/src/nettle-with-libgmp/serpent-set-key.c

Source (jump to first uncovered line)
/* serpent-set-key.c

   The serpent block cipher.

   For more details on this algorithm, see the Serpent website at
   http://www.cl.cam.ac.uk/~rja14/serpent.html

   Copyright (C) 2011, 2014  Niels Möller
   Copyright (C) 2010, 2011  Simon Josefsson
   Copyright (C) 2003, 2004, 2005 Free Software Foundation, Inc.

   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/.
*/

/* This file is derived from cipher/serpent.c in Libgcrypt v1.4.6.
   The adaption to Nettle was made by Simon Josefsson on 2010-12-07
   with final touches on 2011-05-30.  Changes include replacing
   libgcrypt with nettle in the license template, renaming
   serpent_context to serpent_ctx, renaming u32 to uint32_t, removing
   libgcrypt stubs and selftests, modifying entry function prototypes,
   using FOR_BLOCKS to iterate through data in encrypt/decrypt, using
   LE_READ_UINT32 and LE_WRITE_UINT32 to access data in
   encrypt/decrypt, and running indent on the code. */

#if HAVE_CONFIG_H
#include "config.h"
#endif

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

#include "serpent.h"

#include "macros.h"
#include "serpent-internal.h"

/* Magic number, used during generating of the subkeys.  */
#define PHI 0x9E3779B9

/* These are the S-Boxes of Serpent.  They are copied from Serpents
   reference implementation (the optimized one, contained in
   `floppy2') and are therefore:

     Copyright (C) 1998 Ross Anderson, Eli Biham, Lars Knudsen.

  To quote the Serpent homepage
  (http://www.cl.cam.ac.uk/~rja14/serpent.html):

  "Serpent is now completely in the public domain, and we impose no
   restrictions on its use.  This was announced on the 21st August at
   the First AES Candidate Conference. The optimised implementations
   in the submission package are now under the GNU PUBLIC LICENSE
   (GPL), although some comments in the code still say otherwise. You
   are welcome to use Serpent for any application."  */

/* FIXME: Except when used within the key schedule, the inputs are not
   used after the substitution, and hence we could allow them to be
   destroyed. Can this freedom be used to optimize the sboxes? */
#define SBOX0(type, a, b, c, d, w, x, y, z) \
  do { \
    type t02, t03, t05, t06, t07, t08, t09; \
    type t11, t12, t13, t14, t15, t17, t01; \
    t01 = b   ^ c  ; \
    t02 = a   | d  ; \
    t03 = a   ^ b  ; \
    z   = t02 ^ t01; \
    t05 = c   | z  ; \
    t06 = a   ^ d  ; \
    t07 = b   | c  ; \
    t08 = d   & t05; \
    t09 = t03 & t07; \
    y   = t09 ^ t08; \
    t11 = t09 & y  ; \
    t12 = c   ^ d  ; \
    t13 = t07 ^ t11; \
    t14 = b   & t06; \
    t15 = t06 ^ t13; \
    w   =     ~ t15; \
    t17 = w   ^ t14; \
    x   = t12 ^ t17; \
  } while (0)

#define SBOX1(type, a, b, c, d, w, x, y, z) \
  do { \
    type t02, t03, t04, t05, t06, t07, t08; \
    type t10, t11, t12, t13, t16, t17, t01; \
    t01 = a   | d  ; \
    t02 = c   ^ d  ; \
    t03 =     ~ b  ; \
    t04 = a   ^ c  ; \
    t05 = a   | t03; \
    t06 = d   & t04; \
    t07 = t01 & t02; \
    t08 = b   | t06; \
    y   = t02 ^ t05; \
    t10 = t07 ^ t08; \
    t11 = t01 ^ t10; \
    t12 = y   ^ t11; \
    t13 = b   & d  ; \
    z   =     ~ t10; \
    x   = t13 ^ t12; \
    t16 = t10 | x  ; \
    t17 = t05 & t16; \
    w   = c   ^ t17; \
  } while (0)

