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1 #ifndef _CRYPTO1_BS_H
2 #define _CRYPTO1_BS_H
3 #include <stdbool.h>
4 #include <stdint.h>
5 #include <stdio.h>
6 #include <string.h>
7 #include <stdlib.h>
8 #include <unistd.h>
9
10 // bitslice type
11 // while AVX supports 256 bit vector floating point operations, we need integer operations for boolean logic
12 // same for AVX2 and 512 bit vectors
13 // using larger vectors works but seems to generate more register pressure
14 #if defined(__AVX2__)
15 #define MAX_BITSLICES 256
16 #elif defined(__AVX__)
17 #define MAX_BITSLICES 128
18 #elif defined(__SSE2__)
19 #define MAX_BITSLICES 128
20 #else
21 #define MAX_BITSLICES 64
22 #endif
23
24 #define VECTOR_SIZE (MAX_BITSLICES/8)
25 typedef unsigned int __attribute__((aligned(VECTOR_SIZE))) __attribute__((vector_size(VECTOR_SIZE))) bitslice_value_t;
26 typedef union {
27 bitslice_value_t value;
28 uint64_t bytes64[MAX_BITSLICES/64];
29 uint8_t bytes[MAX_BITSLICES/8];
30 } bitslice_t;
31
32 // filter function (f20)
33 // sourced from ``Wirelessly Pickpocketing a Mifare Classic Card'' by Flavio Garcia, Peter van Rossum, Roel Verdult and Ronny Wichers Schreur
34 #define f20a(a,b,c,d) (((a|b)^(a&d))^(c&((a^b)|d)))
35 #define f20b(a,b,c,d) (((a&b)|c)^((a^b)&(c|d)))
36 #define f20c(a,b,c,d,e) ((a|((b|e)&(d^e)))^((a^(b&d))&((c^d)|(b&e))))
37
38 #define crypto1_bs_f20(s) \
39 f20c(f20a((s[47- 9].value), (s[47-11].value), (s[47-13].value), (s[47-15].value)), \
40 f20b((s[47-17].value), (s[47-19].value), (s[47-21].value), (s[47-23].value)), \
41 f20b((s[47-25].value), (s[47-27].value), (s[47-29].value), (s[47-31].value)), \
42 f20a((s[47-33].value), (s[47-35].value), (s[47-37].value), (s[47-39].value)), \
43 f20b((s[47-41].value), (s[47-43].value), (s[47-45].value), (s[47-47].value)))
44
45 // bit indexing
46 #define get_bit(n, word) ((word >> (n)) & 1)
47 #define get_vector_bit(slice, value) get_bit(slice&0x3f, value.bytes64[slice>>6])
48
49 // constant ones/zeroes
50 bitslice_t bs_ones;
51 bitslice_t bs_zeroes;
52
53 // size of crypto-1 state
54 #define STATE_SIZE 48
55 // size of nonce to be decrypted
56 #define KEYSTREAM_SIZE 32
57 // size of first uid^nonce byte to be rolled back to the initial key
58 #define ROLLBACK_SIZE 8
59 // number of nonces required to test to cover entire 48-bit state
60 // I would have said it's 12... but bla goes with 100, so I do too
61 #define NONCE_TESTS 100
62
63 // state pointer management
64 extern __thread bitslice_t states[KEYSTREAM_SIZE+STATE_SIZE];
65 extern __thread bitslice_t * restrict state_p;
66
67 // rewind to the point a0, at which KEYSTREAM_SIZE more bits can be generated
68 #define crypto1_bs_rewind_a0() (state_p = &states[KEYSTREAM_SIZE])
69
70 // bitsliced bytewise parity
71 #define bitsliced_byte_parity(n) (n[0].value ^ n[1].value ^ n[2].value ^ n[3].value ^ n[4].value ^ n[5].value ^ n[6].value ^ n[7].value)
72
73 // 48-bit crypto-1 states are normally represented using 64-bit values
74 typedef union {
75 uint64_t value;
76 uint8_t bytes[8];
77 } state_t;
78
79 // endianness conversion
80 #define rev32(word) (((word & 0xff) << 24) | (((word >> 8) & 0xff) << 16) | (((word >> 16) & 0xff) << 8) | (((word >> 24) & 0xff)))
81 #define rev64(x) (rev32(x)<<32|(rev32((x>>32))))
82 #define rev_state_t rev64
83
84 // crypto-1 functions
85 const bitslice_value_t crypto1_bs_bit(const bitslice_value_t input, const bool is_encrypted);
86 const bitslice_value_t crypto1_bs_lfsr_rollback(const bitslice_value_t input, const bool is_encrypted);
87
88 // initialization functions
89 void crypto1_bs_init();
90
91 // conversion functions
92 void crypto1_bs_bitslice_value32(uint32_t value, bitslice_t bitsliced_value[], size_t bit_len);
93 void crypto1_bs_convert_states(bitslice_t bitsliced_states[], state_t regular_states[]);
94
95 // debug print
96 void crypto1_bs_print_states(bitslice_t *bitsliced_states);
97
98 #endif // _CRYPTO1_BS_H
99
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