]>
cvs.zerfleddert.de Git - proxmark3-svn/blob - client/mifarehost.c
2 // people from mifare@nethemba.com, 2010
4 // This code is licensed to you under the terms of the GNU GPL, version 2 or,
5 // at your option, any later version. See the LICENSE.txt file for the text of
7 //-----------------------------------------------------------------------------
9 //-----------------------------------------------------------------------------
11 #include "mifarehost.h"
18 #include "crapto1/crapto1.h"
19 #include "proxmark3.h"
24 #include "iso14443crc.h"
26 // mifare tracer flags used in mfTraceDecode()
27 #define TRACE_IDLE 0x00
28 #define TRACE_AUTH1 0x01
29 #define TRACE_AUTH2 0x02
30 #define TRACE_AUTH_OK 0x03
31 #define TRACE_READ_DATA 0x04
32 #define TRACE_WRITE_OK 0x05
33 #define TRACE_WRITE_DATA 0x06
34 #define TRACE_ERROR 0xFF
37 static int compare_uint64 ( const void * a
, const void * b
) {
38 // didn't work: (the result is truncated to 32 bits)
39 //return (*(int64_t*)b - *(int64_t*)a);
42 if (*( uint64_t *) b
== *( uint64_t *) a
) return 0 ;
43 else if (*( uint64_t *) b
< *( uint64_t *) a
) return 1 ;
48 // create the intersection (common members) of two sorted lists. Lists are terminated by -1. Result will be in list1. Number of elements is returned.
49 static uint32_t intersection ( uint64_t * list1
, uint64_t * list2
)
51 if ( list1
== NULL
|| list2
== NULL
) {
54 uint64_t * p1
, * p2
, * p3
;
58 while ( * p1
!= - 1 && * p2
!= - 1 ) {
59 if ( compare_uint64 ( p1
, p2
) == 0 ) {
64 while ( compare_uint64 ( p1
, p2
) < 0 ) ++ p1
;
65 while ( compare_uint64 ( p1
, p2
) > 0 ) ++ p2
;
73 // Darkside attack (hf mf mifare)
74 static uint32_t nonce2key ( uint32_t uid
, uint32_t nt
, uint32_t nr
, uint64_t par_info
, uint64_t ks_info
, uint64_t ** keys
) {
75 struct Crypto1State
* states
;
76 uint32_t i
, pos
, rr
; //nr_diff;
77 uint8_t bt
, ks3x
[ 8 ], par
[ 8 ][ 8 ];
78 uint64_t key_recovered
;
79 static uint64_t * keylist
;
82 // Reset the last three significant bits of the reader nonce
85 for ( pos
= 0 ; pos
< 8 ; pos
++) {
86 ks3x
[ 7 - pos
] = ( ks_info
>> ( pos
* 8 )) & 0x0f ;
87 bt
= ( par_info
>> ( pos
* 8 )) & 0xff ;
89 par
[ 7 - pos
][ i
] = ( bt
>> i
) & 0x01 ;
93 states
= lfsr_common_prefix ( nr
, rr
, ks3x
, par
, ( par_info
== 0 ));
100 keylist
= ( uint64_t *) states
;
102 for ( i
= 0 ; keylist
[ i
]; i
++) {
103 lfsr_rollback_word ( states
+ i
, uid
^ nt
, 0 );
104 crypto1_get_lfsr ( states
+ i
, & key_recovered
);
105 keylist
[ i
] = key_recovered
;
114 int mfDarkside ( uint64_t * key
)
117 uint32_t nt
= 0 , nr
= 0 ;
118 uint64_t par_list
= 0 , ks_list
= 0 ;
119 uint64_t * keylist
= NULL
, * last_keylist
= NULL
;