#define SBOX2(type, a, b, c, d, w, x, y, z) \
  do {            \
    type t02, t03, t05, t06, t07, t08; \
    type t09, t10, t12, t13, t14, t01; \
    t01 = a   | c  ; \
    t02 = a   ^ b  ; \
    t03 = d   ^ t01; \
    w   = t02 ^ t03; \
    t05 = c   ^ w  ; \
    t06 = b   ^ t05; \
    t07 = b   | t05; \
    t08 = t01 & t06; \
    t09 = t03 ^ t07; \
    t10 = t02 | t09; \
    x   = t10 ^ t08; \
    t12 = a   | d  ; \
    t13 = t09 ^ x  ; \
    t14 = b   ^ t13; \
    z   =     ~ t09; \
    y   = t12 ^ t14; \
  } while (0)

#define SBOX3(type, a, b, c, d, w, x, y, z) \
  do {           \
    type t02, t03, t04, t05, t06, t07, t08; \
    type t09, t10, t11, t13, t14, t15, t01; \
    t01 = a   ^ c  ; \
    t02 = a   | d  ; \
    t03 = a   & d  ; \
    t04 = t01 & t02; \
    t05 = b   | t03; \
    t06 = a   & b  ; \
    t07 = d   ^ t04; \
    t08 = c   | t06; \
    t09 = b   ^ t07; \
    t10 = d   & t05; \
    t11 = t02 ^ t10; \
    z   = t08 ^ t09; \
    t13 = d   | z  ; \
    t14 = a   | t07; \
    t15 = b   & t13; \
    y   = t08 ^ t11; \
    w   = t14 ^ t15; \
    x   = t05 ^ t04; \
  } while (0)

#define SBOX4(type, a, b, c, d, w, x, y, z) \
  do { \
    type t02, t03, t04, t05, t06, t08, t09; \
    type t10, t11, t12, t13, t14, t15, t16, t01; \
    t01 = a   | b  ; \
    t02 = b   | c  ; \
    t03 = a   ^ t02; \
    t04 = b   ^ d  ; \
    t05 = d   | t03; \
    t06 = d   & t01; \
    z   = t03 ^ t06; \
    t08 = z   & t04; \
    t09 = t04 & t05; \
    t10 = c   ^ t06; \
    t11 = b   & c  ; \
    t12 = t04 ^ t08; \
    t13 = t11 | t03; \
    t14 = t10 ^ t09; \
    t15 = a   & t05; \
    t16 = t11 | t12; \
    y   = t13 ^ t08; \
    x   = t15 ^ t16; \
    w   =     ~ t14; \
  } while (0)

#define SBOX5(type, a, b, c, d, w, x, y, z) \
  do { \
    type t02, t03, t04, t05, t07, t08, t09; \
    type t10, t11, t12, t13, t14, t01; \
    t01 = b   ^ d  ; \
    t02 = b   | d  ; \
    t03 = a   & t01; \
    t04 = c   ^ t02; \
    t05 = t03 ^ t04; \
    w   =     ~ t05; \
    t07 = a   ^ t01; \
    t08 = d   | w  ; \
    t09 = b   | t05; \
    t10 = d   ^ t08; \
    t11 = b   | t07; \
    t12 = t03 | w  ; \
    t13 = t07 | t10; \
    t14 = t01 ^ t11; \
    y   = t09 ^ t13; \
    x   = t07 ^ t08; \
    z   = t12 ^ t14; \
  } while (0)

#define SBOX6(type, a, b, c, d, w, x, y, z) \
  do { \
    type t02, t03, t04, t05, t07, t08, t09, t10;  \
    type t11, t12, t13, t15, t17, t18, t01; \
    t01 = a   & d  ; \
    t02 = b   ^ c  ; \
    t03 = a   ^ d  ; \
    t04 = t01 ^ t02; \
    t05 = b   | c  ; \
    x   =     ~ t04; \
    t07 = t03 & t05; \
    t08 = b   & x  ; \
    t09 = a   | c  ; \
    t10 = t07 ^ t08; \
    t11 = b   | d  ; \
    t12 = c   ^ t11; \
    t13 = t09 ^ t10; \
    y   =     ~ t13; \
    t15 = x   & t03; \
    z   = t12 ^ t07; \
    t17 = a   ^ b  ; \
    t18 = y   ^ t15; \
    w   = t17 ^ t18; \
  } while (0)

