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1a86da7a8398a6d6a3962bf9fdb310efe6de2955
[hashcat.git] / src / shared.c
1 /**
2 * Authors.....: Jens Steube <jens.steube@gmail.com>
3 * Gabriele Gristina <matrix@hashcat.net>
4 * magnum <john.magnum@hushmail.com>
5 *
6 * License.....: MIT
7 */
8
9 #ifdef OSX
10 #include <stdio.h>
11 #endif
12
13 #include <shared.h>
14 #include <limits.h>
15
16 /**
17 * basic bit handling
18 */
19
20 u32 is_power_of_2(u32 v)
21 {
22 return (v && !(v & (v - 1)));
23 }
24
25 u32 rotl32 (const u32 a, const u32 n)
26 {
27 return ((a << n) | (a >> (32 - n)));
28 }
29
30 u32 rotr32 (const u32 a, const u32 n)
31 {
32 return ((a >> n) | (a << (32 - n)));
33 }
34
35 u64 rotl64 (const u64 a, const u64 n)
36 {
37 return ((a << n) | (a >> (64 - n)));
38 }
39
40 u64 rotr64 (const u64 a, const u64 n)
41 {
42 return ((a >> n) | (a << (64 - n)));
43 }
44
45 u32 byte_swap_32 (const u32 n)
46 {
47 return (n & 0xff000000) >> 24
48 | (n & 0x00ff0000) >> 8
49 | (n & 0x0000ff00) << 8
50 | (n & 0x000000ff) << 24;
51 }
52
53 u64 byte_swap_64 (const u64 n)
54 {
55 return (n & 0xff00000000000000ULL) >> 56
56 | (n & 0x00ff000000000000ULL) >> 40
57 | (n & 0x0000ff0000000000ULL) >> 24
58 | (n & 0x000000ff00000000ULL) >> 8
59 | (n & 0x00000000ff000000ULL) << 8
60 | (n & 0x0000000000ff0000ULL) << 24
61 | (n & 0x000000000000ff00ULL) << 40
62 | (n & 0x00000000000000ffULL) << 56;
63 }
64
65 /**
66 * ciphers for use on cpu
67 */
68
69 #include "cpu-des.c"
70 #include "cpu-aes.c"
71
72 /**
73 * hashes for use on cpu
74 */
75
76 #include "cpu-md5.c"
77 #include "cpu-sha256.c"
78
79 /**
80 * logging
81 */
82
83 int last_len = 0;
84
85 void log_final (FILE *fp, const char *fmt, va_list ap)
86 {
87 if (last_len)
88 {
89 fputc ('\r', fp);
90
91 for (int i = 0; i < last_len; i++)
92 {
93 fputc (' ', fp);
94 }
95
96 fputc ('\r', fp);
97 }
98
99 char s[4096] = { 0 };
100
101 int max_len = (int) sizeof (s);
102
103 int len = vsnprintf (s, max_len, fmt, ap);
104
105 if (len > max_len) len = max_len;
106
107 fwrite (s, len, 1, fp);
108
109 fflush (fp);
110
111 last_len = len;
112 }
113
114 void log_out_nn (FILE *fp, const char *fmt, ...)
115 {
116 if (SUPPRESS_OUTPUT) return;
117
118 va_list ap;
119
120 va_start (ap, fmt);
121
122 log_final (fp, fmt, ap);
123
124 va_end (ap);
125 }
126
127 void log_info_nn (const char *fmt, ...)
128 {
129 if (SUPPRESS_OUTPUT) return;
130
131 va_list ap;
132
133 va_start (ap, fmt);
134
135 log_final (stdout, fmt, ap);
136
137 va_end (ap);
138 }
139
140 void log_error_nn (const char *fmt, ...)
141 {
142 if (SUPPRESS_OUTPUT) return;
143
144 va_list ap;
145
146 va_start (ap, fmt);
147
148 log_final (stderr, fmt, ap);
149
150 va_end (ap);
151 }
152
153 void log_out (FILE *fp, const char *fmt, ...)
154 {
155 if (SUPPRESS_OUTPUT) return;
156
157 va_list ap;
158
159 va_start (ap, fmt);
160
161 log_final (fp, fmt, ap);
162
163 va_end (ap);
164
165 fputc ('\n', fp);
166
167 last_len = 0;
168 }
169
170 void log_info (const char *fmt, ...)
171 {
172 if (SUPPRESS_OUTPUT) return;
173
174 va_list ap;
175
176 va_start (ap, fmt);
177
178 log_final (stdout, fmt, ap);
179
180 va_end (ap);
181
182 fputc ('\n', stdout);
183
184 last_len = 0;
185 }
186
187 void log_error (const char *fmt, ...)
188 {
189 if (SUPPRESS_OUTPUT) return;
190
191 fputc ('\n', stderr);
192 fputc ('\n', stderr);
193
194 va_list ap;
195
196 va_start (ap, fmt);
197
198 log_final (stderr, fmt, ap);
199
200 va_end (ap);
201
202 fputc ('\n', stderr);
203 fputc ('\n', stderr);
204
205 last_len = 0;
206 }
207
208 /**
209 * converter
210 */
211
212 u8 int_to_base32 (const u8 c)
213 {
214 static const u8 tbl[0x20] =
215 {
216 0x41, 0x42, 0x43, 0x44, 0x45, 0x46, 0x47, 0x48, 0x49, 0x4a, 0x4b, 0x4c, 0x4d, 0x4e, 0x4f, 0x50,
217 0x51, 0x52, 0x53, 0x54, 0x55, 0x56, 0x57, 0x58, 0x59, 0x5a, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37,
218 };
219
220 return tbl[c];
221 }
222
223 u8 base32_to_int (const u8 c)
224 {
225 if ((c >= 'A') && (c <= 'Z')) return c - 'A';
226 else if ((c >= '2') && (c <= '7')) return c - '2' + 26;
227
228 return 0;
229 }
230
231 u8 int_to_itoa32 (const u8 c)
232 {
233 static const u8 tbl[0x20] =
234 {
235 0x30, 0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38, 0x39, 0x61, 0x62, 0x63, 0x64, 0x65, 0x66,
236 0x67, 0x68, 0x69, 0x6a, 0x6b, 0x6c, 0x6d, 0x6e, 0x6f, 0x70, 0x71, 0x72, 0x73, 0x74, 0x75, 0x76,
237 };
238
239 return tbl[c];
240 }
241
242 u8 itoa32_to_int (const u8 c)
243 {
244 if ((c >= '0') && (c <= '9')) return c - '0';
245 else if ((c >= 'a') && (c <= 'v')) return c - 'a' + 10;
246
247 return 0;
248 }
249
250 u8 int_to_itoa64 (const u8 c)
251 {
252 static const u8 tbl[0x40] =
253 {
254 0x2e, 0x2f, 0x30, 0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38, 0x39, 0x41, 0x42, 0x43, 0x44,
255 0x45, 0x46, 0x47, 0x48, 0x49, 0x4a, 0x4b, 0x4c, 0x4d, 0x4e, 0x4f, 0x50, 0x51, 0x52, 0x53, 0x54,
256 0x55, 0x56, 0x57, 0x58, 0x59, 0x5a, 0x61, 0x62, 0x63, 0x64, 0x65, 0x66, 0x67, 0x68, 0x69, 0x6a,
257 0x6b, 0x6c, 0x6d, 0x6e, 0x6f, 0x70, 0x71, 0x72, 0x73, 0x74, 0x75, 0x76, 0x77, 0x78, 0x79, 0x7a,
258 };
259
260 return tbl[c];
261 }
262
263 u8 itoa64_to_int (const u8 c)
264 {
265 static const u8 tbl[0x100] =
266 {
267 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f, 0x20, 0x21,
268 0x22, 0x23, 0x24, 0x25, 0x26, 0x27, 0x28, 0x29, 0x2a, 0x2b, 0x2c, 0x2d, 0x2e, 0x2f, 0x30, 0x31,
269 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38, 0x39, 0x3a, 0x3b, 0x3c, 0x3d, 0x3e, 0x3f, 0x00, 0x01,
270 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a,
271 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1a,
272 0x1b, 0x1c, 0x1d, 0x1e, 0x1f, 0x20, 0x21, 0x22, 0x23, 0x24, 0x25, 0x20, 0x21, 0x22, 0x23, 0x24,
273 0x25, 0x26, 0x27, 0x28, 0x29, 0x2a, 0x2b, 0x2c, 0x2d, 0x2e, 0x2f, 0x30, 0x31, 0x32, 0x33, 0x34,
274 0x35, 0x36, 0x37, 0x38, 0x39, 0x3a, 0x3b, 0x3c, 0x3d, 0x3e, 0x3f, 0x00, 0x01, 0x02, 0x03, 0x04,
275 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11, 0x12, 0x13, 0x14,
276 0x15, 0x16, 0x17, 0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f, 0x20, 0x21, 0x22, 0x23, 0x24,
277 0x25, 0x26, 0x27, 0x28, 0x29, 0x2a, 0x2b, 0x2c, 0x2d, 0x2e, 0x2f, 0x30, 0x31, 0x32, 0x33, 0x34,
278 0x35, 0x36, 0x37, 0x38, 0x39, 0x3a, 0x3b, 0x3c, 0x3d, 0x3e, 0x3f, 0x00, 0x01, 0x02, 0x03, 0x04,
279 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11, 0x12, 0x13, 0x14,
280 0x15, 0x16, 0x17, 0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f, 0x20, 0x21, 0x22, 0x23, 0x24,
281 0x25, 0x26, 0x27, 0x28, 0x29, 0x2a, 0x2b, 0x2c, 0x2d, 0x2e, 0x2f, 0x30, 0x31, 0x32, 0x33, 0x34,
282 0x35, 0x36, 0x37, 0x38, 0x39, 0x3a, 0x3b, 0x3c, 0x3d, 0x3e, 0x3f, 0x00, 0x01, 0x02, 0x03, 0x04,
283 };
284
285 return tbl[c];
286 }
287
288 u8 int_to_base64 (const u8 c)
289 {
290 static const u8 tbl[0x40] =
291 {
292 0x41, 0x42, 0x43, 0x44, 0x45, 0x46, 0x47, 0x48, 0x49, 0x4a, 0x4b, 0x4c, 0x4d, 0x4e, 0x4f, 0x50,
293 0x51, 0x52, 0x53, 0x54, 0x55, 0x56, 0x57, 0x58, 0x59, 0x5a, 0x61, 0x62, 0x63, 0x64, 0x65, 0x66,
294 0x67, 0x68, 0x69, 0x6a, 0x6b, 0x6c, 0x6d, 0x6e, 0x6f, 0x70, 0x71, 0x72, 0x73, 0x74, 0x75, 0x76,
295 0x77, 0x78, 0x79, 0x7a, 0x30, 0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38, 0x39, 0x2b, 0x2f,
296 };
297
298 return tbl[c];
299 }
300
301 u8 base64_to_int (const u8 c)
302 {
303 static const u8 tbl[0x100] =
304 {
305 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
306 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
307 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x3e, 0x00, 0x00, 0x00, 0x3f,
308 0x34, 0x35, 0x36, 0x37, 0x38, 0x39, 0x3a, 0x3b, 0x3c, 0x3d, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
309 0x00, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e,
310 0x0f, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x00, 0x00, 0x00, 0x00, 0x00,
311 0x00, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f, 0x20, 0x21, 0x22, 0x23, 0x24, 0x25, 0x26, 0x27, 0x28,
312 0x29, 0x2a, 0x2b, 0x2c, 0x2d, 0x2e, 0x2f, 0x30, 0x31, 0x32, 0x33, 0x00, 0x00, 0x00, 0x00, 0x00,
313 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
314 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
315 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
316 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
317 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
318 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
319 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
320 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
321 };
322
323 return tbl[c];
324 }
325
326 u8 int_to_bf64 (const u8 c)
327 {
328 static const u8 tbl[0x40] =
329 {
330 0x2e, 0x2f, 0x41, 0x42, 0x43, 0x44, 0x45, 0x46, 0x47, 0x48, 0x49, 0x4a, 0x4b, 0x4c, 0x4d, 0x4e,
331 0x4f, 0x50, 0x51, 0x52, 0x53, 0x54, 0x55, 0x56, 0x57, 0x58, 0x59, 0x5a, 0x61, 0x62, 0x63, 0x64,
332 0x65, 0x66, 0x67, 0x68, 0x69, 0x6a, 0x6b, 0x6c, 0x6d, 0x6e, 0x6f, 0x70, 0x71, 0x72, 0x73, 0x74,
333 0x75, 0x76, 0x77, 0x78, 0x79, 0x7a, 0x30, 0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38, 0x39,
334 };
335
336 return tbl[c];
337 }
338
339 u8 bf64_to_int (const u8 c)
340 {
341 static const u8 tbl[0x100] =
342 {
343 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
344 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
345 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01,
346 0x36, 0x37, 0x38, 0x39, 0x3a, 0x3b, 0x3c, 0x3d, 0x3e, 0x3f, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
347 0x00, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10,
348 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1a, 0x1b, 0x00, 0x00, 0x00, 0x00, 0x00,
349 0x00, 0x1c, 0x1d, 0x1e, 0x1f, 0x20, 0x21, 0x22, 0x23, 0x24, 0x25, 0x26, 0x27, 0x28, 0x29, 0x2a,
350 0x2b, 0x2c, 0x2d, 0x2e, 0x2f, 0x30, 0x31, 0x32, 0x33, 0x34, 0x35, 0x00, 0x00, 0x00, 0x00, 0x00,
351 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
352 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
353 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
354 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
355 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
356 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
357 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
358 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
359 };
360
361 return tbl[c];
362 }
363
364 u8 int_to_lotus64 (const u8 c)
365 {
366 if (c < 10) return '0' + c;
367 else if (c < 36) return 'A' + c - 10;
368 else if (c < 62) return 'a' + c - 36;
369 else if (c == 62) return '+';
370 else if (c == 63) return '/';
371
372 return 0;
373 }
374
375 u8 lotus64_to_int (const u8 c)
376 {
377 if ((c >= '0') && (c <= '9')) return c - '0';
378 else if ((c >= 'A') && (c <= 'Z')) return c - 'A' + 10;
379 else if ((c >= 'a') && (c <= 'z')) return c - 'a' + 36;
380 else if (c == '+') return 62;
381 else if (c == '/') return 63;
382 else
383
384 return 0;
385 }
386
387 int base32_decode (u8 (*f) (const u8), const u8 *in_buf, int in_len, u8 *out_buf)
388 {
389 const u8 *in_ptr = in_buf;
390
391 u8 *out_ptr = out_buf;
392
393 for (int i = 0; i < in_len; i += 8)
394 {
395 const u8 out_val0 = f (in_ptr[0] & 0x7f);
396 const u8 out_val1 = f (in_ptr[1] & 0x7f);
397 const u8 out_val2 = f (in_ptr[2] & 0x7f);
398 const u8 out_val3 = f (in_ptr[3] & 0x7f);
399 const u8 out_val4 = f (in_ptr[4] & 0x7f);
400 const u8 out_val5 = f (in_ptr[5] & 0x7f);
401 const u8 out_val6 = f (in_ptr[6] & 0x7f);
402 const u8 out_val7 = f (in_ptr[7] & 0x7f);
403
404 out_ptr[0] = ((out_val0 << 3) & 0xf8) | ((out_val1 >> 2) & 0x07);
405 out_ptr[1] = ((out_val1 << 6) & 0xc0) | ((out_val2 << 1) & 0x3e) | ((out_val3 >> 4) & 0x01);
406 out_ptr[2] = ((out_val3 << 4) & 0xf0) | ((out_val4 >> 1) & 0x0f);
407 out_ptr[3] = ((out_val4 << 7) & 0x80) | ((out_val5 << 2) & 0x7c) | ((out_val6 >> 3) & 0x03);
408 out_ptr[4] = ((out_val6 << 5) & 0xe0) | ((out_val7 >> 0) & 0x1f);
409
410 in_ptr += 8;
411 out_ptr += 5;
412 }
413
414 for (int i = 0; i < in_len; i++)
415 {
416 if (in_buf[i] != '=') continue;
417
418 in_len = i;
419 }
420
421 int out_len = (in_len * 5) / 8;
422
423 return out_len;
424 }
425
426 int base32_encode (u8 (*f) (const u8), const u8 *in_buf, int in_len, u8 *out_buf)
427 {
428 const u8 *in_ptr = in_buf;
429
430 u8 *out_ptr = out_buf;
431
432 for (int i = 0; i < in_len; i += 5)
433 {
434 const u8 out_val0 = f ( ((in_ptr[0] >> 3) & 0x1f));
435 const u8 out_val1 = f (((in_ptr[0] << 2) & 0x1c) | ((in_ptr[1] >> 6) & 0x03));
436 const u8 out_val2 = f ( ((in_ptr[1] >> 1) & 0x1f));
437 const u8 out_val3 = f (((in_ptr[1] << 4) & 0x10) | ((in_ptr[2] >> 4) & 0x0f));
438 const u8 out_val4 = f (((in_ptr[2] << 1) & 0x1e) | ((in_ptr[3] >> 7) & 0x01));
439 const u8 out_val5 = f ( ((in_ptr[3] >> 2) & 0x1f));
440 const u8 out_val6 = f (((in_ptr[3] << 3) & 0x18) | ((in_ptr[4] >> 5) & 0x07));
441 const u8 out_val7 = f ( ((in_ptr[4] >> 0) & 0x1f));
442
443 out_ptr[0] = out_val0 & 0x7f;
444 out_ptr[1] = out_val1 & 0x7f;
445 out_ptr[2] = out_val2 & 0x7f;
446 out_ptr[3] = out_val3 & 0x7f;
447 out_ptr[4] = out_val4 & 0x7f;
448 out_ptr[5] = out_val5 & 0x7f;
449 out_ptr[6] = out_val6 & 0x7f;
450 out_ptr[7] = out_val7 & 0x7f;
451
452 in_ptr += 5;
453 out_ptr += 8;
454 }
455
456 int out_len = (int) (((0.5 + (float) in_len) * 8) / 5); // ceil (in_len * 8 / 5)
457
458 while (out_len % 8)
459 {
460 out_buf[out_len] = '=';
461
462 out_len++;
463 }
464
465 return out_len;
466 }
467
468 int base64_decode (u8 (*f) (const u8), const u8 *in_buf, int in_len, u8 *out_buf)
469 {
470 const u8 *in_ptr = in_buf;
471
472 u8 *out_ptr = out_buf;
473
474 for (int i = 0; i < in_len; i += 4)
475 {
476 const u8 out_val0 = f (in_ptr[0] & 0x7f);
477 const u8 out_val1 = f (in_ptr[1] & 0x7f);
478 const u8 out_val2 = f (in_ptr[2] & 0x7f);
479 const u8 out_val3 = f (in_ptr[3] & 0x7f);
480
481 out_ptr[0] = ((out_val0 << 2) & 0xfc) | ((out_val1 >> 4) & 0x03);
482 out_ptr[1] = ((out_val1 << 4) & 0xf0) | ((out_val2 >> 2) & 0x0f);
483 out_ptr[2] = ((out_val2 << 6) & 0xc0) | ((out_val3 >> 0) & 0x3f);
484
485 in_ptr += 4;
486 out_ptr += 3;
487 }
488
489 for (int i = 0; i < in_len; i++)
490 {
491 if (in_buf[i] != '=') continue;
492
493 in_len = i;
494 }
495
496 int out_len = (in_len * 6) / 8;
497
498 return out_len;
499 }
500
501 int base64_encode (u8 (*f) (const u8), const u8 *in_buf, int in_len, u8 *out_buf)
502 {
503 const u8 *in_ptr = in_buf;
504
505 u8 *out_ptr = out_buf;
506
507 for (int i = 0; i < in_len; i += 3)
508 {
509 const u8 out_val0 = f ( ((in_ptr[0] >> 2) & 0x3f));
510 const u8 out_val1 = f (((in_ptr[0] << 4) & 0x30) | ((in_ptr[1] >> 4) & 0x0f));
511 const u8 out_val2 = f (((in_ptr[1] << 2) & 0x3c) | ((in_ptr[2] >> 6) & 0x03));
512 const u8 out_val3 = f ( ((in_ptr[2] >> 0) & 0x3f));
513
514 out_ptr[0] = out_val0 & 0x7f;
515 out_ptr[1] = out_val1 & 0x7f;
516 out_ptr[2] = out_val2 & 0x7f;
517 out_ptr[3] = out_val3 & 0x7f;
518
519 in_ptr += 3;
520 out_ptr += 4;
521 }
522
523 int out_len = (int) (((0.5 + (float) in_len) * 8) / 6); // ceil (in_len * 8 / 6)
524
525 while (out_len % 4)
526 {
527 out_buf[out_len] = '=';
528
529 out_len++;
530 }
531
532 return out_len;
533 }
534
535 int is_valid_hex_char (const u8 c)
536 {
537 if ((c >= '0') && (c <= '9')) return 1;
538 if ((c >= 'A') && (c <= 'F')) return 1;
539 if ((c >= 'a') && (c <= 'f')) return 1;
540
541 return 0;
542 }
543
544 u8 hex_convert (const u8 c)
545 {
546 return (c & 15) + (c >> 6) * 9;
547 }
548
549 u8 hex_to_u8 (const u8 hex[2])
550 {
551 u8 v = 0;
552
553 v |= (hex_convert (hex[1]) << 0);
554 v |= (hex_convert (hex[0]) << 4);
555
556 return (v);
557 }
558
559 u32 hex_to_u32 (const u8 hex[8])
560 {
561 u32 v = 0;
562
563 v |= ((u32) hex_convert (hex[7])) << 0;
564 v |= ((u32) hex_convert (hex[6])) << 4;
565 v |= ((u32) hex_convert (hex[5])) << 8;
566 v |= ((u32) hex_convert (hex[4])) << 12;
567 v |= ((u32) hex_convert (hex[3])) << 16;
568 v |= ((u32) hex_convert (hex[2])) << 20;
569 v |= ((u32) hex_convert (hex[1])) << 24;
570 v |= ((u32) hex_convert (hex[0])) << 28;
571
572 return (v);
573 }
574
575 u64 hex_to_u64 (const u8 hex[16])
576 {
577 u64 v = 0;
578
579 v |= ((u64) hex_convert (hex[15]) << 0);
580 v |= ((u64) hex_convert (hex[14]) << 4);
581 v |= ((u64) hex_convert (hex[13]) << 8);
582 v |= ((u64) hex_convert (hex[12]) << 12);
583 v |= ((u64) hex_convert (hex[11]) << 16);
584 v |= ((u64) hex_convert (hex[10]) << 20);
585 v |= ((u64) hex_convert (hex[ 9]) << 24);
586 v |= ((u64) hex_convert (hex[ 8]) << 28);
587 v |= ((u64) hex_convert (hex[ 7]) << 32);
588 v |= ((u64) hex_convert (hex[ 6]) << 36);
589 v |= ((u64) hex_convert (hex[ 5]) << 40);
590 v |= ((u64) hex_convert (hex[ 4]) << 44);
591 v |= ((u64) hex_convert (hex[ 3]) << 48);
592 v |= ((u64) hex_convert (hex[ 2]) << 52);
593 v |= ((u64) hex_convert (hex[ 1]) << 56);
594 v |= ((u64) hex_convert (hex[ 0]) << 60);
595
596 return (v);
597 }
598
599 void bin_to_hex_lower (const u32 v, u8 hex[8])
600 {
601 hex[0] = v >> 28 & 15;
602 hex[1] = v >> 24 & 15;
603 hex[2] = v >> 20 & 15;
604 hex[3] = v >> 16 & 15;
605 hex[4] = v >> 12 & 15;
606 hex[5] = v >> 8 & 15;
607 hex[6] = v >> 4 & 15;
608 hex[7] = v >> 0 & 15;
609
610 u32 add;
611
612 hex[0] += 6; add = ((hex[0] & 0x10) >> 4) * 39; hex[0] += 42 + add;
613 hex[1] += 6; add = ((hex[1] & 0x10) >> 4) * 39; hex[1] += 42 + add;
614 hex[2] += 6; add = ((hex[2] & 0x10) >> 4) * 39; hex[2] += 42 + add;
615 hex[3] += 6; add = ((hex[3] & 0x10) >> 4) * 39; hex[3] += 42 + add;
616 hex[4] += 6; add = ((hex[4] & 0x10) >> 4) * 39; hex[4] += 42 + add;
617 hex[5] += 6; add = ((hex[5] & 0x10) >> 4) * 39; hex[5] += 42 + add;
618 hex[6] += 6; add = ((hex[6] & 0x10) >> 4) * 39; hex[6] += 42 + add;
619 hex[7] += 6; add = ((hex[7] & 0x10) >> 4) * 39; hex[7] += 42 + add;
620 }
621
622 /**
623 * decoder
624 */
625
626 static void AES128_decrypt_cbc (const u32 key[4], const u32 iv[4], const u32 in[16], u32 out[16])
627 {
628 AES_KEY skey;
629
630 AES_set_decrypt_key ((const u8 *) key, 128, &skey);
631
632 u32 _iv[4] = { 0 };
633
634 _iv[0] = iv[0];
635 _iv[1] = iv[1];
636 _iv[2] = iv[2];
637 _iv[3] = iv[3];
638
639 for (int i = 0; i < 16; i += 4)
640 {
641 u32 _in[4] = { 0 };
642 u32 _out[4] = { 0 };
643
644 _in[0] = in[i + 0];
645 _in[1] = in[i + 1];
646 _in[2] = in[i + 2];
647 _in[3] = in[i + 3];
648
649 AES_decrypt (&skey, (const u8 *) _in, (u8 *) _out);
650
651 _out[0] ^= _iv[0];
652 _out[1] ^= _iv[1];
653 _out[2] ^= _iv[2];
654 _out[3] ^= _iv[3];
655
656 out[i + 0] = _out[0];
657 out[i + 1] = _out[1];
658 out[i + 2] = _out[2];
659 out[i + 3] = _out[3];
660
661 _iv[0] = _in[0];
662 _iv[1] = _in[1];
663 _iv[2] = _in[2];
664 _iv[3] = _in[3];
665 }
666 }
667
668 static void juniper_decrypt_hash (char *in, char *out)
669 {
670 // base64 decode
671
672 u8 base64_buf[100] = { 0 };
673
674 base64_decode (base64_to_int, (const u8 *) in, DISPLAY_LEN_MIN_501, base64_buf);
675
676 // iv stuff
677
678 u32 juniper_iv[4] = { 0 };
679
680 memcpy (juniper_iv, base64_buf, 12);
681
682 memcpy (out, juniper_iv, 12);
683
684 // reversed key
685
686 u32 juniper_key[4] = { 0 };
687
688 juniper_key[0] = byte_swap_32 (0xa6707a7e);
689 juniper_key[1] = byte_swap_32 (0x8df91059);
690 juniper_key[2] = byte_swap_32 (0xdea70ae5);
691 juniper_key[3] = byte_swap_32 (0x2f9c2442);
692
693 // AES decrypt
694
695 u32 *in_ptr = (u32 *) (base64_buf + 12);
696 u32 *out_ptr = (u32 *) (out + 12);
697
698 AES128_decrypt_cbc (juniper_key, juniper_iv, in_ptr, out_ptr);
699 }
700
701 void phpass_decode (u8 digest[16], u8 buf[22])
702 {
703 int l;
704
705 l = itoa64_to_int (buf[ 0]) << 0;
706 l |= itoa64_to_int (buf[ 1]) << 6;
707 l |= itoa64_to_int (buf[ 2]) << 12;
708 l |= itoa64_to_int (buf[ 3]) << 18;
709
710 digest[ 0] = (l >> 0) & 0xff;
711 digest[ 1] = (l >> 8) & 0xff;
712 digest[ 2] = (l >> 16) & 0xff;
713
714 l = itoa64_to_int (buf[ 4]) << 0;
715 l |= itoa64_to_int (buf[ 5]) << 6;
716 l |= itoa64_to_int (buf[ 6]) << 12;
717 l |= itoa64_to_int (buf[ 7]) << 18;
718
719 digest[ 3] = (l >> 0) & 0xff;
720 digest[ 4] = (l >> 8) & 0xff;
721 digest[ 5] = (l >> 16) & 0xff;
722
723 l = itoa64_to_int (buf[ 8]) << 0;
724 l |= itoa64_to_int (buf[ 9]) << 6;
725 l |= itoa64_to_int (buf[10]) << 12;
726 l |= itoa64_to_int (buf[11]) << 18;
727
728 digest[ 6] = (l >> 0) & 0xff;
729 digest[ 7] = (l >> 8) & 0xff;
730 digest[ 8] = (l >> 16) & 0xff;
731
732 l = itoa64_to_int (buf[12]) << 0;
733 l |= itoa64_to_int (buf[13]) << 6;
734 l |= itoa64_to_int (buf[14]) << 12;
735 l |= itoa64_to_int (buf[15]) << 18;
736
737 digest[ 9] = (l >> 0) & 0xff;
738 digest[10] = (l >> 8) & 0xff;
739 digest[11] = (l >> 16) & 0xff;
740
741 l = itoa64_to_int (buf[16]) << 0;
742 l |= itoa64_to_int (buf[17]) << 6;
743 l |= itoa64_to_int (buf[18]) << 12;
744 l |= itoa64_to_int (buf[19]) << 18;
745
746 digest[12] = (l >> 0) & 0xff;
747 digest[13] = (l >> 8) & 0xff;
748 digest[14] = (l >> 16) & 0xff;
749
750 l = itoa64_to_int (buf[20]) << 0;
751 l |= itoa64_to_int (buf[21]) << 6;
752
753 digest[15] = (l >> 0) & 0xff;
754 }
755
756 void phpass_encode (u8 digest[16], u8 buf[22])
757 {
758 int l;
759
760 l = (digest[ 0] << 0) | (digest[ 1] << 8) | (digest[ 2] << 16);
761
762 buf[ 0] = int_to_itoa64 (l & 0x3f); l >>= 6;
763 buf[ 1] = int_to_itoa64 (l & 0x3f); l >>= 6;
764 buf[ 2] = int_to_itoa64 (l & 0x3f); l >>= 6;
765 buf[ 3] = int_to_itoa64 (l & 0x3f);
766
767 l = (digest[ 3] << 0) | (digest[ 4] << 8) | (digest[ 5] << 16);
768
769 buf[ 4] = int_to_itoa64 (l & 0x3f); l >>= 6;
770 buf[ 5] = int_to_itoa64 (l & 0x3f); l >>= 6;
771 buf[ 6] = int_to_itoa64 (l & 0x3f); l >>= 6;
772 buf[ 7] = int_to_itoa64 (l & 0x3f);
773
774 l = (digest[ 6] << 0) | (digest[ 7] << 8) | (digest[ 8] << 16);
775
776 buf[ 8] = int_to_itoa64 (l & 0x3f); l >>= 6;
777 buf[ 9] = int_to_itoa64 (l & 0x3f); l >>= 6;
778 buf[10] = int_to_itoa64 (l & 0x3f); l >>= 6;
779 buf[11] = int_to_itoa64 (l & 0x3f);
780
781 l = (digest[ 9] << 0) | (digest[10] << 8) | (digest[11] << 16);
782
783 buf[12] = int_to_itoa64 (l & 0x3f); l >>= 6;
784 buf[13] = int_to_itoa64 (l & 0x3f); l >>= 6;
785 buf[14] = int_to_itoa64 (l & 0x3f); l >>= 6;
786 buf[15] = int_to_itoa64 (l & 0x3f);
787
788 l = (digest[12] << 0) | (digest[13] << 8) | (digest[14] << 16);
789
790 buf[16] = int_to_itoa64 (l & 0x3f); l >>= 6;
791 buf[17] = int_to_itoa64 (l & 0x3f); l >>= 6;
792 buf[18] = int_to_itoa64 (l & 0x3f); l >>= 6;
793 buf[19] = int_to_itoa64 (l & 0x3f);
794
795 l = (digest[15] << 0);
796
797 buf[20] = int_to_itoa64 (l & 0x3f); l >>= 6;
798 buf[21] = int_to_itoa64 (l & 0x3f);
799 }
800
801 void md5crypt_decode (u8 digest[16], u8 buf[22])
802 {
803 int l;
804
805 l = itoa64_to_int (buf[ 0]) << 0;
806 l |= itoa64_to_int (buf[ 1]) << 6;
807 l |= itoa64_to_int (buf[ 2]) << 12;
808 l |= itoa64_to_int (buf[ 3]) << 18;
809
810 digest[ 0] = (l >> 16) & 0xff;
811 digest[ 6] = (l >> 8) & 0xff;
812 digest[12] = (l >> 0) & 0xff;
813
814 l = itoa64_to_int (buf[ 4]) << 0;
815 l |= itoa64_to_int (buf[ 5]) << 6;
816 l |= itoa64_to_int (buf[ 6]) << 12;
817 l |= itoa64_to_int (buf[ 7]) << 18;
818
819 digest[ 1] = (l >> 16) & 0xff;
820 digest[ 7] = (l >> 8) & 0xff;
821 digest[13] = (l >> 0) & 0xff;
822
823 l = itoa64_to_int (buf[ 8]) << 0;
824 l |= itoa64_to_int (buf[ 9]) << 6;
825 l |= itoa64_to_int (buf[10]) << 12;
826 l |= itoa64_to_int (buf[11]) << 18;
827
828 digest[ 2] = (l >> 16) & 0xff;
829 digest[ 8] = (l >> 8) & 0xff;
830 digest[14] = (l >> 0) & 0xff;
831
832 l = itoa64_to_int (buf[12]) << 0;
833 l |= itoa64_to_int (buf[13]) << 6;
834 l |= itoa64_to_int (buf[14]) << 12;
835 l |= itoa64_to_int (buf[15]) << 18;
836
837 digest[ 3] = (l >> 16) & 0xff;
838 digest[ 9] = (l >> 8) & 0xff;
839 digest[15] = (l >> 0) & 0xff;
840
841 l = itoa64_to_int (buf[16]) << 0;
842 l |= itoa64_to_int (buf[17]) << 6;
843 l |= itoa64_to_int (buf[18]) << 12;
844 l |= itoa64_to_int (buf[19]) << 18;
845
846 digest[ 4] = (l >> 16) & 0xff;
847 digest[10] = (l >> 8) & 0xff;
848 digest[ 5] = (l >> 0) & 0xff;
849
850 l = itoa64_to_int (buf[20]) << 0;
851 l |= itoa64_to_int (buf[21]) << 6;
852
853 digest[11] = (l >> 0) & 0xff;
854 }
855
856 void md5crypt_encode (u8 digest[16], u8 buf[22])
857 {
858 int l;
859
860 l = (digest[ 0] << 16) | (digest[ 6] << 8) | (digest[12] << 0);
861
862 buf[ 0] = int_to_itoa64 (l & 0x3f); l >>= 6;
863 buf[ 1] = int_to_itoa64 (l & 0x3f); l >>= 6;
864 buf[ 2] = int_to_itoa64 (l & 0x3f); l >>= 6;
865 buf[ 3] = int_to_itoa64 (l & 0x3f); l >>= 6;
866
867 l = (digest[ 1] << 16) | (digest[ 7] << 8) | (digest[13] << 0);
868
869 buf[ 4] = int_to_itoa64 (l & 0x3f); l >>= 6;
870 buf[ 5] = int_to_itoa64 (l & 0x3f); l >>= 6;
871 buf[ 6] = int_to_itoa64 (l & 0x3f); l >>= 6;
872 buf[ 7] = int_to_itoa64 (l & 0x3f); l >>= 6;
873
874 l = (digest[ 2] << 16) | (digest[ 8] << 8) | (digest[14] << 0);
875
876 buf[ 8] = int_to_itoa64 (l & 0x3f); l >>= 6;
877 buf[ 9] = int_to_itoa64 (l & 0x3f); l >>= 6;
878 buf[10] = int_to_itoa64 (l & 0x3f); l >>= 6;
879 buf[11] = int_to_itoa64 (l & 0x3f); l >>= 6;
880
881 l = (digest[ 3] << 16) | (digest[ 9] << 8) | (digest[15] << 0);
882
883 buf[12] = int_to_itoa64 (l & 0x3f); l >>= 6;
884 buf[13] = int_to_itoa64 (l & 0x3f); l >>= 6;
885 buf[14] = int_to_itoa64 (l & 0x3f); l >>= 6;
886 buf[15] = int_to_itoa64 (l & 0x3f); l >>= 6;
887
888 l = (digest[ 4] << 16) | (digest[10] << 8) | (digest[ 5] << 0);
889
890 buf[16] = int_to_itoa64 (l & 0x3f); l >>= 6;
891 buf[17] = int_to_itoa64 (l & 0x3f); l >>= 6;
892 buf[18] = int_to_itoa64 (l & 0x3f); l >>= 6;
893 buf[19] = int_to_itoa64 (l & 0x3f); l >>= 6;
894
895 l = (digest[11] << 0);
896
897 buf[20] = int_to_itoa64 (l & 0x3f); l >>= 6;
898 buf[21] = int_to_itoa64 (l & 0x3f); l >>= 6;
899 }
900
901 void sha512crypt_decode (u8 digest[64], u8 buf[86])
902 {
903 int l;
904
905 l = itoa64_to_int (buf[ 0]) << 0;
906 l |= itoa64_to_int (buf[ 1]) << 6;
907 l |= itoa64_to_int (buf[ 2]) << 12;
908 l |= itoa64_to_int (buf[ 3]) << 18;
909
910 digest[ 0] = (l >> 16) & 0xff;
911 digest[21] = (l >> 8) & 0xff;
912 digest[42] = (l >> 0) & 0xff;
913
914 l = itoa64_to_int (buf[ 4]) << 0;
915 l |= itoa64_to_int (buf[ 5]) << 6;
916 l |= itoa64_to_int (buf[ 6]) << 12;
917 l |= itoa64_to_int (buf[ 7]) << 18;
918
919 digest[22] = (l >> 16) & 0xff;
920 digest[43] = (l >> 8) & 0xff;
921 digest[ 1] = (l >> 0) & 0xff;
922
923 l = itoa64_to_int (buf[ 8]) << 0;
924 l |= itoa64_to_int (buf[ 9]) << 6;
925 l |= itoa64_to_int (buf[10]) << 12;
926 l |= itoa64_to_int (buf[11]) << 18;
927
928 digest[44] = (l >> 16) & 0xff;
929 digest[ 2] = (l >> 8) & 0xff;
930 digest[23] = (l >> 0) & 0xff;
931
932 l = itoa64_to_int (buf[12]) << 0;
933 l |= itoa64_to_int (buf[13]) << 6;
934 l |= itoa64_to_int (buf[14]) << 12;
935 l |= itoa64_to_int (buf[15]) << 18;
936
937 digest[ 3] = (l >> 16) & 0xff;
938 digest[24] = (l >> 8) & 0xff;
939 digest[45] = (l >> 0) & 0xff;
940
941 l = itoa64_to_int (buf[16]) << 0;
942 l |= itoa64_to_int (buf[17]) << 6;
943 l |= itoa64_to_int (buf[18]) << 12;
944 l |= itoa64_to_int (buf[19]) << 18;
945
946 digest[25] = (l >> 16) & 0xff;
947 digest[46] = (l >> 8) & 0xff;
948 digest[ 4] = (l >> 0) & 0xff;
949
950 l = itoa64_to_int (buf[20]) << 0;
951 l |= itoa64_to_int (buf[21]) << 6;
952 l |= itoa64_to_int (buf[22]) << 12;
953 l |= itoa64_to_int (buf[23]) << 18;
954
955 digest[47] = (l >> 16) & 0xff;
956 digest[ 5] = (l >> 8) & 0xff;
957 digest[26] = (l >> 0) & 0xff;
958
959 l = itoa64_to_int (buf[24]) << 0;
960 l |= itoa64_to_int (buf[25]) << 6;
961 l |= itoa64_to_int (buf[26]) << 12;
962 l |= itoa64_to_int (buf[27]) << 18;
963
964 digest[ 6] = (l >> 16) & 0xff;
965 digest[27] = (l >> 8) & 0xff;
966 digest[48] = (l >> 0) & 0xff;
967
968 l = itoa64_to_int (buf[28]) << 0;
969 l |= itoa64_to_int (buf[29]) << 6;
970 l |= itoa64_to_int (buf[30]) << 12;
971 l |= itoa64_to_int (buf[31]) << 18;
972
973 digest[28] = (l >> 16) & 0xff;
974 digest[49] = (l >> 8) & 0xff;
975 digest[ 7] = (l >> 0) & 0xff;
976
977 l = itoa64_to_int (buf[32]) << 0;
978 l |= itoa64_to_int (buf[33]) << 6;
979 l |= itoa64_to_int (buf[34]) << 12;
980 l |= itoa64_to_int (buf[35]) << 18;
981
982 digest[50] = (l >> 16) & 0xff;
983 digest[ 8] = (l >> 8) & 0xff;
984 digest[29] = (l >> 0) & 0xff;
985
986 l = itoa64_to_int (buf[36]) << 0;
987 l |= itoa64_to_int (buf[37]) << 6;
988 l |= itoa64_to_int (buf[38]) << 12;
989 l |= itoa64_to_int (buf[39]) << 18;
990
991 digest[ 9] = (l >> 16) & 0xff;
992 digest[30] = (l >> 8) & 0xff;
993 digest[51] = (l >> 0) & 0xff;
994
995 l = itoa64_to_int (buf[40]) << 0;
996 l |= itoa64_to_int (buf[41]) << 6;
997 l |= itoa64_to_int (buf[42]) << 12;
998 l |= itoa64_to_int (buf[43]) << 18;
999
1000 digest[31] = (l >> 16) & 0xff;
1001 digest[52] = (l >> 8) & 0xff;
1002 digest[10] = (l >> 0) & 0xff;
1003
1004 l = itoa64_to_int (buf[44]) << 0;
1005 l |= itoa64_to_int (buf[45]) << 6;
1006 l |= itoa64_to_int (buf[46]) << 12;
1007 l |= itoa64_to_int (buf[47]) << 18;
1008
1009 digest[53] = (l >> 16) & 0xff;
1010 digest[11] = (l >> 8) & 0xff;
1011 digest[32] = (l >> 0) & 0xff;
1012
1013 l = itoa64_to_int (buf[48]) << 0;
1014 l |= itoa64_to_int (buf[49]) << 6;
1015 l |= itoa64_to_int (buf[50]) << 12;
1016 l |= itoa64_to_int (buf[51]) << 18;
1017
1018 digest[12] = (l >> 16) & 0xff;
1019 digest[33] = (l >> 8) & 0xff;
1020 digest[54] = (l >> 0) & 0xff;
1021
1022 l = itoa64_to_int (buf[52]) << 0;
1023 l |= itoa64_to_int (buf[53]) << 6;
1024 l |= itoa64_to_int (buf[54]) << 12;
1025 l |= itoa64_to_int (buf[55]) << 18;
1026
1027 digest[34] = (l >> 16) & 0xff;
1028 digest[55] = (l >> 8) & 0xff;
1029 digest[13] = (l >> 0) & 0xff;
1030
1031 l = itoa64_to_int (buf[56]) << 0;
1032 l |= itoa64_to_int (buf[57]) << 6;
1033 l |= itoa64_to_int (buf[58]) << 12;
1034 l |= itoa64_to_int (buf[59]) << 18;
1035
1036 digest[56] = (l >> 16) & 0xff;
1037 digest[14] = (l >> 8) & 0xff;
1038 digest[35] = (l >> 0) & 0xff;
1039
1040 l = itoa64_to_int (buf[60]) << 0;
1041 l |= itoa64_to_int (buf[61]) << 6;
1042 l |= itoa64_to_int (buf[62]) << 12;
1043 l |= itoa64_to_int (buf[63]) << 18;
1044
1045 digest[15] = (l >> 16) & 0xff;
1046 digest[36] = (l >> 8) & 0xff;
1047 digest[57] = (l >> 0) & 0xff;
1048
1049 l = itoa64_to_int (buf[64]) << 0;
1050 l |= itoa64_to_int (buf[65]) << 6;
1051 l |= itoa64_to_int (buf[66]) << 12;
1052 l |= itoa64_to_int (buf[67]) << 18;
1053
1054 digest[37] = (l >> 16) & 0xff;
1055 digest[58] = (l >> 8) & 0xff;
1056 digest[16] = (l >> 0) & 0xff;
1057
1058 l = itoa64_to_int (buf[68]) << 0;
1059 l |= itoa64_to_int (buf[69]) << 6;
1060 l |= itoa64_to_int (buf[70]) << 12;
1061 l |= itoa64_to_int (buf[71]) << 18;
1062
1063 digest[59] = (l >> 16) & 0xff;
1064 digest[17] = (l >> 8) & 0xff;
1065 digest[38] = (l >> 0) & 0xff;
1066
1067 l = itoa64_to_int (buf[72]) << 0;
1068 l |= itoa64_to_int (buf[73]) << 6;
1069 l |= itoa64_to_int (buf[74]) << 12;
1070 l |= itoa64_to_int (buf[75]) << 18;
1071
1072 digest[18] = (l >> 16) & 0xff;
1073 digest[39] = (l >> 8) & 0xff;
1074 digest[60] = (l >> 0) & 0xff;
1075
1076 l = itoa64_to_int (buf[76]) << 0;
1077 l |= itoa64_to_int (buf[77]) << 6;
1078 l |= itoa64_to_int (buf[78]) << 12;
1079 l |= itoa64_to_int (buf[79]) << 18;
1080
1081 digest[40] = (l >> 16) & 0xff;
1082 digest[61] = (l >> 8) & 0xff;
1083 digest[19] = (l >> 0) & 0xff;
1084
1085 l = itoa64_to_int (buf[80]) << 0;
1086 l |= itoa64_to_int (buf[81]) << 6;
1087 l |= itoa64_to_int (buf[82]) << 12;
1088 l |= itoa64_to_int (buf[83]) << 18;
1089
1090 digest[62] = (l >> 16) & 0xff;
1091 digest[20] = (l >> 8) & 0xff;
1092 digest[41] = (l >> 0) & 0xff;
1093
1094 l = itoa64_to_int (buf[84]) << 0;
1095 l |= itoa64_to_int (buf[85]) << 6;
1096
1097 digest[63] = (l >> 0) & 0xff;
1098 }
1099
1100 void sha512crypt_encode (u8 digest[64], u8 buf[86])
1101 {
1102 int l;
1103
1104 l = (digest[ 0] << 16) | (digest[21] << 8) | (digest[42] << 0);
1105
1106 buf[ 0] = int_to_itoa64 (l & 0x3f); l >>= 6;
1107 buf[ 1] = int_to_itoa64 (l & 0x3f); l >>= 6;
1108 buf[ 2] = int_to_itoa64 (l & 0x3f); l >>= 6;
1109 buf[ 3] = int_to_itoa64 (l & 0x3f); l >>= 6;
1110
1111 l = (digest[22] << 16) | (digest[43] << 8) | (digest[ 1] << 0);
1112
1113 buf[ 4] = int_to_itoa64 (l & 0x3f); l >>= 6;
1114 buf[ 5] = int_to_itoa64 (l & 0x3f); l >>= 6;
1115 buf[ 6] = int_to_itoa64 (l & 0x3f); l >>= 6;
1116 buf[ 7] = int_to_itoa64 (l & 0x3f); l >>= 6;
1117
1118 l = (digest[44] << 16) | (digest[ 2] << 8) | (digest[23] << 0);
1119
1120 buf[ 8] = int_to_itoa64 (l & 0x3f); l >>= 6;
1121 buf[ 9] = int_to_itoa64 (l & 0x3f); l >>= 6;
1122 buf[10] = int_to_itoa64 (l & 0x3f); l >>= 6;
1123 buf[11] = int_to_itoa64 (l & 0x3f); l >>= 6;
1124
1125 l = (digest[ 3] << 16) | (digest[24] << 8) | (digest[45] << 0);
1126
1127 buf[12] = int_to_itoa64 (l & 0x3f); l >>= 6;
1128 buf[13] = int_to_itoa64 (l & 0x3f); l >>= 6;
1129 buf[14] = int_to_itoa64 (l & 0x3f); l >>= 6;
1130 buf[15] = int_to_itoa64 (l & 0x3f); l >>= 6;
1131
1132 l = (digest[25] << 16) | (digest[46] << 8) | (digest[ 4] << 0);
1133
1134 buf[16] = int_to_itoa64 (l & 0x3f); l >>= 6;
1135 buf[17] = int_to_itoa64 (l & 0x3f); l >>= 6;
1136 buf[18] = int_to_itoa64 (l & 0x3f); l >>= 6;
1137 buf[19] = int_to_itoa64 (l & 0x3f); l >>= 6;
1138
1139 l = (digest[47] << 16) | (digest[ 5] << 8) | (digest[26] << 0);
1140
1141 buf[20] = int_to_itoa64 (l & 0x3f); l >>= 6;
1142 buf[21] = int_to_itoa64 (l & 0x3f); l >>= 6;
1143 buf[22] = int_to_itoa64 (l & 0x3f); l >>= 6;
1144 buf[23] = int_to_itoa64 (l & 0x3f); l >>= 6;
1145
1146 l = (digest[ 6] << 16) | (digest[27] << 8) | (digest[48] << 0);
1147
1148 buf[24] = int_to_itoa64 (l & 0x3f); l >>= 6;
1149 buf[25] = int_to_itoa64 (l & 0x3f); l >>= 6;
1150 buf[26] = int_to_itoa64 (l & 0x3f); l >>= 6;
1151 buf[27] = int_to_itoa64 (l & 0x3f); l >>= 6;
1152
1153 l = (digest[28] << 16) | (digest[49] << 8) | (digest[ 7] << 0);
1154
1155 buf[28] = int_to_itoa64 (l & 0x3f); l >>= 6;
1156 buf[29] = int_to_itoa64 (l & 0x3f); l >>= 6;
1157 buf[30] = int_to_itoa64 (l & 0x3f); l >>= 6;
1158 buf[31] = int_to_itoa64 (l & 0x3f); l >>= 6;
1159
1160 l = (digest[50] << 16) | (digest[ 8] << 8) | (digest[29] << 0);
1161
1162 buf[32] = int_to_itoa64 (l & 0x3f); l >>= 6;
1163 buf[33] = int_to_itoa64 (l & 0x3f); l >>= 6;
1164 buf[34] = int_to_itoa64 (l & 0x3f); l >>= 6;
1165 buf[35] = int_to_itoa64 (l & 0x3f); l >>= 6;
1166
1167 l = (digest[ 9] << 16) | (digest[30] << 8) | (digest[51] << 0);
1168
1169 buf[36] = int_to_itoa64 (l & 0x3f); l >>= 6;
1170 buf[37] = int_to_itoa64 (l & 0x3f); l >>= 6;
1171 buf[38] = int_to_itoa64 (l & 0x3f); l >>= 6;
1172 buf[39] = int_to_itoa64 (l & 0x3f); l >>= 6;
1173
1174 l = (digest[31] << 16) | (digest[52] << 8) | (digest[10] << 0);
1175
1176 buf[40] = int_to_itoa64 (l & 0x3f); l >>= 6;
1177 buf[41] = int_to_itoa64 (l & 0x3f); l >>= 6;
1178 buf[42] = int_to_itoa64 (l & 0x3f); l >>= 6;
1179 buf[43] = int_to_itoa64 (l & 0x3f); l >>= 6;
1180
1181 l = (digest[53] << 16) | (digest[11] << 8) | (digest[32] << 0);
1182
1183 buf[44] = int_to_itoa64 (l & 0x3f); l >>= 6;
1184 buf[45] = int_to_itoa64 (l & 0x3f); l >>= 6;
1185 buf[46] = int_to_itoa64 (l & 0x3f); l >>= 6;
1186 buf[47] = int_to_itoa64 (l & 0x3f); l >>= 6;
1187
1188 l = (digest[12] << 16) | (digest[33] << 8) | (digest[54] << 0);
1189
1190 buf[48] = int_to_itoa64 (l & 0x3f); l >>= 6;
1191 buf[49] = int_to_itoa64 (l & 0x3f); l >>= 6;
1192 buf[50] = int_to_itoa64 (l & 0x3f); l >>= 6;
1193 buf[51] = int_to_itoa64 (l & 0x3f); l >>= 6;
1194
1195 l = (digest[34] << 16) | (digest[55] << 8) | (digest[13] << 0);
1196
1197 buf[52] = int_to_itoa64 (l & 0x3f); l >>= 6;
1198 buf[53] = int_to_itoa64 (l & 0x3f); l >>= 6;
1199 buf[54] = int_to_itoa64 (l & 0x3f); l >>= 6;
1200 buf[55] = int_to_itoa64 (l & 0x3f); l >>= 6;
1201
1202 l = (digest[56] << 16) | (digest[14] << 8) | (digest[35] << 0);
1203
1204 buf[56] = int_to_itoa64 (l & 0x3f); l >>= 6;
1205 buf[57] = int_to_itoa64 (l & 0x3f); l >>= 6;
1206 buf[58] = int_to_itoa64 (l & 0x3f); l >>= 6;
1207 buf[59] = int_to_itoa64 (l & 0x3f); l >>= 6;
1208
1209 l = (digest[15] << 16) | (digest[36] << 8) | (digest[57] << 0);
1210
1211 buf[60] = int_to_itoa64 (l & 0x3f); l >>= 6;
1212 buf[61] = int_to_itoa64 (l & 0x3f); l >>= 6;
1213 buf[62] = int_to_itoa64 (l & 0x3f); l >>= 6;
1214 buf[63] = int_to_itoa64 (l & 0x3f); l >>= 6;
1215
1216 l = (digest[37] << 16) | (digest[58] << 8) | (digest[16] << 0);
1217
1218 buf[64] = int_to_itoa64 (l & 0x3f); l >>= 6;
1219 buf[65] = int_to_itoa64 (l & 0x3f); l >>= 6;
1220 buf[66] = int_to_itoa64 (l & 0x3f); l >>= 6;
1221 buf[67] = int_to_itoa64 (l & 0x3f); l >>= 6;
1222
1223 l = (digest[59] << 16) | (digest[17] << 8) | (digest[38] << 0);
1224
1225 buf[68] = int_to_itoa64 (l & 0x3f); l >>= 6;
1226 buf[69] = int_to_itoa64 (l & 0x3f); l >>= 6;
1227 buf[70] = int_to_itoa64 (l & 0x3f); l >>= 6;
1228 buf[71] = int_to_itoa64 (l & 0x3f); l >>= 6;
1229
1230 l = (digest[18] << 16) | (digest[39] << 8) | (digest[60] << 0);
1231
1232 buf[72] = int_to_itoa64 (l & 0x3f); l >>= 6;
1233 buf[73] = int_to_itoa64 (l & 0x3f); l >>= 6;
1234 buf[74] = int_to_itoa64 (l & 0x3f); l >>= 6;
1235 buf[75] = int_to_itoa64 (l & 0x3f); l >>= 6;
1236
1237 l = (digest[40] << 16) | (digest[61] << 8) | (digest[19] << 0);
1238
1239 buf[76] = int_to_itoa64 (l & 0x3f); l >>= 6;
1240 buf[77] = int_to_itoa64 (l & 0x3f); l >>= 6;
1241 buf[78] = int_to_itoa64 (l & 0x3f); l >>= 6;
1242 buf[79] = int_to_itoa64 (l & 0x3f); l >>= 6;
1243
1244 l = (digest[62] << 16) | (digest[20] << 8) | (digest[41] << 0);
1245
1246 buf[80] = int_to_itoa64 (l & 0x3f); l >>= 6;
1247 buf[81] = int_to_itoa64 (l & 0x3f); l >>= 6;
1248 buf[82] = int_to_itoa64 (l & 0x3f); l >>= 6;
1249 buf[83] = int_to_itoa64 (l & 0x3f); l >>= 6;
1250
1251 l = 0 | 0 | (digest[63] << 0);
1252
1253 buf[84] = int_to_itoa64 (l & 0x3f); l >>= 6;
1254 buf[85] = int_to_itoa64 (l & 0x3f); l >>= 6;
1255 }
1256
1257 void sha1aix_decode (u8 digest[20], u8 buf[27])
1258 {
1259 int l;
1260
1261 l = itoa64_to_int (buf[ 0]) << 0;
1262 l |= itoa64_to_int (buf[ 1]) << 6;
1263 l |= itoa64_to_int (buf[ 2]) << 12;
1264 l |= itoa64_to_int (buf[ 3]) << 18;
1265
1266 digest[ 2] = (l >> 0) & 0xff;
1267 digest[ 1] = (l >> 8) & 0xff;
1268 digest[ 0] = (l >> 16) & 0xff;
1269
1270 l = itoa64_to_int (buf[ 4]) << 0;
1271 l |= itoa64_to_int (buf[ 5]) << 6;
1272 l |= itoa64_to_int (buf[ 6]) << 12;
1273 l |= itoa64_to_int (buf[ 7]) << 18;
1274
1275 digest[ 5] = (l >> 0) & 0xff;
1276 digest[ 4] = (l >> 8) & 0xff;
1277 digest[ 3] = (l >> 16) & 0xff;
1278
1279 l = itoa64_to_int (buf[ 8]) << 0;
1280 l |= itoa64_to_int (buf[ 9]) << 6;
1281 l |= itoa64_to_int (buf[10]) << 12;
1282 l |= itoa64_to_int (buf[11]) << 18;
1283
1284 digest[ 8] = (l >> 0) & 0xff;
1285 digest[ 7] = (l >> 8) & 0xff;
1286 digest[ 6] = (l >> 16) & 0xff;
1287
1288 l = itoa64_to_int (buf[12]) << 0;
1289 l |= itoa64_to_int (buf[13]) << 6;
1290 l |= itoa64_to_int (buf[14]) << 12;
1291 l |= itoa64_to_int (buf[15]) << 18;
1292
1293 digest[11] = (l >> 0) & 0xff;
1294 digest[10] = (l >> 8) & 0xff;
1295 digest[ 9] = (l >> 16) & 0xff;
1296
1297 l = itoa64_to_int (buf[16]) << 0;
1298 l |= itoa64_to_int (buf[17]) << 6;
1299 l |= itoa64_to_int (buf[18]) << 12;
1300 l |= itoa64_to_int (buf[19]) << 18;
1301
1302 digest[14] = (l >> 0) & 0xff;
1303 digest[13] = (l >> 8) & 0xff;
1304 digest[12] = (l >> 16) & 0xff;
1305
1306 l = itoa64_to_int (buf[20]) << 0;
1307 l |= itoa64_to_int (buf[21]) << 6;
1308 l |= itoa64_to_int (buf[22]) << 12;
1309 l |= itoa64_to_int (buf[23]) << 18;
1310
1311 digest[17] = (l >> 0) & 0xff;
1312 digest[16] = (l >> 8) & 0xff;
1313 digest[15] = (l >> 16) & 0xff;
1314
1315 l = itoa64_to_int (buf[24]) << 0;
1316 l |= itoa64_to_int (buf[25]) << 6;
1317 l |= itoa64_to_int (buf[26]) << 12;
1318
1319 digest[19] = (l >> 8) & 0xff;
1320 digest[18] = (l >> 16) & 0xff;
1321 }
1322
1323 void sha1aix_encode (u8 digest[20], u8 buf[27])
1324 {
1325 int l;
1326
1327 l = (digest[ 2] << 0) | (digest[ 1] << 8) | (digest[ 0] << 16);
1328
1329 buf[ 0] = int_to_itoa64 (l & 0x3f); l >>= 6;
1330 buf[ 1] = int_to_itoa64 (l & 0x3f); l >>= 6;
1331 buf[ 2] = int_to_itoa64 (l & 0x3f); l >>= 6;
1332 buf[ 3] = int_to_itoa64 (l & 0x3f);
1333
1334 l = (digest[ 5] << 0) | (digest[ 4] << 8) | (digest[ 3] << 16);
1335
1336 buf[ 4] = int_to_itoa64 (l & 0x3f); l >>= 6;
1337 buf[ 5] = int_to_itoa64 (l & 0x3f); l >>= 6;
1338 buf[ 6] = int_to_itoa64 (l & 0x3f); l >>= 6;
1339 buf[ 7] = int_to_itoa64 (l & 0x3f);
1340
1341 l = (digest[ 8] << 0) | (digest[ 7] << 8) | (digest[ 6] << 16);
1342
1343 buf[ 8] = int_to_itoa64 (l & 0x3f); l >>= 6;
1344 buf[ 9] = int_to_itoa64 (l & 0x3f); l >>= 6;
1345 buf[10] = int_to_itoa64 (l & 0x3f); l >>= 6;
1346 buf[11] = int_to_itoa64 (l & 0x3f);
1347
1348 l = (digest[11] << 0) | (digest[10] << 8) | (digest[ 9] << 16);
1349
1350 buf[12] = int_to_itoa64 (l & 0x3f); l >>= 6;
1351 buf[13] = int_to_itoa64 (l & 0x3f); l >>= 6;
1352 buf[14] = int_to_itoa64 (l & 0x3f); l >>= 6;
1353 buf[15] = int_to_itoa64 (l & 0x3f);
1354
1355 l = (digest[14] << 0) | (digest[13] << 8) | (digest[12] << 16);
1356
1357 buf[16] = int_to_itoa64 (l & 0x3f); l >>= 6;
1358 buf[17] = int_to_itoa64 (l & 0x3f); l >>= 6;
1359 buf[18] = int_to_itoa64 (l & 0x3f); l >>= 6;
1360 buf[19] = int_to_itoa64 (l & 0x3f);
1361
1362 l = (digest[17] << 0) | (digest[16] << 8) | (digest[15] << 16);
1363
1364 buf[20] = int_to_itoa64 (l & 0x3f); l >>= 6;
1365 buf[21] = int_to_itoa64 (l & 0x3f); l >>= 6;
1366 buf[22] = int_to_itoa64 (l & 0x3f); l >>= 6;
1367 buf[23] = int_to_itoa64 (l & 0x3f);
1368
1369 l = 0 | (digest[19] << 8) | (digest[18] << 16);
1370
1371 buf[24] = int_to_itoa64 (l & 0x3f); l >>= 6;
1372 buf[25] = int_to_itoa64 (l & 0x3f); l >>= 6;
1373 buf[26] = int_to_itoa64 (l & 0x3f);
1374 }
1375
1376 void sha256aix_decode (u8 digest[32], u8 buf[43])
1377 {
1378 int l;
1379
1380 l = itoa64_to_int (buf[ 0]) << 0;
1381 l |= itoa64_to_int (buf[ 1]) << 6;
1382 l |= itoa64_to_int (buf[ 2]) << 12;
1383 l |= itoa64_to_int (buf[ 3]) << 18;
1384
1385 digest[ 2] = (l >> 0) & 0xff;
1386 digest[ 1] = (l >> 8) & 0xff;
1387 digest[ 0] = (l >> 16) & 0xff;
1388
1389 l = itoa64_to_int (buf[ 4]) << 0;
1390 l |= itoa64_to_int (buf[ 5]) << 6;
1391 l |= itoa64_to_int (buf[ 6]) << 12;
1392 l |= itoa64_to_int (buf[ 7]) << 18;
1393
1394 digest[ 5] = (l >> 0) & 0xff;
1395 digest[ 4] = (l >> 8) & 0xff;
1396 digest[ 3] = (l >> 16) & 0xff;
1397
1398 l = itoa64_to_int (buf[ 8]) << 0;
1399 l |= itoa64_to_int (buf[ 9]) << 6;
1400 l |= itoa64_to_int (buf[10]) << 12;
1401 l |= itoa64_to_int (buf[11]) << 18;
1402
1403 digest[ 8] = (l >> 0) & 0xff;
1404 digest[ 7] = (l >> 8) & 0xff;
1405 digest[ 6] = (l >> 16) & 0xff;
1406
1407 l = itoa64_to_int (buf[12]) << 0;
1408 l |= itoa64_to_int (buf[13]) << 6;
1409 l |= itoa64_to_int (buf[14]) << 12;
1410 l |= itoa64_to_int (buf[15]) << 18;
1411
1412 digest[11] = (l >> 0) & 0xff;
1413 digest[10] = (l >> 8) & 0xff;
1414 digest[ 9] = (l >> 16) & 0xff;
1415
1416 l = itoa64_to_int (buf[16]) << 0;
1417 l |= itoa64_to_int (buf[17]) << 6;
1418 l |= itoa64_to_int (buf[18]) << 12;
1419 l |= itoa64_to_int (buf[19]) << 18;
1420
1421 digest[14] = (l >> 0) & 0xff;
1422 digest[13] = (l >> 8) & 0xff;
1423 digest[12] = (l >> 16) & 0xff;
1424
1425 l = itoa64_to_int (buf[20]) << 0;
1426 l |= itoa64_to_int (buf[21]) << 6;
1427 l |= itoa64_to_int (buf[22]) << 12;
1428 l |= itoa64_to_int (buf[23]) << 18;
1429
1430 digest[17] = (l >> 0) & 0xff;
1431 digest[16] = (l >> 8) & 0xff;
1432 digest[15] = (l >> 16) & 0xff;
1433
1434 l = itoa64_to_int (buf[24]) << 0;
1435 l |= itoa64_to_int (buf[25]) << 6;
1436 l |= itoa64_to_int (buf[26]) << 12;
1437 l |= itoa64_to_int (buf[27]) << 18;
1438
1439 digest[20] = (l >> 0) & 0xff;
1440 digest[19] = (l >> 8) & 0xff;
1441 digest[18] = (l >> 16) & 0xff;
1442
1443 l = itoa64_to_int (buf[28]) << 0;
1444 l |= itoa64_to_int (buf[29]) << 6;
1445 l |= itoa64_to_int (buf[30]) << 12;
1446 l |= itoa64_to_int (buf[31]) << 18;
1447
1448 digest[23] = (l >> 0) & 0xff;
1449 digest[22] = (l >> 8) & 0xff;
1450 digest[21] = (l >> 16) & 0xff;
1451
1452 l = itoa64_to_int (buf[32]) << 0;
1453 l |= itoa64_to_int (buf[33]) << 6;
1454 l |= itoa64_to_int (buf[34]) << 12;
1455 l |= itoa64_to_int (buf[35]) << 18;
1456
1457 digest[26] = (l >> 0) & 0xff;
1458 digest[25] = (l >> 8) & 0xff;
1459 digest[24] = (l >> 16) & 0xff;
1460
1461 l = itoa64_to_int (buf[36]) << 0;
1462 l |= itoa64_to_int (buf[37]) << 6;
1463 l |= itoa64_to_int (buf[38]) << 12;
1464 l |= itoa64_to_int (buf[39]) << 18;
1465
1466 digest[29] = (l >> 0) & 0xff;
1467 digest[28] = (l >> 8) & 0xff;
1468 digest[27] = (l >> 16) & 0xff;
1469
1470 l = itoa64_to_int (buf[40]) << 0;
1471 l |= itoa64_to_int (buf[41]) << 6;
1472 l |= itoa64_to_int (buf[42]) << 12;
1473
1474 //digest[32] = (l >> 0) & 0xff;
1475 digest[31] = (l >> 8) & 0xff;
1476 digest[30] = (l >> 16) & 0xff;
1477 }
1478
1479 void sha256aix_encode (u8 digest[32], u8 buf[43])
1480 {
1481 int l;
1482
1483 l = (digest[ 2] << 0) | (digest[ 1] << 8) | (digest[ 0] << 16);
1484
1485 buf[ 0] = int_to_itoa64 (l & 0x3f); l >>= 6;
1486 buf[ 1] = int_to_itoa64 (l & 0x3f); l >>= 6;
1487 buf[ 2] = int_to_itoa64 (l & 0x3f); l >>= 6;
1488 buf[ 3] = int_to_itoa64 (l & 0x3f);
1489
1490 l = (digest[ 5] << 0) | (digest[ 4] << 8) | (digest[ 3] << 16);
1491
1492 buf[ 4] = int_to_itoa64 (l & 0x3f); l >>= 6;
1493 buf[ 5] = int_to_itoa64 (l & 0x3f); l >>= 6;
1494 buf[ 6] = int_to_itoa64 (l & 0x3f); l >>= 6;
1495 buf[ 7] = int_to_itoa64 (l & 0x3f);
1496
1497 l = (digest[ 8] << 0) | (digest[ 7] << 8) | (digest[ 6] << 16);
1498
1499 buf[ 8] = int_to_itoa64 (l & 0x3f); l >>= 6;
1500 buf[ 9] = int_to_itoa64 (l & 0x3f); l >>= 6;
1501 buf[10] = int_to_itoa64 (l & 0x3f); l >>= 6;
1502 buf[11] = int_to_itoa64 (l & 0x3f);
1503
1504 l = (digest[11] << 0) | (digest[10] << 8) | (digest[ 9] << 16);
1505
1506 buf[12] = int_to_itoa64 (l & 0x3f); l >>= 6;
1507 buf[13] = int_to_itoa64 (l & 0x3f); l >>= 6;
1508 buf[14] = int_to_itoa64 (l & 0x3f); l >>= 6;
1509 buf[15] = int_to_itoa64 (l & 0x3f);
1510
1511 l = (digest[14] << 0) | (digest[13] << 8) | (digest[12] << 16);
1512
1513 buf[16] = int_to_itoa64 (l & 0x3f); l >>= 6;
1514 buf[17] = int_to_itoa64 (l & 0x3f); l >>= 6;
1515 buf[18] = int_to_itoa64 (l & 0x3f); l >>= 6;
1516 buf[19] = int_to_itoa64 (l & 0x3f);
1517
1518 l = (digest[17] << 0) | (digest[16] << 8) | (digest[15] << 16);
1519
1520 buf[20] = int_to_itoa64 (l & 0x3f); l >>= 6;
1521 buf[21] = int_to_itoa64 (l & 0x3f); l >>= 6;
1522 buf[22] = int_to_itoa64 (l & 0x3f); l >>= 6;
1523 buf[23] = int_to_itoa64 (l & 0x3f);
1524
1525 l = (digest[20] << 0) | (digest[19] << 8) | (digest[18] << 16);
1526
1527 buf[24] = int_to_itoa64 (l & 0x3f); l >>= 6;
1528 buf[25] = int_to_itoa64 (l & 0x3f); l >>= 6;
1529 buf[26] = int_to_itoa64 (l & 0x3f); l >>= 6;
1530 buf[27] = int_to_itoa64 (l & 0x3f);
1531
1532 l = (digest[23] << 0) | (digest[22] << 8) | (digest[21] << 16);
1533
1534 buf[28] = int_to_itoa64 (l & 0x3f); l >>= 6;
1535 buf[29] = int_to_itoa64 (l & 0x3f); l >>= 6;
1536 buf[30] = int_to_itoa64 (l & 0x3f); l >>= 6;
1537 buf[31] = int_to_itoa64 (l & 0x3f);
1538
1539 l = (digest[26] << 0) | (digest[25] << 8) | (digest[24] << 16);
1540
1541 buf[32] = int_to_itoa64 (l & 0x3f); l >>= 6;
1542 buf[33] = int_to_itoa64 (l & 0x3f); l >>= 6;
1543 buf[34] = int_to_itoa64 (l & 0x3f); l >>= 6;
1544 buf[35] = int_to_itoa64 (l & 0x3f);
1545
1546 l = (digest[29] << 0) | (digest[28] << 8) | (digest[27] << 16);
1547
1548 buf[36] = int_to_itoa64 (l & 0x3f); l >>= 6;
1549 buf[37] = int_to_itoa64 (l & 0x3f); l >>= 6;
1550 buf[38] = int_to_itoa64 (l & 0x3f); l >>= 6;
1551 buf[39] = int_to_itoa64 (l & 0x3f);
1552
1553 l = 0 | (digest[31] << 8) | (digest[30] << 16);
1554
1555 buf[40] = int_to_itoa64 (l & 0x3f); l >>= 6;
1556 buf[41] = int_to_itoa64 (l & 0x3f); l >>= 6;
1557 buf[42] = int_to_itoa64 (l & 0x3f);
1558 }
1559
1560 void sha512aix_decode (u8 digest[64], u8 buf[86])
1561 {
1562 int l;
1563
1564 l = itoa64_to_int (buf[ 0]) << 0;
1565 l |= itoa64_to_int (buf[ 1]) << 6;
1566 l |= itoa64_to_int (buf[ 2]) << 12;
1567 l |= itoa64_to_int (buf[ 3]) << 18;
1568
1569 digest[ 2] = (l >> 0) & 0xff;
1570 digest[ 1] = (l >> 8) & 0xff;
1571 digest[ 0] = (l >> 16) & 0xff;
1572
1573 l = itoa64_to_int (buf[ 4]) << 0;
1574 l |= itoa64_to_int (buf[ 5]) << 6;
1575 l |= itoa64_to_int (buf[ 6]) << 12;
1576 l |= itoa64_to_int (buf[ 7]) << 18;
1577
1578 digest[ 5] = (l >> 0) & 0xff;
1579 digest[ 4] = (l >> 8) & 0xff;
1580 digest[ 3] = (l >> 16) & 0xff;
1581
1582 l = itoa64_to_int (buf[ 8]) << 0;
1583 l |= itoa64_to_int (buf[ 9]) << 6;
1584 l |= itoa64_to_int (buf[10]) << 12;
1585 l |= itoa64_to_int (buf[11]) << 18;
1586
1587 digest[ 8] = (l >> 0) & 0xff;
1588 digest[ 7] = (l >> 8) & 0xff;
1589 digest[ 6] = (l >> 16) & 0xff;
1590
1591 l = itoa64_to_int (buf[12]) << 0;
1592 l |= itoa64_to_int (buf[13]) << 6;
1593 l |= itoa64_to_int (buf[14]) << 12;
1594 l |= itoa64_to_int (buf[15]) << 18;
1595
1596 digest[11] = (l >> 0) & 0xff;
1597 digest[10] = (l >> 8) & 0xff;
1598 digest[ 9] = (l >> 16) & 0xff;
1599
1600 l = itoa64_to_int (buf[16]) << 0;
1601 l |= itoa64_to_int (buf[17]) << 6;
1602 l |= itoa64_to_int (buf[18]) << 12;
1603 l |= itoa64_to_int (buf[19]) << 18;
1604
1605 digest[14] = (l >> 0) & 0xff;
1606 digest[13] = (l >> 8) & 0xff;
1607 digest[12] = (l >> 16) & 0xff;
1608
1609 l = itoa64_to_int (buf[20]) << 0;
1610 l |= itoa64_to_int (buf[21]) << 6;
1611 l |= itoa64_to_int (buf[22]) << 12;
1612 l |= itoa64_to_int (buf[23]) << 18;
1613
1614 digest[17] = (l >> 0) & 0xff;
1615 digest[16] = (l >> 8) & 0xff;
1616 digest[15] = (l >> 16) & 0xff;
1617
1618 l = itoa64_to_int (buf[24]) << 0;
1619 l |= itoa64_to_int (buf[25]) << 6;
1620 l |= itoa64_to_int (buf[26]) << 12;
1621 l |= itoa64_to_int (buf[27]) << 18;
1622
1623 digest[20] = (l >> 0) & 0xff;
1624 digest[19] = (l >> 8) & 0xff;
1625 digest[18] = (l >> 16) & 0xff;
1626
1627 l = itoa64_to_int (buf[28]) << 0;
1628 l |= itoa64_to_int (buf[29]) << 6;
1629 l |= itoa64_to_int (buf[30]) << 12;
1630 l |= itoa64_to_int (buf[31]) << 18;
1631
1632 digest[23] = (l >> 0) & 0xff;
1633 digest[22] = (l >> 8) & 0xff;
1634 digest[21] = (l >> 16) & 0xff;
1635
1636 l = itoa64_to_int (buf[32]) << 0;
1637 l |= itoa64_to_int (buf[33]) << 6;
1638 l |= itoa64_to_int (buf[34]) << 12;
1639 l |= itoa64_to_int (buf[35]) << 18;
1640
1641 digest[26] = (l >> 0) & 0xff;
1642 digest[25] = (l >> 8) & 0xff;
1643 digest[24] = (l >> 16) & 0xff;
1644
1645 l = itoa64_to_int (buf[36]) << 0;
1646 l |= itoa64_to_int (buf[37]) << 6;
1647 l |= itoa64_to_int (buf[38]) << 12;
1648 l |= itoa64_to_int (buf[39]) << 18;
1649
1650 digest[29] = (l >> 0) & 0xff;
1651 digest[28] = (l >> 8) & 0xff;
1652 digest[27] = (l >> 16) & 0xff;
1653
1654 l = itoa64_to_int (buf[40]) << 0;
1655 l |= itoa64_to_int (buf[41]) << 6;
1656 l |= itoa64_to_int (buf[42]) << 12;
1657 l |= itoa64_to_int (buf[43]) << 18;
1658
1659 digest[32] = (l >> 0) & 0xff;
1660 digest[31] = (l >> 8) & 0xff;
1661 digest[30] = (l >> 16) & 0xff;
1662
1663 l = itoa64_to_int (buf[44]) << 0;
1664 l |= itoa64_to_int (buf[45]) << 6;
1665 l |= itoa64_to_int (buf[46]) << 12;
1666 l |= itoa64_to_int (buf[47]) << 18;
1667
1668 digest[35] = (l >> 0) & 0xff;
1669 digest[34] = (l >> 8) & 0xff;
1670 digest[33] = (l >> 16) & 0xff;
1671
1672 l = itoa64_to_int (buf[48]) << 0;
1673 l |= itoa64_to_int (buf[49]) << 6;
1674 l |= itoa64_to_int (buf[50]) << 12;
1675 l |= itoa64_to_int (buf[51]) << 18;
1676
1677 digest[38] = (l >> 0) & 0xff;
1678 digest[37] = (l >> 8) & 0xff;
1679 digest[36] = (l >> 16) & 0xff;
1680
1681 l = itoa64_to_int (buf[52]) << 0;
1682 l |= itoa64_to_int (buf[53]) << 6;
1683 l |= itoa64_to_int (buf[54]) << 12;
1684 l |= itoa64_to_int (buf[55]) << 18;
1685
1686 digest[41] = (l >> 0) & 0xff;
1687 digest[40] = (l >> 8) & 0xff;
1688 digest[39] = (l >> 16) & 0xff;
1689
1690 l = itoa64_to_int (buf[56]) << 0;
1691 l |= itoa64_to_int (buf[57]) << 6;
1692 l |= itoa64_to_int (buf[58]) << 12;
1693 l |= itoa64_to_int (buf[59]) << 18;
1694
1695 digest[44] = (l >> 0) & 0xff;
1696 digest[43] = (l >> 8) & 0xff;
1697 digest[42] = (l >> 16) & 0xff;
1698
1699 l = itoa64_to_int (buf[60]) << 0;
1700 l |= itoa64_to_int (buf[61]) << 6;
1701 l |= itoa64_to_int (buf[62]) << 12;
1702 l |= itoa64_to_int (buf[63]) << 18;
1703
1704 digest[47] = (l >> 0) & 0xff;
1705 digest[46] = (l >> 8) & 0xff;
1706 digest[45] = (l >> 16) & 0xff;
1707
1708 l = itoa64_to_int (buf[64]) << 0;
1709 l |= itoa64_to_int (buf[65]) << 6;
1710 l |= itoa64_to_int (buf[66]) << 12;
1711 l |= itoa64_to_int (buf[67]) << 18;
1712
1713 digest[50] = (l >> 0) & 0xff;
1714 digest[49] = (l >> 8) & 0xff;
1715 digest[48] = (l >> 16) & 0xff;
1716
1717 l = itoa64_to_int (buf[68]) << 0;
1718 l |= itoa64_to_int (buf[69]) << 6;
1719 l |= itoa64_to_int (buf[70]) << 12;
1720 l |= itoa64_to_int (buf[71]) << 18;
1721
1722 digest[53] = (l >> 0) & 0xff;
1723 digest[52] = (l >> 8) & 0xff;
1724 digest[51] = (l >> 16) & 0xff;
1725
1726 l = itoa64_to_int (buf[72]) << 0;
1727 l |= itoa64_to_int (buf[73]) << 6;
1728 l |= itoa64_to_int (buf[74]) << 12;
1729 l |= itoa64_to_int (buf[75]) << 18;
1730
1731 digest[56] = (l >> 0) & 0xff;
1732 digest[55] = (l >> 8) & 0xff;
1733 digest[54] = (l >> 16) & 0xff;
1734
1735 l = itoa64_to_int (buf[76]) << 0;
1736 l |= itoa64_to_int (buf[77]) << 6;
1737 l |= itoa64_to_int (buf[78]) << 12;
1738 l |= itoa64_to_int (buf[79]) << 18;
1739
1740 digest[59] = (l >> 0) & 0xff;
1741 digest[58] = (l >> 8) & 0xff;
1742 digest[57] = (l >> 16) & 0xff;
1743
1744 l = itoa64_to_int (buf[80]) << 0;
1745 l |= itoa64_to_int (buf[81]) << 6;
1746 l |= itoa64_to_int (buf[82]) << 12;
1747 l |= itoa64_to_int (buf[83]) << 18;
1748
1749 digest[62] = (l >> 0) & 0xff;
1750 digest[61] = (l >> 8) & 0xff;
1751 digest[60] = (l >> 16) & 0xff;
1752
1753 l = itoa64_to_int (buf[84]) << 0;
1754 l |= itoa64_to_int (buf[85]) << 6;
1755
1756 digest[63] = (l >> 16) & 0xff;
1757 }
1758
1759 void sha512aix_encode (u8 digest[64], u8 buf[86])
1760 {
1761 int l;
1762
1763 l = (digest[ 2] << 0) | (digest[ 1] << 8) | (digest[ 0] << 16);
1764
1765 buf[ 0] = int_to_itoa64 (l & 0x3f); l >>= 6;
1766 buf[ 1] = int_to_itoa64 (l & 0x3f); l >>= 6;
1767 buf[ 2] = int_to_itoa64 (l & 0x3f); l >>= 6;
1768 buf[ 3] = int_to_itoa64 (l & 0x3f);
1769
1770 l = (digest[ 5] << 0) | (digest[ 4] << 8) | (digest[ 3] << 16);
1771
1772 buf[ 4] = int_to_itoa64 (l & 0x3f); l >>= 6;
1773 buf[ 5] = int_to_itoa64 (l & 0x3f); l >>= 6;
1774 buf[ 6] = int_to_itoa64 (l & 0x3f); l >>= 6;
1775 buf[ 7] = int_to_itoa64 (l & 0x3f);
1776
1777 l = (digest[ 8] << 0) | (digest[ 7] << 8) | (digest[ 6] << 16);
1778
