/src/nettle-with-mini-gmp/camellia256-set-encrypt-key.c
Line | Count | Source |
1 | | /* camellia256-set-encrypt-key.c |
2 | | |
3 | | Key setup for the camellia block cipher. |
4 | | |
5 | | Copyright (C) 2006,2007 NTT |
6 | | (Nippon Telegraph and Telephone Corporation). |
7 | | |
8 | | Copyright (C) 2010, 2013 Niels Möller |
9 | | |
10 | | This file is part of GNU Nettle. |
11 | | |
12 | | GNU Nettle is free software: you can redistribute it and/or |
13 | | modify it under the terms of either: |
14 | | |
15 | | * the GNU Lesser General Public License as published by the Free |
16 | | Software Foundation; either version 3 of the License, or (at your |
17 | | option) any later version. |
18 | | |
19 | | or |
20 | | |
21 | | * the GNU General Public License as published by the Free |
22 | | Software Foundation; either version 2 of the License, or (at your |
23 | | option) any later version. |
24 | | |
25 | | or both in parallel, as here. |
26 | | |
27 | | GNU Nettle is distributed in the hope that it will be useful, |
28 | | but WITHOUT ANY WARRANTY; without even the implied warranty of |
29 | | MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU |
30 | | General Public License for more details. |
31 | | |
32 | | You should have received copies of the GNU General Public License and |
33 | | the GNU Lesser General Public License along with this program. If |
34 | | not, see http://www.gnu.org/licenses/. |
35 | | */ |
36 | | |
37 | | /* |
38 | | * Algorithm Specification |
39 | | * http://info.isl.ntt.co.jp/crypt/eng/camellia/specifications.html |
40 | | */ |
41 | | |
42 | | /* Based on camellia.c ver 1.2.0, see |
43 | | http://info.isl.ntt.co.jp/crypt/eng/camellia/dl/camellia-LGPL-1.2.0.tar.gz. |
44 | | */ |
45 | | #if HAVE_CONFIG_H |
46 | | # include "config.h" |
47 | | #endif |
48 | | |
49 | | #include <assert.h> |
50 | | #include <limits.h> |
51 | | |
52 | | #include "camellia-internal.h" |
53 | | |
54 | | #include "macros.h" |
55 | | |
56 | | static void |
57 | | _camellia256_set_encrypt_key (struct camellia256_ctx *ctx, |
58 | | uint64_t k0, uint64_t k1, |
59 | | uint64_t k2, uint64_t k3) |
60 | 635 | { |
61 | 635 | uint64_t subkey[_CAMELLIA256_NKEYS + 2]; |
62 | 635 | uint64_t w; |
63 | | |
64 | | /* generate KL dependent subkeys */ |
65 | 635 | subkey[0] = k0; subkey[1] = k1; |
66 | 635 | ROTL128(45, k0, k1); |
67 | 635 | subkey[12] = k0; subkey[13] = k1; |
68 | 635 | ROTL128(15, k0, k1); |
69 | 635 | subkey[16] = k0; subkey[17] = k1; |
70 | 635 | ROTL128(17, k0, k1); |
71 | 635 | subkey[22] = k0; subkey[23] = k1; |
72 | 635 | ROTL128(34, k0, k1); |
73 | 635 | subkey[30] = k0; subkey[31] = k1; |
74 | | |
75 | | /* generate KR dependent subkeys */ |
76 | 635 | ROTL128(15, k2, k3); |
77 | 635 | subkey[4] = k2; subkey[5] = k3; |
78 | 635 | ROTL128(15, k2, k3); |
79 | 635 | subkey[8] = k2; subkey[9] = k3; |
