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sha1.c
Go to the documentation of this file.
1
/*
2
This file is part of libmicrohttpd
3
Copyright (C) 2019-2022 Karlson2k (Evgeny Grin)
4
5
libmicrohttpd is free software; you can redistribute it and/or
6
modify it under the terms of the GNU Lesser General Public
7
License as published by the Free Software Foundation; either
8
version 2.1 of the License, or (at your option) any later version.
9
10
This library is distributed in the hope that it will be useful,
11
but WITHOUT ANY WARRANTY; without even the implied warranty of
12
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
13
Lesser General Public License for more details.
14
15
You should have received a copy of the GNU Lesser General Public
16
License along with this library.
17
If not, see <http://www.gnu.org/licenses/>.
18
*/
19
25
26
#include "
sha1.h
"
27
28
#include <string.h>
29
#ifdef HAVE_MEMORY_H
30
#include <memory.h>
31
#endif
/* HAVE_MEMORY_H */
32
#include "
mhd_bithelpers.h
"
33
#include "
mhd_assert.h
"
34
40
void
41
MHD_SHA1_init
(
void
*ctx_)
42
{
43
struct
sha1_ctx
*
const
ctx = ctx_;
44
/* Initial hash values, see FIPS PUB 180-4 paragraph 5.3.1 */
45
/* Just some "magic" numbers defined by standard */
46
ctx->
H
[0] = UINT32_C (0x67452301);
47
ctx->
H
[1] = UINT32_C (0xefcdab89);
48
ctx->
H
[2] = UINT32_C (0x98badcfe);
49
ctx->
H
[3] = UINT32_C (0x10325476);
50
ctx->
H
[4] = UINT32_C (0xc3d2e1f0);
51
52
/* Initialise number of bytes. */
53
ctx->
count
= 0;
54
}
55
56
63
static
void
64
sha1_transform
(uint32_t
H
[
_SHA1_DIGEST_LENGTH
],
65
const
uint8_t
data
[
SHA1_BLOCK_SIZE
])
66
{
67
/* Working variables,
68
see FIPS PUB 180-4 paragraph 6.1.3 */
69
uint32_t a =
H
[0];
70
uint32_t b =
H
[1];
71
uint32_t c =
H
[2];
72
uint32_t d =
H
[3];
73
uint32_t e =
H
[4];
74
75
/* Data buffer, used as cyclic buffer.
76
See FIPS PUB 180-4 paragraphs 5.2.1, 6.1.3 */
77
uint32_t W[16];
78
79
/* 'Ch' and 'Maj' macro functions are defined with
80
widely-used optimization.
81
See FIPS PUB 180-4 formulae 4.1. */
82
#define Ch(x,y,z) ( (z) ^ ((x) & ((y) ^ (z))) )
83
#define Maj(x,y,z) ( ((x) & (y)) ^ ((z) & ((x) ^ (y))) )
84
/* Unoptimized (original) versions: */
85
/* #define Ch(x,y,z) ( ( (x) & (y) ) ^ ( ~(x) & (z) ) ) */
86
/* #define Maj(x,y,z) ( ((x) & (y)) ^ ((x) & (z)) ^ ((y) & (z)) ) */
87
#define Par(x,y,z) ( (x) ^ (y) ^ (z) )
88
89
/* Single step of SHA-1 computation,
90
see FIPS PUB 180-4 paragraph 6.1.3 step 3.
91
* Note: instead of reassigning all working variables on each step,
92
variables are rotated for each step:
93
SHA1STEP32 (a, b, c, d, e, func, K00, W[0]);
94
SHA1STEP32 (e, a, b, c, d, func, K00, W[1]);
95
so current 'vC' will be used as 'vD' on the next step,
96
current 'vE' will be used as 'vA' on the next step.
97
* Note: 'wt' must be used exactly one time in this macro as it change other data as well
98
every time when used. */
99
100
#define SHA1STEP32(vA,vB,vC,vD,vE,ft,kt,wt) do { \
101
(vE) += _MHD_ROTL32 ((vA), 5) + ft ((vB), (vC), (vD)) + (kt) + (wt); \
102
(vB) = _MHD_ROTL32 ((vB), 30); } while (0)
103
104
/* Get value of W(t) from input data buffer,
105
See FIPS PUB 180-4 paragraph 6.1.3.
