uint32_t *even_head = 0, *even_tail = 0, eks = 0;\r
int i;\r
\r
+ // split the keystream into an odd and even part\r
for(i = 31; i >= 0; i -= 2)\r
oks = oks << 1 | BEBIT(ks2, i);\r
for(i = 30; i >= 0; i -= 2)\r
\r
statelist->odd = statelist->even = 0;\r
\r
+ // initialize statelists: add all possible states which would result into the rightmost 2 bits of the keystream\r
for(i = 1 << 20; i >= 0; --i) {\r
if(filter(i) == (oks & 1))\r
*++odd_tail = i;\r
*++even_tail = i;\r
}\r
\r
+ // extend the statelists. Look at the next 8 Bits of the keystream (4 Bit each odd and even):\r
for(i = 0; i < 4; i++) {\r
extend_table_simple(odd_head, &odd_tail, (oks >>= 1) & 1);\r
extend_table_simple(even_head, &even_tail, (eks >>= 1) & 1);\r
}\r
\r
+ // the statelists now contain all states which could have generated the last 10 Bits of the keystream.\r
+ // 22 bits to go to recover 32 bits in total. From now on, we need to take the "in"\r
+ // parameter into account.\r
in = (in >> 16 & 0xff) | (in << 16) | (in & 0xff00);\r
recover(odd_head, odd_tail, oks,\r
even_head, even_tail, eks, 11, statelist, in << 1);\r
*/\r
uint8_t lfsr_rollback_byte(struct Crypto1State *s, uint32_t in, int fb)\r
{\r
+ /*\r
int i, ret = 0;\r
for (i = 7; i >= 0; --i)\r
ret |= lfsr_rollback_bit(s, BIT(in, i), fb) << i;\r
+*/\r
+\r
+ uint8_t ret = 0;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 7), fb) << 7;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 6), fb) << 6;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 5), fb) << 5;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 4), fb) << 4;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 3), fb) << 3;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 2), fb) << 2;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 1), fb) << 1;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 0), fb) << 0;\r
return ret;\r
}\r
/** lfsr_rollback_word\r
*/\r
uint32_t lfsr_rollback_word(struct Crypto1State *s, uint32_t in, int fb)\r
{\r
+ /*\r
int i;\r
uint32_t ret = 0;\r
for (i = 31; i >= 0; --i)\r
ret |= lfsr_rollback_bit(s, BEBIT(in, i), fb) << (i ^ 24);\r
+*/\r
+ \r
+ uint32_t ret = 0;\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 31), fb) << (31 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 30), fb) << (30 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 29), fb) << (29 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 28), fb) << (28 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 27), fb) << (27 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 26), fb) << (26 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 25), fb) << (25 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 24), fb) << (24 ^ 24);\r
+\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 23), fb) << (23 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 22), fb) << (22 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 21), fb) << (21 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 20), fb) << (20 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 19), fb) << (19 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 18), fb) << (18 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 17), fb) << (17 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 16), fb) << (16 ^ 24);\r
+ \r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 15), fb) << (15 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 14), fb) << (14 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 13), fb) << (13 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 12), fb) << (12 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 11), fb) << (11 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 10), fb) << (10 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 9), fb) << (9 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 8), fb) << (8 ^ 24);\r
+ \r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 7), fb) << (7 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 6), fb) << (6 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 5), fb) << (5 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 4), fb) << (4 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 3), fb) << (3 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 2), fb) << (2 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 1), fb) << (1 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 0), fb) << (0 ^ 24);\r
+ \r
return ret;\r
}\r
\r
*/\r
uint32_t *lfsr_prefix_ks(uint8_t ks[8], int isodd)\r
{\r
- uint32_t c, entry, *candidates = malloc(4 << 10);\r
- int i, size = 0, good;\r
+ uint32_t *candidates = malloc(4 << 10);\r
+ uint32_t c, entry;\r
+ int size = 0, i, good;\r
\r
if(!candidates)\r
return 0;\r
\r
s->odd = s->even = 0;\r
\r
+ free(odd);\r
+ free(even);\r
+\r
return statelist;\r
}\r