#define SBOX7(type, a, b, c, d, w, x, y, z) \
  do { \
    type t02, t03, t04, t05, t06, t08, t09, t10;  \
    type t11, t13, t14, t15, t16, t17, t01; \
    t01 = a   & c  ; \
    t02 =     ~ d  ; \
    t03 = a   & t02; \
    t04 = b   | t01; \
    t05 = a   & b  ; \
    t06 = c   ^ t04; \
    z   = t03 ^ t06; \
    t08 = c   | z  ; \
    t09 = d   | t05; \
    t10 = a   ^ t08; \
    t11 = t04 & z  ; \
    x   = t09 ^ t10; \
    t13 = b   ^ x  ; \
    t14 = t01 ^ x  ; \
    t15 = c   ^ t05; \
    t16 = t11 | t13; \
    t17 = t02 | t14; \
    w   = t15 ^ t17; \
    y   = a   ^ t16; \
  } while (0)

/* Key schedule */
/* Note: Increments k */
#define KS_RECURRENCE(w, i, k)            \
  do {                 \
    uint32_t _wn = (w)[(i)] ^ (w)[((i)+3)&7] ^ w[((i)+5)&7]   \
      ^ w[((i)+7)&7] ^ PHI ^ (k)++;         \
    ((w)[(i)] = ROTL32(11, _wn));         \
  } while (0)

/* Note: Increments k four times and keys once */
#define KS(keys, s, w, i, k)          \
  do {               \
    KS_RECURRENCE(w, (i), (k));          \
    KS_RECURRENCE(w, (i)+1, (k));        \
    KS_RECURRENCE(w, (i)+2, (k));        \
    KS_RECURRENCE(w, (i)+3, (k));        \
    SBOX##s(uint32_t, w[(i)],w[(i)+1],w[(i)+2],w[(i)+3],    \
      (*keys)[0],(*keys)[1],(*keys)[2],(*keys)[3]); \
    (keys)++;             \
  } while (0)

/* Pad user key and convert to an array of 8 uint32_t. */
static void
serpent_key_pad (const uint8_t *key, unsigned int key_length,
     uint32_t *w)
{
  unsigned int i;

  assert (key_length <= SERPENT_MAX_KEY_SIZE);
  
  for (i = 0; key_length >= 4; key_length -=4, key += 4)
    w[i++] = LE_READ_UINT32(key);

  if (i < 8)
    {
      /* Key must be padded according to the Serpent specification.
         "aabbcc" -> "aabbcc0100...00" -> 0x01ccbbaa. */
      uint32_t pad = 0x01;
      
      while (key_length > 0)
  pad = pad << 8 | key[--key_length];

      w[i++] = pad;

      while (i < 8)
  w[i++] = 0;
    }
}

/* Initialize CONTEXT with the key KEY of LENGTH bytes.  */
void
serpent_set_key (struct serpent_ctx *ctx,
     size_t length, const uint8_t * key)
{
  uint32_t w[8];
  uint32_t (*keys)[4];
  unsigned k;
  
  serpent_key_pad (key, length, w);

  /* Derive the 33 subkeys from KEY and store them in SUBKEYS. We do
     the recurrence in the key schedule using W as a circular buffer
     of just 8 uint32_t. */

  /* FIXME: Would be better to invoke SBOX with scalar variables as
     arguments, no arrays. To do that, unpack w into separate
     variables, use temporary variables as the SBOX destination. */

  keys = ctx->keys;
  k = 0;
  for (;;)
    {
      KS(keys, 3, w, 0, k);
      if (k == 132)
  break;
      KS(keys, 2, w, 4, k);
      KS(keys, 1, w, 0, k);
      KS(keys, 0, w, 4, k);
      KS(keys, 7, w, 0, k);
      KS(keys, 6, w, 4, k);
      KS(keys, 5, w, 0, k);
      KS(keys, 4, w, 4, k);
    }
  assert (keys == ctx->keys + 33);
}