80 | 635 | ROTL128(30, k2, k3); |
81 | 635 | subkey[18] = k2; subkey[19] = k3; |
82 | 635 | ROTL128(34, k2, k3); |
83 | 635 | subkey[26] = k2; subkey[27] = k3; |
84 | 635 | ROTL128(34, k2, k3); |
85 | | |
86 | | /* generate KA */ |
87 | | /* The construction of KA is done as |
88 | | |
89 | | D1 = (KL ^ KR) >> 64 |
90 | | D2 = (KL ^ KR) & MASK64 |
91 | | W = F(D1, SIGMA1) |
92 | | D2 = D2 ^ W |
93 | | D1 = F(D2, SIGMA2) ^ (KR >> 64) |
94 | | D2 = F(D1, SIGMA3) ^ W ^ (KR & MASK64) |
95 | | D1 = D1 ^ F(W, SIGMA2) |
96 | | D2 = D2 ^ F(D1, SIGMA3) |
97 | | D1 = D1 ^ F(D2, SIGMA4) |
98 | | */ |
99 | | |
100 | 635 | k0 = subkey[0] ^ k2; |
101 | 635 | k1 = subkey[1] ^ k3; |
102 | | |
103 | 635 | CAMELLIA_F(k0, SIGMA1, w); |
104 | 635 | k1 ^= w; |
105 | | |
106 | 635 | CAMELLIA_F(k1, SIGMA2, k0); |
107 | 635 | k0 ^= k2; |
108 | | |
109 | 635 | CAMELLIA_F(k0, SIGMA3, k1); |
110 | 635 | k1 ^= w ^ k3; |
111 | | |
112 | 635 | CAMELLIA_F(k1, SIGMA4, w); |
113 | 635 | k0 ^= w; |
114 | | |
115 | | /* generate KB */ |
116 | 635 | k2 ^= k0; k3 ^= k1; |
117 | 635 | CAMELLIA_F(k2, SIGMA5, w); |
118 | 635 | k3 ^= w; |
119 | 635 | CAMELLIA_F(k3, SIGMA6, w); |
120 | 635 | k2 ^= w; |
121 | | |
122 | | /* generate KA dependent subkeys */ |
123 | 635 | ROTL128(15, k0, k1); |
124 | 635 | subkey[6] = k0; subkey[7] = k1; |
125 | 635 | ROTL128(30, k0, k1); |
126 | 635 | subkey[14] = k0; subkey[15] = k1; |
127 | 635 | ROTL128(32, k0, k1); |
128 | 635 | subkey[24] = k0; subkey[25] = k1; |
129 | 635 | ROTL128(17, k0, k1); |
130 | 635 | subkey[28] = k0; subkey[29] = k1; |
131 | | |
132 | | /* generate KB dependent subkeys */ |
133 | 635 | subkey[2] = k2; subkey[3] = k3; |
134 | 635 | ROTL128(30, k2, k3); |
135 | 635 | subkey[10] = k2; subkey[11] = k3; |
136 | 635 | ROTL128(30, k2, k3); |
137 | 635 | subkey[20] = k2; subkey[21] = k3; |
138 | 635 | ROTL128(51, k2, k3); |
139 | 635 | subkey[32] = k2; subkey[33] = k3; |
140 | | |
141 | | /* Common final processing */ |
142 | 635 | _nettle_camellia_absorb (_CAMELLIA256_NKEYS, ctx->keys, subkey); |
143 | 635 | } |
144 | | |
145 | | void |
146 | | camellia256_set_encrypt_key(struct camellia256_ctx *ctx, |
147 | | const uint8_t *key) |
148 | 551 | { |
149 | 551 | uint64_t k0, k1, k2, k3; |
150 | 551 | k0 = READ_UINT64(key); |
151 | 551 | k1 = READ_UINT64(key + 8); |
152 | 551 | k2 = READ_UINT64(key + 16); |
153 | 551 | k3 = READ_UINT64(key + 24); |
154 | | |
155 | 551 | _camellia256_set_encrypt_key (ctx, k0, k1, k2, k3); |
156 | 551 | } |
157 | | |
158 | | void |
159 | | camellia192_set_encrypt_key(struct camellia256_ctx *ctx, |
160 | | const uint8_t *key) |
161 | 84 | { |
162 | 84 | uint64_t k0, k1, k2; |
163 | 84 | k0 = READ_UINT64(key); |
164 | 84 | k1 = READ_UINT64(key + 8); |
165 | 84 | k2 = READ_UINT64(key + 16); |
166 | | |
167 | 84 | _camellia256_set_encrypt_key (ctx, k0, k1, k2, ~k2); |
168 | 84 | } |