uint8_t lfsr_rollback_byte(struct Crypto1State* s, uint32_t in, int fb);
uint32_t lfsr_rollback_word(struct Crypto1State* s, uint32_t in, int fb);
int nonce_distance(uint32_t from, uint32_t to);
+#define SWAPENDIAN(x)\
+ (x = (x >> 8 & 0xff00ff) | (x & 0xff00ff) << 8, x = x >> 16 | x << 16)
+
#define FOREACH_VALID_NONCE(N, FILTER, FSIZE)\
uint32_t __n = 0,__M = 0, N = 0;\
int __i;\
x ^= x >> 4;
return BIT(0x6996, x & 0xf);
#else
- asm( "movl %1, %%eax\n"
+ __asm__( "movl %1, %%eax\n"
"mov %%ax, %%cx\n"
"shrl $0x10, %%eax\n"
"xor %%ax, %%cx\n"
#include "crapto1.h"
#include <stdlib.h>
-#define SWAPENDIAN(x)\
- (x = (x >> 8 & 0xff00ff) | (x & 0xff00ff) << 8, x = x >> 16 | x << 16)
-
struct Crypto1State * crypto1_create(uint64_t key)
{
struct Crypto1State *s = malloc(sizeof(*s));
uint8_t crypto1_bit(struct Crypto1State *s, uint8_t in, int is_encrypted)
{
uint32_t feedin;
+ uint32_t tmp;
uint8_t ret = filter(s->odd);
feedin = ret & !!is_encrypted;
feedin ^= LF_POLY_EVEN & s->even;
s->even = s->even << 1 | parity(feedin);
- s->odd ^= (s->odd ^= s->even, s->even ^= s->odd);
+ tmp = s->odd;
+ s->odd = s->even;
+ s->even = tmp;
return ret;
}
uint8_t crypto1_byte(struct Crypto1State *s, uint8_t in, int is_encrypted)
{
+ /*
uint8_t i, ret = 0;
for (i = 0; i < 8; ++i)
ret |= crypto1_bit(s, BIT(in, i), is_encrypted) << i;
-
+ */
+ // unfold loop
+ uint8_t ret = 0;
+ ret |= crypto1_bit(s, BIT(in, 0), is_encrypted) << 0;
+ ret |= crypto1_bit(s, BIT(in, 1), is_encrypted) << 1;
+ ret |= crypto1_bit(s, BIT(in, 2), is_encrypted) << 2;
+ ret |= crypto1_bit(s, BIT(in, 3), is_encrypted) << 3;
+ ret |= crypto1_bit(s, BIT(in, 4), is_encrypted) << 4;
+ ret |= crypto1_bit(s, BIT(in, 5), is_encrypted) << 5;
+ ret |= crypto1_bit(s, BIT(in, 6), is_encrypted) << 6;
+ ret |= crypto1_bit(s, BIT(in, 7), is_encrypted) << 7;
return ret;
}
uint32_t crypto1_word(struct Crypto1State *s, uint32_t in, int is_encrypted)
{
+ /*
uint32_t i, ret = 0;
for (i = 0; i < 32; ++i)
ret |= crypto1_bit(s, BEBIT(in, i), is_encrypted) << (i ^ 24);
-
+*/
+ uint32_t ret = 0;
+ ret |= crypto1_bit(s, BEBIT(in, 0), is_encrypted) << (0 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 1), is_encrypted) << (1 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 2), is_encrypted) << (2 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 3), is_encrypted) << (3 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 4), is_encrypted) << (4 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 5), is_encrypted) << (5 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 6), is_encrypted) << (6 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 7), is_encrypted) << (7 ^ 24);
+
+ ret |= crypto1_bit(s, BEBIT(in, 8), is_encrypted) << (8 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 9), is_encrypted) << (9 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 10), is_encrypted) << (10 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 11), is_encrypted) << (11 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 12), is_encrypted) << (12 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 13), is_encrypted) << (13 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 14), is_encrypted) << (14 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 15), is_encrypted) << (15 ^ 24);
+
+ ret |= crypto1_bit(s, BEBIT(in, 16), is_encrypted) << (16 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 17), is_encrypted) << (17 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 18), is_encrypted) << (18 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 19), is_encrypted) << (19 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 20), is_encrypted) << (20 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 21), is_encrypted) << (21 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 22), is_encrypted) << (22 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 23), is_encrypted) << (23 ^ 24);
+
+ ret |= crypto1_bit(s, BEBIT(in, 24), is_encrypted) << (24 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 25), is_encrypted) << (25 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 26), is_encrypted) << (26 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 27), is_encrypted) << (27 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 28), is_encrypted) << (28 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 29), is_encrypted) << (29 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 30), is_encrypted) << (30 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 31), is_encrypted) << (31 ^ 24);
return ret;
}
uint32_t *even_head = 0, *even_tail = 0, eks = 0;\r
int i;\r
\r
+ // split the keystream into an odd and even part\r
for(i = 31; i >= 0; i -= 2)\r
oks = oks << 1 | BEBIT(ks2, i);\r
for(i = 30; i >= 0; i -= 2)\r
\r
statelist->odd = statelist->even = 0;\r
\r