120 uint32_t keycount
= 0 ;
123 UsbCommand c
= { CMD_READER_MIFARE
, { true , 0 , 0 }};
126 printf ( "------------------------------------------------------------------------- \n " );
127 printf ( "Executing command. Expected execution time: 25sec on average \n " );
128 printf ( "Press button on the proxmark3 device to abort both proxmark3 and client. \n " );
129 printf ( "------------------------------------------------------------------------- \n " );
133 clearCommandBuffer ();
138 int c
= getchar (); ( void ) c
;
151 if ( WaitForResponseTimeout ( CMD_ACK
, & resp
, 1000 )) {
156 uid
= ( uint32_t ) bytes_to_num ( resp
. d
. asBytes
+ 0 , 4 );
157 nt
= ( uint32_t ) bytes_to_num ( resp
. d
. asBytes
+ 4 , 4 );
158 par_list
= bytes_to_num ( resp
. d
. asBytes
+ 8 , 8 );
159 ks_list
= bytes_to_num ( resp
. d
. asBytes
+ 16 , 8 );
160 nr
= bytes_to_num ( resp
. d
. asBytes
+ 24 , 4 );
165 if ( par_list
== 0 && c
. arg
[ 0 ] == true ) {
166 PrintAndLog ( "Parity is all zero. Most likely this card sends NACK on every failed authentication." );
167 PrintAndLog ( "Attack will take a few seconds longer because we need two consecutive successful runs." );
171 keycount
= nonce2key ( uid
, nt
, nr
, par_list
, ks_list
, & keylist
);
174 PrintAndLog ( "Key not found (lfsr_common_prefix list is null). Nt=%08x" , nt
);
175 PrintAndLog ( "This is expected to happen in 25%% of all cases. Trying again with a different reader nonce..." );
179 qsort ( keylist
, keycount
, sizeof (* keylist
), compare_uint64
);
180 keycount
= intersection ( last_keylist
, keylist
);
183 last_keylist
= keylist
;
188 PrintAndLog ( "Found %u possible keys. Trying to authenticate with each of them ... \n " , keycount
);
190 PrintAndLog ( "Found a possible key. Trying to authenticate... \n " );
194 uint8_t keyBlock
[ USB_CMD_DATA_SIZE
];
195 int max_keys
= USB_CMD_DATA_SIZE
/ 6 ;
196 for ( int i
= 0 ; i
< keycount
; i
+= max_keys
) {
197 int size
= keycount
- i
> max_keys
? max_keys
: keycount
- i
;
198 for ( int j
= 0 ; j
< size
; j
++) {
199 if ( last_keylist
== NULL
) {
200 num_to_bytes ( keylist
[ i
* max_keys
+ j
], 6 , keyBlock
);
202 num_to_bytes ( last_keylist
[ i
* max_keys
+ j
], 6 , keyBlock
);
205 if (! mfCheckKeys ( 0 , 0 , false , size
, keyBlock
, key
)) {
215 PrintAndLog ( "Authentication failed. Trying again..." );
217 last_keylist
= keylist
;
225 int mfCheckKeys ( uint8_t blockNo
, uint8_t keyType
, bool clear_trace
, uint8_t keycnt
, uint8_t * keyBlock
, uint64_t * key
){
229 UsbCommand c
= { CMD_MIFARE_CHKKEYS
, {(( blockNo
& 0xff ) | (( keyType
& 0xff )<< 8 )), clear_trace
, keycnt
}};
230 memcpy ( c
. d
. asBytes
, keyBlock
, 6 * keycnt
);
234 if (! WaitForResponseTimeout ( CMD_ACK