1779 buf[ 8] = int_to_itoa64 (l & 0x3f); l >>= 6;
1780 buf[ 9] = int_to_itoa64 (l & 0x3f); l >>= 6;
1781 buf[10] = int_to_itoa64 (l & 0x3f); l >>= 6;
1782 buf[11] = int_to_itoa64 (l & 0x3f);
1783
1784 l = (digest[11] << 0) | (digest[10] << 8) | (digest[ 9] << 16);
1785
1786 buf[12] = int_to_itoa64 (l & 0x3f); l >>= 6;
1787 buf[13] = int_to_itoa64 (l & 0x3f); l >>= 6;
1788 buf[14] = int_to_itoa64 (l & 0x3f); l >>= 6;
1789 buf[15] = int_to_itoa64 (l & 0x3f);
1790
1791 l = (digest[14] << 0) | (digest[13] << 8) | (digest[12] << 16);
1792
1793 buf[16] = int_to_itoa64 (l & 0x3f); l >>= 6;
1794 buf[17] = int_to_itoa64 (l & 0x3f); l >>= 6;
1795 buf[18] = int_to_itoa64 (l & 0x3f); l >>= 6;
1796 buf[19] = int_to_itoa64 (l & 0x3f);
1797
1798 l = (digest[17] << 0) | (digest[16] << 8) | (digest[15] << 16);
1799
1800 buf[20] = int_to_itoa64 (l & 0x3f); l >>= 6;
1801 buf[21] = int_to_itoa64 (l & 0x3f); l >>= 6;
1802 buf[22] = int_to_itoa64 (l & 0x3f); l >>= 6;
1803 buf[23] = int_to_itoa64 (l & 0x3f);
1804
1805 l = (digest[20] << 0) | (digest[19] << 8) | (digest[18] << 16);
1806
1807 buf[24] = int_to_itoa64 (l & 0x3f); l >>= 6;
1808 buf[25] = int_to_itoa64 (l & 0x3f); l >>= 6;
1809 buf[26] = int_to_itoa64 (l & 0x3f); l >>= 6;
1810 buf[27] = int_to_itoa64 (l & 0x3f);
1811
1812 l = (digest[23] << 0) | (digest[22] << 8) | (digest[21] << 16);
1813
1814 buf[28] = int_to_itoa64 (l & 0x3f); l >>= 6;
1815 buf[29] = int_to_itoa64 (l & 0x3f); l >>= 6;
1816 buf[30] = int_to_itoa64 (l & 0x3f); l >>= 6;
1817 buf[31] = int_to_itoa64 (l & 0x3f);
1818
1819 l = (digest[26] << 0) | (digest[25] << 8) | (digest[24] << 16);
1820
1821 buf[32] = int_to_itoa64 (l & 0x3f); l >>= 6;
1822 buf[33] = int_to_itoa64 (l & 0x3f); l >>= 6;
1823 buf[34] = int_to_itoa64 (l & 0x3f); l >>= 6;
1824 buf[35] = int_to_itoa64 (l & 0x3f);
1825
1826 l = (digest[29] << 0) | (digest[28] << 8) | (digest[27] << 16);
1827
1828 buf[36] = int_to_itoa64 (l & 0x3f); l >>= 6;
1829 buf[37] = int_to_itoa64 (l & 0x3f); l >>= 6;
1830 buf[38] = int_to_itoa64 (l & 0x3f); l >>= 6;
1831 buf[39] = int_to_itoa64 (l & 0x3f);
1832
1833 l = (digest[32] << 0) | (digest[31] << 8) | (digest[30] << 16);
1834
1835 buf[40] = int_to_itoa64 (l & 0x3f); l >>= 6;
1836 buf[41] = int_to_itoa64 (l & 0x3f); l >>= 6;
1837 buf[42] = int_to_itoa64 (l & 0x3f); l >>= 6;
1838 buf[43] = int_to_itoa64 (l & 0x3f);
1839
1840 l = (digest[35] << 0) | (digest[34] << 8) | (digest[33] << 16);
1841
1842 buf[44] = int_to_itoa64 (l & 0x3f); l >>= 6;
1843 buf[45] = int_to_itoa64 (l & 0x3f); l >>= 6;
1844 buf[46] = int_to_itoa64 (l & 0x3f); l >>= 6;
1845 buf[47] = int_to_itoa64 (l & 0x3f);
1846
1847 l = (digest[38] << 0) | (digest[37] << 8) | (digest[36] << 16);
1848
1849 buf[48] = int_to_itoa64 (l & 0x3f); l >>= 6;
1850 buf[49] = int_to_itoa64 (l & 0x3f); l >>= 6;
1851 buf[50] = int_to_itoa64 (l & 0x3f); l >>= 6;
1852 buf[51] = int_to_itoa64 (l & 0x3f);
1853
1854 l = (digest[41] << 0) | (digest[40] << 8) | (digest[39] << 16);
1855
1856 buf[52] = int_to_itoa64 (l & 0x3f); l >>= 6;
1857 buf[53] = int_to_itoa64 (l & 0x3f); l >>= 6;
1858 buf[54] = int_to_itoa64 (l & 0x3f); l >>= 6;
1859 buf[55] = int_to_itoa64 (l & 0x3f);
1860
1861 l = (digest[44] << 0) | (digest[43] << 8) | (digest[42] << 16);
1862
1863 buf[56] = int_to_itoa64 (l & 0x3f); l >>= 6;
1864 buf[57] = int_to_itoa64 (l & 0x3f); l >>= 6;
1865 buf[58] = int_to_itoa64 (l & 0x3f); l >>= 6;
1866 buf[59] = int_to_itoa64 (l & 0x3f);
1867
1868 l = (digest[47] << 0) | (digest[46] << 8) | (digest[45] << 16);
1869
1870 buf[60] = int_to_itoa64 (l & 0x3f); l >>= 6;
1871 buf[61] = int_to_itoa64 (l & 0x3f); l >>= 6;
1872 buf[62] = int_to_itoa64 (l & 0x3f); l >>= 6;
1873 buf[63] = int_to_itoa64 (l & 0x3f);
1874
1875 l = (digest[50] << 0) | (digest[49] << 8) | (digest[48] << 16);
1876
1877 buf[64] = int_to_itoa64 (l & 0x3f); l >>= 6;
1878 buf[65] = int_to_itoa64 (l & 0x3f); l >>= 6;
1879 buf[66] = int_to_itoa64 (l & 0x3f); l >>= 6;
1880 buf[67] = int_to_itoa64 (l & 0x3f);
1881
1882 l = (digest[53] << 0) | (digest[52] << 8) | (digest[51] << 16);
1883
1884 buf[68] = int_to_itoa64 (l & 0x3f); l >>= 6;
1885 buf[69] = int_to_itoa64 (l & 0x3f); l >>= 6;
1886 buf[70] = int_to_itoa64 (l & 0x3f); l >>= 6;
1887 buf[71] = int_to_itoa64 (l & 0x3f);
1888
1889 l = (digest[56] << 0) | (digest[55] << 8) | (digest[54] << 16);
1890
1891 buf[72] = int_to_itoa64 (l & 0x3f); l >>= 6;
1892 buf[73] = int_to_itoa64 (l & 0x3f); l >>= 6;
1893 buf[74] = int_to_itoa64 (l & 0x3f); l >>= 6;
1894 buf[75] = int_to_itoa64 (l & 0x3f);
1895
1896 l = (digest[59] << 0) | (digest[58] << 8) | (digest[57] << 16);
1897
1898 buf[76] = int_to_itoa64 (l & 0x3f); l >>= 6;
1899 buf[77] = int_to_itoa64 (l & 0x3f); l >>= 6;
1900 buf[78] = int_to_itoa64 (l & 0x3f); l >>= 6;
1901 buf[79] = int_to_itoa64 (l & 0x3f);
1902
1903 l = (digest[62] << 0) | (digest[61] << 8) | (digest[60] << 16);
1904
1905 buf[80] = int_to_itoa64 (l & 0x3f); l >>= 6;
1906 buf[81] = int_to_itoa64 (l & 0x3f); l >>= 6;
1907 buf[82] = int_to_itoa64 (l & 0x3f); l >>= 6;
1908 buf[83] = int_to_itoa64 (l & 0x3f);
1909
1910 l = 0 | 0 | (digest[63] << 16);
1911
1912 buf[84] = int_to_itoa64 (l & 0x3f); l >>= 6;
1913 buf[85] = int_to_itoa64 (l & 0x3f); l >>= 6;
1914 }
1915
1916 void sha256crypt_decode (u8 digest[32], u8 buf[43])
1917 {
1918 int l;
1919
1920 l = itoa64_to_int (buf[ 0]) << 0;
1921 l |= itoa64_to_int (buf[ 1]) << 6;
1922 l |= itoa64_to_int (buf[ 2]) << 12;
1923 l |= itoa64_to_int (buf[ 3]) << 18;
1924
1925 digest[ 0] = (l >> 16) & 0xff;
1926 digest[10] = (l >> 8) & 0xff;
1927 digest[20] = (l >> 0) & 0xff;
1928
1929 l = itoa64_to_int (buf[ 4]) << 0;
1930 l |= itoa64_to_int (buf[ 5]) << 6;
1931 l |= itoa64_to_int (buf[ 6]) << 12;
1932 l |= itoa64_to_int (buf[ 7]) << 18;
1933
1934 digest[21] = (l >> 16) & 0xff;
1935 digest[ 1] = (l >> 8) & 0xff;
1936 digest[11] = (l >> 0) & 0xff;
1937
1938 l = itoa64_to_int (buf[ 8]) << 0;
1939 l |= itoa64_to_int (buf[ 9]) << 6;
1940 l |= itoa64_to_int (buf[10]) << 12;
1941 l |= itoa64_to_int (buf[11]) << 18;
1942
1943 digest[12] = (l >> 16) & 0xff;
1944 digest[22] = (l >> 8) & 0xff;
1945 digest[ 2] = (l >> 0) & 0xff;
1946
1947 l = itoa64_to_int (buf[12]) << 0;
1948 l |= itoa64_to_int (buf[13]) << 6;
1949 l |= itoa64_to_int (buf[14]) << 12;
1950 l |= itoa64_to_int (buf[15]) << 18;
1951
1952 digest[ 3] = (l >> 16) & 0xff;
1953 digest[13] = (l >> 8) & 0xff;
1954 digest[23] = (l >> 0) & 0xff;
1955
1956 l = itoa64_to_int (buf[16]) << 0;
1957 l |= itoa64_to_int (buf[17]) << 6;
1958 l |= itoa64_to_int (buf[18]) << 12;
1959 l |= itoa64_to_int (buf[19]) << 18;
1960
1961 digest[24] = (l >> 16) & 0xff;
1962 digest[ 4] = (l >> 8) & 0xff;
1963 digest[14] = (l >> 0) & 0xff;
1964
1965 l = itoa64_to_int (buf[20]) << 0;
1966 l |= itoa64_to_int (buf[21]) << 6;
1967 l |= itoa64_to_int (buf[22]) << 12;
1968 l |= itoa64_to_int (buf[23]) << 18;
1969
1970 digest[15] = (l >> 16) & 0xff;
1971 digest[25] = (l >> 8) & 0xff;
1972 digest[ 5] = (l >> 0) & 0xff;
1973
1974 l = itoa64_to_int (buf[24]) << 0;
1975 l |= itoa64_to_int (buf[25]) << 6;
1976 l |= itoa64_to_int (buf[26]) << 12;
1977 l |= itoa64_to_int (buf[27]) << 18;
1978
1979 digest[ 6] = (l >> 16) & 0xff;
1980 digest[16] = (l >> 8) & 0xff;
1981 digest[26] = (l >> 0) & 0xff;
1982
1983 l = itoa64_to_int (buf[28]) << 0;
1984 l |= itoa64_to_int (buf[29]) << 6;
1985 l |= itoa64_to_int (buf[30]) << 12;
1986 l |= itoa64_to_int (buf[31]) << 18;
1987
1988 digest[27] = (l >> 16) & 0xff;
1989 digest[ 7] = (l >> 8) & 0xff;
1990 digest[17] = (l >> 0) & 0xff;
1991
1992 l = itoa64_to_int (buf[32]) << 0;
1993 l |= itoa64_to_int (buf[33]) << 6;
1994 l |= itoa64_to_int (buf[34]) << 12;
1995 l |= itoa64_to_int (buf[35]) << 18;
1996
1997 digest[18] = (l >> 16) & 0xff;
1998 digest[28] = (l >> 8) & 0xff;
1999 digest[ 8] = (l >> 0) & 0xff;
2000
2001 l = itoa64_to_int (buf[36]) << 0;
2002 l |= itoa64_to_int (buf[37]) << 6;
2003 l |= itoa64_to_int (buf[38]) << 12;
2004 l |= itoa64_to_int (buf[39]) << 18;
2005
2006 digest[ 9] = (l >> 16) & 0xff;
2007 digest[19] = (l >> 8) & 0xff;
2008 digest[29] = (l >> 0) & 0xff;
2009
2010 l = itoa64_to_int (buf[40]) << 0;
2011 l |= itoa64_to_int (buf[41]) << 6;
2012 l |= itoa64_to_int (buf[42]) << 12;
2013
2014 digest[31] = (l >> 8) & 0xff;
2015 digest[30] = (l >> 0) & 0xff;
2016 }
2017
2018 void sha256crypt_encode (u8 digest[32], u8 buf[43])
2019 {
2020 int l;
2021
2022 l = (digest[ 0] << 16) | (digest[10] << 8) | (digest[20] << 0);
2023
2024 buf[ 0] = int_to_itoa64 (l & 0x3f); l >>= 6;
2025 buf[ 1] = int_to_itoa64 (l & 0x3f); l >>= 6;
2026 buf[ 2] = int_to_itoa64 (l & 0x3f); l >>= 6;
2027 buf[ 3] = int_to_itoa64 (l & 0x3f); l >>= 6;
2028
2029 l = (digest[21] << 16) | (digest[ 1] << 8) | (digest[11] << 0);
2030
2031 buf[ 4] = int_to_itoa64 (l & 0x3f); l >>= 6;
2032 buf[ 5] = int_to_itoa64 (l & 0x3f); l >>= 6;
2033 buf[ 6] = int_to_itoa64 (l & 0x3f); l >>= 6;
2034 buf[ 7] = int_to_itoa64 (l & 0x3f); l >>= 6;
2035
2036 l = (digest[12] << 16) | (digest[22] << 8) | (digest[ 2] << 0);
2037
2038 buf[ 8] = int_to_itoa64 (l & 0x3f); l >>= 6;
2039 buf[ 9] = int_to_itoa64 (l & 0x3f); l >>= 6;
2040 buf[10] = int_to_itoa64 (l & 0x3f); l >>= 6;
2041 buf[11] = int_to_itoa64 (l & 0x3f); l >>= 6;
2042
2043 l = (digest[ 3] << 16) | (digest[13] << 8) | (digest[23] << 0);
2044
2045 buf[12] = int_to_itoa64 (l & 0x3f); l >>= 6;
2046 buf[13] = int_to_itoa64 (l & 0x3f); l >>= 6;
2047 buf[14] = int_to_itoa64 (l & 0x3f); l >>= 6;
2048 buf[15] = int_to_itoa64 (l & 0x3f); l >>= 6;
2049
2050 l = (digest[24] << 16) | (digest[ 4] << 8) | (digest[14] << 0);
2051
2052 buf[16] = int_to_itoa64 (l & 0x3f); l >>= 6;
2053 buf[17] = int_to_itoa64 (l & 0x3f); l >>= 6;
2054 buf[18] = int_to_itoa64 (l & 0x3f); l >>= 6;
2055 buf[19] = int_to_itoa64 (l & 0x3f); l >>= 6;
2056
2057 l = (digest[15] << 16) | (digest[25] << 8) | (digest[ 5] << 0);
2058
2059 buf[20] = int_to_itoa64 (l & 0x3f); l >>= 6;
2060 buf[21] = int_to_itoa64 (l & 0x3f); l >>= 6;
2061 buf[22] = int_to_itoa64 (l & 0x3f); l >>= 6;
2062 buf[23] = int_to_itoa64 (l & 0x3f); l >>= 6;
2063
2064 l = (digest[ 6] << 16) | (digest[16] << 8) | (digest[26] << 0);
2065
2066 buf[24] = int_to_itoa64 (l & 0x3f); l >>= 6;
2067 buf[25] = int_to_itoa64 (l & 0x3f); l >>= 6;
2068 buf[26] = int_to_itoa64 (l & 0x3f); l >>= 6;
2069 buf[27] = int_to_itoa64 (l & 0x3f); l >>= 6;
2070
2071 l = (digest[27] << 16) | (digest[ 7] << 8) | (digest[17] << 0);
2072
2073 buf[28] = int_to_itoa64 (l & 0x3f); l >>= 6;
2074 buf[29] = int_to_itoa64 (l & 0x3f); l >>= 6;
2075 buf[30] = int_to_itoa64 (l & 0x3f); l >>= 6;
2076 buf[31] = int_to_itoa64 (l & 0x3f); l >>= 6;
2077
2078 l = (digest[18] << 16) | (digest[28] << 8) | (digest[ 8] << 0);
2079
2080 buf[32] = int_to_itoa64 (l & 0x3f); l >>= 6;
2081 buf[33] = int_to_itoa64 (l & 0x3f); l >>= 6;
2082 buf[34] = int_to_itoa64 (l & 0x3f); l >>= 6;
2083 buf[35] = int_to_itoa64 (l & 0x3f); l >>= 6;
2084
2085 l = (digest[ 9] << 16) | (digest[19] << 8) | (digest[29] << 0);
2086
2087 buf[36] = int_to_itoa64 (l & 0x3f); l >>= 6;
2088 buf[37] = int_to_itoa64 (l & 0x3f); l >>= 6;
2089 buf[38] = int_to_itoa64 (l & 0x3f); l >>= 6;
2090 buf[39] = int_to_itoa64 (l & 0x3f); l >>= 6;
2091
2092 l = 0 | (digest[31] << 8) | (digest[30] << 0);
2093
2094 buf[40] = int_to_itoa64 (l & 0x3f); l >>= 6;
2095 buf[41] = int_to_itoa64 (l & 0x3f); l >>= 6;
2096 buf[42] = int_to_itoa64 (l & 0x3f);
2097 }
2098
2099 void drupal7_decode (u8 digest[64], u8 buf[44])
2100 {
2101 int l;
2102
2103 l = itoa64_to_int (buf[ 0]) << 0;
2104 l |= itoa64_to_int (buf[ 1]) << 6;
2105 l |= itoa64_to_int (buf[ 2]) << 12;
2106 l |= itoa64_to_int (buf[ 3]) << 18;
2107
2108 digest[ 0] = (l >> 0) & 0xff;
2109 digest[ 1] = (l >> 8) & 0xff;
2110 digest[ 2] = (l >> 16) & 0xff;
2111
2112 l = itoa64_to_int (buf[ 4]) << 0;
2113 l |= itoa64_to_int (buf[ 5]) << 6;
2114 l |= itoa64_to_int (buf[ 6]) << 12;
2115 l |= itoa64_to_int (buf[ 7]) << 18;
2116
2117 digest[ 3] = (l >> 0) & 0xff;
2118 digest[ 4] = (l >> 8) & 0xff;
2119 digest[ 5] = (l >> 16) & 0xff;
2120
2121 l = itoa64_to_int (buf[ 8]) << 0;
2122 l |= itoa64_to_int (buf[ 9]) << 6;
2123 l |= itoa64_to_int (buf[10]) << 12;
2124 l |= itoa64_to_int (buf[11]) << 18;
2125
2126 digest[ 6] = (l >> 0) & 0xff;
2127 digest[ 7] = (l >> 8) & 0xff;
2128 digest[ 8] = (l >> 16) & 0xff;
2129
2130 l = itoa64_to_int (buf[12]) << 0;
2131 l |= itoa64_to_int (buf[13]) << 6;
2132 l |= itoa64_to_int (buf[14]) << 12;
2133 l |= itoa64_to_int (buf[15]) << 18;
2134
2135 digest[ 9] = (l >> 0) & 0xff;
2136 digest[10] = (l >> 8) & 0xff;
2137 digest[11] = (l >> 16) & 0xff;
2138
2139 l = itoa64_to_int (buf[16]) << 0;
2140 l |= itoa64_to_int (buf[17]) << 6;
2141 l |= itoa64_to_int (buf[18]) << 12;
2142 l |= itoa64_to_int (buf[19]) << 18;
2143
2144 digest[12] = (l >> 0) & 0xff;
2145 digest[13] = (l >> 8) & 0xff;
2146 digest[14] = (l >> 16) & 0xff;
2147
2148 l = itoa64_to_int (buf[20]) << 0;
2149 l |= itoa64_to_int (buf[21]) << 6;
2150 l |= itoa64_to_int (buf[22]) << 12;
2151 l |= itoa64_to_int (buf[23]) << 18;
2152
2153 digest[15] = (l >> 0) & 0xff;
2154 digest[16] = (l >> 8) & 0xff;
2155 digest[17] = (l >> 16) & 0xff;
2156
2157 l = itoa64_to_int (buf[24]) << 0;
2158 l |= itoa64_to_int (buf[25]) << 6;
2159 l |= itoa64_to_int (buf[26]) << 12;
2160 l |= itoa64_to_int (buf[27]) << 18;
2161
2162 digest[18] = (l >> 0) & 0xff;
2163 digest[19] = (l >> 8) & 0xff;
2164 digest[20] = (l >> 16) & 0xff;
2165
2166 l = itoa64_to_int (buf[28]) << 0;
2167 l |= itoa64_to_int (buf[29]) << 6;
2168 l |= itoa64_to_int (buf[30]) << 12;
2169 l |= itoa64_to_int (buf[31]) << 18;
2170
2171 digest[21] = (l >> 0) & 0xff;
2172 digest[22] = (l >> 8) & 0xff;
2173 digest[23] = (l >> 16) & 0xff;
2174
2175 l = itoa64_to_int (buf[32]) << 0;
2176 l |= itoa64_to_int (buf[33]) << 6;
2177 l |= itoa64_to_int (buf[34]) << 12;
2178 l |= itoa64_to_int (buf[35]) << 18;
2179
2180 digest[24] = (l >> 0) & 0xff;
2181 digest[25] = (l >> 8) & 0xff;
2182 digest[26] = (l >> 16) & 0xff;
2183
2184 l = itoa64_to_int (buf[36]) << 0;
2185 l |= itoa64_to_int (buf[37]) << 6;
2186 l |= itoa64_to_int (buf[38]) << 12;
2187 l |= itoa64_to_int (buf[39]) << 18;
2188
2189 digest[27] = (l >> 0) & 0xff;
2190 digest[28] = (l >> 8) & 0xff;
2191 digest[29] = (l >> 16) & 0xff;
2192
2193 l = itoa64_to_int (buf[40]) << 0;
2194 l |= itoa64_to_int (buf[41]) << 6;
2195 l |= itoa64_to_int (buf[42]) << 12;
2196 l |= itoa64_to_int (buf[43]) << 18;
2197
2198 digest[30] = (l >> 0) & 0xff;
2199 digest[31] = (l >> 8) & 0xff;
2200 digest[32] = (l >> 16) & 0xff;
2201
2202 digest[33] = 0;
2203 digest[34] = 0;
2204 digest[35] = 0;
2205 digest[36] = 0;
2206 digest[37] = 0;
2207 digest[38] = 0;
2208 digest[39] = 0;
2209 digest[40] = 0;
2210 digest[41] = 0;
2211 digest[42] = 0;
2212 digest[43] = 0;
2213 digest[44] = 0;
2214 digest[45] = 0;
2215 digest[46] = 0;
2216 digest[47] = 0;
2217 digest[48] = 0;
2218 digest[49] = 0;
2219 digest[50] = 0;
2220 digest[51] = 0;
2221 digest[52] = 0;
2222 digest[53] = 0;
2223 digest[54] = 0;
2224 digest[55] = 0;
2225 digest[56] = 0;
2226 digest[57] = 0;
2227 digest[58] = 0;
2228 digest[59] = 0;
2229 digest[60] = 0;
2230 digest[61] = 0;
2231 digest[62] = 0;
2232 digest[63] = 0;
2233 }
2234
2235 void drupal7_encode (u8 digest[64], u8 buf[43])
2236 {
2237 int l;
2238
2239 l = (digest[ 0] << 0) | (digest[ 1] << 8) | (digest[ 2] << 16);
2240
2241 buf[ 0] = int_to_itoa64 (l & 0x3f); l >>= 6;
2242 buf[ 1] = int_to_itoa64 (l & 0x3f); l >>= 6;
2243 buf[ 2] = int_to_itoa64 (l & 0x3f); l >>= 6;
2244 buf[ 3] = int_to_itoa64 (l & 0x3f);
2245
2246 l = (digest[ 3] << 0) | (digest[ 4] << 8) | (digest[ 5] << 16);
2247
2248 buf[ 4] = int_to_itoa64 (l & 0x3f); l >>= 6;
2249 buf[ 5] = int_to_itoa64 (l & 0x3f); l >>= 6;
2250 buf[ 6] = int_to_itoa64 (l & 0x3f); l >>= 6;
2251 buf[ 7] = int_to_itoa64 (l & 0x3f);
2252
2253 l = (digest[ 6] << 0) | (digest[ 7] << 8) | (digest[ 8] << 16);
2254
2255 buf[ 8] = int_to_itoa64 (l & 0x3f); l >>= 6;
2256 buf[ 9] = int_to_itoa64 (l & 0x3f); l >>= 6;
2257 buf[10] = int_to_itoa64 (l & 0x3f); l >>= 6;
2258 buf[11] = int_to_itoa64 (l & 0x3f);
2259
2260 l = (digest[ 9] << 0) | (digest[10] << 8) | (digest[11] << 16);
2261
2262 buf[12] = int_to_itoa64 (l & 0x3f); l >>= 6;
2263 buf[13] = int_to_itoa64 (l & 0x3f); l >>= 6;
2264 buf[14] = int_to_itoa64 (l & 0x3f); l >>= 6;
2265 buf[15] = int_to_itoa64 (l & 0x3f);
2266
2267 l = (digest[12] << 0) | (digest[13] << 8) | (digest[14] << 16);
2268
2269 buf[16] = int_to_itoa64 (l & 0x3f); l >>= 6;
2270 buf[17] = int_to_itoa64 (l & 0x3f); l >>= 6;
2271 buf[18] = int_to_itoa64 (l & 0x3f); l >>= 6;
2272 buf[19] = int_to_itoa64 (l & 0x3f);
2273
2274 l = (digest[15] << 0) | (digest[16] << 8) | (digest[17] << 16);
2275
2276 buf[20] = int_to_itoa64 (l & 0x3f); l >>= 6;
2277 buf[21] = int_to_itoa64 (l & 0x3f); l >>= 6;
2278 buf[22] = int_to_itoa64 (l & 0x3f); l >>= 6;
2279 buf[23] = int_to_itoa64 (l & 0x3f);
2280
2281 l = (digest[18] << 0) | (digest[19] << 8) | (digest[20] << 16);
2282
2283 buf[24] = int_to_itoa64 (l & 0x3f); l >>= 6;
2284 buf[25] = int_to_itoa64 (l & 0x3f); l >>= 6;
2285 buf[26] = int_to_itoa64 (l & 0x3f); l >>= 6;
2286 buf[27] = int_to_itoa64 (l & 0x3f);
2287
2288 l = (digest[21] << 0) | (digest[22] << 8) | (digest[23] << 16);
2289
2290 buf[28] = int_to_itoa64 (l & 0x3f); l >>= 6;
2291 buf[29] = int_to_itoa64 (l & 0x3f); l >>= 6;
2292 buf[30] = int_to_itoa64 (l & 0x3f); l >>= 6;
2293 buf[31] = int_to_itoa64 (l & 0x3f);
2294
2295 l = (digest[24] << 0) | (digest[25] << 8) | (digest[26] << 16);
2296
2297 buf[32] = int_to_itoa64 (l & 0x3f); l >>= 6;
2298 buf[33] = int_to_itoa64 (l & 0x3f); l >>= 6;
2299 buf[34] = int_to_itoa64 (l & 0x3f); l >>= 6;
2300 buf[35] = int_to_itoa64 (l & 0x3f);
2301
2302 l = (digest[27] << 0) | (digest[28] << 8) | (digest[29] << 16);
2303
2304 buf[36] = int_to_itoa64 (l & 0x3f); l >>= 6;
2305 buf[37] = int_to_itoa64 (l & 0x3f); l >>= 6;
2306 buf[38] = int_to_itoa64 (l & 0x3f); l >>= 6;
2307 buf[39] = int_to_itoa64 (l & 0x3f);
2308
2309 l = (digest[30] << 0) | (digest[31] << 8) | (digest[32] << 16);
2310
2311 buf[40] = int_to_itoa64 (l & 0x3f); l >>= 6;
2312 buf[41] = int_to_itoa64 (l & 0x3f); l >>= 6;
2313 buf[42] = int_to_itoa64 (l & 0x3f); l >>= 6;
2314 //buf[43] = int_to_itoa64 (l & 0x3f);
2315 }
2316
2317 /**
2318 * tty
2319 */
2320
2321 #ifdef LINUX
2322 static struct termio savemodes;
2323 static int havemodes = 0;
2324
2325 int tty_break()
2326 {
2327 struct termio modmodes;
2328
2329 if (ioctl (fileno (stdin), TCGETA, &savemodes) < 0) return -1;
2330
2331 havemodes = 1;
2332
2333 modmodes = savemodes;
2334 modmodes.c_lflag &= ~ICANON;
2335 modmodes.c_cc[VMIN] = 1;
2336 modmodes.c_cc[VTIME] = 0;
2337
2338 return ioctl (fileno (stdin), TCSETAW, &modmodes);
2339 }
2340
2341 int tty_getchar()
2342 {
2343 fd_set rfds;
2344
2345 FD_ZERO (&rfds);
2346
2347 FD_SET (fileno (stdin), &rfds);
2348
2349 struct timeval tv;
2350
2351 tv.tv_sec = 1;
2352 tv.tv_usec = 0;
2353
2354 int retval = select (1, &rfds, NULL, NULL, &tv);
2355
2356 if (retval == 0) return 0;
2357 if (retval == -1) return -1;
2358
2359 return getchar();
2360 }
2361
2362 int tty_fix()
2363 {
2364 if (!havemodes) return 0;
2365
2366 return ioctl (fileno (stdin), TCSETAW, &savemodes);
2367 }
2368 #endif
2369
2370 #ifdef OSX
2371 static struct termios savemodes;
2372 static int havemodes = 0;
2373
2374 int tty_break()
2375 {
2376 struct termios modmodes;
2377
2378 if (ioctl (fileno (stdin), TIOCGETA, &savemodes) < 0) return -1;
2379
2380 havemodes = 1;
2381
2382 modmodes = savemodes;
2383 modmodes.c_lflag &= ~ICANON;
2384 modmodes.c_cc[VMIN] = 1;
2385 modmodes.c_cc[VTIME] = 0;
2386
2387 return ioctl (fileno (stdin), TIOCSETAW, &modmodes);
2388 }
2389
2390 int tty_getchar()
2391 {
2392 fd_set rfds;
2393
2394 FD_ZERO (&rfds);
2395
2396 FD_SET (fileno (stdin), &rfds);
2397
2398 struct timeval tv;
2399
2400 tv.tv_sec = 1;
2401 tv.tv_usec = 0;
2402
2403 int retval = select (1, &rfds, NULL, NULL, &tv);
2404
2405 if (retval == 0) return 0;
2406 if (retval == -1) return -1;
2407
2408 return getchar();
2409 }
2410
2411 int tty_fix()
2412 {
2413 if (!havemodes) return 0;
2414
2415 return ioctl (fileno (stdin), TIOCSETAW, &savemodes);
2416 }
2417 #endif
2418
2419 #ifdef WIN
2420 static DWORD saveMode = 0;
2421
2422 int tty_break()
2423 {
2424 HANDLE stdinHandle = GetStdHandle (STD_INPUT_HANDLE);
2425
2426 GetConsoleMode (stdinHandle, &saveMode);
2427 SetConsoleMode (stdinHandle, ENABLE_PROCESSED_INPUT);
2428
2429 return 0;
2430 }
2431
2432 int tty_getchar()
2433 {
2434 HANDLE stdinHandle = GetStdHandle (STD_INPUT_HANDLE);
2435
2436 DWORD rc = WaitForSingleObject (stdinHandle, 1000);
2437
2438 if (rc == WAIT_TIMEOUT) return 0;
2439 if (rc == WAIT_ABANDONED) return -1;
2440 if (rc == WAIT_FAILED) return -1;
2441
2442 // The whole ReadConsoleInput () part is a workaround.
2443 // For some unknown reason, maybe a mingw bug, a random signal
2444 // is sent to stdin which unblocks WaitForSingleObject () and sets rc 0.
2445 // Then it wants to read with getche () a keyboard input
2446 // which has never been made.
2447
2448 INPUT_RECORD buf[100];
2449
2450 DWORD num = 0;
2451
2452 memset (buf, 0, sizeof (buf));
2453
2454 ReadConsoleInput (stdinHandle, buf, 100, &num);
2455
2456 FlushConsoleInputBuffer (stdinHandle);
2457
2458 for (uint i = 0; i < num; i++)
2459 {
2460 if (buf[i].EventType != KEY_EVENT) continue;
2461
2462 KEY_EVENT_RECORD KeyEvent = buf[i].Event.KeyEvent;
2463
2464 if (KeyEvent.bKeyDown != TRUE) continue;
2465
2466 return KeyEvent.uChar.AsciiChar;
2467 }
2468
2469 return 0;
2470 }
2471
2472 int tty_fix()
2473 {
2474 HANDLE stdinHandle = GetStdHandle (STD_INPUT_HANDLE);
2475
2476 SetConsoleMode (stdinHandle, saveMode);
2477
2478 return 0;
2479 }
2480 #endif
2481
2482 /**
2483 * mem alloc
2484 */
2485
2486 #define MSG_ENOMEM "Insufficient memory available"
2487
2488 void *mycalloc (size_t nmemb, size_t size)
2489 {
2490 void *p = calloc (nmemb, size);
2491
2492 if (p == NULL)
2493 {
2494 log_error ("ERROR: %s", MSG_ENOMEM);
2495
2496 exit (-1);
2497 }
2498
2499 return (p);
2500 }
2501
2502 void *mymalloc (size_t size)
2503 {
2504 void *p = malloc (size);
2505
2506 if (p == NULL)
2507 {
2508 log_error ("ERROR: %s", MSG_ENOMEM);
2509
2510 exit (-1);
2511 }
2512
2513 memset (p, 0, size);
2514
2515 return (p);
2516 }
2517
2518 void myfree (void *ptr)
2519 {
2520 if (ptr == NULL) return;
2521
2522 free (ptr);
2523 }
2524
2525 void *myrealloc (void *ptr, size_t oldsz, size_t add)
2526 {
2527 void *p = realloc (ptr, oldsz + add);
2528
2529 if (p == NULL)
2530 {
2531 log_error ("ERROR: %s", MSG_ENOMEM);
2532
2533 exit (-1);
2534 }
2535
2536 memset ((char *) p + oldsz, 0, add);
2537
2538 return (p);
2539 }
2540
2541 char *mystrdup (const char *s)
2542 {
2543 const size_t len = strlen (s);
2544
2545 char *b = (char *) mymalloc (len + 1);
2546
2547 memcpy (b, s, len);
2548
2549 return (b);
2550 }
2551
2552 FILE *logfile_open (char *logfile)
2553 {
2554 FILE *fp = fopen (logfile, "ab");
2555
2556 if (fp == NULL)
2557 {
2558 fp = stdout;
2559 }
2560
2561 return fp;
2562 }
2563
2564 void logfile_close (FILE *fp)
2565 {
2566 if (fp == stdout) return;
2567
2568 fclose (fp);
2569 }
2570
2571 void logfile_append (const char *fmt, ...)
2572 {
2573 if (data.logfile_disable == 1) return;
2574
2575 FILE *fp = logfile_open (data.logfile);
2576
2577 va_list ap;
2578
2579 va_start (ap, fmt);
2580
2581 vfprintf (fp, fmt, ap);
2582
2583 va_end (ap);
2584
2585 fputc ('\n', fp);
2586
2587 fflush (fp);
2588
2589 logfile_close (fp);
2590 }
2591
2592 int logfile_generate_id ()
2593 {
2594 const int n = rand ();
2595
2596 time_t t;
2597
2598 time (&t);
2599
2600 return t + n;
2601 }
2602
2603 char *logfile_generate_topid ()
2604 {
2605 const int id = logfile_generate_id ();
2606
2607 char *topid = (char *) mymalloc (1 + 16 + 1);
2608
2609 snprintf (topid, 1 + 16, "TOP%08x", id);
2610
2611 return topid;
2612 }
2613
2614 char *logfile_generate_subid ()
2615 {
2616 const int id = logfile_generate_id ();
2617
2618 char *subid = (char *) mymalloc (1 + 16 + 1);
2619
2620 snprintf (subid, 1 + 16, "SUB%08x", id);
2621
2622 return subid;
2623 }
2624
2625 /**
2626 * system
2627 */
2628
2629 #if F_SETLKW
2630 void lock_file (FILE *fp)
2631 {
2632 struct flock lock;
2633
2634 memset (&lock, 0, sizeof (struct flock));
2635
2636 lock.l_type = F_WRLCK;
2637 while (fcntl(fileno(fp), F_SETLKW, &lock))
2638 {
2639 if (errno != EINTR)
2640 {
2641 log_error ("ERROR: failed acquiring write lock: %s", strerror (errno));
2642
2643 exit (-1);
2644 }
2645 }
2646 }
2647
2648 void unlock_file (FILE *fp)
2649 {
2650 struct flock lock;
2651
2652 memset (&lock, 0, sizeof (struct flock));
2653
2654 lock.l_type = F_UNLCK;
2655 fcntl(fileno(fp), F_SETLK, &lock);
2656 }
2657 #endif // F_SETLKW
2658
2659 #ifdef _WIN
2660 void fsync (int fd)
2661 {
2662 HANDLE h = (HANDLE) _get_osfhandle (fd);
2663
2664 FlushFileBuffers (h);
2665 }
2666 #endif
2667
2668 /**
2669 * thermal
2670 */
2671
2672 #ifdef HAVE_HWMON
2673 #if defined(_WIN) && defined(HAVE_NVAPI)
2674 int hm_get_adapter_index_nv (HM_ADAPTER_NV nvGPUHandle[DEVICES_MAX])
2675 {
2676 NvU32 pGpuCount;
2677
2678 if (hm_NvAPI_EnumPhysicalGPUs (data.hm_nv, nvGPUHandle, &pGpuCount) != NVAPI_OK) return (0);
2679
2680 if (pGpuCount == 0)
2681 {
2682 log_info ("WARN: No NvAPI adapters found");
2683
2684 return (0);
2685 }
2686
2687 return (pGpuCount);
2688 }
2689 #endif // _WIN && HAVE_NVAPI
2690
2691 #if defined(LINUX) && defined(HAVE_NVML)
2692 int hm_get_adapter_index_nv (HM_ADAPTER_NV nvGPUHandle[DEVICES_MAX])
2693 {
2694 int pGpuCount = 0;
2695
2696 for (uint i = 0; i < DEVICES_MAX; i++)
2697 {
2698 if (hm_NVML_nvmlDeviceGetHandleByIndex (data.hm_nv, 1, i, &nvGPUHandle[i]) != NVML_SUCCESS) break;
2699
2700 // can be used to determine if the device by index matches the cuda device by index
2701 // char name[100]; memset (name, 0, sizeof (name));
2702 // hm_NVML_nvmlDeviceGetName (data.hm_nv, nvGPUHandle[i], name, sizeof (name) - 1);
2703
2704 pGpuCount++;
2705 }
2706
2707 if (pGpuCount == 0)
2708 {
2709 log_info ("WARN: No NVML adapters found");
2710
2711 return (0);
2712 }
2713
2714 return (pGpuCount);
2715 }
2716 #endif // LINUX && HAVE_NVML
2717
2718 #ifdef HAVE_ADL
2719 int get_adapters_num_amd (void *adl, int *iNumberAdapters)
2720 {
2721 if (hm_ADL_Adapter_NumberOfAdapters_Get ((ADL_PTR *) adl, iNumberAdapters) != ADL_OK) return -1;
2722
2723 if (iNumberAdapters == 0)
2724 {
2725 log_info ("WARN: No ADL adapters found.");
2726
2727 return -1;
2728 }
2729
2730 return 0;
2731 }
2732
2733 /*
2734 int hm_show_performance_level (HM_LIB hm_dll, int iAdapterIndex)
2735 {
2736 ADLODPerformanceLevels *lpOdPerformanceLevels = NULL;
2737 ADLODParameters lpOdParameters;
2738
2739 lpOdParameters.iSize = sizeof (ADLODParameters);
2740 size_t plevels_size = 0;
2741
2742 if (hm_ADL_Overdrive_ODParameters_Get (hm_dll, iAdapterIndex, &lpOdParameters) != ADL_OK) return -1;
2743
2744 log_info ("[DEBUG] %s, adapter %d performance level (%d) : %s %s",
2745 __func__, iAdapterIndex,
2746 lpOdParameters.iNumberOfPerformanceLevels,
2747 (lpOdParameters.iActivityReportingSupported) ? "activity reporting" : "",
2748 (lpOdParameters.iDiscretePerformanceLevels) ? "discrete performance levels" : "performance ranges");
2749
2750 plevels_size = sizeof (ADLODPerformanceLevels) + sizeof (ADLODPerformanceLevel) * (lpOdParameters.iNumberOfPerformanceLevels - 1);
2751
2752 lpOdPerformanceLevels = (ADLODPerformanceLevels *) mymalloc (plevels_size);
2753
2754 lpOdPerformanceLevels->iSize = sizeof (ADLODPerformanceLevels) + sizeof (ADLODPerformanceLevel) * (lpOdParameters.iNumberOfPerformanceLevels - 1);
2755
2756 if (hm_ADL_Overdrive_ODPerformanceLevels_Get (hm_dll, iAdapterIndex, 0, lpOdPerformanceLevels) != ADL_OK) return -1;
2757
2758 for (int j = 0; j < lpOdParameters.iNumberOfPerformanceLevels; j++)
2759 log_info ("[DEBUG] %s, adapter %d, level %d : engine %d, memory %d, voltage: %d",
2760 __func__, iAdapterIndex, j,
2761 lpOdPerformanceLevels->aLevels[j].iEngineClock / 100, lpOdPerformanceLevels->aLevels[j].iMemoryClock / 100, lpOdPerformanceLevels->aLevels[j].iVddc);
2762
2763 myfree (lpOdPerformanceLevels);
2764
2765 return 0;
2766 }
2767 */
2768
2769 LPAdapterInfo hm_get_adapter_info_amd (void *adl, int iNumberAdapters)
2770 {
2771 size_t AdapterInfoSize = iNumberAdapters * sizeof (AdapterInfo);
2772
2773 LPAdapterInfo lpAdapterInfo = (LPAdapterInfo) mymalloc (AdapterInfoSize);
2774
2775 if (hm_ADL_Adapter_AdapterInfo_Get ((ADL_PTR *) adl, lpAdapterInfo, AdapterInfoSize) != ADL_OK) return NULL;
2776
2777 return lpAdapterInfo;
2778 }
2779
2780 /*
2781 //
2782 // does not help at all, since AMD does not assign different bus id, device id when we have multi GPU setups
2783 //
2784
2785 int hm_get_opencl_device_index (hm_attrs_t *hm_device, uint num_adl_adapters, int bus_num, int dev_num)
2786 {
2787 u32 idx = -1;
2788
2789 for (uint i = 0; i < num_adl_adapters; i++)
2790 {
2791 int opencl_bus_num = hm_device[i].busid;
2792 int opencl_dev_num = hm_device[i].devid;
2793
2794 if ((opencl_bus_num == bus_num) && (opencl_dev_num == dev_num))
2795 {
2796 idx = i;
2797
2798 break;
2799 }
2800 }
2801
2802 if (idx >= DEVICES_MAX) return -1;
2803
2804 return idx;
2805 }
2806
2807 void hm_get_opencl_busid_devid (hm_attrs_t *hm_device, uint opencl_num_devices, cl_device_id *devices)
2808 {
2809 for (uint i = 0; i < opencl_num_devices; i++)
2810 {
2811 cl_device_topology_amd device_topology;
2812
2813 hc_clGetDeviceInfo (devices[i], CL_DEVICE_TOPOLOGY_AMD, sizeof (device_topology), &device_topology, NULL);
2814
2815 hm_device[i].busid = device_topology.pcie.bus;
2816 hm_device[i].devid = device_topology.pcie.device;
2817 }
2818 }
2819 */
2820
2821 void hm_sort_adl_adapters_by_busid_devid (u32 *valid_adl_device_list, int num_adl_adapters, LPAdapterInfo lpAdapterInfo)
2822 {
2823 // basically bubble sort
2824
2825 for (int i = 0; i < num_adl_adapters; i++)
2826 {
2827 for (int j = 0; j < num_adl_adapters - 1; j++)
2828 {
2829 // get info of adapter [x]
2830
2831 u32 adapter_index_x = valid_adl_device_list[j];
2832 AdapterInfo info_x = lpAdapterInfo[adapter_index_x];
2833
2834 u32 bus_num_x = info_x.iBusNumber;
2835 u32 dev_num_x = info_x.iDeviceNumber;
2836
2837 // get info of adapter [y]
2838
2839 u32 adapter_index_y = valid_adl_device_list[j + 1];
2840 AdapterInfo info_y = lpAdapterInfo[adapter_index_y];
2841
2842 u32 bus_num_y = info_y.iBusNumber;
2843 u32 dev_num_y = info_y.iDeviceNumber;
2844
2845 uint need_swap = 0;
2846
2847 if (bus_num_y < bus_num_x)
2848 {
2849 need_swap = 1;
2850 }
2851 else if (bus_num_y == bus_num_x)
2852 {
2853 if (dev_num_y < dev_num_x)
2854 {
2855 need_swap = 1;
2856 }
2857 }
2858
2859 if (need_swap == 1)
2860 {
2861 u32 temp = valid_adl_device_list[j + 1];
2862
2863 valid_adl_device_list[j + 1] = valid_adl_device_list[j];
2864 valid_adl_device_list[j + 0] = temp;
2865 }
2866 }
2867 }
2868 }
2869
2870 u32 *hm_get_list_valid_adl_adapters (int iNumberAdapters, int *num_adl_adapters, LPAdapterInfo lpAdapterInfo)
2871 {
2872 *num_adl_adapters = 0;
2873
2874 u32 *adl_adapters = NULL;
2875
2876 int *bus_numbers = NULL;
2877 int *device_numbers = NULL;
2878
2879 for (int i = 0; i < iNumberAdapters; i++)
2880 {
2881 AdapterInfo info = lpAdapterInfo[i];
2882
2883 if (strlen (info.strUDID) < 1) continue;
2884
2885 #ifdef WIN
2886 if (info.iVendorID != 1002) continue;
2887 #else
2888 if (info.iVendorID != 0x1002) continue;
2889 #endif
2890
2891 if (info.iBusNumber < 0) continue;
2892 if (info.iDeviceNumber < 0) continue;
2893
2894 int found = 0;
2895
2896 for (int pos = 0; pos < *num_adl_adapters; pos++)
2897 {
2898 if ((bus_numbers[pos] == info.iBusNumber) && (device_numbers[pos] == info.iDeviceNumber))
2899 {
2900 found = 1;
2901 break;
2902 }
2903 }
2904
2905 if (found) continue;
2906
2907 // add it to the list
2908
2909 adl_adapters = (u32 *) myrealloc (adl_adapters, (*num_adl_adapters) * sizeof (int), sizeof (int));
2910
2911 adl_adapters[*num_adl_adapters] = i;
2912
2913 // rest is just bookkeeping
2914
2915 bus_numbers = (int*) myrealloc (bus_numbers, (*num_adl_adapters) * sizeof (int), sizeof (int));
2916 device_numbers = (int*) myrealloc (device_numbers, (*num_adl_adapters) * sizeof (int), sizeof (int));
2917
2918 bus_numbers[*num_adl_adapters] = info.iBusNumber;
2919 device_numbers[*num_adl_adapters] = info.iDeviceNumber;
2920
2921 (*num_adl_adapters)++;
2922 }
2923
2924 myfree (bus_numbers);
2925 myfree (device_numbers);
2926
2927 // sort the list by increasing bus id, device id number
2928
2929 hm_sort_adl_adapters_by_busid_devid (adl_adapters, *num_adl_adapters, lpAdapterInfo);
2930
2931 return adl_adapters;
2932 }
2933
2934 int hm_check_fanspeed_control (void *adl, hm_attrs_t *hm_device, u32 *valid_adl_device_list, int num_adl_adapters, LPAdapterInfo lpAdapterInfo)
2935 {
2936 // loop through all valid devices
2937
2938 for (int i = 0; i < num_adl_adapters; i++)
2939 {
2940 u32 adapter_index = valid_adl_device_list[i];
2941
2942 // get AdapterInfo
2943
2944 AdapterInfo info = lpAdapterInfo[adapter_index];
2945
2946 // unfortunately this doesn't work since bus id and dev id are not unique
2947 // int opencl_device_index = hm_get_opencl_device_index (hm_device, num_adl_adapters, info.iBusNumber, info.iDeviceNumber);
2948 // if (opencl_device_index == -1) continue;
2949
2950 int opencl_device_index = i;
2951
2952 // if (hm_show_performance_level (adl, info.iAdapterIndex) != 0) return -1;
2953
2954 // get fanspeed info
2955
2956 if (hm_device[opencl_device_index].od_version == 5)
2957 {
2958 ADLFanSpeedInfo FanSpeedInfo;
2959
2960 memset (&FanSpeedInfo, 0, sizeof (ADLFanSpeedInfo));
2961
2962 FanSpeedInfo.iSize = sizeof (ADLFanSpeedInfo);
2963
2964 if (hm_ADL_Overdrive5_FanSpeedInfo_Get (adl, info.iAdapterIndex, 0, &FanSpeedInfo) != ADL_OK) return -1;
2965
2966 // check read and write capability in fanspeedinfo
2967
2968 if ((FanSpeedInfo.iFlags & ADL_DL_FANCTRL_SUPPORTS_PERCENT_READ) &&
2969 (FanSpeedInfo.iFlags & ADL_DL_FANCTRL_SUPPORTS_PERCENT_WRITE))
2970 {
2971 hm_device[opencl_device_index].fan_supported = 1;
2972 }
2973 else
2974 {
2975 hm_device[opencl_device_index].fan_supported = 0;
2976 }
2977 }
2978 else // od_version == 6
2979 {
2980 ADLOD6FanSpeedInfo faninfo;
2981
2982 memset (&faninfo, 0, sizeof (faninfo));
2983
2984 if (hm_ADL_Overdrive6_FanSpeed_Get (adl, info.iAdapterIndex, &faninfo) != ADL_OK) return -1;
2985
2986 // check read capability in fanspeedinfo
2987
2988 if (faninfo.iSpeedType & ADL_OD6_FANSPEED_TYPE_PERCENT)
2989 {
2990 hm_device[opencl_device_index].fan_supported = 1;
2991 }
2992 else
2993 {
2994 hm_device[opencl_device_index].fan_supported = 0;
2995 }
2996 }
2997 }
2998
2999 return 0;
3000 }
3001
3002 int hm_get_overdrive_version (void *adl, hm_attrs_t *hm_device, u32 *valid_adl_device_list, int num_adl_adapters, LPAdapterInfo lpAdapterInfo)
3003 {
3004 for (int i = 0; i < num_adl_adapters; i++)
3005 {
3006 u32 adapter_index = valid_adl_device_list[i];
3007
3008 // get AdapterInfo
3009
3010 AdapterInfo info = lpAdapterInfo[adapter_index];
3011
3012 // get overdrive version
3013
3014 int od_supported = 0;
3015 int od_enabled = 0;
3016 int od_version = 0;
3017
3018 if (hm_ADL_Overdrive_Caps (adl, info.iAdapterIndex, &od_supported, &od_enabled, &od_version) != ADL_OK) return -1;
3019
3020 // store the overdrive version in hm_device
3021
3022 // unfortunately this doesn't work since bus id and dev id are not unique
3023 // int opencl_device_index = hm_get_opencl_device_index (hm_device, num_adl_adapters, info.iBusNumber, info.iDeviceNumber);
3024 // if (opencl_device_index == -1) continue;
3025
3026 int opencl_device_index = i;
3027
3028 hm_device[opencl_device_index].od_version = od_version;
3029 }
3030
3031 return 0;
3032 }
3033
3034 int hm_get_adapter_index_amd (hm_attrs_t *hm_device, u32 *valid_adl_device_list, int num_adl_adapters, LPAdapterInfo lpAdapterInfo)
3035 {
3036 for (int i = 0; i < num_adl_adapters; i++)
3037 {
3038 u32 adapter_index = valid_adl_device_list[i];
3039
3040 // get AdapterInfo
3041
3042 AdapterInfo info = lpAdapterInfo[adapter_index];
3043
3044 // store the iAdapterIndex in hm_device
3045
3046 // unfortunately this doesn't work since bus id and dev id are not unique
3047 // int opencl_device_index = hm_get_opencl_device_index (hm_device, num_adl_adapters, info.iBusNumber, info.iDeviceNumber);
3048 // if (opencl_device_index == -1) continue;
3049
3050 int opencl_device_index = i;
3051
3052 hm_device[opencl_device_index].adapter_index.amd = info.iAdapterIndex;
3053 }
3054
3055 return num_adl_adapters;
3056 }
3057 #endif // HAVE_ADL
3058
3059 int hm_get_temperature_with_device_id (const uint device_id)
3060 {
3061 if ((data.devices_param[device_id].device_type & CL_DEVICE_TYPE_GPU) == 0) return -1;
3062
3063 #ifdef HAVE_ADL
3064 if (data.devices_param[device_id].vendor_id == VENDOR_ID_AMD)
3065 {
3066 if (data.hm_amd)
3067 {
3068 if (data.hm_device[device_id].od_version == 5)
3069 {
3070 ADLTemperature Temperature;
3071
3072 Temperature.iSize = sizeof (ADLTemperature);
3073
3074 if (hm_ADL_Overdrive5_Temperature_Get (data.hm_amd, data.hm_device[device_id].adapter_index.amd, 0, &Temperature) != ADL_OK) return -1;
3075
3076 return Temperature.iTemperature / 1000;
3077 }
3078 else if (data.hm_device[device_id].od_version == 6)
3079 {
3080 int Temperature = 0;
3081
3082 if (hm_ADL_Overdrive6_Temperature_Get (data.hm_amd, data.hm_device[device_id].adapter_index.amd, &Temperature) != ADL_OK) return -1;
3083
3084 return Temperature / 1000;
3085 }
3086 }
3087 }
3088 #endif
3089
3090 #if defined(HAVE_NVML) || defined(HAVE_NVAPI)
3091 if (data.devices_param[device_id].vendor_id == VENDOR_ID_NV)
3092 {
3093 #if defined(LINUX) && defined(HAVE_NVML)
3094 int temperature = 0;
3095
3096 hm_NVML_nvmlDeviceGetTemperature (data.hm_nv, data.hm_device[device_id].adapter_index.nv, NVML_TEMPERATURE_GPU, (uint *) &temperature);
3097
3098 return temperature;
3099 #endif
3100
3101 #if defined(WIN) && defined(HAVE_NVAPI)
3102 NV_GPU_THERMAL_SETTINGS pThermalSettings;
3103
3104 pThermalSettings.version = NV_GPU_THERMAL_SETTINGS_VER;
3105 pThermalSettings.count = NVAPI_MAX_THERMAL_SENSORS_PER_GPU;
3106 pThermalSettings.sensor[0].controller = NVAPI_THERMAL_CONTROLLER_UNKNOWN;
3107 pThermalSettings.sensor[0].target = NVAPI_THERMAL_TARGET_GPU;
3108
3109 if (hm_NvAPI_GPU_GetThermalSettings (data.hm_nv, data.hm_device[device_id].adapter_index.nv, 0, &pThermalSettings) != NVAPI_OK) return -1;
3110
3111 return pThermalSettings.sensor[0].currentTemp;
3112 #endif // WIN && HAVE_NVAPI
3113 }
3114 #endif // HAVE_NVML || HAVE_NVAPI
3115
3116 return -1;
3117 }
3118
3119 int hm_get_fanspeed_with_device_id (const uint device_id)
3120 {
3121 // we shouldn't really need this extra CL_DEVICE_TYPE_GPU check, because fan_supported should not be set w/ CPUs
3122 if ((data.devices_param[device_id].device_type & CL_DEVICE_TYPE_GPU) == 0) return -1;
3123
3124 if (data.hm_device[device_id].fan_supported == 1)
3125 {
3126 #ifdef HAVE_ADL
3127 if (data.devices_param[device_id].vendor_id == VENDOR_ID_AMD)
3128 {
3129 if (data.hm_amd)
3130 {
3131 if (data.hm_device[device_id].od_version == 5)
3132 {
3133 ADLFanSpeedValue lpFanSpeedValue;
3134
3135 memset (&lpFanSpeedValue, 0, sizeof (lpFanSpeedValue));
3136
3137 lpFanSpeedValue.iSize = sizeof (lpFanSpeedValue);
3138 lpFanSpeedValue.iSpeedType = ADL_DL_FANCTRL_SPEED_TYPE_PERCENT;
3139 lpFanSpeedValue.iFlags = ADL_DL_FANCTRL_FLAG_USER_DEFINED_SPEED;
3140
3141 if (hm_ADL_Overdrive5_FanSpeed_Get (data.hm_amd, data.hm_device[device_id].adapter_index.amd, 0, &lpFanSpeedValue) != ADL_OK) return -1;
3142
3143 return lpFanSpeedValue.iFanSpeed;
3144 }
3145 else // od_version == 6
3146 {
3147 ADLOD6FanSpeedInfo faninfo;
3148
3149 memset (&faninfo, 0, sizeof (faninfo));
3150
3151 if (hm_ADL_Overdrive6_FanSpeed_Get (data.hm_amd, data.hm_device[device_id].adapter_index.amd, &faninfo) != ADL_OK) return -1;
3152
3153 return faninfo.iFanSpeedPercent;
3154 }
3155 }
3156 }
3157 #endif // HAVE_ADL
3158
3159 #if defined(HAVE_NVML) || defined(HAVE_NVAPI)
3160 if (data.devices_param[device_id].vendor_id == VENDOR_ID_NV)
3161 {
3162 #if defined(LINUX) && defined(HAVE_NVML)
3163 int speed = 0;
3164
3165 hm_NVML_nvmlDeviceGetFanSpeed (data.hm_nv, 1, data.hm_device[device_id].adapter_index.nv, (uint *) &speed);
3166
3167 return speed;
3168 #endif
3169
3170 #if defined(WIN) && defined(HAVE_NVAPI)
3171
3172 NV_GPU_COOLER_SETTINGS pCoolerSettings;
3173
3174 pCoolerSettings.Version = GPU_COOLER_SETTINGS_VER | sizeof (NV_GPU_COOLER_SETTINGS);
3175
3176 hm_NvAPI_GPU_GetCoolerSettings (data.hm_nv, data.hm_device[device_id].adapter_index.nv, 0, &pCoolerSettings);
3177
3178 return pCoolerSettings.Cooler[0].CurrentLevel;
3179 #endif
3180 }
3181 #endif // HAVE_NVML || HAVE_NVAPI
3182 }
3183
3184 return -1;
3185 }
3186
3187 int hm_get_utilization_with_device_id (const uint device_id)
3188 {
3189 if ((data.devices_param[device_id].device_type & CL_DEVICE_TYPE_GPU) == 0) return -1;
3190
3191 #ifdef HAVE_ADL
3192 if (data.devices_param[device_id].vendor_id == VENDOR_ID_AMD)
3193 {
3194 if (data.hm_amd)
3195 {
3196 ADLPMActivity PMActivity;
3197
3198 PMActivity.iSize = sizeof (ADLPMActivity);
3199
3200 if (hm_ADL_Overdrive_CurrentActivity_Get (data.hm_amd, data.hm_device[device_id].adapter_index.amd, &PMActivity) != ADL_OK) return -1;
3201
3202 return PMActivity.iActivityPercent;
3203 }
3204 }
3205 #endif // HAVE_ADL
3206
3207 #if defined(HAVE_NVML) || defined(HAVE_NVAPI)
3208 if (data.devices_param[device_id].vendor_id == VENDOR_ID_NV)
3209 {
3210 #if defined(LINUX) && defined(HAVE_NVML)
3211 nvmlUtilization_t utilization;
3212
3213 hm_NVML_nvmlDeviceGetUtilizationRates (data.hm_nv, data.hm_device[device_id].adapter_index.nv, &utilization);
3214
3215 return utilization.gpu;
3216 #endif
3217
3218 #if defined(WIN) && defined(HAVE_NVAPI)
3219 NV_GPU_DYNAMIC_PSTATES_INFO_EX pDynamicPstatesInfoEx;
3220
3221 pDynamicPstatesInfoEx.version = NV_GPU_DYNAMIC_PSTATES_INFO_EX_VER;
3222
3223 if (hm_NvAPI_GPU_GetDynamicPstatesInfoEx (data.hm_nv, data.hm_device[device_id].adapter_index.nv, &pDynamicPstatesInfoEx) != NVAPI_OK) return -1;
3224
3225 return pDynamicPstatesInfoEx.utilization[0].percentage;
3226 #endif
3227 }
3228 #endif // HAVE_NVML || HAVE_NVAPI
3229
3230 return -1;
3231 }
3232
3233 #ifdef HAVE_ADL
3234 int hm_set_fanspeed_with_device_id_amd (const uint device_id, const int fanspeed)
3235 {
3236 if (data.hm_device[device_id].fan_supported == 1)
3237 {
3238 if (data.hm_amd)
3239 {
3240 if (data.hm_device[device_id].od_version == 5)
3241 {
3242 ADLFanSpeedValue lpFanSpeedValue;
3243
3244 memset (&lpFanSpeedValue, 0, sizeof (lpFanSpeedValue));
3245
3246 lpFanSpeedValue.iSize = sizeof (lpFanSpeedValue);
3247 lpFanSpeedValue.iSpeedType = ADL_DL_FANCTRL_SPEED_TYPE_PERCENT;
3248 lpFanSpeedValue.iFlags = ADL_DL_FANCTRL_FLAG_USER_DEFINED_SPEED;
3249 lpFanSpeedValue.iFanSpeed = fanspeed;
3250
3251 if (hm_ADL_Overdrive5_FanSpeed_Set (data.hm_amd, data.hm_device[device_id].adapter_index.amd, 0, &lpFanSpeedValue) != ADL_OK) return -1;
3252
3253 return 0;
3254 }
3255 else // od_version == 6
3256 {
3257 ADLOD6FanSpeedValue fan_speed_value;
3258
3259 memset (&fan_speed_value, 0, sizeof (fan_speed_value));
3260
3261 fan_speed_value.iSpeedType = ADL_OD6_FANSPEED_TYPE_PERCENT;
3262 fan_speed_value.iFanSpeed = fanspeed;
3263
3264 if (hm_ADL_Overdrive6_FanSpeed_Set (data.hm_amd, data.hm_device[device_id].adapter_index.amd, &fan_speed_value) != ADL_OK) return -1;
3265
3266 return 0;
3267 }
3268 }
3269 }
3270
3271 return -1;
3272 }
3273 #endif
3274
3275 // helper function for status display
3276
3277 void hm_device_val_to_str (char *target_buf, int max_buf_size, char *suffix, int value)
3278 {
3279 #define VALUE_NOT_AVAILABLE "N/A"
3280
3281 if (value == -1)
3282 {
3283 snprintf (target_buf, max_buf_size, VALUE_NOT_AVAILABLE);
3284 }
3285 else
3286 {
3287 snprintf (target_buf, max_buf_size, "%2d%s", value, suffix);
3288 }
3289 }
3290 #endif // HAVE_HWMON
3291
3292 /**
3293 * maskprocessor
3294 */
3295
3296 void mp_css_to_uniq_tbl (uint css_cnt, cs_t *css, uint uniq_tbls[SP_PW_MAX][CHARSIZ])
3297 {
3298 /* generates a lookup table where key is the char itself for fastest possible lookup performance */
3299
3300 if (css_cnt > SP_PW_MAX)
3301 {
3302 log_error ("ERROR: mask length is too long");
3303
3304 exit (-1);
3305 }
3306
3307 for (uint css_pos = 0; css_pos < css_cnt; css_pos++)
3308 {
3309 uint *uniq_tbl = uniq_tbls[css_pos];
3310
3311 uint *cs_buf = css[css_pos].cs_buf;
3312 uint cs_len = css[css_pos].cs_len;
3313
3314 for (uint cs_pos = 0; cs_pos < cs_len; cs_pos++)
3315 {
3316 uint c = cs_buf[cs_pos] & 0xff;
3317
3318 uniq_tbl[c] = 1;
3319 }
3320 }
3321 }
3322
3323 void mp_add_cs_buf (uint *in_buf, size_t in_len, cs_t *css, int css_cnt)
3324 {
3325 cs_t *cs = &css[css_cnt];
3326
3327 size_t css_uniq_sz = CHARSIZ * sizeof (uint);
3328
3329 uint *css_uniq = (uint *) mymalloc (css_uniq_sz);
3330
3331 size_t i;
3332
3333 for (i = 0; i < cs->cs_len; i++)
3334 {
3335 const uint u = cs->cs_buf[i];
3336
3337 css_uniq[u] = 1;
3338 }
3339
3340 for (i = 0; i < in_len; i++)
3341 {
3342 uint u = in_buf[i] & 0xff;
3343
3344 if (data.opts_type & OPTS_TYPE_PT_UPPER) u = toupper (u);
3345
3346 if (css_uniq[u] == 1) continue;
3347
3348 css_uniq[u] = 1;
3349
3350 cs->cs_buf[cs->cs_len] = u;
3351
3352 cs->cs_len++;
3353 }
3354
3355 myfree (css_uniq);
3356 }
3357
3358 void mp_expand (char *in_buf, size_t in_len, cs_t *mp_sys, cs_t *mp_usr, int mp_usr_offset, int interpret)
3359 {
3360 size_t in_pos;
3361
3362 for (in_pos = 0; in_pos < in_len; in_pos++)
3363 {
3364 uint p0 = in_buf[in_pos] & 0xff;
3365
3366 if (interpret == 1 && p0 == '?')
3367 {
3368 in_pos++;
3369
3370 if (in_pos == in_len) break;
3371
3372 uint p1 = in_buf[in_pos] & 0xff;
3373
3374 switch (p1)
3375 {
3376 case 'l': mp_add_cs_buf (mp_sys[0].cs_buf, mp_sys[0].cs_len, mp_usr, mp_usr_offset);
3377 break;
3378 case 'u': mp_add_cs_buf (mp_sys[1].cs_buf, mp_sys[1].cs_len, mp_usr, mp_usr_offset);
3379 break;
3380 case 'd': mp_add_cs_buf (mp_sys[2].cs_buf, mp_sys[2].cs_len, mp_usr, mp_usr_offset);
3381 break;
3382 case 's': mp_add_cs_buf (mp_sys[3].cs_buf, mp_sys[3].cs_len, mp_usr, mp_usr_offset);
3383 break;
3384 case 'a': mp_add_cs_buf (mp_sys[4].cs_buf, mp_sys[4].cs_len, mp_usr, mp_usr_offset);
3385 break;
3386 case 'b': mp_add_cs_buf (mp_sys[5].cs_buf, mp_sys[5].cs_len, mp_usr, mp_usr_offset);
3387 break;
3388 case '1': if (mp_usr[0].cs_len == 0) { log_error ("ERROR: Custom-charset 1 is undefined\n"); exit (-1); }
3389 mp_add_cs_buf (mp_usr[0].cs_buf, mp_usr[0].cs_len, mp_usr, mp_usr_offset);
3390 break;
3391 case '2': if (mp_usr[1].cs_len == 0) { log_error ("ERROR: Custom-charset 2 is undefined\n"); exit (-1); }
3392 mp_add_cs_buf (mp_usr[1].cs_buf, mp_usr[1].cs_len, mp_usr, mp_usr_offset);
3393 break;
3394 case '3': if (mp_usr[2].cs_len == 0) { log_error ("ERROR: Custom-charset 3 is undefined\n"); exit (-1); }
3395 mp_add_cs_buf (mp_usr[2].cs_buf, mp_usr[2].cs_len, mp_usr, mp_usr_offset);
3396 break;
3397 case '4': if (mp_usr[3].cs_len == 0) { log_error ("ERROR: Custom-charset 4 is undefined\n"); exit (-1); }
3398 mp_add_cs_buf (mp_usr[3].cs_buf, mp_usr[3].cs_len, mp_usr, mp_usr_offset);
3399 break;
3400 case '?': mp_add_cs_buf (&p0, 1, mp_usr, mp_usr_offset);
3401 break;
3402 default: log_error ("Syntax error: %s", in_buf);
3403 exit (-1);
3404 }
3405 }
3406 else
3407 {
3408 if (data.hex_charset)
3409 {
3410 in_pos++;
3411
3412 if (in_pos == in_len)
3413 {
3414 log_error ("ERROR: the hex-charset option always expects couples of exactly 2 hexadecimal chars, failed mask: %s", in_buf);
3415
3416 exit (-1);
3417 }
3418
3419 uint p1 = in_buf[in_pos] & 0xff;
3420
3421 if ((is_valid_hex_char (p0) == 0) || (is_valid_hex_char (p1) == 0))
3422 {
3423 log_error ("ERROR: invalid hex character detected in mask %s", in_buf);
3424
3425 exit (-1);
3426 }
3427
3428 uint chr = 0;
3429
3430 chr = hex_convert (p1) << 0;
3431 chr |= hex_convert (p0) << 4;
3432
3433 mp_add_cs_buf (&chr, 1, mp_usr, mp_usr_offset);
3434 }
3435 else
3436 {
3437 uint chr = p0;
3438
3439 mp_add_cs_buf (&chr, 1, mp_usr, mp_usr_offset);
3440 }
3441 }
3442 }
3443 }
3444
3445 u64 mp_get_sum (uint css_cnt, cs_t *css)
3446 {
3447 u64 sum = 1;
3448
3449 for (uint css_pos = 0; css_pos < css_cnt; css_pos++)
3450 {
3451 sum *= css[css_pos].cs_len;
3452 }
3453
3454 return (sum);
3455 }
3456
3457 cs_t *mp_gen_css (char *mask_buf, size_t mask_len, cs_t *mp_sys, cs_t *mp_usr, uint *css_cnt)
3458 {
3459 cs_t *css = (cs_t *) mycalloc (256, sizeof (cs_t));
3460
3461 uint mask_pos;
3462 uint css_pos;
3463
3464 for (mask_pos = 0, css_pos = 0; mask_pos < mask_len; mask_pos++, css_pos++)
3465 {
3466 char p0 = mask_buf[mask_pos];
3467
3468 if (p0 == '?')
3469 {
3470 mask_pos++;
3471
3472 if (mask_pos == mask_len) break;
3473
3474 char p1 = mask_buf[mask_pos];
3475
3476 uint chr = p1;
3477
3478 switch (p1)
3479 {
3480 case 'l': mp_add_cs_buf (mp_sys[0].cs_buf, mp_sys[0].cs_len, css, css_pos);
3481 break;
3482 case 'u': mp_add_cs_buf (mp_sys[1].cs_buf, mp_sys[1].cs_len, css, css_pos);
3483 break;
3484 case 'd': mp_add_cs_buf (mp_sys[2].cs_buf, mp_sys[2].cs_len, css, css_pos);
3485 break;
3486 case 's': mp_add_cs_buf (mp_sys[3].cs_buf, mp_sys[3].cs_len, css, css_pos);
3487 break;
3488 case 'a': mp_add_cs_buf (mp_sys[4].cs_buf, mp_sys[4].cs_len, css, css_pos);
3489 break;
3490 case 'b': mp_add_cs_buf (mp_sys[5].cs_buf, mp_sys[5].cs_len, css, css_pos);
3491 break;
3492 case '1': if (mp_usr[0].cs_len == 0) { log_error ("ERROR: Custom-charset 1 is undefined\n"); exit (-1); }
3493 mp_add_cs_buf (mp_usr[0].cs_buf, mp_usr[0].cs_len, css, css_pos);
3494 break;
3495 case '2': if (mp_usr[1].cs_len == 0) { log_error ("ERROR: Custom-charset 2 is undefined\n"); exit (-1); }
3496 mp_add_cs_buf (mp_usr[1].cs_buf, mp_usr[1].cs_len, css, css_pos);
3497 break;
3498 case '3': if (mp_usr[2].cs_len == 0) { log_error ("ERROR: Custom-charset 3 is undefined\n"); exit (-1); }
3499 mp_add_cs_buf (mp_usr[2].cs_buf, mp_usr[2].cs_len, css, css_pos);
3500 break;
3501 case '4': if (mp_usr[3].cs_len == 0) { log_error ("ERROR: Custom-charset 4 is undefined\n"); exit (-1); }
3502 mp_add_cs_buf (mp_usr[3].cs_buf, mp_usr[3].cs_len, css, css_pos);
3503 break;
3504 case '?': mp_add_cs_buf (&chr, 1, css, css_pos);
3505 break;
3506 default: log_error ("ERROR: syntax error: %s", mask_buf);
3507 exit (-1);
3508 }
3509 }
3510 else
3511 {
3512 if (data.hex_charset)
3513 {
3514 mask_pos++;
3515
3516 // if there is no 2nd hex character, show an error:
3517
3518 if (mask_pos == mask_len)
3519 {
3520 log_error ("ERROR: the hex-charset option always expects couples of exactly 2 hexadecimal chars, failed mask: %s", mask_buf);
3521
3522 exit (-1);
3523 }
3524
3525 char p1 = mask_buf[mask_pos];
3526
3527 // if they are not valid hex character, show an error:
3528
3529 if ((is_valid_hex_char (p0) == 0) || (is_valid_hex_char (p1) == 0))
3530 {
3531 log_error ("ERROR: invalid hex character detected in mask %s", mask_buf);
3532
3533 exit (-1);
3534 }
3535
3536 uint chr = 0;
3537
3538 chr |= hex_convert (p1) << 0;
3539 chr |= hex_convert (p0) << 4;
3540
3541 mp_add_cs_buf (&chr, 1, css, css_pos);
3542 }
3543 else
3544 {
3545 uint chr = p0;
3546
3547 mp_add_cs_buf (&chr, 1, css, css_pos);
3548 }
3549 }
3550 }
3551
3552 if (css_pos == 0)
3553 {
3554 log_error ("ERROR: invalid mask length (0)");
3555
3556 exit (-1);
3557 }
3558
3559 *css_cnt = css_pos;
3560
3561 return (css);
3562 }
3563
3564 void mp_exec (u64 val, char *buf, cs_t *css, int css_cnt)
3565 {
3566 for (int i = 0; i < css_cnt; i++)
3567 {
3568 uint len = css[i].cs_len;
3569 u64 next = val / len;
3570 uint pos = val % len;
3571 buf[i] = (char) css[i].cs_buf[pos] & 0xff;
3572 val = next;
3573 }
3574 }
3575
3576 void mp_cut_at (char *mask, uint max)
3577 {
3578 uint i;
3579 uint j;
3580 uint mask_len = strlen (mask);
3581
3582 for (i = 0, j = 0; i < mask_len && j < max; i++, j++)
3583 {
3584 if (mask[i] == '?') i++;
3585 }
3586
3587 mask[i] = 0;
3588 }
3589
3590 void mp_setup_sys (cs_t *mp_sys)
3591 {
3592 uint pos;
3593 uint chr;
3594 uint donec[CHARSIZ] = { 0 };
3595
3596 for (pos = 0, chr = 'a'; chr <= 'z'; chr++) { donec[chr] = 1;
3597 mp_sys[0].cs_buf[pos++] = chr;
3598 mp_sys[0].cs_len = pos; }
3599
3600 for (pos = 0, chr = 'A'; chr <= 'Z'; chr++) { donec[chr] = 1;
3601 mp_sys[1].cs_buf[pos++] = chr;
3602 mp_sys[1].cs_len = pos; }
3603
3604 for (pos = 0, chr = '0'; chr <= '9'; chr++) { donec[chr] = 1;
3605 mp_sys[2].cs_buf[pos++] = chr;
3606 mp_sys[2].cs_len = pos; }
3607
3608 for (pos = 0, chr = 0x20; chr <= 0x7e; chr++) { if (donec[chr]) continue;
3609 mp_sys[3].cs_buf[pos++] = chr;
3610 mp_sys[3].cs_len = pos; }
3611
3612 for (pos = 0, chr = 0x20; chr <= 0x7e; chr++) { mp_sys[4].cs_buf[pos++] = chr;
3613 mp_sys[4].cs_len = pos; }
3614
3615 for (pos = 0, chr = 0x00; chr <= 0xff; chr++) { mp_sys[5].cs_buf[pos++] = chr;
3616 mp_sys[5].cs_len = pos; }
3617 }
3618
3619 void mp_setup_usr (cs_t *mp_sys, cs_t *mp_usr, char *buf, uint index)
3620 {
3621 FILE *fp = fopen (buf, "rb");
3622
3623 if (fp == NULL || feof (fp)) // feof() in case if file is empty
3624 {
3625 mp_expand (buf, strlen (buf), mp_sys, mp_usr, index, 1);
3626 }
3627 else
3628 {
3629 char mp_file[1024] = { 0 };
3630
3631 size_t len = fread (mp_file, 1, sizeof (mp_file) - 1, fp);
3632
3633 fclose (fp);
3634
3635 len = in_superchop (mp_file);
3636
3637 if (len == 0)
3638 {
3639 log_info ("WARNING: charset file corrupted");
3640
3641 mp_expand (buf, strlen (buf), mp_sys, mp_usr, index, 1);
3642 }
3643 else
3644 {
3645 mp_expand (mp_file, len, mp_sys, mp_usr, index, 0);
3646 }
3647 }
3648 }
3649
3650 void mp_reset_usr (cs_t *mp_usr, uint index)
3651 {
3652 mp_usr[index].cs_len = 0;
3653
3654 memset (mp_usr[index].cs_buf, 0, sizeof (mp_usr[index].cs_buf));
3655 }
3656
3657 char *mp_get_truncated_mask (char *mask_buf, size_t mask_len, uint len)
3658 {
3659 char *new_mask_buf = (char *) mymalloc (256);
3660
3661 uint mask_pos;
3662
3663 uint css_pos;
3664
3665 for (mask_pos = 0, css_pos = 0; mask_pos < mask_len; mask_pos++, css_pos++)
3666 {
3667 if (css_pos == len) break;
3668
3669 char p0 = mask_buf[mask_pos];
3670
3671 new_mask_buf[mask_pos] = p0;
3672
3673 if (p0 == '?')
