/src/nettle-with-libgmp/camellia256-set-encrypt-key.c

Source
/* camellia256-set-encrypt-key.c

   Key setup for the camellia block cipher.

   Copyright (C) 2006,2007 NTT
   (Nippon Telegraph and Telephone Corporation).

   Copyright (C) 2010, 2013 Niels Möller

   This file is part of GNU Nettle.

   GNU Nettle is free software: you can redistribute it and/or
   modify it under the terms of either:

     * the GNU Lesser General Public License as published by the Free
       Software Foundation; either version 3 of the License, or (at your
       option) any later version.

   or

     * the GNU General Public License as published by the Free
       Software Foundation; either version 2 of the License, or (at your
       option) any later version.

   or both in parallel, as here.

   GNU Nettle is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
   General Public License for more details.

   You should have received copies of the GNU General Public License and
   the GNU Lesser General Public License along with this program.  If
   not, see http://www.gnu.org/licenses/.
*/

/*
 * Algorithm Specification 
 *  http://info.isl.ntt.co.jp/crypt/eng/camellia/specifications.html
 */

/* Based on camellia.c ver 1.2.0, see
   http://info.isl.ntt.co.jp/crypt/eng/camellia/dl/camellia-LGPL-1.2.0.tar.gz.
 */
#if HAVE_CONFIG_H
# include "config.h"
#endif

#include <assert.h>
#include <limits.h>

#include "camellia-internal.h"

#include "macros.h"

static void
_camellia256_set_encrypt_key (struct camellia256_ctx *ctx,
            uint64_t k0, uint64_t k1,
            uint64_t k2, uint64_t k3)
{
  uint64_t subkey[_CAMELLIA256_NKEYS + 2];
  uint64_t w;
  
  /* generate KL dependent subkeys */
  subkey[0] = k0; subkey[1] = k1;
  ROTL128(45, k0, k1);
  subkey[12] = k0; subkey[13] = k1;
  ROTL128(15, k0, k1);
  subkey[16] = k0; subkey[17] = k1;
  ROTL128(17, k0, k1);
  subkey[22] = k0; subkey[23] = k1;
  ROTL128(34, k0, k1);
  subkey[30] = k0; subkey[31] = k1;

  /* generate KR dependent subkeys */
  ROTL128(15, k2, k3);
  subkey[4] = k2; subkey[5] = k3;
  ROTL128(15, k2, k3);
  subkey[8] = k2; subkey[9] = k3;
  ROTL128(30, k2, k3);
  subkey[18] = k2; subkey[19] = k3;
  ROTL128(34, k2, k3);
  subkey[26] = k2; subkey[27] = k3;
  ROTL128(34, k2, k3);

  /* generate KA */
  /* The construction of KA is done as

     D1 = (KL ^ KR) >> 64
     D2 = (KL ^ KR) & MASK64
     W = F(D1, SIGMA1)
     D2 = D2 ^ W
     D1 = F(D2, SIGMA2) ^ (KR >> 64)
     D2 = F(D1, SIGMA3) ^ W ^ (KR & MASK64)
     D1 = D1 ^ F(W, SIGMA2)
     D2 = D2 ^ F(D1, SIGMA3)
     D1 = D1 ^ F(D2, SIGMA4)
  */

  k0 = subkey[0] ^ k2;
  k1 = subkey[1] ^ k3;

  CAMELLIA_F(k0, SIGMA1, w);
  k1 ^= w;

  CAMELLIA_F(k1, SIGMA2, k0);
  k0 ^= k2;

  CAMELLIA_F(k0, SIGMA3, k1);
  k1 ^= w ^ k3;

  CAMELLIA_F(k1, SIGMA4, w);
  k0 ^= w;

  /* generate KB */
  k2 ^= k0; k3 ^= k1;
  CAMELLIA_F(k2, SIGMA5, w);
  k3 ^= w;
  CAMELLIA_F(k3, SIGMA6, w);
  k2 ^= w;

  /* generate KA dependent subkeys */
  ROTL128(15, k0, k1);
  subkey[6] = k0; subkey[7] = k1;
  ROTL128(30, k0, k1);
  subkey[14] = k0; subkey[15] = k1;
  ROTL128(32, k0, k1);
  subkey[24] = k0; subkey[25] = k1;
  ROTL128(17, k0, k1);
  subkey[28] = k0; subkey[29] = k1;

  /* generate KB dependent subkeys */
  subkey[2] = k2; subkey[3] = k3;
  ROTL128(30, k2, k3);
  subkey[10] = k2; subkey[11] = k3;
  ROTL128(30, k2, k3);
  subkey[20] = k2; subkey[21] = k3;
  ROTL128(51, k2, k3);
  subkey[32] = k2; subkey[33] = k3;

