/src/nettle-with-mini-gmp/ocb.c

Source (jump to first uncovered line)
/* ocb.c

   OCB AEAD mode, RFC 7253

   Copyright (C) 2021 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/.
*/

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

#include <string.h>

#include "ocb.h"
#include "block-internal.h"
#include "bswap-internal.h"
#include "memops.h"

#define OCB_MAX_BLOCKS 16

/* Returns 64 bits from the concatenation (u0, u1), starting from bit offset. */
static inline uint64_t
extract(uint64_t u0, uint64_t u1, unsigned offset)
{
  if (offset == 0)
    return u0;
  u0 = bswap64_if_le(u0);
  u1 = bswap64_if_le(u1);
  return bswap64_if_le((u0 << offset) | (u1 >> (64 - offset)));
}

void
ocb_set_key (struct ocb_key *key, const void *cipher, nettle_cipher_func *f)
{
  static const union nettle_block16 zero_block;
  f (cipher, OCB_BLOCK_SIZE, key->L[0].b, zero_block.b);
  block16_mulx_be (&key->L[1], &key->L[0]);
  block16_mulx_be (&key->L[2], &key->L[1]);
}

/* Add x^k L[2], where k is the number of trailing zero bits in i. */
static void
update_offset(const struct ocb_key *key,
        union nettle_block16 *offset, size_t i)
{
  if (i & 1)
    block16_xor (offset, &key->L[2]);
  else
    {
      assert (i > 0);
      union nettle_block16 diff;
      block16_mulx_be (&diff, &key->L[2]);
      for (i >>= 1; !(i&1); i >>= 1)
  block16_mulx_be (&diff, &diff);

      block16_xor (offset, &diff);
    }
}

static void
pad_block (union nettle_block16 *block, size_t length, const uint8_t *data)
{
  memcpy (block->b, data, length);
  block->b[length] = 0x80;
  memset (block->b + length + 1, 0, OCB_BLOCK_SIZE - 1 - length);
}

void
ocb_set_nonce (struct ocb_ctx *ctx,
         const void *cipher, nettle_cipher_func *f,
         size_t tag_length,
         size_t nonce_length, const uint8_t *nonce)
{
  union nettle_block16 top;
  uint64_t stretch;

  unsigned bottom;
  assert (nonce_length < 16);
  assert (tag_length > 0);
  assert (tag_length <= 16);

  /* Bit size, or zero for tag_length == 16 */
  top.b[0] = (tag_length & 15) << 4;
  memset (top.b + 1, 0, 15 - nonce_length);
  top.b[15 - nonce_length] |= 1;
  memcpy (top.b + 16 - nonce_length, nonce, nonce_length);
  bottom = top.b[15] & 0x3f;
  top.b[15] &= 0xc0;

  f (cipher, OCB_BLOCK_SIZE, top.b, top.b);

  stretch = top.u64[0];
#if WORDS_BIGENDIAN
  stretch ^= (top.u64[0] << 8) | (top.u64[1] >> 56);
#else
  stretch ^= (top.u64[0] >> 8) | (top.u64[1] << 56);
#endif

  ctx->initial.u64[0] = extract(top.u64[0], top.u64[1], bottom);
  ctx->initial.u64[1] = extract(top.u64[1], stretch, bottom);
  ctx->sum.u64[0] = ctx->sum.u64[1] = 0;
  ctx->checksum.u64[0] = ctx->checksum.u64[1] = 0;

  ctx->data_count = ctx->message_count = 0;
}

static void
ocb_fill_n (const struct ocb_key *key,
      union nettle_block16 *offset, size_t count,
      size_t n, union nettle_block16 *o)
{
  assert (n > 0);
  union nettle_block16 *prev;
  if (count & 1)
    prev = offset;
  else
    {
      /* Do a single block to align block count. */
      count++; /* Always odd. */
      block16_xor (offset, &key->L[2]);
      block16_set (&o[0], offset);
      prev = o;
      n--; o++;
    }

  for (; n >= 2; n -= 2, o += 2)
    {
      size_t i;
      count += 2; /* Always odd. */