106
Input data must be read in big-endian bytes order,
107
see FIPS PUB 180-4 paragraph 3.1.2. */
108
/* Use cast to (void*) to mute compiler alignment warning,
109
* data was already aligned in previous step */
110
#define GET_W_FROM_DATA(buf,t) \
111
_MHD_GET_32BIT_BE ((const void *)(((const uint8_t*) (buf)) + \
112
(t) * SHA1_BYTES_IN_WORD))
113
114
#ifndef _MHD_GET_32BIT_BE_UNALIGNED
115
if
(0 != (((uintptr_t)
data
) %
_MHD_UINT32_ALIGN
))
116
{
117
/* Copy the unaligned input data to the aligned buffer */
118
memcpy (W,
data
,
SHA1_BLOCK_SIZE
);
119
/* The W[] buffer itself will be used as the source of the data,
120
* but data will be reloaded in correct bytes order during
121
* the next steps */
122
data
= (uint8_t *) W;
123
}
124
#endif
/* _MHD_GET_32BIT_BE_UNALIGNED */
125
126
/* SHA-1 values of Kt for t=0..19, see FIPS PUB 180-4 paragraph 4.2.1. */
127
#define K00 UINT32_C(0x5a827999)
128
/* SHA-1 values of Kt for t=20..39, see FIPS PUB 180-4 paragraph 4.2.1.*/
129
#define K20 UINT32_C(0x6ed9eba1)
130
/* SHA-1 values of Kt for t=40..59, see FIPS PUB 180-4 paragraph 4.2.1.*/
131
#define K40 UINT32_C(0x8f1bbcdc)
132
/* SHA-1 values of Kt for t=60..79, see FIPS PUB 180-4 paragraph 4.2.1.*/
133
#define K60 UINT32_C(0xca62c1d6)
134
135
/* During first 16 steps, before making any calculations on each step,
136
the W element is read from input data buffer as big-endian value and
137
stored in array of W elements. */
138
/* Note: instead of using K constants as array, all K values are specified
139
individually for each step. */
140
SHA1STEP32
(a, b, c, d, e,
Ch
,
K00
, W[0] =
GET_W_FROM_DATA
(
data
, 0));
141
SHA1STEP32
(e, a, b, c, d,
Ch
,
K00
, W[1] =
GET_W_FROM_DATA
(
data
, 1));
142
SHA1STEP32
(d, e, a, b, c,
Ch
,
K00
, W[2] =
GET_W_FROM_DATA
(
data
, 2));
143
SHA1STEP32
(c, d, e, a, b,
Ch
,
K00
, W[3] =
GET_W_FROM_DATA
(
data
, 3));
144
SHA1STEP32
(b, c, d, e, a,
Ch
,
K00
, W[4] =
GET_W_FROM_DATA
(
data
, 4));
145
SHA1STEP32
(a, b, c, d, e,
Ch
,
K00
, W[5] =
GET_W_FROM_DATA
(
data
, 5));
146
SHA1STEP32
(e, a, b, c, d,
Ch
,
K00
, W[6] =
GET_W_FROM_DATA
(
data
, 6));
147
SHA1STEP32
(d, e, a, b, c,
Ch
,
K00
, W[7] =
GET_W_FROM_DATA
(
data
, 7));
148
SHA1STEP32
(c, d, e, a, b,
Ch
,
K00
, W[8] =
GET_W_FROM_DATA
(
data
, 8));
149
SHA1STEP32
(b, c, d, e, a,
Ch
,
K00
, W[9] =
GET_W_FROM_DATA
(
data
, 9));
150
SHA1STEP32
(a, b, c, d, e,
Ch
,
K00
, W[10] =
GET_W_FROM_DATA
(
data
, 10));
151
SHA1STEP32
(e, a, b, c, d,
Ch
,
K00
, W[11] =
GET_W_FROM_DATA
(
data
, 11));
152
SHA1STEP32
(d, e, a, b, c,
Ch
,
K00
, W[12] =
GET_W_FROM_DATA
(
data
, 12));
153
SHA1STEP32
(c, d, e, a, b,
Ch
,
K00
, W[13] =
GET_W_FROM_DATA
(
data
, 13));
154
SHA1STEP32
(b, c, d, e, a,
Ch
,
K00
, W[14] =
GET_W_FROM_DATA
(
data
, 14));
155
SHA1STEP32
(a, b, c, d, e,
Ch
,
K00
, W[15] =
GET_W_FROM_DATA
(
data
, 15));
156
157
/* 'W' generation and assignment for 16 <= t <= 79.