3674 {
3675 mask_pos++;
3676
3677 if (mask_pos == mask_len) break;
3678
3679 new_mask_buf[mask_pos] = mask_buf[mask_pos];
3680 }
3681 else
3682 {
3683 if (data.hex_charset)
3684 {
3685 mask_pos++;
3686
3687 if (mask_pos == mask_len)
3688 {
3689 log_error ("ERROR: the hex-charset option always expects couples of exactly 2 hexadecimal chars, failed mask: %s", mask_buf);
3690
3691 exit (-1);
3692 }
3693
3694 char p1 = mask_buf[mask_pos];
3695
3696 // if they are not valid hex character, show an error:
3697
3698 if ((is_valid_hex_char (p0) == 0) || (is_valid_hex_char (p1) == 0))
3699 {
3700 log_error ("ERROR: invalid hex character detected in mask: %s", mask_buf);
3701
3702 exit (-1);
3703 }
3704
3705 new_mask_buf[mask_pos] = p1;
3706 }
3707 }
3708 }
3709
3710 if (css_pos == len) return (new_mask_buf);
3711
3712 myfree (new_mask_buf);
3713
3714 return (NULL);
3715 }
3716
3717 /**
3718 * statprocessor
3719 */
3720
3721 u64 sp_get_sum (uint start, uint stop, cs_t *root_css_buf)
3722 {
3723 u64 sum = 1;
3724
3725 uint i;
3726
3727 for (i = start; i < stop; i++)
3728 {
3729 sum *= root_css_buf[i].cs_len;
3730 }
3731
3732 return (sum);
3733 }
3734
3735 void sp_exec (u64 ctx, char *pw_buf, cs_t *root_css_buf, cs_t *markov_css_buf, uint start, uint stop)
3736 {
3737 u64 v = ctx;
3738
3739 cs_t *cs = &root_css_buf[start];
3740
3741 uint i;
3742
3743 for (i = start; i < stop; i++)
3744 {
3745 const u64 m = v % cs->cs_len;
3746 const u64 d = v / cs->cs_len;
3747
3748 v = d;
3749
3750 const uint k = cs->cs_buf[m];
3751
3752 pw_buf[i - start] = (char) k;
3753
3754 cs = &markov_css_buf[(i * CHARSIZ) + k];
3755 }
3756 }
3757
3758 int sp_comp_val (const void *p1, const void *p2)
3759 {
3760 hcstat_table_t *b1 = (hcstat_table_t *) p1;
3761 hcstat_table_t *b2 = (hcstat_table_t *) p2;
3762
3763 return b2->val - b1->val;
3764 }
3765
3766 void sp_setup_tbl (const char *shared_dir, char *hcstat, uint disable, uint classic, hcstat_table_t *root_table_buf, hcstat_table_t *markov_table_buf)
3767 {
3768 uint i;
3769 uint j;
3770 uint k;
3771
3772 /**
3773 * Initialize hcstats
3774 */
3775
3776 u64 *root_stats_buf = (u64 *) mycalloc (SP_ROOT_CNT, sizeof (u64));
3777
3778 u64 *root_stats_ptr = root_stats_buf;
3779
3780 u64 *root_stats_buf_by_pos[SP_PW_MAX];
3781
3782 for (i = 0; i < SP_PW_MAX; i++)
3783 {
3784 root_stats_buf_by_pos[i] = root_stats_ptr;
3785
3786 root_stats_ptr += CHARSIZ;
3787 }
3788
3789 u64 *markov_stats_buf = (u64 *) mycalloc (SP_MARKOV_CNT, sizeof (u64));
3790
3791 u64 *markov_stats_ptr = markov_stats_buf;
3792
3793 u64 *markov_stats_buf_by_key[SP_PW_MAX][CHARSIZ];
3794
3795 for (i = 0; i < SP_PW_MAX; i++)
3796 {
3797 for (j = 0; j < CHARSIZ; j++)
3798 {
3799 markov_stats_buf_by_key[i][j] = markov_stats_ptr;
3800
3801 markov_stats_ptr += CHARSIZ;
3802 }
3803 }
3804
3805 /**
3806 * Load hcstats File
3807 */
3808
3809 if (hcstat == NULL)
3810 {
3811 char hcstat_tmp[256] = { 0 };
3812
3813 snprintf (hcstat_tmp, sizeof (hcstat_tmp) - 1, "%s/%s", shared_dir, SP_HCSTAT);
3814
3815 hcstat = hcstat_tmp;
3816 }
3817
3818 FILE *fd = fopen (hcstat, "rb");
3819
3820 if (fd == NULL)
3821 {
3822 log_error ("%s: %s", hcstat, strerror (errno));
3823
3824 exit (-1);
3825 }
3826
3827 if (fread (root_stats_buf, sizeof (u64), SP_ROOT_CNT, fd) != SP_ROOT_CNT)
3828 {
3829 log_error ("%s: Could not load data", hcstat);
3830
3831 fclose (fd);
3832
3833 exit (-1);
3834 }
3835
3836 if (fread (markov_stats_buf, sizeof (u64), SP_MARKOV_CNT, fd) != SP_MARKOV_CNT)
3837 {
3838 log_error ("%s: Could not load data", hcstat);
3839
3840 fclose (fd);
3841
3842 exit (-1);
3843 }
3844
3845 fclose (fd);
3846
3847 /**
3848 * Markov modifier of hcstat_table on user request
3849 */
3850
3851 if (disable)
3852 {
3853 memset (root_stats_buf, 0, SP_ROOT_CNT * sizeof (u64));
3854 memset (markov_stats_buf, 0, SP_MARKOV_CNT * sizeof (u64));
3855 }
3856
3857 if (classic)
3858 {
3859 /* Add all stats to first position */
3860
3861 for (i = 1; i < SP_PW_MAX; i++)
3862 {
3863 u64 *out = root_stats_buf_by_pos[0];
3864 u64 *in = root_stats_buf_by_pos[i];
3865
3866 for (j = 0; j < CHARSIZ; j++)
3867 {
3868 *out++ += *in++;
3869 }
3870 }
3871
3872 for (i = 1; i < SP_PW_MAX; i++)
3873 {
3874 u64 *out = markov_stats_buf_by_key[0][0];
3875 u64 *in = markov_stats_buf_by_key[i][0];
3876
3877 for (j = 0; j < CHARSIZ; j++)
3878 {
3879 for (k = 0; k < CHARSIZ; k++)
3880 {
3881 *out++ += *in++;
3882 }
3883 }
3884 }
3885
3886 /* copy them to all pw_positions */
3887
3888 for (i = 1; i < SP_PW_MAX; i++)
3889 {
3890 memcpy (root_stats_buf_by_pos[i], root_stats_buf_by_pos[0], CHARSIZ * sizeof (u64));
3891 }
3892
3893 for (i = 1; i < SP_PW_MAX; i++)
3894 {
3895 memcpy (markov_stats_buf_by_key[i][0], markov_stats_buf_by_key[0][0], CHARSIZ * CHARSIZ * sizeof (u64));
3896 }
3897 }
3898
3899 /**
3900 * Initialize tables
3901 */
3902
3903 hcstat_table_t *root_table_ptr = root_table_buf;
3904
3905 hcstat_table_t *root_table_buf_by_pos[SP_PW_MAX];
3906
3907 for (i = 0; i < SP_PW_MAX; i++)
3908 {
3909 root_table_buf_by_pos[i] = root_table_ptr;
3910
3911 root_table_ptr += CHARSIZ;
3912 }
3913
3914 hcstat_table_t *markov_table_ptr = markov_table_buf;
3915
3916 hcstat_table_t *markov_table_buf_by_key[SP_PW_MAX][CHARSIZ];
3917
3918 for (i = 0; i < SP_PW_MAX; i++)
3919 {
3920 for (j = 0; j < CHARSIZ; j++)
3921 {
3922 markov_table_buf_by_key[i][j] = markov_table_ptr;
3923
3924 markov_table_ptr += CHARSIZ;
3925 }
3926 }
3927
3928 /**
3929 * Convert hcstat to tables
3930 */
3931
3932 for (i = 0; i < SP_ROOT_CNT; i++)
3933 {
3934 uint key = i % CHARSIZ;
3935
3936 root_table_buf[i].key = key;
3937 root_table_buf[i].val = root_stats_buf[i];
3938 }
3939
3940 for (i = 0; i < SP_MARKOV_CNT; i++)
3941 {
3942 uint key = i % CHARSIZ;
3943
3944 markov_table_buf[i].key = key;
3945 markov_table_buf[i].val = markov_stats_buf[i];
3946 }
3947
3948 myfree (root_stats_buf);
3949 myfree (markov_stats_buf);
3950
3951 /**
3952 * Finally sort them
3953 */
3954
3955 for (i = 0; i < SP_PW_MAX; i++)
3956 {
3957 qsort (root_table_buf_by_pos[i], CHARSIZ, sizeof (hcstat_table_t), sp_comp_val);
3958 }
3959
3960 for (i = 0; i < SP_PW_MAX; i++)
3961 {
3962 for (j = 0; j < CHARSIZ; j++)
3963 {
3964 qsort (markov_table_buf_by_key[i][j], CHARSIZ, sizeof (hcstat_table_t), sp_comp_val);
3965 }
3966 }
3967 }
3968
3969 void sp_tbl_to_css (hcstat_table_t *root_table_buf, hcstat_table_t *markov_table_buf, cs_t *root_css_buf, cs_t *markov_css_buf, uint threshold, uint uniq_tbls[SP_PW_MAX][CHARSIZ])
3970 {
3971 /**
3972 * Convert tables to css
3973 */
3974
3975 for (uint i = 0; i < SP_ROOT_CNT; i++)
3976 {
3977 uint pw_pos = i / CHARSIZ;
3978
3979 cs_t *cs = &root_css_buf[pw_pos];
3980
3981 if (cs->cs_len == threshold) continue;
3982
3983 uint key = root_table_buf[i].key;
3984
3985 if (uniq_tbls[pw_pos][key] == 0) continue;
3986
3987 cs->cs_buf[cs->cs_len] = key;
3988
3989 cs->cs_len++;
3990 }
3991
3992 /**
3993 * Convert table to css
3994 */
3995
3996 for (uint i = 0; i < SP_MARKOV_CNT; i++)
3997 {
3998 uint c = i / CHARSIZ;
3999
4000 cs_t *cs = &markov_css_buf[c];
4001
4002 if (cs->cs_len == threshold) continue;
4003
4004 uint pw_pos = c / CHARSIZ;
4005
4006 uint key = markov_table_buf[i].key;
4007
4008 if ((pw_pos + 1) < SP_PW_MAX) if (uniq_tbls[pw_pos + 1][key] == 0) continue;
4009
4010 cs->cs_buf[cs->cs_len] = key;
4011
4012 cs->cs_len++;
4013 }
4014
4015 /*
4016 for (uint i = 0; i < 8; i++)
4017 {
4018 for (uint j = 0x20; j < 0x80; j++)
4019 {
4020 cs_t *ptr = &markov_css_buf[(i * CHARSIZ) + j];
4021
4022 printf ("pos:%u key:%u len:%u\n", i, j, ptr->cs_len);
4023
4024 for (uint k = 0; k < 10; k++)
4025 {
4026 printf (" %u\n", ptr->cs_buf[k]);
4027 }
4028 }
4029 }
4030 */
4031 }
4032
4033 void sp_stretch_root (hcstat_table_t *in, hcstat_table_t *out)
4034 {
4035 for (uint i = 0; i < SP_PW_MAX; i += 2)
4036 {
4037 memcpy (out, in, CHARSIZ * sizeof (hcstat_table_t));
4038
4039 out += CHARSIZ;
4040 in += CHARSIZ;
4041
4042 out->key = 0;
4043 out->val = 1;
4044
4045 out++;
4046
4047 for (uint j = 1; j < CHARSIZ; j++)
4048 {
4049 out->key = j;
4050 out->val = 0;
4051
4052 out++;
4053 }
4054 }
4055 }
4056
4057 void sp_stretch_markov (hcstat_table_t *in, hcstat_table_t *out)
4058 {
4059 for (uint i = 0; i < SP_PW_MAX; i += 2)
4060 {
4061 memcpy (out, in, CHARSIZ * CHARSIZ * sizeof (hcstat_table_t));
4062
4063 out += CHARSIZ * CHARSIZ;
4064 in += CHARSIZ * CHARSIZ;
4065
4066 for (uint j = 0; j < CHARSIZ; j++)
4067 {
4068 out->key = 0;
4069 out->val = 1;
4070
4071 out++;
4072
4073 for (uint k = 1; k < CHARSIZ; k++)
4074 {
4075 out->key = k;
4076 out->val = 0;
4077
4078 out++;
4079 }
4080 }
4081 }
4082 }
4083
4084 /**
4085 * mixed shared functions
4086 */
4087
4088 void dump_hex (const u8 *s, const int sz)
4089 {
4090 for (int i = 0; i < sz; i++)
4091 {
4092 log_info_nn ("%02x ", s[i]);
4093 }
4094
4095 log_info ("");
4096 }
4097
4098 void usage_mini_print (const char *progname)
4099 {
4100 for (uint i = 0; USAGE_MINI[i] != NULL; i++) log_info (USAGE_MINI[i], progname);
4101 }
4102
4103 void usage_big_print (const char *progname)
4104 {
4105 for (uint i = 0; USAGE_BIG[i] != NULL; i++) log_info (USAGE_BIG[i], progname);
4106 }
4107
4108 char *get_exec_path ()
4109 {
4110 int exec_path_len = 1024;
4111
4112 char *exec_path = (char *) mymalloc (exec_path_len);
4113
4114 #ifdef LINUX
4115
4116 char tmp[32] = { 0 };
4117
4118 snprintf (tmp, sizeof (tmp) - 1, "/proc/%d/exe", getpid ());
4119
4120 const int len = readlink (tmp, exec_path, exec_path_len - 1);
4121
4122 #elif WIN
4123
4124 const int len = GetModuleFileName (NULL, exec_path, exec_path_len - 1);
4125
4126 #elif OSX
4127
4128 uint size = exec_path_len;
4129
4130 if (_NSGetExecutablePath (exec_path, &size) != 0)
4131 {
4132 log_error("! executable path buffer too small\n");
4133
4134 exit (-1);
4135 }
4136
4137 const int len = strlen (exec_path);
4138
4139 #else
4140 #error Your Operating System is not supported or detected
4141 #endif
4142
4143 exec_path[len] = 0;
4144
4145 return exec_path;
4146 }
4147
4148 char *get_install_dir (const char *progname)
4149 {
4150 char *install_dir = mystrdup (progname);
4151 char *last_slash = NULL;
4152
4153 if ((last_slash = strrchr (install_dir, '/')) != NULL)
4154 {
4155 *last_slash = 0;
4156 }
4157 else if ((last_slash = strrchr (install_dir, '\\')) != NULL)
4158 {
4159 *last_slash = 0;
4160 }
4161 else
4162 {
4163 install_dir[0] = '.';
4164 install_dir[1] = 0;
4165 }
4166
4167 return (install_dir);
4168 }
4169
4170 char *get_profile_dir (const char *homedir)
4171 {
4172 #define DOT_HASHCAT ".hashcat"
4173
4174 size_t len = strlen (homedir) + 1 + strlen (DOT_HASHCAT) + 1;
4175
4176 char *profile_dir = (char *) mymalloc (len + 1);
4177
4178 snprintf (profile_dir, len, "%s/%s", homedir, DOT_HASHCAT);
4179
4180 return profile_dir;
4181 }
4182
4183 char *get_session_dir (const char *profile_dir)
4184 {
4185 #define SESSIONS_FOLDER "sessions"
4186
4187 size_t len = strlen (profile_dir) + 1 + strlen (SESSIONS_FOLDER) + 1;
4188
4189 char *session_dir = (char *) mymalloc (len + 1);
4190
4191 snprintf (session_dir, len, "%s/%s", profile_dir, SESSIONS_FOLDER);
4192
4193 return session_dir;
4194 }
4195
4196 uint count_lines (FILE *fd)
4197 {
4198 uint cnt = 0;
4199
4200 char *buf = (char *) mymalloc (HCBUFSIZ + 1);
4201
4202 char prev = '\n';
4203
4204 while (!feof (fd))
4205 {
4206 size_t nread = fread (buf, sizeof (char), HCBUFSIZ, fd);
4207
4208 if (nread < 1) continue;
4209
4210 size_t i;
4211
4212 for (i = 0; i < nread; i++)
4213 {
4214 if (prev == '\n') cnt++;
4215
4216 prev = buf[i];
4217 }
4218 }
4219
4220 myfree (buf);
4221
4222 return cnt;
4223 }
4224
4225 void truecrypt_crc32 (const char *filename, u8 keytab[64])
4226 {
4227 uint crc = ~0;
4228
4229 FILE *fd = fopen (filename, "rb");
4230
4231 if (fd == NULL)
4232 {
4233 log_error ("%s: %s", filename, strerror (errno));
4234
4235 exit (-1);
4236 }
4237
4238 #define MAX_KEY_SIZE (1024 * 1024)
4239
4240 u8 *buf = (u8 *) mymalloc (MAX_KEY_SIZE + 1);
4241
4242 int nread = fread (buf, sizeof (u8), MAX_KEY_SIZE, fd);
4243
4244 fclose (fd);
4245
4246 int kpos = 0;
4247
4248 for (int fpos = 0; fpos < nread; fpos++)
4249 {
4250 crc = crc32tab[(crc ^ buf[fpos]) & 0xff] ^ (crc >> 8);
4251
4252 keytab[kpos++] += (crc >> 24) & 0xff;
4253 keytab[kpos++] += (crc >> 16) & 0xff;
4254 keytab[kpos++] += (crc >> 8) & 0xff;
4255 keytab[kpos++] += (crc >> 0) & 0xff;
4256
4257 if (kpos >= 64) kpos = 0;
4258 }
4259
4260 myfree (buf);
4261 }
4262
4263 #ifdef OSX
4264 int pthread_setaffinity_np (pthread_t thread, size_t cpu_size, cpu_set_t *cpu_set)
4265 {
4266 int core;
4267
4268 for (core = 0; core < (8 * (int)cpu_size); core++)
4269 if (CPU_ISSET(core, cpu_set)) break;
4270
4271 thread_affinity_policy_data_t policy = { core };
4272
4273 const int rc = thread_policy_set (pthread_mach_thread_np (thread), THREAD_AFFINITY_POLICY, (thread_policy_t) &policy, 1);
4274
4275 if (data.quiet == 0)
4276 {
4277 if (rc != KERN_SUCCESS)
4278 {
4279 log_error ("ERROR: %s : %d", "thread_policy_set()", rc);
4280 }
4281 }
4282
4283 return rc;
4284 }
4285 #endif
4286
4287 void set_cpu_affinity (char *cpu_affinity)
4288 {
4289 #ifdef WIN
4290 DWORD_PTR aff_mask = 0;
4291 #elif _POSIX
4292 cpu_set_t cpuset;
4293 CPU_ZERO (&cpuset);
4294 #endif
4295
4296 if (cpu_affinity)
4297 {
4298 char *devices = strdup (cpu_affinity);
4299
4300 char *next = strtok (devices, ",");
4301
4302 do
4303 {
4304 uint cpu_id = atoi (next);
4305
4306 if (cpu_id == 0)
4307 {
4308 #ifdef WIN
4309 aff_mask = 0;
4310 #elif _POSIX
4311 CPU_ZERO (&cpuset);
4312 #endif
4313
4314 break;
4315 }
4316
4317 if (cpu_id > 32)
4318 {
4319 log_error ("ERROR: invalid cpu_id %u specified", cpu_id);
4320
4321 exit (-1);
4322 }
4323
4324 #ifdef WIN
4325 aff_mask |= 1 << (cpu_id - 1);
4326 #elif _POSIX
4327 CPU_SET ((cpu_id - 1), &cpuset);
4328 #endif
4329
4330 } while ((next = strtok (NULL, ",")) != NULL);
4331
4332 free (devices);
4333 }
4334
4335 #ifdef WIN
4336 SetProcessAffinityMask (GetCurrentProcess (), aff_mask);
4337 SetThreadAffinityMask (GetCurrentThread (), aff_mask);
4338 #elif _POSIX
4339 pthread_t thread = pthread_self ();
4340 pthread_setaffinity_np (thread, sizeof (cpu_set_t), &cpuset);
4341 #endif
4342 }
4343
4344 void *rulefind (const void *key, void *base, int nmemb, size_t size, int (*compar) (const void *, const void *))
4345 {
4346 char *element, *end;
4347
4348 end = (char *) base + nmemb * size;
4349
4350 for (element = (char *) base; element < end; element += size)
4351 if (!compar (element, key))
4352 return element;
4353
4354 return NULL;
4355 }
4356
4357 int sort_by_u32 (const void *v1, const void *v2)
4358 {
4359 const u32 *s1 = (const u32 *) v1;
4360 const u32 *s2 = (const u32 *) v2;
4361
4362 return *s1 - *s2;
4363 }
4364
4365 int sort_by_salt (const void *v1, const void *v2)
4366 {
4367 const salt_t *s1 = (const salt_t *) v1;
4368 const salt_t *s2 = (const salt_t *) v2;
4369
4370 const int res1 = s1->salt_len - s2->salt_len;
4371
4372 if (res1 != 0) return (res1);
4373
4374 const int res2 = s1->salt_iter - s2->salt_iter;
4375
4376 if (res2 != 0) return (res2);
4377
4378 uint n;
4379
4380 n = 16;
4381
4382 while (n--)
4383 {
4384 if (s1->salt_buf[n] > s2->salt_buf[n]) return ( 1);
4385 if (s1->salt_buf[n] < s2->salt_buf[n]) return (-1);
4386 }
4387
4388 n = 8;
4389
4390 while (n--)
4391 {
4392 if (s1->salt_buf_pc[n] > s2->salt_buf_pc[n]) return ( 1);
4393 if (s1->salt_buf_pc[n] < s2->salt_buf_pc[n]) return (-1);
4394 }
4395
4396 return (0);
4397 }
4398
4399 int sort_by_salt_buf (const void *v1, const void *v2)
4400 {
4401 const pot_t *p1 = (const pot_t *) v1;
4402 const pot_t *p2 = (const pot_t *) v2;
4403
4404 const hash_t *h1 = &p1->hash;
4405 const hash_t *h2 = &p2->hash;
4406
4407 const salt_t *s1 = h1->salt;
4408 const salt_t *s2 = h2->salt;
4409
4410 uint n = 16;
4411
4412 while (n--)
4413 {
4414 if (s1->salt_buf[n] > s2->salt_buf[n]) return ( 1);
4415 if (s1->salt_buf[n] < s2->salt_buf[n]) return (-1);
4416 }
4417
4418 return 0;
4419 }
4420
4421 int sort_by_hash_t_salt (const void *v1, const void *v2)
4422 {
4423 const hash_t *h1 = (const hash_t *) v1;
4424 const hash_t *h2 = (const hash_t *) v2;
4425
4426 const salt_t *s1 = h1->salt;
4427 const salt_t *s2 = h2->salt;
4428
4429 // testphase: this should work
4430 uint n = 16;
4431
4432 while (n--)
4433 {
4434 if (s1->salt_buf[n] > s2->salt_buf[n]) return ( 1);
4435 if (s1->salt_buf[n] < s2->salt_buf[n]) return (-1);
4436 }
4437
4438 /* original code, seems buggy since salt_len can be very big (had a case with 131 len)
4439 also it thinks salt_buf[x] is a char but its a uint so salt_len should be / 4
4440 if (s1->salt_len > s2->salt_len) return ( 1);
4441 if (s1->salt_len < s2->salt_len) return (-1);
4442
4443 uint n = s1->salt_len;
4444
4445 while (n--)
4446 {
4447 if (s1->salt_buf[n] > s2->salt_buf[n]) return ( 1);
4448 if (s1->salt_buf[n] < s2->salt_buf[n]) return (-1);
4449 }
4450 */
4451
4452 return 0;
4453 }
4454
4455 int sort_by_hash_t_salt_hccap (const void *v1, const void *v2)
4456 {
4457 const hash_t *h1 = (const hash_t *) v1;
4458 const hash_t *h2 = (const hash_t *) v2;
4459
4460 const salt_t *s1 = h1->salt;
4461 const salt_t *s2 = h2->salt;
4462
4463 // 16 - 2 (since last 2 uints contain the digest)
4464 uint n = 14;
4465
4466 while (n--)
4467 {
4468 if (s1->salt_buf[n] > s2->salt_buf[n]) return ( 1);
4469 if (s1->salt_buf[n] < s2->salt_buf[n]) return (-1);
4470 }
4471
4472 return 0;
4473 }
4474
4475 int sort_by_hash_no_salt (const void *v1, const void *v2)
4476 {
4477 const hash_t *h1 = (const hash_t *) v1;
4478 const hash_t *h2 = (const hash_t *) v2;
4479
4480 const void *d1 = h1->digest;
4481 const void *d2 = h2->digest;
4482
4483 return data.sort_by_digest (d1, d2);
4484 }
4485
4486 int sort_by_hash (const void *v1, const void *v2)
4487 {
4488 const hash_t *h1 = (const hash_t *) v1;
4489 const hash_t *h2 = (const hash_t *) v2;
4490
4491 if (data.isSalted)
4492 {
4493 const salt_t *s1 = h1->salt;
4494 const salt_t *s2 = h2->salt;
4495
4496 int res = sort_by_salt (s1, s2);
4497
4498 if (res != 0) return (res);
4499 }
4500
4501 const void *d1 = h1->digest;
4502 const void *d2 = h2->digest;
4503
4504 return data.sort_by_digest (d1, d2);
4505 }
4506
4507 int sort_by_pot (const void *v1, const void *v2)
4508 {
4509 const pot_t *p1 = (const pot_t *) v1;
4510 const pot_t *p2 = (const pot_t *) v2;
4511
4512 const hash_t *h1 = &p1->hash;
4513 const hash_t *h2 = &p2->hash;
4514
4515 return sort_by_hash (h1, h2);
4516 }
4517
4518 int sort_by_mtime (const void *p1, const void *p2)
4519 {
4520 const char **f1 = (const char **) p1;
4521 const char **f2 = (const char **) p2;
4522
4523 struct stat s1; stat (*f1, &s1);
4524 struct stat s2; stat (*f2, &s2);
4525
4526 return s2.st_mtime - s1.st_mtime;
4527 }
4528
4529 int sort_by_cpu_rule (const void *p1, const void *p2)
4530 {
4531 const cpu_rule_t *r1 = (const cpu_rule_t *) p1;
4532 const cpu_rule_t *r2 = (const cpu_rule_t *) p2;
4533
4534 return memcmp (r1, r2, sizeof (cpu_rule_t));
4535 }
4536
4537 int sort_by_kernel_rule (const void *p1, const void *p2)
4538 {
4539 const kernel_rule_t *r1 = (const kernel_rule_t *) p1;
4540 const kernel_rule_t *r2 = (const kernel_rule_t *) p2;
4541
4542 return memcmp (r1, r2, sizeof (kernel_rule_t));
4543 }
4544
4545 int sort_by_stringptr (const void *p1, const void *p2)
4546 {
4547 const char **s1 = (const char **) p1;
4548 const char **s2 = (const char **) p2;
4549
4550 return strcmp (*s1, *s2);
4551 }
4552
4553 int sort_by_dictstat (const void *s1, const void *s2)
4554 {
4555 dictstat_t *d1 = (dictstat_t *) s1;
4556 dictstat_t *d2 = (dictstat_t *) s2;
4557
4558 #ifdef LINUX
4559 d2->stat.st_atim = d1->stat.st_atim;
4560 #else
4561 d2->stat.st_atime = d1->stat.st_atime;
4562 #endif
4563
4564 return memcmp (&d1->stat, &d2->stat, sizeof (struct stat));
4565 }
4566
4567 int sort_by_bitmap (const void *p1, const void *p2)
4568 {
4569 const bitmap_result_t *b1 = (const bitmap_result_t *) p1;
4570 const bitmap_result_t *b2 = (const bitmap_result_t *) p2;
4571
4572 return b1->collisions - b2->collisions;
4573 }
4574
4575 int sort_by_digest_4_2 (const void *v1, const void *v2)
4576 {
4577 const u32 *d1 = (const u32 *) v1;
4578 const u32 *d2 = (const u32 *) v2;
4579
4580 uint n = 2;
4581
4582 while (n--)
4583 {
4584 if (d1[n] > d2[n]) return ( 1);
4585 if (d1[n] < d2[n]) return (-1);
4586 }
4587
4588 return (0);
4589 }
4590
4591 int sort_by_digest_4_4 (const void *v1, const void *v2)
4592 {
4593 const u32 *d1 = (const u32 *) v1;
4594 const u32 *d2 = (const u32 *) v2;
4595
4596 uint n = 4;
4597
4598 while (n--)
4599 {
4600 if (d1[n] > d2[n]) return ( 1);
4601 if (d1[n] < d2[n]) return (-1);
4602 }
4603
4604 return (0);
4605 }
4606
4607 int sort_by_digest_4_5 (const void *v1, const void *v2)
4608 {
4609 const u32 *d1 = (const u32 *) v1;
4610 const u32 *d2 = (const u32 *) v2;
4611
4612 uint n = 5;
4613
4614 while (n--)
4615 {
4616 if (d1[n] > d2[n]) return ( 1);
4617 if (d1[n] < d2[n]) return (-1);
4618 }
4619
4620 return (0);
4621 }
4622
4623 int sort_by_digest_4_6 (const void *v1, const void *v2)
4624 {
4625 const u32 *d1 = (const u32 *) v1;
4626 const u32 *d2 = (const u32 *) v2;
4627
4628 uint n = 6;
4629
4630 while (n--)
4631 {
4632 if (d1[n] > d2[n]) return ( 1);
4633 if (d1[n] < d2[n]) return (-1);
4634 }
4635
4636 return (0);
4637 }
4638
4639 int sort_by_digest_4_8 (const void *v1, const void *v2)
4640 {
4641 const u32 *d1 = (const u32 *) v1;
4642 const u32 *d2 = (const u32 *) v2;
4643
4644 uint n = 8;
4645
4646 while (n--)
4647 {
4648 if (d1[n] > d2[n]) return ( 1);
4649 if (d1[n] < d2[n]) return (-1);
4650 }
4651
4652 return (0);
4653 }
4654
4655 int sort_by_digest_4_16 (const void *v1, const void *v2)
4656 {
4657 const u32 *d1 = (const u32 *) v1;
4658 const u32 *d2 = (const u32 *) v2;
4659
4660 uint n = 16;
4661
4662 while (n--)
4663 {
4664 if (d1[n] > d2[n]) return ( 1);
4665 if (d1[n] < d2[n]) return (-1);
4666 }
4667
4668 return (0);
4669 }
4670
4671 int sort_by_digest_4_32 (const void *v1, const void *v2)
4672 {
4673 const u32 *d1 = (const u32 *) v1;
4674 const u32 *d2 = (const u32 *) v2;
4675
4676 uint n = 32;
4677
4678 while (n--)
4679 {
4680 if (d1[n] > d2[n]) return ( 1);
4681 if (d1[n] < d2[n]) return (-1);
4682 }
4683
4684 return (0);
4685 }
4686
4687 int sort_by_digest_4_64 (const void *v1, const void *v2)
4688 {
4689 const u32 *d1 = (const u32 *) v1;
4690 const u32 *d2 = (const u32 *) v2;
4691
4692 uint n = 64;
4693
4694 while (n--)
4695 {
4696 if (d1[n] > d2[n]) return ( 1);
4697 if (d1[n] < d2[n]) return (-1);
4698 }
4699
4700 return (0);
4701 }
4702
4703 int sort_by_digest_8_8 (const void *v1, const void *v2)
4704 {
4705 const u64 *d1 = (const u64 *) v1;
4706 const u64 *d2 = (const u64 *) v2;
4707
4708 uint n = 8;
4709
4710 while (n--)
4711 {
4712 if (d1[n] > d2[n]) return ( 1);
4713 if (d1[n] < d2[n]) return (-1);
4714 }
4715
4716 return (0);
4717 }
4718
4719 int sort_by_digest_8_16 (const void *v1, const void *v2)
4720 {
4721 const u64 *d1 = (const u64 *) v1;
4722 const u64 *d2 = (const u64 *) v2;
4723
4724 uint n = 16;
4725
4726 while (n--)
4727 {
4728 if (d1[n] > d2[n]) return ( 1);
4729 if (d1[n] < d2[n]) return (-1);
4730 }
4731
4732 return (0);
4733 }
4734
4735 int sort_by_digest_8_25 (const void *v1, const void *v2)
4736 {
4737 const u64 *d1 = (const u64 *) v1;
4738 const u64 *d2 = (const u64 *) v2;
4739
4740 uint n = 25;
4741
4742 while (n--)
4743 {
4744 if (d1[n] > d2[n]) return ( 1);
4745 if (d1[n] < d2[n]) return (-1);
4746 }
4747
4748 return (0);
4749 }
4750
4751 int sort_by_digest_p0p1 (const void *v1, const void *v2)
4752 {
4753 const u32 *d1 = (const u32 *) v1;
4754 const u32 *d2 = (const u32 *) v2;
4755
4756 const uint dgst_pos0 = data.dgst_pos0;
4757 const uint dgst_pos1 = data.dgst_pos1;
4758 const uint dgst_pos2 = data.dgst_pos2;
4759 const uint dgst_pos3 = data.dgst_pos3;
4760
4761 if (d1[dgst_pos3] > d2[dgst_pos3]) return ( 1);
4762 if (d1[dgst_pos3] < d2[dgst_pos3]) return (-1);
4763 if (d1[dgst_pos2] > d2[dgst_pos2]) return ( 1);
4764 if (d1[dgst_pos2] < d2[dgst_pos2]) return (-1);
4765 if (d1[dgst_pos1] > d2[dgst_pos1]) return ( 1);
4766 if (d1[dgst_pos1] < d2[dgst_pos1]) return (-1);
4767 if (d1[dgst_pos0] > d2[dgst_pos0]) return ( 1);
4768 if (d1[dgst_pos0] < d2[dgst_pos0]) return (-1);
4769
4770 return (0);
4771 }
4772
4773 int sort_by_tuning_db_alias (const void *v1, const void *v2)
4774 {
4775 const tuning_db_alias_t *t1 = (const tuning_db_alias_t *) v1;
4776 const tuning_db_alias_t *t2 = (const tuning_db_alias_t *) v2;
4777
4778 const int res1 = strcmp (t1->device_name, t2->device_name);
4779
4780 if (res1 != 0) return (res1);
4781
4782 return 0;
4783 }
4784
4785 int sort_by_tuning_db_entry (const void *v1, const void *v2)
4786 {
4787 const tuning_db_entry_t *t1 = (const tuning_db_entry_t *) v1;
4788 const tuning_db_entry_t *t2 = (const tuning_db_entry_t *) v2;
4789
4790 const int res1 = strcmp (t1->device_name, t2->device_name);
4791
4792 if (res1 != 0) return (res1);
4793
4794 const int res2 = t1->attack_mode
4795 - t2->attack_mode;
4796
4797 if (res2 != 0) return (res2);
4798
4799 const int res3 = t1->hash_type
4800 - t2->hash_type;
4801
4802 if (res3 != 0) return (res3);
4803
4804 return 0;
4805 }
4806
4807 void format_debug (char *debug_file, uint debug_mode, unsigned char *orig_plain_ptr, uint orig_plain_len, unsigned char *mod_plain_ptr, uint mod_plain_len, char *rule_buf, int rule_len)
4808 {
4809 uint outfile_autohex = data.outfile_autohex;
4810
4811 unsigned char *rule_ptr = (unsigned char *) rule_buf;
4812
4813 FILE *debug_fp = NULL;
4814
4815 if (debug_file != NULL)
4816 {
4817 debug_fp = fopen (debug_file, "ab");
4818
4819 lock_file (debug_fp);
4820 }
4821 else
4822 {
4823 debug_fp = stderr;
4824 }
4825
4826 if (debug_fp == NULL)
4827 {
4828 log_info ("WARNING: Could not open debug-file for writing");
4829 }
4830 else
4831 {
4832 if ((debug_mode == 2) || (debug_mode == 3) || (debug_mode == 4))
4833 {
4834 format_plain (debug_fp, orig_plain_ptr, orig_plain_len, outfile_autohex);
4835
4836 if ((debug_mode == 3) || (debug_mode == 4)) fputc (':', debug_fp);
4837 }
4838
4839 fwrite (rule_ptr, rule_len, 1, debug_fp);
4840
4841 if (debug_mode == 4)
4842 {
4843 fputc (':', debug_fp);
4844
4845 format_plain (debug_fp, mod_plain_ptr, mod_plain_len, outfile_autohex);
4846 }
4847
4848 fputc ('\n', debug_fp);
4849
4850 if (debug_file != NULL) fclose (debug_fp);
4851 }
4852 }
4853
4854 void format_plain (FILE *fp, unsigned char *plain_ptr, uint plain_len, uint outfile_autohex)
4855 {
4856 int needs_hexify = 0;
4857
4858 if (outfile_autohex == 1)
4859 {
4860 for (uint i = 0; i < plain_len; i++)
4861 {
4862 if (plain_ptr[i] < 0x20)
4863 {
4864 needs_hexify = 1;
4865
4866 break;
4867 }
4868
4869 if (plain_ptr[i] > 0x7f)
4870 {
4871 needs_hexify = 1;
4872
4873 break;
4874 }
4875 }
4876 }
4877
4878 if (needs_hexify == 1)
4879 {
4880 fprintf (fp, "$HEX[");
4881
4882 for (uint i = 0; i < plain_len; i++)
4883 {
4884 fprintf (fp, "%02x", plain_ptr[i]);
4885 }
4886
4887 fprintf (fp, "]");
4888 }
4889 else
4890 {
4891 fwrite (plain_ptr, plain_len, 1, fp);
4892 }
4893 }
4894
4895 void format_output (FILE *out_fp, char *out_buf, unsigned char *plain_ptr, const uint plain_len, const u64 crackpos, unsigned char *username, const uint user_len)
4896 {
4897 uint outfile_format = data.outfile_format;
4898
4899 char separator = data.separator;
4900
4901 if (outfile_format & OUTFILE_FMT_HASH)
4902 {
4903 fprintf (out_fp, "%s", out_buf);
4904
4905 if (outfile_format & (OUTFILE_FMT_PLAIN | OUTFILE_FMT_HEXPLAIN | OUTFILE_FMT_CRACKPOS))
4906 {
4907 fputc (separator, out_fp);
4908 }
4909 }
4910 else if (data.username)
4911 {
4912 if (username != NULL)
4913 {
4914 for (uint i = 0; i < user_len; i++)
4915 {
4916 fprintf (out_fp, "%c", username[i]);
4917 }
4918
4919 if (outfile_format & (OUTFILE_FMT_PLAIN | OUTFILE_FMT_HEXPLAIN | OUTFILE_FMT_CRACKPOS))
4920 {
4921 fputc (separator, out_fp);
4922 }
4923 }
4924 }
4925
4926 if (outfile_format & OUTFILE_FMT_PLAIN)
4927 {
4928 format_plain (out_fp, plain_ptr, plain_len, data.outfile_autohex);
4929
4930 if (outfile_format & (OUTFILE_FMT_HEXPLAIN | OUTFILE_FMT_CRACKPOS))
4931 {
4932 fputc (separator, out_fp);
4933 }
4934 }
4935
4936 if (outfile_format & OUTFILE_FMT_HEXPLAIN)
4937 {
4938 for (uint i = 0; i < plain_len; i++)
4939 {
4940 fprintf (out_fp, "%02x", plain_ptr[i]);
4941 }
4942
4943 if (outfile_format & (OUTFILE_FMT_CRACKPOS))
4944 {
4945 fputc (separator, out_fp);
4946 }
4947 }
4948
4949 if (outfile_format & OUTFILE_FMT_CRACKPOS)
4950 {
4951 #ifdef _WIN
4952 __mingw_fprintf (out_fp, "%llu", crackpos);
4953 #endif
4954
4955 #ifdef _POSIX
4956 #ifdef __x86_64__
4957 fprintf (out_fp, "%lu", (unsigned long) crackpos);
4958 #else
4959 fprintf (out_fp, "%llu", crackpos);
4960 #endif
4961 #endif
4962 }
4963
4964 fputc ('\n', out_fp);
4965 }
4966
4967 void handle_show_request (pot_t *pot, uint pot_cnt, char *input_buf, int input_len, hash_t *hashes_buf, int (*sort_by_pot) (const void *, const void *), FILE *out_fp)
4968 {
4969 pot_t pot_key;
4970
4971 pot_key.hash.salt = hashes_buf->salt;
4972 pot_key.hash.digest = hashes_buf->digest;
4973
4974 pot_t *pot_ptr = (pot_t *) bsearch (&pot_key, pot, pot_cnt, sizeof (pot_t), sort_by_pot);
4975
4976 if (pot_ptr)
4977 {
4978 log_info_nn ("");
4979
4980 input_buf[input_len] = 0;
4981
4982 // user
4983 unsigned char *username = NULL;
4984 uint user_len = 0;
4985
4986 if (data.username)
4987 {
4988 user_t *user = hashes_buf->hash_info->user;
4989
4990 if (user)
4991 {
4992 username = (unsigned char *) (user->user_name);
4993
4994 user_len = user->user_len;
4995 }
4996 }
4997
4998 // do output the line
4999 format_output (out_fp, input_buf, (unsigned char *) pot_ptr->plain_buf, pot_ptr->plain_len, 0, username, user_len);
5000 }
5001 }
5002
5003 #define LM_WEAK_HASH "\x4e\xcf\x0d\x0c\x0a\xe2\xfb\xc1"
5004 #define LM_MASKED_PLAIN "[notfound]"
5005
5006 void handle_show_request_lm (pot_t *pot, uint pot_cnt, char *input_buf, int input_len, hash_t *hash_left, hash_t *hash_right, int (*sort_by_pot) (const void *, const void *), FILE *out_fp)
5007 {
5008 // left
5009
5010 pot_t pot_left_key;
5011
5012 pot_left_key.hash.salt = hash_left->salt;
5013 pot_left_key.hash.digest = hash_left->digest;
5014
5015 pot_t *pot_left_ptr = (pot_t *) bsearch (&pot_left_key, pot, pot_cnt, sizeof (pot_t), sort_by_pot);
5016
5017 // right
5018
5019 uint weak_hash_found = 0;
5020
5021 pot_t pot_right_key;
5022
5023 pot_right_key.hash.salt = hash_right->salt;
5024 pot_right_key.hash.digest = hash_right->digest;
5025
5026 pot_t *pot_right_ptr = (pot_t *) bsearch (&pot_right_key, pot, pot_cnt, sizeof (pot_t), sort_by_pot);
5027
5028 if (pot_right_ptr == NULL)
5029 {
5030 // special case, if "weak hash"
5031
5032 if (memcmp (hash_right->digest, LM_WEAK_HASH, 8) == 0)
5033 {
5034 weak_hash_found = 1;
5035
5036 pot_right_ptr = (pot_t *) mycalloc (1, sizeof (pot_t));
5037
5038 // in theory this is not needed, but we are paranoia:
5039
5040 memset (pot_right_ptr->plain_buf, 0, sizeof (pot_right_ptr->plain_buf));
5041 pot_right_ptr->plain_len = 0;
5042 }
5043 }
5044
5045 if ((pot_left_ptr == NULL) && (pot_right_ptr == NULL))
5046 {
5047 if (weak_hash_found == 1) myfree (pot_right_ptr); // this shouldn't happen at all: if weak_hash_found == 1, than pot_right_ptr is not NULL for sure
5048
5049 return;
5050 }
5051
5052 // at least one half was found:
5053
5054 log_info_nn ("");
5055
5056 input_buf[input_len] = 0;
5057
5058 // user
5059
5060 unsigned char *username = NULL;
5061 uint user_len = 0;
5062
5063 if (data.username)
5064 {
5065 user_t *user = hash_left->hash_info->user;
5066
5067 if (user)
5068 {
5069 username = (unsigned char *) (user->user_name);
5070
5071 user_len = user->user_len;
5072 }
5073 }
5074
5075 // mask the part which was not found
5076
5077 uint left_part_masked = 0;
5078 uint right_part_masked = 0;
5079
5080 uint mask_plain_len = strlen (LM_MASKED_PLAIN);
5081
5082 if (pot_left_ptr == NULL)
5083 {
5084 left_part_masked = 1;
5085
5086 pot_left_ptr = (pot_t *) mycalloc (1, sizeof (pot_t));
5087
5088 memset (pot_left_ptr->plain_buf, 0, sizeof (pot_left_ptr->plain_buf));
5089
5090 memcpy (pot_left_ptr->plain_buf, LM_MASKED_PLAIN, mask_plain_len);
5091 pot_left_ptr->plain_len = mask_plain_len;
5092 }
5093
5094 if (pot_right_ptr == NULL)
5095 {
5096 right_part_masked = 1;
5097
5098 pot_right_ptr = (pot_t *) mycalloc (1, sizeof (pot_t));
5099
5100 memset (pot_right_ptr->plain_buf, 0, sizeof (pot_right_ptr->plain_buf));
5101
5102 memcpy (pot_right_ptr->plain_buf, LM_MASKED_PLAIN, mask_plain_len);
5103 pot_right_ptr->plain_len = mask_plain_len;
5104 }
5105
5106 // create the pot_ptr out of pot_left_ptr and pot_right_ptr
5107
5108 pot_t pot_ptr;
5109
5110 pot_ptr.plain_len = pot_left_ptr->plain_len + pot_right_ptr->plain_len;
5111
5112 memcpy (pot_ptr.plain_buf, pot_left_ptr->plain_buf, pot_left_ptr->plain_len);
5113
5114 memcpy (pot_ptr.plain_buf + pot_left_ptr->plain_len, pot_right_ptr->plain_buf, pot_right_ptr->plain_len);
5115
5116 // do output the line
5117
5118 format_output (out_fp, input_buf, (unsigned char *) pot_ptr.plain_buf, pot_ptr.plain_len, 0, username, user_len);
5119
5120 if (weak_hash_found == 1) myfree (pot_right_ptr);
5121
5122 if (left_part_masked == 1) myfree (pot_left_ptr);
5123 if (right_part_masked == 1) myfree (pot_right_ptr);
5124 }
5125
5126 void handle_left_request (pot_t *pot, uint pot_cnt, char *input_buf, int input_len, hash_t *hashes_buf, int (*sort_by_pot) (const void *, const void *), FILE *out_fp)
5127 {
5128 pot_t pot_key;
5129
5130 memcpy (&pot_key.hash, hashes_buf, sizeof (hash_t));
5131
5132 pot_t *pot_ptr = (pot_t *) bsearch (&pot_key, pot, pot_cnt, sizeof (pot_t), sort_by_pot);
5133
5134 if (pot_ptr == NULL)
5135 {
5136 log_info_nn ("");
5137
5138 input_buf[input_len] = 0;
5139
5140 format_output (out_fp, input_buf, NULL, 0, 0, NULL, 0);
5141 }
5142 }
5143
5144 void handle_left_request_lm (pot_t *pot, uint pot_cnt, char *input_buf, int input_len, hash_t *hash_left, hash_t *hash_right, int (*sort_by_pot) (const void *, const void *), FILE *out_fp)
5145 {
5146 // left
5147
5148 pot_t pot_left_key;
5149
5150 memcpy (&pot_left_key.hash, hash_left, sizeof (hash_t));
5151
5152 pot_t *pot_left_ptr = (pot_t *) bsearch (&pot_left_key, pot, pot_cnt, sizeof (pot_t), sort_by_pot);
5153
5154 // right
5155
5156 pot_t pot_right_key;
5157
5158 memcpy (&pot_right_key.hash, hash_right, sizeof (hash_t));
5159
5160 pot_t *pot_right_ptr = (pot_t *) bsearch (&pot_right_key, pot, pot_cnt, sizeof (pot_t), sort_by_pot);
5161
5162 uint weak_hash_found = 0;
5163
5164 if (pot_right_ptr == NULL)
5165 {
5166 // special case, if "weak hash"
5167
5168 if (memcmp (hash_right->digest, LM_WEAK_HASH, 8) == 0)
5169 {
5170 weak_hash_found = 1;
5171
5172 // we just need that pot_right_ptr is not a NULL pointer
5173
5174 pot_right_ptr = (pot_t *) mycalloc (1, sizeof (pot_t));
5175 }
5176 }
5177
5178 if ((pot_left_ptr != NULL) && (pot_right_ptr != NULL))
5179 {
5180 if (weak_hash_found == 1) myfree (pot_right_ptr);
5181
5182 return;
5183 }
5184
5185 // ... at least one part was not cracked
5186
5187 log_info_nn ("");
5188
5189 input_buf[input_len] = 0;
5190
5191 // only show the hash part which is still not cracked
5192
5193 uint user_len = input_len - 32;
5194
5195 char *hash_output = (char *) mymalloc (33);
5196
5197 memcpy (hash_output, input_buf, input_len);
5198
5199 if (pot_left_ptr != NULL)
5200 {
5201 // only show right part (because left part was already found)
5202
5203 memcpy (hash_output + user_len, input_buf + user_len + 16, 16);
5204
5205 hash_output[user_len + 16] = 0;
5206 }
5207
5208 if (pot_right_ptr != NULL)
5209 {
5210 // only show left part (because right part was already found)
5211
5212 memcpy (hash_output + user_len, input_buf + user_len, 16);
5213
5214 hash_output[user_len + 16] = 0;
5215 }
5216
5217 format_output (out_fp, hash_output, NULL, 0, 0, NULL, 0);
5218
5219 myfree (hash_output);
5220
5221 if (weak_hash_found == 1) myfree (pot_right_ptr);
5222 }
5223
5224 uint setup_opencl_platforms_filter (char *opencl_platforms)
5225 {
5226 uint opencl_platforms_filter = 0;
5227
5228 if (opencl_platforms)
5229 {
5230 char *platforms = strdup (opencl_platforms);
5231
5232 char *next = strtok (platforms, ",");
5233
5234 do
5235 {
5236 int platform = atoi (next);
5237
5238 if (platform < 1 || platform > 32)
5239 {
5240 log_error ("ERROR: invalid OpenCL platform %u specified", platform);
5241
5242 exit (-1);
5243 }
5244
5245 opencl_platforms_filter |= 1 << (platform - 1);
5246
5247 } while ((next = strtok (NULL, ",")) != NULL);
5248
5249 free (platforms);
5250 }
5251 else
5252 {
5253 opencl_platforms_filter = -1;
5254 }
5255
5256 return opencl_platforms_filter;
5257 }
5258
5259 u32 setup_devices_filter (char *opencl_devices)
5260 {
5261 u32 devices_filter = 0;
5262
5263 if (opencl_devices)
5264 {
5265 char *devices = strdup (opencl_devices);
5266
5267 char *next = strtok (devices, ",");
5268
5269 do
5270 {
5271 int device_id = atoi (next);
5272
5273 if (device_id < 1 || device_id > 32)
5274 {
5275 log_error ("ERROR: invalid device_id %u specified", device_id);
5276
5277 exit (-1);
5278 }
5279
5280 devices_filter |= 1 << (device_id - 1);
5281
5282 } while ((next = strtok (NULL, ",")) != NULL);
5283
5284 free (devices);
5285 }
5286 else
5287 {
5288 devices_filter = -1;
5289 }
5290
5291 return devices_filter;
5292 }
5293
5294 cl_device_type setup_device_types_filter (char *opencl_device_types)
5295 {
5296 cl_device_type device_types_filter = 0;
5297
5298 if (opencl_device_types)
5299 {
5300 char *device_types = strdup (opencl_device_types);
5301
5302 char *next = strtok (device_types, ",");
5303
5304 do
5305 {
5306 int device_type = atoi (next);
5307
5308 if (device_type < 1 || device_type > 3)
5309 {
5310 log_error ("ERROR: invalid device_type %u specified", device_type);
5311
5312 exit (-1);
5313 }
5314
5315 device_types_filter |= 1 << device_type;
5316
5317 } while ((next = strtok (NULL, ",")) != NULL);
5318
5319 free (device_types);
5320 }
5321 else
5322 {
5323 // Do not use CPU by default, this often reduces GPU performance because
5324 // the CPU is too busy to handle GPU synchronization
5325
5326 device_types_filter = CL_DEVICE_TYPE_ALL & ~CL_DEVICE_TYPE_CPU;
5327 }
5328
5329 return device_types_filter;
5330 }
5331
5332 u32 get_random_num (const u32 min, const u32 max)
5333 {
5334 if (min == max) return (min);
5335
5336 return ((rand () % (max - min)) + min);
5337 }
5338
5339 u32 mydivc32 (const u32 dividend, const u32 divisor)
5340 {
5341 u32 quotient = dividend / divisor;
5342
5343 if (dividend % divisor) quotient++;
5344
5345 return quotient;
5346 }
5347
5348 u64 mydivc64 (const u64 dividend, const u64 divisor)
5349 {
5350 u64 quotient = dividend / divisor;
5351
5352 if (dividend % divisor) quotient++;
5353
5354 return quotient;
5355 }
5356
5357 void format_timer_display (struct tm *tm, char *buf, size_t len)
5358 {
5359 const char *time_entities_s[] = { "year", "day", "hour", "min", "sec" };
5360 const char *time_entities_m[] = { "years", "days", "hours", "mins", "secs" };
5361
5362 if (tm->tm_year - 70)
5363 {
5364 char *time_entity1 = ((tm->tm_year - 70) == 1) ? (char *) time_entities_s[0] : (char *) time_entities_m[0];
5365 char *time_entity2 = ( tm->tm_yday == 1) ? (char *) time_entities_s[1] : (char *) time_entities_m[1];
5366
5367 snprintf (buf, len - 1, "%d %s, %d %s", tm->tm_year - 70, time_entity1, tm->tm_yday, time_entity2);
5368 }
5369 else if (tm->tm_yday)
5370 {
5371 char *time_entity1 = (tm->tm_yday == 1) ? (char *) time_entities_s[1] : (char *) time_entities_m[1];
5372 char *time_entity2 = (tm->tm_hour == 1) ? (char *) time_entities_s[2] : (char *) time_entities_m[2];
5373
5374 snprintf (buf, len - 1, "%d %s, %d %s", tm->tm_yday, time_entity1, tm->tm_hour, time_entity2);
5375 }
5376 else if (tm->tm_hour)
5377 {
5378 char *time_entity1 = (tm->tm_hour == 1) ? (char *) time_entities_s[2] : (char *) time_entities_m[2];
5379 char *time_entity2 = (tm->tm_min == 1) ? (char *) time_entities_s[3] : (char *) time_entities_m[3];
5380
5381 snprintf (buf, len - 1, "%d %s, %d %s", tm->tm_hour, time_entity1, tm->tm_min, time_entity2);
5382 }
5383 else if (tm->tm_min)
5384 {
5385 char *time_entity1 = (tm->tm_min == 1) ? (char *) time_entities_s[3] : (char *) time_entities_m[3];
5386 char *time_entity2 = (tm->tm_sec == 1) ? (char *) time_entities_s[4] : (char *) time_entities_m[4];
5387
5388 snprintf (buf, len - 1, "%d %s, %d %s", tm->tm_min, time_entity1, tm->tm_sec, time_entity2);
5389 }
5390 else
5391 {
5392 char *time_entity1 = (tm->tm_sec == 1) ? (char *) time_entities_s[4] : (char *) time_entities_m[4];
5393
5394 snprintf (buf, len - 1, "%d %s", tm->tm_sec, time_entity1);
5395 }
5396 }
5397
5398 void format_speed_display (float val, char *buf, size_t len)
5399 {
5400 if (val <= 0)
5401 {
5402 buf[0] = '0';
5403 buf[1] = ' ';
5404 buf[2] = 0;
5405
5406 return;
5407 }
5408
5409 char units[7] = { ' ', 'k', 'M', 'G', 'T', 'P', 'E' };
5410
5411 uint level = 0;
5412
5413 while (val > 99999)
5414 {
5415 val /= 1000;
5416
5417 level++;
5418 }
5419
5420 /* generate output */
5421
5422 if (level == 0)
5423 {
5424 snprintf (buf, len - 1, "%.0f ", val);
5425 }
5426 else
5427 {
5428 snprintf (buf, len - 1, "%.1f %c", val, units[level]);
5429 }
5430 }
5431
5432 void lowercase (u8 *buf, int len)
5433 {
5434 for (int i = 0; i < len; i++) buf[i] = tolower (buf[i]);
5435 }
5436
5437 void uppercase (u8 *buf, int len)
5438 {
5439 for (int i = 0; i < len; i++) buf[i] = toupper (buf[i]);
5440 }
5441
5442 int fgetl (FILE *fp, char *line_buf)
5443 {
5444 int line_len = 0;
5445
5446 while (!feof (fp))
5447 {
5448 const int c = fgetc (fp);
5449
5450 if (c == EOF) break;
5451
5452 line_buf[line_len] = (char) c;
5453
5454 line_len++;
5455
5456 if (line_len == HCBUFSIZ) line_len--;
5457
5458 if (c == '\n') break;
5459 }
5460
5461 if (line_len == 0) return 0;
5462
5463 if (line_buf[line_len - 1] == '\n')
5464 {
5465 line_len--;
5466
5467 line_buf[line_len] = 0;
5468 }
5469
5470 if (line_len == 0) return 0;
5471
5472 if (line_buf[line_len - 1] == '\r')
5473 {
5474 line_len--;
5475
5476 line_buf[line_len] = 0;
5477 }
5478
5479 return (line_len);
5480 }
5481
5482 int in_superchop (char *buf)
5483 {
5484 int len = strlen (buf);
5485
5486 while (len)
5487 {
5488 if (buf[len - 1] == '\n')
5489 {
5490 len--;
5491
5492 continue;
5493 }
5494
5495 if (buf[len - 1] == '\r')
5496 {
5497 len--;
5498
5499 continue;
5500 }
5501
5502 break;
5503 }
5504
5505 buf[len] = 0;
5506
5507 return len;
5508 }
5509
5510 char **scan_directory (const char *path)
5511 {
5512 char *tmp_path = mystrdup (path);
5513
5514 size_t tmp_path_len = strlen (tmp_path);
5515
5516 while (tmp_path[tmp_path_len - 1] == '/' || tmp_path[tmp_path_len - 1] == '\\')
5517 {
5518 tmp_path[tmp_path_len - 1] = 0;
5519
5520 tmp_path_len = strlen (tmp_path);
5521 }
5522
5523 char **files = NULL;
5524
5525 int num_files = 0;
5526
5527 DIR *d = NULL;
5528
5529 if ((d = opendir (tmp_path)) != NULL)
5530 {
5531 #ifdef OSX
5532 struct dirent e;
5533
5534 for (;;) {
5535 memset (&e, 0, sizeof (e));
5536 struct dirent *de = NULL;
5537
5538 if (readdir_r (d, &e, &de) != 0)
5539 {
5540 log_error ("ERROR: readdir_r() failed");
5541
5542 break;
5543 }
5544
5545 if (de == NULL) break;
5546 #else
5547 struct dirent *de;
5548
5549 while ((de = readdir (d)) != NULL)
5550 {
5551 #endif
5552 if ((strcmp (de->d_name, ".") == 0) || (strcmp (de->d_name, "..") == 0)) continue;
5553
5554 int path_size = strlen (tmp_path) + 1 + strlen (de->d_name);
5555
5556 char *path_file = (char *) mymalloc (path_size + 1);
5557
5558 snprintf (path_file, path_size + 1, "%s/%s", tmp_path, de->d_name);
5559
5560 path_file[path_size] = 0;
5561
5562 DIR *d_test;
5563
5564 if ((d_test = opendir (path_file)) != NULL)
5565 {
5566 closedir (d_test);
5567
5568 myfree (path_file);
5569 }
5570 else
5571 {
5572 files = (char **) myrealloc (files, num_files * sizeof (char *), sizeof (char *));
5573
5574 num_files++;
5575
5576 files[num_files - 1] = path_file;
5577 }
5578 }
5579
5580 closedir (d);
5581 }
5582 else if (errno == ENOTDIR)
5583 {
5584 files = (char **) myrealloc (files, num_files * sizeof (char *), sizeof (char *));
5585
5586 num_files++;
5587
5588 files[num_files - 1] = mystrdup (path);
5589 }
5590
5591 files = (char **) myrealloc (files, num_files * sizeof (char *), sizeof (char *));
5592
5593 num_files++;
5594
5595 files[num_files - 1] = NULL;
5596
5597 myfree (tmp_path);
5598
5599 return (files);
5600 }
5601
5602 int count_dictionaries (char **dictionary_files)
5603 {
5604 if (dictionary_files == NULL) return 0;
5605
5606 int cnt = 0;
5607
5608 for (int d = 0; dictionary_files[d] != NULL; d++)
5609 {
5610 cnt++;
5611 }
5612
5613 return (cnt);
5614 }
5615
5616 char *stroptitype (const uint opti_type)
5617 {
5618 switch (opti_type)
5619 {
5620 case OPTI_TYPE_ZERO_BYTE: return ((char *) OPTI_STR_ZERO_BYTE); break;
5621 case OPTI_TYPE_PRECOMPUTE_INIT: return ((char *) OPTI_STR_PRECOMPUTE_INIT); break;
5622 case OPTI_TYPE_PRECOMPUTE_MERKLE: return ((char *) OPTI_STR_PRECOMPUTE_MERKLE); break;
5623 case OPTI_TYPE_PRECOMPUTE_PERMUT: return ((char *) OPTI_STR_PRECOMPUTE_PERMUT); break;
5624 case OPTI_TYPE_MEET_IN_MIDDLE: return ((char *) OPTI_STR_MEET_IN_MIDDLE); break;
5625 case OPTI_TYPE_EARLY_SKIP: return ((char *) OPTI_STR_EARLY_SKIP); break;
5626 case OPTI_TYPE_NOT_SALTED: return ((char *) OPTI_STR_NOT_SALTED); break;
5627 case OPTI_TYPE_NOT_ITERATED: return ((char *) OPTI_STR_NOT_ITERATED); break;
5628 case OPTI_TYPE_PREPENDED_SALT: return ((char *) OPTI_STR_PREPENDED_SALT); break;
5629 case OPTI_TYPE_APPENDED_SALT: return ((char *) OPTI_STR_APPENDED_SALT); break;
5630 case OPTI_TYPE_SINGLE_HASH: return ((char *) OPTI_STR_SINGLE_HASH); break;
5631 case OPTI_TYPE_SINGLE_SALT: return ((char *) OPTI_STR_SINGLE_SALT); break;
5632 case OPTI_TYPE_BRUTE_FORCE: return ((char *) OPTI_STR_BRUTE_FORCE); break;
5633 case OPTI_TYPE_RAW_HASH: return ((char *) OPTI_STR_RAW_HASH); break;
5634 case OPTI_TYPE_USES_BITS_8: return ((char *) OPTI_STR_USES_BITS_8); break;
5635 case OPTI_TYPE_USES_BITS_16: return ((char *) OPTI_STR_USES_BITS_16); break;
5636 case OPTI_TYPE_USES_BITS_32: return ((char *) OPTI_STR_USES_BITS_32); break;
5637 case OPTI_TYPE_USES_BITS_64: return ((char *) OPTI_STR_USES_BITS_64); break;
5638 }
5639
5640 return (NULL);
5641 }
5642
5643 char *strparser (const uint parser_status)
5644 {
5645 switch (parser_status)
5646 {
5647 case PARSER_OK: return ((char *) PA_000); break;
5648 case PARSER_COMMENT: return ((char *) PA_001); break;
5649 case PARSER_GLOBAL_ZERO: return ((char *) PA_002); break;
5650 case PARSER_GLOBAL_LENGTH: return ((char *) PA_003); break;
5651 case PARSER_HASH_LENGTH: return ((char *) PA_004); break;
5652 case PARSER_HASH_VALUE: return ((char *) PA_005); break;
5653 case PARSER_SALT_LENGTH: return ((char *) PA_006); break;
5654 case PARSER_SALT_VALUE: return ((char *) PA_007); break;
5655 case PARSER_SALT_ITERATION: return ((char *) PA_008); break;
5656 case PARSER_SEPARATOR_UNMATCHED: return ((char *) PA_009); break;
5657 case PARSER_SIGNATURE_UNMATCHED: return ((char *) PA_010); break;
5658 case PARSER_HCCAP_FILE_SIZE: return ((char *) PA_011); break;
5659 case PARSER_HCCAP_EAPOL_SIZE: return ((char *) PA_012); break;
5660 case PARSER_PSAFE2_FILE_SIZE: return ((char *) PA_013); break;
5661 case PARSER_PSAFE3_FILE_SIZE: return ((char *) PA_014); break;
5662 case PARSER_TC_FILE_SIZE: return ((char *) PA_015); break;
5663 case PARSER_SIP_AUTH_DIRECTIVE: return ((char *) PA_016); break;
5664 }
5665
5666 return ((char *) PA_255);
5667 }
5668
5669 char *strhashtype (const uint hash_mode)
5670 {
5671 switch (hash_mode)
5672 {
5673 case 0: return ((char *) HT_00000); break;
5674 case 10: return ((char *) HT_00010); break;
5675 case 11: return ((char *) HT_00011); break;
5676 case 12: return ((char *) HT_00012); break;
5677 case 20: return ((char *) HT_00020); break;
5678 case 21: return ((char *) HT_00021); break;
5679 case 22: return ((char *) HT_00022); break;
5680 case 23: return ((char *) HT_00023); break;
5681 case 30: return ((char *) HT_00030); break;
5682 case 40: return ((char *) HT_00040); break;
5683 case 50: return ((char *) HT_00050); break;
5684 case 60: return ((char *) HT_00060); break;
5685 case 100: return ((char *) HT_00100); break;
5686 case 101: return ((char *) HT_00101); break;
5687 case 110: return ((char *) HT_00110); break;
5688 case 111: return ((char *) HT_00111); break;
5689 case 112: return ((char *) HT_00112); break;
5690 case 120: return ((char *) HT_00120); break;
5691 case 121: return ((char *) HT_00121); break;
5692 case 122: return ((char *) HT_00122); break;
5693 case 124: return ((char *) HT_00124); break;
5694 case 125: return ((char *) HT_00125); break;
5695 case 130: return ((char *) HT_00130); break;
5696 case 131: return ((char *) HT_00131); break;
5697 case 132: return ((char *) HT_00132); break;
5698 case 133: return ((char *) HT_00133); break;
5699 case 140: return ((char *) HT_00140); break;
5700 case 141: return ((char *) HT_00141); break;
5701 case 150: return ((char *) HT_00150); break;
5702 case 160: return ((char *) HT_00160); break;
5703 case 190: return ((char *) HT_00190); break;
5704 case 200: return ((char *) HT_00200); break;
5705 case 300: return ((char *) HT_00300); break;
5706 case 400: return ((char *) HT_00400); break;
5707 case 500: return ((char *) HT_00500); break;
5708 case 501: return ((char *) HT_00501); break;
5709 case 900: return ((char *) HT_00900); break;
5710 case 910: return ((char *) HT_00910); break;
5711 case 1000: return ((char *) HT_01000); break;
5712 case 1100: return ((char *) HT_01100); break;
5713 case 1400: return ((char *) HT_01400); break;
5714 case 1410: return ((char *) HT_01410); break;
5715 case 1420: return ((char *) HT_01420); break;
5716 case 1421: return ((char *) HT_01421); break;
5717 case 1430: return ((char *) HT_01430); break;
5718 case 1440: return ((char *) HT_01440); break;
5719 case 1441: return ((char *) HT_01441); break;
5720 case 1450: return ((char *) HT_01450); break;
5721 case 1460: return ((char *) HT_01460); break;
5722 case 1500: return ((char *) HT_01500); break;
5723 case 1600: return ((char *) HT_01600); break;
5724 case 1700: return ((char *) HT_01700); break;
5725 case 1710: return ((char *) HT_01710); break;
5726 case 1711: return ((char *) HT_01711); break;
5727 case 1720: return ((char *) HT_01720); break;
5728 case 1722: return ((char *) HT_01722); break;
5729 case 1730: return ((char *) HT_01730); break;
5730 case 1731: return ((char *) HT_01731); break;
5731 case 1740: return ((char *) HT_01740); break;
5732 case 1750: return ((char *) HT_01750); break;
5733 case 1760: return ((char *) HT_01760); break;
5734 case 1800: return ((char *) HT_01800); break;
5735 case 2100: return ((char *) HT_02100); break;
5736 case 2400: return ((char *) HT_02400); break;
5737 case 2410: return ((char *) HT_02410); break;
5738 case 2500: return ((char *) HT_02500); break;
5739 case 2600: return ((char *) HT_02600); break;
5740 case 2611: return ((char *) HT_02611); break;
5741 case 2612: return ((char *) HT_02612); break;
5742 case 2711: return ((char *) HT_02711); break;
5743 case 2811: return ((char *) HT_02811); break;
5744 case 3000: return ((char *) HT_03000); break;
5745 case 3100: return ((char *) HT_03100); break;
5746 case 3200: return ((char *) HT_03200); break;
5747 case 3710: return ((char *) HT_03710); break;
5748 case 3711: return ((char *) HT_03711); break;
5749 case 3800: return ((char *) HT_03800); break;
5750 case 4300: return ((char *) HT_04300); break;
5751 case 4400: return ((char *) HT_04400); break;
5752 case 4500: return ((char *) HT_04500); break;
5753 case 4700: return ((char *) HT_04700); break;
5754 case 4800: return ((char *) HT_04800); break;
5755 case 4900: return ((char *) HT_04900); break;
5756 case 5000: return ((char *) HT_05000); break;
5757 case 5100: return ((char *) HT_05100); break;
5758 case 5200: return ((char *) HT_05200); break;
5759 case 5300: return ((char *) HT_05300); break;
5760 case 5400: return ((char *) HT_05400); break;
5761 case 5500: return ((char *) HT_05500); break;
5762 case 5600: return ((char *) HT_05600); break;
5763 case 5700: return ((char *) HT_05700); break;
5764 case 5800: return ((char *) HT_05800); break;
5765 case 6000: return ((char *) HT_06000); break;
5766 case 6100: return ((char *) HT_06100); break;
5767 case 6211: return ((char *) HT_06211); break;
5768 case 6212: return ((char *) HT_06212); break;
5769 case 6213: return ((char *) HT_06213); break;
5770 case 6221: return ((char *) HT_06221); break;
5771 case 6222: return ((char *) HT_06222); break;
5772 case 6223: return ((char *) HT_06223); break;
5773 case 6231: return ((char *) HT_06231); break;
5774 case 6232: return ((char *) HT_06232); break;
5775 case 6233: return ((char *) HT_06233); break;
5776 case 6241: return ((char *) HT_06241); break;
5777 case 6242: return ((char *) HT_06242); break;
5778 case 6243: return ((char *) HT_06243); break;
5779 case 6300: return ((char *) HT_06300); break;
5780 case 6400: return ((char *) HT_06400); break;
5781 case 6500: return ((char *) HT_06500); break;
5782 case 6600: return ((char *) HT_06600); break;
5783 case 6700: return ((char *) HT_06700); break;
5784 case 6800: return ((char *) HT_06800); break;
5785 case 6900: return ((char *) HT_06900); break;
5786 case 7100: return ((char *) HT_07100); break;
5787 case 7200: return ((char *) HT_07200); break;
5788 case 7300: return ((char *) HT_07300); break;
5789 case 7400: return ((char *) HT_07400); break;
5790 case 7500: return ((char *) HT_07500); break;
5791 case 7600: return ((char *) HT_07600); break;
5792 case 7700: return ((char *) HT_07700); break;
5793 case 7800: return ((char *) HT_07800); break;
5794 case 7900: return ((char *) HT_07900); break;
5795 case 8000: return ((char *) HT_08000); break;
5796 case 8100: return ((char *) HT_08100); break;
5797 case 8200: return ((char *) HT_08200); break;
5798 case 8300: return ((char *) HT_08300); break;
5799 case 8400: return ((char *) HT_08400); break;
5800 case 8500: return ((char *) HT_08500); break;
5801 case 8600: return ((char *) HT_08600); break;
5802 case 8700: return ((char *) HT_08700); break;
5803 case 8800: return ((char *) HT_08800); break;
5804 case 8900: return ((char *) HT_08900); break;
5805 case 9000: return ((char *) HT_09000); break;
5806 case 9100: return ((char *) HT_09100); break;
5807 case 9200: return ((char *) HT_09200); break;
5808 case 9300: return ((char *) HT_09300); break;
5809 case 9400: return ((char *) HT_09400); break;
5810 case 9500: return ((char *) HT_09500); break;
5811 case 9600: return ((char *) HT_09600); break;
5812 case 9700: return ((char *) HT_09700); break;
5813 case 9710: return ((char *) HT_09710); break;
5814 case 9720: return ((char *) HT_09720); break;
5815 case 9800: return ((char *) HT_09800); break;
5816 case 9810: return ((char *) HT_09810); break;
5817 case 9820: return ((char *) HT_09820); break;
5818 case 9900: return ((char *) HT_09900); break;
5819 case 10000: return ((char *) HT_10000); break;
5820 case 10100: return ((char *) HT_10100); break;
5821 case 10200: return ((char *) HT_10200); break;
5822 case 10300: return ((char *) HT_10300); break;
5823 case 10400: return ((char *) HT_10400); break;
5824 case 10410: return ((char *) HT_10410); break;
5825 case 10420: return ((char *) HT_10420); break;
5826 case 10500: return ((char *) HT_10500); break;
5827 case 10600: return ((char *) HT_10600); break;
5828 case 10700: return ((char *) HT_10700); break;
5829 case 10800: return ((char *) HT_10800); break;
5830 case 10900: return ((char *) HT_10900); break;
5831 case 11000: return ((char *) HT_11000); break;
5832 case 11100: return ((char *) HT_11100); break;
5833 case 11200: return ((char *) HT_11200); break;
5834 case 11300: return ((char *) HT_11300); break;
5835 case 11400: return ((char *) HT_11400); break;