,& resp
, 3000 )) return 1 ;
235 if (( resp
. arg
[ 0 ] & 0xff ) != 0x01 ) return 2 ;
236 * key
= bytes_to_num ( resp
. d
. asBytes
, 6 );
240 // Compare 16 Bits out of cryptostate
241 int Compare16Bits ( const void * a
, const void * b
) {
242 if ((*( uint64_t *) b
& 0x00ff000000ff0000 ) == (*( uint64_t *) a
& 0x00ff000000ff0000 )) return 0 ;
243 else if ((*( uint64_t *) b
& 0x00ff000000ff0000 ) > (*( uint64_t *) a
& 0x00ff000000ff0000 )) return 1 ;
250 struct Crypto1State
* slhead
;
254 struct Crypto1State
* sltail
;
266 // wrapper function for multi-threaded lfsr_recovery32
267 void * nested_worker_thread ( void * arg
)
269 struct Crypto1State
* p1
;
270 StateList_t
* statelist
= arg
;
272 statelist
-> head
. slhead
= lfsr_recovery32 ( statelist
-> ks1
, statelist
-> nt
^ statelist
-> uid
);
273 for ( p1
= statelist
-> head
. slhead
; *( uint64_t *) p1
!= 0 ; p1
++);
274 statelist
-> len
= p1
- statelist
-> head
. slhead
;
275 statelist
-> tail
. sltail
= -- p1
;
276 qsort ( statelist
-> head
. slhead
, statelist
-> len
, sizeof ( uint64_t ), Compare16Bits
);
278 return statelist
-> head
. slhead
;
281 int mfnested ( uint8_t blockNo
, uint8_t keyType
, uint8_t * key
, uint8_t trgBlockNo
, uint8_t trgKeyType
, uint8_t * resultKey
, bool calibrate
)
287 StateList_t statelists
[ 2 ];
288 struct Crypto1State
* p1
, * p2
, * p3
, * p4
;
291 WaitForResponseTimeout ( CMD_ACK
, NULL
, 100 );
293 UsbCommand c
= { CMD_MIFARE_NESTED
, { blockNo
+ keyType
* 0x100 , trgBlockNo
+ trgKeyType
* 0x100 , calibrate
}};
294 memcpy ( c
. d
. asBytes
, key
, 6 );
297 if (! WaitForResponseTimeout ( CMD_ACK
, & resp
, 1500 )) {
302 return resp
. arg
[ 0 ]; // error during nested
305 memcpy (& uid
, resp
. d
. asBytes
, 4 );
306 PrintAndLog ( "uid:%08x trgbl=%d trgkey=%x" , uid
, ( uint16_t ) resp
. arg
[ 2 ] & 0xff , ( uint16_t ) resp
. arg
[ 2 ] >> 8 );
308 for ( i
= 0 ; i
< 2 ; i
++) {
309 statelists
[ i
]. blockNo
= resp
. arg
[ 2 ] & 0xff ;
310 statelists
[ i
]. keyType
= ( resp
. arg
[ 2 ] >> 8 ) & 0xff ;
311 statelists
[ i
]. uid
= uid
;
312 memcpy (& statelists
[ i
]. nt
, ( void *)( resp
. d
. asBytes
+ 4 + i
* 8 + 0 ), 4 );
313 memcpy (& statelists
[ i
]. ks1
, ( void *)( resp
. d
. asBytes
+ 4 + i
* 8 + 4 ), 4 );
318 pthread_t thread_id
[ 2 ];
320 // create and run worker threads
321 for ( i
= 0 ; i
< 2 ; i
++) {
322 pthread_create ( thread_id
+ i
, NULL
, nested_worker_thread
, & statelists
[ i
]);
325 // wait for threads to terminate:
326 for ( i
= 0 ; i
< 2 ; i
++) {
327 pthread_join ( thread_id
[ i
], ( void *)& statelists
[ i
]. head
. slhead
);
331 // the first 16 Bits of the cryptostate already contain part of our key.