158
See FIPS PUB 180-4 paragraph 6.1.3.
159
As only last 16 'W' are used in calculations, it is possible to
160
use 16 elements array of W as cyclic buffer. */
161
#define Wgen(w,t) _MHD_ROTL32((w)[(t + 13) & 0xf] ^ (w)[(t + 8) & 0xf] \
162
^ (w)[(t + 2) & 0xf] ^ (w)[t & 0xf], 1)
163
164
/* During last 60 steps, before making any calculations on each step,
165
W element is generated from W elements of cyclic buffer and generated value
166
stored back in cyclic buffer. */
167
/* Note: instead of using K constants as array, all K values are specified
168
individually for each step, see FIPS PUB 180-4 paragraph 4.2.1. */
169
SHA1STEP32
(e, a, b, c, d,
Ch
,
K00
, W[16 & 0xf] =
Wgen
(W, 16));
170
SHA1STEP32
(d, e, a, b, c,
Ch
,
K00
, W[17 & 0xf] =
Wgen
(W, 17));
171
SHA1STEP32
(c, d, e, a, b,
Ch
,
K00
, W[18 & 0xf] =
Wgen
(W, 18));
172
SHA1STEP32
(b, c, d, e, a,
Ch
,
K00
, W[19 & 0xf] =
Wgen
(W, 19));
173
SHA1STEP32
(a, b, c, d, e,
Par
,
K20
, W[20 & 0xf] =
Wgen
(W, 20));
174
SHA1STEP32
(e, a, b, c, d,
Par
,
K20
, W[21 & 0xf] =
Wgen
(W, 21));
175
SHA1STEP32
(d, e, a, b, c,
Par
,
K20
, W[22 & 0xf] =
Wgen
(W, 22));
176
SHA1STEP32
(c, d, e, a, b,
Par
,
K20
, W[23 & 0xf] =
Wgen
(W, 23));
177
SHA1STEP32
(b, c, d, e, a,
Par
,
K20
, W[24 & 0xf] =
Wgen
(W, 24));
178
SHA1STEP32
(a, b, c, d, e,
Par
,
K20
, W[25 & 0xf] =
Wgen
(W, 25));
179
SHA1STEP32
(e, a, b, c, d,
Par
,
K20
, W[26 & 0xf] =
Wgen
(W, 26));
180
SHA1STEP32
(d, e, a, b, c,
Par
,
K20
, W[27 & 0xf] =
Wgen
(W, 27));
181
SHA1STEP32
(c, d, e, a, b,
Par
,
K20
, W[28 & 0xf] =
Wgen
(W, 28));
182
SHA1STEP32
(b, c, d, e, a,
Par
,
K20
, W[29 & 0xf] =
Wgen
(W, 29));
183
SHA1STEP32
(a, b, c, d, e,
Par
,
K20
, W[30 & 0xf] =
Wgen
(W, 30));
184
SHA1STEP32
(e, a, b, c, d,
Par
,
K20
, W[31 & 0xf] =
Wgen
(W, 31));
185
SHA1STEP32
(d, e, a, b, c,
Par
,
K20
, W[32 & 0xf] =
Wgen
(W, 32));
186
SHA1STEP32
(c, d, e, a, b,
Par
,
K20
, W[33 & 0xf] =
Wgen
(W, 33));
187
SHA1STEP32
(b, c, d, e, a,
Par
,
K20
, W[34 & 0xf] =
Wgen
(W, 34));
188
SHA1STEP32
(a, b, c, d, e,
Par
,
K20
, W[35 & 0xf] =
Wgen
(W, 35));
189
SHA1STEP32
(e, a, b, c, d,
Par
,
K20
, W[36 & 0xf] =
Wgen
(W, 36));
190
SHA1STEP32
(d, e, a, b, c,
Par
,
K20
, W[37 & 0xf] =
Wgen
(W, 37));
191
SHA1STEP32
(c, d, e, a, b,
Par
,
K20
, W[38 & 0xf] =
Wgen
(W, 38));
192
SHA1STEP32