5836 case 11500: return ((char *) HT_11500); break;
5837 case 11600: return ((char *) HT_11600); break;
5838 case 11700: return ((char *) HT_11700); break;
5839 case 11800: return ((char *) HT_11800); break;
5840 case 11900: return ((char *) HT_11900); break;
5841 case 12000: return ((char *) HT_12000); break;
5842 case 12100: return ((char *) HT_12100); break;
5843 case 12200: return ((char *) HT_12200); break;
5844 case 12300: return ((char *) HT_12300); break;
5845 case 12400: return ((char *) HT_12400); break;
5846 case 12500: return ((char *) HT_12500); break;
5847 case 12600: return ((char *) HT_12600); break;
5848 case 12700: return ((char *) HT_12700); break;
5849 case 12800: return ((char *) HT_12800); break;
5850 case 12900: return ((char *) HT_12900); break;
5851 case 13000: return ((char *) HT_13000); break;
5852 case 13100: return ((char *) HT_13100); break;
5853 case 13200: return ((char *) HT_13200); break;
5854 case 13300: return ((char *) HT_13300); break;
5855 case 13400: return ((char *) HT_13400); break;
5856 case 13500: return ((char *) HT_13500); break;
5857 }
5858
5859 return ((char *) "Unknown");
5860 }
5861
5862 char *strstatus (const uint devices_status)
5863 {
5864 switch (devices_status)
5865 {
5866 case STATUS_INIT: return ((char *) ST_0000); break;
5867 case STATUS_STARTING: return ((char *) ST_0001); break;
5868 case STATUS_RUNNING: return ((char *) ST_0002); break;
5869 case STATUS_PAUSED: return ((char *) ST_0003); break;
5870 case STATUS_EXHAUSTED: return ((char *) ST_0004); break;
5871 case STATUS_CRACKED: return ((char *) ST_0005); break;
5872 case STATUS_ABORTED: return ((char *) ST_0006); break;
5873 case STATUS_QUIT: return ((char *) ST_0007); break;
5874 case STATUS_BYPASS: return ((char *) ST_0008); break;
5875 case STATUS_STOP_AT_CHECKPOINT: return ((char *) ST_0009); break;
5876 case STATUS_AUTOTUNE: return ((char *) ST_0010); break;
5877 }
5878
5879 return ((char *) "Unknown");
5880 }
5881
5882 void ascii_digest (char *out_buf, uint salt_pos, uint digest_pos)
5883 {
5884 uint hash_type = data.hash_type;
5885 uint hash_mode = data.hash_mode;
5886 uint salt_type = data.salt_type;
5887 uint opts_type = data.opts_type;
5888 uint opti_type = data.opti_type;
5889 uint dgst_size = data.dgst_size;
5890
5891 char *hashfile = data.hashfile;
5892
5893 uint len = 4096;
5894
5895 uint digest_buf[64] = { 0 };
5896
5897 u64 *digest_buf64 = (u64 *) digest_buf;
5898
5899 char *digests_buf_ptr = (char *) data.digests_buf;
5900
5901 memcpy (digest_buf, digests_buf_ptr + (data.salts_buf[salt_pos].digests_offset * dgst_size) + (digest_pos * dgst_size), dgst_size);
5902
5903 if (opti_type & OPTI_TYPE_PRECOMPUTE_PERMUT)
5904 {
5905 uint tt;
5906
5907 switch (hash_type)
5908 {
5909 case HASH_TYPE_DESCRYPT:
5910 FP (digest_buf[1], digest_buf[0], tt);
5911 break;
5912
5913 case HASH_TYPE_DESRACF:
5914 digest_buf[0] = rotl32 (digest_buf[0], 29);
5915 digest_buf[1] = rotl32 (digest_buf[1], 29);
5916
5917 FP (digest_buf[1], digest_buf[0], tt);
5918 break;
5919
5920 case HASH_TYPE_LM:
5921 FP (digest_buf[1], digest_buf[0], tt);
5922 break;
5923
5924 case HASH_TYPE_NETNTLM:
5925 digest_buf[0] = rotl32 (digest_buf[0], 29);
5926 digest_buf[1] = rotl32 (digest_buf[1], 29);
5927 digest_buf[2] = rotl32 (digest_buf[2], 29);
5928 digest_buf[3] = rotl32 (digest_buf[3], 29);
5929
5930 FP (digest_buf[1], digest_buf[0], tt);
5931 FP (digest_buf[3], digest_buf[2], tt);
5932 break;
5933
5934 case HASH_TYPE_BSDICRYPT:
5935 digest_buf[0] = rotl32 (digest_buf[0], 31);
5936 digest_buf[1] = rotl32 (digest_buf[1], 31);
5937
5938 FP (digest_buf[1], digest_buf[0], tt);
5939 break;
5940 }
5941 }
5942
5943 if (opti_type & OPTI_TYPE_PRECOMPUTE_MERKLE)
5944 {
5945 switch (hash_type)
5946 {
5947 case HASH_TYPE_MD4:
5948 digest_buf[0] += MD4M_A;
5949 digest_buf[1] += MD4M_B;
5950 digest_buf[2] += MD4M_C;
5951 digest_buf[3] += MD4M_D;
5952 break;
5953
5954 case HASH_TYPE_MD5:
5955 digest_buf[0] += MD5M_A;
5956 digest_buf[1] += MD5M_B;
5957 digest_buf[2] += MD5M_C;
5958 digest_buf[3] += MD5M_D;
5959 break;
5960
5961 case HASH_TYPE_SHA1:
5962 digest_buf[0] += SHA1M_A;
5963 digest_buf[1] += SHA1M_B;
5964 digest_buf[2] += SHA1M_C;
5965 digest_buf[3] += SHA1M_D;
5966 digest_buf[4] += SHA1M_E;
5967 break;
5968
5969 case HASH_TYPE_SHA256:
5970 digest_buf[0] += SHA256M_A;
5971 digest_buf[1] += SHA256M_B;
5972 digest_buf[2] += SHA256M_C;
5973 digest_buf[3] += SHA256M_D;
5974 digest_buf[4] += SHA256M_E;
5975 digest_buf[5] += SHA256M_F;
5976 digest_buf[6] += SHA256M_G;
5977 digest_buf[7] += SHA256M_H;
5978 break;
5979
5980 case HASH_TYPE_SHA384:
5981 digest_buf64[0] += SHA384M_A;
5982 digest_buf64[1] += SHA384M_B;
5983 digest_buf64[2] += SHA384M_C;
5984 digest_buf64[3] += SHA384M_D;
5985 digest_buf64[4] += SHA384M_E;
5986 digest_buf64[5] += SHA384M_F;
5987 digest_buf64[6] += 0;
5988 digest_buf64[7] += 0;
5989 break;
5990
5991 case HASH_TYPE_SHA512:
5992 digest_buf64[0] += SHA512M_A;
5993 digest_buf64[1] += SHA512M_B;
5994 digest_buf64[2] += SHA512M_C;
5995 digest_buf64[3] += SHA512M_D;
5996 digest_buf64[4] += SHA512M_E;
5997 digest_buf64[5] += SHA512M_F;
5998 digest_buf64[6] += SHA512M_G;
5999 digest_buf64[7] += SHA512M_H;
6000 break;
6001 }
6002 }
6003
6004 if (opts_type & OPTS_TYPE_PT_GENERATE_LE)
6005 {
6006 if (dgst_size == DGST_SIZE_4_2)
6007 {
6008 for (int i = 0; i < 2; i++) digest_buf[i] = byte_swap_32 (digest_buf[i]);
6009 }
6010 else if (dgst_size == DGST_SIZE_4_4)
6011 {
6012 for (int i = 0; i < 4; i++) digest_buf[i] = byte_swap_32 (digest_buf[i]);
6013 }
6014 else if (dgst_size == DGST_SIZE_4_5)
6015 {
6016 for (int i = 0; i < 5; i++) digest_buf[i] = byte_swap_32 (digest_buf[i]);
6017 }
6018 else if (dgst_size == DGST_SIZE_4_6)
6019 {
6020 for (int i = 0; i < 6; i++) digest_buf[i] = byte_swap_32 (digest_buf[i]);
6021 }
6022 else if (dgst_size == DGST_SIZE_4_8)
6023 {
6024 for (int i = 0; i < 8; i++) digest_buf[i] = byte_swap_32 (digest_buf[i]);
6025 }
6026 else if ((dgst_size == DGST_SIZE_4_16) || (dgst_size == DGST_SIZE_8_8)) // same size, same result :)
6027 {
6028 if (hash_type == HASH_TYPE_WHIRLPOOL)
6029 {
6030 for (int i = 0; i < 16; i++) digest_buf[i] = byte_swap_32 (digest_buf[i]);
6031 }
6032 else if (hash_type == HASH_TYPE_SHA384)
6033 {
6034 for (int i = 0; i < 8; i++) digest_buf64[i] = byte_swap_64 (digest_buf64[i]);
6035 }
6036 else if (hash_type == HASH_TYPE_SHA512)
6037 {
6038 for (int i = 0; i < 8; i++) digest_buf64[i] = byte_swap_64 (digest_buf64[i]);
6039 }
6040 else if (hash_type == HASH_TYPE_GOST)
6041 {
6042 for (int i = 0; i < 16; i++) digest_buf[i] = byte_swap_32 (digest_buf[i]);
6043 }
6044 }
6045 else if (dgst_size == DGST_SIZE_4_64)
6046 {
6047 for (int i = 0; i < 64; i++) digest_buf[i] = byte_swap_32 (digest_buf[i]);
6048 }
6049 else if (dgst_size == DGST_SIZE_8_25)
6050 {
6051 for (int i = 0; i < 25; i++) digest_buf64[i] = byte_swap_64 (digest_buf64[i]);
6052 }
6053 }
6054
6055 uint isSalted = ((data.salt_type == SALT_TYPE_INTERN)
6056 | (data.salt_type == SALT_TYPE_EXTERN)
6057 | (data.salt_type == SALT_TYPE_EMBEDDED));
6058
6059 salt_t salt;
6060
6061 if (isSalted)
6062 {
6063 memset (&salt, 0, sizeof (salt_t));
6064
6065 memcpy (&salt, &data.salts_buf[salt_pos], sizeof (salt_t));
6066
6067 char *ptr = (char *) salt.salt_buf;
6068
6069 uint len = salt.salt_len;
6070
6071 if (opti_type & OPTI_TYPE_PRECOMPUTE_PERMUT)
6072 {
6073 uint tt;
6074
6075 switch (hash_type)
6076 {
6077 case HASH_TYPE_NETNTLM:
6078
6079 salt.salt_buf[0] = rotr32 (salt.salt_buf[0], 3);
6080 salt.salt_buf[1] = rotr32 (salt.salt_buf[1], 3);
6081
6082 FP (salt.salt_buf[1], salt.salt_buf[0], tt);
6083
6084 break;
6085 }
6086 }
6087
6088 if (opts_type & OPTS_TYPE_ST_UNICODE)
6089 {
6090 for (uint i = 0, j = 0; i < len; i += 1, j += 2)
6091 {
6092 ptr[i] = ptr[j];
6093 }
6094
6095 len = len / 2;
6096 }
6097
6098 if (opts_type & OPTS_TYPE_ST_GENERATE_LE)
6099 {
6100 uint max = salt.salt_len / 4;
6101
6102 if (len % 4) max++;
6103
6104 for (uint i = 0; i < max; i++)
6105 {
6106 salt.salt_buf[i] = byte_swap_32 (salt.salt_buf[i]);
6107 }
6108 }
6109
6110 if (opts_type & OPTS_TYPE_ST_HEX)
6111 {
6112 char tmp[64] = { 0 };
6113
6114 for (uint i = 0, j = 0; i < len; i += 1, j += 2)
6115 {
6116 sprintf (tmp + j, "%02x", (unsigned char) ptr[i]);
6117 }
6118
6119 len = len * 2;
6120
6121 memcpy (ptr, tmp, len);
6122 }
6123
6124 uint memset_size = ((48 - (int) len) > 0) ? (48 - len) : 0;
6125
6126 memset (ptr + len, 0, memset_size);
6127
6128 salt.salt_len = len;
6129 }
6130
6131 //
6132 // some modes require special encoding
6133 //
6134
6135 uint out_buf_plain[256] = { 0 };
6136 uint out_buf_salt[256] = { 0 };
6137
6138 char tmp_buf[1024] = { 0 };
6139
6140 char *ptr_plain = (char *) out_buf_plain;
6141 char *ptr_salt = (char *) out_buf_salt;
6142
6143 if (hash_mode == 22)
6144 {
6145 char username[30] = { 0 };
6146
6147 memcpy (username, salt.salt_buf, salt.salt_len - 22);
6148
6149 char sig[6] = { 'n', 'r', 'c', 's', 't', 'n' };
6150
6151 u16 *ptr = (u16 *) digest_buf;
6152
6153 tmp_buf[ 0] = sig[0];
6154 tmp_buf[ 1] = int_to_base64 (((ptr[1]) >> 12) & 0x3f);
6155 tmp_buf[ 2] = int_to_base64 (((ptr[1]) >> 6) & 0x3f);
6156 tmp_buf[ 3] = int_to_base64 (((ptr[1]) >> 0) & 0x3f);
6157 tmp_buf[ 4] = int_to_base64 (((ptr[0]) >> 12) & 0x3f);
6158 tmp_buf[ 5] = int_to_base64 (((ptr[0]) >> 6) & 0x3f);
6159 tmp_buf[ 6] = sig[1];
6160 tmp_buf[ 7] = int_to_base64 (((ptr[0]) >> 0) & 0x3f);
6161 tmp_buf[ 8] = int_to_base64 (((ptr[3]) >> 12) & 0x3f);
6162 tmp_buf[ 9] = int_to_base64 (((ptr[3]) >> 6) & 0x3f);
6163 tmp_buf[10] = int_to_base64 (((ptr[3]) >> 0) & 0x3f);
6164 tmp_buf[11] = int_to_base64 (((ptr[2]) >> 12) & 0x3f);
6165 tmp_buf[12] = sig[2];
6166 tmp_buf[13] = int_to_base64 (((ptr[2]) >> 6) & 0x3f);
6167 tmp_buf[14] = int_to_base64 (((ptr[2]) >> 0) & 0x3f);
6168 tmp_buf[15] = int_to_base64 (((ptr[5]) >> 12) & 0x3f);
6169 tmp_buf[16] = int_to_base64 (((ptr[5]) >> 6) & 0x3f);
6170 tmp_buf[17] = sig[3];
6171 tmp_buf[18] = int_to_base64 (((ptr[5]) >> 0) & 0x3f);
6172 tmp_buf[19] = int_to_base64 (((ptr[4]) >> 12) & 0x3f);
6173 tmp_buf[20] = int_to_base64 (((ptr[4]) >> 6) & 0x3f);
6174 tmp_buf[21] = int_to_base64 (((ptr[4]) >> 0) & 0x3f);
6175 tmp_buf[22] = int_to_base64 (((ptr[7]) >> 12) & 0x3f);
6176 tmp_buf[23] = sig[4];
6177 tmp_buf[24] = int_to_base64 (((ptr[7]) >> 6) & 0x3f);
6178 tmp_buf[25] = int_to_base64 (((ptr[7]) >> 0) & 0x3f);
6179 tmp_buf[26] = int_to_base64 (((ptr[6]) >> 12) & 0x3f);
6180 tmp_buf[27] = int_to_base64 (((ptr[6]) >> 6) & 0x3f);
6181 tmp_buf[28] = int_to_base64 (((ptr[6]) >> 0) & 0x3f);
6182 tmp_buf[29] = sig[5];
6183
6184 snprintf (out_buf, len-1, "%s:%s",
6185 tmp_buf,
6186 username);
6187 }
6188 else if (hash_mode == 23)
6189 {
6190 // do not show the skyper part in output
6191
6192 char *salt_buf_ptr = (char *) salt.salt_buf;
6193
6194 salt_buf_ptr[salt.salt_len - 8] = 0;
6195
6196 snprintf (out_buf, len-1, "%08x%08x%08x%08x:%s",
6197 digest_buf[0],
6198 digest_buf[1],
6199 digest_buf[2],
6200 digest_buf[3],
6201 salt_buf_ptr);
6202 }
6203 else if (hash_mode == 101)
6204 {
6205 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6206
6207 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6208 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6209 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6210 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6211 digest_buf[4] = byte_swap_32 (digest_buf[4]);
6212
6213 memcpy (tmp_buf, digest_buf, 20);
6214
6215 base64_encode (int_to_base64, (const u8 *) tmp_buf, 20, (u8 *) ptr_plain);
6216
6217 snprintf (out_buf, len-1, "{SHA}%s", ptr_plain);
6218 }
6219 else if (hash_mode == 111)
6220 {
6221 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6222
6223 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6224 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6225 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6226 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6227 digest_buf[4] = byte_swap_32 (digest_buf[4]);
6228
6229 memcpy (tmp_buf, digest_buf, 20);
6230 memcpy (tmp_buf + 20, salt.salt_buf, salt.salt_len);
6231
6232 base64_encode (int_to_base64, (const u8 *) tmp_buf, 20 + salt.salt_len, (u8 *) ptr_plain);
6233
6234 snprintf (out_buf, len-1, "{SSHA}%s", ptr_plain);
6235 }
6236 else if ((hash_mode == 122) || (hash_mode == 125))
6237 {
6238 snprintf (out_buf, len-1, "%s%08x%08x%08x%08x%08x",
6239 (char *) salt.salt_buf,
6240 digest_buf[0],
6241 digest_buf[1],
6242 digest_buf[2],
6243 digest_buf[3],
6244 digest_buf[4]);
6245 }
6246 else if (hash_mode == 124)
6247 {
6248 snprintf (out_buf, len-1, "sha1$%s$%08x%08x%08x%08x%08x",
6249 (char *) salt.salt_buf,
6250 digest_buf[0],
6251 digest_buf[1],
6252 digest_buf[2],
6253 digest_buf[3],
6254 digest_buf[4]);
6255 }
6256 else if (hash_mode == 131)
6257 {
6258 snprintf (out_buf, len-1, "0x0100%s%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x",
6259 (char *) salt.salt_buf,
6260 0, 0, 0, 0, 0,
6261 digest_buf[0],
6262 digest_buf[1],
6263 digest_buf[2],
6264 digest_buf[3],
6265 digest_buf[4]);
6266 }
6267 else if (hash_mode == 132)
6268 {
6269 snprintf (out_buf, len-1, "0x0100%s%08x%08x%08x%08x%08x",
6270 (char *) salt.salt_buf,
6271 digest_buf[0],
6272 digest_buf[1],
6273 digest_buf[2],
6274 digest_buf[3],
6275 digest_buf[4]);
6276 }
6277 else if (hash_mode == 133)
6278 {
6279 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6280
6281 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6282 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6283 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6284 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6285 digest_buf[4] = byte_swap_32 (digest_buf[4]);
6286
6287 memcpy (tmp_buf, digest_buf, 20);
6288
6289 base64_encode (int_to_base64, (const u8 *) tmp_buf, 20, (u8 *) ptr_plain);
6290
6291 snprintf (out_buf, len-1, "%s", ptr_plain);
6292 }
6293 else if (hash_mode == 141)
6294 {
6295 memcpy (tmp_buf, salt.salt_buf, salt.salt_len);
6296
6297 base64_encode (int_to_base64, (const u8 *) tmp_buf, salt.salt_len, (u8 *) ptr_salt);
6298
6299 memset (tmp_buf, 0, sizeof (tmp_buf));
6300
6301 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6302
6303 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6304 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6305 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6306 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6307 digest_buf[4] = byte_swap_32 (digest_buf[4]);
6308
6309 memcpy (tmp_buf, digest_buf, 20);
6310
6311 base64_encode (int_to_base64, (const u8 *) tmp_buf, 20, (u8 *) ptr_plain);
6312
6313 ptr_plain[27] = 0;
6314
6315 snprintf (out_buf, len-1, "%s%s*%s", SIGNATURE_EPISERVER, ptr_salt, ptr_plain);
6316 }
6317 else if (hash_mode == 400)
6318 {
6319 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6320
6321 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6322 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6323 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6324 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6325
6326 phpass_encode ((unsigned char *) digest_buf, (unsigned char *) ptr_plain);
6327
6328 snprintf (out_buf, len-1, "%s%s%s", (char *) salt.salt_sign, (char *) salt.salt_buf, (char *) ptr_plain);
6329 }
6330 else if (hash_mode == 500)
6331 {
6332 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6333
6334 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6335 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6336 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6337 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6338
6339 md5crypt_encode ((unsigned char *) digest_buf, (unsigned char *) ptr_plain);
6340
6341 if (salt.salt_iter == ROUNDS_MD5CRYPT)
6342 {
6343 snprintf (out_buf, len-1, "$1$%s$%s", (char *) salt.salt_buf, (char *) ptr_plain);
6344 }
6345 else
6346 {
6347 snprintf (out_buf, len-1, "$1$rounds=%i$%s$%s", salt.salt_iter, (char *) salt.salt_buf, (char *) ptr_plain);
6348 }
6349 }
6350 else if (hash_mode == 501)
6351 {
6352 uint digest_idx = salt.digests_offset + digest_pos;
6353
6354 hashinfo_t **hashinfo_ptr = data.hash_info;
6355 char *hash_buf = hashinfo_ptr[digest_idx]->orighash;
6356
6357 snprintf (out_buf, len-1, "%s", hash_buf);
6358 }
6359 else if (hash_mode == 1421)
6360 {
6361 u8 *salt_ptr = (u8 *) salt.salt_buf;
6362
6363 snprintf (out_buf, len-1, "%c%c%c%c%c%c%08x%08x%08x%08x%08x%08x%08x%08x",
6364 salt_ptr[0],
6365 salt_ptr[1],
6366 salt_ptr[2],
6367 salt_ptr[3],
6368 salt_ptr[4],
6369 salt_ptr[5],
6370 digest_buf[0],
6371 digest_buf[1],
6372 digest_buf[2],
6373 digest_buf[3],
6374 digest_buf[4],
6375 digest_buf[5],
6376 digest_buf[6],
6377 digest_buf[7]);
6378 }
6379 else if (hash_mode == 1441)
6380 {
6381 memcpy (tmp_buf, salt.salt_buf, salt.salt_len);
6382
6383 base64_encode (int_to_base64, (const u8 *) tmp_buf, salt.salt_len, (u8 *) ptr_salt);
6384
6385 memset (tmp_buf, 0, sizeof (tmp_buf));
6386
6387 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6388
6389 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6390 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6391 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6392 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6393 digest_buf[4] = byte_swap_32 (digest_buf[4]);
6394 digest_buf[5] = byte_swap_32 (digest_buf[5]);
6395 digest_buf[6] = byte_swap_32 (digest_buf[6]);
6396 digest_buf[7] = byte_swap_32 (digest_buf[7]);
6397
6398 memcpy (tmp_buf, digest_buf, 32);
6399
6400 base64_encode (int_to_base64, (const u8 *) tmp_buf, 32, (u8 *) ptr_plain);
6401
6402 ptr_plain[43] = 0;
6403
6404 snprintf (out_buf, len-1, "%s%s*%s", SIGNATURE_EPISERVER4, ptr_salt, ptr_plain);
6405 }
6406 else if (hash_mode == 1500)
6407 {
6408 out_buf[0] = salt.salt_sign[0] & 0xff;
6409 out_buf[1] = salt.salt_sign[1] & 0xff;
6410 //original method, but changed because of this ticket: https://hashcat.net/trac/ticket/269
6411 //out_buf[0] = int_to_itoa64 ((salt.salt_buf[0] >> 0) & 0x3f);
6412 //out_buf[1] = int_to_itoa64 ((salt.salt_buf[0] >> 6) & 0x3f);
6413
6414 memset (tmp_buf, 0, sizeof (tmp_buf));
6415
6416 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6417
6418 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6419 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6420
6421 memcpy (tmp_buf, digest_buf, 8);
6422
6423 base64_encode (int_to_itoa64, (const u8 *) tmp_buf, 8, (u8 *) ptr_plain);
6424
6425 snprintf (out_buf + 2, len-1-2, "%s", ptr_plain);
6426
6427 out_buf[13] = 0;
6428 }
6429 else if (hash_mode == 1600)
6430 {
6431 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6432
6433 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6434 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6435 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6436 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6437
6438 md5crypt_encode ((unsigned char *) digest_buf, (unsigned char *) ptr_plain);
6439
6440 if (salt.salt_iter == ROUNDS_MD5CRYPT)
6441 {
6442 snprintf (out_buf, len-1, "$apr1$%s$%s", (char *) salt.salt_buf, (char *) ptr_plain);
6443 }
6444 else
6445 {
6446 snprintf (out_buf, len-1, "$apr1$rounds=%i$%s$%s", salt.salt_iter, (char *) salt.salt_buf, (char *) ptr_plain);
6447 }
6448 }
6449 else if (hash_mode == 1711)
6450 {
6451 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6452
6453 digest_buf64[0] = byte_swap_64 (digest_buf64[0]);
6454 digest_buf64[1] = byte_swap_64 (digest_buf64[1]);
6455 digest_buf64[2] = byte_swap_64 (digest_buf64[2]);
6456 digest_buf64[3] = byte_swap_64 (digest_buf64[3]);
6457 digest_buf64[4] = byte_swap_64 (digest_buf64[4]);
6458 digest_buf64[5] = byte_swap_64 (digest_buf64[5]);
6459 digest_buf64[6] = byte_swap_64 (digest_buf64[6]);
6460 digest_buf64[7] = byte_swap_64 (digest_buf64[7]);
6461
6462 memcpy (tmp_buf, digest_buf, 64);
6463 memcpy (tmp_buf + 64, salt.salt_buf, salt.salt_len);
6464
6465 base64_encode (int_to_base64, (const u8 *) tmp_buf, 64 + salt.salt_len, (u8 *) ptr_plain);
6466
6467 snprintf (out_buf, len-1, "%s%s", SIGNATURE_SHA512B64S, ptr_plain);
6468 }
6469 else if (hash_mode == 1722)
6470 {
6471 uint *ptr = digest_buf;
6472
6473 snprintf (out_buf, len-1, "%s%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x",
6474 (unsigned char *) salt.salt_buf,
6475 ptr[ 1], ptr[ 0],
6476 ptr[ 3], ptr[ 2],
6477 ptr[ 5], ptr[ 4],
6478 ptr[ 7], ptr[ 6],
6479 ptr[ 9], ptr[ 8],
6480 ptr[11], ptr[10],
6481 ptr[13], ptr[12],
6482 ptr[15], ptr[14]);
6483 }
6484 else if (hash_mode == 1731)
6485 {
6486 uint *ptr = digest_buf;
6487
6488 snprintf (out_buf, len-1, "0x0200%s%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x",
6489 (unsigned char *) salt.salt_buf,
6490 ptr[ 1], ptr[ 0],
6491 ptr[ 3], ptr[ 2],
6492 ptr[ 5], ptr[ 4],
6493 ptr[ 7], ptr[ 6],
6494 ptr[ 9], ptr[ 8],
6495 ptr[11], ptr[10],
6496 ptr[13], ptr[12],
6497 ptr[15], ptr[14]);
6498 }
6499 else if (hash_mode == 1800)
6500 {
6501 // temp workaround
6502
6503 digest_buf64[0] = byte_swap_64 (digest_buf64[0]);
6504 digest_buf64[1] = byte_swap_64 (digest_buf64[1]);
6505 digest_buf64[2] = byte_swap_64 (digest_buf64[2]);
6506 digest_buf64[3] = byte_swap_64 (digest_buf64[3]);
6507 digest_buf64[4] = byte_swap_64 (digest_buf64[4]);
6508 digest_buf64[5] = byte_swap_64 (digest_buf64[5]);
6509 digest_buf64[6] = byte_swap_64 (digest_buf64[6]);
6510 digest_buf64[7] = byte_swap_64 (digest_buf64[7]);
6511
6512 sha512crypt_encode ((unsigned char *) digest_buf64, (unsigned char *) ptr_plain);
6513
6514 if (salt.salt_iter == ROUNDS_SHA512CRYPT)
6515 {
6516 snprintf (out_buf, len-1, "$6$%s$%s", (char *) salt.salt_buf, (char *) ptr_plain);
6517 }
6518 else
6519 {
6520 snprintf (out_buf, len-1, "$6$rounds=%i$%s$%s", salt.salt_iter, (char *) salt.salt_buf, (char *) ptr_plain);
6521 }
6522 }
6523 else if (hash_mode == 2100)
6524 {
6525 uint pos = 0;
6526
6527 snprintf (out_buf + pos, len-1, "%s%i#",
6528 SIGNATURE_DCC2,
6529 salt.salt_iter + 1);
6530
6531 uint signature_len = strlen (out_buf);
6532
6533 pos += signature_len;
6534 len -= signature_len;
6535
6536 char *salt_ptr = (char *) salt.salt_buf;
6537
6538 for (uint i = 0; i < salt.salt_len; i++, pos++, len--) snprintf (out_buf + pos, len-1, "%c", salt_ptr[i]);
6539
6540 snprintf (out_buf + pos, len-1, "#%08x%08x%08x%08x",
6541 byte_swap_32 (digest_buf[0]),
6542 byte_swap_32 (digest_buf[1]),
6543 byte_swap_32 (digest_buf[2]),
6544 byte_swap_32 (digest_buf[3]));
6545 }
6546 else if ((hash_mode == 2400) || (hash_mode == 2410))
6547 {
6548 memcpy (tmp_buf, digest_buf, 16);
6549
6550 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6551
6552 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6553 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6554 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6555 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6556
6557 out_buf[ 0] = int_to_itoa64 ((digest_buf[0] >> 0) & 0x3f);
6558 out_buf[ 1] = int_to_itoa64 ((digest_buf[0] >> 6) & 0x3f);
6559 out_buf[ 2] = int_to_itoa64 ((digest_buf[0] >> 12) & 0x3f);
6560 out_buf[ 3] = int_to_itoa64 ((digest_buf[0] >> 18) & 0x3f);
6561
6562 out_buf[ 4] = int_to_itoa64 ((digest_buf[1] >> 0) & 0x3f);
6563 out_buf[ 5] = int_to_itoa64 ((digest_buf[1] >> 6) & 0x3f);
6564 out_buf[ 6] = int_to_itoa64 ((digest_buf[1] >> 12) & 0x3f);
6565 out_buf[ 7] = int_to_itoa64 ((digest_buf[1] >> 18) & 0x3f);
6566
6567 out_buf[ 8] = int_to_itoa64 ((digest_buf[2] >> 0) & 0x3f);
6568 out_buf[ 9] = int_to_itoa64 ((digest_buf[2] >> 6) & 0x3f);
6569 out_buf[10] = int_to_itoa64 ((digest_buf[2] >> 12) & 0x3f);
6570 out_buf[11] = int_to_itoa64 ((digest_buf[2] >> 18) & 0x3f);
6571
6572 out_buf[12] = int_to_itoa64 ((digest_buf[3] >> 0) & 0x3f);
6573 out_buf[13] = int_to_itoa64 ((digest_buf[3] >> 6) & 0x3f);
6574 out_buf[14] = int_to_itoa64 ((digest_buf[3] >> 12) & 0x3f);
6575 out_buf[15] = int_to_itoa64 ((digest_buf[3] >> 18) & 0x3f);
6576
6577 out_buf[16] = 0;
6578 }
6579 else if (hash_mode == 2500)
6580 {
6581 wpa_t *wpas = (wpa_t *) data.esalts_buf;
6582
6583 wpa_t *wpa = &wpas[salt_pos];
6584
6585 snprintf (out_buf, len-1, "%s:%02x%02x%02x%02x%02x%02x:%02x%02x%02x%02x%02x%02x",
6586 (char *) salt.salt_buf,
6587 wpa->orig_mac1[0],
6588 wpa->orig_mac1[1],
6589 wpa->orig_mac1[2],
6590 wpa->orig_mac1[3],
6591 wpa->orig_mac1[4],
6592 wpa->orig_mac1[5],
6593 wpa->orig_mac2[0],
6594 wpa->orig_mac2[1],
6595 wpa->orig_mac2[2],
6596 wpa->orig_mac2[3],
6597 wpa->orig_mac2[4],
6598 wpa->orig_mac2[5]);
6599 }
6600 else if (hash_mode == 4400)
6601 {
6602 snprintf (out_buf, len-1, "%08x%08x%08x%08x",
6603 byte_swap_32 (digest_buf[0]),
6604 byte_swap_32 (digest_buf[1]),
6605 byte_swap_32 (digest_buf[2]),
6606 byte_swap_32 (digest_buf[3]));
6607 }
6608 else if (hash_mode == 4700)
6609 {
6610 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x",
6611 byte_swap_32 (digest_buf[0]),
6612 byte_swap_32 (digest_buf[1]),
6613 byte_swap_32 (digest_buf[2]),
6614 byte_swap_32 (digest_buf[3]),
6615 byte_swap_32 (digest_buf[4]));
6616 }
6617 else if (hash_mode == 4800)
6618 {
6619 u8 chap_id_byte = (u8) salt.salt_buf[4];
6620
6621 snprintf (out_buf, len-1, "%08x%08x%08x%08x:%08x%08x%08x%08x:%02x",
6622 digest_buf[0],
6623 digest_buf[1],
6624 digest_buf[2],
6625 digest_buf[3],
6626 byte_swap_32 (salt.salt_buf[0]),
6627 byte_swap_32 (salt.salt_buf[1]),
6628 byte_swap_32 (salt.salt_buf[2]),
6629 byte_swap_32 (salt.salt_buf[3]),
6630 chap_id_byte);
6631 }
6632 else if (hash_mode == 4900)
6633 {
6634 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x",
6635 byte_swap_32 (digest_buf[0]),
6636 byte_swap_32 (digest_buf[1]),
6637 byte_swap_32 (digest_buf[2]),
6638 byte_swap_32 (digest_buf[3]),
6639 byte_swap_32 (digest_buf[4]));
6640 }
6641 else if (hash_mode == 5100)
6642 {
6643 snprintf (out_buf, len-1, "%08x%08x",
6644 digest_buf[0],
6645 digest_buf[1]);
6646 }
6647 else if (hash_mode == 5200)
6648 {
6649 snprintf (out_buf, len-1, "%s", hashfile);
6650 }
6651 else if (hash_mode == 5300)
6652 {
6653 ikepsk_t *ikepsks = (ikepsk_t *) data.esalts_buf;
6654
6655 ikepsk_t *ikepsk = &ikepsks[salt_pos];
6656
6657 int buf_len = len -1;
6658
6659 // msg_buf
6660
6661 uint ikepsk_msg_len = ikepsk->msg_len / 4;
6662
6663 for (uint i = 0; i < ikepsk_msg_len; i++)
6664 {
6665 if ((i == 32) || (i == 64) || (i == 66) || (i == 68) || (i == 108))
6666 {
6667 snprintf (out_buf, buf_len, ":");
6668
6669 buf_len--;
6670 out_buf++;
6671 }
6672
6673 snprintf (out_buf, buf_len, "%08x", byte_swap_32 (ikepsk->msg_buf[i]));
6674
6675 buf_len -= 8;
6676 out_buf += 8;
6677 }
6678
6679 // nr_buf
6680
6681 uint ikepsk_nr_len = ikepsk->nr_len / 4;
6682
6683 for (uint i = 0; i < ikepsk_nr_len; i++)
6684 {
6685 if ((i == 0) || (i == 5))
6686 {
6687 snprintf (out_buf, buf_len, ":");
6688
6689 buf_len--;
6690 out_buf++;
6691 }
6692
6693 snprintf (out_buf, buf_len, "%08x", byte_swap_32 (ikepsk->nr_buf[i]));
6694
6695 buf_len -= 8;
6696 out_buf += 8;
6697 }
6698
6699 // digest_buf
6700
6701 for (uint i = 0; i < 4; i++)
6702 {
6703 if (i == 0)
6704 {
6705 snprintf (out_buf, buf_len, ":");
6706
6707 buf_len--;
6708 out_buf++;
6709 }
6710
6711 snprintf (out_buf, buf_len, "%08x", digest_buf[i]);
6712
6713 buf_len -= 8;
6714 out_buf += 8;
6715 }
6716 }
6717 else if (hash_mode == 5400)
6718 {
6719 ikepsk_t *ikepsks = (ikepsk_t *) data.esalts_buf;
6720
6721 ikepsk_t *ikepsk = &ikepsks[salt_pos];
6722
6723 int buf_len = len -1;
6724
6725 // msg_buf
6726
6727 uint ikepsk_msg_len = ikepsk->msg_len / 4;
6728
6729 for (uint i = 0; i < ikepsk_msg_len; i++)
6730 {
6731 if ((i == 32) || (i == 64) || (i == 66) || (i == 68) || (i == 108))
6732 {
6733 snprintf (out_buf, buf_len, ":");
6734
6735 buf_len--;
6736 out_buf++;
6737 }
6738
6739 snprintf (out_buf, buf_len, "%08x", byte_swap_32 (ikepsk->msg_buf[i]));
6740
6741 buf_len -= 8;
6742 out_buf += 8;
6743 }
6744
6745 // nr_buf
6746
6747 uint ikepsk_nr_len = ikepsk->nr_len / 4;
6748
6749 for (uint i = 0; i < ikepsk_nr_len; i++)
6750 {
6751 if ((i == 0) || (i == 5))
6752 {
6753 snprintf (out_buf, buf_len, ":");
6754
6755 buf_len--;
6756 out_buf++;
6757 }
6758
6759 snprintf (out_buf, buf_len, "%08x", byte_swap_32 (ikepsk->nr_buf[i]));
6760
6761 buf_len -= 8;
6762 out_buf += 8;
6763 }
6764
6765 // digest_buf
6766
6767 for (uint i = 0; i < 5; i++)
6768 {
6769 if (i == 0)
6770 {
6771 snprintf (out_buf, buf_len, ":");
6772
6773 buf_len--;
6774 out_buf++;
6775 }
6776
6777 snprintf (out_buf, buf_len, "%08x", digest_buf[i]);
6778
6779 buf_len -= 8;
6780 out_buf += 8;
6781 }
6782 }
6783 else if (hash_mode == 5500)
6784 {
6785 netntlm_t *netntlms = (netntlm_t *) data.esalts_buf;
6786
6787 netntlm_t *netntlm = &netntlms[salt_pos];
6788
6789 char user_buf[64] = { 0 };
6790 char domain_buf[64] = { 0 };
6791 char srvchall_buf[1024] = { 0 };
6792 char clichall_buf[1024] = { 0 };
6793
6794 for (uint i = 0, j = 0; j < netntlm->user_len; i += 1, j += 2)
6795 {
6796 char *ptr = (char *) netntlm->userdomain_buf;
6797
6798 user_buf[i] = ptr[j];
6799 }
6800
6801 for (uint i = 0, j = 0; j < netntlm->domain_len; i += 1, j += 2)
6802 {
6803 char *ptr = (char *) netntlm->userdomain_buf;
6804
6805 domain_buf[i] = ptr[netntlm->user_len + j];
6806 }
6807
6808 for (uint i = 0, j = 0; i < netntlm->srvchall_len; i += 1, j += 2)
6809 {
6810 u8 *ptr = (u8 *) netntlm->chall_buf;
6811
6812 sprintf (srvchall_buf + j, "%02x", ptr[i]);
6813 }
6814
6815 for (uint i = 0, j = 0; i < netntlm->clichall_len; i += 1, j += 2)
6816 {
6817 u8 *ptr = (u8 *) netntlm->chall_buf;
6818
6819 sprintf (clichall_buf + j, "%02x", ptr[netntlm->srvchall_len + i]);
6820 }
6821
6822 snprintf (out_buf, len-1, "%s::%s:%s:%08x%08x%08x%08x%08x%08x:%s",
6823 user_buf,
6824 domain_buf,
6825 srvchall_buf,
6826 digest_buf[0],
6827 digest_buf[1],
6828 digest_buf[2],
6829 digest_buf[3],
6830 byte_swap_32 (salt.salt_buf_pc[0]),
6831 byte_swap_32 (salt.salt_buf_pc[1]),
6832 clichall_buf);
6833 }
6834 else if (hash_mode == 5600)
6835 {
6836 netntlm_t *netntlms = (netntlm_t *) data.esalts_buf;
6837
6838 netntlm_t *netntlm = &netntlms[salt_pos];
6839
6840 char user_buf[64] = { 0 };
6841 char domain_buf[64] = { 0 };
6842 char srvchall_buf[1024] = { 0 };
6843 char clichall_buf[1024] = { 0 };
6844
6845 for (uint i = 0, j = 0; j < netntlm->user_len; i += 1, j += 2)
6846 {
6847 char *ptr = (char *) netntlm->userdomain_buf;
6848
6849 user_buf[i] = ptr[j];
6850 }
6851
6852 for (uint i = 0, j = 0; j < netntlm->domain_len; i += 1, j += 2)
6853 {
6854 char *ptr = (char *) netntlm->userdomain_buf;
6855
6856 domain_buf[i] = ptr[netntlm->user_len + j];
6857 }
6858
6859 for (uint i = 0, j = 0; i < netntlm->srvchall_len; i += 1, j += 2)
6860 {
6861 u8 *ptr = (u8 *) netntlm->chall_buf;
6862
6863 sprintf (srvchall_buf + j, "%02x", ptr[i]);
6864 }
6865
6866 for (uint i = 0, j = 0; i < netntlm->clichall_len; i += 1, j += 2)
6867 {
6868 u8 *ptr = (u8 *) netntlm->chall_buf;
6869
6870 sprintf (clichall_buf + j, "%02x", ptr[netntlm->srvchall_len + i]);
6871 }
6872
6873 snprintf (out_buf, len-1, "%s::%s:%s:%08x%08x%08x%08x:%s",
6874 user_buf,
6875 domain_buf,
6876 srvchall_buf,
6877 digest_buf[0],
6878 digest_buf[1],
6879 digest_buf[2],
6880 digest_buf[3],
6881 clichall_buf);
6882 }
6883 else if (hash_mode == 5700)
6884 {
6885 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6886
6887 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6888 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6889 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6890 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6891 digest_buf[4] = byte_swap_32 (digest_buf[4]);
6892 digest_buf[5] = byte_swap_32 (digest_buf[5]);
6893 digest_buf[6] = byte_swap_32 (digest_buf[6]);
6894 digest_buf[7] = byte_swap_32 (digest_buf[7]);
6895
6896 memcpy (tmp_buf, digest_buf, 32);
6897
6898 base64_encode (int_to_itoa64, (const u8 *) tmp_buf, 32, (u8 *) ptr_plain);
6899
6900 ptr_plain[43] = 0;
6901
6902 snprintf (out_buf, len-1, "%s", ptr_plain);
6903 }
6904 else if (hash_mode == 5800)
6905 {
6906 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6907 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6908 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6909 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6910 digest_buf[4] = byte_swap_32 (digest_buf[4]);
6911
6912 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x",
6913 digest_buf[0],
6914 digest_buf[1],
6915 digest_buf[2],
6916 digest_buf[3],
6917 digest_buf[4]);
6918 }
6919 else if ((hash_mode >= 6200) && (hash_mode <= 6299))
6920 {
6921 snprintf (out_buf, len-1, "%s", hashfile);
6922 }
6923 else if (hash_mode == 6300)
6924 {
6925 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
6926
6927 digest_buf[0] = byte_swap_32 (digest_buf[0]);
6928 digest_buf[1] = byte_swap_32 (digest_buf[1]);
6929 digest_buf[2] = byte_swap_32 (digest_buf[2]);
6930 digest_buf[3] = byte_swap_32 (digest_buf[3]);
6931
6932 md5crypt_encode ((unsigned char *) digest_buf, (unsigned char *) ptr_plain);
6933
6934 snprintf (out_buf, len-1, "{smd5}%s$%s", (char *) salt.salt_buf, (char *) ptr_plain);
6935 }
6936 else if (hash_mode == 6400)
6937 {
6938 sha256aix_encode ((unsigned char *) digest_buf, (unsigned char *) ptr_plain);
6939
6940 snprintf (out_buf, len-1, "{ssha256}%02d$%s$%s", salt.salt_sign[0], (char *) salt.salt_buf, (char *) ptr_plain);
6941 }
6942 else if (hash_mode == 6500)
6943 {
6944 sha512aix_encode ((unsigned char *) digest_buf64, (unsigned char *) ptr_plain);
6945
6946 snprintf (out_buf, len-1, "{ssha512}%02d$%s$%s", salt.salt_sign[0], (char *) salt.salt_buf, (char *) ptr_plain);
6947 }
6948 else if (hash_mode == 6600)
6949 {
6950 agilekey_t *agilekeys = (agilekey_t *) data.esalts_buf;
6951
6952 agilekey_t *agilekey = &agilekeys[salt_pos];
6953
6954 salt.salt_buf[0] = byte_swap_32 (salt.salt_buf[0]);
6955 salt.salt_buf[1] = byte_swap_32 (salt.salt_buf[1]);
6956
6957 uint buf_len = len - 1;
6958
6959 uint off = snprintf (out_buf, buf_len, "%d:%08x%08x:", salt.salt_iter + 1, salt.salt_buf[0], salt.salt_buf[1]);
6960 buf_len -= 22;
6961
6962 for (uint i = 0, j = off; i < 1040; i++, j += 2)
6963 {
6964 snprintf (out_buf + j, buf_len, "%02x", agilekey->cipher[i]);
6965
6966 buf_len -= 2;
6967 }
6968 }
6969 else if (hash_mode == 6700)
6970 {
6971 sha1aix_encode ((unsigned char *) digest_buf, (unsigned char *) ptr_plain);
6972
6973 snprintf (out_buf, len-1, "{ssha1}%02d$%s$%s", salt.salt_sign[0], (char *) salt.salt_buf, (char *) ptr_plain);
6974 }
6975 else if (hash_mode == 6800)
6976 {
6977 snprintf (out_buf, len-1, "%s", (char *) salt.salt_buf);
6978 }
6979 else if (hash_mode == 7100)
6980 {
6981 uint *ptr = digest_buf;
6982
6983 pbkdf2_sha512_t *pbkdf2_sha512s = (pbkdf2_sha512_t *) data.esalts_buf;
6984
6985 pbkdf2_sha512_t *pbkdf2_sha512 = &pbkdf2_sha512s[salt_pos];
6986
6987 uint esalt[8] = { 0 };
6988
6989 esalt[0] = byte_swap_32 (pbkdf2_sha512->salt_buf[0]);
6990 esalt[1] = byte_swap_32 (pbkdf2_sha512->salt_buf[1]);
6991 esalt[2] = byte_swap_32 (pbkdf2_sha512->salt_buf[2]);
6992 esalt[3] = byte_swap_32 (pbkdf2_sha512->salt_buf[3]);
6993 esalt[4] = byte_swap_32 (pbkdf2_sha512->salt_buf[4]);
6994 esalt[5] = byte_swap_32 (pbkdf2_sha512->salt_buf[5]);
6995 esalt[6] = byte_swap_32 (pbkdf2_sha512->salt_buf[6]);
6996 esalt[7] = byte_swap_32 (pbkdf2_sha512->salt_buf[7]);
6997
6998 snprintf (out_buf, len-1, "%s%i$%08x%08x%08x%08x%08x%08x%08x%08x$%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x",
6999 SIGNATURE_SHA512OSX,
7000 salt.salt_iter + 1,
7001 esalt[ 0], esalt[ 1],
7002 esalt[ 2], esalt[ 3],
7003 esalt[ 4], esalt[ 5],
7004 esalt[ 6], esalt[ 7],
7005 ptr [ 1], ptr [ 0],
7006 ptr [ 3], ptr [ 2],
7007 ptr [ 5], ptr [ 4],
7008 ptr [ 7], ptr [ 6],
7009 ptr [ 9], ptr [ 8],
7010 ptr [11], ptr [10],
7011 ptr [13], ptr [12],
7012 ptr [15], ptr [14]);
7013 }
7014 else if (hash_mode == 7200)
7015 {
7016 uint *ptr = digest_buf;
7017
7018 pbkdf2_sha512_t *pbkdf2_sha512s = (pbkdf2_sha512_t *) data.esalts_buf;
7019
7020 pbkdf2_sha512_t *pbkdf2_sha512 = &pbkdf2_sha512s[salt_pos];
7021
7022 uint len_used = 0;
7023
7024 snprintf (out_buf + len_used, len - len_used - 1, "%s%i.", SIGNATURE_SHA512GRUB, salt.salt_iter + 1);
7025
7026 len_used = strlen (out_buf);
7027
7028 unsigned char *salt_buf_ptr = (unsigned char *) pbkdf2_sha512->salt_buf;
7029
7030 for (uint i = 0; i < salt.salt_len; i++, len_used += 2)
7031 {
7032 snprintf (out_buf + len_used, len - len_used - 1, "%02x", salt_buf_ptr[i]);
7033 }
7034
7035 snprintf (out_buf + len_used, len - len_used - 1, ".%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x",
7036 ptr [ 1], ptr [ 0],
7037 ptr [ 3], ptr [ 2],
7038 ptr [ 5], ptr [ 4],
7039 ptr [ 7], ptr [ 6],
7040 ptr [ 9], ptr [ 8],
7041 ptr [11], ptr [10],
7042 ptr [13], ptr [12],
7043 ptr [15], ptr [14]);
7044 }
7045 else if (hash_mode == 7300)
7046 {
7047 rakp_t *rakps = (rakp_t *) data.esalts_buf;
7048
7049 rakp_t *rakp = &rakps[salt_pos];
7050
7051 for (uint i = 0, j = 0; (i * 4) < rakp->salt_len; i += 1, j += 8)
7052 {
7053 sprintf (out_buf + j, "%08x", rakp->salt_buf[i]);
7054 }
7055
7056 snprintf (out_buf + rakp->salt_len * 2, len - 1, ":%08x%08x%08x%08x%08x",
7057 digest_buf[0],
7058 digest_buf[1],
7059 digest_buf[2],
7060 digest_buf[3],
7061 digest_buf[4]);
7062 }
7063 else if (hash_mode == 7400)
7064 {
7065 // the encoder is a bit too intelligent, it expects the input data in the wrong BOM
7066
7067 digest_buf[0] = byte_swap_32 (digest_buf[0]);
7068 digest_buf[1] = byte_swap_32 (digest_buf[1]);
7069 digest_buf[2] = byte_swap_32 (digest_buf[2]);
7070 digest_buf[3] = byte_swap_32 (digest_buf[3]);
7071 digest_buf[4] = byte_swap_32 (digest_buf[4]);
7072 digest_buf[5] = byte_swap_32 (digest_buf[5]);
7073 digest_buf[6] = byte_swap_32 (digest_buf[6]);
7074 digest_buf[7] = byte_swap_32 (digest_buf[7]);
7075
7076 sha256crypt_encode ((unsigned char *) digest_buf, (unsigned char *) ptr_plain);
7077
7078 if (salt.salt_iter == ROUNDS_SHA256CRYPT)
7079 {
7080 snprintf (out_buf, len-1, "$5$%s$%s", (char *) salt.salt_buf, (char *) ptr_plain);
7081 }
7082 else
7083 {
7084 snprintf (out_buf, len-1, "$5$rounds=%i$%s$%s", salt.salt_iter, (char *) salt.salt_buf, (char *) ptr_plain);
7085 }
7086 }
7087 else if (hash_mode == 7500)
7088 {
7089 krb5pa_t *krb5pas = (krb5pa_t *) data.esalts_buf;
7090
7091 krb5pa_t *krb5pa = &krb5pas[salt_pos];
7092
7093 u8 *ptr_timestamp = (u8 *) krb5pa->timestamp;
7094 u8 *ptr_checksum = (u8 *) krb5pa->checksum;
7095
7096 char data[128] = { 0 };
7097
7098 char *ptr_data = data;
7099
7100 for (uint i = 0; i < 36; i++, ptr_data += 2)
7101 {
7102 sprintf (ptr_data, "%02x", ptr_timestamp[i]);
7103 }
7104
7105 for (uint i = 0; i < 16; i++, ptr_data += 2)
7106 {
7107 sprintf (ptr_data, "%02x", ptr_checksum[i]);
7108 }
7109
7110 *ptr_data = 0;
7111
7112 snprintf (out_buf, len-1, "%s$%s$%s$%s$%s",
7113 SIGNATURE_KRB5PA,
7114 (char *) krb5pa->user,
7115 (char *) krb5pa->realm,
7116 (char *) krb5pa->salt,
7117 data);
7118 }
7119 else if (hash_mode == 7700)
7120 {
7121 snprintf (out_buf, len-1, "%s$%08X%08X",
7122 (char *) salt.salt_buf,
7123 digest_buf[0],
7124 digest_buf[1]);
7125 }
7126 else if (hash_mode == 7800)
7127 {
7128 snprintf (out_buf, len-1, "%s$%08X%08X%08X%08X%08X",
7129 (char *) salt.salt_buf,
7130 digest_buf[0],
7131 digest_buf[1],
7132 digest_buf[2],
7133 digest_buf[3],
7134 digest_buf[4]);
7135 }
7136 else if (hash_mode == 7900)
7137 {
7138 drupal7_encode ((unsigned char *) digest_buf64, (unsigned char *) ptr_plain);
7139
7140 // ugly hack start
7141
7142 char *tmp = (char *) salt.salt_buf_pc;
7143
7144 ptr_plain[42] = tmp[0];
7145
7146 // ugly hack end
7147
7148 ptr_plain[43] = 0;
7149
7150 snprintf (out_buf, len-1, "%s%s%s", (char *) salt.salt_sign, (char *) salt.salt_buf, (char *) ptr_plain);
7151 }
7152 else if (hash_mode == 8000)
7153 {
7154 snprintf (out_buf, len-1, "0xc007%s%08x%08x%08x%08x%08x%08x%08x%08x",
7155 (unsigned char *) salt.salt_buf,
7156 digest_buf[0],
7157 digest_buf[1],
7158 digest_buf[2],
7159 digest_buf[3],
7160 digest_buf[4],
7161 digest_buf[5],
7162 digest_buf[6],
7163 digest_buf[7]);
7164 }
7165 else if (hash_mode == 8100)
7166 {
7167 salt.salt_buf[0] = byte_swap_32 (salt.salt_buf[0]);
7168 salt.salt_buf[1] = byte_swap_32 (salt.salt_buf[1]);
7169
7170 snprintf (out_buf, len-1, "1%s%08x%08x%08x%08x%08x",
7171 (unsigned char *) salt.salt_buf,
7172 digest_buf[0],
7173 digest_buf[1],
7174 digest_buf[2],
7175 digest_buf[3],
7176 digest_buf[4]);
7177 }
7178 else if (hash_mode == 8200)
7179 {
7180 cloudkey_t *cloudkeys = (cloudkey_t *) data.esalts_buf;
7181
7182 cloudkey_t *cloudkey = &cloudkeys[salt_pos];
7183
7184 char data_buf[4096] = { 0 };
7185
7186 for (int i = 0, j = 0; i < 512; i += 1, j += 8)
7187 {
7188 sprintf (data_buf + j, "%08x", cloudkey->data_buf[i]);
7189 }
7190
7191 data_buf[cloudkey->data_len * 2] = 0;
7192
7193 digest_buf[0] = byte_swap_32 (digest_buf[0]);
7194 digest_buf[1] = byte_swap_32 (digest_buf[1]);
7195 digest_buf[2] = byte_swap_32 (digest_buf[2]);
7196 digest_buf[3] = byte_swap_32 (digest_buf[3]);
7197 digest_buf[4] = byte_swap_32 (digest_buf[4]);
7198 digest_buf[5] = byte_swap_32 (digest_buf[5]);
7199 digest_buf[6] = byte_swap_32 (digest_buf[6]);
7200 digest_buf[7] = byte_swap_32 (digest_buf[7]);
7201
7202 salt.salt_buf[0] = byte_swap_32 (salt.salt_buf[0]);
7203 salt.salt_buf[1] = byte_swap_32 (salt.salt_buf[1]);
7204 salt.salt_buf[2] = byte_swap_32 (salt.salt_buf[2]);
7205 salt.salt_buf[3] = byte_swap_32 (salt.salt_buf[3]);
7206
7207 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x%08x%08x%08x:%08x%08x%08x%08x:%u:%s",
7208 digest_buf[0],
7209 digest_buf[1],
7210 digest_buf[2],
7211 digest_buf[3],
7212 digest_buf[4],
7213 digest_buf[5],
7214 digest_buf[6],
7215 digest_buf[7],
7216 salt.salt_buf[0],
7217 salt.salt_buf[1],
7218 salt.salt_buf[2],
7219 salt.salt_buf[3],
7220 salt.salt_iter + 1,
7221 data_buf);
7222 }
7223 else if (hash_mode == 8300)
7224 {
7225 char digest_buf_c[34] = { 0 };
7226
7227 digest_buf[0] = byte_swap_32 (digest_buf[0]);
7228 digest_buf[1] = byte_swap_32 (digest_buf[1]);
7229 digest_buf[2] = byte_swap_32 (digest_buf[2]);
7230 digest_buf[3] = byte_swap_32 (digest_buf[3]);
7231 digest_buf[4] = byte_swap_32 (digest_buf[4]);
7232
7233 base32_encode (int_to_itoa32, (const u8 *) digest_buf, 20, (u8 *) digest_buf_c);
7234
7235 digest_buf_c[32] = 0;
7236
7237 // domain
7238
7239 const uint salt_pc_len = salt.salt_buf_pc[7]; // what a hack
7240
7241 char domain_buf_c[33] = { 0 };
7242
7243 memcpy (domain_buf_c, (char *) salt.salt_buf_pc, salt_pc_len);
7244
7245 for (uint i = 0; i < salt_pc_len; i++)
7246 {
7247 const char next = domain_buf_c[i];
7248
7249 domain_buf_c[i] = '.';
7250
7251 i += next;
7252 }
7253
7254 domain_buf_c[salt_pc_len] = 0;
7255
7256 // final
7257
7258 snprintf (out_buf, len-1, "%s:%s:%s:%u", digest_buf_c, domain_buf_c, (char *) salt.salt_buf, salt.salt_iter);
7259 }
7260 else if (hash_mode == 8500)
7261 {
7262 snprintf (out_buf, len-1, "%s*%s*%08X%08X", SIGNATURE_RACF, (char *) salt.salt_buf, digest_buf[0], digest_buf[1]);
7263 }
7264 else if (hash_mode == 2612)
7265 {
7266 snprintf (out_buf, len-1, "%s%s$%08x%08x%08x%08x",
7267 SIGNATURE_PHPS,
7268 (char *) salt.salt_buf,
7269 digest_buf[0],
7270 digest_buf[1],
7271 digest_buf[2],
7272 digest_buf[3]);
7273 }
7274 else if (hash_mode == 3711)
7275 {
7276 char *salt_ptr = (char *) salt.salt_buf;
7277
7278 salt_ptr[salt.salt_len - 1] = 0;
7279
7280 snprintf (out_buf, len-1, "%s%s$%08x%08x%08x%08x",
7281 SIGNATURE_MEDIAWIKI_B,
7282 salt_ptr,
7283 digest_buf[0],
7284 digest_buf[1],
7285 digest_buf[2],
7286 digest_buf[3]);
7287 }
7288 else if (hash_mode == 8800)
7289 {
7290 androidfde_t *androidfdes = (androidfde_t *) data.esalts_buf;
7291
7292 androidfde_t *androidfde = &androidfdes[salt_pos];
7293
7294 char tmp[3073] = { 0 };
7295
7296 for (uint i = 0, j = 0; i < 384; i += 1, j += 8)
7297 {
7298 sprintf (tmp + j, "%08x", androidfde->data[i]);
7299 }
7300
7301 tmp[3072] = 0;
7302
7303 snprintf (out_buf, len-1, "%s16$%08x%08x%08x%08x$16$%08x%08x%08x%08x$%s",
7304 SIGNATURE_ANDROIDFDE,
7305 byte_swap_32 (salt.salt_buf[0]),
7306 byte_swap_32 (salt.salt_buf[1]),
7307 byte_swap_32 (salt.salt_buf[2]),
7308 byte_swap_32 (salt.salt_buf[3]),
7309 byte_swap_32 (digest_buf[0]),
7310 byte_swap_32 (digest_buf[1]),
7311 byte_swap_32 (digest_buf[2]),
7312 byte_swap_32 (digest_buf[3]),
7313 tmp);
7314 }
7315 else if (hash_mode == 8900)
7316 {
7317 uint N = salt.scrypt_N;
7318 uint r = salt.scrypt_r;
7319 uint p = salt.scrypt_p;
7320
7321 char base64_salt[32] = { 0 };
7322
7323 base64_encode (int_to_base64, (const u8 *) salt.salt_buf, salt.salt_len, (u8 *) base64_salt);
7324
7325 memset (tmp_buf, 0, 46);
7326
7327 digest_buf[0] = byte_swap_32 (digest_buf[0]);
7328 digest_buf[1] = byte_swap_32 (digest_buf[1]);
7329 digest_buf[2] = byte_swap_32 (digest_buf[2]);
7330 digest_buf[3] = byte_swap_32 (digest_buf[3]);
7331 digest_buf[4] = byte_swap_32 (digest_buf[4]);
7332 digest_buf[5] = byte_swap_32 (digest_buf[5]);
7333 digest_buf[6] = byte_swap_32 (digest_buf[6]);
7334 digest_buf[7] = byte_swap_32 (digest_buf[7]);
7335 digest_buf[8] = 0; // needed for base64_encode ()
7336
7337 base64_encode (int_to_base64, (const u8 *) digest_buf, 32, (u8 *) tmp_buf);
7338
7339 snprintf (out_buf, len-1, "%s:%i:%i:%i:%s:%s",
7340 SIGNATURE_SCRYPT,
7341 N,
7342 r,
7343 p,
7344 base64_salt,
7345 tmp_buf);
7346 }
7347 else if (hash_mode == 9000)
7348 {
7349 snprintf (out_buf, len-1, "%s", hashfile);
7350 }
7351 else if (hash_mode == 9200)
7352 {
7353 // salt
7354
7355 pbkdf2_sha256_t *pbkdf2_sha256s = (pbkdf2_sha256_t *) data.esalts_buf;
7356
7357 pbkdf2_sha256_t *pbkdf2_sha256 = &pbkdf2_sha256s[salt_pos];
7358
7359 unsigned char *salt_buf_ptr = (unsigned char *) pbkdf2_sha256->salt_buf;
7360
7361 // hash
7362
7363 digest_buf[0] = byte_swap_32 (digest_buf[0]);
7364 digest_buf[1] = byte_swap_32 (digest_buf[1]);
7365 digest_buf[2] = byte_swap_32 (digest_buf[2]);
7366 digest_buf[3] = byte_swap_32 (digest_buf[3]);
7367 digest_buf[4] = byte_swap_32 (digest_buf[4]);
7368 digest_buf[5] = byte_swap_32 (digest_buf[5]);
7369 digest_buf[6] = byte_swap_32 (digest_buf[6]);
7370 digest_buf[7] = byte_swap_32 (digest_buf[7]);
7371 digest_buf[8] = 0; // needed for base64_encode ()
7372
7373 char tmp_buf[64] = { 0 };
7374
7375 base64_encode (int_to_itoa64, (const u8 *) digest_buf, 32, (u8 *) tmp_buf);
7376 tmp_buf[43] = 0; // cut it here
7377
7378 // output
7379
7380 snprintf (out_buf, len-1, "%s%s$%s", SIGNATURE_CISCO8, salt_buf_ptr, tmp_buf);
7381 }
7382 else if (hash_mode == 9300)
7383 {
7384 digest_buf[0] = byte_swap_32 (digest_buf[0]);
7385 digest_buf[1] = byte_swap_32 (digest_buf[1]);
7386 digest_buf[2] = byte_swap_32 (digest_buf[2]);
7387 digest_buf[3] = byte_swap_32 (digest_buf[3]);
7388 digest_buf[4] = byte_swap_32 (digest_buf[4]);
7389 digest_buf[5] = byte_swap_32 (digest_buf[5]);
7390 digest_buf[6] = byte_swap_32 (digest_buf[6]);
7391 digest_buf[7] = byte_swap_32 (digest_buf[7]);
7392 digest_buf[8] = 0; // needed for base64_encode ()
7393
7394 char tmp_buf[64] = { 0 };
7395
7396 base64_encode (int_to_itoa64, (const u8 *) digest_buf, 32, (u8 *) tmp_buf);
7397 tmp_buf[43] = 0; // cut it here
7398
7399 unsigned char *salt_buf_ptr = (unsigned char *) salt.salt_buf;
7400
7401 snprintf (out_buf, len-1, "%s%s$%s", SIGNATURE_CISCO9, salt_buf_ptr, tmp_buf);
7402 }
7403 else if (hash_mode == 9400)
7404 {
7405 office2007_t *office2007s = (office2007_t *) data.esalts_buf;
7406
7407 office2007_t *office2007 = &office2007s[salt_pos];
7408
7409 snprintf (out_buf, len-1, "%s*%u*%u*%u*%u*%08x%08x%08x%08x*%08x%08x%08x%08x*%08x%08x%08x%08x%08x",
7410 SIGNATURE_OFFICE2007,
7411 2007,
7412 20,
7413 office2007->keySize,
7414 16,
7415 salt.salt_buf[0],
7416 salt.salt_buf[1],
7417 salt.salt_buf[2],
7418 salt.salt_buf[3],
7419 office2007->encryptedVerifier[0],
7420 office2007->encryptedVerifier[1],
7421 office2007->encryptedVerifier[2],
7422 office2007->encryptedVerifier[3],
7423 office2007->encryptedVerifierHash[0],
7424 office2007->encryptedVerifierHash[1],
7425 office2007->encryptedVerifierHash[2],
7426 office2007->encryptedVerifierHash[3],
7427 office2007->encryptedVerifierHash[4]);
7428 }
7429 else if (hash_mode == 9500)
7430 {
7431 office2010_t *office2010s = (office2010_t *) data.esalts_buf;
7432
7433 office2010_t *office2010 = &office2010s[salt_pos];
7434
7435 snprintf (out_buf, len-1, "%s*%u*%u*%u*%u*%08x%08x%08x%08x*%08x%08x%08x%08x*%08x%08x%08x%08x%08x%08x%08x%08x", SIGNATURE_OFFICE2010, 2010, 100000, 128, 16,
7436
7437 salt.salt_buf[0],
7438 salt.salt_buf[1],
7439 salt.salt_buf[2],
7440 salt.salt_buf[3],
7441 office2010->encryptedVerifier[0],
7442 office2010->encryptedVerifier[1],
7443 office2010->encryptedVerifier[2],
7444 office2010->encryptedVerifier[3],
7445 office2010->encryptedVerifierHash[0],
7446 office2010->encryptedVerifierHash[1],
7447 office2010->encryptedVerifierHash[2],
7448 office2010->encryptedVerifierHash[3],
7449 office2010->encryptedVerifierHash[4],
7450 office2010->encryptedVerifierHash[5],
7451 office2010->encryptedVerifierHash[6],
7452 office2010->encryptedVerifierHash[7]);
7453 }
7454 else if (hash_mode == 9600)
7455 {
7456 office2013_t *office2013s = (office2013_t *) data.esalts_buf;
7457
7458 office2013_t *office2013 = &office2013s[salt_pos];
7459
7460 snprintf (out_buf, len-1, "%s*%u*%u*%u*%u*%08x%08x%08x%08x*%08x%08x%08x%08x*%08x%08x%08x%08x%08x%08x%08x%08x", SIGNATURE_OFFICE2013, 2013, 100000, 256, 16,
7461
7462 salt.salt_buf[0],
7463 salt.salt_buf[1],
7464 salt.salt_buf[2],
7465 salt.salt_buf[3],
7466 office2013->encryptedVerifier[0],
7467 office2013->encryptedVerifier[1],
7468 office2013->encryptedVerifier[2],
7469 office2013->encryptedVerifier[3],
7470 office2013->encryptedVerifierHash[0],
7471 office2013->encryptedVerifierHash[1],
7472 office2013->encryptedVerifierHash[2],
7473 office2013->encryptedVerifierHash[3],
7474 office2013->encryptedVerifierHash[4],
7475 office2013->encryptedVerifierHash[5],
7476 office2013->encryptedVerifierHash[6],
7477 office2013->encryptedVerifierHash[7]);
7478 }
7479 else if (hash_mode == 9700)
7480 {
7481 oldoffice01_t *oldoffice01s = (oldoffice01_t *) data.esalts_buf;
7482
7483 oldoffice01_t *oldoffice01 = &oldoffice01s[salt_pos];
7484
7485 snprintf (out_buf, len-1, "%s*%08x%08x%08x%08x*%08x%08x%08x%08x*%08x%08x%08x%08x",
7486 (oldoffice01->version == 0) ? SIGNATURE_OLDOFFICE0 : SIGNATURE_OLDOFFICE1,
7487 byte_swap_32 (salt.salt_buf[0]),
7488 byte_swap_32 (salt.salt_buf[1]),
7489 byte_swap_32 (salt.salt_buf[2]),
7490 byte_swap_32 (salt.salt_buf[3]),
7491 byte_swap_32 (oldoffice01->encryptedVerifier[0]),
7492 byte_swap_32 (oldoffice01->encryptedVerifier[1]),
7493 byte_swap_32 (oldoffice01->encryptedVerifier[2]),
7494 byte_swap_32 (oldoffice01->encryptedVerifier[3]),
7495 byte_swap_32 (oldoffice01->encryptedVerifierHash[0]),
7496 byte_swap_32 (oldoffice01->encryptedVerifierHash[1]),
7497 byte_swap_32 (oldoffice01->encryptedVerifierHash[2]),
7498 byte_swap_32 (oldoffice01->encryptedVerifierHash[3]));
7499 }
7500 else if (hash_mode == 9710)
7501 {
7502 oldoffice01_t *oldoffice01s = (oldoffice01_t *) data.esalts_buf;
7503
7504 oldoffice01_t *oldoffice01 = &oldoffice01s[salt_pos];
7505
7506 snprintf (out_buf, len-1, "%s*%08x%08x%08x%08x*%08x%08x%08x%08x*%08x%08x%08x%08x",
7507 (oldoffice01->version == 0) ? SIGNATURE_OLDOFFICE0 : SIGNATURE_OLDOFFICE1,
7508 byte_swap_32 (salt.salt_buf[0]),
7509 byte_swap_32 (salt.salt_buf[1]),
7510 byte_swap_32 (salt.salt_buf[2]),
7511 byte_swap_32 (salt.salt_buf[3]),
7512 byte_swap_32 (oldoffice01->encryptedVerifier[0]),
7513 byte_swap_32 (oldoffice01->encryptedVerifier[1]),
7514 byte_swap_32 (oldoffice01->encryptedVerifier[2]),
7515 byte_swap_32 (oldoffice01->encryptedVerifier[3]),
7516 byte_swap_32 (oldoffice01->encryptedVerifierHash[0]),
7517 byte_swap_32 (oldoffice01->encryptedVerifierHash[1]),
7518 byte_swap_32 (oldoffice01->encryptedVerifierHash[2]),
7519 byte_swap_32 (oldoffice01->encryptedVerifierHash[3]));
7520 }
7521 else if (hash_mode == 9720)
7522 {
7523 oldoffice01_t *oldoffice01s = (oldoffice01_t *) data.esalts_buf;
7524
7525 oldoffice01_t *oldoffice01 = &oldoffice01s[salt_pos];
7526
7527 u8 *rc4key = (u8 *) oldoffice01->rc4key;
7528
7529 snprintf (out_buf, len-1, "%s*%08x%08x%08x%08x*%08x%08x%08x%08x*%08x%08x%08x%08x:%02x%02x%02x%02x%02x",
7530 (oldoffice01->version == 0) ? SIGNATURE_OLDOFFICE0 : SIGNATURE_OLDOFFICE1,
7531 byte_swap_32 (salt.salt_buf[0]),
7532 byte_swap_32 (salt.salt_buf[1]),
7533 byte_swap_32 (salt.salt_buf[2]),
7534 byte_swap_32 (salt.salt_buf[3]),
7535 byte_swap_32 (oldoffice01->encryptedVerifier[0]),
7536 byte_swap_32 (oldoffice01->encryptedVerifier[1]),
7537 byte_swap_32 (oldoffice01->encryptedVerifier[2]),
7538 byte_swap_32 (oldoffice01->encryptedVerifier[3]),
7539 byte_swap_32 (oldoffice01->encryptedVerifierHash[0]),
7540 byte_swap_32 (oldoffice01->encryptedVerifierHash[1]),
7541 byte_swap_32 (oldoffice01->encryptedVerifierHash[2]),
7542 byte_swap_32 (oldoffice01->encryptedVerifierHash[3]),
7543 rc4key[0],
7544 rc4key[1],
7545 rc4key[2],
7546 rc4key[3],
7547 rc4key[4]);
7548 }
7549 else if (hash_mode == 9800)
7550 {
7551 oldoffice34_t *oldoffice34s = (oldoffice34_t *) data.esalts_buf;
7552
7553 oldoffice34_t *oldoffice34 = &oldoffice34s[salt_pos];
7554
7555 snprintf (out_buf, len-1, "%s*%08x%08x%08x%08x*%08x%08x%08x%08x*%08x%08x%08x%08x%08x",
7556 (oldoffice34->version == 3) ? SIGNATURE_OLDOFFICE3 : SIGNATURE_OLDOFFICE4,
7557 salt.salt_buf[0],
7558 salt.salt_buf[1],
7559 salt.salt_buf[2],
7560 salt.salt_buf[3],
7561 byte_swap_32 (oldoffice34->encryptedVerifier[0]),
7562 byte_swap_32 (oldoffice34->encryptedVerifier[1]),
7563 byte_swap_32 (oldoffice34->encryptedVerifier[2]),
7564 byte_swap_32 (oldoffice34->encryptedVerifier[3]),
7565 byte_swap_32 (oldoffice34->encryptedVerifierHash[0]),
7566 byte_swap_32 (oldoffice34->encryptedVerifierHash[1]),
7567 byte_swap_32 (oldoffice34->encryptedVerifierHash[2]),
7568 byte_swap_32 (oldoffice34->encryptedVerifierHash[3]),
7569 byte_swap_32 (oldoffice34->encryptedVerifierHash[4]));
7570 }
7571 else if (hash_mode == 9810)
7572 {
7573 oldoffice34_t *oldoffice34s = (oldoffice34_t *) data.esalts_buf;
7574
7575 oldoffice34_t *oldoffice34 = &oldoffice34s[salt_pos];
7576
7577 snprintf (out_buf, len-1, "%s*%08x%08x%08x%08x*%08x%08x%08x%08x*%08x%08x%08x%08x%08x",
7578 (oldoffice34->version == 3) ? SIGNATURE_OLDOFFICE3 : SIGNATURE_OLDOFFICE4,
7579 salt.salt_buf[0],
7580 salt.salt_buf[1],
7581 salt.salt_buf[2],
7582 salt.salt_buf[3],
7583 byte_swap_32 (oldoffice34->encryptedVerifier[0]),
7584 byte_swap_32 (oldoffice34->encryptedVerifier[1]),
7585 byte_swap_32 (oldoffice34->encryptedVerifier[2]),
7586 byte_swap_32 (oldoffice34->encryptedVerifier[3]),
7587 byte_swap_32 (oldoffice34->encryptedVerifierHash[0]),
7588 byte_swap_32 (oldoffice34->encryptedVerifierHash[1]),
7589 byte_swap_32 (oldoffice34->encryptedVerifierHash[2]),
7590 byte_swap_32 (oldoffice34->encryptedVerifierHash[3]),
7591 byte_swap_32 (oldoffice34->encryptedVerifierHash[4]));
7592 }
7593 else if (hash_mode == 9820)
7594 {
7595 oldoffice34_t *oldoffice34s = (oldoffice34_t *) data.esalts_buf;
7596
7597 oldoffice34_t *oldoffice34 = &oldoffice34s[salt_pos];
7598
7599 u8 *rc4key = (u8 *) oldoffice34->rc4key;
7600
7601 snprintf (out_buf, len-1, "%s*%08x%08x%08x%08x*%08x%08x%08x%08x*%08x%08x%08x%08x%08x:%02x%02x%02x%02x%02x",
7602 (oldoffice34->version == 3) ? SIGNATURE_OLDOFFICE3 : SIGNATURE_OLDOFFICE4,
7603 salt.salt_buf[0],
7604 salt.salt_buf[1],
7605 salt.salt_buf[2],
7606 salt.salt_buf[3],
7607 byte_swap_32 (oldoffice34->encryptedVerifier[0]),
7608 byte_swap_32 (oldoffice34->encryptedVerifier[1]),
7609 byte_swap_32 (oldoffice34->encryptedVerifier[2]),
7610 byte_swap_32 (oldoffice34->encryptedVerifier[3]),
7611 byte_swap_32 (oldoffice34->encryptedVerifierHash[0]),
7612 byte_swap_32 (oldoffice34->encryptedVerifierHash[1]),
7613 byte_swap_32 (oldoffice34->encryptedVerifierHash[2]),
7614 byte_swap_32 (oldoffice34->encryptedVerifierHash[3]),
7615 byte_swap_32 (oldoffice34->encryptedVerifierHash[4]),
7616 rc4key[0],
7617 rc4key[1],
7618 rc4key[2],