332 // Create the intersection of the two lists based on these 16 Bits and
333 // roll back the cryptostate
334 p1
= p3
= statelists
[ 0 ]. head
. slhead
;
335 p2
= p4
= statelists
[ 1 ]. head
. slhead
;
336 while ( p1
<= statelists
[ 0 ]. tail
. sltail
&& p2
<= statelists
[ 1 ]. tail
. sltail
) {
337 if ( Compare16Bits ( p1
, p2
) == 0 ) {
338 struct Crypto1State savestate
, * savep
= & savestate
;
340 while ( Compare16Bits ( p1
, savep
) == 0 && p1
<= statelists
[ 0 ]. tail
. sltail
) {
342 lfsr_rollback_word ( p3
, statelists
[ 0 ]. nt
^ statelists
[ 0 ]. uid
, 0 );
347 while ( Compare16Bits ( p2
, savep
) == 0 && p2
<= statelists
[ 1 ]. tail
. sltail
) {
349 lfsr_rollback_word ( p4
, statelists
[ 1 ]. nt
^ statelists
[ 1 ]. uid
, 0 );
355 while ( Compare16Bits ( p1
, p2
) == - 1 ) p1
++;
356 while ( Compare16Bits ( p1
, p2
) == 1 ) p2
++;
361 statelists
[ 0 ]. len
= p3
- statelists
[ 0 ]. head
. slhead
;
362 statelists
[ 1 ]. len
= p4
- statelists
[ 1 ]. head
. slhead
;
363 statelists
[ 0 ]. tail
. sltail
=-- p3
;
364 statelists
[ 1 ]. tail
. sltail
=-- p4
;
366 // the statelists now contain possible keys. The key we are searching for must be in the
367 // intersection of both lists. Create the intersection:
368 qsort ( statelists
[ 0 ]. head
. keyhead
, statelists
[ 0 ]. len
, sizeof ( uint64_t ), compare_uint64
);
369 qsort ( statelists
[ 1 ]. head
. keyhead
, statelists
[ 1 ]. len
, sizeof ( uint64_t ), compare_uint64
);
370 statelists
[ 0 ]. len
= intersection ( statelists
[ 0 ]. head
. keyhead
, statelists
[ 1 ]. head
. keyhead
);
372 memset ( resultKey
, 0 , 6 );
373 // The list may still contain several key candidates. Test each of them with mfCheckKeys
374 for ( i
= 0 ; i
< statelists
[ 0 ]. len
; i
++) {
377 crypto1_get_lfsr ( statelists
[ 0 ]. head
. slhead
+ i
, & key64
);
378 num_to_bytes ( key64
, 6 , keyBlock
);
380 if (! mfCheckKeys ( statelists
[ 0 ]. blockNo
, statelists
[ 0 ]. keyType
, false , 1 , keyBlock
, & key64
)) {
381 num_to_bytes ( key64
, 6 , resultKey
);
386 free ( statelists
[ 0 ]. head
. slhead
);
387 free ( statelists
[ 1 ]. head
. slhead
);
394 int mfEmlGetMem ( uint8_t * data
, int blockNum
, int blocksCount
) {
395 UsbCommand c
= { CMD_MIFARE_EML_MEMGET
, { blockNum
, blocksCount
, 0 }};
399 if (! WaitForResponseTimeout ( CMD_ACK
,& resp
, 1500 )) return 1 ;
400 memcpy ( data
, resp
. d
. asBytes
, blocksCount
* 16 );
404 int mfEmlSetMem ( uint8_t * data
, int blockNum
, int blocksCount
) {
405 UsbCommand c
= { CMD_MIFARE_EML_MEMSET
, { blockNum
, blocksCount
, 0 }};
406 memcpy ( c
. d
. asBytes
, data
, blocksCount
* 16 );
413 int mfCGetBlock ( uint8_t blockNo
, uint8_t * data
, uint8_t params
) {
416 UsbCommand c
= { CMD_MIFARE_CGETBLOCK
, { params
, 0 , blockNo
}};
420 if ( WaitForResponseTimeout ( CMD_ACK