(b, c, d, e, a,
Par
,
K20
, W[39 & 0xf] =
Wgen
(W, 39));
193
SHA1STEP32
(a, b, c, d, e,
Maj
,
K40
, W[40 & 0xf] =
Wgen
(W, 40));
194
SHA1STEP32
(e, a, b, c, d,
Maj
,
K40
, W[41 & 0xf] =
Wgen
(W, 41));
195
SHA1STEP32
(d, e, a, b, c,
Maj
,
K40
, W[42 & 0xf] =
Wgen
(W, 42));
196
SHA1STEP32
(c, d, e, a, b,
Maj
,
K40
, W[43 & 0xf] =
Wgen
(W, 43));
197
SHA1STEP32
(b, c, d, e, a,
Maj
,
K40
, W[44 & 0xf] =
Wgen
(W, 44));
198
SHA1STEP32
(a, b, c, d, e,
Maj
,
K40
, W[45 & 0xf] =
Wgen
(W, 45));
199
SHA1STEP32
(e, a, b, c, d,
Maj
,
K40
, W[46 & 0xf] =
Wgen
(W, 46));
200
SHA1STEP32
(d, e, a, b, c,
Maj
,
K40
, W[47 & 0xf] =
Wgen
(W, 47));
201
SHA1STEP32
(c, d, e, a, b,
Maj
,
K40
, W[48 & 0xf] =
Wgen
(W, 48));
202
SHA1STEP32
(b, c, d, e, a,
Maj
,
K40
, W[49 & 0xf] =
Wgen
(W, 49));
203
SHA1STEP32
(a, b, c, d, e,
Maj
,
K40
, W[50 & 0xf] =
Wgen
(W, 50));
204
SHA1STEP32
(e, a, b, c, d,
Maj
,
K40
, W[51 & 0xf] =
Wgen
(W, 51));
205
SHA1STEP32
(d, e, a, b, c,
Maj
,
K40
, W[52 & 0xf] =
Wgen
(W, 52));
206
SHA1STEP32
(c, d, e, a, b,
Maj
,
K40
, W[53 & 0xf] =
Wgen
(W, 53));
207
SHA1STEP32
(b, c, d, e, a,
Maj
,
K40
, W[54 & 0xf] =
Wgen
(W, 54));
208
SHA1STEP32
(a, b, c, d, e,
Maj
,
K40
, W[55 & 0xf] =
Wgen
(W, 55));
209
SHA1STEP32
(e, a, b, c, d,
Maj
,
K40
, W[56 & 0xf] =
Wgen
(W, 56));
210
SHA1STEP32
(d, e, a, b, c,
Maj
,
K40
, W[57 & 0xf] =
Wgen
(W, 57));
211
SHA1STEP32
(c, d, e, a, b,
Maj
,
K40
, W[58 & 0xf] =
Wgen
(W, 58));
212
SHA1STEP32
(b, c, d, e, a,
Maj
,
K40
, W[59 & 0xf] =
Wgen
(W, 59));
213
SHA1STEP32
(a, b, c, d, e,
Par
,
K60
, W[60 & 0xf] =
Wgen
(W, 60));
214
SHA1STEP32
(e, a, b, c, d,
Par
,
K60
, W[61 & 0xf] =
Wgen
(W, 61));
215
SHA1STEP32
(d, e, a, b, c,
Par
,
K60
, W[62 & 0xf] =
Wgen
(W, 62));
216
SHA1STEP32
(c, d, e, a, b,
Par
,
K60
, W[63 & 0xf] =
Wgen
(W, 63));
217
SHA1STEP32
(b, c, d, e, a,
Par
,
K60
, W[64 & 0xf] =
Wgen
(W, 64));
218
SHA1STEP32
(a, b, c, d, e,
Par
,
K60
, W[65 & 0xf] =
Wgen
(W, 65));
219
SHA1STEP32
(e, a, b, c, d,
Par
,
K60
, W[66 & 0xf] =
Wgen
(W, 66));
220
SHA1STEP32
(d, e, a, b, c,
Par
,
K60
, W[67 & 0xf] =
Wgen
(W, 67));
221
SHA1STEP32
(c, d, e, a, b,
Par
,
K60
, W[68 & 0xf] =
Wgen
(W, 68));
222
SHA1STEP32
(b, c, d, e, a,
Par
,
K60
, W[69 & 0xf] =
Wgen
(W, 69));
223
SHA1STEP32
(a, b, c, d, e,
Par
,
K60
, W[70 & 0xf] =
Wgen
(W, 70));