7619 rc4key[3],
7620 rc4key[4]);
7621 }
7622 else if (hash_mode == 10000)
7623 {
7624 // salt
7625
7626 pbkdf2_sha256_t *pbkdf2_sha256s = (pbkdf2_sha256_t *) data.esalts_buf;
7627
7628 pbkdf2_sha256_t *pbkdf2_sha256 = &pbkdf2_sha256s[salt_pos];
7629
7630 unsigned char *salt_buf_ptr = (unsigned char *) pbkdf2_sha256->salt_buf;
7631
7632 // hash
7633
7634 digest_buf[0] = byte_swap_32 (digest_buf[0]);
7635 digest_buf[1] = byte_swap_32 (digest_buf[1]);
7636 digest_buf[2] = byte_swap_32 (digest_buf[2]);
7637 digest_buf[3] = byte_swap_32 (digest_buf[3]);
7638 digest_buf[4] = byte_swap_32 (digest_buf[4]);
7639 digest_buf[5] = byte_swap_32 (digest_buf[5]);
7640 digest_buf[6] = byte_swap_32 (digest_buf[6]);
7641 digest_buf[7] = byte_swap_32 (digest_buf[7]);
7642 digest_buf[8] = 0; // needed for base64_encode ()
7643
7644 char tmp_buf[64] = { 0 };
7645
7646 base64_encode (int_to_base64, (const u8 *) digest_buf, 32, (u8 *) tmp_buf);
7647
7648 // output
7649
7650 snprintf (out_buf, len-1, "%s%i$%s$%s", SIGNATURE_DJANGOPBKDF2, salt.salt_iter + 1, salt_buf_ptr, tmp_buf);
7651 }
7652 else if (hash_mode == 10100)
7653 {
7654 snprintf (out_buf, len-1, "%08x%08x:%u:%u:%08x%08x%08x%08x",
7655 digest_buf[0],
7656 digest_buf[1],
7657 2,
7658 4,
7659 byte_swap_32 (salt.salt_buf[0]),
7660 byte_swap_32 (salt.salt_buf[1]),
7661 byte_swap_32 (salt.salt_buf[2]),
7662 byte_swap_32 (salt.salt_buf[3]));
7663 }
7664 else if (hash_mode == 10200)
7665 {
7666 cram_md5_t *cram_md5s = (cram_md5_t *) data.esalts_buf;
7667
7668 cram_md5_t *cram_md5 = &cram_md5s[salt_pos];
7669
7670 // challenge
7671
7672 char challenge[100] = { 0 };
7673
7674 base64_encode (int_to_base64, (const u8 *) salt.salt_buf, salt.salt_len, (u8 *) challenge);
7675
7676 // response
7677
7678 char tmp_buf[100] = { 0 };
7679
7680 uint tmp_len = snprintf (tmp_buf, 100, "%s %08x%08x%08x%08x",
7681 (char *) cram_md5->user,
7682 digest_buf[0],
7683 digest_buf[1],
7684 digest_buf[2],
7685 digest_buf[3]);
7686
7687 char response[100] = { 0 };
7688
7689 base64_encode (int_to_base64, (const u8 *) tmp_buf, tmp_len, (u8 *) response);
7690
7691 snprintf (out_buf, len-1, "%s%s$%s", SIGNATURE_CRAM_MD5, challenge, response);
7692 }
7693 else if (hash_mode == 10300)
7694 {
7695 char tmp_buf[100] = { 0 };
7696
7697 memcpy (tmp_buf + 0, digest_buf, 20);
7698 memcpy (tmp_buf + 20, salt.salt_buf, salt.salt_len);
7699
7700 uint tmp_len = 20 + salt.salt_len;
7701
7702 // base64 encode it
7703
7704 char base64_encoded[100] = { 0 };
7705
7706 base64_encode (int_to_base64, (const u8 *) tmp_buf, tmp_len, (u8 *) base64_encoded);
7707
7708 snprintf (out_buf, len-1, "%s%i}%s", SIGNATURE_SAPH_SHA1, salt.salt_iter + 1, base64_encoded);
7709 }
7710 else if (hash_mode == 10400)
7711 {
7712 pdf_t *pdfs = (pdf_t *) data.esalts_buf;
7713
7714 pdf_t *pdf = &pdfs[salt_pos];
7715
7716 snprintf (out_buf, len-1, "$pdf$%d*%d*%d*%d*%d*%d*%08x%08x%08x%08x*%d*%08x%08x%08x%08x%08x%08x%08x%08x*%d*%08x%08x%08x%08x%08x%08x%08x%08x",
7717
7718 pdf->V,
7719 pdf->R,
7720 40,
7721 pdf->P,
7722 pdf->enc_md,
7723 pdf->id_len,
7724 byte_swap_32 (pdf->id_buf[0]),
7725 byte_swap_32 (pdf->id_buf[1]),
7726 byte_swap_32 (pdf->id_buf[2]),
7727 byte_swap_32 (pdf->id_buf[3]),
7728 pdf->u_len,
7729 byte_swap_32 (pdf->u_buf[0]),
7730 byte_swap_32 (pdf->u_buf[1]),
7731 byte_swap_32 (pdf->u_buf[2]),
7732 byte_swap_32 (pdf->u_buf[3]),
7733 byte_swap_32 (pdf->u_buf[4]),
7734 byte_swap_32 (pdf->u_buf[5]),
7735 byte_swap_32 (pdf->u_buf[6]),
7736 byte_swap_32 (pdf->u_buf[7]),
7737 pdf->o_len,
7738 byte_swap_32 (pdf->o_buf[0]),
7739 byte_swap_32 (pdf->o_buf[1]),
7740 byte_swap_32 (pdf->o_buf[2]),
7741 byte_swap_32 (pdf->o_buf[3]),
7742 byte_swap_32 (pdf->o_buf[4]),
7743 byte_swap_32 (pdf->o_buf[5]),
7744 byte_swap_32 (pdf->o_buf[6]),
7745 byte_swap_32 (pdf->o_buf[7])
7746 );
7747 }
7748 else if (hash_mode == 10410)
7749 {
7750 pdf_t *pdfs = (pdf_t *) data.esalts_buf;
7751
7752 pdf_t *pdf = &pdfs[salt_pos];
7753
7754 snprintf (out_buf, len-1, "$pdf$%d*%d*%d*%d*%d*%d*%08x%08x%08x%08x*%d*%08x%08x%08x%08x%08x%08x%08x%08x*%d*%08x%08x%08x%08x%08x%08x%08x%08x",
7755
7756 pdf->V,
7757 pdf->R,
7758 40,
7759 pdf->P,
7760 pdf->enc_md,
7761 pdf->id_len,
7762 byte_swap_32 (pdf->id_buf[0]),
7763 byte_swap_32 (pdf->id_buf[1]),
7764 byte_swap_32 (pdf->id_buf[2]),
7765 byte_swap_32 (pdf->id_buf[3]),
7766 pdf->u_len,
7767 byte_swap_32 (pdf->u_buf[0]),
7768 byte_swap_32 (pdf->u_buf[1]),
7769 byte_swap_32 (pdf->u_buf[2]),
7770 byte_swap_32 (pdf->u_buf[3]),
7771 byte_swap_32 (pdf->u_buf[4]),
7772 byte_swap_32 (pdf->u_buf[5]),
7773 byte_swap_32 (pdf->u_buf[6]),
7774 byte_swap_32 (pdf->u_buf[7]),
7775 pdf->o_len,
7776 byte_swap_32 (pdf->o_buf[0]),
7777 byte_swap_32 (pdf->o_buf[1]),
7778 byte_swap_32 (pdf->o_buf[2]),
7779 byte_swap_32 (pdf->o_buf[3]),
7780 byte_swap_32 (pdf->o_buf[4]),
7781 byte_swap_32 (pdf->o_buf[5]),
7782 byte_swap_32 (pdf->o_buf[6]),
7783 byte_swap_32 (pdf->o_buf[7])
7784 );
7785 }
7786 else if (hash_mode == 10420)
7787 {
7788 pdf_t *pdfs = (pdf_t *) data.esalts_buf;
7789
7790 pdf_t *pdf = &pdfs[salt_pos];
7791
7792 u8 *rc4key = (u8 *) pdf->rc4key;
7793
7794 snprintf (out_buf, len-1, "$pdf$%d*%d*%d*%d*%d*%d*%08x%08x%08x%08x*%d*%08x%08x%08x%08x%08x%08x%08x%08x*%d*%08x%08x%08x%08x%08x%08x%08x%08x:%02x%02x%02x%02x%02x",
7795
7796 pdf->V,
7797 pdf->R,
7798 40,
7799 pdf->P,
7800 pdf->enc_md,
7801 pdf->id_len,
7802 byte_swap_32 (pdf->id_buf[0]),
7803 byte_swap_32 (pdf->id_buf[1]),
7804 byte_swap_32 (pdf->id_buf[2]),
7805 byte_swap_32 (pdf->id_buf[3]),
7806 pdf->u_len,
7807 byte_swap_32 (pdf->u_buf[0]),
7808 byte_swap_32 (pdf->u_buf[1]),
7809 byte_swap_32 (pdf->u_buf[2]),
7810 byte_swap_32 (pdf->u_buf[3]),
7811 byte_swap_32 (pdf->u_buf[4]),
7812 byte_swap_32 (pdf->u_buf[5]),
7813 byte_swap_32 (pdf->u_buf[6]),
7814 byte_swap_32 (pdf->u_buf[7]),
7815 pdf->o_len,
7816 byte_swap_32 (pdf->o_buf[0]),
7817 byte_swap_32 (pdf->o_buf[1]),
7818 byte_swap_32 (pdf->o_buf[2]),
7819 byte_swap_32 (pdf->o_buf[3]),
7820 byte_swap_32 (pdf->o_buf[4]),
7821 byte_swap_32 (pdf->o_buf[5]),
7822 byte_swap_32 (pdf->o_buf[6]),
7823 byte_swap_32 (pdf->o_buf[7]),
7824 rc4key[0],
7825 rc4key[1],
7826 rc4key[2],
7827 rc4key[3],
7828 rc4key[4]
7829 );
7830 }
7831 else if (hash_mode == 10500)
7832 {
7833 pdf_t *pdfs = (pdf_t *) data.esalts_buf;
7834
7835 pdf_t *pdf = &pdfs[salt_pos];
7836
7837 if (pdf->id_len == 32)
7838 {
7839 snprintf (out_buf, len-1, "$pdf$%d*%d*%d*%d*%d*%d*%08x%08x%08x%08x%08x%08x%08x%08x*%d*%08x%08x%08x%08x%08x%08x%08x%08x*%d*%08x%08x%08x%08x%08x%08x%08x%08x",
7840
7841 pdf->V,
7842 pdf->R,
7843 128,
7844 pdf->P,
7845 pdf->enc_md,
7846 pdf->id_len,
7847 byte_swap_32 (pdf->id_buf[0]),
7848 byte_swap_32 (pdf->id_buf[1]),
7849 byte_swap_32 (pdf->id_buf[2]),
7850 byte_swap_32 (pdf->id_buf[3]),
7851 byte_swap_32 (pdf->id_buf[4]),
7852 byte_swap_32 (pdf->id_buf[5]),
7853 byte_swap_32 (pdf->id_buf[6]),
7854 byte_swap_32 (pdf->id_buf[7]),
7855 pdf->u_len,
7856 byte_swap_32 (pdf->u_buf[0]),
7857 byte_swap_32 (pdf->u_buf[1]),
7858 byte_swap_32 (pdf->u_buf[2]),
7859 byte_swap_32 (pdf->u_buf[3]),
7860 byte_swap_32 (pdf->u_buf[4]),
7861 byte_swap_32 (pdf->u_buf[5]),
7862 byte_swap_32 (pdf->u_buf[6]),
7863 byte_swap_32 (pdf->u_buf[7]),
7864 pdf->o_len,
7865 byte_swap_32 (pdf->o_buf[0]),
7866 byte_swap_32 (pdf->o_buf[1]),
7867 byte_swap_32 (pdf->o_buf[2]),
7868 byte_swap_32 (pdf->o_buf[3]),
7869 byte_swap_32 (pdf->o_buf[4]),
7870 byte_swap_32 (pdf->o_buf[5]),
7871 byte_swap_32 (pdf->o_buf[6]),
7872 byte_swap_32 (pdf->o_buf[7])
7873 );
7874 }
7875 else
7876 {
7877 snprintf (out_buf, len-1, "$pdf$%d*%d*%d*%d*%d*%d*%08x%08x%08x%08x*%d*%08x%08x%08x%08x%08x%08x%08x%08x*%d*%08x%08x%08x%08x%08x%08x%08x%08x",
7878
7879 pdf->V,
7880 pdf->R,
7881 128,
7882 pdf->P,
7883 pdf->enc_md,
7884 pdf->id_len,
7885 byte_swap_32 (pdf->id_buf[0]),
7886 byte_swap_32 (pdf->id_buf[1]),
7887 byte_swap_32 (pdf->id_buf[2]),
7888 byte_swap_32 (pdf->id_buf[3]),
7889 pdf->u_len,
7890 byte_swap_32 (pdf->u_buf[0]),
7891 byte_swap_32 (pdf->u_buf[1]),
7892 byte_swap_32 (pdf->u_buf[2]),
7893 byte_swap_32 (pdf->u_buf[3]),
7894 byte_swap_32 (pdf->u_buf[4]),
7895 byte_swap_32 (pdf->u_buf[5]),
7896 byte_swap_32 (pdf->u_buf[6]),
7897 byte_swap_32 (pdf->u_buf[7]),
7898 pdf->o_len,
7899 byte_swap_32 (pdf->o_buf[0]),
7900 byte_swap_32 (pdf->o_buf[1]),
7901 byte_swap_32 (pdf->o_buf[2]),
7902 byte_swap_32 (pdf->o_buf[3]),
7903 byte_swap_32 (pdf->o_buf[4]),
7904 byte_swap_32 (pdf->o_buf[5]),
7905 byte_swap_32 (pdf->o_buf[6]),
7906 byte_swap_32 (pdf->o_buf[7])
7907 );
7908 }
7909 }
7910 else if (hash_mode == 10600)
7911 {
7912 uint digest_idx = salt.digests_offset + digest_pos;
7913
7914 hashinfo_t **hashinfo_ptr = data.hash_info;
7915 char *hash_buf = hashinfo_ptr[digest_idx]->orighash;
7916
7917 snprintf (out_buf, len-1, "%s", hash_buf);
7918 }
7919 else if (hash_mode == 10700)
7920 {
7921 uint digest_idx = salt.digests_offset + digest_pos;
7922
7923 hashinfo_t **hashinfo_ptr = data.hash_info;
7924 char *hash_buf = hashinfo_ptr[digest_idx]->orighash;
7925
7926 snprintf (out_buf, len-1, "%s", hash_buf);
7927 }
7928 else if (hash_mode == 10900)
7929 {
7930 uint digest_idx = salt.digests_offset + digest_pos;
7931
7932 hashinfo_t **hashinfo_ptr = data.hash_info;
7933 char *hash_buf = hashinfo_ptr[digest_idx]->orighash;
7934
7935 snprintf (out_buf, len-1, "%s", hash_buf);
7936 }
7937 else if (hash_mode == 11100)
7938 {
7939 u32 salt_challenge = salt.salt_buf[0];
7940
7941 salt_challenge = byte_swap_32 (salt_challenge);
7942
7943 unsigned char *user_name = (unsigned char *) (salt.salt_buf + 1);
7944
7945 snprintf (out_buf, len-1, "%s%s*%08x*%08x%08x%08x%08x",
7946 SIGNATURE_POSTGRESQL_AUTH,
7947 user_name,
7948 salt_challenge,
7949 digest_buf[0],
7950 digest_buf[1],
7951 digest_buf[2],
7952 digest_buf[3]);
7953 }
7954 else if (hash_mode == 11200)
7955 {
7956 snprintf (out_buf, len-1, "%s%s*%08x%08x%08x%08x%08x",
7957 SIGNATURE_MYSQL_AUTH,
7958 (unsigned char *) salt.salt_buf,
7959 digest_buf[0],
7960 digest_buf[1],
7961 digest_buf[2],
7962 digest_buf[3],
7963 digest_buf[4]);
7964 }
7965 else if (hash_mode == 11300)
7966 {
7967 bitcoin_wallet_t *bitcoin_wallets = (bitcoin_wallet_t *) data.esalts_buf;
7968
7969 bitcoin_wallet_t *bitcoin_wallet = &bitcoin_wallets[salt_pos];
7970
7971 const uint cry_master_len = bitcoin_wallet->cry_master_len;
7972 const uint ckey_len = bitcoin_wallet->ckey_len;
7973 const uint public_key_len = bitcoin_wallet->public_key_len;
7974
7975 char *cry_master_buf = (char *) mymalloc ((cry_master_len * 2) + 1);
7976 char *ckey_buf = (char *) mymalloc ((ckey_len * 2) + 1);
7977 char *public_key_buf = (char *) mymalloc ((public_key_len * 2) + 1);
7978
7979 for (uint i = 0, j = 0; i < cry_master_len; i += 1, j += 2)
7980 {
7981 const u8 *ptr = (const u8 *) bitcoin_wallet->cry_master_buf;
7982
7983 sprintf (cry_master_buf + j, "%02x", ptr[i]);
7984 }
7985
7986 for (uint i = 0, j = 0; i < ckey_len; i += 1, j += 2)
7987 {
7988 const u8 *ptr = (const u8 *) bitcoin_wallet->ckey_buf;
7989
7990 sprintf (ckey_buf + j, "%02x", ptr[i]);
7991 }
7992
7993 for (uint i = 0, j = 0; i < public_key_len; i += 1, j += 2)
7994 {
7995 const u8 *ptr = (const u8 *) bitcoin_wallet->public_key_buf;
7996
7997 sprintf (public_key_buf + j, "%02x", ptr[i]);
7998 }
7999
8000 snprintf (out_buf, len-1, "%s%d$%s$%d$%s$%d$%d$%s$%d$%s",
8001 SIGNATURE_BITCOIN_WALLET,
8002 cry_master_len * 2,
8003 cry_master_buf,
8004 salt.salt_len,
8005 (unsigned char *) salt.salt_buf,
8006 salt.salt_iter + 1,
8007 ckey_len * 2,
8008 ckey_buf,
8009 public_key_len * 2,
8010 public_key_buf
8011 );
8012
8013 free (cry_master_buf);
8014 free (ckey_buf);
8015 free (public_key_buf);
8016 }
8017 else if (hash_mode == 11400)
8018 {
8019 uint digest_idx = salt.digests_offset + digest_pos;
8020
8021 hashinfo_t **hashinfo_ptr = data.hash_info;
8022 char *hash_buf = hashinfo_ptr[digest_idx]->orighash;
8023
8024 snprintf (out_buf, len-1, "%s", hash_buf);
8025 }
8026 else if (hash_mode == 11600)
8027 {
8028 seven_zip_t *seven_zips = (seven_zip_t *) data.esalts_buf;
8029
8030 seven_zip_t *seven_zip = &seven_zips[salt_pos];
8031
8032 const uint data_len = seven_zip->data_len;
8033
8034 char *data_buf = (char *) mymalloc ((data_len * 2) + 1);
8035
8036 for (uint i = 0, j = 0; i < data_len; i += 1, j += 2)
8037 {
8038 const u8 *ptr = (const u8 *) seven_zip->data_buf;
8039
8040 sprintf (data_buf + j, "%02x", ptr[i]);
8041 }
8042
8043 snprintf (out_buf, len-1, "%s%u$%u$%u$%s$%u$%08x%08x%08x%08x$%u$%u$%u$%s",
8044 SIGNATURE_SEVEN_ZIP,
8045 0,
8046 salt.salt_sign[0],
8047 0,
8048 (char *) seven_zip->salt_buf,
8049 seven_zip->iv_len,
8050 seven_zip->iv_buf[0],
8051 seven_zip->iv_buf[1],
8052 seven_zip->iv_buf[2],
8053 seven_zip->iv_buf[3],
8054 seven_zip->crc,
8055 seven_zip->data_len,
8056 seven_zip->unpack_size,
8057 data_buf);
8058
8059 free (data_buf);
8060 }
8061 else if (hash_mode == 11700)
8062 {
8063 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x%08x%08x%08x",
8064 digest_buf[0],
8065 digest_buf[1],
8066 digest_buf[2],
8067 digest_buf[3],
8068 digest_buf[4],
8069 digest_buf[5],
8070 digest_buf[6],
8071 digest_buf[7]);
8072 }
8073 else if (hash_mode == 11800)
8074 {
8075 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x",
8076 digest_buf[ 0],
8077 digest_buf[ 1],
8078 digest_buf[ 2],
8079 digest_buf[ 3],
8080 digest_buf[ 4],
8081 digest_buf[ 5],
8082 digest_buf[ 6],
8083 digest_buf[ 7],
8084 digest_buf[ 8],
8085 digest_buf[ 9],
8086 digest_buf[10],
8087 digest_buf[11],
8088 digest_buf[12],
8089 digest_buf[13],
8090 digest_buf[14],
8091 digest_buf[15]);
8092 }
8093 else if (hash_mode == 11900)
8094 {
8095 uint digest_idx = salt.digests_offset + digest_pos;
8096
8097 hashinfo_t **hashinfo_ptr = data.hash_info;
8098 char *hash_buf = hashinfo_ptr[digest_idx]->orighash;
8099
8100 snprintf (out_buf, len-1, "%s", hash_buf);
8101 }
8102 else if (hash_mode == 12000)
8103 {
8104 uint digest_idx = salt.digests_offset + digest_pos;
8105
8106 hashinfo_t **hashinfo_ptr = data.hash_info;
8107 char *hash_buf = hashinfo_ptr[digest_idx]->orighash;
8108
8109 snprintf (out_buf, len-1, "%s", hash_buf);
8110 }
8111 else if (hash_mode == 12100)
8112 {
8113 uint digest_idx = salt.digests_offset + digest_pos;
8114
8115 hashinfo_t **hashinfo_ptr = data.hash_info;
8116 char *hash_buf = hashinfo_ptr[digest_idx]->orighash;
8117
8118 snprintf (out_buf, len-1, "%s", hash_buf);
8119 }
8120 else if (hash_mode == 12200)
8121 {
8122 uint *ptr_digest = digest_buf;
8123 uint *ptr_salt = salt.salt_buf;
8124
8125 snprintf (out_buf, len-1, "%s0$1$%08x%08x$%08x%08x",
8126 SIGNATURE_ECRYPTFS,
8127 ptr_salt[0],
8128 ptr_salt[1],
8129 ptr_digest[0],
8130 ptr_digest[1]);
8131 }
8132 else if (hash_mode == 12300)
8133 {
8134 uint *ptr_digest = digest_buf;
8135 uint *ptr_salt = salt.salt_buf;
8136
8137 snprintf (out_buf, len-1, "%08X%08X%08X%08X%08X%08X%08X%08X%08X%08X%08X%08X%08X%08X%08X%08X%08X%08X%08X%08X",
8138 ptr_digest[ 0], ptr_digest[ 1],
8139 ptr_digest[ 2], ptr_digest[ 3],
8140 ptr_digest[ 4], ptr_digest[ 5],
8141 ptr_digest[ 6], ptr_digest[ 7],
8142 ptr_digest[ 8], ptr_digest[ 9],
8143 ptr_digest[10], ptr_digest[11],
8144 ptr_digest[12], ptr_digest[13],
8145 ptr_digest[14], ptr_digest[15],
8146 ptr_salt[0],
8147 ptr_salt[1],
8148 ptr_salt[2],
8149 ptr_salt[3]);
8150 }
8151 else if (hash_mode == 12400)
8152 {
8153 // encode iteration count
8154
8155 char salt_iter[5] = { 0 };
8156
8157 salt_iter[0] = int_to_itoa64 ((salt.salt_iter ) & 0x3f);
8158 salt_iter[1] = int_to_itoa64 ((salt.salt_iter >> 6) & 0x3f);
8159 salt_iter[2] = int_to_itoa64 ((salt.salt_iter >> 12) & 0x3f);
8160 salt_iter[3] = int_to_itoa64 ((salt.salt_iter >> 18) & 0x3f);
8161 salt_iter[4] = 0;
8162
8163 // encode salt
8164
8165 ptr_salt[0] = int_to_itoa64 ((salt.salt_buf[0] ) & 0x3f);
8166 ptr_salt[1] = int_to_itoa64 ((salt.salt_buf[0] >> 6) & 0x3f);
8167 ptr_salt[2] = int_to_itoa64 ((salt.salt_buf[0] >> 12) & 0x3f);
8168 ptr_salt[3] = int_to_itoa64 ((salt.salt_buf[0] >> 18) & 0x3f);
8169 ptr_salt[4] = 0;
8170
8171 // encode digest
8172
8173 memset (tmp_buf, 0, sizeof (tmp_buf));
8174
8175 digest_buf[0] = byte_swap_32 (digest_buf[0]);
8176 digest_buf[1] = byte_swap_32 (digest_buf[1]);
8177
8178 memcpy (tmp_buf, digest_buf, 8);
8179
8180 base64_encode (int_to_itoa64, (const u8 *) tmp_buf, 8, (u8 *) ptr_plain);
8181
8182 ptr_plain[11] = 0;
8183
8184 // fill the resulting buffer
8185
8186 snprintf (out_buf, len - 1, "_%s%s%s", salt_iter, ptr_salt, ptr_plain);
8187 }
8188 else if (hash_mode == 12500)
8189 {
8190 snprintf (out_buf, len - 1, "%s*0*%08x%08x*%08x%08x%08x%08x",
8191 SIGNATURE_RAR3,
8192 byte_swap_32 (salt.salt_buf[0]),
8193 byte_swap_32 (salt.salt_buf[1]),
8194 salt.salt_buf[2],
8195 salt.salt_buf[3],
8196 salt.salt_buf[4],
8197 salt.salt_buf[5]);
8198 }
8199 else if (hash_mode == 12600)
8200 {
8201 snprintf (out_buf, len - 1, "%08x%08x%08x%08x%08x%08x%08x%08x",
8202 digest_buf[0] + salt.salt_buf_pc[0],
8203 digest_buf[1] + salt.salt_buf_pc[1],
8204 digest_buf[2] + salt.salt_buf_pc[2],
8205 digest_buf[3] + salt.salt_buf_pc[3],
8206 digest_buf[4] + salt.salt_buf_pc[4],
8207 digest_buf[5] + salt.salt_buf_pc[5],
8208 digest_buf[6] + salt.salt_buf_pc[6],
8209 digest_buf[7] + salt.salt_buf_pc[7]);
8210 }
8211 else if (hash_mode == 12700)
8212 {
8213 uint digest_idx = salt.digests_offset + digest_pos;
8214
8215 hashinfo_t **hashinfo_ptr = data.hash_info;
8216 char *hash_buf = hashinfo_ptr[digest_idx]->orighash;
8217
8218 snprintf (out_buf, len-1, "%s", hash_buf);
8219 }
8220 else if (hash_mode == 12800)
8221 {
8222 const u8 *ptr = (const u8 *) salt.salt_buf;
8223
8224 snprintf (out_buf, len-1, "%s,%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x,%d,%08x%08x%08x%08x%08x%08x%08x%08x",
8225 SIGNATURE_MS_DRSR,
8226 ptr[0],
8227 ptr[1],
8228 ptr[2],
8229 ptr[3],
8230 ptr[4],
8231 ptr[5],
8232 ptr[6],
8233 ptr[7],
8234 ptr[8],
8235 ptr[9],
8236 salt.salt_iter + 1,
8237 byte_swap_32 (digest_buf[0]),
8238 byte_swap_32 (digest_buf[1]),
8239 byte_swap_32 (digest_buf[2]),
8240 byte_swap_32 (digest_buf[3]),
8241 byte_swap_32 (digest_buf[4]),
8242 byte_swap_32 (digest_buf[5]),
8243 byte_swap_32 (digest_buf[6]),
8244 byte_swap_32 (digest_buf[7])
8245 );
8246 }
8247 else if (hash_mode == 12900)
8248 {
8249 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x",
8250 salt.salt_buf[ 4],
8251 salt.salt_buf[ 5],
8252 salt.salt_buf[ 6],
8253 salt.salt_buf[ 7],
8254 salt.salt_buf[ 8],
8255 salt.salt_buf[ 9],
8256 salt.salt_buf[10],
8257 salt.salt_buf[11],
8258 byte_swap_32 (digest_buf[0]),
8259 byte_swap_32 (digest_buf[1]),
8260 byte_swap_32 (digest_buf[2]),
8261 byte_swap_32 (digest_buf[3]),
8262 byte_swap_32 (digest_buf[4]),
8263 byte_swap_32 (digest_buf[5]),
8264 byte_swap_32 (digest_buf[6]),
8265 byte_swap_32 (digest_buf[7]),
8266 salt.salt_buf[ 0],
8267 salt.salt_buf[ 1],
8268 salt.salt_buf[ 2],
8269 salt.salt_buf[ 3]
8270 );
8271 }
8272 else if (hash_mode == 13000)
8273 {
8274 rar5_t *rar5s = (rar5_t *) data.esalts_buf;
8275
8276 rar5_t *rar5 = &rar5s[salt_pos];
8277
8278 snprintf (out_buf, len-1, "$rar5$16$%08x%08x%08x%08x$%u$%08x%08x%08x%08x$8$%08x%08x",
8279 salt.salt_buf[0],
8280 salt.salt_buf[1],
8281 salt.salt_buf[2],
8282 salt.salt_buf[3],
8283 salt.salt_sign[0],
8284 rar5->iv[0],
8285 rar5->iv[1],
8286 rar5->iv[2],
8287 rar5->iv[3],
8288 byte_swap_32 (digest_buf[0]),
8289 byte_swap_32 (digest_buf[1])
8290 );
8291 }
8292 else if (hash_mode == 13100)
8293 {
8294 krb5tgs_t *krb5tgss = (krb5tgs_t *) data.esalts_buf;
8295
8296 krb5tgs_t *krb5tgs = &krb5tgss[salt_pos];
8297
8298 u8 *ptr_checksum = (u8 *) krb5tgs->checksum;
8299 u8 *ptr_edata2 = (u8 *) krb5tgs->edata2;
8300
8301 char data[2560 * 4 * 2] = { 0 };
8302
8303 char *ptr_data = data;
8304
8305 for (uint i = 0; i < 16; i++, ptr_data += 2)
8306 sprintf (ptr_data, "%02x", ptr_checksum[i]);
8307
8308 /* skip '$' */
8309 ptr_data++;
8310
8311 for (uint i = 0; i < krb5tgs->edata2_len; i++, ptr_data += 2)
8312 sprintf (ptr_data, "%02x", ptr_edata2[i]);
8313
8314 snprintf (out_buf, len-1, "%s$%s$%s$%s",
8315 SIGNATURE_KRB5TGS,
8316 (char *) krb5tgs->account_info,
8317 data,
8318 data + 33);
8319 }
8320 else if (hash_mode == 13200)
8321 {
8322 snprintf (out_buf, len-1, "%s*%d*%08x%08x%08x%08x*%08x%08x%08x%08x%08x%08x",
8323 SIGNATURE_AXCRYPT,
8324 salt.salt_iter,
8325 salt.salt_buf[0],
8326 salt.salt_buf[1],
8327 salt.salt_buf[2],
8328 salt.salt_buf[3],
8329 salt.salt_buf[4],
8330 salt.salt_buf[5],
8331 salt.salt_buf[6],
8332 salt.salt_buf[7],
8333 salt.salt_buf[8],
8334 salt.salt_buf[9]);
8335 }
8336 else if (hash_mode == 13300)
8337 {
8338 snprintf (out_buf, len-1, "%s$%08x%08x%08x%08x",
8339 SIGNATURE_AXCRYPT_SHA1,
8340 digest_buf[0],
8341 digest_buf[1],
8342 digest_buf[2],
8343 digest_buf[3]);
8344 }
8345 else if (hash_mode == 13400)
8346 {
8347 keepass_t *keepasss = (keepass_t *) data.esalts_buf;
8348
8349 keepass_t *keepass = &keepasss[salt_pos];
8350
8351 u32 version = (u32) keepass->version;
8352 u32 rounds = salt.salt_iter;
8353 u32 algorithm = (u32) keepass->algorithm;
8354 u32 keyfile_len = (u32) keepass->keyfile_len;
8355
8356 u32 *ptr_final_random_seed = (u32 *) keepass->final_random_seed ;
8357 u32 *ptr_transf_random_seed = (u32 *) keepass->transf_random_seed ;
8358 u32 *ptr_enc_iv = (u32 *) keepass->enc_iv ;
8359 u32 *ptr_contents_hash = (u32 *) keepass->contents_hash ;
8360 u32 *ptr_keyfile = (u32 *) keepass->keyfile ;
8361
8362 /* specific to version 1 */
8363 u32 contents_len;
8364 u32 *ptr_contents;
8365
8366 /* specific to version 2 */
8367 u32 expected_bytes_len;
8368 u32 *ptr_expected_bytes;
8369
8370 u32 final_random_seed_len;
8371 u32 transf_random_seed_len;
8372 u32 enc_iv_len;
8373 u32 contents_hash_len;
8374
8375 transf_random_seed_len = 8;
8376 enc_iv_len = 4;
8377 contents_hash_len = 8;
8378 final_random_seed_len = 8;
8379
8380 if (version == 1)
8381 final_random_seed_len = 4;
8382
8383 snprintf (out_buf, len-1, "%s*%d*%d*%d",
8384 SIGNATURE_KEEPASS,
8385 version,
8386 rounds,
8387 algorithm);
8388
8389 char *ptr_data = out_buf;
8390
8391 ptr_data += strlen(out_buf);
8392
8393 *ptr_data = '*';
8394 ptr_data++;
8395
8396 for (uint i = 0; i < final_random_seed_len; i++, ptr_data += 8)
8397 sprintf (ptr_data, "%08x", ptr_final_random_seed[i]);
8398
8399 *ptr_data = '*';
8400 ptr_data++;
8401
8402 for (uint i = 0; i < transf_random_seed_len; i++, ptr_data += 8)
8403 sprintf (ptr_data, "%08x", ptr_transf_random_seed[i]);
8404
8405 *ptr_data = '*';
8406 ptr_data++;
8407
8408 for (uint i = 0; i < enc_iv_len; i++, ptr_data += 8)
8409 sprintf (ptr_data, "%08x", ptr_enc_iv[i]);
8410
8411 *ptr_data = '*';
8412 ptr_data++;
8413
8414 if (version == 1)
8415 {
8416 contents_len = (u32) keepass->contents_len;
8417 ptr_contents = (u32 *) keepass->contents;
8418
8419 for (uint i = 0; i < contents_hash_len; i++, ptr_data += 8)
8420 sprintf (ptr_data, "%08x", ptr_contents_hash[i]);
8421
8422 *ptr_data = '*';
8423 ptr_data++;
8424
8425 /* inline flag */
8426 *ptr_data = '1';
8427 ptr_data++;
8428
8429 *ptr_data = '*';
8430 ptr_data++;
8431
8432 char ptr_contents_len[10] = { 0 };
8433
8434 sprintf ((char*) ptr_contents_len, "%d", contents_len);
8435
8436 sprintf (ptr_data, "%d", contents_len);
8437
8438 ptr_data += strlen(ptr_contents_len);
8439
8440 *ptr_data = '*';
8441 ptr_data++;
8442
8443 for (uint i = 0; i < contents_len / 4; i++, ptr_data += 8)
8444 sprintf (ptr_data, "%08x", ptr_contents[i]);
8445 }
8446 else if (version == 2)
8447 {
8448 expected_bytes_len = 8;
8449 ptr_expected_bytes = (u32 *) keepass->expected_bytes ;
8450
8451 for (uint i = 0; i < expected_bytes_len; i++, ptr_data += 8)
8452 sprintf (ptr_data, "%08x", ptr_expected_bytes[i]);
8453
8454 *ptr_data = '*';
8455 ptr_data++;
8456
8457 for (uint i = 0; i < contents_hash_len; i++, ptr_data += 8)
8458 sprintf (ptr_data, "%08x", ptr_contents_hash[i]);
8459 }
8460 if (keyfile_len)
8461 {
8462 *ptr_data = '*';
8463 ptr_data++;
8464
8465 /* inline flag */
8466 *ptr_data = '1';
8467 ptr_data++;
8468
8469 *ptr_data = '*';
8470 ptr_data++;
8471
8472 sprintf (ptr_data, "%d", keyfile_len);
8473
8474 ptr_data += 2;
8475
8476 *ptr_data = '*';
8477 ptr_data++;
8478
8479 for (uint i = 0; i < 8; i++, ptr_data += 8)
8480 sprintf (ptr_data, "%08x", ptr_keyfile[i]);
8481 }
8482 }
8483 else if (hash_mode == 13500)
8484 {
8485 pstoken_t *pstokens = (pstoken_t *) data.esalts_buf;
8486 pstoken_t *pstoken = &pstokens[salt_pos];
8487
8488 uint mysalt_len = pstoken->salt_len > 512 ? 512 : pstoken->salt_len;
8489
8490 u8 pstoken_tmp[mysalt_len + 1];
8491
8492 memset(pstoken_tmp, 0, mysalt_len + 1);
8493
8494 for (uint i = 0; i < mysalt_len; i++)
8495 {
8496 snprintf((char *)(pstoken_tmp + i), (size_t)2, "%02x", pstoken->salt_buf[i]);
8497 }
8498
8499 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x:%s",
8500 digest_buf[0],
8501 digest_buf[1],
8502 digest_buf[2],
8503 digest_buf[3],
8504 digest_buf[4],
8505 pstoken_tmp);
8506 }
8507 else
8508 {
8509 if (hash_type == HASH_TYPE_MD4)
8510 {
8511 snprintf (out_buf, 255, "%08x%08x%08x%08x",
8512 digest_buf[0],
8513 digest_buf[1],
8514 digest_buf[2],
8515 digest_buf[3]);
8516 }
8517 else if (hash_type == HASH_TYPE_MD5)
8518 {
8519 snprintf (out_buf, len-1, "%08x%08x%08x%08x",
8520 digest_buf[0],
8521 digest_buf[1],
8522 digest_buf[2],
8523 digest_buf[3]);
8524 }
8525 else if (hash_type == HASH_TYPE_SHA1)
8526 {
8527 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x",
8528 digest_buf[0],
8529 digest_buf[1],
8530 digest_buf[2],
8531 digest_buf[3],
8532 digest_buf[4]);
8533 }
8534 else if (hash_type == HASH_TYPE_SHA256)
8535 {
8536 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x%08x%08x%08x",
8537 digest_buf[0],
8538 digest_buf[1],
8539 digest_buf[2],
8540 digest_buf[3],
8541 digest_buf[4],
8542 digest_buf[5],
8543 digest_buf[6],
8544 digest_buf[7]);
8545 }
8546 else if (hash_type == HASH_TYPE_SHA384)
8547 {
8548 uint *ptr = digest_buf;
8549
8550 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x",
8551 ptr[ 1], ptr[ 0],
8552 ptr[ 3], ptr[ 2],
8553 ptr[ 5], ptr[ 4],
8554 ptr[ 7], ptr[ 6],
8555 ptr[ 9], ptr[ 8],
8556 ptr[11], ptr[10]);
8557 }
8558 else if (hash_type == HASH_TYPE_SHA512)
8559 {
8560 uint *ptr = digest_buf;
8561
8562 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x",
8563 ptr[ 1], ptr[ 0],
8564 ptr[ 3], ptr[ 2],
8565 ptr[ 5], ptr[ 4],
8566 ptr[ 7], ptr[ 6],
8567 ptr[ 9], ptr[ 8],
8568 ptr[11], ptr[10],
8569 ptr[13], ptr[12],
8570 ptr[15], ptr[14]);
8571 }
8572 else if (hash_type == HASH_TYPE_LM)
8573 {
8574 snprintf (out_buf, len-1, "%08x%08x",
8575 digest_buf[0],
8576 digest_buf[1]);
8577 }
8578 else if (hash_type == HASH_TYPE_ORACLEH)
8579 {
8580 snprintf (out_buf, len-1, "%08X%08X",
8581 digest_buf[0],
8582 digest_buf[1]);
8583 }
8584 else if (hash_type == HASH_TYPE_BCRYPT)
8585 {
8586 base64_encode (int_to_bf64, (const u8 *) salt.salt_buf, 16, (u8 *) tmp_buf + 0);
8587 base64_encode (int_to_bf64, (const u8 *) digest_buf, 23, (u8 *) tmp_buf + 22);
8588
8589 tmp_buf[22 + 31] = 0; // base64_encode wants to pad
8590
8591 snprintf (out_buf, len-1, "%s$%s", (char *) salt.salt_sign, tmp_buf);
8592 }
8593 else if (hash_type == HASH_TYPE_KECCAK)
8594 {
8595 uint *ptr = digest_buf;
8596
8597 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x",
8598 ptr[ 1], ptr[ 0],
8599 ptr[ 3], ptr[ 2],
8600 ptr[ 5], ptr[ 4],
8601 ptr[ 7], ptr[ 6],
8602 ptr[ 9], ptr[ 8],
8603 ptr[11], ptr[10],
8604 ptr[13], ptr[12],
8605 ptr[15], ptr[14],
8606 ptr[17], ptr[16],
8607 ptr[19], ptr[18],
8608 ptr[21], ptr[20],
8609 ptr[23], ptr[22],
8610 ptr[25], ptr[24],
8611 ptr[27], ptr[26],
8612 ptr[29], ptr[28],
8613 ptr[31], ptr[30],
8614 ptr[33], ptr[32],
8615 ptr[35], ptr[34],
8616 ptr[37], ptr[36],
8617 ptr[39], ptr[38],
8618 ptr[41], ptr[30],
8619 ptr[43], ptr[42],
8620 ptr[45], ptr[44],
8621 ptr[47], ptr[46],
8622 ptr[49], ptr[48]
8623 );
8624
8625 out_buf[salt.keccak_mdlen * 2] = 0;
8626 }
8627 else if (hash_type == HASH_TYPE_RIPEMD160)
8628 {
8629 snprintf (out_buf, 255, "%08x%08x%08x%08x%08x",
8630 digest_buf[0],
8631 digest_buf[1],
8632 digest_buf[2],
8633 digest_buf[3],
8634 digest_buf[4]);
8635 }
8636 else if (hash_type == HASH_TYPE_WHIRLPOOL)
8637 {
8638 digest_buf[ 0] = digest_buf[ 0];
8639 digest_buf[ 1] = digest_buf[ 1];
8640 digest_buf[ 2] = digest_buf[ 2];
8641 digest_buf[ 3] = digest_buf[ 3];
8642 digest_buf[ 4] = digest_buf[ 4];
8643 digest_buf[ 5] = digest_buf[ 5];
8644 digest_buf[ 6] = digest_buf[ 6];
8645 digest_buf[ 7] = digest_buf[ 7];
8646 digest_buf[ 8] = digest_buf[ 8];
8647 digest_buf[ 9] = digest_buf[ 9];
8648 digest_buf[10] = digest_buf[10];
8649 digest_buf[11] = digest_buf[11];
8650 digest_buf[12] = digest_buf[12];
8651 digest_buf[13] = digest_buf[13];
8652 digest_buf[14] = digest_buf[14];
8653 digest_buf[15] = digest_buf[15];
8654
8655 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x%08x",
8656 digest_buf[ 0],
8657 digest_buf[ 1],
8658 digest_buf[ 2],
8659 digest_buf[ 3],
8660 digest_buf[ 4],
8661 digest_buf[ 5],
8662 digest_buf[ 6],
8663 digest_buf[ 7],
8664 digest_buf[ 8],
8665 digest_buf[ 9],
8666 digest_buf[10],
8667 digest_buf[11],
8668 digest_buf[12],
8669 digest_buf[13],
8670 digest_buf[14],
8671 digest_buf[15]);
8672 }
8673 else if (hash_type == HASH_TYPE_GOST)
8674 {
8675 snprintf (out_buf, len-1, "%08x%08x%08x%08x%08x%08x%08x%08x",
8676 digest_buf[0],
8677 digest_buf[1],
8678 digest_buf[2],
8679 digest_buf[3],
8680 digest_buf[4],
8681 digest_buf[5],
8682 digest_buf[6],
8683 digest_buf[7]);
8684 }
8685 else if (hash_type == HASH_TYPE_MYSQL)
8686 {
8687 snprintf (out_buf, len-1, "%08x%08x",
8688 digest_buf[0],
8689 digest_buf[1]);
8690 }
8691 else if (hash_type == HASH_TYPE_LOTUS5)
8692 {
8693 snprintf (out_buf, len-1, "%08x%08x%08x%08x",
8694 digest_buf[0],
8695 digest_buf[1],
8696 digest_buf[2],
8697 digest_buf[3]);
8698 }
8699 else if (hash_type == HASH_TYPE_LOTUS6)
8700 {
8701 digest_buf[ 0] = byte_swap_32 (digest_buf[ 0]);
8702 digest_buf[ 1] = byte_swap_32 (digest_buf[ 1]);
8703 digest_buf[ 2] = byte_swap_32 (digest_buf[ 2]);
8704 digest_buf[ 3] = byte_swap_32 (digest_buf[ 3]);
8705
8706 char buf[16] = { 0 };
8707
8708 memcpy (buf + 0, salt.salt_buf, 5);
8709 memcpy (buf + 5, digest_buf, 9);
8710
8711 buf[3] -= -4;
8712
8713 base64_encode (int_to_lotus64, (const u8 *) buf, 14, (u8 *) tmp_buf);
8714
8715 tmp_buf[18] = salt.salt_buf_pc[7];
8716 tmp_buf[19] = 0;
8717
8718 snprintf (out_buf, len-1, "(G%s)", tmp_buf);
8719 }
8720 else if (hash_type == HASH_TYPE_LOTUS8)
8721 {
8722 char buf[52] = { 0 };
8723
8724 // salt
8725
8726 memcpy (buf + 0, salt.salt_buf, 16);
8727
8728 buf[3] -= -4;
8729
8730 // iteration
8731
8732 snprintf (buf + 16, 11, "%010i", salt.salt_iter + 1);
8733
8734 // chars
8735
8736 buf[26] = salt.salt_buf_pc[0];
8737 buf[27] = salt.salt_buf_pc[1];
8738
8739 // digest
8740
8741 memcpy (buf + 28, digest_buf, 8);
8742
8743 base64_encode (int_to_lotus64, (const u8 *) buf, 36, (u8 *) tmp_buf);
8744
8745 tmp_buf[49] = 0;
8746
8747 snprintf (out_buf, len-1, "(H%s)", tmp_buf);
8748 }
8749 else if (hash_type == HASH_TYPE_CRC32)
8750 {
8751 snprintf (out_buf, len-1, "%08x", byte_swap_32 (digest_buf[0]));
8752 }
8753 }
8754
8755 if (salt_type == SALT_TYPE_INTERN)
8756 {
8757 size_t pos = strlen (out_buf);
8758
8759 out_buf[pos] = data.separator;
8760
8761 char *ptr = (char *) salt.salt_buf;
8762
8763 memcpy (out_buf + pos + 1, ptr, salt.salt_len);
8764
8765 out_buf[pos + 1 + salt.salt_len] = 0;
8766 }
8767 }
8768
8769 void to_hccap_t (hccap_t *hccap, uint salt_pos, uint digest_pos)
8770 {
8771 memset (hccap, 0, sizeof (hccap_t));
8772
8773 salt_t *salt = &data.salts_buf[salt_pos];
8774
8775 memcpy (hccap->essid, salt->salt_buf, salt->salt_len);
8776
8777 wpa_t *wpas = (wpa_t *) data.esalts_buf;
8778 wpa_t *wpa = &wpas[salt_pos];
8779
8780 hccap->keyver = wpa->keyver;
8781
8782 hccap->eapol_size = wpa->eapol_size;
8783
8784 if (wpa->keyver != 1)
8785 {
8786 uint eapol_tmp[64] = { 0 };
8787
8788 for (uint i = 0; i < 64; i++)
8789 {
8790 eapol_tmp[i] = byte_swap_32 (wpa->eapol[i]);
8791 }
8792
8793 memcpy (hccap->eapol, eapol_tmp, wpa->eapol_size);
8794 }
8795 else
8796 {
8797 memcpy (hccap->eapol, wpa->eapol, wpa->eapol_size);
8798 }
8799
8800 memcpy (hccap->mac1, wpa->orig_mac1, 6);
8801 memcpy (hccap->mac2, wpa->orig_mac2, 6);
8802 memcpy (hccap->nonce1, wpa->orig_nonce1, 32);
8803 memcpy (hccap->nonce2, wpa->orig_nonce2, 32);
8804
8805 char *digests_buf_ptr = (char *) data.digests_buf;
8806
8807 uint dgst_size = data.dgst_size;
8808
8809 uint *digest_ptr = (uint *) (digests_buf_ptr + (data.salts_buf[salt_pos].digests_offset * dgst_size) + (digest_pos * dgst_size));
8810
8811 if (wpa->keyver != 1)
8812 {
8813 uint digest_tmp[4] = { 0 };
8814
8815 digest_tmp[0] = byte_swap_32 (digest_ptr[0]);
8816 digest_tmp[1] = byte_swap_32 (digest_ptr[1]);
8817 digest_tmp[2] = byte_swap_32 (digest_ptr[2]);
8818 digest_tmp[3] = byte_swap_32 (digest_ptr[3]);
8819
8820 memcpy (hccap->keymic, digest_tmp, 16);
8821 }
8822 else
8823 {
8824 memcpy (hccap->keymic, digest_ptr, 16);
8825 }
8826 }
8827
8828 void SuspendThreads ()
8829 {
8830 if (data.devices_status == STATUS_RUNNING)
8831 {
8832 hc_timer_set (&data.timer_paused);
8833
8834 data.devices_status = STATUS_PAUSED;
8835
8836 log_info ("Paused");
8837 }
8838 }
8839
8840 void ResumeThreads ()
8841 {
8842 if (data.devices_status == STATUS_PAUSED)
8843 {
8844 float ms_paused;
8845
8846 hc_timer_get (data.timer_paused, ms_paused);
8847
8848 data.ms_paused += ms_paused;
8849
8850 data.devices_status = STATUS_RUNNING;
8851
8852 log_info ("Resumed");
8853 }
8854 }
8855
8856 void bypass ()
8857 {
8858 if (data.devices_status != STATUS_RUNNING) return;
8859
8860 data.devices_status = STATUS_BYPASS;
8861
8862 log_info ("Next dictionary / mask in queue selected, bypassing current one");
8863 }
8864
8865 void stop_at_checkpoint ()
8866 {
8867 if (data.devices_status != STATUS_STOP_AT_CHECKPOINT)
8868 {
8869 if (data.devices_status != STATUS_RUNNING) return;
8870 }
8871
8872 // this feature only makes sense if --restore-disable was not specified
8873
8874 if (data.restore_disable == 1)
8875 {
8876 log_info ("WARNING: this feature is disabled when --restore-disable was specified");
8877
8878 return;
8879 }
8880
8881 // check if monitoring of Restore Point updates should be enabled or disabled
8882
8883 if (data.devices_status != STATUS_STOP_AT_CHECKPOINT)
8884 {
8885 data.devices_status = STATUS_STOP_AT_CHECKPOINT;
8886
8887 // save the current restore point value
8888
8889 data.checkpoint_cur_words = get_lowest_words_done ();
8890
8891 log_info ("Checkpoint enabled: will quit at next Restore Point update");
8892 }
8893 else
8894 {
8895 data.devices_status = STATUS_RUNNING;
8896
8897 // reset the global value for checkpoint checks
8898
8899 data.checkpoint_cur_words = 0;
8900
8901 log_info ("Checkpoint disabled: Restore Point updates will no longer be monitored");
8902 }
8903 }
8904
8905 void myabort ()
8906 {
8907 if (data.devices_status == STATUS_INIT) return;
8908 if (data.devices_status == STATUS_STARTING) return;
8909
8910 data.devices_status = STATUS_ABORTED;
8911 }
8912
8913 void myquit ()
8914 {
8915 if (data.devices_status == STATUS_INIT) return;
8916 if (data.devices_status == STATUS_STARTING) return;
8917
8918 data.devices_status = STATUS_QUIT;
8919 }
8920
8921 void load_kernel (const char *kernel_file, int num_devices, size_t *kernel_lengths, const u8 **kernel_sources)
8922 {
8923 FILE *fp = fopen (kernel_file, "rb");
8924
8925 if (fp != NULL)
8926 {
8927 struct stat st;
8928
8929 memset (&st, 0, sizeof (st));
8930
8931 stat (kernel_file, &st);
8932
8933 u8 *buf = (u8 *) mymalloc (st.st_size + 1);
8934
8935 size_t num_read = fread (buf, sizeof (u8), st.st_size, fp);
8936
8937 if (num_read != (size_t) st.st_size)
8938 {
8939 log_error ("ERROR: %s: %s", kernel_file, strerror (errno));
8940
8941 exit (-1);
8942 }
8943
8944 fclose (fp);
8945
8946 buf[st.st_size] = 0;
8947
8948 for (int i = 0; i < num_devices; i++)
8949 {
8950 kernel_lengths[i] = (size_t) st.st_size;
8951
8952 kernel_sources[i] = buf;
8953 }
8954 }
8955 else
8956 {
8957 log_error ("ERROR: %s: %s", kernel_file, strerror (errno));
8958
8959 exit (-1);
8960 }
8961
8962 return;
8963 }
8964
8965 void writeProgramBin (char *dst, u8 *binary, size_t binary_size)
8966 {
8967 if (binary_size > 0)
8968 {
8969 FILE *fp = fopen (dst, "wb");
8970
8971 lock_file (fp);
8972 fwrite (binary, sizeof (u8), binary_size, fp);
8973
8974 fflush (fp);
8975 fclose (fp);
8976 }
8977 }
8978
8979 /**
8980 * restore
8981 */
8982
8983 restore_data_t *init_restore (int argc, char **argv)
8984 {
8985 restore_data_t *rd = (restore_data_t *) mymalloc (sizeof (restore_data_t));
8986
8987 if (data.restore_disable == 0)
8988 {
8989 FILE *fp = fopen (data.eff_restore_file, "rb");
8990
8991 if (fp)
8992 {
8993 size_t nread = fread (rd, sizeof (restore_data_t), 1, fp);
8994
8995 if (nread != 1)
8996 {
8997 log_error ("ERROR: cannot read %s", data.eff_restore_file);
8998
8999 exit (-1);
9000 }
9001
9002 fclose (fp);
9003
9004 if (rd->pid)
9005 {
9006 char *pidbin = (char *) mymalloc (HCBUFSIZ);
9007
9008 int pidbin_len = -1;
9009
9010 #ifdef _POSIX
9011 snprintf (pidbin, HCBUFSIZ - 1, "/proc/%d/cmdline", rd->pid);
9012
9013 FILE *fd = fopen (pidbin, "rb");
9014
9015 if (fd)
9016 {
9017 pidbin_len = fread (pidbin, 1, HCBUFSIZ, fd);
9018
9019 pidbin[pidbin_len] = 0;
9020
9021 fclose (fd);
9022
9023 char *argv0_r = strrchr (argv[0], '/');
9024
9025 char *pidbin_r = strrchr (pidbin, '/');
9026
9027 if (argv0_r == NULL) argv0_r = argv[0];
9028
9029 if (pidbin_r == NULL) pidbin_r = pidbin;
9030
9031 if (strcmp (argv0_r, pidbin_r) == 0)
9032 {
9033 log_error ("ERROR: already an instance %s running on pid %d", pidbin, rd->pid);
9034
9035 exit (-1);
9036 }
9037 }
9038
9039 #elif _WIN
9040 HANDLE hProcess = OpenProcess (PROCESS_ALL_ACCESS, FALSE, rd->pid);
9041
9042 char *pidbin2 = (char *) mymalloc (HCBUFSIZ);
9043
9044 int pidbin2_len = -1;
9045
9046 pidbin_len = GetModuleFileName (NULL, pidbin, HCBUFSIZ);
9047 pidbin2_len = GetModuleFileNameEx (hProcess, NULL, pidbin2, HCBUFSIZ);
9048
9049 pidbin[pidbin_len] = 0;
9050 pidbin2[pidbin2_len] = 0;
9051
9052 if (pidbin2_len)
9053 {
9054 if (strcmp (pidbin, pidbin2) == 0)
9055 {
9056 log_error ("ERROR: already an instance %s running on pid %d", pidbin2, rd->pid);
9057
9058 exit (-1);
9059 }
9060 }
9061
9062 myfree (pidbin2);
9063
9064 #endif
9065
9066 myfree (pidbin);
9067 }
9068
9069 if (rd->version_bin < RESTORE_MIN)
9070 {
9071 log_error ("ERROR: cannot use outdated %s. Please remove it.", data.eff_restore_file);
9072
9073 exit (-1);
9074 }
9075 }
9076 }
9077
9078 memset (rd, 0, sizeof (restore_data_t));
9079
9080 rd->version_bin = VERSION_BIN;
9081
9082 #ifdef _POSIX
9083 rd->pid = getpid ();
9084 #elif _WIN
9085 rd->pid = GetCurrentProcessId ();
9086 #endif
9087
9088 if (getcwd (rd->cwd, 255) == NULL)
9089 {
9090 myfree (rd);
9091
9092 return (NULL);
9093 }
9094
9095 rd->argc = argc;
9096 rd->argv = argv;
9097
9098 return (rd);
9099 }
9100
9101 void read_restore (const char *eff_restore_file, restore_data_t *rd)
9102 {
9103 FILE *fp = fopen (eff_restore_file, "rb");
9104
9105 if (fp == NULL)
9106 {
9107 log_error ("ERROR: restore file '%s': %s", eff_restore_file, strerror (errno));
9108
9109 exit (-1);
9110 }
9111
9112 if (fread (rd, sizeof (restore_data_t), 1, fp) != 1)
9113 {
9114 log_error ("ERROR: cannot read %s", eff_restore_file);
9115
9116 exit (-1);
9117 }
9118
9119 rd->argv = (char **) mycalloc (rd->argc, sizeof (char *));
9120
9121 char *buf = (char *) mymalloc (HCBUFSIZ);
9122
9123 for (uint i = 0; i < rd->argc; i++)
9124 {
9125 if (fgets (buf, HCBUFSIZ - 1, fp) == NULL)
9126 {
9127 log_error ("ERROR: cannot read %s", eff_restore_file);
9128
9129 exit (-1);
9130 }
9131
9132 size_t len = strlen (buf);
9133
9134 if (len) buf[len - 1] = 0;
9135
9136 rd->argv[i] = mystrdup (buf);
9137 }
9138
9139 myfree (buf);
9140
9141 fclose (fp);
9142
9143 log_info ("INFO: Changing current working directory to the path found within the .restore file: '%s'", rd->cwd);
9144
9145 if (chdir (rd->cwd))
9146 {
9147 log_error ("ERROR: The directory '%s' does not exist. It is needed to restore (--restore) the session.\n"
9148 " You could either create this directory (or link it) or update the .restore file using e.g. the analyze_hc_restore.pl tool:\n"
9149 " https://github.com/philsmd/analyze_hc_restore\n"
9150 " The directory must be relative to (or contain) all files/folders mentioned within the command line.", rd->cwd);
9151
9152 exit (-1);
9153 }
9154 }
9155
9156 u64 get_lowest_words_done ()
9157 {
9158 u64 words_cur = -1;
9159
9160 for (uint device_id = 0; device_id < data.devices_cnt; device_id++)
9161 {
9162 hc_device_param_t *device_param = &data.devices_param[device_id];
9163
9164 if (device_param->skipped) continue;
9165
9166 const u64 words_done = device_param->words_done;
9167
9168 if (words_done < words_cur) words_cur = words_done;
9169 }
9170
9171 // It's possible that a device's workload isn't finished right after a restore-case.
9172 // In that case, this function would return 0 and overwrite the real restore point
9173 // There's also data.words_cur which is set to rd->words_cur but it changes while
9174 // the attack is running therefore we should stick to rd->words_cur.
9175 // Note that -s influences rd->words_cur we should keep a close look on that.
9176
9177 if (words_cur < data.rd->words_cur) words_cur = data.rd->words_cur;
9178
9179 return words_cur;
9180 }
9181
9182 void write_restore (const char *new_restore_file, restore_data_t *rd)
9183 {
9184 u64 words_cur = get_lowest_words_done ();
9185
9186 rd->words_cur = words_cur;
9187
9188 FILE *fp = fopen (new_restore_file, "wb");
9189
9190 if (fp == NULL)
9191 {
9192 log_error ("ERROR: %s: %s", new_restore_file, strerror (errno));
9193
9194 exit (-1);
9195 }
9196
9197 if (setvbuf (fp, NULL, _IONBF, 0))
9198 {
9199 log_error ("ERROR: setvbuf file '%s': %s", new_restore_file, strerror (errno));
9200
9201 exit (-1);
9202 }
9203
9204 fwrite (rd, sizeof (restore_data_t), 1, fp);
9205
9206 for (uint i = 0; i < rd->argc; i++)
9207 {
9208 fprintf (fp, "%s", rd->argv[i]);
9209 fputc ('\n', fp);
9210 }
9211
9212 fflush (fp);
9213
9214 fsync (fileno (fp));
9215
9216 fclose (fp);
9217 }
9218
9219 void cycle_restore ()
9220 {
9221 const char *eff_restore_file = data.eff_restore_file;
9222 const char *new_restore_file = data.new_restore_file;
9223
9224 restore_data_t *rd = data.rd;
9225
9226 write_restore (new_restore_file, rd);
9227
9228 struct stat st;
9229
9230 memset (&st, 0, sizeof(st));
9231
9232 if (stat (eff_restore_file, &st) == 0)
9233 {
9234 if (unlink (eff_restore_file))
9235 {
9236 log_info ("WARN: unlink file '%s': %s", eff_restore_file, strerror (errno));
9237 }
9238 }
9239
9240 if (rename (new_restore_file, eff_restore_file))
9241 {
9242 log_info ("WARN: rename file '%s' to '%s': %s", new_restore_file, eff_restore_file, strerror (errno));
9243 }
9244 }
9245
9246 void check_checkpoint ()
9247 {
9248 // if (data.restore_disable == 1) break; (this is already implied by previous checks)
9249
9250 u64 words_cur = get_lowest_words_done ();
9251
9252 if (words_cur != data.checkpoint_cur_words)
9253 {
9254 myabort ();
9255 }
9256 }
9257
9258 /**
9259 * tuning db
9260 */
9261
9262 void tuning_db_destroy (tuning_db_t *tuning_db)
9263 {
9264 int i;
9265
9266 for (i = 0; i < tuning_db->alias_cnt; i++)
9267 {
9268 tuning_db_alias_t *alias = &tuning_db->alias_buf[i];
9269
9270 myfree (alias->device_name);
9271 myfree (alias->alias_name);
9272 }
9273
9274 for (i = 0; i < tuning_db->entry_cnt; i++)
9275 {
9276 tuning_db_entry_t *entry = &tuning_db->entry_buf[i];
9277
9278 myfree (entry->device_name);
9279 }
9280
9281 myfree (tuning_db->alias_buf);
9282 myfree (tuning_db->entry_buf);
9283
9284 myfree (tuning_db);
9285 }
9286
9287 tuning_db_t *tuning_db_alloc (FILE *fp)
9288 {
9289 tuning_db_t *tuning_db = (tuning_db_t *) mymalloc (sizeof (tuning_db_t));
9290
9291 int num_lines = count_lines (fp);
9292
9293 // a bit over-allocated
9294
9295 tuning_db->alias_buf = (tuning_db_alias_t *) mycalloc (num_lines + 1, sizeof (tuning_db_alias_t));
9296 tuning_db->alias_cnt = 0;
9297
9298 tuning_db->entry_buf = (tuning_db_entry_t *) mycalloc (num_lines + 1, sizeof (tuning_db_entry_t));
9299 tuning_db->entry_cnt = 0;
9300
9301 return tuning_db;
9302 }
9303
9304 tuning_db_t *tuning_db_init (const char *tuning_db_file)
9305 {
9306 FILE *fp = fopen (tuning_db_file, "rb");
9307
9308 if (fp == NULL)
9309 {
9310 log_error ("%s: %s", tuning_db_file, strerror (errno));
9311
9312 exit (-1);
9313 }
9314
9315 tuning_db_t *tuning_db = tuning_db_alloc (fp);
9316
9317 rewind (fp);
9318
9319 int line_num = 0;
9320
9321 char *buf = (char *) mymalloc (HCBUFSIZ);
9322
9323 while (!feof (fp))
9324 {
9325 char *line_buf = fgets (buf, HCBUFSIZ - 1, fp);
9326
9327 if (line_buf == NULL) break;
9328
9329 line_num++;
9330
9331 const int line_len = in_superchop (line_buf);
9332
9333 if (line_len == 0) continue;
9334
9335 if (line_buf[0] == '#') continue;
9336
9337 // start processing
9338
9339 char *token_ptr[7] = { NULL };
9340
9341 int token_cnt = 0;
9342
9343 char *next = strtok (line_buf, "\t ");
9344
9345 token_ptr[token_cnt] = next;
9346
9347 token_cnt++;
9348
9349 while ((next = strtok (NULL, "\t ")) != NULL)
9350 {
9351 token_ptr[token_cnt] = next;
9352
9353 token_cnt++;
9354 }
9355
9356 if (token_cnt == 2)
9357 {
9358 char *device_name = token_ptr[0];
9359 char *alias_name = token_ptr[1];
9360
9361 tuning_db_alias_t *alias = &tuning_db->alias_buf[tuning_db->alias_cnt];
9362
9363 alias->device_name = mystrdup (device_name);
9364 alias->alias_name = mystrdup (alias_name);
9365
9366 tuning_db->alias_cnt++;
9367 }
9368 else if (token_cnt == 6)
9369 {
9370 if ((token_ptr[1][0] != '0') &&
9371 (token_ptr[1][0] != '1') &&
9372 (token_ptr[1][0] != '3') &&
9373 (token_ptr[1][0] != '*'))
9374 {
9375 log_info ("WARNING: Tuning-db: Invalid attack_mode '%c' in Line '%u'", token_ptr[1][0], line_num);
9376
9377 continue;
9378 }
9379
9380 if ((token_ptr[3][0] != '1') &&
9381 (token_ptr[3][0] != '2') &&
9382 (token_ptr[3][0] != '4') &&
9383 (token_ptr[3][0] != '8') &&
9384 (token_ptr[3][0] != 'N'))
9385 {
9386 log_info ("WARNING: Tuning-db: Invalid vector_width '%c' in Line '%u'", token_ptr[3][0], line_num);
9387
9388 continue;
9389 }
9390
9391 char *device_name = token_ptr[0];
9392
9393 int attack_mode = -1;
9394 int hash_type = -1;
9395 int vector_width = -1;
9396 int kernel_accel = -1;
9397 int kernel_loops = -1;
9398
9399 if (token_ptr[1][0] != '*') attack_mode = atoi (token_ptr[1]);
9400 if (token_ptr[2][0] != '*') hash_type = atoi (token_ptr[2]);
9401 if (token_ptr[3][0] != 'N') vector_width = atoi (token_ptr[3]);
9402
9403 if (token_ptr[4][0] != 'A')
9404 {
9405 kernel_accel = atoi (token_ptr[4]);
9406
9407 if ((kernel_accel < 1) || (kernel_accel > 1024))
9408 {
9409 log_info ("WARNING: Tuning-db: Invalid kernel_accel '%d' in Line '%u'", kernel_accel, line_num);
9410
9411 continue;
9412 }
9413 }
9414 else
9415 {
9416 kernel_accel = 0;
9417 }
9418
9419 if (token_ptr[5][0] != 'A')
9420 {
9421 kernel_loops = atoi (token_ptr[5]);
9422
9423 if ((kernel_loops < 1) || (kernel_loops > 1024))
9424 {
9425 log_info ("WARNING: Tuning-db: Invalid kernel_loops '%d' in Line '%u'", kernel_loops, line_num);
9426
9427 continue;
9428 }
9429 }
9430 else
9431 {
9432 kernel_loops = 0;
9433 }
9434
9435 tuning_db_entry_t *entry = &tuning_db->entry_buf[tuning_db->entry_cnt];
9436
9437 entry->device_name = mystrdup (device_name);
9438 entry->attack_mode = attack_mode;
9439 entry->hash_type = hash_type;
9440 entry->vector_width = vector_width;
9441 entry->kernel_accel = kernel_accel;
9442 entry->kernel_loops = kernel_loops;
9443
9444 tuning_db->entry_cnt++;
9445 }
9446 else
9447 {
9448 log_info ("WARNING: Tuning-db: Invalid number of token in Line '%u'", line_num);
9449
9450 continue;
9451 }
9452 }
9453
9454 myfree (buf);
9455
9456 fclose (fp);
9457
9458 // todo: print loaded 'cnt' message
9459
9460 // sort the database
9461
9462 qsort (tuning_db->alias_buf, tuning_db->alias_cnt, sizeof (tuning_db_alias_t), sort_by_tuning_db_alias);
9463 qsort (tuning_db->entry_buf, tuning_db->entry_cnt, sizeof (tuning_db_entry_t), sort_by_tuning_db_entry);
9464
9465 return tuning_db;
9466 }
9467
9468 tuning_db_entry_t *tuning_db_search (tuning_db_t *tuning_db, hc_device_param_t *device_param, int attack_mode, int hash_type)
9469 {
9470 static tuning_db_entry_t s;
9471
9472 // first we need to convert all spaces in the device_name to underscore
9473
9474 char *device_name_nospace = strdup (device_param->device_name);
9475
9476 int device_name_length = strlen (device_name_nospace);
9477
9478 int i;
9479
9480 for (i = 0; i < device_name_length; i++)
9481 {
9482 if (device_name_nospace[i] == ' ') device_name_nospace[i] = '_';
9483 }
9484
9485 // find out if there's an alias configured
9486
9487 tuning_db_alias_t a;
9488
9489 a.device_name = device_name_nospace;
9490
9491 tuning_db_alias_t *alias = bsearch (&a, tuning_db->alias_buf, tuning_db->alias_cnt, sizeof (tuning_db_alias_t), sort_by_tuning_db_alias);
9492
9493 char *alias_name = (alias == NULL) ? NULL : alias->alias_name;
9494
9495 // attack-mode 6 and 7 are attack-mode 1 basically
9496
9497 if (attack_mode == 6) attack_mode = 1;
9498 if (attack_mode == 7) attack_mode = 1;
9499
9500 // bsearch is not ideal but fast enough
9501
9502 s.device_name = device_name_nospace;
9503 s.attack_mode = attack_mode;
9504 s.hash_type = hash_type;
9505
9506 tuning_db_entry_t *entry = NULL;
9507
9508 // this will produce all 2^3 combinations required
9509
9510 for (i = 0; i < 8; i++)
9511 {
9512 s.device_name = (i & 1) ? "*" : device_name_nospace;
9513 s.attack_mode = (i & 2) ? -1 : attack_mode;
9514 s.hash_type = (i & 4) ? -1 : hash_type;
9515
9516 entry = bsearch (&s, tuning_db->entry_buf, tuning_db->entry_cnt, sizeof (tuning_db_entry_t), sort_by_tuning_db_entry);
9517
9518 if (entry != NULL) break;
9519
9520 // in non-wildcard mode do some additional checks:
9521
9522 if ((i & 1) == 0)
9523 {
9524 // in case we have an alias-name
9525
9526 if (alias_name != NULL)
9527 {
9528 s.device_name = alias_name;
9529
9530 entry = bsearch (&s, tuning_db->entry_buf, tuning_db->entry_cnt, sizeof (tuning_db_entry_t), sort_by_tuning_db_entry);
9531
9532 if (entry != NULL) break;
9533 }
9534
9535 // or by device type
9536
9537 if (device_param->device_type & CL_DEVICE_TYPE_CPU)
9538 {
9539 s.device_name = "DEVICE_TYPE_CPU";
9540 }
9541 else if (device_param->device_type & CL_DEVICE_TYPE_GPU)
9542 {
9543 s.device_name = "DEVICE_TYPE_GPU";
9544 }
9545 else if (device_param->device_type & CL_DEVICE_TYPE_ACCELERATOR)
9546 {
9547 s.device_name = "DEVICE_TYPE_ACCELERATOR";
9548 }
9549
9550 entry = bsearch (&s, tuning_db->entry_buf, tuning_db->entry_cnt, sizeof (tuning_db_entry_t), sort_by_tuning_db_entry);
9551
9552 if (entry != NULL) break;
9553 }
9554 }
9555
9556 // free converted device_name
9557
9558 myfree (device_name_nospace);
9559
9560 return entry;
9561 }
9562
9563 /**
9564 * parser
9565 */
9566
9567 uint parse_and_store_salt (char *out, char *in, uint salt_len)
9568 {
9569 u8 tmp[256] = { 0 };
9570
9571 if (salt_len > sizeof (tmp))
9572 {
9573 return UINT_MAX;
9574 }
9575
9576 memcpy (tmp, in, salt_len);
9577
9578 if (data.opts_type & OPTS_TYPE_ST_HEX)
9579 {
9580 if ((salt_len % 2) == 0)
9581 {
9582 u32 new_salt_len = salt_len / 2;
9583
9584 for (uint i = 0, j = 0; i < new_salt_len; i += 1, j += 2)
9585 {
9586 u8 p0 = tmp[j + 0];
9587 u8 p1 = tmp[j + 1];
9588
9589 tmp[i] = hex_convert (p1) << 0;
9590 tmp[i] |= hex_convert (p0) << 4;
9591 }
9592
9593 salt_len = new_salt_len;
9594 }
9595 else
9596 {
9597 return UINT_MAX;
9598 }
9599 }
9600 else if (data.opts_type & OPTS_TYPE_ST_BASE64)
9601 {
9602 salt_len = base64_decode (base64_to_int, (const u8 *) in, salt_len, (u8 *) tmp);
9603 }
9604
9605 memset (tmp + salt_len, 0, sizeof (tmp) - salt_len);
9606
9607 if (data.opts_type & OPTS_TYPE_ST_UNICODE)
9608 {
9609 if (salt_len < 20)
9610 {
9611 u32 *tmp_uint = (u32 *) tmp;
9612
9613 tmp_uint[9] = ((tmp_uint[4] >> 8) & 0x00FF0000) | ((tmp_uint[4] >> 16) & 0x000000FF);
9614 tmp_uint[8] = ((tmp_uint[4] << 8) & 0x00FF0000) | ((tmp_uint[4] >> 0) & 0x000000FF);
9615 tmp_uint[7] = ((tmp_uint[3] >> 8) & 0x00FF0000) | ((tmp_uint[3] >> 16) & 0x000000FF);
9616 tmp_uint[6] = ((tmp_uint[3] << 8) & 0x00FF0000) | ((tmp_uint[3] >> 0) & 0x000000FF);
9617 tmp_uint[5] = ((tmp_uint[2] >> 8) & 0x00FF0000) | ((tmp_uint[2] >> 16) & 0x000000FF);
9618 tmp_uint[4] = ((tmp_uint[2] << 8) & 0x00FF0000) | ((tmp_uint[2] >> 0) & 0x000000FF);
9619 tmp_uint[3] = ((tmp_uint[1] >> 8) & 0x00FF0000) | ((tmp_uint[1] >> 16) & 0x000000FF);
9620 tmp_uint[2] = ((tmp_uint[1] << 8) & 0x00FF0000) | ((tmp_uint[1] >> 0) & 0x000000FF);
9621 tmp_uint[1] = ((tmp_uint[0] >> 8) & 0x00FF0000) | ((tmp_uint[0] >> 16) & 0x000000FF);
9622 tmp_uint[0] = ((tmp_uint[0] << 8) & 0x00FF0000) | ((tmp_uint[0] >> 0) & 0x000000FF);
9623
9624 salt_len = salt_len * 2;
9625 }
9626 else
9627 {
9628 return UINT_MAX;
9629 }
9630 }
9631
9632 if (data.opts_type & OPTS_TYPE_ST_LOWER)
9633 {
9634 lowercase (tmp, salt_len);
9635 }
9636
9637 if (data.opts_type & OPTS_TYPE_ST_UPPER)
9638 {
9639 uppercase (tmp, salt_len);
9640 }
9641
9642 u32 len = salt_len;
9643
9644 if (data.opts_type & OPTS_TYPE_ST_ADD80)
9645 {
9646 tmp[len++] = 0x80;
9647 }
9648
9649 if (data.opts_type & OPTS_TYPE_ST_ADD01)
9650 {
9651 tmp[len++] = 0x01;
9652 }
9653
9654 if (data.opts_type & OPTS_TYPE_ST_GENERATE_LE)
9655 {
9656 u32 *tmp_uint = (uint *) tmp;
9657
9658 u32 max = len / 4;
9659
9660 if (len % 4) max++;
9661
9662 for (u32 i = 0; i < max; i++)
9663 {
9664 tmp_uint[i] = byte_swap_32 (tmp_uint[i]);
9665 }
9666
9667 // Important: we may need to increase the length of memcpy since
9668 // we don't want to "loose" some swapped bytes (could happen if
9669 // they do not perfectly fit in the 4-byte blocks)
9670 // Memcpy does always copy the bytes in the BE order, but since
9671 // we swapped them, some important bytes could be in positions
9672 // we normally skip with the original len
9673
9674 if (len % 4) len += 4 - (len % 4);
9675 }
9676
9677 memcpy (out, tmp, len);
9678
9679 return (salt_len);
9680 }
9681
9682 int bcrypt_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
9683 {
9684 if ((input_len < DISPLAY_LEN_MIN_3200) || (input_len > DISPLAY_LEN_MAX_3200)) return (PARSER_GLOBAL_LENGTH);
9685
9686 if ((memcmp (SIGNATURE_BCRYPT1, input_buf, 4)) && (memcmp (SIGNATURE_BCRYPT2, input_buf, 4)) && (memcmp (SIGNATURE_BCRYPT3, input_buf, 4))) return (PARSER_SIGNATURE_UNMATCHED);
9687
9688 u32 *digest = (u32 *) hash_buf->digest;
9689
9690 salt_t *salt = hash_buf->salt;
9691
9692 memcpy ((char *) salt->salt_sign, input_buf, 6);
9693
9694 char *iter_pos = input_buf + 4;
9695
9696 salt->salt_iter = 1 << atoi (iter_pos);
9697
9698 char *salt_pos = strchr (iter_pos, '$');
9699
9700 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
9701
9702 salt_pos++;
9703
9704 uint salt_len = 16;
9705
9706 salt->salt_len = salt_len;
9707
9708 u8 tmp_buf[100] = { 0 };
9709
9710 base64_decode (bf64_to_int, (const u8 *) salt_pos, 22, tmp_buf);
9711
9712 char *salt_buf_ptr = (char *) salt->salt_buf;
9713
9714 memcpy (salt_buf_ptr, tmp_buf, 16);
9715
9716 salt->salt_buf[0] = byte_swap_32 (salt->salt_buf[0]);
9717 salt->salt_buf[1] = byte_swap_32 (salt->salt_buf[1]);
9718 salt->salt_buf[2] = byte_swap_32 (salt->salt_buf[2]);
9719 salt->salt_buf[3] = byte_swap_32 (salt->salt_buf[3]);
9720
9721 char *hash_pos = salt_pos + 22;
9722
9723 memset (tmp_buf, 0, sizeof (tmp_buf));
9724
9725 base64_decode (bf64_to_int, (const u8 *) hash_pos, 31, tmp_buf);
9726
9727 memcpy (digest, tmp_buf, 24);
9728
9729 digest[0] = byte_swap_32 (digest[0]);
9730 digest[1] = byte_swap_32 (digest[1]);
9731 digest[2] = byte_swap_32 (digest[2]);
9732 digest[3] = byte_swap_32 (digest[3]);
9733 digest[4] = byte_swap_32 (digest[4]);
9734 digest[5] = byte_swap_32 (digest[5]);
9735
9736 digest[5] &= ~0xff; // its just 23 not 24 !