,& resp
, 1500 )) {
421 isOK
= resp
. arg
[ 0 ] & 0xff ;
422 memcpy ( data
, resp
. d
. asBytes
, 16 );
425 PrintAndLog ( "Command execute timeout" );
431 int mfCSetBlock ( uint8_t blockNo
, uint8_t * data
, uint8_t * uid
, bool wantWipe
, uint8_t params
) {
434 UsbCommand c
= { CMD_MIFARE_CSETBLOCK
, { wantWipe
, params
& ( 0xFE | ( uid
== NULL
? 0 : 1 )), blockNo
}};
435 memcpy ( c
. d
. asBytes
, data
, 16 );
439 if ( WaitForResponseTimeout ( CMD_ACK
,& resp
, 1500 )) {
440 isOK
= resp
. arg
[ 0 ] & 0xff ;
442 memcpy ( uid
, resp
. d
. asBytes
, 4 );
446 PrintAndLog ( "Command execute timeout" );
452 int mfCSetUID ( uint8_t * uid
, uint8_t * atqa
, uint8_t * sak
, uint8_t * oldUID
, bool wantWipe
) {
453 uint8_t oldblock0
[ 16 ] = { 0x00 };
454 uint8_t block0
[ 16 ] = { 0x00 };
456 int old
= mfCGetBlock ( 0 , oldblock0
, CSETBLOCK_SINGLE_OPER
);
458 memcpy ( block0
, oldblock0
, 16 );
459 PrintAndLog ( "old block 0: %s" , sprint_hex ( block0
, 16 ));
461 PrintAndLog ( "Couldn't get old data. Will write over the last bytes of Block 0." );
464 // fill in the new values
466 memcpy ( block0
, uid
, 4 );
468 block0
[ 4 ] = block0
[ 0 ]^ block0
[ 1 ]^ block0
[ 2 ]^ block0
[ 3 ];
469 // mifare classic SAK(byte 5) and ATQA(byte 6 and 7, reversed)
476 PrintAndLog ( "new block 0: %s" , sprint_hex ( block0
, 16 ));
477 return mfCSetBlock ( 0 , block0
, oldUID
, wantWipe
, CSETBLOCK_SINGLE_OPER
);
483 static uint8_t trailerAccessBytes
[ 4 ] = { 0x08 , 0x77 , 0x8F , 0x00 };
486 char logHexFileName
[ FILE_PATH_SIZE
] = { 0x00 };
487 static uint8_t traceCard
[ 4096 ] = { 0x00 };
488 static char traceFileName
[ FILE_PATH_SIZE
] = { 0x00 };
489 static int traceState
= TRACE_IDLE
;
490 static uint8_t traceCurBlock
= 0 ;
491 static uint8_t traceCurKey
= 0 ;
493 struct Crypto1State
* traceCrypto1
= NULL
;
495 struct Crypto1State
* revstate
;
500 uint32_t uid
; // serial number
501 uint32_t nt
; // tag challenge
502 uint32_t nr_enc
; // encrypted reader challenge
503 uint32_t ar_enc
; // encrypted reader response
504 uint32_t at_enc
; // encrypted tag response
506 int isTraceCardEmpty ( void ) {
507 return (( traceCard
[ 0 ] == 0 ) && ( traceCard
[ 1 ] == 0 ) && ( traceCard
[ 2 ] == 0 ) && ( traceCard
[ 3 ] == 0 ));
510 int isBlockEmpty ( int blockN
) {
511 for ( int i
= 0 ; i
< 16 ; i
++)
512 if ( traceCard
[ blockN
* 16 + i
] != 0 ) return 0 ;
517 int isBlockTrailer ( int blockN
) {
518 return (( blockN
& 0x03 ) == 0x03 );
521 int saveTraceCard ( void ) {
524 if ((! strlen ( traceFileName
)) || ( isTraceCardEmpty ())) return 0 ;
526 f
= fopen ( traceFileName
, "w+" );
529 for ( int i
= 0 ; i
< 64 ; i
++) { // blocks
530 for ( int j
= 0 ; j
< 16 ; j
++) // bytes
531 fprintf ( f
, "%02x" , *( traceCard
+ i
* 16 + j
));
538 int loadTraceCard ( uint8_t * tuid
) {