224
SHA1STEP32
(e, a, b, c, d,
Par
,
K60
, W[71 & 0xf] =
Wgen
(W, 71));
225
SHA1STEP32
(d, e, a, b, c,
Par
,
K60
, W[72 & 0xf] =
Wgen
(W, 72));
226
SHA1STEP32
(c, d, e, a, b,
Par
,
K60
, W[73 & 0xf] =
Wgen
(W, 73));
227
SHA1STEP32
(b, c, d, e, a,
Par
,
K60
, W[74 & 0xf] =
Wgen
(W, 74));
228
SHA1STEP32
(a, b, c, d, e,
Par
,
K60
, W[75 & 0xf] =
Wgen
(W, 75));
229
SHA1STEP32
(e, a, b, c, d,
Par
,
K60
, W[76 & 0xf] =
Wgen
(W, 76));
230
SHA1STEP32
(d, e, a, b, c,
Par
,
K60
, W[77 & 0xf] =
Wgen
(W, 77));
231
SHA1STEP32
(c, d, e, a, b,
Par
,
K60
, W[78 & 0xf] =
Wgen
(W, 78));
232
SHA1STEP32
(b, c, d, e, a,
Par
,
K60
, W[79 & 0xf] =
Wgen
(W, 79));
233
234
/* Compute intermediate hash.
235
See FIPS PUB 180-4 paragraph 6.1.3 step 4. */
236
H
[0] += a;
237
H
[1] += b;
238
H
[2] += c;
239
H
[3] += d;
240
H
[4] += e;
241
}
242
243
251
void
252
MHD_SHA1_update
(
void
*ctx_,
253
const
uint8_t *
data
,
254
size_t
length)
255
{
256
struct
sha1_ctx
*
const
ctx = ctx_;
257
unsigned
bytes_have;
258
259
mhd_assert
((
data
!=
NULL
) || (length == 0));
260
261
if
(0 == length)
262
return
;
/* Do nothing */
263
264
/* Note: (count & (SHA1_BLOCK_SIZE-1))
265
equal (count % SHA1_BLOCK_SIZE) for this block size. */
266
bytes_have = (unsigned) (ctx->
count
& (
SHA1_BLOCK_SIZE
- 1));
267
ctx->
count
+= length;
268
269
if
(0 != bytes_have)
270
{
271
unsigned
bytes_left =
SHA1_BLOCK_SIZE
- bytes_have;
272
if
(length >= bytes_left)
273
{
/* Combine new data with the data in the buffer and
274
process the full block. */
275
memcpy (ctx->
buffer
+ bytes_have,
276
data
,
277
bytes_left);
278
data
+= bytes_left;
279
length -= bytes_left;
280
sha1_transform
(ctx->
H
, ctx->
buffer
);
281
bytes_have = 0;
282
}
283
}
284
285
while
(
SHA1_BLOCK_SIZE
<= length)
286
{
/* Process any full blocks of new data directly,
287
without copying to the buffer. */
288
sha1_transform
(ctx->
H
,
data
);
289
data
+=
SHA1_BLOCK_SIZE
;
290
length -=
SHA1_BLOCK_SIZE
;
291
}
292
293
if
(0 != length)
294
{
/* Copy incomplete block of new data (if any)
295
to the buffer. */
296
memcpy (ctx->
buffer
+ bytes_have,
data
, length);
297
}
298
}
299
300
305
#define SHA1_SIZE_OF_LEN_ADD (64 / 8)
306
313
void
314
MHD_SHA1_finish
(
void
*ctx_,
315
uint8_t digest[
SHA1_DIGEST_SIZE
])
316
{
317
struct
sha1_ctx
*
const
ctx = ctx_;