9737
9738 return (PARSER_OK);
9739 }
9740
9741 int cisco4_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
9742 {
9743 if ((input_len < DISPLAY_LEN_MIN_5700) || (input_len > DISPLAY_LEN_MAX_5700)) return (PARSER_GLOBAL_LENGTH);
9744
9745 u32 *digest = (u32 *) hash_buf->digest;
9746
9747 u8 tmp_buf[100] = { 0 };
9748
9749 base64_decode (itoa64_to_int, (const u8 *) input_buf, 43, tmp_buf);
9750
9751 memcpy (digest, tmp_buf, 32);
9752
9753 digest[0] = byte_swap_32 (digest[0]);
9754 digest[1] = byte_swap_32 (digest[1]);
9755 digest[2] = byte_swap_32 (digest[2]);
9756 digest[3] = byte_swap_32 (digest[3]);
9757 digest[4] = byte_swap_32 (digest[4]);
9758 digest[5] = byte_swap_32 (digest[5]);
9759 digest[6] = byte_swap_32 (digest[6]);
9760 digest[7] = byte_swap_32 (digest[7]);
9761
9762 digest[0] -= SHA256M_A;
9763 digest[1] -= SHA256M_B;
9764 digest[2] -= SHA256M_C;
9765 digest[3] -= SHA256M_D;
9766 digest[4] -= SHA256M_E;
9767 digest[5] -= SHA256M_F;
9768 digest[6] -= SHA256M_G;
9769 digest[7] -= SHA256M_H;
9770
9771 return (PARSER_OK);
9772 }
9773
9774 int lm_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
9775 {
9776 if ((input_len < DISPLAY_LEN_MIN_3000) || (input_len > DISPLAY_LEN_MAX_3000)) return (PARSER_GLOBAL_LENGTH);
9777
9778 u32 *digest = (u32 *) hash_buf->digest;
9779
9780 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
9781 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
9782
9783 digest[0] = byte_swap_32 (digest[0]);
9784 digest[1] = byte_swap_32 (digest[1]);
9785
9786 uint tt;
9787
9788 IP (digest[0], digest[1], tt);
9789
9790 digest[0] = digest[0];
9791 digest[1] = digest[1];
9792 digest[2] = 0;
9793 digest[3] = 0;
9794
9795 return (PARSER_OK);
9796 }
9797
9798 int arubaos_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
9799 {
9800 if ((input_len < DISPLAY_LEN_MIN_125) || (input_len > DISPLAY_LEN_MAX_125)) return (PARSER_GLOBAL_LENGTH);
9801
9802 if ((input_buf[8] != '0') || (input_buf[9] != '1')) return (PARSER_SIGNATURE_UNMATCHED);
9803
9804 u32 *digest = (u32 *) hash_buf->digest;
9805
9806 salt_t *salt = hash_buf->salt;
9807
9808 char *hash_pos = input_buf + 10;
9809
9810 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
9811 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
9812 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
9813 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
9814 digest[4] = hex_to_u32 ((const u8 *) &hash_pos[32]);
9815
9816 digest[0] -= SHA1M_A;
9817 digest[1] -= SHA1M_B;
9818 digest[2] -= SHA1M_C;
9819 digest[3] -= SHA1M_D;
9820 digest[4] -= SHA1M_E;
9821
9822 uint salt_len = 10;
9823
9824 char *salt_buf_ptr = (char *) salt->salt_buf;
9825
9826 salt_len = parse_and_store_salt (salt_buf_ptr, input_buf, salt_len);
9827
9828 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
9829
9830 salt->salt_len = salt_len;
9831
9832 return (PARSER_OK);
9833 }
9834
9835 int osx1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
9836 {
9837 if ((input_len < DISPLAY_LEN_MIN_122) || (input_len > DISPLAY_LEN_MAX_122)) return (PARSER_GLOBAL_LENGTH);
9838
9839 u32 *digest = (u32 *) hash_buf->digest;
9840
9841 salt_t *salt = hash_buf->salt;
9842
9843 char *hash_pos = input_buf + 8;
9844
9845 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
9846 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
9847 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
9848 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
9849 digest[4] = hex_to_u32 ((const u8 *) &hash_pos[32]);
9850
9851 digest[0] -= SHA1M_A;
9852 digest[1] -= SHA1M_B;
9853 digest[2] -= SHA1M_C;
9854 digest[3] -= SHA1M_D;
9855 digest[4] -= SHA1M_E;
9856
9857 uint salt_len = 8;
9858
9859 char *salt_buf_ptr = (char *) salt->salt_buf;
9860
9861 salt_len = parse_and_store_salt (salt_buf_ptr, input_buf, salt_len);
9862
9863 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
9864
9865 salt->salt_len = salt_len;
9866
9867 return (PARSER_OK);
9868 }
9869
9870 int osx512_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
9871 {
9872 if ((input_len < DISPLAY_LEN_MIN_1722) || (input_len > DISPLAY_LEN_MAX_1722)) return (PARSER_GLOBAL_LENGTH);
9873
9874 u64 *digest = (u64 *) hash_buf->digest;
9875
9876 salt_t *salt = hash_buf->salt;
9877
9878 char *hash_pos = input_buf + 8;
9879
9880 digest[0] = hex_to_u64 ((const u8 *) &hash_pos[ 0]);
9881 digest[1] = hex_to_u64 ((const u8 *) &hash_pos[ 16]);
9882 digest[2] = hex_to_u64 ((const u8 *) &hash_pos[ 32]);
9883 digest[3] = hex_to_u64 ((const u8 *) &hash_pos[ 48]);
9884 digest[4] = hex_to_u64 ((const u8 *) &hash_pos[ 64]);
9885 digest[5] = hex_to_u64 ((const u8 *) &hash_pos[ 80]);
9886 digest[6] = hex_to_u64 ((const u8 *) &hash_pos[ 96]);
9887 digest[7] = hex_to_u64 ((const u8 *) &hash_pos[112]);
9888
9889 digest[0] -= SHA512M_A;
9890 digest[1] -= SHA512M_B;
9891 digest[2] -= SHA512M_C;
9892 digest[3] -= SHA512M_D;
9893 digest[4] -= SHA512M_E;
9894 digest[5] -= SHA512M_F;
9895 digest[6] -= SHA512M_G;
9896 digest[7] -= SHA512M_H;
9897
9898 uint salt_len = 8;
9899
9900 char *salt_buf_ptr = (char *) salt->salt_buf;
9901
9902 salt_len = parse_and_store_salt (salt_buf_ptr, input_buf, salt_len);
9903
9904 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
9905
9906 salt->salt_len = salt_len;
9907
9908 return (PARSER_OK);
9909 }
9910
9911 int osc_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
9912 {
9913 if (data.opts_type & OPTS_TYPE_ST_HEX)
9914 {
9915 if ((input_len < DISPLAY_LEN_MIN_21H) || (input_len > DISPLAY_LEN_MAX_21H)) return (PARSER_GLOBAL_LENGTH);
9916 }
9917 else
9918 {
9919 if ((input_len < DISPLAY_LEN_MIN_21) || (input_len > DISPLAY_LEN_MAX_21)) return (PARSER_GLOBAL_LENGTH);
9920 }
9921
9922 u32 *digest = (u32 *) hash_buf->digest;
9923
9924 salt_t *salt = hash_buf->salt;
9925
9926 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
9927 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
9928 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
9929 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
9930
9931 digest[0] = byte_swap_32 (digest[0]);
9932 digest[1] = byte_swap_32 (digest[1]);
9933 digest[2] = byte_swap_32 (digest[2]);
9934 digest[3] = byte_swap_32 (digest[3]);
9935
9936 digest[0] -= MD5M_A;
9937 digest[1] -= MD5M_B;
9938 digest[2] -= MD5M_C;
9939 digest[3] -= MD5M_D;
9940
9941 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
9942
9943 uint salt_len = input_len - 32 - 1;
9944
9945 char *salt_buf = input_buf + 32 + 1;
9946
9947 char *salt_buf_ptr = (char *) salt->salt_buf;
9948
9949 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
9950
9951 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
9952
9953 salt->salt_len = salt_len;
9954
9955 return (PARSER_OK);
9956 }
9957
9958 int netscreen_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
9959 {
9960 if (data.opts_type & OPTS_TYPE_ST_HEX)
9961 {
9962 if ((input_len < DISPLAY_LEN_MIN_22H) || (input_len > DISPLAY_LEN_MAX_22H)) return (PARSER_GLOBAL_LENGTH);
9963 }
9964 else
9965 {
9966 if ((input_len < DISPLAY_LEN_MIN_22) || (input_len > DISPLAY_LEN_MAX_22)) return (PARSER_GLOBAL_LENGTH);
9967 }
9968
9969 // unscramble
9970
9971 char clean_input_buf[32] = { 0 };
9972
9973 char sig[6] = { 'n', 'r', 'c', 's', 't', 'n' };
9974 int pos[6] = { 0, 6, 12, 17, 23, 29 };
9975
9976 for (int i = 0, j = 0, k = 0; i < 30; i++)
9977 {
9978 if (i == pos[j])
9979 {
9980 if (sig[j] != input_buf[i]) return (PARSER_SIGNATURE_UNMATCHED);
9981
9982 j++;
9983 }
9984 else
9985 {
9986 clean_input_buf[k] = input_buf[i];
9987
9988 k++;
9989 }
9990 }
9991
9992 // base64 decode
9993
9994 u32 *digest = (u32 *) hash_buf->digest;
9995
9996 salt_t *salt = hash_buf->salt;
9997
9998 u32 a, b, c, d, e, f;
9999
10000 a = base64_to_int (clean_input_buf[ 0] & 0x7f);
10001 b = base64_to_int (clean_input_buf[ 1] & 0x7f);
10002 c = base64_to_int (clean_input_buf[ 2] & 0x7f);
10003 d = base64_to_int (clean_input_buf[ 3] & 0x7f);
10004 e = base64_to_int (clean_input_buf[ 4] & 0x7f);
10005 f = base64_to_int (clean_input_buf[ 5] & 0x7f);
10006
10007 digest[0] = (((a << 12) | (b << 6) | (c)) << 16)
10008 | (((d << 12) | (e << 6) | (f)) << 0);
10009
10010 a = base64_to_int (clean_input_buf[ 6] & 0x7f);
10011 b = base64_to_int (clean_input_buf[ 7] & 0x7f);
10012 c = base64_to_int (clean_input_buf[ 8] & 0x7f);
10013 d = base64_to_int (clean_input_buf[ 9] & 0x7f);
10014 e = base64_to_int (clean_input_buf[10] & 0x7f);
10015 f = base64_to_int (clean_input_buf[11] & 0x7f);
10016
10017 digest[1] = (((a << 12) | (b << 6) | (c)) << 16)
10018 | (((d << 12) | (e << 6) | (f)) << 0);
10019
10020 a = base64_to_int (clean_input_buf[12] & 0x7f);
10021 b = base64_to_int (clean_input_buf[13] & 0x7f);
10022 c = base64_to_int (clean_input_buf[14] & 0x7f);
10023 d = base64_to_int (clean_input_buf[15] & 0x7f);
10024 e = base64_to_int (clean_input_buf[16] & 0x7f);
10025 f = base64_to_int (clean_input_buf[17] & 0x7f);
10026
10027 digest[2] = (((a << 12) | (b << 6) | (c)) << 16)
10028 | (((d << 12) | (e << 6) | (f)) << 0);
10029
10030 a = base64_to_int (clean_input_buf[18] & 0x7f);
10031 b = base64_to_int (clean_input_buf[19] & 0x7f);
10032 c = base64_to_int (clean_input_buf[20] & 0x7f);
10033 d = base64_to_int (clean_input_buf[21] & 0x7f);
10034 e = base64_to_int (clean_input_buf[22] & 0x7f);
10035 f = base64_to_int (clean_input_buf[23] & 0x7f);
10036
10037 digest[3] = (((a << 12) | (b << 6) | (c)) << 16)
10038 | (((d << 12) | (e << 6) | (f)) << 0);
10039
10040 digest[0] = byte_swap_32 (digest[0]);
10041 digest[1] = byte_swap_32 (digest[1]);
10042 digest[2] = byte_swap_32 (digest[2]);
10043 digest[3] = byte_swap_32 (digest[3]);
10044
10045 digest[0] -= MD5M_A;
10046 digest[1] -= MD5M_B;
10047 digest[2] -= MD5M_C;
10048 digest[3] -= MD5M_D;
10049
10050 if (input_buf[30] != ':') return (PARSER_SEPARATOR_UNMATCHED);
10051
10052 uint salt_len = input_len - 30 - 1;
10053
10054 char *salt_buf = input_buf + 30 + 1;
10055
10056 char *salt_buf_ptr = (char *) salt->salt_buf;
10057
10058 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
10059
10060 // max. salt length: 55 (max for MD5) - 22 (":Administration Tools:") - 1 (0x80) = 32
10061 // 32 - 4 bytes (to fit w0lr for all attack modes) = 28
10062
10063 if (salt_len > 28) return (PARSER_SALT_LENGTH);
10064
10065 salt->salt_len = salt_len;
10066
10067 memcpy (salt_buf_ptr + salt_len, ":Administration Tools:", 22);
10068
10069 salt->salt_len += 22;
10070
10071 return (PARSER_OK);
10072 }
10073
10074 int smf_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10075 {
10076 if (data.opts_type & OPTS_TYPE_ST_HEX)
10077 {
10078 if ((input_len < DISPLAY_LEN_MIN_121H) || (input_len > DISPLAY_LEN_MAX_121H)) return (PARSER_GLOBAL_LENGTH);
10079 }
10080 else
10081 {
10082 if ((input_len < DISPLAY_LEN_MIN_121) || (input_len > DISPLAY_LEN_MAX_121)) return (PARSER_GLOBAL_LENGTH);
10083 }
10084
10085 u32 *digest = (u32 *) hash_buf->digest;
10086
10087 salt_t *salt = hash_buf->salt;
10088
10089 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
10090 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
10091 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
10092 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
10093 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
10094
10095 digest[0] -= SHA1M_A;
10096 digest[1] -= SHA1M_B;
10097 digest[2] -= SHA1M_C;
10098 digest[3] -= SHA1M_D;
10099 digest[4] -= SHA1M_E;
10100
10101 if (input_buf[40] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
10102
10103 uint salt_len = input_len - 40 - 1;
10104
10105 char *salt_buf = input_buf + 40 + 1;
10106
10107 char *salt_buf_ptr = (char *) salt->salt_buf;
10108
10109 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
10110
10111 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
10112
10113 salt->salt_len = salt_len;
10114
10115 return (PARSER_OK);
10116 }
10117
10118 int dcc2_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10119 {
10120 if (data.opts_type & OPTS_TYPE_ST_HEX)
10121 {
10122 if ((input_len < DISPLAY_LEN_MIN_2100H) || (input_len > DISPLAY_LEN_MAX_2100H)) return (PARSER_GLOBAL_LENGTH);
10123 }
10124 else
10125 {
10126 if ((input_len < DISPLAY_LEN_MIN_2100) || (input_len > DISPLAY_LEN_MAX_2100)) return (PARSER_GLOBAL_LENGTH);
10127 }
10128
10129 if (memcmp (SIGNATURE_DCC2, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
10130
10131 char *iter_pos = input_buf + 6;
10132
10133 salt_t *salt = hash_buf->salt;
10134
10135 uint iter = atoi (iter_pos);
10136
10137 if (iter < 1)
10138 {
10139 iter = ROUNDS_DCC2;
10140 }
10141
10142 salt->salt_iter = iter - 1;
10143
10144 char *salt_pos = strchr (iter_pos, '#');
10145
10146 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
10147
10148 salt_pos++;
10149
10150 char *digest_pos = strchr (salt_pos, '#');
10151
10152 if (digest_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
10153
10154 digest_pos++;
10155
10156 uint salt_len = digest_pos - salt_pos - 1;
10157
10158 u32 *digest = (u32 *) hash_buf->digest;
10159
10160 digest[0] = hex_to_u32 ((const u8 *) &digest_pos[ 0]);
10161 digest[1] = hex_to_u32 ((const u8 *) &digest_pos[ 8]);
10162 digest[2] = hex_to_u32 ((const u8 *) &digest_pos[16]);
10163 digest[3] = hex_to_u32 ((const u8 *) &digest_pos[24]);
10164
10165 char *salt_buf_ptr = (char *) salt->salt_buf;
10166
10167 salt_len = parse_and_store_salt (salt_buf_ptr, salt_pos, salt_len);
10168
10169 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
10170
10171 salt->salt_len = salt_len;
10172
10173 return (PARSER_OK);
10174 }
10175
10176 int wpa_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10177 {
10178 u32 *digest = (u32 *) hash_buf->digest;
10179
10180 salt_t *salt = hash_buf->salt;
10181
10182 wpa_t *wpa = (wpa_t *) hash_buf->esalt;
10183
10184 hccap_t in;
10185
10186 memcpy (&in, input_buf, input_len);
10187
10188 if (in.eapol_size < 1 || in.eapol_size > 255) return (PARSER_HCCAP_EAPOL_SIZE);
10189
10190 memcpy (digest, in.keymic, 16);
10191
10192 /*
10193 http://www.one-net.eu/jsw/j_sec/m_ptype.html
10194 The phrase "Pairwise key expansion"
10195 Access Point Address (referred to as Authenticator Address AA)
10196 Supplicant Address (referred to as Supplicant Address SA)
10197 Access Point Nonce (referred to as Authenticator Anonce)
10198 Wireless Device Nonce (referred to as Supplicant Nonce Snonce)
10199 */
10200
10201 uint salt_len = strlen (in.essid);
10202
10203 if (salt_len > 36)
10204 {
10205 log_info ("WARNING: the length of the ESSID is too long. The hccap file may be invalid or corrupted");
10206
10207 return (PARSER_SALT_LENGTH);
10208 }
10209
10210 memcpy (salt->salt_buf, in.essid, salt_len);
10211
10212 salt->salt_len = salt_len;
10213
10214 salt->salt_iter = ROUNDS_WPA2 - 1;
10215
10216 unsigned char *pke_ptr = (unsigned char *) wpa->pke;
10217
10218 memcpy (pke_ptr, "Pairwise key expansion", 23);
10219
10220 if (memcmp (in.mac1, in.mac2, 6) < 0)
10221 {
10222 memcpy (pke_ptr + 23, in.mac1, 6);
10223 memcpy (pke_ptr + 29, in.mac2, 6);
10224 }
10225 else
10226 {
10227 memcpy (pke_ptr + 23, in.mac2, 6);
10228 memcpy (pke_ptr + 29, in.mac1, 6);
10229 }
10230
10231 if (memcmp (in.nonce1, in.nonce2, 32) < 0)
10232 {
10233 memcpy (pke_ptr + 35, in.nonce1, 32);
10234 memcpy (pke_ptr + 67, in.nonce2, 32);
10235 }
10236 else
10237 {
10238 memcpy (pke_ptr + 35, in.nonce2, 32);
10239 memcpy (pke_ptr + 67, in.nonce1, 32);
10240 }
10241
10242 for (int i = 0; i < 25; i++)
10243 {
10244 wpa->pke[i] = byte_swap_32 (wpa->pke[i]);
10245 }
10246
10247 memcpy (wpa->orig_mac1, in.mac1, 6);
10248 memcpy (wpa->orig_mac2, in.mac2, 6);
10249 memcpy (wpa->orig_nonce1, in.nonce1, 32);
10250 memcpy (wpa->orig_nonce2, in.nonce2, 32);
10251
10252 wpa->keyver = in.keyver;
10253
10254 if (wpa->keyver > 255)
10255 {
10256 log_info ("ATTENTION!");
10257 log_info (" The WPA/WPA2 key version in your .hccap file is invalid!");
10258 log_info (" This could be due to a recent aircrack-ng bug.");
10259 log_info (" The key version was automatically reset to a reasonable value.");
10260 log_info ("");
10261
10262 wpa->keyver &= 0xff;
10263 }
10264
10265 wpa->eapol_size = in.eapol_size;
10266
10267 unsigned char *eapol_ptr = (unsigned char *) wpa->eapol;
10268
10269 memcpy (eapol_ptr, in.eapol, wpa->eapol_size);
10270
10271 memset (eapol_ptr + wpa->eapol_size, 0, 256 - wpa->eapol_size);
10272
10273 eapol_ptr[wpa->eapol_size] = (unsigned char) 0x80;
10274
10275 if (wpa->keyver == 1)
10276 {
10277 // nothing to do
10278 }
10279 else
10280 {
10281 digest[0] = byte_swap_32 (digest[0]);
10282 digest[1] = byte_swap_32 (digest[1]);
10283 digest[2] = byte_swap_32 (digest[2]);
10284 digest[3] = byte_swap_32 (digest[3]);
10285
10286 for (int i = 0; i < 64; i++)
10287 {
10288 wpa->eapol[i] = byte_swap_32 (wpa->eapol[i]);
10289 }
10290 }
10291
10292 uint32_t *p0 = (uint32_t *) in.essid;
10293 uint32_t c0 = 0;
10294 uint32_t c1 = 0;
10295
10296 for (uint i = 0; i < sizeof (in.essid) / sizeof (uint32_t); i++) c0 ^= *p0++;
10297 for (uint i = 0; i < sizeof (wpa->pke) / sizeof (wpa->pke[0]); i++) c1 ^= wpa->pke[i];
10298
10299 salt->salt_buf[10] = c0;
10300 salt->salt_buf[11] = c1;
10301
10302 return (PARSER_OK);
10303 }
10304
10305 int psafe2_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10306 {
10307 u32 *digest = (u32 *) hash_buf->digest;
10308
10309 salt_t *salt = hash_buf->salt;
10310
10311 if (input_len == 0)
10312 {
10313 log_error ("Password Safe v2 container not specified");
10314
10315 exit (-1);
10316 }
10317
10318 FILE *fp = fopen (input_buf, "rb");
10319
10320 if (fp == NULL)
10321 {
10322 log_error ("%s: %s", input_buf, strerror (errno));
10323
10324 exit (-1);
10325 }
10326
10327 psafe2_hdr buf;
10328
10329 memset (&buf, 0, sizeof (psafe2_hdr));
10330
10331 int n = fread (&buf, sizeof (psafe2_hdr), 1, fp);
10332
10333 fclose (fp);
10334
10335 if (n != 1) return (PARSER_PSAFE2_FILE_SIZE);
10336
10337 salt->salt_buf[0] = buf.random[0];
10338 salt->salt_buf[1] = buf.random[1];
10339
10340 salt->salt_len = 8;
10341 salt->salt_iter = 1000;
10342
10343 digest[0] = byte_swap_32 (buf.hash[0]);
10344 digest[1] = byte_swap_32 (buf.hash[1]);
10345 digest[2] = byte_swap_32 (buf.hash[2]);
10346 digest[3] = byte_swap_32 (buf.hash[3]);
10347 digest[4] = byte_swap_32 (buf.hash[4]);
10348
10349 return (PARSER_OK);
10350 }
10351
10352 int psafe3_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10353 {
10354 u32 *digest = (u32 *) hash_buf->digest;
10355
10356 salt_t *salt = hash_buf->salt;
10357
10358 if (input_len == 0)
10359 {
10360 log_error (".psafe3 not specified");
10361
10362 exit (-1);
10363 }
10364
10365 FILE *fp = fopen (input_buf, "rb");
10366
10367 if (fp == NULL)
10368 {
10369 log_error ("%s: %s", input_buf, strerror (errno));
10370
10371 exit (-1);
10372 }
10373
10374 psafe3_t in;
10375
10376 int n = fread (&in, sizeof (psafe3_t), 1, fp);
10377
10378 fclose (fp);
10379
10380 data.hashfile = input_buf; // we will need this in case it gets cracked
10381
10382 if (memcmp (SIGNATURE_PSAFE3, in.signature, 4)) return (PARSER_SIGNATURE_UNMATCHED);
10383
10384 if (n != 1) return (PARSER_PSAFE3_FILE_SIZE);
10385
10386 salt->salt_iter = in.iterations + 1;
10387
10388 salt->salt_buf[0] = in.salt_buf[0];
10389 salt->salt_buf[1] = in.salt_buf[1];
10390 salt->salt_buf[2] = in.salt_buf[2];
10391 salt->salt_buf[3] = in.salt_buf[3];
10392 salt->salt_buf[4] = in.salt_buf[4];
10393 salt->salt_buf[5] = in.salt_buf[5];
10394 salt->salt_buf[6] = in.salt_buf[6];
10395 salt->salt_buf[7] = in.salt_buf[7];
10396
10397 salt->salt_len = 32;
10398
10399 digest[0] = in.hash_buf[0];
10400 digest[1] = in.hash_buf[1];
10401 digest[2] = in.hash_buf[2];
10402 digest[3] = in.hash_buf[3];
10403 digest[4] = in.hash_buf[4];
10404 digest[5] = in.hash_buf[5];
10405 digest[6] = in.hash_buf[6];
10406 digest[7] = in.hash_buf[7];
10407
10408 digest[0] = byte_swap_32 (digest[0]);
10409 digest[1] = byte_swap_32 (digest[1]);
10410 digest[2] = byte_swap_32 (digest[2]);
10411 digest[3] = byte_swap_32 (digest[3]);
10412 digest[4] = byte_swap_32 (digest[4]);
10413 digest[5] = byte_swap_32 (digest[5]);
10414 digest[6] = byte_swap_32 (digest[6]);
10415 digest[7] = byte_swap_32 (digest[7]);
10416
10417 return (PARSER_OK);
10418 }
10419
10420 int phpass_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10421 {
10422 if ((input_len < DISPLAY_LEN_MIN_400) || (input_len > DISPLAY_LEN_MAX_400)) return (PARSER_GLOBAL_LENGTH);
10423
10424 if ((memcmp (SIGNATURE_PHPASS1, input_buf, 3)) && (memcmp (SIGNATURE_PHPASS2, input_buf, 3))) return (PARSER_SIGNATURE_UNMATCHED);
10425
10426 u32 *digest = (u32 *) hash_buf->digest;
10427
10428 salt_t *salt = hash_buf->salt;
10429
10430 char *iter_pos = input_buf + 3;
10431
10432 uint salt_iter = 1 << itoa64_to_int (iter_pos[0]);
10433
10434 if (salt_iter > 0x80000000) return (PARSER_SALT_ITERATION);
10435
10436 memcpy ((char *) salt->salt_sign, input_buf, 4);
10437
10438 salt->salt_iter = salt_iter;
10439
10440 char *salt_pos = iter_pos + 1;
10441
10442 uint salt_len = 8;
10443
10444 memcpy ((char *) salt->salt_buf, salt_pos, salt_len);
10445
10446 salt->salt_len = salt_len;
10447
10448 char *hash_pos = salt_pos + salt_len;
10449
10450 phpass_decode ((unsigned char *) digest, (unsigned char *) hash_pos);
10451
10452 return (PARSER_OK);
10453 }
10454
10455 int md5crypt_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10456 {
10457 if (input_len < DISPLAY_LEN_MIN_500) return (PARSER_GLOBAL_LENGTH);
10458
10459 if (memcmp (SIGNATURE_MD5CRYPT, input_buf, 3)) return (PARSER_SIGNATURE_UNMATCHED);
10460
10461 u32 *digest = (u32 *) hash_buf->digest;
10462
10463 salt_t *salt = hash_buf->salt;
10464
10465 char *salt_pos = input_buf + 3;
10466
10467 uint iterations_len = 0;
10468
10469 if (memcmp (salt_pos, "rounds=", 7) == 0)
10470 {
10471 salt_pos += 7;
10472
10473 for (iterations_len = 0; salt_pos[0] >= '0' && salt_pos[0] <= '9' && iterations_len < 7; iterations_len++, salt_pos += 1) continue;
10474
10475 if (iterations_len == 0 ) return (PARSER_SALT_ITERATION);
10476 if (salt_pos[0] != '$') return (PARSER_SIGNATURE_UNMATCHED);
10477
10478 salt_pos[0] = 0x0;
10479
10480 salt->salt_iter = atoi (salt_pos - iterations_len);
10481
10482 salt_pos += 1;
10483
10484 iterations_len += 8;
10485 }
10486 else
10487 {
10488 salt->salt_iter = ROUNDS_MD5CRYPT;
10489 }
10490
10491 if (input_len > (DISPLAY_LEN_MAX_500 + iterations_len)) return (PARSER_GLOBAL_LENGTH);
10492
10493 char *hash_pos = strchr (salt_pos, '$');
10494
10495 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
10496
10497 uint salt_len = hash_pos - salt_pos;
10498
10499 if (salt_len > 8) return (PARSER_SALT_LENGTH);
10500
10501 memcpy ((char *) salt->salt_buf, salt_pos, salt_len);
10502
10503 salt->salt_len = salt_len;
10504
10505 hash_pos++;
10506
10507 uint hash_len = input_len - 3 - iterations_len - salt_len - 1;
10508
10509 if (hash_len != 22) return (PARSER_HASH_LENGTH);
10510
10511 md5crypt_decode ((unsigned char *) digest, (unsigned char *) hash_pos);
10512
10513 return (PARSER_OK);
10514 }
10515
10516 int md5apr1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10517 {
10518 if (memcmp (SIGNATURE_MD5APR1, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
10519
10520 u32 *digest = (u32 *) hash_buf->digest;
10521
10522 salt_t *salt = hash_buf->salt;
10523
10524 char *salt_pos = input_buf + 6;
10525
10526 uint iterations_len = 0;
10527
10528 if (memcmp (salt_pos, "rounds=", 7) == 0)
10529 {
10530 salt_pos += 7;
10531
10532 for (iterations_len = 0; salt_pos[0] >= '0' && salt_pos[0] <= '9' && iterations_len < 7; iterations_len++, salt_pos += 1) continue;
10533
10534 if (iterations_len == 0 ) return (PARSER_SALT_ITERATION);
10535 if (salt_pos[0] != '$') return (PARSER_SIGNATURE_UNMATCHED);
10536
10537 salt_pos[0] = 0x0;
10538
10539 salt->salt_iter = atoi (salt_pos - iterations_len);
10540
10541 salt_pos += 1;
10542
10543 iterations_len += 8;
10544 }
10545 else
10546 {
10547 salt->salt_iter = ROUNDS_MD5CRYPT;
10548 }
10549
10550 if ((input_len < DISPLAY_LEN_MIN_1600) || (input_len > DISPLAY_LEN_MAX_1600 + iterations_len)) return (PARSER_GLOBAL_LENGTH);
10551
10552 char *hash_pos = strchr (salt_pos, '$');
10553
10554 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
10555
10556 uint salt_len = hash_pos - salt_pos;
10557
10558 if (salt_len > 8) return (PARSER_SALT_LENGTH);
10559
10560 memcpy ((char *) salt->salt_buf, salt_pos, salt_len);
10561
10562 salt->salt_len = salt_len;
10563
10564 hash_pos++;
10565
10566 md5crypt_decode ((unsigned char *) digest, (unsigned char *) hash_pos);
10567
10568 return (PARSER_OK);
10569 }
10570
10571 int episerver_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10572 {
10573 if ((input_len < DISPLAY_LEN_MIN_141) || (input_len > DISPLAY_LEN_MAX_141)) return (PARSER_GLOBAL_LENGTH);
10574
10575 if (memcmp (SIGNATURE_EPISERVER, input_buf, 14)) return (PARSER_SIGNATURE_UNMATCHED);
10576
10577 u32 *digest = (u32 *) hash_buf->digest;
10578
10579 salt_t *salt = hash_buf->salt;
10580
10581 char *salt_pos = input_buf + 14;
10582
10583 char *hash_pos = strchr (salt_pos, '*');
10584
10585 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
10586
10587 hash_pos++;
10588
10589 uint salt_len = hash_pos - salt_pos - 1;
10590
10591 char *salt_buf_ptr = (char *) salt->salt_buf;
10592
10593 salt_len = parse_and_store_salt (salt_buf_ptr, salt_pos, salt_len);
10594
10595 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
10596
10597 salt->salt_len = salt_len;
10598
10599 u8 tmp_buf[100] = { 0 };
10600
10601 base64_decode (base64_to_int, (const u8 *) hash_pos, 27, tmp_buf);
10602
10603 memcpy (digest, tmp_buf, 20);
10604
10605 digest[0] = byte_swap_32 (digest[0]);
10606 digest[1] = byte_swap_32 (digest[1]);
10607 digest[2] = byte_swap_32 (digest[2]);
10608 digest[3] = byte_swap_32 (digest[3]);
10609 digest[4] = byte_swap_32 (digest[4]);
10610
10611 digest[0] -= SHA1M_A;
10612 digest[1] -= SHA1M_B;
10613 digest[2] -= SHA1M_C;
10614 digest[3] -= SHA1M_D;
10615 digest[4] -= SHA1M_E;
10616
10617 return (PARSER_OK);
10618 }
10619
10620 int descrypt_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10621 {
10622 if ((input_len < DISPLAY_LEN_MIN_1500) || (input_len > DISPLAY_LEN_MAX_1500)) return (PARSER_GLOBAL_LENGTH);
10623
10624 unsigned char c12 = itoa64_to_int (input_buf[12]);
10625
10626 if (c12 & 3) return (PARSER_HASH_VALUE);
10627
10628 u32 *digest = (u32 *) hash_buf->digest;
10629
10630 salt_t *salt = hash_buf->salt;
10631
10632 // for ascii_digest
10633 salt->salt_sign[0] = input_buf[0];
10634 salt->salt_sign[1] = input_buf[1];
10635
10636 salt->salt_buf[0] = itoa64_to_int (input_buf[0])
10637 | itoa64_to_int (input_buf[1]) << 6;
10638
10639 salt->salt_len = 2;
10640
10641 u8 tmp_buf[100] = { 0 };
10642
10643 base64_decode (itoa64_to_int, (const u8 *) input_buf + 2, 11, tmp_buf);
10644
10645 memcpy (digest, tmp_buf, 8);
10646
10647 uint tt;
10648
10649 IP (digest[0], digest[1], tt);
10650
10651 digest[2] = 0;
10652 digest[3] = 0;
10653
10654 return (PARSER_OK);
10655 }
10656
10657 int md4_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10658 {
10659 if ((input_len < DISPLAY_LEN_MIN_900) || (input_len > DISPLAY_LEN_MAX_900)) return (PARSER_GLOBAL_LENGTH);
10660
10661 u32 *digest = (u32 *) hash_buf->digest;
10662
10663 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
10664 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
10665 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
10666 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
10667
10668 digest[0] = byte_swap_32 (digest[0]);
10669 digest[1] = byte_swap_32 (digest[1]);
10670 digest[2] = byte_swap_32 (digest[2]);
10671 digest[3] = byte_swap_32 (digest[3]);
10672
10673 digest[0] -= MD4M_A;
10674 digest[1] -= MD4M_B;
10675 digest[2] -= MD4M_C;
10676 digest[3] -= MD4M_D;
10677
10678 return (PARSER_OK);
10679 }
10680
10681 int md4s_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10682 {
10683 if (data.opts_type & OPTS_TYPE_ST_HEX)
10684 {
10685 if ((input_len < DISPLAY_LEN_MIN_910H) || (input_len > DISPLAY_LEN_MAX_910H)) return (PARSER_GLOBAL_LENGTH);
10686 }
10687 else
10688 {
10689 if ((input_len < DISPLAY_LEN_MIN_910) || (input_len > DISPLAY_LEN_MAX_910)) return (PARSER_GLOBAL_LENGTH);
10690 }
10691
10692 u32 *digest = (u32 *) hash_buf->digest;
10693
10694 salt_t *salt = hash_buf->salt;
10695
10696 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
10697 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
10698 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
10699 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
10700
10701 digest[0] = byte_swap_32 (digest[0]);
10702 digest[1] = byte_swap_32 (digest[1]);
10703 digest[2] = byte_swap_32 (digest[2]);
10704 digest[3] = byte_swap_32 (digest[3]);
10705
10706 digest[0] -= MD4M_A;
10707 digest[1] -= MD4M_B;
10708 digest[2] -= MD4M_C;
10709 digest[3] -= MD4M_D;
10710
10711 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
10712
10713 uint salt_len = input_len - 32 - 1;
10714
10715 char *salt_buf = input_buf + 32 + 1;
10716
10717 char *salt_buf_ptr = (char *) salt->salt_buf;
10718
10719 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
10720
10721 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
10722
10723 salt->salt_len = salt_len;
10724
10725 return (PARSER_OK);
10726 }
10727
10728 int md5_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10729 {
10730 if ((input_len < DISPLAY_LEN_MIN_0) || (input_len > DISPLAY_LEN_MAX_0)) return (PARSER_GLOBAL_LENGTH);
10731
10732 u32 *digest = (u32 *) hash_buf->digest;
10733
10734 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
10735 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
10736 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
10737 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
10738
10739 digest[0] = byte_swap_32 (digest[0]);
10740 digest[1] = byte_swap_32 (digest[1]);
10741 digest[2] = byte_swap_32 (digest[2]);
10742 digest[3] = byte_swap_32 (digest[3]);
10743
10744 digest[0] -= MD5M_A;
10745 digest[1] -= MD5M_B;
10746 digest[2] -= MD5M_C;
10747 digest[3] -= MD5M_D;
10748
10749 return (PARSER_OK);
10750 }
10751
10752 int md5half_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10753 {
10754 if ((input_len < DISPLAY_LEN_MIN_5100) || (input_len > DISPLAY_LEN_MAX_5100)) return (PARSER_GLOBAL_LENGTH);
10755
10756 u32 *digest = (u32 *) hash_buf->digest;
10757
10758 digest[0] = hex_to_u32 ((const u8 *) &input_buf[0]);
10759 digest[1] = hex_to_u32 ((const u8 *) &input_buf[8]);
10760 digest[2] = 0;
10761 digest[3] = 0;
10762
10763 digest[0] = byte_swap_32 (digest[0]);
10764 digest[1] = byte_swap_32 (digest[1]);
10765
10766 return (PARSER_OK);
10767 }
10768
10769 int md5s_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10770 {
10771 if (data.opts_type & OPTS_TYPE_ST_HEX)
10772 {
10773 if ((input_len < DISPLAY_LEN_MIN_10H) || (input_len > DISPLAY_LEN_MAX_10H)) return (PARSER_GLOBAL_LENGTH);
10774 }
10775 else
10776 {
10777 if ((input_len < DISPLAY_LEN_MIN_10) || (input_len > DISPLAY_LEN_MAX_10)) return (PARSER_GLOBAL_LENGTH);
10778 }
10779
10780 u32 *digest = (u32 *) hash_buf->digest;
10781
10782 salt_t *salt = hash_buf->salt;
10783
10784 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
10785 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
10786 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
10787 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
10788
10789 digest[0] = byte_swap_32 (digest[0]);
10790 digest[1] = byte_swap_32 (digest[1]);
10791 digest[2] = byte_swap_32 (digest[2]);
10792 digest[3] = byte_swap_32 (digest[3]);
10793
10794 digest[0] -= MD5M_A;
10795 digest[1] -= MD5M_B;
10796 digest[2] -= MD5M_C;
10797 digest[3] -= MD5M_D;
10798
10799 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
10800
10801 uint salt_len = input_len - 32 - 1;
10802
10803 char *salt_buf = input_buf + 32 + 1;
10804
10805 char *salt_buf_ptr = (char *) salt->salt_buf;
10806
10807 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
10808
10809 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
10810
10811 salt->salt_len = salt_len;
10812
10813 return (PARSER_OK);
10814 }
10815
10816 int md5pix_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10817 {
10818 if ((input_len < DISPLAY_LEN_MIN_2400) || (input_len > DISPLAY_LEN_MAX_2400)) return (PARSER_GLOBAL_LENGTH);
10819
10820 u32 *digest = (u32 *) hash_buf->digest;
10821
10822 digest[0] = itoa64_to_int (input_buf[ 0]) << 0
10823 | itoa64_to_int (input_buf[ 1]) << 6
10824 | itoa64_to_int (input_buf[ 2]) << 12
10825 | itoa64_to_int (input_buf[ 3]) << 18;
10826 digest[1] = itoa64_to_int (input_buf[ 4]) << 0
10827 | itoa64_to_int (input_buf[ 5]) << 6
10828 | itoa64_to_int (input_buf[ 6]) << 12
10829 | itoa64_to_int (input_buf[ 7]) << 18;
10830 digest[2] = itoa64_to_int (input_buf[ 8]) << 0
10831 | itoa64_to_int (input_buf[ 9]) << 6
10832 | itoa64_to_int (input_buf[10]) << 12
10833 | itoa64_to_int (input_buf[11]) << 18;
10834 digest[3] = itoa64_to_int (input_buf[12]) << 0
10835 | itoa64_to_int (input_buf[13]) << 6
10836 | itoa64_to_int (input_buf[14]) << 12
10837 | itoa64_to_int (input_buf[15]) << 18;
10838
10839 digest[0] -= MD5M_A;
10840 digest[1] -= MD5M_B;
10841 digest[2] -= MD5M_C;
10842 digest[3] -= MD5M_D;
10843
10844 digest[0] &= 0x00ffffff;
10845 digest[1] &= 0x00ffffff;
10846 digest[2] &= 0x00ffffff;
10847 digest[3] &= 0x00ffffff;
10848
10849 return (PARSER_OK);
10850 }
10851
10852 int md5asa_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10853 {
10854 if (data.opts_type & OPTS_TYPE_ST_HEX)
10855 {
10856 if ((input_len < DISPLAY_LEN_MIN_2410H) || (input_len > DISPLAY_LEN_MAX_2410H)) return (PARSER_GLOBAL_LENGTH);
10857 }
10858 else
10859 {
10860 if ((input_len < DISPLAY_LEN_MIN_2410) || (input_len > DISPLAY_LEN_MAX_2410)) return (PARSER_GLOBAL_LENGTH);
10861 }
10862
10863 u32 *digest = (u32 *) hash_buf->digest;
10864
10865 salt_t *salt = hash_buf->salt;
10866
10867 digest[0] = itoa64_to_int (input_buf[ 0]) << 0
10868 | itoa64_to_int (input_buf[ 1]) << 6
10869 | itoa64_to_int (input_buf[ 2]) << 12
10870 | itoa64_to_int (input_buf[ 3]) << 18;
10871 digest[1] = itoa64_to_int (input_buf[ 4]) << 0
10872 | itoa64_to_int (input_buf[ 5]) << 6
10873 | itoa64_to_int (input_buf[ 6]) << 12
10874 | itoa64_to_int (input_buf[ 7]) << 18;
10875 digest[2] = itoa64_to_int (input_buf[ 8]) << 0
10876 | itoa64_to_int (input_buf[ 9]) << 6
10877 | itoa64_to_int (input_buf[10]) << 12
10878 | itoa64_to_int (input_buf[11]) << 18;
10879 digest[3] = itoa64_to_int (input_buf[12]) << 0
10880 | itoa64_to_int (input_buf[13]) << 6
10881 | itoa64_to_int (input_buf[14]) << 12
10882 | itoa64_to_int (input_buf[15]) << 18;
10883
10884 digest[0] -= MD5M_A;
10885 digest[1] -= MD5M_B;
10886 digest[2] -= MD5M_C;
10887 digest[3] -= MD5M_D;
10888
10889 digest[0] &= 0x00ffffff;
10890 digest[1] &= 0x00ffffff;
10891 digest[2] &= 0x00ffffff;
10892 digest[3] &= 0x00ffffff;
10893
10894 if (input_buf[16] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
10895
10896 uint salt_len = input_len - 16 - 1;
10897
10898 char *salt_buf = input_buf + 16 + 1;
10899
10900 char *salt_buf_ptr = (char *) salt->salt_buf;
10901
10902 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
10903
10904 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
10905
10906 salt->salt_len = salt_len;
10907
10908 return (PARSER_OK);
10909 }
10910
10911 void transform_netntlmv1_key (const u8 *nthash, u8 *key)
10912 {
10913 key[0] = (nthash[0] >> 0);
10914 key[1] = (nthash[0] << 7) | (nthash[1] >> 1);
10915 key[2] = (nthash[1] << 6) | (nthash[2] >> 2);
10916 key[3] = (nthash[2] << 5) | (nthash[3] >> 3);
10917 key[4] = (nthash[3] << 4) | (nthash[4] >> 4);
10918 key[5] = (nthash[4] << 3) | (nthash[5] >> 5);
10919 key[6] = (nthash[5] << 2) | (nthash[6] >> 6);
10920 key[7] = (nthash[6] << 1);
10921
10922 key[0] |= 0x01;
10923 key[1] |= 0x01;
10924 key[2] |= 0x01;
10925 key[3] |= 0x01;
10926 key[4] |= 0x01;
10927 key[5] |= 0x01;
10928 key[6] |= 0x01;
10929 key[7] |= 0x01;
10930 }
10931
10932 int netntlmv1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
10933 {
10934 if ((input_len < DISPLAY_LEN_MIN_5500) || (input_len > DISPLAY_LEN_MAX_5500)) return (PARSER_GLOBAL_LENGTH);
10935
10936 u32 *digest = (u32 *) hash_buf->digest;
10937
10938 salt_t *salt = hash_buf->salt;
10939
10940 netntlm_t *netntlm = (netntlm_t *) hash_buf->esalt;
10941
10942 /**
10943 * parse line
10944 */
10945
10946 char *user_pos = input_buf;
10947
10948 char *unused_pos = strchr (user_pos, ':');
10949
10950 if (unused_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
10951
10952 uint user_len = unused_pos - user_pos;
10953
10954 if (user_len > 60) return (PARSER_SALT_LENGTH);
10955
10956 unused_pos++;
10957
10958 char *domain_pos = strchr (unused_pos, ':');
10959
10960 if (domain_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
10961
10962 uint unused_len = domain_pos - unused_pos;
10963
10964 if (unused_len != 0) return (PARSER_SALT_LENGTH);
10965
10966 domain_pos++;
10967
10968 char *srvchall_pos = strchr (domain_pos, ':');
10969
10970 if (srvchall_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
10971
10972 uint domain_len = srvchall_pos - domain_pos;
10973
10974 if (domain_len > 45) return (PARSER_SALT_LENGTH);
10975
10976 srvchall_pos++;
10977
10978 char *hash_pos = strchr (srvchall_pos, ':');
10979
10980 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
10981
10982 uint srvchall_len = hash_pos - srvchall_pos;
10983
10984 // if (srvchall_len != 0) return (PARSER_SALT_LENGTH);
10985
10986 hash_pos++;
10987
10988 char *clichall_pos = strchr (hash_pos, ':');
10989
10990 if (clichall_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
10991
10992 uint hash_len = clichall_pos - hash_pos;
10993
10994 if (hash_len != 48) return (PARSER_HASH_LENGTH);
10995
10996 clichall_pos++;
10997
10998 uint clichall_len = input_len - user_len - 1 - unused_len - 1 - domain_len - 1 - srvchall_len - 1 - hash_len - 1;
10999
11000 if (clichall_len != 16) return (PARSER_SALT_LENGTH);
11001
11002 /**
11003 * store some data for later use
11004 */
11005
11006 netntlm->user_len = user_len * 2;
11007 netntlm->domain_len = domain_len * 2;
11008 netntlm->srvchall_len = srvchall_len / 2;
11009 netntlm->clichall_len = clichall_len / 2;
11010
11011 char *userdomain_ptr = (char *) netntlm->userdomain_buf;
11012 char *chall_ptr = (char *) netntlm->chall_buf;
11013
11014 /**
11015 * handle username and domainname
11016 */
11017
11018 for (uint i = 0; i < user_len; i++)
11019 {
11020 *userdomain_ptr++ = user_pos[i];
11021 *userdomain_ptr++ = 0;
11022 }
11023
11024 for (uint i = 0; i < domain_len; i++)
11025 {
11026 *userdomain_ptr++ = domain_pos[i];
11027 *userdomain_ptr++ = 0;
11028 }
11029
11030 /**
11031 * handle server challenge encoding
11032 */
11033
11034 for (uint i = 0; i < srvchall_len; i += 2)
11035 {
11036 const char p0 = srvchall_pos[i + 0];
11037 const char p1 = srvchall_pos[i + 1];
11038
11039 *chall_ptr++ = hex_convert (p1) << 0
11040 | hex_convert (p0) << 4;
11041 }
11042
11043 /**
11044 * handle client challenge encoding
11045 */
11046
11047 for (uint i = 0; i < clichall_len; i += 2)
11048 {
11049 const char p0 = clichall_pos[i + 0];
11050 const char p1 = clichall_pos[i + 1];
11051
11052 *chall_ptr++ = hex_convert (p1) << 0
11053 | hex_convert (p0) << 4;
11054 }
11055
11056 /**
11057 * store data
11058 */
11059
11060 char *salt_buf_ptr = (char *) salt->salt_buf;
11061
11062 uint salt_len = parse_and_store_salt (salt_buf_ptr, clichall_pos, clichall_len);
11063
11064 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
11065
11066 salt->salt_len = salt_len;
11067
11068 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
11069 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
11070 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
11071 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
11072
11073 digest[0] = byte_swap_32 (digest[0]);
11074 digest[1] = byte_swap_32 (digest[1]);
11075 digest[2] = byte_swap_32 (digest[2]);
11076 digest[3] = byte_swap_32 (digest[3]);
11077
11078 /* special case, last 8 byte do not need to be checked since they are brute-forced next */
11079
11080 uint digest_tmp[2] = { 0 };
11081
11082 digest_tmp[0] = hex_to_u32 ((const u8 *) &hash_pos[32]);
11083 digest_tmp[1] = hex_to_u32 ((const u8 *) &hash_pos[40]);
11084
11085 digest_tmp[0] = byte_swap_32 (digest_tmp[0]);
11086 digest_tmp[1] = byte_swap_32 (digest_tmp[1]);
11087
11088 /* special case 2: ESS */
11089
11090 if (srvchall_len == 48)
11091 {
11092 if ((netntlm->chall_buf[2] == 0) && (netntlm->chall_buf[3] == 0) && (netntlm->chall_buf[4] == 0) && (netntlm->chall_buf[5] == 0))
11093 {
11094 uint w[16] = { 0 };
11095
11096 w[ 0] = netntlm->chall_buf[6];
11097 w[ 1] = netntlm->chall_buf[7];
11098 w[ 2] = netntlm->chall_buf[0];
11099 w[ 3] = netntlm->chall_buf[1];
11100 w[ 4] = 0x80;
11101 w[14] = 16 * 8;
11102
11103 uint dgst[4] = { 0 };
11104
11105 dgst[0] = MAGIC_A;
11106 dgst[1] = MAGIC_B;
11107 dgst[2] = MAGIC_C;
11108 dgst[3] = MAGIC_D;
11109
11110 md5_64 (w, dgst);
11111
11112 salt->salt_buf[0] = dgst[0];
11113 salt->salt_buf[1] = dgst[1];
11114 }
11115 }
11116
11117 /* precompute netntlmv1 exploit start */
11118
11119 for (uint i = 0; i < 0x10000; i++)
11120 {
11121 uint key_md4[2] = { i, 0 };
11122 uint key_des[2] = { 0, 0 };
11123
11124 transform_netntlmv1_key ((u8 *) key_md4, (u8 *) key_des);
11125
11126 uint Kc[16] = { 0 };
11127 uint Kd[16] = { 0 };
11128
11129 _des_keysetup (key_des, Kc, Kd, c_skb);
11130
11131 uint data3[2] = { salt->salt_buf[0], salt->salt_buf[1] };
11132
11133 _des_encrypt (data3, Kc, Kd, c_SPtrans);
11134
11135 if (data3[0] != digest_tmp[0]) continue;
11136 if (data3[1] != digest_tmp[1]) continue;
11137
11138 salt->salt_buf[2] = i;
11139
11140 salt->salt_len = 24;
11141
11142 break;
11143 }
11144
11145 salt->salt_buf_pc[0] = digest_tmp[0];
11146 salt->salt_buf_pc[1] = digest_tmp[1];
11147
11148 /* precompute netntlmv1 exploit stop */
11149
11150 u32 tt;
11151
11152 IP (digest[0], digest[1], tt);
11153 IP (digest[2], digest[3], tt);
11154
11155 digest[0] = rotr32 (digest[0], 29);
11156 digest[1] = rotr32 (digest[1], 29);
11157 digest[2] = rotr32 (digest[2], 29);
11158 digest[3] = rotr32 (digest[3], 29);
11159
11160 IP (salt->salt_buf[0], salt->salt_buf[1], tt);
11161
11162 salt->salt_buf[0] = rotl32 (salt->salt_buf[0], 3);
11163 salt->salt_buf[1] = rotl32 (salt->salt_buf[1], 3);
11164
11165 return (PARSER_OK);
11166 }
11167
11168 int netntlmv2_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11169 {
11170 if ((input_len < DISPLAY_LEN_MIN_5600) || (input_len > DISPLAY_LEN_MAX_5600)) return (PARSER_GLOBAL_LENGTH);
11171
11172 u32 *digest = (u32 *) hash_buf->digest;
11173
11174 salt_t *salt = hash_buf->salt;
11175
11176 netntlm_t *netntlm = (netntlm_t *) hash_buf->esalt;
11177
11178 /**
11179 * parse line
11180 */
11181
11182 char *user_pos = input_buf;
11183
11184 char *unused_pos = strchr (user_pos, ':');
11185
11186 if (unused_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
11187
11188 uint user_len = unused_pos - user_pos;
11189
11190 if (user_len > 60) return (PARSER_SALT_LENGTH);
11191
11192 unused_pos++;
11193
11194 char *domain_pos = strchr (unused_pos, ':');
11195
11196 if (domain_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
11197
11198 uint unused_len = domain_pos - unused_pos;
11199
11200 if (unused_len != 0) return (PARSER_SALT_LENGTH);
11201
11202 domain_pos++;
11203
11204 char *srvchall_pos = strchr (domain_pos, ':');
11205
11206 if (srvchall_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
11207
11208 uint domain_len = srvchall_pos - domain_pos;
11209
11210 if (domain_len > 45) return (PARSER_SALT_LENGTH);
11211
11212 srvchall_pos++;
11213
11214 char *hash_pos = strchr (srvchall_pos, ':');
11215
11216 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
11217
11218 uint srvchall_len = hash_pos - srvchall_pos;
11219
11220 if (srvchall_len != 16) return (PARSER_SALT_LENGTH);
11221
11222 hash_pos++;
11223
11224 char *clichall_pos = strchr (hash_pos, ':');
11225
11226 if (clichall_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
11227
11228 uint hash_len = clichall_pos - hash_pos;
11229
11230 if (hash_len != 32) return (PARSER_HASH_LENGTH);
11231
11232 clichall_pos++;
11233
11234 uint clichall_len = input_len - user_len - 1 - unused_len - 1 - domain_len - 1 - srvchall_len - 1 - hash_len - 1;
11235
11236 if (clichall_len > 1024) return (PARSER_SALT_LENGTH);
11237
11238 if (clichall_len % 2) return (PARSER_SALT_VALUE);
11239
11240 /**
11241 * store some data for later use
11242 */
11243
11244 netntlm->user_len = user_len * 2;
11245 netntlm->domain_len = domain_len * 2;
11246 netntlm->srvchall_len = srvchall_len / 2;
11247 netntlm->clichall_len = clichall_len / 2;
11248
11249 char *userdomain_ptr = (char *) netntlm->userdomain_buf;
11250 char *chall_ptr = (char *) netntlm->chall_buf;
11251
11252 /**
11253 * handle username and domainname
11254 */
11255
11256 for (uint i = 0; i < user_len; i++)
11257 {
11258 *userdomain_ptr++ = toupper (user_pos[i]);
11259 *userdomain_ptr++ = 0;
11260 }
11261
11262 for (uint i = 0; i < domain_len; i++)
11263 {
11264 *userdomain_ptr++ = domain_pos[i];
11265 *userdomain_ptr++ = 0;
11266 }
11267
11268 *userdomain_ptr++ = 0x80;
11269
11270 /**
11271 * handle server challenge encoding
11272 */
11273
11274 for (uint i = 0; i < srvchall_len; i += 2)
11275 {
11276 const char p0 = srvchall_pos[i + 0];
11277 const char p1 = srvchall_pos[i + 1];
11278
11279 *chall_ptr++ = hex_convert (p1) << 0
11280 | hex_convert (p0) << 4;
11281 }
11282
11283 /**
11284 * handle client challenge encoding
11285 */
11286
11287 for (uint i = 0; i < clichall_len; i += 2)
11288 {
11289 const char p0 = clichall_pos[i + 0];
11290 const char p1 = clichall_pos[i + 1];
11291
11292 *chall_ptr++ = hex_convert (p1) << 0
11293 | hex_convert (p0) << 4;
11294 }
11295
11296 *chall_ptr++ = 0x80;
11297
11298 /**
11299 * handle hash itself
11300 */
11301
11302 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
11303 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
11304 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
11305 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
11306
11307 digest[0] = byte_swap_32 (digest[0]);
11308 digest[1] = byte_swap_32 (digest[1]);
11309 digest[2] = byte_swap_32 (digest[2]);
11310 digest[3] = byte_swap_32 (digest[3]);
11311
11312 /**
11313 * reuse challange data as salt_buf, its the buffer that is most likely unique
11314 */
11315
11316 salt->salt_buf[0] = 0;
11317 salt->salt_buf[1] = 0;
11318 salt->salt_buf[2] = 0;
11319 salt->salt_buf[3] = 0;
11320 salt->salt_buf[4] = 0;
11321 salt->salt_buf[5] = 0;
11322 salt->salt_buf[6] = 0;
11323 salt->salt_buf[7] = 0;
11324
11325 uint *uptr;
11326
11327 uptr = (uint *) netntlm->userdomain_buf;
11328
11329 for (uint i = 0; i < 16; i += 16)
11330 {
11331 md5_64 (uptr, salt->salt_buf);
11332 }
11333
11334 uptr = (uint *) netntlm->chall_buf;
11335
11336 for (uint i = 0; i < 256; i += 16)
11337 {
11338 md5_64 (uptr, salt->salt_buf);
11339 }
11340
11341 salt->salt_len = 16;
11342
11343 return (PARSER_OK);
11344 }
11345
11346 int joomla_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11347 {
11348 if (data.opts_type & OPTS_TYPE_ST_HEX)
11349 {
11350 if ((input_len < DISPLAY_LEN_MIN_11H) || (input_len > DISPLAY_LEN_MAX_11H)) return (PARSER_GLOBAL_LENGTH);
11351 }
11352 else
11353 {
11354 if ((input_len < DISPLAY_LEN_MIN_11) || (input_len > DISPLAY_LEN_MAX_11)) return (PARSER_GLOBAL_LENGTH);
11355 }
11356
11357 u32 *digest = (u32 *) hash_buf->digest;
11358
11359 salt_t *salt = hash_buf->salt;
11360
11361 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11362 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11363 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11364 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11365
11366 digest[0] = byte_swap_32 (digest[0]);
11367 digest[1] = byte_swap_32 (digest[1]);
11368 digest[2] = byte_swap_32 (digest[2]);
11369 digest[3] = byte_swap_32 (digest[3]);
11370
11371 digest[0] -= MD5M_A;
11372 digest[1] -= MD5M_B;
11373 digest[2] -= MD5M_C;
11374 digest[3] -= MD5M_D;
11375
11376 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
11377
11378 uint salt_len = input_len - 32 - 1;
11379
11380 char *salt_buf = input_buf + 32 + 1;
11381
11382 char *salt_buf_ptr = (char *) salt->salt_buf;
11383
11384 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
11385
11386 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
11387
11388 salt->salt_len = salt_len;
11389
11390 return (PARSER_OK);
11391 }
11392
11393 int postgresql_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11394 {
11395 if (data.opts_type & OPTS_TYPE_ST_HEX)
11396 {
11397 if ((input_len < DISPLAY_LEN_MIN_12H) || (input_len > DISPLAY_LEN_MAX_12H)) return (PARSER_GLOBAL_LENGTH);
11398 }
11399 else
11400 {
11401 if ((input_len < DISPLAY_LEN_MIN_12) || (input_len > DISPLAY_LEN_MAX_12)) return (PARSER_GLOBAL_LENGTH);
11402 }
11403
11404 u32 *digest = (u32 *) hash_buf->digest;
11405
11406 salt_t *salt = hash_buf->salt;
11407
11408 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11409 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11410 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11411 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11412
11413 digest[0] = byte_swap_32 (digest[0]);
11414 digest[1] = byte_swap_32 (digest[1]);
11415 digest[2] = byte_swap_32 (digest[2]);
11416 digest[3] = byte_swap_32 (digest[3]);
11417
11418 digest[0] -= MD5M_A;
11419 digest[1] -= MD5M_B;
11420 digest[2] -= MD5M_C;
11421 digest[3] -= MD5M_D;
11422
11423 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
11424
11425 uint salt_len = input_len - 32 - 1;
11426
11427 char *salt_buf = input_buf + 32 + 1;
11428
11429 char *salt_buf_ptr = (char *) salt->salt_buf;
11430
11431 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
11432
11433 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
11434
11435 salt->salt_len = salt_len;
11436
11437 return (PARSER_OK);
11438 }
11439
11440 int md5md5_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11441 {
11442 if ((input_len < DISPLAY_LEN_MIN_2600) || (input_len > DISPLAY_LEN_MAX_2600)) return (PARSER_GLOBAL_LENGTH);
11443
11444 u32 *digest = (u32 *) hash_buf->digest;
11445
11446 salt_t *salt = hash_buf->salt;
11447
11448 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11449 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11450 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11451 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11452
11453 digest[0] = byte_swap_32 (digest[0]);
11454 digest[1] = byte_swap_32 (digest[1]);
11455 digest[2] = byte_swap_32 (digest[2]);
11456 digest[3] = byte_swap_32 (digest[3]);
11457
11458 digest[0] -= MD5M_A;
11459 digest[1] -= MD5M_B;
11460 digest[2] -= MD5M_C;
11461 digest[3] -= MD5M_D;
11462
11463 /**
11464 * This is a virtual salt. While the algorithm is basically not salted
11465 * we can exploit the salt buffer to set the 0x80 and the w[14] value.
11466 * This way we can save a special md5md5 kernel and reuse the one from vbull.