      /* Based on trailing zeros of ctx->message_count - 1, the
         initial shift below discards a one bit. */
      block16_mulx_be (&o[0], &key->L[2]);
      for (i = count >> 1; !(i&1); i >>= 1)
  block16_mulx_be (&o[0], &o[0]);

      block16_xor (&o[0], prev);
      block16_xor3 (&o[1], &o[0], &key->L[2]);
      prev = &o[1];
    }
  block16_set(offset, prev);

  if (n > 0)
    {
      update_offset (key, offset, ++count);
      block16_set (o, offset);
    }
}

void
ocb_update (struct ocb_ctx *ctx, const struct ocb_key *key,
      const void *cipher, nettle_cipher_func *f,
      size_t length, const uint8_t *data)
{
  union nettle_block16 block[OCB_MAX_BLOCKS];
  size_t n = length / OCB_BLOCK_SIZE;
  assert (ctx->message_count == 0);

  if (ctx->data_count == 0)
    ctx->offset.u64[0] = ctx->offset.u64[1] = 0;

  while (n > 0)
    {
      size_t size, i;
      size_t blocks = (n <= OCB_MAX_BLOCKS) ? n
  : OCB_MAX_BLOCKS - 1 + (ctx->data_count & 1);

      ocb_fill_n (key, &ctx->offset, ctx->data_count, blocks, block);
      ctx->data_count += blocks;

      size = blocks * OCB_BLOCK_SIZE;
      memxor (block[0].b, data, size);
      f (cipher, size, block[0].b, block[0].b);
      for (i = 0; i < blocks; i++)
  block16_xor(&ctx->sum, &block[i]);

      n -= blocks; data += size;
    }

  length &= 15;
  if (length > 0)
    {
      union nettle_block16 block;
      pad_block (&block, length, data);
      block16_xor (&ctx->offset, &key->L[0]);
      block16_xor (&block, &ctx->offset);

      f (cipher, OCB_BLOCK_SIZE, block.b, block.b);
      block16_xor (&ctx->sum, &block);
    }
}

static void
ocb_crypt_n (struct ocb_ctx *ctx, const struct ocb_key *key,
       const void *cipher, nettle_cipher_func *f,
       size_t n, uint8_t *dst, const uint8_t *src)
{
  union nettle_block16 o[OCB_MAX_BLOCKS], block[OCB_MAX_BLOCKS];
  size_t size;

  while (n > 0)
    {
      size_t blocks = (n <= OCB_MAX_BLOCKS) ? n
  : OCB_MAX_BLOCKS - 1 + (ctx->message_count & 1);

      ocb_fill_n (key, &ctx->offset, ctx->message_count, blocks, o);
      ctx->message_count += blocks;

      size = blocks * OCB_BLOCK_SIZE;
      memxor3 (block[0].b, o[0].b, src, size);
      f (cipher, size, block[0].b, block[0].b);
      memxor3 (dst, block[0].b, o[0].b, size);

      n -= blocks; src += size; dst += size;
    }
}

/* Rotate bytes c positions to the right, in memory order. */
#if WORDS_BIGENDIAN
# define MEM_ROTATE_RIGHT(c, s0, s1) do {       \
    uint64_t __rotate_t = ((s0) >> (8*(c))) | ((s1) << (64-8*(c))); \
    (s1) = ((s1) >> (8*(c))) | ((s0) << (64-8*(c)));      \
    (s0) = __rotate_t;              \
  } while (0)
#else
# define MEM_ROTATE_RIGHT(c, s0, s1) do {       \
    uint64_t __rotate_t = ((s0) << (8*(c))) | ((s1) >> (64-8*(c))); \
    (s1) = ((s1) << (8*(c))) | ((s0) >> (64-8*(c)));      \
    (s0) = __rotate_t;              \
  } while (0)
#endif

/* Mask for the first c bytes in memory */
#if WORDS_BIGENDIAN
# define MEM_MASK(c) (-((uint64_t) 1 << (64 - 8*(c))))
#else
# define MEM_MASK(c) (((uint64_t) 1 << (8*(c))) - 1)
#endif