318
uint64_t num_bits;
319
unsigned
bytes_have;
320
321
num_bits = ctx->
count
<< 3;
322
/* Note: (count & (SHA1_BLOCK_SIZE-1))
323
equals (count % SHA1_BLOCK_SIZE) for this block size. */
324
bytes_have = (unsigned) (ctx->
count
& (
SHA1_BLOCK_SIZE
- 1));
325
326
/* Input data must be padded with bit "1" and with length of data in bits.
327
See FIPS PUB 180-4 paragraph 5.1.1. */
328
/* Data is always processed in form of bytes (not by individual bits),
329
therefore position of first padding bit in byte is always predefined (0x80). */
330
/* Buffer always have space at least for one byte (as full buffers are
331
processed immediately). */
332
ctx->
buffer
[bytes_have++] = 0x80;
333
334
if
(
SHA1_BLOCK_SIZE
- bytes_have <
SHA1_SIZE_OF_LEN_ADD
)
335
{
/* No space in current block to put total length of message.
336
Pad current block with zeros and process it. */
337
if
(
SHA1_BLOCK_SIZE
> bytes_have)
338
memset (ctx->
buffer
+ bytes_have, 0,
SHA1_BLOCK_SIZE
- bytes_have);
339
/* Process full block. */
340
sha1_transform
(ctx->
H
, ctx->
buffer
);
341
/* Start new block. */
342
bytes_have = 0;
343
}
344
345
/* Pad the rest of the buffer with zeros. */
346
memset (ctx->
buffer
+ bytes_have, 0,
347
SHA1_BLOCK_SIZE
-
SHA1_SIZE_OF_LEN_ADD
- bytes_have);
348
/* Put the number of bits in the processed message as a big-endian value. */
349
_MHD_PUT_64BIT_BE_SAFE
(ctx->
buffer
+
SHA1_BLOCK_SIZE
-
SHA1_SIZE_OF_LEN_ADD
,
350
num_bits);
351
/* Process the full final block. */
352
sha1_transform
(ctx->
H
, ctx->
buffer
);
353
354
/* Put final hash/digest in BE mode */
355
#ifndef _MHD_PUT_32BIT_BE_UNALIGNED
356
if
(0 != ((uintptr_t) digest) %
_MHD_UINT32_ALIGN
)
357
{
358
uint32_t alig_dgst[
_SHA1_DIGEST_LENGTH
];
359
_MHD_PUT_32BIT_BE
(alig_dgst + 0, ctx->
H
[0]);
360
_MHD_PUT_32BIT_BE
(alig_dgst + 1, ctx->
H
[1]);
361
_MHD_PUT_32BIT_BE
(alig_dgst + 2, ctx->
H
[2]);
362
_MHD_PUT_32BIT_BE
(alig_dgst + 3, ctx->
H
[3]);
363
_MHD_PUT_32BIT_BE
(alig_dgst + 4, ctx->
H
[4]);
364
/* Copy result to unaligned destination address */
365
memcpy (digest, alig_dgst,
SHA1_DIGEST_SIZE
);
366
}
367
else
368
#else
/* _MHD_PUT_32BIT_BE_UNALIGNED */
369
if
(1)
370
#endif
/* _MHD_PUT_32BIT_BE_UNALIGNED */
371
{
372
/* Use cast to (void*) here to mute compiler alignment warnings.