void
serpent128_set_key (struct serpent_ctx *ctx, const uint8_t *key)
{
  serpent_set_key (ctx, SERPENT128_KEY_SIZE, key);
}

void
serpent192_set_key (struct serpent_ctx *ctx, const uint8_t *key)
{
  serpent_set_key (ctx, SERPENT192_KEY_SIZE, key);
}

void
serpent256_set_key (struct serpent_ctx *ctx, const uint8_t *key)
{
  serpent_set_key (ctx, SERPENT256_KEY_SIZE, key);
}

Coverage Report

Created: 2023-02-22 06:14

Line	Count	Source (jump to first uncovered line)
1		/* serpent-set-key.c
2
3		The serpent block cipher.
4
5		For more details on this algorithm, see the Serpent website at
6		http://www.cl.cam.ac.uk/~rja14/serpent.html
7
8		Copyright (C) 2011, 2014 Niels Möller
9		Copyright (C) 2010, 2011 Simon Josefsson
10		Copyright (C) 2003, 2004, 2005 Free Software Foundation, Inc.
11
12		This file is part of GNU Nettle.
13
14		GNU Nettle is free software: you can redistribute it and/or
15		modify it under the terms of either:
16
17		* the GNU Lesser General Public License as published by the Free
18		Software Foundation; either version 3 of the License, or (at your
19		option) any later version.
20
21		or
22
23		* the GNU General Public License as published by the Free
24		Software Foundation; either version 2 of the License, or (at your
25		option) any later version.
26
27		or both in parallel, as here.
28
29		GNU Nettle is distributed in the hope that it will be useful,
30		but WITHOUT ANY WARRANTY; without even the implied warranty of
31		MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
32		General Public License for more details.
33
34		You should have received copies of the GNU General Public License and
35		the GNU Lesser General Public License along with this program. If
36		not, see http://www.gnu.org/licenses/.
37		*/
38
39		/* This file is derived from cipher/serpent.c in Libgcrypt v1.4.6.
40		The adaption to Nettle was made by Simon Josefsson on 2010-12-07
41		with final touches on 2011-05-30. Changes include replacing
42		libgcrypt with nettle in the license template, renaming
43		serpent_context to serpent_ctx, renaming u32 to uint32_t, removing
44		libgcrypt stubs and selftests, modifying entry function prototypes,
45		using FOR_BLOCKS to iterate through data in encrypt/decrypt, using
46		LE_READ_UINT32 and LE_WRITE_UINT32 to access data in
47		encrypt/decrypt, and running indent on the code. */
48
49		#if HAVE_CONFIG_H
50		#include "config.h"
51		#endif
52
53		#include <assert.h>
54		#include <limits.h>
55
56		#include "serpent.h"
57
58		#include "macros.h"
59		#include "serpent-internal.h"
60
61		/* Magic number, used during generating of the subkeys. */
62	16.8k	#define PHI 0x9E3779B9
63
64		/* These are the S-Boxes of Serpent. They are copied from Serpents
65		reference implementation (the optimized one, contained in
66		`floppy2') and are therefore:
67
68		Copyright (C) 1998 Ross Anderson, Eli Biham, Lars Knudsen.
69
70		To quote the Serpent homepage