/* Checksum of n complete blocks. */
static void
ocb_checksum_n (union nettle_block16 *checksum,
    size_t n, const uint8_t *src)
{
  unsigned initial;
  uint64_t edge_word = 0;
  uint64_t s0, s1;

  if (n == 1)
    {
      memxor (checksum->b, src, OCB_BLOCK_SIZE);
      return;
    }

  /* Initial unaligned bytes. */
  initial = -(uintptr_t) src & 7;

  if (initial > 0)
    {
      /* Input not 64-bit aligned. Read initial bytes. */
      unsigned i;
      /* Edge word is read in big-endian order */
      for (i = initial; i > 0; i--)
  edge_word = (edge_word << 8) + *src++;
      n--;
    }

  /* Now src is 64-bit aligned, so do 64-bit reads. */
  for (s0 = s1 = 0 ; n > 0; n--, src += OCB_BLOCK_SIZE)
    {
      s0 ^= ((const uint64_t *) src)[0];
      s1 ^= ((const uint64_t *) src)[1];
    }
  if (initial > 0)
    {
      unsigned i;
      uint64_t mask;
      s0 ^= ((const uint64_t *) src)[0];
      for (i = 8 - initial, src += 8; i > 0; i--)
  edge_word = (edge_word << 8) + *src++;

      /* Rotate [s0, s1] right initial bytes. */
      MEM_ROTATE_RIGHT(initial, s0, s1);
      /* Add in the edge bytes.  */
      mask = MEM_MASK(initial);
      edge_word = bswap64_if_le (edge_word);
      s0 ^= (edge_word & mask);
      s1 ^= (edge_word & ~mask);
    }
  checksum->u64[0] ^= s0;
  checksum->u64[1] ^= s1;
}

void
ocb_encrypt (struct ocb_ctx *ctx, const struct ocb_key *key,
       const void *cipher, nettle_cipher_func *f,
       size_t length, uint8_t *dst, const uint8_t *src)
{
  size_t n = length / OCB_BLOCK_SIZE;

  if (ctx->message_count == 0)
    ctx->offset = ctx->initial;

  if (n > 0)
    {
      ocb_checksum_n (&ctx->checksum, n, src);
      ocb_crypt_n (ctx, key, cipher, f, n, dst, src);
      length &= 15;
    }
  if (length > 0)
    {
      union nettle_block16 block;

      src += n*OCB_BLOCK_SIZE; dst += n*OCB_BLOCK_SIZE;

      pad_block (&block, length, src);
      block16_xor (&ctx->checksum, &block);

      block16_xor (&ctx->offset, &key->L[0]);
      f (cipher, OCB_BLOCK_SIZE, block.b, ctx->offset.b);
      memxor3 (dst, block.b, src, length);
      ctx->message_count++;
    }
}

void
ocb_decrypt (struct ocb_ctx *ctx, const struct ocb_key *key,
       const void *encrypt_ctx, nettle_cipher_func *encrypt,
       const void *decrypt_ctx, nettle_cipher_func *decrypt,
       size_t length, uint8_t *dst, const uint8_t *src)
{
  size_t n = length / OCB_BLOCK_SIZE;

  if (ctx->message_count == 0)
    ctx->offset = ctx->initial;

  if (n > 0)
    {
      ocb_crypt_n (ctx, key, decrypt_ctx, decrypt, n, dst, src);
      ocb_checksum_n (&ctx->checksum, n, dst);
      length &= 15;
    }
  if (length > 0)
    {
      union nettle_block16 block;

      src += n*OCB_BLOCK_SIZE; dst += n*OCB_BLOCK_SIZE;

      block16_xor (&ctx->offset, &key->L[0]);
      encrypt (encrypt_ctx, OCB_BLOCK_SIZE, block.b, ctx->offset.b);
      memxor3 (dst, block.b, src, length);

      pad_block (&block, length, dst);
      block16_xor (&ctx->checksum, &block);
      ctx->message_count++;
    }
}