373
* Compilers are not smart enough to see that alignment has been checked. */
374
_MHD_PUT_32BIT_BE
((
void
*) (digest + 0 *
SHA1_BYTES_IN_WORD
), ctx->
H
[0]);
375
_MHD_PUT_32BIT_BE
((
void
*) (digest + 1 *
SHA1_BYTES_IN_WORD
), ctx->
H
[1]);
376
_MHD_PUT_32BIT_BE
((
void
*) (digest + 2 *
SHA1_BYTES_IN_WORD
), ctx->
H
[2]);
377
_MHD_PUT_32BIT_BE
((
void
*) (digest + 3 *
SHA1_BYTES_IN_WORD
), ctx->
H
[3]);
378
_MHD_PUT_32BIT_BE
((
void
*) (digest + 4 *
SHA1_BYTES_IN_WORD
), ctx->
H
[4]);
379
}
380
381
/* Erase potentially sensitive data. */
382
memset (ctx, 0,
sizeof
(
struct
sha1_ctx
));
383
}
_MHD_UINT32_ALIGN
#define _MHD_UINT32_ALIGN
Definition
mhd_align.h:85
mhd_assert.h
macros for mhd_assert()
mhd_assert
#define mhd_assert(ignore)
Definition
mhd_assert.h:45
mhd_bithelpers.h
macros for bits manipulations
_MHD_PUT_64BIT_BE_SAFE
_MHD_static_inline void _MHD_PUT_64BIT_BE_SAFE(void *dst, uint64_t value)
Definition
mhd_bithelpers.h:225
_MHD_PUT_32BIT_BE
#define _MHD_PUT_32BIT_BE(addr, value32)
Definition
mhd_bithelpers.h:273
NULL
#define NULL
Definition
mhd_mono_clock.c:66
data
void * data
Definition
microhttpd.h:4030
MHD_SHA1_update
void MHD_SHA1_update(void *ctx_, const uint8_t *data, size_t length)
Definition
sha1.c:252
Wgen
#define Wgen(w, t)
MHD_SHA1_finish
void MHD_SHA1_finish(void *ctx_, uint8_t digest[SHA1_DIGEST_SIZE])
Definition
sha1.c:314
K00
#define K00
K40
#define K40
Maj
#define Maj(x, y, z)
Par
#define Par(x, y, z)
SHA1STEP32
#define SHA1STEP32(vA, vB, vC, vD, vE, ft, kt, wt)
Ch
#define Ch(x, y, z)
MHD_SHA1_init
void MHD_SHA1_init(void *ctx_)
Definition
sha1.c:41
K20
#define K20
SHA1_SIZE_OF_LEN_ADD
#define SHA1_SIZE_OF_LEN_ADD
Definition
sha1.c:305
GET_W_FROM_DATA
#define GET_W_FROM_DATA(buf, t)
K60
#define K60
sha1_transform
static void sha1_transform(uint32_t H[_SHA1_DIGEST_LENGTH], const uint8_t data[SHA1_BLOCK_SIZE])
Definition
sha1.c:64
sha1.h
Calculation of SHA-1 digest.
_SHA1_DIGEST_LENGTH
#define _SHA1_DIGEST_LENGTH
Definition
sha1.h:38
SHA1_DIGEST_SIZE
#define SHA1_DIGEST_SIZE
Definition
sha1.h:53
SHA1_BLOCK_SIZE
#define SHA1_BLOCK_SIZE
Definition
sha1.h:68
SHA1_BYTES_IN_WORD
#define SHA1_BYTES_IN_WORD
Definition
sha1.h:48
sha1_ctx
Definition
sha1.h:72
sha1_ctx::count
uint64_t count
Definition
sha1.h:75
sha1_ctx::buffer
uint8_t buffer[SHA1_BLOCK_SIZE]
Definition
sha1.h:74
sha1_ctx::H
uint32_t H[_SHA1_DIGEST_LENGTH]
Definition
sha1.h:73
src
microhttpd
sha1.c
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