1 // Bit-sliced Crypto-1 implementation
2 // The cipher states are stored with the least significant bit first, hence all bit indexes are reversed here
4 Copyright (c) 2015-2016 Aram Verstegen
6 Permission is hereby granted, free of charge, to any person obtaining a copy
7 of this software and associated documentation files (the "Software"), to deal
8 in the Software without restriction, including without limitation the rights
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11 furnished to do so, subject to the following conditions:
13 The above copyright notice and this permission notice shall be included in
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25 #include "crypto1_bs.h"
27 #define __STDC_FORMAT_MACROS
32 // The following functions use this global or thread-local state
33 // It is sized to fit exactly KEYSTREAM_SIZE more states next to the initial state
34 __thread bitslice_t states
[KEYSTREAM_SIZE
+STATE_SIZE
];
35 __thread bitslice_t
* restrict state_p
;
37 void crypto1_bs_init(){
38 // initialize constant one and zero bit vectors
39 memset(bs_ones
.bytes
, 0xff, VECTOR_SIZE
);
40 memset(bs_zeroes
.bytes
, 0x00, VECTOR_SIZE
);
43 // The following functions have side effects on 48 bitslices at the state_p pointer
44 // use the crypto1_bs_rewind_* macros to (re-)initialize them as needed
46 inline const bitslice_value_t
crypto1_bs_bit(const bitslice_value_t input
, const bool is_encrypted
){
47 bitslice_value_t feedback
= (state_p
[47- 0].value
^ state_p
[47- 5].value
^ state_p
[47- 9].value
^
48 state_p
[47-10].value
^ state_p
[47-12].value
^ state_p
[47-14].value
^
49 state_p
[47-15].value
^ state_p
[47-17].value
^ state_p
[47-19].value
^
50 state_p
[47-24].value
^ state_p
[47-25].value
^ state_p
[47-27].value
^
51 state_p
[47-29].value
^ state_p
[47-35].value
^ state_p
[47-39].value
^
52 state_p
[47-41].value
^ state_p
[47-42].value
^ state_p
[47-43].value
);
53 const bitslice_value_t ks_bits
= crypto1_bs_f20(state_p
);
58 state_p
[0].value
= feedback
^ input
;
62 inline const bitslice_value_t
crypto1_bs_lfsr_rollback(const bitslice_value_t input
, const bool is_encrypted
){
63 bitslice_value_t feedout
= state_p
[0].value
;
65 const bitslice_value_t ks_bits
= crypto1_bs_f20(state_p
);
69 const bitslice_value_t feedback
= (feedout
^ state_p
[47- 5].value
^ state_p
[47- 9].value
^
70 state_p
[47-10].value
^ state_p
[47-12].value
^ state_p
[47-14].value
^
71 state_p
[47-15].value
^ state_p
[47-17].value
^ state_p
[47-19].value
^
72 state_p
[47-24].value
^ state_p
[47-25].value
^ state_p
[47-27].value
^
73 state_p
[47-29].value
^ state_p
[47-35].value
^ state_p
[47-39].value
^
74 state_p
[47-41].value
^ state_p
[47-42].value
^ state_p
[47-43].value
);
75 state_p
[47].value
= feedback
^ input
;
79 // side-effect free from here on
80 // note that bytes are sliced and unsliced with reversed endianness
81 inline void crypto1_bs_convert_states(bitslice_t bitsliced_states
[], state_t regular_states
[]){
82 size_t bit_idx
= 0, slice_idx
= 0;
83 state_t values
[MAX_BITSLICES
];
84 memset(values
, 0x0, sizeof(values
));
86 for(slice_idx
= 0; slice_idx
< MAX_BITSLICES
; slice_idx
++){
87 for(bit_idx
= 0; bit_idx
< STATE_SIZE
; bit_idx
++){
88 bool bit
= get_vector_bit(slice_idx
, bitsliced_states
[bit_idx
]);
89 values
[slice_idx
].value
<<= 1;
90 values
[slice_idx
].value
|= bit
;
93 values
[slice_idx
].value
= rev_state_t(values
[slice_idx
].value
);
94 // roll off unused bits
95 //values[slice_idx].value >>= ((sizeof(state_t)*8)-STATE_SIZE); // - 48
96 values
[slice_idx
].value
>>= 16;
98 memcpy(regular_states
, values
, sizeof(values
));
102 void crypto1_bs_bitslice_value32(uint32_t value
, bitslice_t bitsliced_value
[], size_t bit_len
){
103 // load nonce bytes with unswapped endianness
105 for(bit_idx
= 0; bit_idx
< bit_len
; bit_idx
++){
106 bool bit
= get_bit(bit_len
-1-bit_idx
, rev32(value
));
108 bitsliced_value
[bit_idx
].value
= bs_ones
.value
;
110 bitsliced_value
[bit_idx
].value
= bs_zeroes
.value
;
115 void crypto1_bs_print_states(bitslice_t bitsliced_states
[]){
116 size_t slice_idx
= 0;
117 state_t values
[MAX_BITSLICES
] = {{0x00}};
118 crypto1_bs_convert_states(bitsliced_states
, values
);
119 for(slice_idx
= 0; slice_idx
< MAX_BITSLICES
; slice_idx
++){
120 printf("State %03zu: %012"llx
"\n", slice_idx
, values
[slice_idx
].value
);