void
ocb_digest (const struct ocb_ctx *ctx, const struct ocb_key *key,
      const void *cipher, nettle_cipher_func *f,
      size_t length, uint8_t *digest)
{
  union nettle_block16 block;
  assert (length <= OCB_DIGEST_SIZE);
  block16_xor3 (&block,  &key->L[1],
    (ctx->message_count > 0) ? &ctx->offset : &ctx->initial);
  block16_xor (&block, &ctx->checksum);
  f (cipher, OCB_BLOCK_SIZE, block.b, block.b);
  memxor3 (digest, block.b, ctx->sum.b, length);
}

void
ocb_encrypt_message (const struct ocb_key *key,
         const void *cipher, nettle_cipher_func *f,
         size_t nlength, const uint8_t *nonce,
         size_t alength, const uint8_t *adata,
         size_t tlength,
         size_t clength, uint8_t *dst, const uint8_t *src)
{
  struct ocb_ctx ctx;
  assert (clength >= tlength);
  ocb_set_nonce (&ctx, cipher, f, tlength, nlength, nonce);
  ocb_update (&ctx, key, cipher, f, alength, adata);
  ocb_encrypt (&ctx, key, cipher, f,  clength - tlength, dst, src);
  ocb_digest (&ctx, key, cipher, f, tlength, dst + clength - tlength);
}

int
ocb_decrypt_message (const struct ocb_key *key,
         const void *encrypt_ctx, nettle_cipher_func *encrypt,
         const void *decrypt_ctx, nettle_cipher_func *decrypt,
         size_t nlength, const uint8_t *nonce,
         size_t alength, const uint8_t *adata,
         size_t tlength,
         size_t mlength, uint8_t *dst, const uint8_t *src)
{
  struct ocb_ctx ctx;
  union nettle_block16 digest;
  ocb_set_nonce (&ctx, encrypt_ctx, encrypt, tlength, nlength, nonce);
  ocb_update (&ctx, key, encrypt_ctx, encrypt, alength, adata);
  ocb_decrypt (&ctx, key, encrypt_ctx, encrypt, decrypt_ctx, decrypt,
         mlength, dst, src);
  ocb_digest (&ctx, key, encrypt_ctx, encrypt, tlength, digest.b);
  return memeql_sec(digest.b, src + mlength, tlength);
}