11467 */
11468
11469 char *salt_buf_ptr = (char *) salt->salt_buf;
11470
11471 uint salt_len = parse_and_store_salt (salt_buf_ptr, (char *) "", 0);
11472
11473 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
11474
11475 salt->salt_len = salt_len;
11476
11477 return (PARSER_OK);
11478 }
11479
11480 int vb3_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11481 {
11482 if (data.opts_type & OPTS_TYPE_ST_HEX)
11483 {
11484 if ((input_len < DISPLAY_LEN_MIN_2611H) || (input_len > DISPLAY_LEN_MAX_2611H)) return (PARSER_GLOBAL_LENGTH);
11485 }
11486 else
11487 {
11488 if ((input_len < DISPLAY_LEN_MIN_2611) || (input_len > DISPLAY_LEN_MAX_2611)) return (PARSER_GLOBAL_LENGTH);
11489 }
11490
11491 u32 *digest = (u32 *) hash_buf->digest;
11492
11493 salt_t *salt = hash_buf->salt;
11494
11495 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11496 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11497 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11498 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11499
11500 digest[0] = byte_swap_32 (digest[0]);
11501 digest[1] = byte_swap_32 (digest[1]);
11502 digest[2] = byte_swap_32 (digest[2]);
11503 digest[3] = byte_swap_32 (digest[3]);
11504
11505 digest[0] -= MD5M_A;
11506 digest[1] -= MD5M_B;
11507 digest[2] -= MD5M_C;
11508 digest[3] -= MD5M_D;
11509
11510 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
11511
11512 uint salt_len = input_len - 32 - 1;
11513
11514 char *salt_buf = input_buf + 32 + 1;
11515
11516 char *salt_buf_ptr = (char *) salt->salt_buf;
11517
11518 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
11519
11520 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
11521
11522 salt->salt_len = salt_len;
11523
11524 return (PARSER_OK);
11525 }
11526
11527 int vb30_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11528 {
11529 if (data.opts_type & OPTS_TYPE_ST_HEX)
11530 {
11531 if ((input_len < DISPLAY_LEN_MIN_2711H) || (input_len > DISPLAY_LEN_MAX_2711H)) return (PARSER_GLOBAL_LENGTH);
11532 }
11533 else
11534 {
11535 if ((input_len < DISPLAY_LEN_MIN_2711) || (input_len > DISPLAY_LEN_MAX_2711)) return (PARSER_GLOBAL_LENGTH);
11536 }
11537
11538 u32 *digest = (u32 *) hash_buf->digest;
11539
11540 salt_t *salt = hash_buf->salt;
11541
11542 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11543 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11544 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11545 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11546
11547 digest[0] = byte_swap_32 (digest[0]);
11548 digest[1] = byte_swap_32 (digest[1]);
11549 digest[2] = byte_swap_32 (digest[2]);
11550 digest[3] = byte_swap_32 (digest[3]);
11551
11552 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
11553
11554 uint salt_len = input_len - 32 - 1;
11555
11556 char *salt_buf = input_buf + 32 + 1;
11557
11558 char *salt_buf_ptr = (char *) salt->salt_buf;
11559
11560 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
11561
11562 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
11563
11564 salt->salt_len = salt_len;
11565
11566 return (PARSER_OK);
11567 }
11568
11569 int dcc_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11570 {
11571 if (data.opts_type & OPTS_TYPE_ST_HEX)
11572 {
11573 if ((input_len < DISPLAY_LEN_MIN_1100H) || (input_len > DISPLAY_LEN_MAX_1100H)) return (PARSER_GLOBAL_LENGTH);
11574 }
11575 else
11576 {
11577 if ((input_len < DISPLAY_LEN_MIN_1100) || (input_len > DISPLAY_LEN_MAX_1100)) return (PARSER_GLOBAL_LENGTH);
11578 }
11579
11580 u32 *digest = (u32 *) hash_buf->digest;
11581
11582 salt_t *salt = hash_buf->salt;
11583
11584 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11585 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11586 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11587 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11588
11589 digest[0] = byte_swap_32 (digest[0]);
11590 digest[1] = byte_swap_32 (digest[1]);
11591 digest[2] = byte_swap_32 (digest[2]);
11592 digest[3] = byte_swap_32 (digest[3]);
11593
11594 digest[0] -= MD4M_A;
11595 digest[1] -= MD4M_B;
11596 digest[2] -= MD4M_C;
11597 digest[3] -= MD4M_D;
11598
11599 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
11600
11601 uint salt_len = input_len - 32 - 1;
11602
11603 char *salt_buf = input_buf + 32 + 1;
11604
11605 char *salt_buf_ptr = (char *) salt->salt_buf;
11606
11607 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
11608
11609 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
11610
11611 salt->salt_len = salt_len;
11612
11613 return (PARSER_OK);
11614 }
11615
11616 int ipb2_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11617 {
11618 if (data.opts_type & OPTS_TYPE_ST_HEX)
11619 {
11620 if ((input_len < DISPLAY_LEN_MIN_2811H) || (input_len > DISPLAY_LEN_MAX_2811H)) return (PARSER_GLOBAL_LENGTH);
11621 }
11622 else
11623 {
11624 if ((input_len < DISPLAY_LEN_MIN_2811) || (input_len > DISPLAY_LEN_MAX_2811)) return (PARSER_GLOBAL_LENGTH);
11625 }
11626
11627 u32 *digest = (u32 *) hash_buf->digest;
11628
11629 salt_t *salt = hash_buf->salt;
11630
11631 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11632 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11633 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11634 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11635
11636 digest[0] = byte_swap_32 (digest[0]);
11637 digest[1] = byte_swap_32 (digest[1]);
11638 digest[2] = byte_swap_32 (digest[2]);
11639 digest[3] = byte_swap_32 (digest[3]);
11640
11641 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
11642
11643 uint salt_len = input_len - 32 - 1;
11644
11645 char *salt_buf = input_buf + 32 + 1;
11646
11647 uint salt_pc_block[16] = { 0 };
11648
11649 char *salt_pc_block_ptr = (char *) salt_pc_block;
11650
11651 salt_len = parse_and_store_salt (salt_pc_block_ptr, salt_buf, salt_len);
11652
11653 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
11654
11655 salt_pc_block_ptr[salt_len] = (unsigned char) 0x80;
11656
11657 salt_pc_block[14] = salt_len * 8;
11658
11659 uint salt_pc_digest[4] = { MAGIC_A, MAGIC_B, MAGIC_C, MAGIC_D };
11660
11661 md5_64 (salt_pc_block, salt_pc_digest);
11662
11663 salt_pc_digest[0] = byte_swap_32 (salt_pc_digest[0]);
11664 salt_pc_digest[1] = byte_swap_32 (salt_pc_digest[1]);
11665 salt_pc_digest[2] = byte_swap_32 (salt_pc_digest[2]);
11666 salt_pc_digest[3] = byte_swap_32 (salt_pc_digest[3]);
11667
11668 u8 *salt_buf_ptr = (u8 *) salt->salt_buf;
11669
11670 memcpy (salt_buf_ptr, salt_buf, salt_len);
11671
11672 u8 *salt_buf_pc_ptr = (u8 *) salt->salt_buf_pc;
11673
11674 bin_to_hex_lower (salt_pc_digest[0], salt_buf_pc_ptr + 0);
11675 bin_to_hex_lower (salt_pc_digest[1], salt_buf_pc_ptr + 8);
11676 bin_to_hex_lower (salt_pc_digest[2], salt_buf_pc_ptr + 16);
11677 bin_to_hex_lower (salt_pc_digest[3], salt_buf_pc_ptr + 24);
11678
11679 salt->salt_len = 32; // changed, was salt_len before -- was a bug? 32 should be correct
11680
11681 return (PARSER_OK);
11682 }
11683
11684 int sha1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11685 {
11686 if ((input_len < DISPLAY_LEN_MIN_100) || (input_len > DISPLAY_LEN_MAX_100)) return (PARSER_GLOBAL_LENGTH);
11687
11688 u32 *digest = (u32 *) hash_buf->digest;
11689
11690 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11691 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11692 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11693 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11694 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
11695
11696 digest[0] -= SHA1M_A;
11697 digest[1] -= SHA1M_B;
11698 digest[2] -= SHA1M_C;
11699 digest[3] -= SHA1M_D;
11700 digest[4] -= SHA1M_E;
11701
11702 return (PARSER_OK);
11703 }
11704
11705 int sha1linkedin_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11706 {
11707 if ((input_len < DISPLAY_LEN_MIN_100) || (input_len > DISPLAY_LEN_MAX_100)) return (PARSER_GLOBAL_LENGTH);
11708
11709 u32 *digest = (u32 *) hash_buf->digest;
11710
11711 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11712 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11713 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11714 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11715 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
11716
11717 return (PARSER_OK);
11718 }
11719
11720 int sha1axcrypt_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11721 {
11722 if ((input_len < DISPLAY_LEN_MIN_13300) || (input_len > DISPLAY_LEN_MAX_13300)) return (PARSER_GLOBAL_LENGTH);
11723
11724 if (memcmp (SIGNATURE_AXCRYPT_SHA1, input_buf, 13)) return (PARSER_SIGNATURE_UNMATCHED);
11725
11726 u32 *digest = (u32 *) hash_buf->digest;
11727
11728 input_buf +=14;
11729
11730 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11731 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11732 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11733 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11734 digest[4] = 0x00000000;
11735
11736 return (PARSER_OK);
11737 }
11738
11739 int sha1s_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11740 {
11741 if (data.opts_type & OPTS_TYPE_ST_HEX)
11742 {
11743 if ((input_len < DISPLAY_LEN_MIN_110H) || (input_len > DISPLAY_LEN_MAX_110H)) return (PARSER_GLOBAL_LENGTH);
11744 }
11745 else
11746 {
11747 if ((input_len < DISPLAY_LEN_MIN_110) || (input_len > DISPLAY_LEN_MAX_110)) return (PARSER_GLOBAL_LENGTH);
11748 }
11749
11750 u32 *digest = (u32 *) hash_buf->digest;
11751
11752 salt_t *salt = hash_buf->salt;
11753
11754 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11755 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11756 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11757 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11758 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
11759
11760 digest[0] -= SHA1M_A;
11761 digest[1] -= SHA1M_B;
11762 digest[2] -= SHA1M_C;
11763 digest[3] -= SHA1M_D;
11764 digest[4] -= SHA1M_E;
11765
11766 if (input_buf[40] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
11767
11768 uint salt_len = input_len - 40 - 1;
11769
11770 char *salt_buf = input_buf + 40 + 1;
11771
11772 char *salt_buf_ptr = (char *) salt->salt_buf;
11773
11774 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
11775
11776 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
11777
11778 salt->salt_len = salt_len;
11779
11780 return (PARSER_OK);
11781 }
11782
11783 int pstoken_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11784 {
11785 if (data.opts_type & OPTS_TYPE_ST_HEX)
11786 {
11787 if ((input_len < DISPLAY_LEN_MIN_13500) || (input_len > DISPLAY_LEN_MAX_13500)) return (PARSER_GLOBAL_LENGTH);
11788 }
11789 else
11790 {
11791 if ((input_len < DISPLAY_LEN_MIN_13500) || (input_len > DISPLAY_LEN_MAX_13500)) return (PARSER_GLOBAL_LENGTH);
11792 }
11793
11794 u32 *digest = (u32 *) hash_buf->digest;
11795 salt_t *salt = hash_buf->salt;
11796 pstoken_t *pstoken = (pstoken_t *) hash_buf->esalt;
11797 u8 pstoken_tmp[DISPLAY_LEN_MAX_13500 - 40 - 1];
11798
11799 memset(pstoken_tmp, 0, DISPLAY_LEN_MAX_13500 - 40 - 1);
11800
11801 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
11802 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
11803 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
11804 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
11805 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
11806
11807 digest[0] -= SHA1M_A;
11808 digest[1] -= SHA1M_B;
11809 digest[2] -= SHA1M_C;
11810 digest[3] -= SHA1M_D;
11811 digest[4] -= SHA1M_E;
11812
11813 if (input_buf[40] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
11814
11815 uint salt_len = input_len - 40 - 1;
11816
11817 char *salt_buf = input_buf + 40 + 1;
11818
11819 if (salt_len == UINT_MAX || salt_len % 2 != 0) return (PARSER_SALT_LENGTH);
11820
11821 for (uint i = 0; i < salt_len / 2; i++)
11822 {
11823 pstoken_tmp[i] = hex_to_u8 ((const u8 *) &salt_buf[i * 2]);
11824 }
11825
11826 salt_len /= 2;
11827 salt->salt_len = salt_len;
11828 pstoken->salt_len = salt_len;
11829
11830 memcpy(salt->salt_buf, pstoken_tmp, 16);
11831 memcpy(pstoken->salt_buf, pstoken_tmp, salt_len);
11832
11833 return (PARSER_OK);
11834 }
11835
11836
11837 int sha1b64_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11838 {
11839 if ((input_len < DISPLAY_LEN_MIN_101) || (input_len > DISPLAY_LEN_MAX_101)) return (PARSER_GLOBAL_LENGTH);
11840
11841 if (memcmp (SIGNATURE_SHA1B64, input_buf, 5)) return (PARSER_SIGNATURE_UNMATCHED);
11842
11843 u32 *digest = (u32 *) hash_buf->digest;
11844
11845 u8 tmp_buf[100] = { 0 };
11846
11847 base64_decode (base64_to_int, (const u8 *) input_buf + 5, input_len - 5, tmp_buf);
11848
11849 memcpy (digest, tmp_buf, 20);
11850
11851 digest[0] = byte_swap_32 (digest[0]);
11852 digest[1] = byte_swap_32 (digest[1]);
11853 digest[2] = byte_swap_32 (digest[2]);
11854 digest[3] = byte_swap_32 (digest[3]);
11855 digest[4] = byte_swap_32 (digest[4]);
11856
11857 digest[0] -= SHA1M_A;
11858 digest[1] -= SHA1M_B;
11859 digest[2] -= SHA1M_C;
11860 digest[3] -= SHA1M_D;
11861 digest[4] -= SHA1M_E;
11862
11863 return (PARSER_OK);
11864 }
11865
11866 int sha1b64s_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11867 {
11868 if ((input_len < DISPLAY_LEN_MIN_111) || (input_len > DISPLAY_LEN_MAX_111)) return (PARSER_GLOBAL_LENGTH);
11869
11870 if (memcmp (SIGNATURE_SSHA1B64_lower, input_buf, 6) && memcmp (SIGNATURE_SSHA1B64_upper, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
11871
11872 u32 *digest = (u32 *) hash_buf->digest;
11873
11874 salt_t *salt = hash_buf->salt;
11875
11876 u8 tmp_buf[100] = { 0 };
11877
11878 int tmp_len = base64_decode (base64_to_int, (const u8 *) input_buf + 6, input_len - 6, tmp_buf);
11879
11880 if (tmp_len < 20) return (PARSER_HASH_LENGTH);
11881
11882 memcpy (digest, tmp_buf, 20);
11883
11884 int salt_len = tmp_len - 20;
11885
11886 if (salt_len < 0) return (PARSER_SALT_LENGTH);
11887
11888 salt->salt_len = salt_len;
11889
11890 memcpy (salt->salt_buf, tmp_buf + 20, salt->salt_len);
11891
11892 if (data.opts_type & OPTS_TYPE_ST_ADD80)
11893 {
11894 char *ptr = (char *) salt->salt_buf;
11895
11896 ptr[salt->salt_len] = 0x80;
11897 }
11898
11899 digest[0] = byte_swap_32 (digest[0]);
11900 digest[1] = byte_swap_32 (digest[1]);
11901 digest[2] = byte_swap_32 (digest[2]);
11902 digest[3] = byte_swap_32 (digest[3]);
11903 digest[4] = byte_swap_32 (digest[4]);
11904
11905 digest[0] -= SHA1M_A;
11906 digest[1] -= SHA1M_B;
11907 digest[2] -= SHA1M_C;
11908 digest[3] -= SHA1M_D;
11909 digest[4] -= SHA1M_E;
11910
11911 return (PARSER_OK);
11912 }
11913
11914 int mssql2000_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11915 {
11916 if ((input_len < DISPLAY_LEN_MIN_131) || (input_len > DISPLAY_LEN_MAX_131)) return (PARSER_GLOBAL_LENGTH);
11917
11918 if (memcmp (SIGNATURE_MSSQL, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
11919
11920 u32 *digest = (u32 *) hash_buf->digest;
11921
11922 salt_t *salt = hash_buf->salt;
11923
11924 char *salt_buf = input_buf + 6;
11925
11926 uint salt_len = 8;
11927
11928 char *salt_buf_ptr = (char *) salt->salt_buf;
11929
11930 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
11931
11932 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
11933
11934 salt->salt_len = salt_len;
11935
11936 char *hash_pos = input_buf + 6 + 8 + 40;
11937
11938 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
11939 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
11940 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
11941 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
11942 digest[4] = hex_to_u32 ((const u8 *) &hash_pos[32]);
11943
11944 digest[0] -= SHA1M_A;
11945 digest[1] -= SHA1M_B;
11946 digest[2] -= SHA1M_C;
11947 digest[3] -= SHA1M_D;
11948 digest[4] -= SHA1M_E;
11949
11950 return (PARSER_OK);
11951 }
11952
11953 int mssql2005_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11954 {
11955 if ((input_len < DISPLAY_LEN_MIN_132) || (input_len > DISPLAY_LEN_MAX_132)) return (PARSER_GLOBAL_LENGTH);
11956
11957 if (memcmp (SIGNATURE_MSSQL, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
11958
11959 u32 *digest = (u32 *) hash_buf->digest;
11960
11961 salt_t *salt = hash_buf->salt;
11962
11963 char *salt_buf = input_buf + 6;
11964
11965 uint salt_len = 8;
11966
11967 char *salt_buf_ptr = (char *) salt->salt_buf;
11968
11969 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
11970
11971 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
11972
11973 salt->salt_len = salt_len;
11974
11975 char *hash_pos = input_buf + 6 + 8;
11976
11977 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
11978 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
11979 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
11980 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
11981 digest[4] = hex_to_u32 ((const u8 *) &hash_pos[32]);
11982
11983 digest[0] -= SHA1M_A;
11984 digest[1] -= SHA1M_B;
11985 digest[2] -= SHA1M_C;
11986 digest[3] -= SHA1M_D;
11987 digest[4] -= SHA1M_E;
11988
11989 return (PARSER_OK);
11990 }
11991
11992 int mssql2012_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
11993 {
11994 if ((input_len < DISPLAY_LEN_MIN_1731) || (input_len > DISPLAY_LEN_MAX_1731)) return (PARSER_GLOBAL_LENGTH);
11995
11996 if (memcmp (SIGNATURE_MSSQL2012, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
11997
11998 u64 *digest = (u64 *) hash_buf->digest;
11999
12000 salt_t *salt = hash_buf->salt;
12001
12002 char *salt_buf = input_buf + 6;
12003
12004 uint salt_len = 8;
12005
12006 char *salt_buf_ptr = (char *) salt->salt_buf;
12007
12008 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
12009
12010 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
12011
12012 salt->salt_len = salt_len;
12013
12014 char *hash_pos = input_buf + 6 + 8;
12015
12016 digest[0] = hex_to_u64 ((const u8 *) &hash_pos[ 0]);
12017 digest[1] = hex_to_u64 ((const u8 *) &hash_pos[ 16]);
12018 digest[2] = hex_to_u64 ((const u8 *) &hash_pos[ 32]);
12019 digest[3] = hex_to_u64 ((const u8 *) &hash_pos[ 48]);
12020 digest[4] = hex_to_u64 ((const u8 *) &hash_pos[ 64]);
12021 digest[5] = hex_to_u64 ((const u8 *) &hash_pos[ 80]);
12022 digest[6] = hex_to_u64 ((const u8 *) &hash_pos[ 96]);
12023 digest[7] = hex_to_u64 ((const u8 *) &hash_pos[112]);
12024
12025 digest[0] -= SHA512M_A;
12026 digest[1] -= SHA512M_B;
12027 digest[2] -= SHA512M_C;
12028 digest[3] -= SHA512M_D;
12029 digest[4] -= SHA512M_E;
12030 digest[5] -= SHA512M_F;
12031 digest[6] -= SHA512M_G;
12032 digest[7] -= SHA512M_H;
12033
12034 return (PARSER_OK);
12035 }
12036
12037 int oracleh_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12038 {
12039 if (data.opts_type & OPTS_TYPE_ST_HEX)
12040 {
12041 if ((input_len < DISPLAY_LEN_MIN_3100H) || (input_len > DISPLAY_LEN_MAX_3100H)) return (PARSER_GLOBAL_LENGTH);
12042 }
12043 else
12044 {
12045 if ((input_len < DISPLAY_LEN_MIN_3100) || (input_len > DISPLAY_LEN_MAX_3100)) return (PARSER_GLOBAL_LENGTH);
12046 }
12047
12048 u32 *digest = (u32 *) hash_buf->digest;
12049
12050 salt_t *salt = hash_buf->salt;
12051
12052 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
12053 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
12054 digest[2] = 0;
12055 digest[3] = 0;
12056
12057 digest[0] = byte_swap_32 (digest[0]);
12058 digest[1] = byte_swap_32 (digest[1]);
12059
12060 if (input_buf[16] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
12061
12062 uint salt_len = input_len - 16 - 1;
12063
12064 char *salt_buf = input_buf + 16 + 1;
12065
12066 char *salt_buf_ptr = (char *) salt->salt_buf;
12067
12068 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
12069
12070 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
12071
12072 salt->salt_len = salt_len;
12073
12074 return (PARSER_OK);
12075 }
12076
12077 int oracles_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12078 {
12079 if ((input_len < DISPLAY_LEN_MIN_112) || (input_len > DISPLAY_LEN_MAX_112)) return (PARSER_GLOBAL_LENGTH);
12080
12081 u32 *digest = (u32 *) hash_buf->digest;
12082
12083 salt_t *salt = hash_buf->salt;
12084
12085 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
12086 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
12087 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
12088 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
12089 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
12090
12091 digest[0] -= SHA1M_A;
12092 digest[1] -= SHA1M_B;
12093 digest[2] -= SHA1M_C;
12094 digest[3] -= SHA1M_D;
12095 digest[4] -= SHA1M_E;
12096
12097 if (input_buf[40] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
12098
12099 uint salt_len = input_len - 40 - 1;
12100
12101 char *salt_buf = input_buf + 40 + 1;
12102
12103 char *salt_buf_ptr = (char *) salt->salt_buf;
12104
12105 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
12106
12107 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
12108
12109 salt->salt_len = salt_len;
12110
12111 return (PARSER_OK);
12112 }
12113
12114 int oraclet_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12115 {
12116 if ((input_len < DISPLAY_LEN_MIN_12300) || (input_len > DISPLAY_LEN_MAX_12300)) return (PARSER_GLOBAL_LENGTH);
12117
12118 u32 *digest = (u32 *) hash_buf->digest;
12119
12120 salt_t *salt = hash_buf->salt;
12121
12122 char *hash_pos = input_buf;
12123
12124 digest[ 0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
12125 digest[ 1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
12126 digest[ 2] = hex_to_u32 ((const u8 *) &hash_pos[ 16]);
12127 digest[ 3] = hex_to_u32 ((const u8 *) &hash_pos[ 24]);
12128 digest[ 4] = hex_to_u32 ((const u8 *) &hash_pos[ 32]);
12129 digest[ 5] = hex_to_u32 ((const u8 *) &hash_pos[ 40]);
12130 digest[ 6] = hex_to_u32 ((const u8 *) &hash_pos[ 48]);
12131 digest[ 7] = hex_to_u32 ((const u8 *) &hash_pos[ 56]);
12132 digest[ 8] = hex_to_u32 ((const u8 *) &hash_pos[ 64]);
12133 digest[ 9] = hex_to_u32 ((const u8 *) &hash_pos[ 72]);
12134 digest[10] = hex_to_u32 ((const u8 *) &hash_pos[ 80]);
12135 digest[11] = hex_to_u32 ((const u8 *) &hash_pos[ 88]);
12136 digest[12] = hex_to_u32 ((const u8 *) &hash_pos[ 96]);
12137 digest[13] = hex_to_u32 ((const u8 *) &hash_pos[104]);
12138 digest[14] = hex_to_u32 ((const u8 *) &hash_pos[112]);
12139 digest[15] = hex_to_u32 ((const u8 *) &hash_pos[120]);
12140
12141 char *salt_pos = input_buf + 128;
12142
12143 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &salt_pos[ 0]);
12144 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &salt_pos[ 8]);
12145 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &salt_pos[16]);
12146 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &salt_pos[24]);
12147
12148 salt->salt_iter = ROUNDS_ORACLET - 1;
12149 salt->salt_len = 16;
12150
12151 return (PARSER_OK);
12152 }
12153
12154 int sha256_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12155 {
12156 if ((input_len < DISPLAY_LEN_MIN_1400) || (input_len > DISPLAY_LEN_MAX_1400)) return (PARSER_GLOBAL_LENGTH);
12157
12158 u32 *digest = (u32 *) hash_buf->digest;
12159
12160 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
12161 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
12162 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
12163 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
12164 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
12165 digest[5] = hex_to_u32 ((const u8 *) &input_buf[40]);
12166 digest[6] = hex_to_u32 ((const u8 *) &input_buf[48]);
12167 digest[7] = hex_to_u32 ((const u8 *) &input_buf[56]);
12168
12169 digest[0] -= SHA256M_A;
12170 digest[1] -= SHA256M_B;
12171 digest[2] -= SHA256M_C;
12172 digest[3] -= SHA256M_D;
12173 digest[4] -= SHA256M_E;
12174 digest[5] -= SHA256M_F;
12175 digest[6] -= SHA256M_G;
12176 digest[7] -= SHA256M_H;
12177
12178 return (PARSER_OK);
12179 }
12180
12181 int sha256s_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12182 {
12183 if (data.opts_type & OPTS_TYPE_ST_HEX)
12184 {
12185 if ((input_len < DISPLAY_LEN_MIN_1410H) || (input_len > DISPLAY_LEN_MAX_1410H)) return (PARSER_GLOBAL_LENGTH);
12186 }
12187 else
12188 {
12189 if ((input_len < DISPLAY_LEN_MIN_1410) || (input_len > DISPLAY_LEN_MAX_1410)) return (PARSER_GLOBAL_LENGTH);
12190 }
12191
12192 u32 *digest = (u32 *) hash_buf->digest;
12193
12194 salt_t *salt = hash_buf->salt;
12195
12196 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
12197 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
12198 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
12199 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
12200 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
12201 digest[5] = hex_to_u32 ((const u8 *) &input_buf[40]);
12202 digest[6] = hex_to_u32 ((const u8 *) &input_buf[48]);
12203 digest[7] = hex_to_u32 ((const u8 *) &input_buf[56]);
12204
12205 digest[0] -= SHA256M_A;
12206 digest[1] -= SHA256M_B;
12207 digest[2] -= SHA256M_C;
12208 digest[3] -= SHA256M_D;
12209 digest[4] -= SHA256M_E;
12210 digest[5] -= SHA256M_F;
12211 digest[6] -= SHA256M_G;
12212 digest[7] -= SHA256M_H;
12213
12214 if (input_buf[64] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
12215
12216 uint salt_len = input_len - 64 - 1;
12217
12218 char *salt_buf = input_buf + 64 + 1;
12219
12220 char *salt_buf_ptr = (char *) salt->salt_buf;
12221
12222 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
12223
12224 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
12225
12226 salt->salt_len = salt_len;
12227
12228 return (PARSER_OK);
12229 }
12230
12231 int sha384_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12232 {
12233 if ((input_len < DISPLAY_LEN_MIN_10800) || (input_len > DISPLAY_LEN_MAX_10800)) return (PARSER_GLOBAL_LENGTH);
12234
12235 u64 *digest = (u64 *) hash_buf->digest;
12236
12237 digest[0] = hex_to_u64 ((const u8 *) &input_buf[ 0]);
12238 digest[1] = hex_to_u64 ((const u8 *) &input_buf[ 16]);
12239 digest[2] = hex_to_u64 ((const u8 *) &input_buf[ 32]);
12240 digest[3] = hex_to_u64 ((const u8 *) &input_buf[ 48]);
12241 digest[4] = hex_to_u64 ((const u8 *) &input_buf[ 64]);
12242 digest[5] = hex_to_u64 ((const u8 *) &input_buf[ 80]);
12243 digest[6] = 0;
12244 digest[7] = 0;
12245
12246 digest[0] -= SHA384M_A;
12247 digest[1] -= SHA384M_B;
12248 digest[2] -= SHA384M_C;
12249 digest[3] -= SHA384M_D;
12250 digest[4] -= SHA384M_E;
12251 digest[5] -= SHA384M_F;
12252 digest[6] -= 0;
12253 digest[7] -= 0;
12254
12255 return (PARSER_OK);
12256 }
12257
12258 int sha512_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12259 {
12260 if ((input_len < DISPLAY_LEN_MIN_1700) || (input_len > DISPLAY_LEN_MAX_1700)) return (PARSER_GLOBAL_LENGTH);
12261
12262 u64 *digest = (u64 *) hash_buf->digest;
12263
12264 digest[0] = hex_to_u64 ((const u8 *) &input_buf[ 0]);
12265 digest[1] = hex_to_u64 ((const u8 *) &input_buf[ 16]);
12266 digest[2] = hex_to_u64 ((const u8 *) &input_buf[ 32]);
12267 digest[3] = hex_to_u64 ((const u8 *) &input_buf[ 48]);
12268 digest[4] = hex_to_u64 ((const u8 *) &input_buf[ 64]);
12269 digest[5] = hex_to_u64 ((const u8 *) &input_buf[ 80]);
12270 digest[6] = hex_to_u64 ((const u8 *) &input_buf[ 96]);
12271 digest[7] = hex_to_u64 ((const u8 *) &input_buf[112]);
12272
12273 digest[0] -= SHA512M_A;
12274 digest[1] -= SHA512M_B;
12275 digest[2] -= SHA512M_C;
12276 digest[3] -= SHA512M_D;
12277 digest[4] -= SHA512M_E;
12278 digest[5] -= SHA512M_F;
12279 digest[6] -= SHA512M_G;
12280 digest[7] -= SHA512M_H;
12281
12282 return (PARSER_OK);
12283 }
12284
12285 int sha512s_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12286 {
12287 if (data.opts_type & OPTS_TYPE_ST_HEX)
12288 {
12289 if ((input_len < DISPLAY_LEN_MIN_1710H) || (input_len > DISPLAY_LEN_MAX_1710H)) return (PARSER_GLOBAL_LENGTH);
12290 }
12291 else
12292 {
12293 if ((input_len < DISPLAY_LEN_MIN_1710) || (input_len > DISPLAY_LEN_MAX_1710)) return (PARSER_GLOBAL_LENGTH);
12294 }
12295
12296 u64 *digest = (u64 *) hash_buf->digest;
12297
12298 salt_t *salt = hash_buf->salt;
12299
12300 digest[0] = hex_to_u64 ((const u8 *) &input_buf[ 0]);
12301 digest[1] = hex_to_u64 ((const u8 *) &input_buf[ 16]);
12302 digest[2] = hex_to_u64 ((const u8 *) &input_buf[ 32]);
12303 digest[3] = hex_to_u64 ((const u8 *) &input_buf[ 48]);
12304 digest[4] = hex_to_u64 ((const u8 *) &input_buf[ 64]);
12305 digest[5] = hex_to_u64 ((const u8 *) &input_buf[ 80]);
12306 digest[6] = hex_to_u64 ((const u8 *) &input_buf[ 96]);
12307 digest[7] = hex_to_u64 ((const u8 *) &input_buf[112]);
12308
12309 digest[0] -= SHA512M_A;
12310 digest[1] -= SHA512M_B;
12311 digest[2] -= SHA512M_C;
12312 digest[3] -= SHA512M_D;
12313 digest[4] -= SHA512M_E;
12314 digest[5] -= SHA512M_F;
12315 digest[6] -= SHA512M_G;
12316 digest[7] -= SHA512M_H;
12317
12318 if (input_buf[128] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
12319
12320 uint salt_len = input_len - 128 - 1;
12321
12322 char *salt_buf = input_buf + 128 + 1;
12323
12324 char *salt_buf_ptr = (char *) salt->salt_buf;
12325
12326 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
12327
12328 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
12329
12330 salt->salt_len = salt_len;
12331
12332 return (PARSER_OK);
12333 }
12334
12335 int sha512crypt_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12336 {
12337 if (memcmp (SIGNATURE_SHA512CRYPT, input_buf, 3)) return (PARSER_SIGNATURE_UNMATCHED);
12338
12339 u64 *digest = (u64 *) hash_buf->digest;
12340
12341 salt_t *salt = hash_buf->salt;
12342
12343 char *salt_pos = input_buf + 3;
12344
12345 uint iterations_len = 0;
12346
12347 if (memcmp (salt_pos, "rounds=", 7) == 0)
12348 {
12349 salt_pos += 7;
12350
12351 for (iterations_len = 0; salt_pos[0] >= '0' && salt_pos[0] <= '9' && iterations_len < 7; iterations_len++, salt_pos += 1) continue;
12352
12353 if (iterations_len == 0 ) return (PARSER_SALT_ITERATION);
12354 if (salt_pos[0] != '$') return (PARSER_SIGNATURE_UNMATCHED);
12355
12356 salt_pos[0] = 0x0;
12357
12358 salt->salt_iter = atoi (salt_pos - iterations_len);
12359
12360 salt_pos += 1;
12361
12362 iterations_len += 8;
12363 }
12364 else
12365 {
12366 salt->salt_iter = ROUNDS_SHA512CRYPT;
12367 }
12368
12369 if ((input_len < DISPLAY_LEN_MIN_1800) || (input_len > DISPLAY_LEN_MAX_1800 + iterations_len)) return (PARSER_GLOBAL_LENGTH);
12370
12371 char *hash_pos = strchr (salt_pos, '$');
12372
12373 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12374
12375 uint salt_len = hash_pos - salt_pos;
12376
12377 if (salt_len > 16) return (PARSER_SALT_LENGTH);
12378
12379 memcpy ((char *) salt->salt_buf, salt_pos, salt_len);
12380
12381 salt->salt_len = salt_len;
12382
12383 hash_pos++;
12384
12385 sha512crypt_decode ((unsigned char *) digest, (unsigned char *) hash_pos);
12386
12387 return (PARSER_OK);
12388 }
12389
12390 int keccak_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12391 {
12392 if ((input_len < DISPLAY_LEN_MIN_5000) || (input_len > DISPLAY_LEN_MAX_5000)) return (PARSER_GLOBAL_LENGTH);
12393
12394 if (input_len % 16) return (PARSER_GLOBAL_LENGTH);
12395
12396 u64 *digest = (u64 *) hash_buf->digest;
12397
12398 salt_t *salt = hash_buf->salt;
12399
12400 uint keccak_mdlen = input_len / 2;
12401
12402 for (uint i = 0; i < keccak_mdlen / 8; i++)
12403 {
12404 digest[i] = hex_to_u64 ((const u8 *) &input_buf[i * 16]);
12405
12406 digest[i] = byte_swap_64 (digest[i]);
12407 }
12408
12409 salt->keccak_mdlen = keccak_mdlen;
12410
12411 return (PARSER_OK);
12412 }
12413
12414 int ikepsk_md5_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12415 {
12416 if ((input_len < DISPLAY_LEN_MIN_5300) || (input_len > DISPLAY_LEN_MAX_5300)) return (PARSER_GLOBAL_LENGTH);
12417
12418 u32 *digest = (u32 *) hash_buf->digest;
12419
12420 salt_t *salt = hash_buf->salt;
12421
12422 ikepsk_t *ikepsk = (ikepsk_t *) hash_buf->esalt;
12423
12424 /**
12425 * Parse that strange long line
12426 */
12427
12428 char *in_off[9];
12429
12430 size_t in_len[9] = { 0 };
12431
12432 in_off[0] = strtok (input_buf, ":");
12433
12434 if (in_off[0] == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12435
12436 in_len[0] = strlen (in_off[0]);
12437
12438 size_t i;
12439
12440 for (i = 1; i < 9; i++)
12441 {
12442 in_off[i] = strtok (NULL, ":");
12443
12444 if (in_off[i] == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12445
12446 in_len[i] = strlen (in_off[i]);
12447 }
12448
12449 char *ptr = (char *) ikepsk->msg_buf;
12450
12451 for (i = 0; i < in_len[0]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[0] + i);
12452 for (i = 0; i < in_len[1]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[1] + i);
12453 for (i = 0; i < in_len[2]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[2] + i);
12454 for (i = 0; i < in_len[3]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[3] + i);
12455 for (i = 0; i < in_len[4]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[4] + i);
12456 for (i = 0; i < in_len[5]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[5] + i);
12457
12458 *ptr = 0x80;
12459
12460 ikepsk->msg_len = (in_len[0] + in_len[1] + in_len[2] + in_len[3] + in_len[4] + in_len[5]) / 2;
12461
12462 ptr = (char *) ikepsk->nr_buf;
12463
12464 for (i = 0; i < in_len[6]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[6] + i);
12465 for (i = 0; i < in_len[7]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[7] + i);
12466
12467 *ptr = 0x80;
12468
12469 ikepsk->nr_len = (in_len[6] + in_len[7]) / 2;
12470
12471 /**
12472 * Store to database
12473 */
12474
12475 ptr = in_off[8];
12476
12477 digest[0] = hex_to_u32 ((const u8 *) &ptr[ 0]);
12478 digest[1] = hex_to_u32 ((const u8 *) &ptr[ 8]);
12479 digest[2] = hex_to_u32 ((const u8 *) &ptr[16]);
12480 digest[3] = hex_to_u32 ((const u8 *) &ptr[24]);
12481
12482 digest[0] = byte_swap_32 (digest[0]);
12483 digest[1] = byte_swap_32 (digest[1]);
12484 digest[2] = byte_swap_32 (digest[2]);
12485 digest[3] = byte_swap_32 (digest[3]);
12486
12487 salt->salt_len = 32;
12488
12489 salt->salt_buf[0] = ikepsk->nr_buf[0];
12490 salt->salt_buf[1] = ikepsk->nr_buf[1];
12491 salt->salt_buf[2] = ikepsk->nr_buf[2];
12492 salt->salt_buf[3] = ikepsk->nr_buf[3];
12493 salt->salt_buf[4] = ikepsk->nr_buf[4];
12494 salt->salt_buf[5] = ikepsk->nr_buf[5];
12495 salt->salt_buf[6] = ikepsk->nr_buf[6];
12496 salt->salt_buf[7] = ikepsk->nr_buf[7];
12497
12498 return (PARSER_OK);
12499 }
12500
12501 int ikepsk_sha1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12502 {
12503 if ((input_len < DISPLAY_LEN_MIN_5400) || (input_len > DISPLAY_LEN_MAX_5400)) return (PARSER_GLOBAL_LENGTH);
12504
12505 u32 *digest = (u32 *) hash_buf->digest;
12506
12507 salt_t *salt = hash_buf->salt;
12508
12509 ikepsk_t *ikepsk = (ikepsk_t *) hash_buf->esalt;
12510
12511 /**
12512 * Parse that strange long line
12513 */
12514
12515 char *in_off[9];
12516
12517 size_t in_len[9] = { 0 };
12518
12519 in_off[0] = strtok (input_buf, ":");
12520
12521 if (in_off[0] == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12522
12523 in_len[0] = strlen (in_off[0]);
12524
12525 size_t i;
12526
12527 for (i = 1; i < 9; i++)
12528 {
12529 in_off[i] = strtok (NULL, ":");
12530
12531 if (in_off[i] == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12532
12533 in_len[i] = strlen (in_off[i]);
12534 }
12535
12536 char *ptr = (char *) ikepsk->msg_buf;
12537
12538 for (i = 0; i < in_len[0]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[0] + i);
12539 for (i = 0; i < in_len[1]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[1] + i);
12540 for (i = 0; i < in_len[2]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[2] + i);
12541 for (i = 0; i < in_len[3]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[3] + i);
12542 for (i = 0; i < in_len[4]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[4] + i);
12543 for (i = 0; i < in_len[5]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[5] + i);
12544
12545 *ptr = 0x80;
12546
12547 ikepsk->msg_len = (in_len[0] + in_len[1] + in_len[2] + in_len[3] + in_len[4] + in_len[5]) / 2;
12548
12549 ptr = (char *) ikepsk->nr_buf;
12550
12551 for (i = 0; i < in_len[6]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[6] + i);
12552 for (i = 0; i < in_len[7]; i += 2) *ptr++ = hex_to_u8 ((const u8 *) in_off[7] + i);
12553
12554 *ptr = 0x80;
12555
12556 ikepsk->nr_len = (in_len[6] + in_len[7]) / 2;
12557
12558 /**
12559 * Store to database
12560 */
12561
12562 ptr = in_off[8];
12563
12564 digest[0] = hex_to_u32 ((const u8 *) &ptr[ 0]);
12565 digest[1] = hex_to_u32 ((const u8 *) &ptr[ 8]);
12566 digest[2] = hex_to_u32 ((const u8 *) &ptr[16]);
12567 digest[3] = hex_to_u32 ((const u8 *) &ptr[24]);
12568 digest[4] = hex_to_u32 ((const u8 *) &ptr[32]);
12569
12570 salt->salt_len = 32;
12571
12572 salt->salt_buf[0] = ikepsk->nr_buf[0];
12573 salt->salt_buf[1] = ikepsk->nr_buf[1];
12574 salt->salt_buf[2] = ikepsk->nr_buf[2];
12575 salt->salt_buf[3] = ikepsk->nr_buf[3];
12576 salt->salt_buf[4] = ikepsk->nr_buf[4];
12577 salt->salt_buf[5] = ikepsk->nr_buf[5];
12578 salt->salt_buf[6] = ikepsk->nr_buf[6];
12579 salt->salt_buf[7] = ikepsk->nr_buf[7];
12580
12581 return (PARSER_OK);
12582 }
12583
12584 int ripemd160_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12585 {
12586 if ((input_len < DISPLAY_LEN_MIN_6000) || (input_len > DISPLAY_LEN_MAX_6000)) return (PARSER_GLOBAL_LENGTH);
12587
12588 u32 *digest = (u32 *) hash_buf->digest;
12589
12590 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
12591 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
12592 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
12593 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
12594 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
12595
12596 digest[0] = byte_swap_32 (digest[0]);
12597 digest[1] = byte_swap_32 (digest[1]);
12598 digest[2] = byte_swap_32 (digest[2]);
12599 digest[3] = byte_swap_32 (digest[3]);
12600 digest[4] = byte_swap_32 (digest[4]);
12601
12602 return (PARSER_OK);
12603 }
12604
12605 int whirlpool_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12606 {
12607 if ((input_len < DISPLAY_LEN_MIN_6100) || (input_len > DISPLAY_LEN_MAX_6100)) return (PARSER_GLOBAL_LENGTH);
12608
12609 u32 *digest = (u32 *) hash_buf->digest;
12610
12611 digest[ 0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
12612 digest[ 1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
12613 digest[ 2] = hex_to_u32 ((const u8 *) &input_buf[ 16]);
12614 digest[ 3] = hex_to_u32 ((const u8 *) &input_buf[ 24]);
12615 digest[ 4] = hex_to_u32 ((const u8 *) &input_buf[ 32]);
12616 digest[ 5] = hex_to_u32 ((const u8 *) &input_buf[ 40]);
12617 digest[ 6] = hex_to_u32 ((const u8 *) &input_buf[ 48]);
12618 digest[ 7] = hex_to_u32 ((const u8 *) &input_buf[ 56]);
12619 digest[ 8] = hex_to_u32 ((const u8 *) &input_buf[ 64]);
12620 digest[ 9] = hex_to_u32 ((const u8 *) &input_buf[ 72]);
12621 digest[10] = hex_to_u32 ((const u8 *) &input_buf[ 80]);
12622 digest[11] = hex_to_u32 ((const u8 *) &input_buf[ 88]);
12623 digest[12] = hex_to_u32 ((const u8 *) &input_buf[ 96]);
12624 digest[13] = hex_to_u32 ((const u8 *) &input_buf[104]);
12625 digest[14] = hex_to_u32 ((const u8 *) &input_buf[112]);
12626 digest[15] = hex_to_u32 ((const u8 *) &input_buf[120]);
12627
12628 return (PARSER_OK);
12629 }
12630
12631 int androidpin_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12632 {
12633 if ((input_len < DISPLAY_LEN_MIN_5800) || (input_len > DISPLAY_LEN_MAX_5800)) return (PARSER_GLOBAL_LENGTH);
12634
12635 u32 *digest = (u32 *) hash_buf->digest;
12636
12637 salt_t *salt = hash_buf->salt;
12638
12639 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
12640 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
12641 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
12642 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
12643 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
12644
12645 if (input_buf[40] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
12646
12647 uint salt_len = input_len - 40 - 1;
12648
12649 char *salt_buf = input_buf + 40 + 1;
12650
12651 char *salt_buf_ptr = (char *) salt->salt_buf;
12652
12653 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
12654
12655 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
12656
12657 salt->salt_len = salt_len;
12658
12659 salt->salt_iter = ROUNDS_ANDROIDPIN - 1;
12660
12661 return (PARSER_OK);
12662 }
12663
12664 int truecrypt_parse_hash_1k (char *input_buf, uint input_len, hash_t *hash_buf)
12665 {
12666 u32 *digest = (u32 *) hash_buf->digest;
12667
12668 salt_t *salt = hash_buf->salt;
12669
12670 tc_t *tc = (tc_t *) hash_buf->esalt;
12671
12672 if (input_len == 0)
12673 {
12674 log_error ("TrueCrypt container not specified");
12675
12676 exit (-1);
12677 }
12678
12679 FILE *fp = fopen (input_buf, "rb");
12680
12681 if (fp == NULL)
12682 {
12683 log_error ("%s: %s", input_buf, strerror (errno));
12684
12685 exit (-1);
12686 }
12687
12688 char buf[512] = { 0 };
12689
12690 int n = fread (buf, 1, sizeof (buf), fp);
12691
12692 fclose (fp);
12693
12694 if (n != 512) return (PARSER_TC_FILE_SIZE);
12695
12696 memcpy (tc->salt_buf, buf, 64);
12697
12698 memcpy (tc->data_buf, buf + 64, 512 - 64);
12699
12700 salt->salt_buf[0] = tc->salt_buf[0];
12701
12702 salt->salt_len = 4;
12703
12704 salt->salt_iter = 1000 - 1;
12705
12706 digest[0] = tc->data_buf[0];
12707
12708 return (PARSER_OK);
12709 }
12710
12711 int truecrypt_parse_hash_2k (char *input_buf, uint input_len, hash_t *hash_buf)
12712 {
12713 u32 *digest = (u32 *) hash_buf->digest;
12714
12715 salt_t *salt = hash_buf->salt;
12716
12717 tc_t *tc = (tc_t *) hash_buf->esalt;
12718
12719 if (input_len == 0)
12720 {
12721 log_error ("TrueCrypt container not specified");
12722
12723 exit (-1);
12724 }
12725
12726 FILE *fp = fopen (input_buf, "rb");
12727
12728 if (fp == NULL)
12729 {
12730 log_error ("%s: %s", input_buf, strerror (errno));
12731
12732 exit (-1);
12733 }
12734
12735 char buf[512] = { 0 };
12736
12737 int n = fread (buf, 1, sizeof (buf), fp);
12738
12739 fclose (fp);
12740
12741 if (n != 512) return (PARSER_TC_FILE_SIZE);
12742
12743 memcpy (tc->salt_buf, buf, 64);
12744
12745 memcpy (tc->data_buf, buf + 64, 512 - 64);
12746
12747 salt->salt_buf[0] = tc->salt_buf[0];
12748
12749 salt->salt_len = 4;
12750
12751 salt->salt_iter = 2000 - 1;
12752
12753 digest[0] = tc->data_buf[0];
12754
12755 return (PARSER_OK);
12756 }
12757
12758 int md5aix_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12759 {
12760 if ((input_len < DISPLAY_LEN_MIN_6300) || (input_len > DISPLAY_LEN_MAX_6300)) return (PARSER_GLOBAL_LENGTH);
12761
12762 if (memcmp (SIGNATURE_MD5AIX, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
12763
12764 u32 *digest = (u32 *) hash_buf->digest;
12765
12766 salt_t *salt = hash_buf->salt;
12767
12768 char *salt_pos = input_buf + 6;
12769
12770 char *hash_pos = strchr (salt_pos, '$');
12771
12772 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12773
12774 uint salt_len = hash_pos - salt_pos;
12775
12776 if (salt_len < 8) return (PARSER_SALT_LENGTH);
12777
12778 memcpy ((char *) salt->salt_buf, salt_pos, salt_len);
12779
12780 salt->salt_len = salt_len;
12781
12782 salt->salt_iter = 1000;
12783
12784 hash_pos++;
12785
12786 md5crypt_decode ((unsigned char *) digest, (unsigned char *) hash_pos);
12787
12788 return (PARSER_OK);
12789 }
12790
12791 int sha1aix_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12792 {
12793 if ((input_len < DISPLAY_LEN_MIN_6700) || (input_len > DISPLAY_LEN_MAX_6700)) return (PARSER_GLOBAL_LENGTH);
12794
12795 if (memcmp (SIGNATURE_SHA1AIX, input_buf, 7)) return (PARSER_SIGNATURE_UNMATCHED);
12796
12797 u32 *digest = (u32 *) hash_buf->digest;
12798
12799 salt_t *salt = hash_buf->salt;
12800
12801 char *iter_pos = input_buf + 7;
12802
12803 char *salt_pos = strchr (iter_pos, '$');
12804
12805 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12806
12807 salt_pos++;
12808
12809 char *hash_pos = strchr (salt_pos, '$');
12810
12811 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12812
12813 uint salt_len = hash_pos - salt_pos;
12814
12815 if (salt_len < 16) return (PARSER_SALT_LENGTH);
12816
12817 memcpy ((char *) salt->salt_buf, salt_pos, salt_len);
12818
12819 salt->salt_len = salt_len;
12820
12821 char salt_iter[3] = { iter_pos[0], iter_pos[1], 0 };
12822
12823 salt->salt_sign[0] = atoi (salt_iter);
12824
12825 salt->salt_iter = (1 << atoi (salt_iter)) - 1;
12826
12827 hash_pos++;
12828
12829 sha1aix_decode ((unsigned char *) digest, (unsigned char *) hash_pos);
12830
12831 digest[0] = byte_swap_32 (digest[0]);
12832 digest[1] = byte_swap_32 (digest[1]);
12833 digest[2] = byte_swap_32 (digest[2]);
12834 digest[3] = byte_swap_32 (digest[3]);
12835 digest[4] = byte_swap_32 (digest[4]);
12836
12837 return (PARSER_OK);
12838 }
12839
12840 int sha256aix_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12841 {
12842 if ((input_len < DISPLAY_LEN_MIN_6400) || (input_len > DISPLAY_LEN_MAX_6400)) return (PARSER_GLOBAL_LENGTH);
12843
12844 if (memcmp (SIGNATURE_SHA256AIX, input_buf, 9)) return (PARSER_SIGNATURE_UNMATCHED);
12845
12846 u32 *digest = (u32 *) hash_buf->digest;
12847
12848 salt_t *salt = hash_buf->salt;
12849
12850 char *iter_pos = input_buf + 9;
12851
12852 char *salt_pos = strchr (iter_pos, '$');
12853
12854 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12855
12856 salt_pos++;
12857
12858 char *hash_pos = strchr (salt_pos, '$');
12859
12860 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12861
12862 uint salt_len = hash_pos - salt_pos;
12863
12864 if (salt_len < 16) return (PARSER_SALT_LENGTH);
12865
12866 memcpy ((char *) salt->salt_buf, salt_pos, salt_len);
12867
12868 salt->salt_len = salt_len;
12869
12870 char salt_iter[3] = { iter_pos[0], iter_pos[1], 0 };
12871
12872 salt->salt_sign[0] = atoi (salt_iter);
12873
12874 salt->salt_iter = (1 << atoi (salt_iter)) - 1;
12875
12876 hash_pos++;
12877
12878 sha256aix_decode ((unsigned char *) digest, (unsigned char *) hash_pos);
12879
12880 digest[0] = byte_swap_32 (digest[0]);
12881 digest[1] = byte_swap_32 (digest[1]);
12882 digest[2] = byte_swap_32 (digest[2]);
12883 digest[3] = byte_swap_32 (digest[3]);
12884 digest[4] = byte_swap_32 (digest[4]);
12885 digest[5] = byte_swap_32 (digest[5]);
12886 digest[6] = byte_swap_32 (digest[6]);
12887 digest[7] = byte_swap_32 (digest[7]);
12888
12889 return (PARSER_OK);
12890 }
12891
12892 int sha512aix_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12893 {
12894 if ((input_len < DISPLAY_LEN_MIN_6500) || (input_len > DISPLAY_LEN_MAX_6500)) return (PARSER_GLOBAL_LENGTH);
12895
12896 if (memcmp (SIGNATURE_SHA512AIX, input_buf, 9)) return (PARSER_SIGNATURE_UNMATCHED);
12897
12898 u64 *digest = (u64 *) hash_buf->digest;
12899
12900 salt_t *salt = hash_buf->salt;
12901
12902 char *iter_pos = input_buf + 9;
12903
12904 char *salt_pos = strchr (iter_pos, '$');
12905
12906 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12907
12908 salt_pos++;
12909
12910 char *hash_pos = strchr (salt_pos, '$');
12911
12912 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12913
12914 uint salt_len = hash_pos - salt_pos;
12915
12916 if (salt_len < 16) return (PARSER_SALT_LENGTH);
12917
12918 memcpy ((char *) salt->salt_buf, salt_pos, salt_len);
12919
12920 salt->salt_len = salt_len;
12921
12922 char salt_iter[3] = { iter_pos[0], iter_pos[1], 0 };
12923
12924 salt->salt_sign[0] = atoi (salt_iter);
12925
12926 salt->salt_iter = (1 << atoi (salt_iter)) - 1;
12927
12928 hash_pos++;
12929
12930 sha512aix_decode ((unsigned char *) digest, (unsigned char *) hash_pos);
12931
12932 digest[0] = byte_swap_64 (digest[0]);
12933 digest[1] = byte_swap_64 (digest[1]);
12934 digest[2] = byte_swap_64 (digest[2]);
12935 digest[3] = byte_swap_64 (digest[3]);
12936 digest[4] = byte_swap_64 (digest[4]);
12937 digest[5] = byte_swap_64 (digest[5]);
12938 digest[6] = byte_swap_64 (digest[6]);
12939 digest[7] = byte_swap_64 (digest[7]);
12940
12941 return (PARSER_OK);
12942 }
12943
12944 int agilekey_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
12945 {
12946 if ((input_len < DISPLAY_LEN_MIN_6600) || (input_len > DISPLAY_LEN_MAX_6600)) return (PARSER_GLOBAL_LENGTH);
12947
12948 u32 *digest = (u32 *) hash_buf->digest;
12949
12950 salt_t *salt = hash_buf->salt;
12951
12952 agilekey_t *agilekey = (agilekey_t *) hash_buf->esalt;
12953
12954 /**
12955 * parse line
12956 */
12957
12958 char *iterations_pos = input_buf;
12959
12960 char *saltbuf_pos = strchr (iterations_pos, ':');
12961
12962 if (saltbuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12963
12964 uint iterations_len = saltbuf_pos - iterations_pos;
12965
12966 if (iterations_len > 6) return (PARSER_SALT_LENGTH);
12967
12968 saltbuf_pos++;
12969
12970 char *cipherbuf_pos = strchr (saltbuf_pos, ':');
12971
12972 if (cipherbuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
12973
12974 uint saltbuf_len = cipherbuf_pos - saltbuf_pos;
12975
12976 if (saltbuf_len != 16) return (PARSER_SALT_LENGTH);
12977
12978 uint cipherbuf_len = input_len - iterations_len - 1 - saltbuf_len - 1;
12979
12980 if (cipherbuf_len != 2080) return (PARSER_HASH_LENGTH);
12981
12982 cipherbuf_pos++;
12983
12984 /**
12985 * pbkdf2 iterations
12986 */
12987
12988 salt->salt_iter = atoi (iterations_pos) - 1;
12989
12990 /**
12991 * handle salt encoding
12992 */
12993
12994 char *saltbuf_ptr = (char *) salt->salt_buf;
12995
12996 for (uint i = 0; i < saltbuf_len; i += 2)
12997 {
12998 const char p0 = saltbuf_pos[i + 0];
12999 const char p1 = saltbuf_pos[i + 1];
13000
13001 *saltbuf_ptr++ = hex_convert (p1) << 0
13002 | hex_convert (p0) << 4;
13003 }
13004
13005 salt->salt_len = saltbuf_len / 2;
13006
13007 /**
13008 * handle cipher encoding
13009 */
13010
13011 uint *tmp = (uint *) mymalloc (32);
13012
13013 char *cipherbuf_ptr = (char *) tmp;
13014
13015 for (uint i = 2016; i < cipherbuf_len; i += 2)
13016 {
13017 const char p0 = cipherbuf_pos[i + 0];
13018 const char p1 = cipherbuf_pos[i + 1];
13019
13020 *cipherbuf_ptr++ = hex_convert (p1) << 0
13021 | hex_convert (p0) << 4;
13022 }
13023
13024 // iv is stored at salt_buf 4 (length 16)
13025 // data is stored at salt_buf 8 (length 16)
13026
13027 salt->salt_buf[ 4] = byte_swap_32 (tmp[0]);
13028 salt->salt_buf[ 5] = byte_swap_32 (tmp[1]);
13029 salt->salt_buf[ 6] = byte_swap_32 (tmp[2]);
13030 salt->salt_buf[ 7] = byte_swap_32 (tmp[3]);
13031
13032 salt->salt_buf[ 8] = byte_swap_32 (tmp[4]);
13033 salt->salt_buf[ 9] = byte_swap_32 (tmp[5]);
13034 salt->salt_buf[10] = byte_swap_32 (tmp[6]);
13035 salt->salt_buf[11] = byte_swap_32 (tmp[7]);
13036
13037 free (tmp);
13038
13039 for (uint i = 0, j = 0; i < 1040; i += 1, j += 2)
13040 {
13041 const char p0 = cipherbuf_pos[j + 0];
13042 const char p1 = cipherbuf_pos[j + 1];
13043
13044 agilekey->cipher[i] = hex_convert (p1) << 0
13045 | hex_convert (p0) << 4;
13046 }
13047
13048 /**
13049 * digest buf
13050 */
13051
13052 digest[0] = 0x10101010;
13053 digest[1] = 0x10101010;
13054 digest[2] = 0x10101010;
13055 digest[3] = 0x10101010;
13056
13057 return (PARSER_OK);
13058 }
13059
13060 int lastpass_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13061 {
13062 if ((input_len < DISPLAY_LEN_MIN_6800) || (input_len > DISPLAY_LEN_MAX_6800)) return (PARSER_GLOBAL_LENGTH);
13063
13064 u32 *digest = (u32 *) hash_buf->digest;
13065
13066 salt_t *salt = hash_buf->salt;
13067
13068 char *hashbuf_pos = input_buf;
13069
13070 char *iterations_pos = strchr (hashbuf_pos, ':');
13071
13072 if (iterations_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13073
13074 uint hash_len = iterations_pos - hashbuf_pos;
13075
13076 if ((hash_len != 32) && (hash_len != 64)) return (PARSER_HASH_LENGTH);
13077
13078 iterations_pos++;
13079
13080 char *saltbuf_pos = strchr (iterations_pos, ':');
13081
13082 if (saltbuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13083
13084 uint iterations_len = saltbuf_pos - iterations_pos;
13085
13086 saltbuf_pos++;
13087
13088 uint salt_len = input_len - hash_len - 1 - iterations_len - 1;
13089
13090 if (salt_len > 32) return (PARSER_SALT_LENGTH);
13091
13092 char *salt_buf_ptr = (char *) salt->salt_buf;
13093
13094 salt_len = parse_and_store_salt (salt_buf_ptr, saltbuf_pos, salt_len);
13095
13096 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
13097
13098 salt->salt_len = salt_len;
13099
13100 salt->salt_iter = atoi (iterations_pos) - 1;
13101
13102 digest[0] = hex_to_u32 ((const u8 *) &hashbuf_pos[ 0]);
13103 digest[1] = hex_to_u32 ((const u8 *) &hashbuf_pos[ 8]);
13104 digest[2] = hex_to_u32 ((const u8 *) &hashbuf_pos[16]);
13105 digest[3] = hex_to_u32 ((const u8 *) &hashbuf_pos[24]);
13106
13107 return (PARSER_OK);
13108 }
13109
13110 int gost_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13111 {
13112 if ((input_len < DISPLAY_LEN_MIN_6900) || (input_len > DISPLAY_LEN_MAX_6900)) return (PARSER_GLOBAL_LENGTH);
13113
13114 u32 *digest = (u32 *) hash_buf->digest;
13115
13116 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
13117 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
13118 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
13119 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
13120 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
13121 digest[5] = hex_to_u32 ((const u8 *) &input_buf[40]);
13122 digest[6] = hex_to_u32 ((const u8 *) &input_buf[48]);
13123 digest[7] = hex_to_u32 ((const u8 *) &input_buf[56]);
13124
13125 digest[0] = byte_swap_32 (digest[0]);
13126 digest[1] = byte_swap_32 (digest[1]);
13127 digest[2] = byte_swap_32 (digest[2]);
13128 digest[3] = byte_swap_32 (digest[3]);
13129 digest[4] = byte_swap_32 (digest[4]);
13130 digest[5] = byte_swap_32 (digest[5]);
13131 digest[6] = byte_swap_32 (digest[6]);
13132 digest[7] = byte_swap_32 (digest[7]);
13133
13134 return (PARSER_OK);
13135 }
13136
13137 int sha256crypt_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13138 {
13139 if (memcmp (SIGNATURE_SHA256CRYPT, input_buf, 3)) return (PARSER_SIGNATURE_UNMATCHED);
13140
13141 u32 *digest = (u32 *) hash_buf->digest;
13142
13143 salt_t *salt = hash_buf->salt;
13144
13145 char *salt_pos = input_buf + 3;
13146
13147 uint iterations_len = 0;
13148
13149 if (memcmp (salt_pos, "rounds=", 7) == 0)
13150 {
13151 salt_pos += 7;
13152
13153 for (iterations_len = 0; salt_pos[0] >= '0' && salt_pos[0] <= '9' && iterations_len < 7; iterations_len++, salt_pos += 1) continue;
13154
13155 if (iterations_len == 0 ) return (PARSER_SALT_ITERATION);
13156 if (salt_pos[0] != '$') return (PARSER_SIGNATURE_UNMATCHED);
13157
13158 salt_pos[0] = 0x0;
13159
13160 salt->salt_iter = atoi (salt_pos - iterations_len);
13161
13162 salt_pos += 1;
13163
13164 iterations_len += 8;
13165 }
13166 else
13167 {
13168 salt->salt_iter = ROUNDS_SHA256CRYPT;
13169 }
13170
13171 if ((input_len < DISPLAY_LEN_MIN_7400) || (input_len > DISPLAY_LEN_MAX_7400 + iterations_len)) return (PARSER_GLOBAL_LENGTH);
13172
13173 char *hash_pos = strchr (salt_pos, '$');
13174
13175 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13176
13177 uint salt_len = hash_pos - salt_pos;
13178
13179 if (salt_len > 16) return (PARSER_SALT_LENGTH);
13180
13181 memcpy ((char *) salt->salt_buf, salt_pos, salt_len);
13182
13183 salt->salt_len = salt_len;
13184
13185 hash_pos++;
13186
13187 sha256crypt_decode ((unsigned char *) digest, (unsigned char *) hash_pos);
13188
13189 return (PARSER_OK);
13190 }
13191
13192 int sha512osx_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13193 {
13194 uint max_len = DISPLAY_LEN_MAX_7100 + (2 * 128);
13195
13196 if ((input_len < DISPLAY_LEN_MIN_7100) || (input_len > max_len)) return (PARSER_GLOBAL_LENGTH);
13197
13198 if (memcmp (SIGNATURE_SHA512OSX, input_buf, 4)) return (PARSER_SIGNATURE_UNMATCHED);
13199
13200 u64 *digest = (u64 *) hash_buf->digest;
13201
13202 salt_t *salt = hash_buf->salt;
13203
13204 pbkdf2_sha512_t *pbkdf2_sha512 = (pbkdf2_sha512_t *) hash_buf->esalt;
13205
13206 char *iter_pos = input_buf + 4;
13207
13208 char *salt_pos = strchr (iter_pos, '$');
13209
13210 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13211
13212 salt_pos++;
13213
13214 char *hash_pos = strchr (salt_pos, '$');
13215
13216 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13217
13218 if (((input_len - (hash_pos - input_buf) - 1) % 128) != 0) return (PARSER_GLOBAL_LENGTH);
13219
13220 hash_pos++;
13221
13222 digest[0] = hex_to_u64 ((const u8 *) &hash_pos[ 0]);
13223 digest[1] = hex_to_u64 ((const u8 *) &hash_pos[ 16]);
13224 digest[2] = hex_to_u64 ((const u8 *) &hash_pos[ 32]);
13225 digest[3] = hex_to_u64 ((const u8 *) &hash_pos[ 48]);
13226 digest[4] = hex_to_u64 ((const u8 *) &hash_pos[ 64]);
13227 digest[5] = hex_to_u64 ((const u8 *) &hash_pos[ 80]);
13228 digest[6] = hex_to_u64 ((const u8 *) &hash_pos[ 96]);
13229 digest[7] = hex_to_u64 ((const u8 *) &hash_pos[112]);
13230
13231 uint salt_len = hash_pos - salt_pos - 1;
13232
13233 if ((salt_len % 2) != 0) return (PARSER_SALT_LENGTH);
13234
13235 salt->salt_len = salt_len / 2;
13236
13237 pbkdf2_sha512->salt_buf[0] = hex_to_u32 ((const u8 *) &salt_pos[ 0]);
13238 pbkdf2_sha512->salt_buf[1] = hex_to_u32 ((const u8 *) &salt_pos[ 8]);
13239 pbkdf2_sha512->salt_buf[2] = hex_to_u32 ((const u8 *) &salt_pos[16]);
13240 pbkdf2_sha512->salt_buf[3] = hex_to_u32 ((const u8 *) &salt_pos[24]);
13241 pbkdf2_sha512->salt_buf[4] = hex_to_u32 ((const u8 *) &salt_pos[32]);
13242 pbkdf2_sha512->salt_buf[5] = hex_to_u32 ((const u8 *) &salt_pos[40]);
13243 pbkdf2_sha512->salt_buf[6] = hex_to_u32 ((const u8 *) &salt_pos[48]);
13244 pbkdf2_sha512->salt_buf[7] = hex_to_u32 ((const u8 *) &salt_pos[56]);
13245
13246 pbkdf2_sha512->salt_buf[0] = byte_swap_32 (pbkdf2_sha512->salt_buf[0]);
13247 pbkdf2_sha512->salt_buf[1] = byte_swap_32 (pbkdf2_sha512->salt_buf[1]);
13248 pbkdf2_sha512->salt_buf[2] = byte_swap_32 (pbkdf2_sha512->salt_buf[2]);
13249 pbkdf2_sha512->salt_buf[3] = byte_swap_32 (pbkdf2_sha512->salt_buf[3]);
13250 pbkdf2_sha512->salt_buf[4] = byte_swap_32 (pbkdf2_sha512->salt_buf[4]);
13251 pbkdf2_sha512->salt_buf[5] = byte_swap_32 (pbkdf2_sha512->salt_buf[5]);
13252 pbkdf2_sha512->salt_buf[6] = byte_swap_32 (pbkdf2_sha512->salt_buf[6]);
13253 pbkdf2_sha512->salt_buf[7] = byte_swap_32 (pbkdf2_sha512->salt_buf[7]);
13254 pbkdf2_sha512->salt_buf[8] = 0x01000000;
13255 pbkdf2_sha512->salt_buf[9] = 0x80;
13256
13257 salt->salt_buf[0] = pbkdf2_sha512->salt_buf[0];
13258
13259 salt->salt_iter = atoi (iter_pos) - 1;
13260
13261 return (PARSER_OK);
13262 }
13263
13264 int episerver4_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13265 {
13266 if ((input_len < DISPLAY_LEN_MIN_1441) || (input_len > DISPLAY_LEN_MAX_1441)) return (PARSER_GLOBAL_LENGTH);
13267
13268 if (memcmp (SIGNATURE_EPISERVER4, input_buf, 14)) return (PARSER_SIGNATURE_UNMATCHED);
13269
13270 u32 *digest = (u32 *) hash_buf->digest;
13271
13272 salt_t *salt = hash_buf->salt;
13273
13274 char *salt_pos = input_buf + 14;
13275
13276 char *hash_pos = strchr (salt_pos, '*');
13277
13278 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13279
13280 hash_pos++;
13281
13282 uint salt_len = hash_pos - salt_pos - 1;
13283
13284 char *salt_buf_ptr = (char *) salt->salt_buf;
13285
13286 salt_len = parse_and_store_salt (salt_buf_ptr, salt_pos, salt_len);
13287
13288 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
13289
13290 salt->salt_len = salt_len;
13291
13292 u8 tmp_buf[100] = { 0 };
13293
13294 base64_decode (base64_to_int, (const u8 *) hash_pos, 43, tmp_buf);
13295
13296 memcpy (digest, tmp_buf, 32);
13297
13298 digest[0] = byte_swap_32 (digest[0]);
13299 digest[1] = byte_swap_32 (digest[1]);
13300 digest[2] = byte_swap_32 (digest[2]);
13301 digest[3] = byte_swap_32 (digest[3]);
13302 digest[4] = byte_swap_32 (digest[4]);
13303 digest[5] = byte_swap_32 (digest[5]);
13304 digest[6] = byte_swap_32 (digest[6]);
13305 digest[7] = byte_swap_32 (digest[7]);
13306
13307 digest[0] -= SHA256M_A;
13308 digest[1] -= SHA256M_B;
13309 digest[2] -= SHA256M_C;
13310 digest[3] -= SHA256M_D;
13311 digest[4] -= SHA256M_E;
13312 digest[5] -= SHA256M_F;
13313 digest[6] -= SHA256M_G;
13314 digest[7] -= SHA256M_H;
13315
13316 return (PARSER_OK);
13317 }
13318
13319 int sha512grub_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13320 {
13321 uint max_len = DISPLAY_LEN_MAX_7200 + (8 * 128);
13322
13323 if ((input_len < DISPLAY_LEN_MIN_7200) || (input_len > max_len)) return (PARSER_GLOBAL_LENGTH);
13324
13325 if (memcmp (SIGNATURE_SHA512GRUB, input_buf, 19)) return (PARSER_SIGNATURE_UNMATCHED);
13326
13327 u64 *digest = (u64 *) hash_buf->digest;
13328
13329 salt_t *salt = hash_buf->salt;
13330
13331 pbkdf2_sha512_t *pbkdf2_sha512 = (pbkdf2_sha512_t *) hash_buf->esalt;
13332
13333 char *iter_pos = input_buf + 19;
13334
13335 char *salt_pos = strchr (iter_pos, '.');
13336
13337 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13338
13339 salt_pos++;
13340
13341 char *hash_pos = strchr (salt_pos, '.');
13342
13343 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13344
13345 if (((input_len - (hash_pos - input_buf) - 1) % 128) != 0) return (PARSER_GLOBAL_LENGTH);
13346
13347 hash_pos++;
13348
13349 digest[0] = hex_to_u64 ((const u8 *) &hash_pos[ 0]);
13350 digest[1] = hex_to_u64 ((const u8 *) &hash_pos[ 16]);
13351 digest[2] = hex_to_u64 ((const u8 *) &hash_pos[ 32]);
13352 digest[3] = hex_to_u64 ((const u8 *) &hash_pos[ 48]);
13353 digest[4] = hex_to_u64 ((const u8 *) &hash_pos[ 64]);
13354 digest[5] = hex_to_u64 ((const u8 *) &hash_pos[ 80]);
13355 digest[6] = hex_to_u64 ((const u8 *) &hash_pos[ 96]);
13356 digest[7] = hex_to_u64 ((const u8 *) &hash_pos[112]);
13357
13358 uint salt_len = hash_pos - salt_pos - 1;
13359
13360 salt_len /= 2;
13361
13362 char *salt_buf_ptr = (char *) pbkdf2_sha512->salt_buf;
13363
13364 uint i;
13365
13366 for (i = 0; i < salt_len; i++)
13367 {
13368 salt_buf_ptr[i] = hex_to_u8 ((const u8 *) &salt_pos[i * 2]);
13369 }
13370
13371 salt_buf_ptr[salt_len + 3] = 0x01;
13372 salt_buf_ptr[salt_len + 4] = 0x80;
13373
13374 salt->salt_buf[0] = pbkdf2_sha512->salt_buf[0];
13375
13376 salt->salt_len = salt_len;
13377
13378 salt->salt_iter = atoi (iter_pos) - 1;
13379
13380 return (PARSER_OK);
13381 }
13382
13383 int sha512b64s_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13384 {
13385 if ((input_len < DISPLAY_LEN_MIN_1711) || (input_len > DISPLAY_LEN_MAX_1711)) return (PARSER_GLOBAL_LENGTH);
13386
13387 if (memcmp (SIGNATURE_SHA512B64S, input_buf, 9)) return (PARSER_SIGNATURE_UNMATCHED);
13388
13389 u64 *digest = (u64 *) hash_buf->digest;
13390
13391 salt_t *salt = hash_buf->salt;
13392
13393 u8 tmp_buf[120] = { 0 };
13394
13395 int tmp_len = base64_decode (base64_to_int, (const u8 *) input_buf + 9, input_len - 9, tmp_buf);
13396
13397 if (tmp_len < 64) return (PARSER_HASH_LENGTH);
13398
13399 memcpy (digest, tmp_buf, 64);
13400
13401 digest[0] = byte_swap_64 (digest[0]);
13402 digest[1] = byte_swap_64 (digest[1]);
13403 digest[2] = byte_swap_64 (digest[2]);
13404 digest[3] = byte_swap_64 (digest[3]);
13405 digest[4] = byte_swap_64 (digest[4]);
13406 digest[5] = byte_swap_64 (digest[5]);
13407 digest[6] = byte_swap_64 (digest[6]);
13408 digest[7] = byte_swap_64 (digest[7]);
13409
13410 digest[0] -= SHA512M_A;
13411 digest[1] -= SHA512M_B;
13412 digest[2] -= SHA512M_C;
13413 digest[3] -= SHA512M_D;
13414 digest[4] -= SHA512M_E;
13415 digest[5] -= SHA512M_F;
13416 digest[6] -= SHA512M_G;
13417 digest[7] -= SHA512M_H;
13418
13419 int salt_len = tmp_len - 64;
13420
13421 if (salt_len < 0) return (PARSER_SALT_LENGTH);
13422
13423 salt->salt_len = salt_len;
13424
13425 memcpy (salt->salt_buf, tmp_buf + 64, salt->salt_len);
13426
13427 if (data.opts_type & OPTS_TYPE_ST_ADD80)
13428 {
13429 char *ptr = (char *) salt->salt_buf;
13430
13431 ptr[salt->salt_len] = 0x80;
13432 }
13433
13434 return (PARSER_OK);
13435 }
13436
13437 int hmacmd5_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13438 {
13439 if (data.opts_type & OPTS_TYPE_ST_HEX)
13440 {
13441 if ((input_len < DISPLAY_LEN_MIN_50H) || (input_len > DISPLAY_LEN_MAX_50H)) return (PARSER_GLOBAL_LENGTH);
13442 }
13443 else
13444 {
13445 if ((input_len < DISPLAY_LEN_MIN_50) || (input_len > DISPLAY_LEN_MAX_50)) return (PARSER_GLOBAL_LENGTH);
13446 }
13447
13448 u32 *digest = (u32 *) hash_buf->digest;
13449
13450 salt_t *salt = hash_buf->salt;
13451
13452 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
13453 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
13454 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
13455 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
13456
13457 digest[0] = byte_swap_32 (digest[0]);
13458 digest[1] = byte_swap_32 (digest[1]);
13459 digest[2] = byte_swap_32 (digest[2]);
13460 digest[3] = byte_swap_32 (digest[3]);
13461
13462 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
13463
13464 uint salt_len = input_len - 32 - 1;
13465
13466 char *salt_buf = input_buf + 32 + 1;
13467
13468 char *salt_buf_ptr = (char *) salt->salt_buf;
13469
13470 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
13471
13472 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
13473
13474 salt->salt_len = salt_len;
13475
13476 return (PARSER_OK);
13477 }
13478
13479 int hmacsha1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13480 {
13481 if (data.opts_type & OPTS_TYPE_ST_HEX)
13482 {
13483 if ((input_len < DISPLAY_LEN_MIN_150H) || (input_len > DISPLAY_LEN_MAX_150H)) return (PARSER_GLOBAL_LENGTH);
13484 }
13485 else
13486 {
13487 if ((input_len < DISPLAY_LEN_MIN_150) || (input_len > DISPLAY_LEN_MAX_150)) return (PARSER_GLOBAL_LENGTH);
13488 }
13489
13490 u32 *digest = (u32 *) hash_buf->digest;
13491
13492 salt_t *salt = hash_buf->salt;
13493
13494 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
13495 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
13496 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
13497 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
13498 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
13499
13500 if (input_buf[40] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
13501
13502 uint salt_len = input_len - 40 - 1;
13503
13504 char *salt_buf = input_buf + 40 + 1;
13505
13506 char *salt_buf_ptr = (char *) salt->salt_buf;
13507
13508 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
13509
13510 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
13511
13512 salt->salt_len = salt_len;
13513
13514 return (PARSER_OK);
13515 }
13516
13517 int hmacsha256_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13518 {
13519 if (data.opts_type & OPTS_TYPE_ST_HEX)
13520 {
13521 if ((input_len < DISPLAY_LEN_MIN_1450H) || (input_len > DISPLAY_LEN_MAX_1450H)) return (PARSER_GLOBAL_LENGTH);
13522 }
13523 else
13524 {
13525 if ((input_len < DISPLAY_LEN_MIN_1450) || (input_len > DISPLAY_LEN_MAX_1450)) return (PARSER_GLOBAL_LENGTH);
13526 }
13527
13528 u32 *digest = (u32 *) hash_buf->digest;
13529
13530 salt_t *salt = hash_buf->salt;
13531
13532 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
13533 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
13534 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
13535 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
13536 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
13537 digest[5] = hex_to_u32 ((const u8 *) &input_buf[40]);
13538 digest[6] = hex_to_u32 ((const u8 *) &input_buf[48]);
13539 digest[7] = hex_to_u32 ((const u8 *) &input_buf[56]);
13540
13541 if (input_buf[64] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
13542
13543 uint salt_len = input_len - 64 - 1;
13544
13545 char *salt_buf = input_buf + 64 + 1;
13546
13547 char *salt_buf_ptr = (char *) salt->salt_buf;
13548
13549 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
13550
13551 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
13552
13553 salt->salt_len = salt_len;
13554
13555 return (PARSER_OK);
13556 }
13557
13558 int hmacsha512_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13559 {
13560 if (data.opts_type & OPTS_TYPE_ST_HEX)
13561 {
13562 if ((input_len < DISPLAY_LEN_MIN_1750H) || (input_len > DISPLAY_LEN_MAX_1750H)) return (PARSER_GLOBAL_LENGTH);
13563 }
13564 else
13565 {
13566 if ((input_len < DISPLAY_LEN_MIN_1750) || (input_len > DISPLAY_LEN_MAX_1750)) return (PARSER_GLOBAL_LENGTH);
13567 }
13568
13569 u64 *digest = (u64 *) hash_buf->digest;
13570
13571 salt_t *salt = hash_buf->salt;
13572
13573 digest[0] = hex_to_u64 ((const u8 *) &input_buf[ 0]);
13574 digest[1] = hex_to_u64 ((const u8 *) &input_buf[ 16]);
13575 digest[2] = hex_to_u64 ((const u8 *) &input_buf[ 32]);
13576 digest[3] = hex_to_u64 ((const u8 *) &input_buf[ 48]);
13577 digest[4] = hex_to_u64 ((const u8 *) &input_buf[ 64]);
13578 digest[5] = hex_to_u64 ((const u8 *) &input_buf[ 80]);
13579 digest[6] = hex_to_u64 ((const u8 *) &input_buf[ 96]);
13580 digest[7] = hex_to_u64 ((const u8 *) &input_buf[112]);
13581
13582 if (input_buf[128] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
13583
13584 uint salt_len = input_len - 128 - 1;
13585
13586 char *salt_buf = input_buf + 128 + 1;
13587
13588 char *salt_buf_ptr = (char *) salt->salt_buf;
13589
13590 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
13591
13592 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
13593
13594 salt->salt_len = salt_len;
13595
13596 return (PARSER_OK);
13597 }
13598
13599 int krb5pa_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13600 {
13601 if ((input_len < DISPLAY_LEN_MIN_7500) || (input_len > DISPLAY_LEN_MAX_7500)) return (PARSER_GLOBAL_LENGTH);
13602
13603 if (memcmp (SIGNATURE_KRB5PA, input_buf, 10)) return (PARSER_SIGNATURE_UNMATCHED);
13604
13605 u32 *digest = (u32 *) hash_buf->digest;
13606
13607 salt_t *salt = hash_buf->salt;
13608
13609 krb5pa_t *krb5pa = (krb5pa_t *) hash_buf->esalt;
13610
13611 /**
13612 * parse line
13613 */
13614
13615 char *user_pos = input_buf + 10 + 1;
13616
13617 char *realm_pos = strchr (user_pos, '$');
13618
13619 if (realm_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13620
13621 uint user_len = realm_pos - user_pos;
13622
13623 if (user_len >= 64) return (PARSER_SALT_LENGTH);
13624
13625 realm_pos++;
13626
13627 char *salt_pos = strchr (realm_pos, '$');
13628
13629 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13630
13631 uint realm_len = salt_pos - realm_pos;
13632
13633 if (realm_len >= 64) return (PARSER_SALT_LENGTH);
13634
13635 salt_pos++;
13636
13637 char *data_pos = strchr (salt_pos, '$');
13638
13639 if (data_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13640
13641 uint salt_len = data_pos - salt_pos;
13642
13643 if (salt_len >= 128) return (PARSER_SALT_LENGTH);
13644
13645 data_pos++;
13646
13647 uint data_len = input_len - 10 - 1 - user_len - 1 - realm_len - 1 - salt_len - 1;
13648
13649 if (data_len != ((36 + 16) * 2)) return (PARSER_SALT_LENGTH);
13650
13651 /**
13652 * copy data
13653 */
13654
13655 memcpy (krb5pa->user, user_pos, user_len);
13656 memcpy (krb5pa->realm, realm_pos, realm_len);
13657 memcpy (krb5pa->salt, salt_pos, salt_len);
13658
13659 char *timestamp_ptr = (char *) krb5pa->timestamp;
13660
13661 for (uint i = 0; i < (36 * 2); i += 2)
13662 {
13663 const char p0 = data_pos[i + 0];
13664 const char p1 = data_pos[i + 1];
13665
13666 *timestamp_ptr++ = hex_convert (p1) << 0
13667 | hex_convert (p0) << 4;
13668 }
13669
13670 char *checksum_ptr = (char *) krb5pa->checksum;
13671
13672 for (uint i = (36 * 2); i < ((36 + 16) * 2); i += 2)
13673 {
13674 const char p0 = data_pos[i + 0];
13675 const char p1 = data_pos[i + 1];
13676
13677 *checksum_ptr++ = hex_convert (p1) << 0
13678 | hex_convert (p0) << 4;
13679 }
13680
13681 /**
13682 * copy some data to generic buffers to make sorting happy
13683 */
13684
13685 salt->salt_buf[0] = krb5pa->timestamp[0];
13686 salt->salt_buf[1] = krb5pa->timestamp[1];
13687 salt->salt_buf[2] = krb5pa->timestamp[2];
13688 salt->salt_buf[3] = krb5pa->timestamp[3];
13689 salt->salt_buf[4] = krb5pa->timestamp[4];
13690 salt->salt_buf[5] = krb5pa->timestamp[5];
13691 salt->salt_buf[6] = krb5pa->timestamp[6];
13692 salt->salt_buf[7] = krb5pa->timestamp[7];
13693 salt->salt_buf[8] = krb5pa->timestamp[8];
13694
13695 salt->salt_len = 36;
13696
13697 digest[0] = krb5pa->checksum[0];
13698 digest[1] = krb5pa->checksum[1];
13699 digest[2] = krb5pa->checksum[2];
13700 digest[3] = krb5pa->checksum[3];
13701
13702 return (PARSER_OK);
13703 }
13704
13705 int sapb_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13706 {
13707 if ((input_len < DISPLAY_LEN_MIN_7700) || (input_len > DISPLAY_LEN_MAX_7700)) return (PARSER_GLOBAL_LENGTH);
13708
13709 u32 *digest = (u32 *) hash_buf->digest;
13710
13711 salt_t *salt = hash_buf->salt;
13712
13713 /**
13714 * parse line
13715 */
13716
13717 char *salt_pos = input_buf;
13718
13719 char *hash_pos = strchr (salt_pos, '$');
13720
13721 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13722
13723 uint salt_len = hash_pos - salt_pos;
13724
13725 if (salt_len >= 40) return (PARSER_SALT_LENGTH);
13726
13727 hash_pos++;
13728
13729 uint hash_len = input_len - 1 - salt_len;
13730
13731 if (hash_len != 16) return (PARSER_HASH_LENGTH);
13732
13733 /**
13734 * valid some data
13735 */
13736
13737 uint user_len = 0;
13738
13739 for (uint i = 0; i < salt_len; i++)
13740 {
13741 if (salt_pos[i] == ' ') continue;
13742
13743 user_len++;
13744 }
13745
13746 // SAP user names cannot be longer than 12 characters
13747 if (user_len > 12) return (PARSER_SALT_LENGTH);
13748
13749 // SAP user name cannot start with ! or ?
13750 if (salt_pos[0] == '!' || salt_pos[0] == '?') return (PARSER_SALT_VALUE);
13751
13752 /**
13753 * copy data
13754 */
13755
13756 char *salt_buf_ptr = (char *) salt->salt_buf;
13757
13758 salt_len = parse_and_store_salt (salt_buf_ptr, salt_pos, salt_len);
13759
13760 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
13761
13762 salt->salt_len = salt_len;
13763
13764 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[0]);
13765 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[8]);
13766 digest[2] = 0;
13767 digest[3] = 0;
13768
13769 digest[0] = byte_swap_32 (digest[0]);
13770 digest[1] = byte_swap_32 (digest[1]);
13771
13772 return (PARSER_OK);
13773 }
13774
13775 int sapg_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13776 {
13777 if ((input_len < DISPLAY_LEN_MIN_7800) || (input_len > DISPLAY_LEN_MAX_7800)) return (PARSER_GLOBAL_LENGTH);
13778
13779 u32 *digest = (u32 *) hash_buf->digest;
13780
13781 salt_t *salt = hash_buf->salt;
13782
13783 /**
13784 * parse line
13785 */
13786
13787 char *salt_pos = input_buf;
13788
13789 char *hash_pos = strchr (salt_pos, '$');
13790
13791 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13792
13793 uint salt_len = hash_pos - salt_pos;
13794
13795 if (salt_len >= 40) return (PARSER_SALT_LENGTH);
13796
13797 hash_pos++;
13798
13799 uint hash_len = input_len - 1 - salt_len;
13800
13801 if (hash_len != 40) return (PARSER_HASH_LENGTH);
13802
13803 /**
13804 * valid some data
13805 */
13806
13807 uint user_len = 0;
13808
13809 for (uint i = 0; i < salt_len; i++)
13810 {
13811 if (salt_pos[i] == ' ') continue;
13812
13813 user_len++;
13814 }
13815
13816 // SAP user names cannot be longer than 12 characters
13817 // this is kinda buggy. if the username is in utf the length can be up to length 12*3
13818 // so far nobody complained so we stay with this because it helps in optimization
13819 // final string can have a max size of 32 (password) + (10 * 5) = lengthMagicArray + 12 (max salt) + 1 (the 0x80)
13820
13821 if (user_len > 12) return (PARSER_SALT_LENGTH);
13822
13823 // SAP user name cannot start with ! or ?
13824 if (salt_pos[0] == '!' || salt_pos[0] == '?') return (PARSER_SALT_VALUE);
13825
13826 /**
13827 * copy data
13828 */
13829
13830 char *salt_buf_ptr = (char *) salt->salt_buf;
13831
13832 salt_len = parse_and_store_salt (salt_buf_ptr, salt_pos, salt_len);
13833
13834 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
13835
13836 salt->salt_len = salt_len;
13837
13838 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
13839 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
13840 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
13841 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
13842 digest[4] = hex_to_u32 ((const u8 *) &hash_pos[32]);
13843
13844 return (PARSER_OK);
13845 }
13846
13847 int drupal7_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13848 {
13849 if ((input_len < DISPLAY_LEN_MIN_7900) || (input_len > DISPLAY_LEN_MAX_7900)) return (PARSER_GLOBAL_LENGTH);
13850
13851 if (memcmp (SIGNATURE_DRUPAL7, input_buf, 3)) return (PARSER_SIGNATURE_UNMATCHED);
13852
13853 u64 *digest = (u64 *) hash_buf->digest;
13854
13855 salt_t *salt = hash_buf->salt;
13856
13857 char *iter_pos = input_buf + 3;
13858
13859 uint salt_iter = 1 << itoa64_to_int (iter_pos[0]);
13860
13861 if (salt_iter > 0x80000000) return (PARSER_SALT_ITERATION);
13862
13863 memcpy ((char *) salt->salt_sign, input_buf, 4);
13864
13865 salt->salt_iter = salt_iter;
13866
13867 char *salt_pos = iter_pos + 1;
13868
13869 uint salt_len = 8;
13870
13871 memcpy ((char *) salt->salt_buf, salt_pos, salt_len);
13872
13873 salt->salt_len = salt_len;
13874
13875 char *hash_pos = salt_pos + salt_len;
13876
13877 drupal7_decode ((unsigned char *) digest, (unsigned char *) hash_pos);
13878
13879 // ugly hack start
13880
13881 char *tmp = (char *) salt->salt_buf_pc;
13882
13883 tmp[0] = hash_pos[42];
13884
13885 // ugly hack end
13886
13887 digest[ 0] = byte_swap_64 (digest[ 0]);
13888 digest[ 1] = byte_swap_64 (digest[ 1]);
13889 digest[ 2] = byte_swap_64 (digest[ 2]);
13890 digest[ 3] = byte_swap_64 (digest[ 3]);
13891 digest[ 4] = 0;
13892 digest[ 5] = 0;
13893 digest[ 6] = 0;
13894 digest[ 7] = 0;
13895
13896 return (PARSER_OK);
13897 }
13898
13899 int sybasease_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13900 {
13901 if ((input_len < DISPLAY_LEN_MIN_8000) || (input_len > DISPLAY_LEN_MAX_8000)) return (PARSER_GLOBAL_LENGTH);
13902
13903 if (memcmp (SIGNATURE_SYBASEASE, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
13904
13905 u32 *digest = (u32 *) hash_buf->digest;
13906
13907 salt_t *salt = hash_buf->salt;
13908
13909 char *salt_buf = input_buf + 6;
13910
13911 uint salt_len = 16;
13912
13913 char *salt_buf_ptr = (char *) salt->salt_buf;
13914
13915 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
13916
13917 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
13918
13919 salt->salt_len = salt_len;
13920
13921 char *hash_pos = input_buf + 6 + 16;
13922
13923 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
13924 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
13925 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
13926 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
13927 digest[4] = hex_to_u32 ((const u8 *) &hash_pos[32]);
13928 digest[5] = hex_to_u32 ((const u8 *) &hash_pos[40]);
13929 digest[6] = hex_to_u32 ((const u8 *) &hash_pos[48]);
13930 digest[7] = hex_to_u32 ((const u8 *) &hash_pos[56]);
13931
13932 return (PARSER_OK);
13933 }
13934
13935 int mysql323_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13936 {
13937 if ((input_len < DISPLAY_LEN_MIN_200) || (input_len > DISPLAY_LEN_MAX_200)) return (PARSER_GLOBAL_LENGTH);
13938
13939 u32 *digest = (u32 *) hash_buf->digest;
13940
13941 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
13942 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
13943 digest[2] = 0;
13944 digest[3] = 0;
13945
13946 return (PARSER_OK);
13947 }
13948
13949 int rakp_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
13950 {
13951 if ((input_len < DISPLAY_LEN_MIN_7300) || (input_len > DISPLAY_LEN_MAX_7300)) return (PARSER_GLOBAL_LENGTH);
13952
13953 u32 *digest = (u32 *) hash_buf->digest;
13954
13955 salt_t *salt = hash_buf->salt;
13956
13957 rakp_t *rakp = (rakp_t *) hash_buf->esalt;
13958
13959 char *saltbuf_pos = input_buf;
13960
13961 char *hashbuf_pos = strchr (saltbuf_pos, ':');
13962
13963 if (hashbuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
13964
13965 uint saltbuf_len = hashbuf_pos - saltbuf_pos;
13966
13967 if (saltbuf_len < 64) return (PARSER_SALT_LENGTH);
13968 if (saltbuf_len > 512) return (PARSER_SALT_LENGTH);
13969
13970 if (saltbuf_len & 1) return (PARSER_SALT_LENGTH); // muss gerade sein wegen hex
13971
13972 hashbuf_pos++;
13973
13974 uint hashbuf_len = input_len - saltbuf_len - 1;
13975
13976 if (hashbuf_len != 40) return (PARSER_HASH_LENGTH);
13977
13978 char *salt_ptr = (char *) saltbuf_pos;
13979 char *rakp_ptr = (char *) rakp->salt_buf;
13980
13981 uint i;
13982 uint j;
13983
13984 for (i = 0, j = 0; i < saltbuf_len; i += 2, j += 1)
13985 {
13986 rakp_ptr[j] = hex_to_u8 ((const u8 *) &salt_ptr[i]);
13987 }
13988
13989 rakp_ptr[j] = 0x80;
13990
13991 rakp->salt_len = j;
13992
13993 for (i = 0; i < 64; i++)
13994 {
13995 rakp->salt_buf[i] = byte_swap_32 (rakp->salt_buf[i]);
13996 }
13997
13998 salt->salt_buf[0] = rakp->salt_buf[0];
13999 salt->salt_buf[1] = rakp->salt_buf[1];
14000 salt->salt_buf[2] = rakp->salt_buf[2];
14001 salt->salt_buf[3] = rakp->salt_buf[3];
14002 salt->salt_buf[4] = rakp->salt_buf[4];
14003 salt->salt_buf[5] = rakp->salt_buf[5];
14004 salt->salt_buf[6] = rakp->salt_buf[6];
14005 salt->salt_buf[7] = rakp->salt_buf[7];
14006
14007 salt->salt_len = 32; // muss min. 32 haben
14008
14009 digest[0] = hex_to_u32 ((const u8 *) &hashbuf_pos[ 0]);
14010 digest[1] = hex_to_u32 ((const u8 *) &hashbuf_pos[ 8]);
14011 digest[2] = hex_to_u32 ((const u8 *) &hashbuf_pos[16]);
14012 digest[3] = hex_to_u32 ((const u8 *) &hashbuf_pos[24]);
14013 digest[4] = hex_to_u32 ((const u8 *) &hashbuf_pos[32]);
14014
14015 return (PARSER_OK);
14016 }
14017
14018 int netscaler_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14019 {
14020 if ((input_len < DISPLAY_LEN_MIN_8100) || (input_len > DISPLAY_LEN_MAX_8100)) return (PARSER_GLOBAL_LENGTH);
14021
14022 u32 *digest = (u32 *) hash_buf->digest;
14023
14024 salt_t *salt = hash_buf->salt;
14025
14026 if (memcmp (SIGNATURE_NETSCALER, input_buf, 1)) return (PARSER_SIGNATURE_UNMATCHED);
14027
14028 char *salt_pos = input_buf + 1;
14029
14030 memcpy (salt->salt_buf, salt_pos, 8);
14031
14032 salt->salt_buf[0] = byte_swap_32 (salt->salt_buf[0]);
14033 salt->salt_buf[1] = byte_swap_32 (salt->salt_buf[1]);
14034
14035 salt->salt_len = 8;
14036
14037 char *hash_pos = salt_pos + 8;
14038
14039 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
14040 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
14041 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
14042 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
14043 digest[4] = hex_to_u32 ((const u8 *) &hash_pos[32]);
14044
14045 digest[0] -= SHA1M_A;
14046 digest[1] -= SHA1M_B;
14047 digest[2] -= SHA1M_C;
14048 digest[3] -= SHA1M_D;
14049 digest[4] -= SHA1M_E;
14050
14051 return (PARSER_OK);
14052 }
14053
14054 int chap_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14055 {
14056 if ((input_len < DISPLAY_LEN_MIN_4800) || (input_len > DISPLAY_LEN_MAX_4800)) return (PARSER_GLOBAL_LENGTH);
14057
14058 u32 *digest = (u32 *) hash_buf->digest;
14059
14060 salt_t *salt = hash_buf->salt;
14061
14062 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
14063 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
14064 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
14065 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
14066
14067 digest[0] = byte_swap_32 (digest[0]);
14068 digest[1] = byte_swap_32 (digest[1]);
14069 digest[2] = byte_swap_32 (digest[2]);
14070 digest[3] = byte_swap_32 (digest[3]);
14071
14072 digest[0] -= MD5M_A;
14073 digest[1] -= MD5M_B;
14074 digest[2] -= MD5M_C;
14075 digest[3] -= MD5M_D;
14076
14077 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
14078
14079 char *salt_buf_ptr = input_buf + 32 + 1;
14080
14081 u32 *salt_buf = salt->salt_buf;
14082
14083 salt_buf[0] = hex_to_u32 ((const u8 *) &salt_buf_ptr[ 0]);
14084 salt_buf[1] = hex_to_u32 ((const u8 *) &salt_buf_ptr[ 8]);
14085 salt_buf[2] = hex_to_u32 ((const u8 *) &salt_buf_ptr[16]);
14086 salt_buf[3] = hex_to_u32 ((const u8 *) &salt_buf_ptr[24]);
14087
14088 salt_buf[0] = byte_swap_32 (salt_buf[0]);
14089 salt_buf[1] = byte_swap_32 (salt_buf[1]);
14090 salt_buf[2] = byte_swap_32 (salt_buf[2]);
14091 salt_buf[3] = byte_swap_32 (salt_buf[3]);
14092
14093 salt->salt_len = 16 + 1;
14094
14095 if (input_buf[65] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
14096
14097 char *idbyte_buf_ptr = input_buf + 32 + 1 + 32 + 1;
14098
14099 salt_buf[4] = hex_to_u8 ((const u8 *) &idbyte_buf_ptr[0]) & 0xff;
14100
14101 return (PARSER_OK);
14102 }
14103
14104 int cloudkey_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14105 {
14106 if ((input_len < DISPLAY_LEN_MIN_8200) || (input_len > DISPLAY_LEN_MAX_8200)) return (PARSER_GLOBAL_LENGTH);
14107
14108 u32 *digest = (u32 *) hash_buf->digest;
14109
14110 salt_t *salt = hash_buf->salt;
14111
14112 cloudkey_t *cloudkey = (cloudkey_t *) hash_buf->esalt;
14113
14114 /**
14115 * parse line
14116 */
14117
14118 char *hashbuf_pos = input_buf;
14119
14120 char *saltbuf_pos = strchr (hashbuf_pos, ':');
14121
14122 if (saltbuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14123
14124 const uint hashbuf_len = saltbuf_pos - hashbuf_pos;
14125
14126 if (hashbuf_len != 64) return (PARSER_HASH_LENGTH);
14127
14128 saltbuf_pos++;
14129
14130 char *iteration_pos = strchr (saltbuf_pos, ':');
14131
14132 if (iteration_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14133
14134 const uint saltbuf_len = iteration_pos - saltbuf_pos;
14135
14136 if (saltbuf_len != 32) return (PARSER_SALT_LENGTH);
14137
14138 iteration_pos++;
14139
14140 char *databuf_pos = strchr (iteration_pos, ':');
14141
14142 if (databuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14143
14144 const uint iteration_len = databuf_pos - iteration_pos;
14145
14146 if (iteration_len < 1) return (PARSER_SALT_ITERATION);
14147 if (iteration_len > 8) return (PARSER_SALT_ITERATION);
14148
14149 const uint databuf_len = input_len - hashbuf_len - 1 - saltbuf_len - 1 - iteration_len - 1;
14150
14151 if (databuf_len < 1) return (PARSER_SALT_LENGTH);
14152 if (databuf_len > 2048) return (PARSER_SALT_LENGTH);
14153
14154 databuf_pos++;
14155
14156 // digest
14157
14158 digest[0] = hex_to_u32 ((const u8 *) &hashbuf_pos[ 0]);
14159 digest[1] = hex_to_u32 ((const u8 *) &hashbuf_pos[ 8]);
14160 digest[2] = hex_to_u32 ((const u8 *) &hashbuf_pos[16]);
14161 digest[3] = hex_to_u32 ((const u8 *) &hashbuf_pos[24]);
14162 digest[4] = hex_to_u32 ((const u8 *) &hashbuf_pos[32]);
14163 digest[5] = hex_to_u32 ((const u8 *) &hashbuf_pos[40]);
14164 digest[6] = hex_to_u32 ((const u8 *) &hashbuf_pos[48]);
14165 digest[7] = hex_to_u32 ((const u8 *) &hashbuf_pos[56]);
14166
14167 // salt
14168
14169 char *saltbuf_ptr = (char *) salt->salt_buf;
14170
14171 for (uint i = 0; i < saltbuf_len; i += 2)
14172 {
14173 const char p0 = saltbuf_pos[i + 0];
14174 const char p1 = saltbuf_pos[i + 1];
14175
14176 *saltbuf_ptr++ = hex_convert (p1) << 0
14177 | hex_convert (p0) << 4;
14178 }
14179
14180 salt->salt_buf[4] = 0x01000000;
14181 salt->salt_buf[5] = 0x80;
14182
14183 salt->salt_len = saltbuf_len / 2;
14184
14185 // iteration
14186
14187 salt->salt_iter = atoi (iteration_pos) - 1;
14188
14189 // data
14190
14191 char *databuf_ptr = (char *) cloudkey->data_buf;
14192
14193 for (uint i = 0; i < databuf_len; i += 2)
14194 {
14195 const char p0 = databuf_pos[i + 0];
14196 const char p1 = databuf_pos[i + 1];
14197
14198 *databuf_ptr++ = hex_convert (p1) << 0
14199 | hex_convert (p0) << 4;
14200 }
14201
14202 *databuf_ptr++ = 0x80;
14203
14204 for (uint i = 0; i < 512; i++)
14205 {
14206 cloudkey->data_buf[i] = byte_swap_32 (cloudkey->data_buf[i]);
14207 }
14208
14209 cloudkey->data_len = databuf_len / 2;
14210
14211 return (PARSER_OK);
14212 }
14213
14214 int nsec3_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14215 {
14216 if ((input_len < DISPLAY_LEN_MIN_8300) || (input_len > DISPLAY_LEN_MAX_8300)) return (PARSER_GLOBAL_LENGTH);
14217
14218 u32 *digest = (u32 *) hash_buf->digest;
14219
14220 salt_t *salt = hash_buf->salt;
14221
14222 /**
14223 * parse line
14224 */
14225
14226 char *hashbuf_pos = input_buf;
14227
14228 char *domainbuf_pos = strchr (hashbuf_pos, ':');
14229
14230 if (domainbuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14231
14232 const uint hashbuf_len = domainbuf_pos - hashbuf_pos;
14233
14234 if (hashbuf_len != 32) return (PARSER_HASH_LENGTH);
14235
14236 domainbuf_pos++;
14237
14238 if (domainbuf_pos[0] != '.') return (PARSER_SALT_VALUE);
14239
14240 char *saltbuf_pos = strchr (domainbuf_pos, ':');
14241
14242 if (saltbuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14243
14244 const uint domainbuf_len = saltbuf_pos - domainbuf_pos;
14245
14246 if (domainbuf_len >= 32) return (PARSER_SALT_LENGTH);
14247
14248 saltbuf_pos++;
14249
14250 char *iteration_pos = strchr (saltbuf_pos, ':');
14251
14252 if (iteration_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14253
14254 const uint saltbuf_len = iteration_pos - saltbuf_pos;
14255
14256 if (saltbuf_len >= 28) return (PARSER_SALT_LENGTH); // 28 = 32 - 4; 4 = length
14257
14258 if ((domainbuf_len + saltbuf_len) >= 48) return (PARSER_SALT_LENGTH);
14259
14260 iteration_pos++;
14261
14262 const uint iteration_len = input_len - hashbuf_len - 1 - domainbuf_len - 1 - saltbuf_len - 1;
14263
14264 if (iteration_len < 1) return (PARSER_SALT_ITERATION);
14265 if (iteration_len > 5) return (PARSER_SALT_ITERATION);
14266
14267 // ok, the plan for this algorithm is the following:
14268 // we have 2 salts here, the domain-name and a random salt
14269 // while both are used in the initial transformation,
14270 // only the random salt is used in the following iterations
14271 // so we create two buffer, one that includes domain-name (stored into salt_buf_pc[])
14272 // and one that includes only the real salt (stored into salt_buf[]).