+ // initialize statelists: add all possible states which would result into the rightmost 2 bits of the keystream\r
for(i = 1 << 20; i >= 0; --i) {\r
if(filter(i) == (oks & 1))\r
*++odd_tail = i;\r
*++even_tail = i;\r
}\r
\r
+ // extend the statelists. Look at the next 8 Bits of the keystream (4 Bit each odd and even):\r
for(i = 0; i < 4; i++) {\r
extend_table_simple(odd_head, &odd_tail, (oks >>= 1) & 1);\r
extend_table_simple(even_head, &even_tail, (eks >>= 1) & 1);\r
}\r
\r
+ // the statelists now contain all states which could have generated the last 10 Bits of the keystream.\r
+ // 22 bits to go to recover 32 bits in total. From now on, we need to take the "in"\r
+ // parameter into account.\r
in = (in >> 16 & 0xff) | (in << 16) | (in & 0xff00);\r
recover(odd_head, odd_tail, oks,\r
even_head, even_tail, eks, 11, statelist, in << 1);\r
*/\r
uint8_t lfsr_rollback_byte(struct Crypto1State *s, uint32_t in, int fb)\r
{\r
+ /*\r
int i, ret = 0;\r
for (i = 7; i >= 0; --i)\r
ret |= lfsr_rollback_bit(s, BIT(in, i), fb) << i;\r
+*/\r
+\r
+ uint8_t ret = 0;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 7), fb) << 7;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 6), fb) << 6;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 5), fb) << 5;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 4), fb) << 4;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 3), fb) << 3;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 2), fb) << 2;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 1), fb) << 1;\r
+ ret |= lfsr_rollback_bit(s, BIT(in, 0), fb) << 0;\r
return ret;\r
}\r
/** lfsr_rollback_word\r
*/\r
uint32_t lfsr_rollback_word(struct Crypto1State *s, uint32_t in, int fb)\r
{\r
+ /*\r
int i;\r
uint32_t ret = 0;\r
for (i = 31; i >= 0; --i)\r
ret |= lfsr_rollback_bit(s, BEBIT(in, i), fb) << (i ^ 24);\r
+*/\r
+ \r
+ uint32_t ret = 0;\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 31), fb) << (31 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 30), fb) << (30 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 29), fb) << (29 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 28), fb) << (28 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 27), fb) << (27 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 26), fb) << (26 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 25), fb) << (25 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 24), fb) << (24 ^ 24);\r
+\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 23), fb) << (23 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 22), fb) << (22 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 21), fb) << (21 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 20), fb) << (20 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 19), fb) << (19 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 18), fb) << (18 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 17), fb) << (17 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 16), fb) << (16 ^ 24);\r
+ \r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 15), fb) << (15 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 14), fb) << (14 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 13), fb) << (13 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 12), fb) << (12 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 11), fb) << (11 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 10), fb) << (10 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 9), fb) << (9 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 8), fb) << (8 ^ 24);\r
+ \r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 7), fb) << (7 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 6), fb) << (6 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 5), fb) << (5 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 4), fb) << (4 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 3), fb) << (3 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 2), fb) << (2 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 1), fb) << (1 ^ 24);\r
+ ret |= lfsr_rollback_bit(s, BEBIT(in, 0), fb) << (0 ^ 24);\r
+ \r
return ret;\r
}\r
\r
*/\r
uint32_t *lfsr_prefix_ks(uint8_t ks[8], int isodd)\r
{\r
- uint32_t c, entry, *candidates = malloc(4 << 10);\r
- int i, size = 0, good;\r
+ uint32_t *candidates = malloc(4 << 10);\r
+ uint32_t c, entry;\r
+ int size = 0, i, good;\r
\r
if(!candidates)\r
return 0;\r
\r
s->odd = s->even = 0;\r
\r
+ free(odd);\r
+ free(even);\r
+\r
return statelist;\r
}\r
struct Crypto1State* lfsr_recovery32(uint32_t ks2, uint32_t in);
struct Crypto1State* lfsr_recovery64(uint32_t ks2, uint32_t ks3);
uint32_t *lfsr_prefix_ks(uint8_t ks[8], int isodd);
-struct Crypto1State*
-lfsr_common_prefix(uint32_t pfx, uint32_t rr, uint8_t ks[8], uint8_t par[8][8]);