Coverage Report

Created: 2024-06-28 06:39

Line	Count	Source (jump to first uncovered line)
1		/* ocb.c
2
3		OCB AEAD mode, RFC 7253
4
5		Copyright (C) 2021 Niels Möller
6
7		This file is part of GNU Nettle.
8
9		GNU Nettle is free software: you can redistribute it and/or
10		modify it under the terms of either:
11
12		* the GNU Lesser General Public License as published by the Free
13		Software Foundation; either version 3 of the License, or (at your
14		option) any later version.
15
16		or
17
18		* the GNU General Public License as published by the Free
19		Software Foundation; either version 2 of the License, or (at your
20		option) any later version.
21
22		or both in parallel, as here.
23
24		GNU Nettle is distributed in the hope that it will be useful,
25		but WITHOUT ANY WARRANTY; without even the implied warranty of
26		MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
27		General Public License for more details.
28
29		You should have received copies of the GNU General Public License and
30		the GNU Lesser General Public License along with this program. If
31		not, see http://www.gnu.org/licenses/.
32		*/
33
34		#if HAVE_CONFIG_H
35		# include "config.h"
36		#endif
37
38		#include <string.h>
39
40		#include "ocb.h"
41		#include "block-internal.h"
42		#include "bswap-internal.h"
43		#include "memops.h"
44
45	1.05k	#define OCB_MAX_BLOCKS 16
46
47		/* Returns 64 bits from the concatenation (u0, u1), starting from bit offset. */
48		static inline uint64_t
49		extract(uint64_t u0, uint64_t u1, unsigned offset)
50	1.01k	{
51	1.01k	if (offset == 0)
52	70	return u0;
53	946	u0 = bswap64_if_le(u0);
54	946	u1 = bswap64_if_le(u1);
55	946	return bswap64_if_le((u0 << offset) \| (u1 >> (64 - offset)));
56	1.01k	}
57
58		void
59		ocb_set_key (struct ocb_key key, const void cipher, nettle_cipher_func *f)
60	508	{
61	508	static const union nettle_block16 zero_block;
62	508	f (cipher, OCB_BLOCK_SIZE, key->L[0].b, zero_block.b);
63	508	block16_mulx_be (&key->L[1], &key->L[0]);
64	508	block16_mulx_be (&key->L[2], &key->L[1]);
65	508	}
66
67		/* Add x^k L[2], where k is the number of trailing zero bits in i. */
68		static void
69		update_offset(const struct ocb_key *key,
70		union nettle_block16 *offset, size_t i)
71	401	{
72	401	if (i & 1)
73	0	block16_xor (offset, &key->L[2]);
74	401	else
75	401	{
76	401	assert (i > 0);
77	401	union nettle_block16 diff;
78	401	block16_mulx_be (&diff, &key->L[2]);
79	656	for (i >>= 1; !(i&1); i >>= 1)
80	255	block16_mulx_be (&diff, &diff);
81
82	401	block16_xor (offset, &diff);
83	401	}
84	401	}
85
86		static void
87		pad_block (union nettle_block16 block, size_t length, const uint8_t data)
88	511	{
89	511	memcpy (block->b, data, length);
90	511	block->b[length] = 0x80;
91	511	memset (block->b + length + 1, 0, OCB_BLOCK_SIZE - 1 - length);
92	511	}
93
94		void
95		ocb_set_nonce (struct ocb_ctx *ctx,
96		const void cipher, nettle_cipher_func f,
97		size_t tag_length,
98		size_t nonce_length, const uint8_t *nonce)
99	508	{
100	508	union nettle_block16 top;
101	508	uint64_t stretch;
102
103	508	unsigned bottom;
104	508	assert (nonce_length < 16);
105	508	assert (tag_length > 0);
106	508	assert (tag_length <= 16);
107
108		/* Bit size, or zero for tag_length == 16 */
109	508	top.b[0] = (tag_length & 15) << 4;
110	508	memset (top.b + 1, 0, 15 - nonce_length);
111	508	top.b[15 - nonce_length] \|= 1;