71		(http://www.cl.cam.ac.uk/~rja14/serpent.html):
72
73		"Serpent is now completely in the public domain, and we impose no
74		restrictions on its use. This was announced on the 21st August at
75		the First AES Candidate Conference. The optimised implementations
76		in the submission package are now under the GNU PUBLIC LICENSE
77		(GPL), although some comments in the code still say otherwise. You
78		are welcome to use Serpent for any application." */
79
80		/* FIXME: Except when used within the key schedule, the inputs are not
81		used after the substitution, and hence we could allow them to be
82		destroyed. Can this freedom be used to optimize the sboxes? */
83		#define SBOX0(type, a, b, c, d, w, x, y, z) \
84	512	do { \
85	512	type t02, t03, t05, t06, t07, t08, t09; \
86	512	type t11, t12, t13, t14, t15, t17, t01; \
87	512	t01 = b ^ c ; \
88	512	t02 = a \| d ; \
89	512	t03 = a ^ b ; \
90	512	z = t02 ^ t01; \
91	512	t05 = c \| z ; \
92	512	t06 = a ^ d ; \
93	512	t07 = b \| c ; \
94	512	t08 = d & t05; \
95	512	t09 = t03 & t07; \
96	512	y = t09 ^ t08; \
97	512	t11 = t09 & y ; \
98	512	t12 = c ^ d ; \
99	512	t13 = t07 ^ t11; \
100	512	t14 = b & t06; \
101	512	t15 = t06 ^ t13; \
102	512	w = ~ t15; \
103	512	t17 = w ^ t14; \
104	512	x = t12 ^ t17; \
105	512	} while (0)
106
107		#define SBOX1(type, a, b, c, d, w, x, y, z) \
108	512	do { \
109	512	type t02, t03, t04, t05, t06, t07, t08; \
110	512	type t10, t11, t12, t13, t16, t17, t01; \
111	512	t01 = a \| d ; \
112	512	t02 = c ^ d ; \
113	512	t03 = ~ b ; \
114	512	t04 = a ^ c ; \
115	512	t05 = a \| t03; \
116	512	t06 = d & t04; \
117	512	t07 = t01 & t02; \
118	512	t08 = b \| t06; \
119	512	y = t02 ^ t05; \
120	512	t10 = t07 ^ t08; \
121	512	t11 = t01 ^ t10; \
122	512	t12 = y ^ t11; \
123	512	t13 = b & d ; \
124	512	z = ~ t10; \
125	512	x = t13 ^ t12; \
126	512	t16 = t10 \| x ; \
127	512	t17 = t05 & t16; \
128	512	w = c ^ t17; \
129	512	} while (0)
130
131		#define SBOX2(type, a, b, c, d, w, x, y, z) \
132	512	do { \
133	512	type t02, t03, t05, t06, t07, t08; \
134	512	type t09, t10, t12, t13, t14, t01; \
135	512	t01 = a \| c ; \
136	512	t02 = a ^ b ; \
137	512	t03 = d ^ t01; \
138	512	w = t02 ^ t03; \
139	512	t05 = c ^ w ; \
140	512	t06 = b ^ t05; \
141	512	t07 = b \| t05; \
142	512	t08 = t01 & t06; \
143	512	t09 = t03 ^ t07; \
144	512	t10 = t02 \| t09; \
145	512	x = t10 ^ t08; \
146	512	t12 = a \| d ; \
147	512	t13 = t09 ^ x ; \
148	512	t14 = b ^ t13; \
149	512	z = ~ t09; \
150	512	y = t12 ^ t14; \
151	512	} while (0)
152
153		#define SBOX3(type, a, b, c, d, w, x, y, z) \
154	640	do { \
155	640	type t02, t03, t04, t05, t06, t07, t08; \
156	640	type t09, t10, t11, t13, t14, t15, t01; \
157	640	t01 = a ^ c ; \
158	640	t02 = a \| d ; \
159	640	t03 = a & d ; \
160	640	t04 = t01 & t02; \
161	640	t05 = b \| t03; \
162	640	t06 = a & b ; \
163	640	t07 = d ^ t04; \
164	640	t08 = c \| t06; \
165	640	t09 = b ^ t07; \