  /* Common final processing */
  _nettle_camellia_absorb (_CAMELLIA256_NKEYS, ctx->keys, subkey);
}

void
camellia256_set_encrypt_key(struct camellia256_ctx *ctx,
          const uint8_t *key)
{
  uint64_t k0, k1, k2, k3;
  k0 = READ_UINT64(key);
  k1 = READ_UINT64(key +  8);
  k2 = READ_UINT64(key + 16);
  k3 = READ_UINT64(key + 24);

  _camellia256_set_encrypt_key (ctx, k0, k1, k2, k3);
}

void
camellia192_set_encrypt_key(struct camellia256_ctx *ctx,
          const uint8_t *key)
{
  uint64_t k0, k1, k2;
  k0 = READ_UINT64(key);
  k1 = READ_UINT64(key +  8);
  k2 = READ_UINT64(key + 16);

  _camellia256_set_encrypt_key (ctx, k0, k1, k2, ~k2);
}

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	393	{
61	393	uint64_t subkey[_CAMELLIA256_NKEYS + 2];
62	393	uint64_t w;
63
64		/* generate KL dependent subkeys */
65	393	subkey[0] = k0; subkey[1] = k1;
66	393	ROTL128(45, k0, k1);
67	393	subkey[12] = k0; subkey[13] = k1;
68	393	ROTL128(15, k0, k1);
69	393	subkey[16] = k0; subkey[17] = k1;
70	393	ROTL128(17, k0, k1);
71	393	subkey[22] = k0; subkey[23] = k1;
72	393	ROTL128(34, k0, k1);
73	393	subkey[30] = k0; subkey[31] = k1;
74
75		/* generate KR dependent subkeys */
76	393	ROTL128(15, k2, k3);
77	393	subkey[4] = k2; subkey[5] = k3;
78	393	ROTL128(15, k2, k3);
79	393	subkey[8] = k2; subkey[9] = k3;
80	393	ROTL128(30, k2, k3);
81	393	subkey[18] = k2; subkey[19] = k3;
82	393	ROTL128(34, k2, k3);
83	393	subkey[26] = k2; subkey[27] = k3;
84	393	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	393	k0 = subkey[0] ^ k2;
101	393	k1 = subkey[1] ^ k3;
102
103	393	CAMELLIA_F(k0, SIGMA1, w);
104	393	k1 ^= w;
105
106	393	CAMELLIA_F(k1, SIGMA2, k0);
107	393	k0 ^= k2;
108
109	393	CAMELLIA_F(k0, SIGMA3, k1);
110	393	k1 ^= w ^ k3;
111
112	393	CAMELLIA_F(k1, SIGMA4, w);
113	393	k0 ^= w;
114
115		/* generate KB */
116	393	k2 ^= k0; k3 ^= k1;
117	393	CAMELLIA_F(k2, SIGMA5, w);
118	393	k3 ^= w;
119	393	CAMELLIA_F(k3, SIGMA6, w);
120	393	k2 ^= w;
121
122		/* generate KA dependent subkeys */
123	393	ROTL128(15, k0, k1);
124	393	subkey[6] = k0; subkey[7] = k1;
125	393	ROTL128(30, k0, k1);
126	393	subkey[14] = k0; subkey[15] = k1;
127	393	ROTL128(32, k0, k1);
128	393	subkey[24] = k0; subkey[25] = k1;
129	393	ROTL128(17, k0, k1);
130	393	subkey[28] = k0; subkey[29] = k1;
131
132		/* generate KB dependent subkeys */
133	393	subkey[2] = k2; subkey[3] = k3;
134	393	ROTL128(30, k2, k3);
135	393	subkey[10] = k2; subkey[11] = k3;
136	393	ROTL128(30, k2, k3);
137	393	subkey[20] = k2; subkey[21] = k3;
138	393	ROTL128(51, k2, k3);
139	393	subkey[32] = k2; subkey[33] = k3;
140
141		/* Common final processing */
142	393	_nettle_camellia_absorb (_CAMELLIA256_NKEYS, ctx->keys, subkey);
143	393	}
144
145		void
146		camellia256_set_encrypt_key(struct camellia256_ctx *ctx,
147		const uint8_t *key)
148	351	{
149	351	uint64_t k0, k1, k2, k3;
150	351	k0 = READ_UINT64(key);
151	351	k1 = READ_UINT64(key + 8);
152	351	k2 = READ_UINT64(key + 16);
153	351	k3 = READ_UINT64(key + 24);
154
155	351	_camellia256_set_encrypt_key (ctx, k0, k1, k2, k3);
156	351	}
157
158		void
159		camellia192_set_encrypt_key(struct camellia256_ctx *ctx,
160		const uint8_t *key)
161	42	{
162	42	uint64_t k0, k1, k2;
163	42	k0 = READ_UINT64(key);
164	42	k1 = READ_UINT64(key + 8);
165	42	k2 = READ_UINT64(key + 16);
166
167	42	_camellia256_set_encrypt_key (ctx, k0, k1, k2, ~k2);
168	42	}

Coverage Report

Created: 2024-06-28 06:39