112	508	memcpy (top.b + 16 - nonce_length, nonce, nonce_length);
113	508	bottom = top.b[15] & 0x3f;
114	508	top.b[15] &= 0xc0;
115
116	508	f (cipher, OCB_BLOCK_SIZE, top.b, top.b);
117
118	508	stretch = top.u64[0];
119		#if WORDS_BIGENDIAN
120		stretch ^= (top.u64[0] << 8) \| (top.u64[1] >> 56);
121		#else
122	508	stretch ^= (top.u64[0] >> 8) \| (top.u64[1] << 56);
123	508	#endif
124
125	508	ctx->initial.u64[0] = extract(top.u64[0], top.u64[1], bottom);
126	508	ctx->initial.u64[1] = extract(top.u64[1], stretch, bottom);
127	508	ctx->sum.u64[0] = ctx->sum.u64[1] = 0;
128	508	ctx->checksum.u64[0] = ctx->checksum.u64[1] = 0;
129
130	508	ctx->data_count = ctx->message_count = 0;
131	508	}
132
133		static void
134		ocb_fill_n (const struct ocb_key *key,
135		union nettle_block16 *offset, size_t count,
136		size_t n, union nettle_block16 *o)
137	924	{
138	924	assert (n > 0);
139	924	union nettle_block16 *prev;
140	924	if (count & 1)
141	369	prev = offset;
142	555	else
143	555	{
144		/* Do a single block to align block count. */
145	555	count++; /* Always odd. */
146	555	block16_xor (offset, &key->L[2]);
147	555	block16_set (&o[0], offset);
148	555	prev = o;
149	555	n--; o++;
150	555	}
151
152	3.11k	for (; n >= 2; n -= 2, o += 2)
153	2.18k	{
154	2.18k	size_t i;
155	2.18k	count += 2; /* Always odd. */
156
157		/* Based on trailing zeros of ctx->message_count - 1, the
158		initial shift below discards a one bit. */
159	2.18k	block16_mulx_be (&o[0], &key->L[2]);
160	3.86k	for (i = count >> 1; !(i&1); i >>= 1)
161	1.67k	block16_mulx_be (&o[0], &o[0]);
162
163	2.18k	block16_xor (&o[0], prev);
164	2.18k	block16_xor3 (&o[1], &o[0], &key->L[2]);
165	2.18k	prev = &o[1];
166	2.18k	}
167	924	block16_set(offset, prev);
168
169	924	if (n > 0)
170	401	{
171	401	update_offset (key, offset, ++count);
172	401	block16_set (o, offset);
173	401	}
174	924	}
175
176		void
177		ocb_update (struct ocb_ctx ctx, const struct ocb_key key,
178		const void cipher, nettle_cipher_func f,
179		size_t length, const uint8_t *data)
180	4.14k	{
181	4.14k	union nettle_block16 block[OCB_MAX_BLOCKS];
182	4.14k	size_t n = length / OCB_BLOCK_SIZE;
183	4.14k	assert (ctx->message_count == 0);
184
185	4.14k	if (ctx->data_count == 0)
186	475	ctx->offset.u64[0] = ctx->offset.u64[1] = 0;
187
188	4.54k	while (n > 0)
189	404	{
190	404	size_t size, i;
191	404	size_t blocks = (n <= OCB_MAX_BLOCKS) ? n
192	404	: OCB_MAX_BLOCKS - 1 + (ctx->data_count & 1);
193
194	404	ocb_fill_n (key, &ctx->offset, ctx->data_count, blocks, block);
195	404	ctx->data_count += blocks;
196
197	404	size = blocks * OCB_BLOCK_SIZE;
198	404	memxor (block[0].b, data, size);
199	404	f (cipher, size, block[0].b, block[0].b);
200	2.04k	for (i = 0; i < blocks; i++)
201	1.64k	block16_xor(&ctx->sum, &block[i]);
202
203	404	n -= blocks; data += size;
204	404	}
205
206	4.14k	length &= 15;
207	4.14k	if (length > 0)
208	195	{
209	195	union nettle_block16 block;
210	195	pad_block (&block, length, data);
211	195	block16_xor (&ctx->offset, &key->L[0]);
212	195	block16_xor (&block, &ctx->offset);
213
214	195	f (cipher, OCB_BLOCK_SIZE, block.b, block.b);
215	195	block16_xor (&ctx->sum, &block);
216	195	}
217	4.14k	}
218
219		static void
220		ocb_crypt_n (struct ocb_ctx ctx, const struct ocb_key key,
221		const void cipher, nettle_cipher_func f,
222		size_t n, uint8_t dst, const uint8_t src)
223	415	{