166	640	t10 = d & t05; \
167	640	t11 = t02 ^ t10; \
168	640	z = t08 ^ t09; \
169	640	t13 = d \| z ; \
170	640	t14 = a \| t07; \
171	640	t15 = b & t13; \
172	640	y = t08 ^ t11; \
173	640	w = t14 ^ t15; \
174	640	x = t05 ^ t04; \
175	640	} while (0)
176
177		#define SBOX4(type, a, b, c, d, w, x, y, z) \
178	512	do { \
179	512	type t02, t03, t04, t05, t06, t08, t09; \
180	512	type t10, t11, t12, t13, t14, t15, t16, t01; \
181	512	t01 = a \| b ; \
182	512	t02 = b \| c ; \
183	512	t03 = a ^ t02; \
184	512	t04 = b ^ d ; \
185	512	t05 = d \| t03; \
186	512	t06 = d & t01; \
187	512	z = t03 ^ t06; \
188	512	t08 = z & t04; \
189	512	t09 = t04 & t05; \
190	512	t10 = c ^ t06; \
191	512	t11 = b & c ; \
192	512	t12 = t04 ^ t08; \
193	512	t13 = t11 \| t03; \
194	512	t14 = t10 ^ t09; \
195	512	t15 = a & t05; \
196	512	t16 = t11 \| t12; \
197	512	y = t13 ^ t08; \
198	512	x = t15 ^ t16; \
199	512	w = ~ t14; \
200	512	} while (0)
201
202		#define SBOX5(type, a, b, c, d, w, x, y, z) \
203	512	do { \
204	512	type t02, t03, t04, t05, t07, t08, t09; \
205	512	type t10, t11, t12, t13, t14, t01; \
206	512	t01 = b ^ d ; \
207	512	t02 = b \| d ; \
208	512	t03 = a & t01; \
209	512	t04 = c ^ t02; \
210	512	t05 = t03 ^ t04; \
211	512	w = ~ t05; \
212	512	t07 = a ^ t01; \
213	512	t08 = d \| w ; \
214	512	t09 = b \| t05; \
215	512	t10 = d ^ t08; \
216	512	t11 = b \| t07; \
217	512	t12 = t03 \| w ; \
218	512	t13 = t07 \| t10; \
219	512	t14 = t01 ^ t11; \
220	512	y = t09 ^ t13; \
221	512	x = t07 ^ t08; \
222	512	z = t12 ^ t14; \
223	512	} while (0)
224
225		#define SBOX6(type, a, b, c, d, w, x, y, z) \
226	512	do { \
227	512	type t02, t03, t04, t05, t07, t08, t09, t10; \
228	512	type t11, t12, t13, t15, t17, t18, t01; \
229	512	t01 = a & d ; \
230	512	t02 = b ^ c ; \
231	512	t03 = a ^ d ; \
232	512	t04 = t01 ^ t02; \
233	512	t05 = b \| c ; \
234	512	x = ~ t04; \
235	512	t07 = t03 & t05; \
236	512	t08 = b & x ; \
237	512	t09 = a \| c ; \
238	512	t10 = t07 ^ t08; \
239	512	t11 = b \| d ; \
240	512	t12 = c ^ t11; \
241	512	t13 = t09 ^ t10; \
242	512	y = ~ t13; \
243	512	t15 = x & t03; \
244	512	z = t12 ^ t07; \
245	512	t17 = a ^ b ; \
246	512	t18 = y ^ t15; \
247	512	w = t17 ^ t18; \
248	512	} while (0)
249
250		#define SBOX7(type, a, b, c, d, w, x, y, z) \
251	512	do { \
252	512	type t02, t03, t04, t05, t06, t08, t09, t10; \
253	512	type t11, t13, t14, t15, t16, t17, t01; \
254	512	t01 = a & c ; \
255	512	t02 = ~ d ; \
256	512	t03 = a & t02; \
257	512	t04 = b \| t01; \
258	512	t05 = a & b ; \
259	512	t06 = c ^ t04; \
260	512	z = t03 ^ t06; \
261	512	t08 = c \| z ; \
262	512	t09 = d \| t05; \
263	512	t10 = a ^ t08; \
264	512	t11 = t04 & z ; \
265	512	x = t09 ^ t10; \
266	512	t13 = b ^ x ; \
267	512	t14 = t01 ^ x ; \
268	512	t15 = c ^ t05; \
269	512	t16 = t11 \| t13; \
270	512	t17 = t02 \| t14; \
271	512	w = t15 ^ t17; \
272	512	y = a ^ t16; \
273	512	} while (0)
274
275		/* Key schedule */
276		/* Note: Increments k */