+struct Crypto1State* lfsr_common_prefix(uint32_t pfx, uint32_t rr, uint8_t ks[8], uint8_t par[8][8]);
+struct Crypto1State* lfsr_common_prefix_ex(uint32_t pfx, uint32_t rr, uint8_t ks[8], uint8_t par[8][8]);
+
uint8_t lfsr_rollback_bit(struct Crypto1State* s, uint32_t in, int fb);
uint8_t lfsr_rollback_byte(struct Crypto1State* s, uint32_t in, int fb);
uint32_t lfsr_rollback_word(struct Crypto1State* s, uint32_t in, int fb);
int nonce_distance(uint32_t from, uint32_t to);
+#define SWAPENDIAN(x)\
+ (x = (x >> 8 & 0xff00ff) | (x & 0xff00ff) << 8, x = x >> 16 | x << 16)
+
#define FOREACH_VALID_NONCE(N, FILTER, FSIZE)\
uint32_t __n = 0,__M = 0, N = 0;\
int __i;\
x ^= x >> 4;
return BIT(0x6996, x & 0xf);
#else
- asm( "movl %1, %%eax\n"
+ __asm__( "movl %1, %%eax\n"
"mov %%ax, %%cx\n"
"shrl $0x10, %%eax\n"
"xor %%ax, %%cx\n"
#include "crapto1.h"
#include <stdlib.h>
-#define SWAPENDIAN(x)\
- (x = (x >> 8 & 0xff00ff) | (x & 0xff00ff) << 8, x = x >> 16 | x << 16)
-
struct Crypto1State * crypto1_create(uint64_t key)
{
struct Crypto1State *s = malloc(sizeof(*s));
uint8_t crypto1_bit(struct Crypto1State *s, uint8_t in, int is_encrypted)
{
uint32_t feedin;
+ uint32_t tmp;
uint8_t ret = filter(s->odd);
feedin = ret & !!is_encrypted;
feedin ^= LF_POLY_EVEN & s->even;
s->even = s->even << 1 | parity(feedin);
- s->odd ^= (s->odd ^= s->even, s->even ^= s->odd);
+ tmp = s->odd;
+ s->odd = s->even;
+ s->even = tmp;
return ret;
}
uint8_t crypto1_byte(struct Crypto1State *s, uint8_t in, int is_encrypted)
{
+ /*
uint8_t i, ret = 0;
for (i = 0; i < 8; ++i)
ret |= crypto1_bit(s, BIT(in, i), is_encrypted) << i;
-
+ */
+ // unfold loop
+ uint8_t ret = 0;
+ ret |= crypto1_bit(s, BIT(in, 0), is_encrypted) << 0;
+ ret |= crypto1_bit(s, BIT(in, 1), is_encrypted) << 1;
+ ret |= crypto1_bit(s, BIT(in, 2), is_encrypted) << 2;
+ ret |= crypto1_bit(s, BIT(in, 3), is_encrypted) << 3;
+ ret |= crypto1_bit(s, BIT(in, 4), is_encrypted) << 4;
+ ret |= crypto1_bit(s, BIT(in, 5), is_encrypted) << 5;
+ ret |= crypto1_bit(s, BIT(in, 6), is_encrypted) << 6;
+ ret |= crypto1_bit(s, BIT(in, 7), is_encrypted) << 7;
return ret;
}
uint32_t crypto1_word(struct Crypto1State *s, uint32_t in, int is_encrypted)
{
+ /*
uint32_t i, ret = 0;
for (i = 0; i < 32; ++i)
ret |= crypto1_bit(s, BEBIT(in, i), is_encrypted) << (i ^ 24);
-
+*/
+ uint32_t ret = 0;
+ ret |= crypto1_bit(s, BEBIT(in, 0), is_encrypted) << (0 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 1), is_encrypted) << (1 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 2), is_encrypted) << (2 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 3), is_encrypted) << (3 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 4), is_encrypted) << (4 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 5), is_encrypted) << (5 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 6), is_encrypted) << (6 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 7), is_encrypted) << (7 ^ 24);
+
+ ret |= crypto1_bit(s, BEBIT(in, 8), is_encrypted) << (8 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 9), is_encrypted) << (9 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 10), is_encrypted) << (10 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 11), is_encrypted) << (11 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 12), is_encrypted) << (12 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 13), is_encrypted) << (13 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 14), is_encrypted) << (14 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 15), is_encrypted) << (15 ^ 24);
+
+ ret |= crypto1_bit(s, BEBIT(in, 16), is_encrypted) << (16 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 17), is_encrypted) << (17 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 18), is_encrypted) << (18 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 19), is_encrypted) << (19 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 20), is_encrypted) << (20 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 21), is_encrypted) << (21 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 22), is_encrypted) << (22 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 23), is_encrypted) << (23 ^ 24);
+
+ ret |= crypto1_bit(s, BEBIT(in, 24), is_encrypted) << (24 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 25), is_encrypted) << (25 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 26), is_encrypted) << (26 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 27), is_encrypted) << (27 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 28), is_encrypted) << (28 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 29), is_encrypted) << (29 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 30), is_encrypted) << (30 ^ 24);
+ ret |= crypto1_bit(s, BEBIT(in, 31), is_encrypted) << (31 ^ 24);
return ret;
}
projects / proxmark3-svn / commitdiff