224	415	union nettle_block16 o[OCB_MAX_BLOCKS], block[OCB_MAX_BLOCKS];
225	415	size_t size;
226
227	935	while (n > 0)
228	520	{
229	520	size_t blocks = (n <= OCB_MAX_BLOCKS) ? n
230	520	: OCB_MAX_BLOCKS - 1 + (ctx->message_count & 1);
231
232	520	ocb_fill_n (key, &ctx->offset, ctx->message_count, blocks, o);
233	520	ctx->message_count += blocks;
234
235	520	size = blocks * OCB_BLOCK_SIZE;
236	520	memxor3 (block[0].b, o[0].b, src, size);
237	520	f (cipher, size, block[0].b, block[0].b);
238	520	memxor3 (dst, block[0].b, o[0].b, size);
239
240	520	n -= blocks; src += size; dst += size;
241	520	}
242	415	}
243
244		/* Rotate bytes c positions to the right, in memory order. */
245		#if WORDS_BIGENDIAN
246		# define MEM_ROTATE_RIGHT(c, s0, s1) do { \
247		uint64_t __rotate_t = ((s0) >> (8(c))) \| ((s1) << (64-8(c))); \
248		(s1) = ((s1) >> (8(c))) \| ((s0) << (64-8(c))); \
249		(s0) = __rotate_t; \
250		} while (0)
251		#else
252	0	# define MEM_ROTATE_RIGHT(c, s0, s1) do { \
253	0	uint64_t __rotate_t = ((s0) << (8(c))) \| ((s1) >> (64-8(c))); \
254	0	(s1) = ((s1) << (8(c))) \| ((s0) >> (64-8(c))); \
255	0	(s0) = __rotate_t; \
256	0	} while (0)
257		#endif
258
259		/* Mask for the first c bytes in memory */
260		#if WORDS_BIGENDIAN
261		# define MEM_MASK(c) (-((uint64_t) 1 << (64 - 8*(c))))
262		#else
263	0	# define MEM_MASK(c) (((uint64_t) 1 << (8*(c))) - 1)
264		#endif
265
266		/* Checksum of n complete blocks. */
267		static void
268		ocb_checksum_n (union nettle_block16 *checksum,
269		size_t n, const uint8_t *src)
270	415	{
271	415	unsigned initial;
272	415	uint64_t edge_word = 0;
273	415	uint64_t s0, s1;
274
275	415	if (n == 1)
276	186	{
277	186	memxor (checksum->b, src, OCB_BLOCK_SIZE);
278	186	return;
279	186	}
280
281		/* Initial unaligned bytes. */
282	229	initial = -(uintptr_t) src & 7;
283
284	229	if (initial > 0)
285	0	{
286		/* Input not 64-bit aligned. Read initial bytes. */
287	0	unsigned i;
288		/* Edge word is read in big-endian order */
289	0	for (i = initial; i > 0; i--)
290	0	edge_word = (edge_word << 8) + *src++;
291	0	n--;
292	0	}
293
294		/* Now src is 64-bit aligned, so do 64-bit reads. */
295	3.73k	for (s0 = s1 = 0 ; n > 0; n--, src += OCB_BLOCK_SIZE)
296	3.50k	{
297	3.50k	s0 ^= ((const uint64_t *) src)[0];
298	3.50k	s1 ^= ((const uint64_t *) src)[1];
299	3.50k	}
300	229	if (initial > 0)
301	0	{
302	0	unsigned i;
303	0	uint64_t mask;
304	0	s0 ^= ((const uint64_t *) src)[0];
305	0	for (i = 8 - initial, src += 8; i > 0; i--)
306	0	edge_word = (edge_word << 8) + *src++;
307
308		/* Rotate [s0, s1] right initial bytes. */
309	0	MEM_ROTATE_RIGHT(initial, s0, s1);
310		/* Add in the edge bytes. */
311	0	mask = MEM_MASK(initial);
312	0	edge_word = bswap64_if_le (edge_word);
313	0	s0 ^= (edge_word & mask);
314	0	s1 ^= (edge_word & ~mask);
315	0	}
316	229	checksum->u64[0] ^= s0;
317	229	checksum->u64[1] ^= s1;
318	229	}
319
320		void
321		ocb_encrypt (struct ocb_ctx ctx, const struct ocb_key key,
322		const void cipher, nettle_cipher_func f,
323		size_t length, uint8_t dst, const uint8_t src)
324	1.67k	{
325	1.67k	size_t n = length / OCB_BLOCK_SIZE;
326
327	1.67k	if (ctx->message_count == 0)
328	708	ctx->offset = ctx->initial;
329
330	1.67k	if (n > 0)
331	226	{
332	226	ocb_checksum_n (&ctx->checksum, n, src);
333	226	ocb_crypt_n (ctx, key, cipher, f, n, dst, src);
334	226	length &= 15;
335	226	}