277		#define KS_RECURRENCE(w, i, k) \
278	16.8k	do { \
279	16.8k	uint32_t _wn = (w)[(i)] ^ (w)[((i)+3)&7] ^ w[((i)+5)&7] \
280	16.8k	^ w[((i)+7)&7] ^ PHI ^ (k)++; \
281	16.8k	((w)[(i)] = ROTL32(11, _wn)); \
282	16.8k	} while (0)
283
284		/* Note: Increments k four times and keys once */
285		#define KS(keys, s, w, i, k) \
286	4.22k	do { \
287	4.22k	KS_RECURRENCE(w, (i), (k)); \
288	4.22k	KS_RECURRENCE(w, (i)+1, (k)); \
289	4.22k	KS_RECURRENCE(w, (i)+2, (k)); \
290	4.22k	KS_RECURRENCE(w, (i)+3, (k)); \
291	4.22k	SBOX##s(uint32_t, w[(i)],w[(i)+1],w[(i)+2],w[(i)+3], \
292	4.22k	(keys)[0],(keys)[1],(keys)[2],(keys)[3]); \
293	4.22k	(keys)++; \
294	4.22k	} while (0)
295
296		/* Pad user key and convert to an array of 8 uint32_t. */
297		static void
298		serpent_key_pad (const uint8_t *key, unsigned int key_length,
299		uint32_t *w)
300	128	{
301	128	unsigned int i;
302
303	128	assert (key_length <= SERPENT_MAX_KEY_SIZE);
304
305	1.06k	for (i = 0; key_length >= 4; key_length -=4, key += 4)
306	936	w[i++] = LE_READ_UINT32(key);
307
308	128	if (i < 8)
309	52	{
310		/* Key must be padded according to the Serpent specification.
311		"aabbcc" -> "aabbcc0100...00" -> 0x01ccbbaa. */
312	52	uint32_t pad = 0x01;
313
314	88	while (key_length > 0)
315	36	pad = pad << 8 \| key[--key_length];
316
317	52	w[i++] = pad;
318
319	88	while (i < 8)
320	36	w[i++] = 0;
321	52	}
322	128	}
323
324		/* Initialize CONTEXT with the key KEY of LENGTH bytes. */
325		void
326		serpent_set_key (struct serpent_ctx *ctx,
327		size_t length, const uint8_t * key)
328	128	{
329	128	uint32_t w[8];
330	128	uint32_t (*keys)[4];
331	128	unsigned k;
332
333	128	serpent_key_pad (key, length, w);
334
335		/* Derive the 33 subkeys from KEY and store them in SUBKEYS. We do
336		the recurrence in the key schedule using W as a circular buffer
337		of just 8 uint32_t. */
338
339		/* FIXME: Would be better to invoke SBOX with scalar variables as
340		arguments, no arrays. To do that, unpack w into separate
341		variables, use temporary variables as the SBOX destination. */
342
343	128	keys = ctx->keys;
344	128	k = 0;
345	128	for (;;)
346	640	{
347	640	KS(keys, 3, w, 0, k);
348	640	if (k == 132)
349	128	break;
350	512	KS(keys, 2, w, 4, k);
351	512	KS(keys, 1, w, 0, k);
352	512	KS(keys, 0, w, 4, k);
353	512	KS(keys, 7, w, 0, k);
354	512	KS(keys, 6, w, 4, k);
355	512	KS(keys, 5, w, 0, k);
356	512	KS(keys, 4, w, 4, k);
357	512	}
358	128	assert (keys == ctx->keys + 33);
359	128	}
360
361		void
362		serpent128_set_key (struct serpent_ctx ctx, const uint8_t key)
363	0	{
364	0	serpent_set_key (ctx, SERPENT128_KEY_SIZE, key);
365	0	}
366
367		void
368		serpent192_set_key (struct serpent_ctx ctx, const uint8_t key)
369	0	{
370	0	serpent_set_key (ctx, SERPENT192_KEY_SIZE, key);
371	0	}
372
373		void
374		serpent256_set_key (struct serpent_ctx ctx, const uint8_t key)
375	0	{
376	0	serpent_set_key (ctx, SERPENT256_KEY_SIZE, key);
377	0	}