FAILED! Decoded data does not match input.\n" );
}
else
{
printf( "Decoding matches input. OK.\n" );
}
TwoFishDestroy(tfb);
TwoFishDestroy(tfa);
return(0);
}
#endif
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