540 char buf
[ 64 ] = { 0x00 };
541 uint8_t buf8
[ 64 ] = { 0x00 };
544 if (! isTraceCardEmpty ())
547 memset ( traceCard
, 0x00 , 4096 );
548 memcpy ( traceCard
, tuid
+ 3 , 4 );
550 FillFileNameByUID ( traceFileName
, tuid
, ".eml" , 7 );
552 f
= fopen ( traceFileName
, "r" );
559 memset ( buf
, 0 , sizeof ( buf
));
560 if ( fgets ( buf
, sizeof ( buf
), f
) == NULL
) {
561 PrintAndLog ( "File reading error." );
566 if ( strlen ( buf
) < 32 ){
568 PrintAndLog ( "File content error. Block data must include 32 HEX symbols" );
572 for ( i
= 0 ; i
< 32 ; i
+= 2 )
573 sscanf (& buf
[ i
], "%02x" , ( unsigned int *)& buf8
[ i
/ 2 ]);
575 memcpy ( traceCard
+ blockNum
* 16 , buf8
, 16 );
584 int mfTraceInit ( uint8_t * tuid
, uint8_t * atqa
, uint8_t sak
, bool wantSaveToEmlFile
) {
587 crypto1_destroy ( traceCrypto1
);
591 if ( wantSaveToEmlFile
)
594 traceCard
[ 4 ] = traceCard
[ 0 ] ^ traceCard
[ 1 ] ^ traceCard
[ 2 ] ^ traceCard
[ 3 ];
596 memcpy (& traceCard
[ 6 ], atqa
, 2 );
598 uid
= bytes_to_num ( tuid
+ 3 , 4 );
600 traceState
= TRACE_IDLE
;
605 void mf_crypto1_decrypt ( struct Crypto1State
* pcs
, uint8_t * data
, int len
, bool isEncrypted
){
610 for ( i
= 0 ; i
< len
; i
++)
611 data
[ i
] = crypto1_byte ( pcs
, 0x00 , isEncrypted
) ^ data
[ i
];
614 for ( i
= 0 ; i
< 4 ; i
++)
615 bt
|= ( crypto1_bit ( pcs
, 0 , isEncrypted
) ^ BIT ( data
[ 0 ], i
)) << i
;
623 int mfTraceDecode ( uint8_t * data_src
, int len
, bool wantSaveToEmlFile
) {
626 if ( traceState
== TRACE_ERROR
) return 1 ;
628 traceState
= TRACE_ERROR
;
632 memcpy ( data
, data_src
, len
);
633 if (( traceCrypto1
) && (( traceState
== TRACE_IDLE
) || ( traceState
> TRACE_AUTH_OK
))) {
634 mf_crypto1_decrypt ( traceCrypto1
, data
, len
, 0 );
635 PrintAndLog ( "dec> %s" , sprint_hex ( data
, len
));
636 AddLogHex ( logHexFileName
, "dec> " , data
, len
);
639 switch ( traceState
) {
641 // check packet crc16!
642 if (( len
>= 4 ) && (! CheckCrc14443 ( CRC_14443_A
, data
, len
))) {
643 PrintAndLog ( "dec> CRC ERROR!!!" );
644 AddLogLine ( logHexFileName
, "dec> " , "CRC ERROR!!!" );
645 traceState
= TRACE_ERROR
; // do not decrypt the next commands
650 if (( len
== 4 ) && (( data
[ 0 ] == 0x60 ) || ( data
[ 0 ] == 0x61 ))) {
651 traceState
= TRACE_AUTH1
;
652 traceCurBlock
= data
[ 1 ];
653 traceCurKey
= data
[ 0 ] == 60 ? 1 : 0 ;
658 if (( len
== 4 ) && (( data
[ 0 ] == 0x30 ))) {
659 traceState
= TRACE_READ_DATA
;
660 traceCurBlock
= data
[ 1 ];
665 if (( len
== 4 ) && (( data
[ 0 ] == 0xA0 ))) {
666 traceState
= TRACE_WRITE_OK
;
667 traceCurBlock
= data
[ 1 ];
672 if (( len
== 4 ) && (( data
[ 0 ] == 0x50 ) && ( data
[ 1 ] == 0x00 ))) {
673 traceState
= TRACE_ERROR
; // do not decrypt the next commands
680 case TRACE_READ_DATA
:
682 traceState
= TRACE_IDLE
;
684 if ( isBlockTrailer ( traceCurBlock