336	1.67k	if (length > 0)
337	144	{
338	144	union nettle_block16 block;
339
340	144	src += nOCB_BLOCK_SIZE; dst += nOCB_BLOCK_SIZE;
341
342	144	pad_block (&block, length, src);
343	144	block16_xor (&ctx->checksum, &block);
344
345	144	block16_xor (&ctx->offset, &key->L[0]);
346	144	f (cipher, OCB_BLOCK_SIZE, block.b, ctx->offset.b);
347	144	memxor3 (dst, block.b, src, length);
348	144	ctx->message_count++;
349	144	}
350	1.67k	}
351
352		void
353		ocb_decrypt (struct ocb_ctx ctx, const struct ocb_key key,
354		const void encrypt_ctx, nettle_cipher_func encrypt,
355		const void decrypt_ctx, nettle_cipher_func decrypt,
356		size_t length, uint8_t dst, const uint8_t src)
357	1.25k	{
358	1.25k	size_t n = length / OCB_BLOCK_SIZE;
359
360	1.25k	if (ctx->message_count == 0)
361	591	ctx->offset = ctx->initial;
362
363	1.25k	if (n > 0)
364	189	{
365	189	ocb_crypt_n (ctx, key, decrypt_ctx, decrypt, n, dst, src);
366	189	ocb_checksum_n (&ctx->checksum, n, dst);
367	189	length &= 15;
368	189	}
369	1.25k	if (length > 0)
370	172	{
371	172	union nettle_block16 block;
372
373	172	src += nOCB_BLOCK_SIZE; dst += nOCB_BLOCK_SIZE;
374
375	172	block16_xor (&ctx->offset, &key->L[0]);
376	172	encrypt (encrypt_ctx, OCB_BLOCK_SIZE, block.b, ctx->offset.b);
377	172	memxor3 (dst, block.b, src, length);
378
379	172	pad_block (&block, length, dst);
380	172	block16_xor (&ctx->checksum, &block);
381	172	ctx->message_count++;
382	172	}
383	1.25k	}
384
385		void
386		ocb_digest (const struct ocb_ctx ctx, const struct ocb_key key,
387		const void cipher, nettle_cipher_func f,
388		size_t length, uint8_t *digest)
389	508	{
390	508	union nettle_block16 block;
391	508	assert (length <= OCB_DIGEST_SIZE);
392	508	block16_xor3 (&block, &key->L[1],
393	508	(ctx->message_count > 0) ? &ctx->offset : &ctx->initial);
394	508	block16_xor (&block, &ctx->checksum);
395	508	f (cipher, OCB_BLOCK_SIZE, block.b, block.b);
396	508	memxor3 (digest, block.b, ctx->sum.b, length);
397	508	}
398
399		void
400		ocb_encrypt_message (const struct ocb_key *key,
401		const void cipher, nettle_cipher_func f,
402		size_t nlength, const uint8_t *nonce,
403		size_t alength, const uint8_t *adata,
404		size_t tlength,
405		size_t clength, uint8_t dst, const uint8_t src)
406	0	{
407	0	struct ocb_ctx ctx;
408	0	assert (clength >= tlength);
409	0	ocb_set_nonce (&ctx, cipher, f, tlength, nlength, nonce);
410	0	ocb_update (&ctx, key, cipher, f, alength, adata);
411	0	ocb_encrypt (&ctx, key, cipher, f, clength - tlength, dst, src);
412	0	ocb_digest (&ctx, key, cipher, f, tlength, dst + clength - tlength);
413	0	}
414
415		int
416		ocb_decrypt_message (const struct ocb_key *key,
417		const void encrypt_ctx, nettle_cipher_func encrypt,
418		const void decrypt_ctx, nettle_cipher_func decrypt,
419		size_t nlength, const uint8_t *nonce,
420		size_t alength, const uint8_t *adata,
421		size_t tlength,
422		size_t mlength, uint8_t dst, const uint8_t src)
423	0	{
424	0	struct ocb_ctx ctx;
425	0	union nettle_block16 digest;
426	0	ocb_set_nonce (&ctx, encrypt_ctx, encrypt, tlength, nlength, nonce);
427	0	ocb_update (&ctx, key, encrypt_ctx, encrypt, alength, adata);
428	0	ocb_decrypt (&ctx, key, encrypt_ctx, encrypt, decrypt_ctx, decrypt,
429	0	mlength, dst, src);
430	0	ocb_digest (&ctx, key, encrypt_ctx, encrypt, tlength, digest.b);
431	0	return memeql_sec(digest.b, src + mlength, tlength);
432	0	}