)) {
685 memcpy ( traceCard
+ traceCurBlock
* 16 + 6 , data
+ 6 , 4 );
687 memcpy ( traceCard
+ traceCurBlock
* 16 , data
, 16 );
689 if ( wantSaveToEmlFile
) saveTraceCard ();
692 traceState
= TRACE_ERROR
;
698 if (( len
== 1 ) && ( data
[ 0 ] == 0x0a )) {
699 traceState
= TRACE_WRITE_DATA
;
703 traceState
= TRACE_ERROR
;
708 case TRACE_WRITE_DATA
:
710 traceState
= TRACE_IDLE
;
712 memcpy ( traceCard
+ traceCurBlock
* 16 , data
, 16 );
713 if ( wantSaveToEmlFile
) saveTraceCard ();
716 traceState
= TRACE_ERROR
;
723 traceState
= TRACE_AUTH2
;
724 nt
= bytes_to_num ( data
, 4 );
727 traceState
= TRACE_ERROR
;
734 traceState
= TRACE_AUTH_OK
;
736 nr_enc
= bytes_to_num ( data
, 4 );
737 ar_enc
= bytes_to_num ( data
+ 4 , 4 );
740 traceState
= TRACE_ERROR
;
747 traceState
= TRACE_IDLE
;
749 at_enc
= bytes_to_num ( data
, 4 );
752 ks2
= ar_enc
^ prng_successor ( nt
, 64 );
753 ks3
= at_enc
^ prng_successor ( nt
, 96 );
754 revstate
= lfsr_recovery64 ( ks2
, ks3
);
755 lfsr_rollback_word ( revstate
, 0 , 0 );
756 lfsr_rollback_word ( revstate
, 0 , 0 );
757 lfsr_rollback_word ( revstate
, nr_enc
, 1 );
758 lfsr_rollback_word ( revstate
, uid
^ nt
, 0 );
760 crypto1_get_lfsr ( revstate
, & lfsr
);
761 printf ( "key> %x%x \n " , ( unsigned int )(( lfsr
& 0xFFFFFFFF00000000 ) >> 32 ), ( unsigned int )( lfsr
& 0xFFFFFFFF ));
762 AddLogUint64 ( logHexFileName
, "key> " , lfsr
);
764 int blockShift
= (( traceCurBlock
& 0xFC ) + 3 ) * 16 ;
765 if ( isBlockEmpty (( traceCurBlock
& 0xFC ) + 3 )) memcpy ( traceCard
+ blockShift
+ 6 , trailerAccessBytes
, 4 );
768 num_to_bytes ( lfsr
, 6 , traceCard
+ blockShift
+ 10 );
770 num_to_bytes ( lfsr
, 6 , traceCard
+ blockShift
);
772 if ( wantSaveToEmlFile
) saveTraceCard ();
775 crypto1_destroy ( traceCrypto1
);
778 // set cryptosystem state
779 traceCrypto1
= lfsr_recovery64 ( ks2
, ks3
);
781 // nt = crypto1_word(traceCrypto1, nt ^ uid, 1) ^ nt;
783 /* traceCrypto1 = crypto1_create(lfsr); // key in lfsr
784 crypto1_word(traceCrypto1, nt ^ uid, 0);
785 crypto1_word(traceCrypto1, ar, 1);
786 crypto1_word(traceCrypto1, 0, 0);
787 crypto1_word(traceCrypto1, 0, 0);*/
791 traceState
= TRACE_ERROR
;
797 traceState
= TRACE_ERROR
;
804 int tryDecryptWord ( uint32_t nt
, uint32_t ar_enc
, uint32_t at_enc
, uint8_t * data
, int len
){
806 uint32_t nt; // tag challenge
807 uint32_t ar_enc; // encrypted reader response
808 uint32_t at_enc; // encrypted tag response
811 crypto1_destroy ( traceCrypto1
);
813 ks2
= ar_enc
^ prng_successor ( nt
, 64 );
814 ks3
= at_enc
^ prng_successor ( nt
, 96 );
815 traceCrypto1
= lfsr_recovery64 ( ks2
, ks3
);
817 mf_crypto1_decrypt ( traceCrypto1
, data
, len
, 0 );
819 PrintAndLog ( "Decrypted data: [%s]" , sprint_hex ( data
, len
) );
820 crypto1_destroy ( traceCrypto1
);