14273 // the domain-name length is put into array position 7 of salt_buf_pc[] since there is not salt_pc_len
14274
14275 u8 tmp_buf[100] = { 0 };
14276
14277 base32_decode (itoa32_to_int, (const u8 *) hashbuf_pos, 32, tmp_buf);
14278
14279 memcpy (digest, tmp_buf, 20);
14280
14281 digest[0] = byte_swap_32 (digest[0]);
14282 digest[1] = byte_swap_32 (digest[1]);
14283 digest[2] = byte_swap_32 (digest[2]);
14284 digest[3] = byte_swap_32 (digest[3]);
14285 digest[4] = byte_swap_32 (digest[4]);
14286
14287 // domain
14288
14289 char *salt_buf_pc_ptr = (char *) salt->salt_buf_pc;
14290
14291 memcpy (salt_buf_pc_ptr, domainbuf_pos, domainbuf_len);
14292
14293 char *len_ptr = NULL;
14294
14295 for (uint i = 0; i < domainbuf_len; i++)
14296 {
14297 if (salt_buf_pc_ptr[i] == '.')
14298 {
14299 len_ptr = &salt_buf_pc_ptr[i];
14300
14301 *len_ptr = 0;
14302 }
14303 else
14304 {
14305 *len_ptr += 1;
14306 }
14307 }
14308
14309 salt->salt_buf_pc[7] = domainbuf_len;
14310
14311 // "real" salt
14312
14313 char *salt_buf_ptr = (char *) salt->salt_buf;
14314
14315 const uint salt_len = parse_and_store_salt (salt_buf_ptr, saltbuf_pos, saltbuf_len);
14316
14317 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
14318
14319 salt->salt_len = salt_len;
14320
14321 // iteration
14322
14323 salt->salt_iter = atoi (iteration_pos);
14324
14325 return (PARSER_OK);
14326 }
14327
14328 int wbb3_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14329 {
14330 if ((input_len < DISPLAY_LEN_MIN_8400) || (input_len > DISPLAY_LEN_MAX_8400)) return (PARSER_GLOBAL_LENGTH);
14331
14332 u32 *digest = (u32 *) hash_buf->digest;
14333
14334 salt_t *salt = hash_buf->salt;
14335
14336 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
14337 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
14338 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
14339 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
14340 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
14341
14342 if (input_buf[40] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
14343
14344 uint salt_len = input_len - 40 - 1;
14345
14346 char *salt_buf = input_buf + 40 + 1;
14347
14348 char *salt_buf_ptr = (char *) salt->salt_buf;
14349
14350 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
14351
14352 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
14353
14354 salt->salt_len = salt_len;
14355
14356 return (PARSER_OK);
14357 }
14358
14359 int racf_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14360 {
14361 const u8 ascii_to_ebcdic[] =
14362 {
14363 0x00, 0x01, 0x02, 0x03, 0x37, 0x2d, 0x2e, 0x2f, 0x16, 0x05, 0x25, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f,
14364 0x10, 0x11, 0x12, 0x13, 0x3c, 0x3d, 0x32, 0x26, 0x18, 0x19, 0x3f, 0x27, 0x1c, 0x1d, 0x1e, 0x1f,
14365 0x40, 0x4f, 0x7f, 0x7b, 0x5b, 0x6c, 0x50, 0x7d, 0x4d, 0x5d, 0x5c, 0x4e, 0x6b, 0x60, 0x4b, 0x61,
14366 0xf0, 0xf1, 0xf2, 0xf3, 0xf4, 0xf5, 0xf6, 0xf7, 0xf8, 0xf9, 0x7a, 0x5e, 0x4c, 0x7e, 0x6e, 0x6f,
14367 0x7c, 0xc1, 0xc2, 0xc3, 0xc4, 0xc5, 0xc6, 0xc7, 0xc8, 0xc9, 0xd1, 0xd2, 0xd3, 0xd4, 0xd5, 0xd6,
14368 0xd7, 0xd8, 0xd9, 0xe2, 0xe3, 0xe4, 0xe5, 0xe6, 0xe7, 0xe8, 0xe9, 0x4a, 0xe0, 0x5a, 0x5f, 0x6d,
14369 0x79, 0x81, 0x82, 0x83, 0x84, 0x85, 0x86, 0x87, 0x88, 0x89, 0x91, 0x92, 0x93, 0x94, 0x95, 0x96,
14370 0x97, 0x98, 0x99, 0xa2, 0xa3, 0xa4, 0xa5, 0xa6, 0xa7, 0xa8, 0xa9, 0xc0, 0x6a, 0xd0, 0xa1, 0x07,
14371 0x20, 0x21, 0x22, 0x23, 0x24, 0x15, 0x06, 0x17, 0x28, 0x29, 0x2a, 0x2b, 0x2c, 0x09, 0x0a, 0x1b,
14372 0x30, 0x31, 0x1a, 0x33, 0x34, 0x35, 0x36, 0x08, 0x38, 0x39, 0x3a, 0x3b, 0x04, 0x14, 0x3e, 0xe1,
14373 0x41, 0x42, 0x43, 0x44, 0x45, 0x46, 0x47, 0x48, 0x49, 0x51, 0x52, 0x53, 0x54, 0x55, 0x56, 0x57,
14374 0x58, 0x59, 0x62, 0x63, 0x64, 0x65, 0x66, 0x67, 0x68, 0x69, 0x70, 0x71, 0x72, 0x73, 0x74, 0x75,
14375 0x76, 0x77, 0x78, 0x80, 0x8a, 0x8b, 0x8c, 0x8d, 0x8e, 0x8f, 0x90, 0x9a, 0x9b, 0x9c, 0x9d, 0x9e,
14376 0x9f, 0xa0, 0xaa, 0xab, 0xac, 0xad, 0xae, 0xaf, 0xb0, 0xb1, 0xb2, 0xb3, 0xb4, 0xb5, 0xb6, 0xb7,
14377 0xb8, 0xb9, 0xba, 0xbb, 0xbc, 0xbd, 0xbe, 0xbf, 0xca, 0xcb, 0xcc, 0xcd, 0xce, 0xcf, 0xda, 0xdb,
14378 0xdc, 0xdd, 0xde, 0xdf, 0xea, 0xeb, 0xec, 0xed, 0xee, 0xef, 0xfa, 0xfb, 0xfc, 0xfd, 0xfe, 0xff,
14379 };
14380
14381 if ((input_len < DISPLAY_LEN_MIN_8500) || (input_len > DISPLAY_LEN_MAX_8500)) return (PARSER_GLOBAL_LENGTH);
14382
14383 if (memcmp (SIGNATURE_RACF, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
14384
14385 u32 *digest = (u32 *) hash_buf->digest;
14386
14387 salt_t *salt = hash_buf->salt;
14388
14389 char *salt_pos = input_buf + 6 + 1;
14390
14391 char *digest_pos = strchr (salt_pos, '*');
14392
14393 if (digest_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14394
14395 uint salt_len = digest_pos - salt_pos;
14396
14397 if (salt_len > 8) return (PARSER_SALT_LENGTH);
14398
14399 uint hash_len = input_len - 1 - salt_len - 1 - 6;
14400
14401 if (hash_len != 16) return (PARSER_HASH_LENGTH);
14402
14403 digest_pos++;
14404
14405 char *salt_buf_ptr = (char *) salt->salt_buf;
14406 char *salt_buf_pc_ptr = (char *) salt->salt_buf_pc;
14407
14408 salt_len = parse_and_store_salt (salt_buf_ptr, salt_pos, salt_len);
14409
14410 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
14411
14412 salt->salt_len = salt_len;
14413
14414 for (uint i = 0; i < salt_len; i++)
14415 {
14416 salt_buf_pc_ptr[i] = ascii_to_ebcdic[(int) salt_buf_ptr[i]];
14417 }
14418 for (uint i = salt_len; i < 8; i++)
14419 {
14420 salt_buf_pc_ptr[i] = 0x40;
14421 }
14422
14423 uint tt;
14424
14425 IP (salt->salt_buf_pc[0], salt->salt_buf_pc[1], tt);
14426
14427 salt->salt_buf_pc[0] = rotl32 (salt->salt_buf_pc[0], 3u);
14428 salt->salt_buf_pc[1] = rotl32 (salt->salt_buf_pc[1], 3u);
14429
14430 digest[0] = hex_to_u32 ((const u8 *) &digest_pos[ 0]);
14431 digest[1] = hex_to_u32 ((const u8 *) &digest_pos[ 8]);
14432
14433 digest[0] = byte_swap_32 (digest[0]);
14434 digest[1] = byte_swap_32 (digest[1]);
14435
14436 IP (digest[0], digest[1], tt);
14437
14438 digest[0] = rotr32 (digest[0], 29);
14439 digest[1] = rotr32 (digest[1], 29);
14440 digest[2] = 0;
14441 digest[3] = 0;
14442
14443 return (PARSER_OK);
14444 }
14445
14446 int lotus5_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14447 {
14448 if ((input_len < DISPLAY_LEN_MIN_8600) || (input_len > DISPLAY_LEN_MAX_8600)) return (PARSER_GLOBAL_LENGTH);
14449
14450 u32 *digest = (u32 *) hash_buf->digest;
14451
14452 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
14453 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
14454 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
14455 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
14456
14457 digest[0] = byte_swap_32 (digest[0]);
14458 digest[1] = byte_swap_32 (digest[1]);
14459 digest[2] = byte_swap_32 (digest[2]);
14460 digest[3] = byte_swap_32 (digest[3]);
14461
14462 return (PARSER_OK);
14463 }
14464
14465 int lotus6_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14466 {
14467 if ((input_len < DISPLAY_LEN_MIN_8700) || (input_len > DISPLAY_LEN_MAX_8700)) return (PARSER_GLOBAL_LENGTH);
14468
14469 if ((input_buf[0] != '(') || (input_buf[1] != 'G') || (input_buf[21] != ')')) return (PARSER_SIGNATURE_UNMATCHED);
14470
14471 u32 *digest = (u32 *) hash_buf->digest;
14472
14473 salt_t *salt = hash_buf->salt;
14474
14475 u8 tmp_buf[120] = { 0 };
14476
14477 base64_decode (lotus64_to_int, (const u8 *) input_buf + 2, input_len - 3, tmp_buf);
14478
14479 tmp_buf[3] += -4; // dont ask!
14480
14481 memcpy (salt->salt_buf, tmp_buf, 5);
14482
14483 salt->salt_len = 5;
14484
14485 memcpy (digest, tmp_buf + 5, 9);
14486
14487 // yes, only 9 byte are needed to crack, but 10 to display
14488
14489 salt->salt_buf_pc[7] = input_buf[20];
14490
14491 return (PARSER_OK);
14492 }
14493
14494 int lotus8_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14495 {
14496 if ((input_len < DISPLAY_LEN_MIN_9100) || (input_len > DISPLAY_LEN_MAX_9100)) return (PARSER_GLOBAL_LENGTH);
14497
14498 if ((input_buf[0] != '(') || (input_buf[1] != 'H') || (input_buf[DISPLAY_LEN_MAX_9100 - 1] != ')')) return (PARSER_SIGNATURE_UNMATCHED);
14499
14500 u32 *digest = (u32 *) hash_buf->digest;
14501
14502 salt_t *salt = hash_buf->salt;
14503
14504 u8 tmp_buf[120] = { 0 };
14505
14506 base64_decode (lotus64_to_int, (const u8 *) input_buf + 2, input_len - 3, tmp_buf);
14507
14508 tmp_buf[3] += -4; // dont ask!
14509
14510 // salt
14511
14512 memcpy (salt->salt_buf, tmp_buf, 16);
14513
14514 salt->salt_len = 16; // Attention: in theory we have 2 salt_len, one for the -m 8700 part (len: 8), 2nd for the 9100 part (len: 16)
14515
14516 // iteration
14517
14518 char tmp_iter_buf[11] = { 0 };
14519
14520 memcpy (tmp_iter_buf, tmp_buf + 16, 10);
14521
14522 tmp_iter_buf[10] = 0;
14523
14524 salt->salt_iter = atoi (tmp_iter_buf);
14525
14526 if (salt->salt_iter < 1) // well, the limit hopefully is much higher
14527 {
14528 return (PARSER_SALT_ITERATION);
14529 }
14530
14531 salt->salt_iter--; // first round in init
14532
14533 // 2 additional bytes for display only
14534
14535 salt->salt_buf_pc[0] = tmp_buf[26];
14536 salt->salt_buf_pc[1] = tmp_buf[27];
14537
14538 // digest
14539
14540 memcpy (digest, tmp_buf + 28, 8);
14541
14542 digest[0] = byte_swap_32 (digest[0]);
14543 digest[1] = byte_swap_32 (digest[1]);
14544 digest[2] = 0;
14545 digest[3] = 0;
14546
14547 return (PARSER_OK);
14548 }
14549
14550 int hmailserver_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14551 {
14552 if ((input_len < DISPLAY_LEN_MIN_1421) || (input_len > DISPLAY_LEN_MAX_1421)) return (PARSER_GLOBAL_LENGTH);
14553
14554 u32 *digest = (u32 *) hash_buf->digest;
14555
14556 salt_t *salt = hash_buf->salt;
14557
14558 char *salt_buf_pos = input_buf;
14559
14560 char *hash_buf_pos = salt_buf_pos + 6;
14561
14562 digest[0] = hex_to_u32 ((const u8 *) &hash_buf_pos[ 0]);
14563 digest[1] = hex_to_u32 ((const u8 *) &hash_buf_pos[ 8]);
14564 digest[2] = hex_to_u32 ((const u8 *) &hash_buf_pos[16]);
14565 digest[3] = hex_to_u32 ((const u8 *) &hash_buf_pos[24]);
14566 digest[4] = hex_to_u32 ((const u8 *) &hash_buf_pos[32]);
14567 digest[5] = hex_to_u32 ((const u8 *) &hash_buf_pos[40]);
14568 digest[6] = hex_to_u32 ((const u8 *) &hash_buf_pos[48]);
14569 digest[7] = hex_to_u32 ((const u8 *) &hash_buf_pos[56]);
14570
14571 digest[0] -= SHA256M_A;
14572 digest[1] -= SHA256M_B;
14573 digest[2] -= SHA256M_C;
14574 digest[3] -= SHA256M_D;
14575 digest[4] -= SHA256M_E;
14576 digest[5] -= SHA256M_F;
14577 digest[6] -= SHA256M_G;
14578 digest[7] -= SHA256M_H;
14579
14580 char *salt_buf_ptr = (char *) salt->salt_buf;
14581
14582 const uint salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf_pos, 6);
14583
14584 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
14585
14586 salt->salt_len = salt_len;
14587
14588 return (PARSER_OK);
14589 }
14590
14591 int phps_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14592 {
14593 if ((input_len < DISPLAY_LEN_MIN_2612) || (input_len > DISPLAY_LEN_MAX_2612)) return (PARSER_GLOBAL_LENGTH);
14594
14595 u32 *digest = (u32 *) hash_buf->digest;
14596
14597 if (memcmp (SIGNATURE_PHPS, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
14598
14599 salt_t *salt = hash_buf->salt;
14600
14601 char *salt_buf = input_buf + 6;
14602
14603 char *digest_buf = strchr (salt_buf, '$');
14604
14605 if (digest_buf == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14606
14607 uint salt_len = digest_buf - salt_buf;
14608
14609 digest_buf++; // skip the '$' symbol
14610
14611 char *salt_buf_ptr = (char *) salt->salt_buf;
14612
14613 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
14614
14615 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
14616
14617 salt->salt_len = salt_len;
14618
14619 digest[0] = hex_to_u32 ((const u8 *) &digest_buf[ 0]);
14620 digest[1] = hex_to_u32 ((const u8 *) &digest_buf[ 8]);
14621 digest[2] = hex_to_u32 ((const u8 *) &digest_buf[16]);
14622 digest[3] = hex_to_u32 ((const u8 *) &digest_buf[24]);
14623
14624 digest[0] = byte_swap_32 (digest[0]);
14625 digest[1] = byte_swap_32 (digest[1]);
14626 digest[2] = byte_swap_32 (digest[2]);
14627 digest[3] = byte_swap_32 (digest[3]);
14628
14629 digest[0] -= MD5M_A;
14630 digest[1] -= MD5M_B;
14631 digest[2] -= MD5M_C;
14632 digest[3] -= MD5M_D;
14633
14634 return (PARSER_OK);
14635 }
14636
14637 int mediawiki_b_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14638 {
14639 if ((input_len < DISPLAY_LEN_MIN_3711) || (input_len > DISPLAY_LEN_MAX_3711)) return (PARSER_GLOBAL_LENGTH);
14640
14641 if (memcmp (SIGNATURE_MEDIAWIKI_B, input_buf, 3)) return (PARSER_SIGNATURE_UNMATCHED);
14642
14643 u32 *digest = (u32 *) hash_buf->digest;
14644
14645 salt_t *salt = hash_buf->salt;
14646
14647 char *salt_buf = input_buf + 3;
14648
14649 char *digest_buf = strchr (salt_buf, '$');
14650
14651 if (digest_buf == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14652
14653 uint salt_len = digest_buf - salt_buf;
14654
14655 digest_buf++; // skip the '$' symbol
14656
14657 char *salt_buf_ptr = (char *) salt->salt_buf;
14658
14659 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
14660
14661 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
14662
14663 salt_buf_ptr[salt_len] = 0x2d;
14664
14665 salt->salt_len = salt_len + 1;
14666
14667 digest[0] = hex_to_u32 ((const u8 *) &digest_buf[ 0]);
14668 digest[1] = hex_to_u32 ((const u8 *) &digest_buf[ 8]);
14669 digest[2] = hex_to_u32 ((const u8 *) &digest_buf[16]);
14670 digest[3] = hex_to_u32 ((const u8 *) &digest_buf[24]);
14671
14672 digest[0] = byte_swap_32 (digest[0]);
14673 digest[1] = byte_swap_32 (digest[1]);
14674 digest[2] = byte_swap_32 (digest[2]);
14675 digest[3] = byte_swap_32 (digest[3]);
14676
14677 digest[0] -= MD5M_A;
14678 digest[1] -= MD5M_B;
14679 digest[2] -= MD5M_C;
14680 digest[3] -= MD5M_D;
14681
14682 return (PARSER_OK);
14683 }
14684
14685 int peoplesoft_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14686 {
14687 if ((input_len < DISPLAY_LEN_MIN_133) || (input_len > DISPLAY_LEN_MAX_133)) return (PARSER_GLOBAL_LENGTH);
14688
14689 u32 *digest = (u32 *) hash_buf->digest;
14690
14691 salt_t *salt = hash_buf->salt;
14692
14693 u8 tmp_buf[100] = { 0 };
14694
14695 base64_decode (base64_to_int, (const u8 *) input_buf, input_len, tmp_buf);
14696
14697 memcpy (digest, tmp_buf, 20);
14698
14699 digest[0] = byte_swap_32 (digest[0]);
14700 digest[1] = byte_swap_32 (digest[1]);
14701 digest[2] = byte_swap_32 (digest[2]);
14702 digest[3] = byte_swap_32 (digest[3]);
14703 digest[4] = byte_swap_32 (digest[4]);
14704
14705 digest[0] -= SHA1M_A;
14706 digest[1] -= SHA1M_B;
14707 digest[2] -= SHA1M_C;
14708 digest[3] -= SHA1M_D;
14709 digest[4] -= SHA1M_E;
14710
14711 salt->salt_buf[0] = 0x80;
14712
14713 salt->salt_len = 0;
14714
14715 return (PARSER_OK);
14716 }
14717
14718 int skype_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14719 {
14720 if ((input_len < DISPLAY_LEN_MIN_23) || (input_len > DISPLAY_LEN_MAX_23)) return (PARSER_GLOBAL_LENGTH);
14721
14722 u32 *digest = (u32 *) hash_buf->digest;
14723
14724 salt_t *salt = hash_buf->salt;
14725
14726 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
14727 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
14728 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
14729 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
14730
14731 digest[0] = byte_swap_32 (digest[0]);
14732 digest[1] = byte_swap_32 (digest[1]);
14733 digest[2] = byte_swap_32 (digest[2]);
14734 digest[3] = byte_swap_32 (digest[3]);
14735
14736 digest[0] -= MD5M_A;
14737 digest[1] -= MD5M_B;
14738 digest[2] -= MD5M_C;
14739 digest[3] -= MD5M_D;
14740
14741 if (input_buf[32] != ':') return (PARSER_SEPARATOR_UNMATCHED);
14742
14743 uint salt_len = input_len - 32 - 1;
14744
14745 char *salt_buf = input_buf + 32 + 1;
14746
14747 char *salt_buf_ptr = (char *) salt->salt_buf;
14748
14749 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
14750
14751 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
14752
14753 /*
14754 * add static "salt" part
14755 */
14756
14757 memcpy (salt_buf_ptr + salt_len, "\nskyper\n", 8);
14758
14759 salt_len += 8;
14760
14761 salt->salt_len = salt_len;
14762
14763 return (PARSER_OK);
14764 }
14765
14766 int androidfde_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14767 {
14768 if ((input_len < DISPLAY_LEN_MIN_8800) || (input_len > DISPLAY_LEN_MAX_8800)) return (PARSER_GLOBAL_LENGTH);
14769
14770 if (memcmp (SIGNATURE_ANDROIDFDE, input_buf, 5)) return (PARSER_SIGNATURE_UNMATCHED);
14771
14772 u32 *digest = (u32 *) hash_buf->digest;
14773
14774 salt_t *salt = hash_buf->salt;
14775
14776 androidfde_t *androidfde = (androidfde_t *) hash_buf->esalt;
14777
14778 /**
14779 * parse line
14780 */
14781
14782 char *saltlen_pos = input_buf + 1 + 3 + 1;
14783
14784 char *saltbuf_pos = strchr (saltlen_pos, '$');
14785
14786 if (saltbuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14787
14788 uint saltlen_len = saltbuf_pos - saltlen_pos;
14789
14790 if (saltlen_len != 2) return (PARSER_SALT_LENGTH);
14791
14792 saltbuf_pos++;
14793
14794 char *keylen_pos = strchr (saltbuf_pos, '$');
14795
14796 if (keylen_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14797
14798 uint saltbuf_len = keylen_pos - saltbuf_pos;
14799
14800 if (saltbuf_len != 32) return (PARSER_SALT_LENGTH);
14801
14802 keylen_pos++;
14803
14804 char *keybuf_pos = strchr (keylen_pos, '$');
14805
14806 if (keybuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14807
14808 uint keylen_len = keybuf_pos - keylen_pos;
14809
14810 if (keylen_len != 2) return (PARSER_SALT_LENGTH);
14811
14812 keybuf_pos++;
14813
14814 char *databuf_pos = strchr (keybuf_pos, '$');
14815
14816 if (databuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14817
14818 uint keybuf_len = databuf_pos - keybuf_pos;
14819
14820 if (keybuf_len != 32) return (PARSER_SALT_LENGTH);
14821
14822 databuf_pos++;
14823
14824 uint data_len = input_len - 1 - 3 - 1 - saltlen_len - 1 - saltbuf_len - 1 - keylen_len - 1 - keybuf_len - 1;
14825
14826 if (data_len != 3072) return (PARSER_SALT_LENGTH);
14827
14828 /**
14829 * copy data
14830 */
14831
14832 digest[0] = hex_to_u32 ((const u8 *) &keybuf_pos[ 0]);
14833 digest[1] = hex_to_u32 ((const u8 *) &keybuf_pos[ 8]);
14834 digest[2] = hex_to_u32 ((const u8 *) &keybuf_pos[16]);
14835 digest[3] = hex_to_u32 ((const u8 *) &keybuf_pos[24]);
14836
14837 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &saltbuf_pos[ 0]);
14838 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &saltbuf_pos[ 8]);
14839 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &saltbuf_pos[16]);
14840 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &saltbuf_pos[24]);
14841
14842 salt->salt_buf[0] = byte_swap_32 (salt->salt_buf[0]);
14843 salt->salt_buf[1] = byte_swap_32 (salt->salt_buf[1]);
14844 salt->salt_buf[2] = byte_swap_32 (salt->salt_buf[2]);
14845 salt->salt_buf[3] = byte_swap_32 (salt->salt_buf[3]);
14846
14847 salt->salt_len = 16;
14848 salt->salt_iter = ROUNDS_ANDROIDFDE - 1;
14849
14850 for (uint i = 0, j = 0; i < 3072; i += 8, j += 1)
14851 {
14852 androidfde->data[j] = hex_to_u32 ((const u8 *) &databuf_pos[i]);
14853 }
14854
14855 return (PARSER_OK);
14856 }
14857
14858 int scrypt_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14859 {
14860 if ((input_len < DISPLAY_LEN_MIN_8900) || (input_len > DISPLAY_LEN_MAX_8900)) return (PARSER_GLOBAL_LENGTH);
14861
14862 if (memcmp (SIGNATURE_SCRYPT, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
14863
14864 u32 *digest = (u32 *) hash_buf->digest;
14865
14866 salt_t *salt = hash_buf->salt;
14867
14868 /**
14869 * parse line
14870 */
14871
14872 // first is the N salt parameter
14873
14874 char *N_pos = input_buf + 6;
14875
14876 if (N_pos[0] != ':') return (PARSER_SEPARATOR_UNMATCHED);
14877
14878 N_pos++;
14879
14880 salt->scrypt_N = atoi (N_pos);
14881
14882 // r
14883
14884 char *r_pos = strchr (N_pos, ':');
14885
14886 if (r_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14887
14888 r_pos++;
14889
14890 salt->scrypt_r = atoi (r_pos);
14891
14892 // p
14893
14894 char *p_pos = strchr (r_pos, ':');
14895
14896 if (p_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14897
14898 p_pos++;
14899
14900 salt->scrypt_p = atoi (p_pos);
14901
14902 // salt
14903
14904 char *saltbuf_pos = strchr (p_pos, ':');
14905
14906 if (saltbuf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14907
14908 saltbuf_pos++;
14909
14910 char *hash_pos = strchr (saltbuf_pos, ':');
14911
14912 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
14913
14914 hash_pos++;
14915
14916 // base64 decode
14917
14918 int salt_len_base64 = hash_pos - saltbuf_pos;
14919
14920 if (salt_len_base64 > 45) return (PARSER_SALT_LENGTH);
14921
14922 u8 tmp_buf[33] = { 0 };
14923
14924 int tmp_len = base64_decode (base64_to_int, (const u8 *) saltbuf_pos, salt_len_base64, tmp_buf);
14925
14926 char *salt_buf_ptr = (char *) salt->salt_buf;
14927
14928 memcpy (salt_buf_ptr, tmp_buf, tmp_len);
14929
14930 salt->salt_len = tmp_len;
14931 salt->salt_iter = 1;
14932
14933 // digest - base64 decode
14934
14935 memset (tmp_buf, 0, sizeof (tmp_buf));
14936
14937 tmp_len = input_len - (hash_pos - input_buf);
14938
14939 if (tmp_len != 44) return (PARSER_GLOBAL_LENGTH);
14940
14941 base64_decode (base64_to_int, (const u8 *) hash_pos, tmp_len, tmp_buf);
14942
14943 memcpy (digest, tmp_buf, 32);
14944
14945 return (PARSER_OK);
14946 }
14947
14948 int juniper_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14949 {
14950 if ((input_len < DISPLAY_LEN_MIN_501) || (input_len > DISPLAY_LEN_MAX_501)) return (PARSER_GLOBAL_LENGTH);
14951
14952 u32 *digest = (u32 *) hash_buf->digest;
14953
14954 salt_t *salt = hash_buf->salt;
14955
14956 /**
14957 * parse line
14958 */
14959
14960 char decrypted[76] = { 0 }; // iv + hash
14961
14962 juniper_decrypt_hash (input_buf, decrypted);
14963
14964 char *md5crypt_hash = decrypted + 12;
14965
14966 if (memcmp (md5crypt_hash, "$1$danastre$", 12)) return (PARSER_SALT_VALUE);
14967
14968 salt->salt_iter = ROUNDS_MD5CRYPT;
14969
14970 char *salt_pos = md5crypt_hash + 3;
14971
14972 char *hash_pos = strchr (salt_pos, '$'); // or simply salt_pos + 8
14973
14974 salt->salt_len = hash_pos - salt_pos; // should be 8
14975
14976 memcpy ((char *) salt->salt_buf, salt_pos, salt->salt_len);
14977
14978 hash_pos++;
14979
14980 md5crypt_decode ((unsigned char *) digest, (unsigned char *) hash_pos);
14981
14982 return (PARSER_OK);
14983 }
14984
14985 int cisco8_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
14986 {
14987 if ((input_len < DISPLAY_LEN_MIN_9200) || (input_len > DISPLAY_LEN_MAX_9200)) return (PARSER_GLOBAL_LENGTH);
14988
14989 if (memcmp (SIGNATURE_CISCO8, input_buf, 3)) return (PARSER_SIGNATURE_UNMATCHED);
14990
14991 u32 *digest = (u32 *) hash_buf->digest;
14992
14993 salt_t *salt = hash_buf->salt;
14994
14995 pbkdf2_sha256_t *pbkdf2_sha256 = (pbkdf2_sha256_t *) hash_buf->esalt;
14996
14997 /**
14998 * parse line
14999 */
15000
15001 // first is *raw* salt
15002
15003 char *salt_pos = input_buf + 3;
15004
15005 char *hash_pos = strchr (salt_pos, '$');
15006
15007 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15008
15009 uint salt_len = hash_pos - salt_pos;
15010
15011 if (salt_len != 14) return (PARSER_SALT_LENGTH);
15012
15013 hash_pos++;
15014
15015 char *salt_buf_ptr = (char *) pbkdf2_sha256->salt_buf;
15016
15017 memcpy (salt_buf_ptr, salt_pos, 14);
15018
15019 salt_buf_ptr[17] = 0x01;
15020 salt_buf_ptr[18] = 0x80;
15021
15022 // add some stuff to normal salt to make sorted happy
15023
15024 salt->salt_buf[0] = pbkdf2_sha256->salt_buf[0];
15025 salt->salt_buf[1] = pbkdf2_sha256->salt_buf[1];
15026 salt->salt_buf[2] = pbkdf2_sha256->salt_buf[2];
15027 salt->salt_buf[3] = pbkdf2_sha256->salt_buf[3];
15028
15029 salt->salt_len = salt_len;
15030 salt->salt_iter = ROUNDS_CISCO8 - 1;
15031
15032 // base64 decode hash
15033
15034 u8 tmp_buf[100] = { 0 };
15035
15036 uint hash_len = input_len - 3 - salt_len - 1;
15037
15038 int tmp_len = base64_decode (itoa64_to_int, (const u8 *) hash_pos, hash_len, tmp_buf);
15039
15040 if (tmp_len != 32) return (PARSER_HASH_LENGTH);
15041
15042 memcpy (digest, tmp_buf, 32);
15043
15044 digest[0] = byte_swap_32 (digest[0]);
15045 digest[1] = byte_swap_32 (digest[1]);
15046 digest[2] = byte_swap_32 (digest[2]);
15047 digest[3] = byte_swap_32 (digest[3]);
15048 digest[4] = byte_swap_32 (digest[4]);
15049 digest[5] = byte_swap_32 (digest[5]);
15050 digest[6] = byte_swap_32 (digest[6]);
15051 digest[7] = byte_swap_32 (digest[7]);
15052
15053 return (PARSER_OK);
15054 }
15055
15056 int cisco9_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
15057 {
15058 if ((input_len < DISPLAY_LEN_MIN_9300) || (input_len > DISPLAY_LEN_MAX_9300)) return (PARSER_GLOBAL_LENGTH);
15059
15060 if (memcmp (SIGNATURE_CISCO9, input_buf, 3)) return (PARSER_SIGNATURE_UNMATCHED);
15061
15062 u32 *digest = (u32 *) hash_buf->digest;
15063
15064 salt_t *salt = hash_buf->salt;
15065
15066 /**
15067 * parse line
15068 */
15069
15070 // first is *raw* salt
15071
15072 char *salt_pos = input_buf + 3;
15073
15074 char *hash_pos = strchr (salt_pos, '$');
15075
15076 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15077
15078 uint salt_len = hash_pos - salt_pos;
15079
15080 if (salt_len != 14) return (PARSER_SALT_LENGTH);
15081
15082 salt->salt_len = salt_len;
15083 hash_pos++;
15084
15085 char *salt_buf_ptr = (char *) salt->salt_buf;
15086
15087 memcpy (salt_buf_ptr, salt_pos, salt_len);
15088 salt_buf_ptr[salt_len] = 0;
15089
15090 // base64 decode hash
15091
15092 u8 tmp_buf[100] = { 0 };
15093
15094 uint hash_len = input_len - 3 - salt_len - 1;
15095
15096 int tmp_len = base64_decode (itoa64_to_int, (const u8 *) hash_pos, hash_len, tmp_buf);
15097
15098 if (tmp_len != 32) return (PARSER_HASH_LENGTH);
15099
15100 memcpy (digest, tmp_buf, 32);
15101
15102 // fixed:
15103 salt->scrypt_N = 16384;
15104 salt->scrypt_r = 1;
15105 salt->scrypt_p = 1;
15106 salt->salt_iter = 1;
15107
15108 return (PARSER_OK);
15109 }
15110
15111 int office2007_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
15112 {
15113 if ((input_len < DISPLAY_LEN_MIN_9400) || (input_len > DISPLAY_LEN_MAX_9400)) return (PARSER_GLOBAL_LENGTH);
15114
15115 if (memcmp (SIGNATURE_OFFICE2007, input_buf, 8)) return (PARSER_SIGNATURE_UNMATCHED);
15116
15117 u32 *digest = (u32 *) hash_buf->digest;
15118
15119 salt_t *salt = hash_buf->salt;
15120
15121 office2007_t *office2007 = (office2007_t *) hash_buf->esalt;
15122
15123 /**
15124 * parse line
15125 */
15126
15127 char *version_pos = input_buf + 8 + 1;
15128
15129 char *verifierHashSize_pos = strchr (version_pos, '*');
15130
15131 if (verifierHashSize_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15132
15133 u32 version_len = verifierHashSize_pos - version_pos;
15134
15135 if (version_len != 4) return (PARSER_SALT_LENGTH);
15136
15137 verifierHashSize_pos++;
15138
15139 char *keySize_pos = strchr (verifierHashSize_pos, '*');
15140
15141 if (keySize_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15142
15143 u32 verifierHashSize_len = keySize_pos - verifierHashSize_pos;
15144
15145 if (verifierHashSize_len != 2) return (PARSER_SALT_LENGTH);
15146
15147 keySize_pos++;
15148
15149 char *saltSize_pos = strchr (keySize_pos, '*');
15150
15151 if (saltSize_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15152
15153 u32 keySize_len = saltSize_pos - keySize_pos;
15154
15155 if (keySize_len != 3) return (PARSER_SALT_LENGTH);
15156
15157 saltSize_pos++;
15158
15159 char *osalt_pos = strchr (saltSize_pos, '*');
15160
15161 if (osalt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15162
15163 u32 saltSize_len = osalt_pos - saltSize_pos;
15164
15165 if (saltSize_len != 2) return (PARSER_SALT_LENGTH);
15166
15167 osalt_pos++;
15168
15169 char *encryptedVerifier_pos = strchr (osalt_pos, '*');
15170
15171 if (encryptedVerifier_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15172
15173 u32 osalt_len = encryptedVerifier_pos - osalt_pos;
15174
15175 if (osalt_len != 32) return (PARSER_SALT_LENGTH);
15176
15177 encryptedVerifier_pos++;
15178
15179 char *encryptedVerifierHash_pos = strchr (encryptedVerifier_pos, '*');
15180
15181 if (encryptedVerifierHash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15182
15183 u32 encryptedVerifier_len = encryptedVerifierHash_pos - encryptedVerifier_pos;
15184
15185 if (encryptedVerifier_len != 32) return (PARSER_SALT_LENGTH);
15186
15187 encryptedVerifierHash_pos++;
15188
15189 u32 encryptedVerifierHash_len = input_len - 8 - 1 - version_len - 1 - verifierHashSize_len - 1 - keySize_len - 1 - saltSize_len - 1 - osalt_len - 1 - encryptedVerifier_len - 1;
15190
15191 if (encryptedVerifierHash_len != 40) return (PARSER_SALT_LENGTH);
15192
15193 const uint version = atoi (version_pos);
15194
15195 if (version != 2007) return (PARSER_SALT_VALUE);
15196
15197 const uint verifierHashSize = atoi (verifierHashSize_pos);
15198
15199 if (verifierHashSize != 20) return (PARSER_SALT_VALUE);
15200
15201 const uint keySize = atoi (keySize_pos);
15202
15203 if ((keySize != 128) && (keySize != 256)) return (PARSER_SALT_VALUE);
15204
15205 office2007->keySize = keySize;
15206
15207 const uint saltSize = atoi (saltSize_pos);
15208
15209 if (saltSize != 16) return (PARSER_SALT_VALUE);
15210
15211 /**
15212 * salt
15213 */
15214
15215 salt->salt_len = 16;
15216 salt->salt_iter = ROUNDS_OFFICE2007;
15217
15218 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &osalt_pos[ 0]);
15219 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &osalt_pos[ 8]);
15220 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &osalt_pos[16]);
15221 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &osalt_pos[24]);
15222
15223 /**
15224 * esalt
15225 */
15226
15227 office2007->encryptedVerifier[0] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 0]);
15228 office2007->encryptedVerifier[1] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 8]);
15229 office2007->encryptedVerifier[2] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[16]);
15230 office2007->encryptedVerifier[3] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[24]);
15231
15232 office2007->encryptedVerifierHash[0] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 0]);
15233 office2007->encryptedVerifierHash[1] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 8]);
15234 office2007->encryptedVerifierHash[2] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[16]);
15235 office2007->encryptedVerifierHash[3] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[24]);
15236 office2007->encryptedVerifierHash[4] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[32]);
15237
15238 /**
15239 * digest
15240 */
15241
15242 digest[0] = office2007->encryptedVerifierHash[0];
15243 digest[1] = office2007->encryptedVerifierHash[1];
15244 digest[2] = office2007->encryptedVerifierHash[2];
15245 digest[3] = office2007->encryptedVerifierHash[3];
15246
15247 return (PARSER_OK);
15248 }
15249
15250 int office2010_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
15251 {
15252 if ((input_len < DISPLAY_LEN_MIN_9500) || (input_len > DISPLAY_LEN_MAX_9500)) return (PARSER_GLOBAL_LENGTH);
15253
15254 if (memcmp (SIGNATURE_OFFICE2010, input_buf, 8)) return (PARSER_SIGNATURE_UNMATCHED);
15255
15256 u32 *digest = (u32 *) hash_buf->digest;
15257
15258 salt_t *salt = hash_buf->salt;
15259
15260 office2010_t *office2010 = (office2010_t *) hash_buf->esalt;
15261
15262 /**
15263 * parse line
15264 */
15265
15266 char *version_pos = input_buf + 8 + 1;
15267
15268 char *spinCount_pos = strchr (version_pos, '*');
15269
15270 if (spinCount_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15271
15272 u32 version_len = spinCount_pos - version_pos;
15273
15274 if (version_len != 4) return (PARSER_SALT_LENGTH);
15275
15276 spinCount_pos++;
15277
15278 char *keySize_pos = strchr (spinCount_pos, '*');
15279
15280 if (keySize_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15281
15282 u32 spinCount_len = keySize_pos - spinCount_pos;
15283
15284 if (spinCount_len != 6) return (PARSER_SALT_LENGTH);
15285
15286 keySize_pos++;
15287
15288 char *saltSize_pos = strchr (keySize_pos, '*');
15289
15290 if (saltSize_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15291
15292 u32 keySize_len = saltSize_pos - keySize_pos;
15293
15294 if (keySize_len != 3) return (PARSER_SALT_LENGTH);
15295
15296 saltSize_pos++;
15297
15298 char *osalt_pos = strchr (saltSize_pos, '*');
15299
15300 if (osalt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15301
15302 u32 saltSize_len = osalt_pos - saltSize_pos;
15303
15304 if (saltSize_len != 2) return (PARSER_SALT_LENGTH);
15305
15306 osalt_pos++;
15307
15308 char *encryptedVerifier_pos = strchr (osalt_pos, '*');
15309
15310 if (encryptedVerifier_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15311
15312 u32 osalt_len = encryptedVerifier_pos - osalt_pos;
15313
15314 if (osalt_len != 32) return (PARSER_SALT_LENGTH);
15315
15316 encryptedVerifier_pos++;
15317
15318 char *encryptedVerifierHash_pos = strchr (encryptedVerifier_pos, '*');
15319
15320 if (encryptedVerifierHash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15321
15322 u32 encryptedVerifier_len = encryptedVerifierHash_pos - encryptedVerifier_pos;
15323
15324 if (encryptedVerifier_len != 32) return (PARSER_SALT_LENGTH);
15325
15326 encryptedVerifierHash_pos++;
15327
15328 u32 encryptedVerifierHash_len = input_len - 8 - 1 - version_len - 1 - spinCount_len - 1 - keySize_len - 1 - saltSize_len - 1 - osalt_len - 1 - encryptedVerifier_len - 1;
15329
15330 if (encryptedVerifierHash_len != 64) return (PARSER_SALT_LENGTH);
15331
15332 const uint version = atoi (version_pos);
15333
15334 if (version != 2010) return (PARSER_SALT_VALUE);
15335
15336 const uint spinCount = atoi (spinCount_pos);
15337
15338 if (spinCount != 100000) return (PARSER_SALT_VALUE);
15339
15340 const uint keySize = atoi (keySize_pos);
15341
15342 if (keySize != 128) return (PARSER_SALT_VALUE);
15343
15344 const uint saltSize = atoi (saltSize_pos);
15345
15346 if (saltSize != 16) return (PARSER_SALT_VALUE);
15347
15348 /**
15349 * salt
15350 */
15351
15352 salt->salt_len = 16;
15353 salt->salt_iter = spinCount;
15354
15355 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &osalt_pos[ 0]);
15356 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &osalt_pos[ 8]);
15357 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &osalt_pos[16]);
15358 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &osalt_pos[24]);
15359
15360 /**
15361 * esalt
15362 */
15363
15364 office2010->encryptedVerifier[0] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 0]);
15365 office2010->encryptedVerifier[1] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 8]);
15366 office2010->encryptedVerifier[2] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[16]);
15367 office2010->encryptedVerifier[3] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[24]);
15368
15369 office2010->encryptedVerifierHash[0] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 0]);
15370 office2010->encryptedVerifierHash[1] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 8]);
15371 office2010->encryptedVerifierHash[2] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[16]);
15372 office2010->encryptedVerifierHash[3] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[24]);
15373 office2010->encryptedVerifierHash[4] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[32]);
15374 office2010->encryptedVerifierHash[5] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[40]);
15375 office2010->encryptedVerifierHash[6] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[48]);
15376 office2010->encryptedVerifierHash[7] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[56]);
15377
15378 /**
15379 * digest
15380 */
15381
15382 digest[0] = office2010->encryptedVerifierHash[0];
15383 digest[1] = office2010->encryptedVerifierHash[1];
15384 digest[2] = office2010->encryptedVerifierHash[2];
15385 digest[3] = office2010->encryptedVerifierHash[3];
15386
15387 return (PARSER_OK);
15388 }
15389
15390 int office2013_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
15391 {
15392 if ((input_len < DISPLAY_LEN_MIN_9600) || (input_len > DISPLAY_LEN_MAX_9600)) return (PARSER_GLOBAL_LENGTH);
15393
15394 if (memcmp (SIGNATURE_OFFICE2013, input_buf, 8)) return (PARSER_SIGNATURE_UNMATCHED);
15395
15396 u32 *digest = (u32 *) hash_buf->digest;
15397
15398 salt_t *salt = hash_buf->salt;
15399
15400 office2013_t *office2013 = (office2013_t *) hash_buf->esalt;
15401
15402 /**
15403 * parse line
15404 */
15405
15406 char *version_pos = input_buf + 8 + 1;
15407
15408 char *spinCount_pos = strchr (version_pos, '*');
15409
15410 if (spinCount_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15411
15412 u32 version_len = spinCount_pos - version_pos;
15413
15414 if (version_len != 4) return (PARSER_SALT_LENGTH);
15415
15416 spinCount_pos++;
15417
15418 char *keySize_pos = strchr (spinCount_pos, '*');
15419
15420 if (keySize_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15421
15422 u32 spinCount_len = keySize_pos - spinCount_pos;
15423
15424 if (spinCount_len != 6) return (PARSER_SALT_LENGTH);
15425
15426 keySize_pos++;
15427
15428 char *saltSize_pos = strchr (keySize_pos, '*');
15429
15430 if (saltSize_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15431
15432 u32 keySize_len = saltSize_pos - keySize_pos;
15433
15434 if (keySize_len != 3) return (PARSER_SALT_LENGTH);
15435
15436 saltSize_pos++;
15437
15438 char *osalt_pos = strchr (saltSize_pos, '*');
15439
15440 if (osalt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15441
15442 u32 saltSize_len = osalt_pos - saltSize_pos;
15443
15444 if (saltSize_len != 2) return (PARSER_SALT_LENGTH);
15445
15446 osalt_pos++;
15447
15448 char *encryptedVerifier_pos = strchr (osalt_pos, '*');
15449
15450 if (encryptedVerifier_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15451
15452 u32 osalt_len = encryptedVerifier_pos - osalt_pos;
15453
15454 if (osalt_len != 32) return (PARSER_SALT_LENGTH);
15455
15456 encryptedVerifier_pos++;
15457
15458 char *encryptedVerifierHash_pos = strchr (encryptedVerifier_pos, '*');
15459
15460 if (encryptedVerifierHash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15461
15462 u32 encryptedVerifier_len = encryptedVerifierHash_pos - encryptedVerifier_pos;
15463
15464 if (encryptedVerifier_len != 32) return (PARSER_SALT_LENGTH);
15465
15466 encryptedVerifierHash_pos++;
15467
15468 u32 encryptedVerifierHash_len = input_len - 8 - 1 - version_len - 1 - spinCount_len - 1 - keySize_len - 1 - saltSize_len - 1 - osalt_len - 1 - encryptedVerifier_len - 1;
15469
15470 if (encryptedVerifierHash_len != 64) return (PARSER_SALT_LENGTH);
15471
15472 const uint version = atoi (version_pos);
15473
15474 if (version != 2013) return (PARSER_SALT_VALUE);
15475
15476 const uint spinCount = atoi (spinCount_pos);
15477
15478 if (spinCount != 100000) return (PARSER_SALT_VALUE);
15479
15480 const uint keySize = atoi (keySize_pos);
15481
15482 if (keySize != 256) return (PARSER_SALT_VALUE);
15483
15484 const uint saltSize = atoi (saltSize_pos);
15485
15486 if (saltSize != 16) return (PARSER_SALT_VALUE);
15487
15488 /**
15489 * salt
15490 */
15491
15492 salt->salt_len = 16;
15493 salt->salt_iter = spinCount;
15494
15495 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &osalt_pos[ 0]);
15496 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &osalt_pos[ 8]);
15497 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &osalt_pos[16]);
15498 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &osalt_pos[24]);
15499
15500 /**
15501 * esalt
15502 */
15503
15504 office2013->encryptedVerifier[0] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 0]);
15505 office2013->encryptedVerifier[1] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 8]);
15506 office2013->encryptedVerifier[2] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[16]);
15507 office2013->encryptedVerifier[3] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[24]);
15508
15509 office2013->encryptedVerifierHash[0] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 0]);
15510 office2013->encryptedVerifierHash[1] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 8]);
15511 office2013->encryptedVerifierHash[2] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[16]);
15512 office2013->encryptedVerifierHash[3] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[24]);
15513 office2013->encryptedVerifierHash[4] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[32]);
15514 office2013->encryptedVerifierHash[5] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[40]);
15515 office2013->encryptedVerifierHash[6] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[48]);
15516 office2013->encryptedVerifierHash[7] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[56]);
15517
15518 /**
15519 * digest
15520 */
15521
15522 digest[0] = office2013->encryptedVerifierHash[0];
15523 digest[1] = office2013->encryptedVerifierHash[1];
15524 digest[2] = office2013->encryptedVerifierHash[2];
15525 digest[3] = office2013->encryptedVerifierHash[3];
15526
15527 return (PARSER_OK);
15528 }
15529
15530 int oldoffice01_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
15531 {
15532 if ((input_len < DISPLAY_LEN_MIN_9700) || (input_len > DISPLAY_LEN_MAX_9700)) return (PARSER_GLOBAL_LENGTH);
15533
15534 if ((memcmp (SIGNATURE_OLDOFFICE0, input_buf, 12)) && (memcmp (SIGNATURE_OLDOFFICE1, input_buf, 12))) return (PARSER_SIGNATURE_UNMATCHED);
15535
15536 u32 *digest = (u32 *) hash_buf->digest;
15537
15538 salt_t *salt = hash_buf->salt;
15539
15540 oldoffice01_t *oldoffice01 = (oldoffice01_t *) hash_buf->esalt;
15541
15542 /**
15543 * parse line
15544 */
15545
15546 char *version_pos = input_buf + 11;
15547
15548 char *osalt_pos = strchr (version_pos, '*');
15549
15550 if (osalt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15551
15552 u32 version_len = osalt_pos - version_pos;
15553
15554 if (version_len != 1) return (PARSER_SALT_LENGTH);
15555
15556 osalt_pos++;
15557
15558 char *encryptedVerifier_pos = strchr (osalt_pos, '*');
15559
15560 if (encryptedVerifier_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15561
15562 u32 osalt_len = encryptedVerifier_pos - osalt_pos;
15563
15564 if (osalt_len != 32) return (PARSER_SALT_LENGTH);
15565
15566 encryptedVerifier_pos++;
15567
15568 char *encryptedVerifierHash_pos = strchr (encryptedVerifier_pos, '*');
15569
15570 if (encryptedVerifierHash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15571
15572 u32 encryptedVerifier_len = encryptedVerifierHash_pos - encryptedVerifier_pos;
15573
15574 if (encryptedVerifier_len != 32) return (PARSER_SALT_LENGTH);
15575
15576 encryptedVerifierHash_pos++;
15577
15578 u32 encryptedVerifierHash_len = input_len - 11 - version_len - 1 - osalt_len - 1 - encryptedVerifier_len - 1;
15579
15580 if (encryptedVerifierHash_len != 32) return (PARSER_SALT_LENGTH);
15581
15582 const uint version = *version_pos - 0x30;
15583
15584 if (version != 0 && version != 1) return (PARSER_SALT_VALUE);
15585
15586 /**
15587 * esalt
15588 */
15589
15590 oldoffice01->version = version;
15591
15592 oldoffice01->encryptedVerifier[0] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 0]);
15593 oldoffice01->encryptedVerifier[1] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 8]);
15594 oldoffice01->encryptedVerifier[2] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[16]);
15595 oldoffice01->encryptedVerifier[3] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[24]);
15596
15597 oldoffice01->encryptedVerifier[0] = byte_swap_32 (oldoffice01->encryptedVerifier[0]);
15598 oldoffice01->encryptedVerifier[1] = byte_swap_32 (oldoffice01->encryptedVerifier[1]);
15599 oldoffice01->encryptedVerifier[2] = byte_swap_32 (oldoffice01->encryptedVerifier[2]);
15600 oldoffice01->encryptedVerifier[3] = byte_swap_32 (oldoffice01->encryptedVerifier[3]);
15601
15602 oldoffice01->encryptedVerifierHash[0] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 0]);
15603 oldoffice01->encryptedVerifierHash[1] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 8]);
15604 oldoffice01->encryptedVerifierHash[2] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[16]);
15605 oldoffice01->encryptedVerifierHash[3] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[24]);
15606
15607 oldoffice01->encryptedVerifierHash[0] = byte_swap_32 (oldoffice01->encryptedVerifierHash[0]);
15608 oldoffice01->encryptedVerifierHash[1] = byte_swap_32 (oldoffice01->encryptedVerifierHash[1]);
15609 oldoffice01->encryptedVerifierHash[2] = byte_swap_32 (oldoffice01->encryptedVerifierHash[2]);
15610 oldoffice01->encryptedVerifierHash[3] = byte_swap_32 (oldoffice01->encryptedVerifierHash[3]);
15611
15612 /**
15613 * salt
15614 */
15615
15616 salt->salt_len = 16;
15617
15618 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &osalt_pos[ 0]);
15619 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &osalt_pos[ 8]);
15620 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &osalt_pos[16]);
15621 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &osalt_pos[24]);
15622
15623 salt->salt_buf[0] = byte_swap_32 (salt->salt_buf[0]);
15624 salt->salt_buf[1] = byte_swap_32 (salt->salt_buf[1]);
15625 salt->salt_buf[2] = byte_swap_32 (salt->salt_buf[2]);
15626 salt->salt_buf[3] = byte_swap_32 (salt->salt_buf[3]);
15627
15628 // this is a workaround as office produces multiple documents with the same salt
15629
15630 salt->salt_len += 32;
15631
15632 salt->salt_buf[ 4] = oldoffice01->encryptedVerifier[0];
15633 salt->salt_buf[ 5] = oldoffice01->encryptedVerifier[1];
15634 salt->salt_buf[ 6] = oldoffice01->encryptedVerifier[2];
15635 salt->salt_buf[ 7] = oldoffice01->encryptedVerifier[3];
15636 salt->salt_buf[ 8] = oldoffice01->encryptedVerifierHash[0];
15637 salt->salt_buf[ 9] = oldoffice01->encryptedVerifierHash[1];
15638 salt->salt_buf[10] = oldoffice01->encryptedVerifierHash[2];
15639 salt->salt_buf[11] = oldoffice01->encryptedVerifierHash[3];
15640
15641 /**
15642 * digest
15643 */
15644
15645 digest[0] = oldoffice01->encryptedVerifierHash[0];
15646 digest[1] = oldoffice01->encryptedVerifierHash[1];
15647 digest[2] = oldoffice01->encryptedVerifierHash[2];
15648 digest[3] = oldoffice01->encryptedVerifierHash[3];
15649
15650 return (PARSER_OK);
15651 }
15652
15653 int oldoffice01cm1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
15654 {
15655 return oldoffice01_parse_hash (input_buf, input_len, hash_buf);
15656 }
15657
15658 int oldoffice01cm2_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
15659 {
15660 if ((input_len < DISPLAY_LEN_MIN_9720) || (input_len > DISPLAY_LEN_MAX_9720)) return (PARSER_GLOBAL_LENGTH);
15661
15662 if ((memcmp (SIGNATURE_OLDOFFICE0, input_buf, 12)) && (memcmp (SIGNATURE_OLDOFFICE1, input_buf, 12))) return (PARSER_SIGNATURE_UNMATCHED);
15663
15664 u32 *digest = (u32 *) hash_buf->digest;
15665
15666 salt_t *salt = hash_buf->salt;
15667
15668 oldoffice01_t *oldoffice01 = (oldoffice01_t *) hash_buf->esalt;
15669
15670 /**
15671 * parse line
15672 */
15673
15674 char *version_pos = input_buf + 11;
15675
15676 char *osalt_pos = strchr (version_pos, '*');
15677
15678 if (osalt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15679
15680 u32 version_len = osalt_pos - version_pos;
15681
15682 if (version_len != 1) return (PARSER_SALT_LENGTH);
15683
15684 osalt_pos++;
15685
15686 char *encryptedVerifier_pos = strchr (osalt_pos, '*');
15687
15688 if (encryptedVerifier_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15689
15690 u32 osalt_len = encryptedVerifier_pos - osalt_pos;
15691
15692 if (osalt_len != 32) return (PARSER_SALT_LENGTH);
15693
15694 encryptedVerifier_pos++;
15695
15696 char *encryptedVerifierHash_pos = strchr (encryptedVerifier_pos, '*');
15697
15698 if (encryptedVerifierHash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15699
15700 u32 encryptedVerifier_len = encryptedVerifierHash_pos - encryptedVerifier_pos;
15701
15702 if (encryptedVerifier_len != 32) return (PARSER_SALT_LENGTH);
15703
15704 encryptedVerifierHash_pos++;
15705
15706 char *rc4key_pos = strchr (encryptedVerifierHash_pos, ':');
15707
15708 if (rc4key_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15709
15710 u32 encryptedVerifierHash_len = rc4key_pos - encryptedVerifierHash_pos;
15711
15712 if (encryptedVerifierHash_len != 32) return (PARSER_SALT_LENGTH);
15713
15714 rc4key_pos++;
15715
15716 u32 rc4key_len = input_len - 11 - version_len - 1 - osalt_len - 1 - encryptedVerifier_len - 1 - encryptedVerifierHash_len - 1;
15717
15718 if (rc4key_len != 10) return (PARSER_SALT_LENGTH);
15719
15720 const uint version = *version_pos - 0x30;
15721
15722 if (version != 0 && version != 1) return (PARSER_SALT_VALUE);
15723
15724 /**
15725 * esalt
15726 */
15727
15728 oldoffice01->version = version;
15729
15730 oldoffice01->encryptedVerifier[0] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 0]);
15731 oldoffice01->encryptedVerifier[1] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 8]);
15732 oldoffice01->encryptedVerifier[2] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[16]);
15733 oldoffice01->encryptedVerifier[3] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[24]);
15734
15735 oldoffice01->encryptedVerifier[0] = byte_swap_32 (oldoffice01->encryptedVerifier[0]);
15736 oldoffice01->encryptedVerifier[1] = byte_swap_32 (oldoffice01->encryptedVerifier[1]);
15737 oldoffice01->encryptedVerifier[2] = byte_swap_32 (oldoffice01->encryptedVerifier[2]);
15738 oldoffice01->encryptedVerifier[3] = byte_swap_32 (oldoffice01->encryptedVerifier[3]);
15739
15740 oldoffice01->encryptedVerifierHash[0] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 0]);
15741 oldoffice01->encryptedVerifierHash[1] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 8]);
15742 oldoffice01->encryptedVerifierHash[2] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[16]);
15743 oldoffice01->encryptedVerifierHash[3] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[24]);
15744
15745 oldoffice01->encryptedVerifierHash[0] = byte_swap_32 (oldoffice01->encryptedVerifierHash[0]);
15746 oldoffice01->encryptedVerifierHash[1] = byte_swap_32 (oldoffice01->encryptedVerifierHash[1]);
15747 oldoffice01->encryptedVerifierHash[2] = byte_swap_32 (oldoffice01->encryptedVerifierHash[2]);
15748 oldoffice01->encryptedVerifierHash[3] = byte_swap_32 (oldoffice01->encryptedVerifierHash[3]);
15749
15750 oldoffice01->rc4key[1] = 0;
15751 oldoffice01->rc4key[0] = 0;
15752
15753 oldoffice01->rc4key[0] |= hex_convert (rc4key_pos[0]) << 28;
15754 oldoffice01->rc4key[0] |= hex_convert (rc4key_pos[1]) << 24;
15755 oldoffice01->rc4key[0] |= hex_convert (rc4key_pos[2]) << 20;
15756 oldoffice01->rc4key[0] |= hex_convert (rc4key_pos[3]) << 16;
15757 oldoffice01->rc4key[0] |= hex_convert (rc4key_pos[4]) << 12;
15758 oldoffice01->rc4key[0] |= hex_convert (rc4key_pos[5]) << 8;
15759 oldoffice01->rc4key[0] |= hex_convert (rc4key_pos[6]) << 4;
15760 oldoffice01->rc4key[0] |= hex_convert (rc4key_pos[7]) << 0;
15761 oldoffice01->rc4key[1] |= hex_convert (rc4key_pos[8]) << 28;
15762 oldoffice01->rc4key[1] |= hex_convert (rc4key_pos[9]) << 24;
15763
15764 oldoffice01->rc4key[0] = byte_swap_32 (oldoffice01->rc4key[0]);
15765 oldoffice01->rc4key[1] = byte_swap_32 (oldoffice01->rc4key[1]);
15766
15767 /**
15768 * salt
15769 */
15770
15771 salt->salt_len = 16;
15772
15773 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &osalt_pos[ 0]);
15774 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &osalt_pos[ 8]);
15775 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &osalt_pos[16]);
15776 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &osalt_pos[24]);
15777
15778 salt->salt_buf[0] = byte_swap_32 (salt->salt_buf[0]);
15779 salt->salt_buf[1] = byte_swap_32 (salt->salt_buf[1]);
15780 salt->salt_buf[2] = byte_swap_32 (salt->salt_buf[2]);
15781 salt->salt_buf[3] = byte_swap_32 (salt->salt_buf[3]);
15782
15783 // this is a workaround as office produces multiple documents with the same salt
15784
15785 salt->salt_len += 32;
15786
15787 salt->salt_buf[ 4] = oldoffice01->encryptedVerifier[0];
15788 salt->salt_buf[ 5] = oldoffice01->encryptedVerifier[1];
15789 salt->salt_buf[ 6] = oldoffice01->encryptedVerifier[2];
15790 salt->salt_buf[ 7] = oldoffice01->encryptedVerifier[3];
15791 salt->salt_buf[ 8] = oldoffice01->encryptedVerifierHash[0];
15792 salt->salt_buf[ 9] = oldoffice01->encryptedVerifierHash[1];
15793 salt->salt_buf[10] = oldoffice01->encryptedVerifierHash[2];
15794 salt->salt_buf[11] = oldoffice01->encryptedVerifierHash[3];
15795
15796 /**
15797 * digest
15798 */
15799
15800 digest[0] = oldoffice01->rc4key[0];
15801 digest[1] = oldoffice01->rc4key[1];
15802 digest[2] = 0;
15803 digest[3] = 0;
15804
15805 return (PARSER_OK);
15806 }
15807
15808 int oldoffice34_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
15809 {
15810 if ((input_len < DISPLAY_LEN_MIN_9800) || (input_len > DISPLAY_LEN_MAX_9800)) return (PARSER_GLOBAL_LENGTH);
15811
15812 if ((memcmp (SIGNATURE_OLDOFFICE3, input_buf, 12)) && (memcmp (SIGNATURE_OLDOFFICE4, input_buf, 12))) return (PARSER_SIGNATURE_UNMATCHED);
15813
15814 u32 *digest = (u32 *) hash_buf->digest;
15815
15816 salt_t *salt = hash_buf->salt;
15817
15818 oldoffice34_t *oldoffice34 = (oldoffice34_t *) hash_buf->esalt;
15819
15820 /**
15821 * parse line
15822 */
15823
15824 char *version_pos = input_buf + 11;
15825
15826 char *osalt_pos = strchr (version_pos, '*');
15827
15828 if (osalt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15829
15830 u32 version_len = osalt_pos - version_pos;
15831
15832 if (version_len != 1) return (PARSER_SALT_LENGTH);
15833
15834 osalt_pos++;
15835
15836 char *encryptedVerifier_pos = strchr (osalt_pos, '*');
15837
15838 if (encryptedVerifier_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15839
15840 u32 osalt_len = encryptedVerifier_pos - osalt_pos;
15841
15842 if (osalt_len != 32) return (PARSER_SALT_LENGTH);
15843
15844 encryptedVerifier_pos++;
15845
15846 char *encryptedVerifierHash_pos = strchr (encryptedVerifier_pos, '*');
15847
15848 if (encryptedVerifierHash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15849
15850 u32 encryptedVerifier_len = encryptedVerifierHash_pos - encryptedVerifier_pos;
15851
15852 if (encryptedVerifier_len != 32) return (PARSER_SALT_LENGTH);
15853
15854 encryptedVerifierHash_pos++;
15855
15856 u32 encryptedVerifierHash_len = input_len - 11 - version_len - 1 - osalt_len - 1 - encryptedVerifier_len - 1;
15857
15858 if (encryptedVerifierHash_len != 40) return (PARSER_SALT_LENGTH);
15859
15860 const uint version = *version_pos - 0x30;
15861
15862 if (version != 3 && version != 4) return (PARSER_SALT_VALUE);
15863
15864 /**
15865 * esalt
15866 */
15867
15868 oldoffice34->version = version;
15869
15870 oldoffice34->encryptedVerifier[0] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 0]);
15871 oldoffice34->encryptedVerifier[1] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 8]);
15872 oldoffice34->encryptedVerifier[2] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[16]);
15873 oldoffice34->encryptedVerifier[3] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[24]);
15874
15875 oldoffice34->encryptedVerifier[0] = byte_swap_32 (oldoffice34->encryptedVerifier[0]);
15876 oldoffice34->encryptedVerifier[1] = byte_swap_32 (oldoffice34->encryptedVerifier[1]);
15877 oldoffice34->encryptedVerifier[2] = byte_swap_32 (oldoffice34->encryptedVerifier[2]);
15878 oldoffice34->encryptedVerifier[3] = byte_swap_32 (oldoffice34->encryptedVerifier[3]);
15879
15880 oldoffice34->encryptedVerifierHash[0] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 0]);
15881 oldoffice34->encryptedVerifierHash[1] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 8]);
15882 oldoffice34->encryptedVerifierHash[2] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[16]);
15883 oldoffice34->encryptedVerifierHash[3] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[24]);
15884 oldoffice34->encryptedVerifierHash[4] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[32]);
15885
15886 oldoffice34->encryptedVerifierHash[0] = byte_swap_32 (oldoffice34->encryptedVerifierHash[0]);
15887 oldoffice34->encryptedVerifierHash[1] = byte_swap_32 (oldoffice34->encryptedVerifierHash[1]);
15888 oldoffice34->encryptedVerifierHash[2] = byte_swap_32 (oldoffice34->encryptedVerifierHash[2]);
15889 oldoffice34->encryptedVerifierHash[3] = byte_swap_32 (oldoffice34->encryptedVerifierHash[3]);
15890 oldoffice34->encryptedVerifierHash[4] = byte_swap_32 (oldoffice34->encryptedVerifierHash[4]);
15891
15892 /**
15893 * salt
15894 */
15895
15896 salt->salt_len = 16;
15897
15898 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &osalt_pos[ 0]);
15899 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &osalt_pos[ 8]);
15900 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &osalt_pos[16]);
15901 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &osalt_pos[24]);
15902
15903 // this is a workaround as office produces multiple documents with the same salt
15904
15905 salt->salt_len += 32;
15906
15907 salt->salt_buf[ 4] = oldoffice34->encryptedVerifier[0];
15908 salt->salt_buf[ 5] = oldoffice34->encryptedVerifier[1];
15909 salt->salt_buf[ 6] = oldoffice34->encryptedVerifier[2];
15910 salt->salt_buf[ 7] = oldoffice34->encryptedVerifier[3];
15911 salt->salt_buf[ 8] = oldoffice34->encryptedVerifierHash[0];
15912 salt->salt_buf[ 9] = oldoffice34->encryptedVerifierHash[1];
15913 salt->salt_buf[10] = oldoffice34->encryptedVerifierHash[2];
15914 salt->salt_buf[11] = oldoffice34->encryptedVerifierHash[3];
15915
15916 /**
15917 * digest
15918 */
15919
15920 digest[0] = oldoffice34->encryptedVerifierHash[0];
15921 digest[1] = oldoffice34->encryptedVerifierHash[1];
15922 digest[2] = oldoffice34->encryptedVerifierHash[2];
15923 digest[3] = oldoffice34->encryptedVerifierHash[3];
15924
15925 return (PARSER_OK);
15926 }
15927
15928 int oldoffice34cm1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
15929 {
15930 if (memcmp (SIGNATURE_OLDOFFICE3, input_buf, 12)) return (PARSER_SIGNATURE_UNMATCHED);
15931
15932 return oldoffice34_parse_hash (input_buf, input_len, hash_buf);
15933 }
15934
15935 int oldoffice34cm2_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
15936 {
15937 if ((input_len < DISPLAY_LEN_MIN_9820) || (input_len > DISPLAY_LEN_MAX_9820)) return (PARSER_GLOBAL_LENGTH);
15938
15939 if (memcmp (SIGNATURE_OLDOFFICE3, input_buf, 12)) return (PARSER_SIGNATURE_UNMATCHED);
15940
15941 u32 *digest = (u32 *) hash_buf->digest;
15942
15943 salt_t *salt = hash_buf->salt;
15944
15945 oldoffice34_t *oldoffice34 = (oldoffice34_t *) hash_buf->esalt;
15946
15947 /**
15948 * parse line
15949 */
15950
15951 char *version_pos = input_buf + 11;
15952
15953 char *osalt_pos = strchr (version_pos, '*');
15954
15955 if (osalt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15956
15957 u32 version_len = osalt_pos - version_pos;
15958
15959 if (version_len != 1) return (PARSER_SALT_LENGTH);
15960
15961 osalt_pos++;
15962
15963 char *encryptedVerifier_pos = strchr (osalt_pos, '*');
15964
15965 if (encryptedVerifier_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15966
15967 u32 osalt_len = encryptedVerifier_pos - osalt_pos;
15968
15969 if (osalt_len != 32) return (PARSER_SALT_LENGTH);
15970
15971 encryptedVerifier_pos++;
15972
15973 char *encryptedVerifierHash_pos = strchr (encryptedVerifier_pos, '*');
15974
15975 if (encryptedVerifierHash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15976
15977 u32 encryptedVerifier_len = encryptedVerifierHash_pos - encryptedVerifier_pos;
15978
15979 if (encryptedVerifier_len != 32) return (PARSER_SALT_LENGTH);
15980
15981 encryptedVerifierHash_pos++;
15982
15983 char *rc4key_pos = strchr (encryptedVerifierHash_pos, ':');
15984
15985 if (rc4key_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
15986
15987 u32 encryptedVerifierHash_len = rc4key_pos - encryptedVerifierHash_pos;
15988
15989 if (encryptedVerifierHash_len != 40) return (PARSER_SALT_LENGTH);
15990
15991 rc4key_pos++;
15992
15993 u32 rc4key_len = input_len - 11 - version_len - 1 - osalt_len - 1 - encryptedVerifier_len - 1 - encryptedVerifierHash_len - 1;
15994
15995 if (rc4key_len != 10) return (PARSER_SALT_LENGTH);
15996
15997 const uint version = *version_pos - 0x30;
15998
15999 if (version != 3 && version != 4) return (PARSER_SALT_VALUE);
16000
16001 /**
16002 * esalt
16003 */
16004
16005 oldoffice34->version = version;
16006
16007 oldoffice34->encryptedVerifier[0] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 0]);
16008 oldoffice34->encryptedVerifier[1] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[ 8]);
16009 oldoffice34->encryptedVerifier[2] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[16]);
16010 oldoffice34->encryptedVerifier[3] = hex_to_u32 ((const u8 *) &encryptedVerifier_pos[24]);
16011
16012 oldoffice34->encryptedVerifier[0] = byte_swap_32 (oldoffice34->encryptedVerifier[0]);
16013 oldoffice34->encryptedVerifier[1] = byte_swap_32 (oldoffice34->encryptedVerifier[1]);
16014 oldoffice34->encryptedVerifier[2] = byte_swap_32 (oldoffice34->encryptedVerifier[2]);
16015 oldoffice34->encryptedVerifier[3] = byte_swap_32 (oldoffice34->encryptedVerifier[3]);
16016
16017 oldoffice34->encryptedVerifierHash[0] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 0]);
16018 oldoffice34->encryptedVerifierHash[1] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[ 8]);
16019 oldoffice34->encryptedVerifierHash[2] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[16]);
16020 oldoffice34->encryptedVerifierHash[3] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[24]);
16021 oldoffice34->encryptedVerifierHash[4] = hex_to_u32 ((const u8 *) &encryptedVerifierHash_pos[32]);
16022
16023 oldoffice34->encryptedVerifierHash[0] = byte_swap_32 (oldoffice34->encryptedVerifierHash[0]);
16024 oldoffice34->encryptedVerifierHash[1] = byte_swap_32 (oldoffice34->encryptedVerifierHash[1]);
16025 oldoffice34->encryptedVerifierHash[2] = byte_swap_32 (oldoffice34->encryptedVerifierHash[2]);
16026 oldoffice34->encryptedVerifierHash[3] = byte_swap_32 (oldoffice34->encryptedVerifierHash[3]);
16027 oldoffice34->encryptedVerifierHash[4] = byte_swap_32 (oldoffice34->encryptedVerifierHash[4]);
16028
16029 oldoffice34->rc4key[1] = 0;
16030 oldoffice34->rc4key[0] = 0;
16031
16032 oldoffice34->rc4key[0] |= hex_convert (rc4key_pos[0]) << 28;
16033 oldoffice34->rc4key[0] |= hex_convert (rc4key_pos[1]) << 24;
16034 oldoffice34->rc4key[0] |= hex_convert (rc4key_pos[2]) << 20;
16035 oldoffice34->rc4key[0] |= hex_convert (rc4key_pos[3]) << 16;
16036 oldoffice34->rc4key[0] |= hex_convert (rc4key_pos[4]) << 12;
16037 oldoffice34->rc4key[0] |= hex_convert (rc4key_pos[5]) << 8;
16038 oldoffice34->rc4key[0] |= hex_convert (rc4key_pos[6]) << 4;
16039 oldoffice34->rc4key[0] |= hex_convert (rc4key_pos[7]) << 0;
16040 oldoffice34->rc4key[1] |= hex_convert (rc4key_pos[8]) << 28;
16041 oldoffice34->rc4key[1] |= hex_convert (rc4key_pos[9]) << 24;
16042
16043 oldoffice34->rc4key[0] = byte_swap_32 (oldoffice34->rc4key[0]);
16044 oldoffice34->rc4key[1] = byte_swap_32 (oldoffice34->rc4key[1]);
16045
16046 /**
16047 * salt
16048 */
16049
16050 salt->salt_len = 16;
16051
16052 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &osalt_pos[ 0]);
16053 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &osalt_pos[ 8]);
16054 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &osalt_pos[16]);
16055 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &osalt_pos[24]);
16056
16057 // this is a workaround as office produces multiple documents with the same salt
16058
16059 salt->salt_len += 32;
16060
16061 salt->salt_buf[ 4] = oldoffice34->encryptedVerifier[0];
16062 salt->salt_buf[ 5] = oldoffice34->encryptedVerifier[1];
16063 salt->salt_buf[ 6] = oldoffice34->encryptedVerifier[2];
16064 salt->salt_buf[ 7] = oldoffice34->encryptedVerifier[3];
16065 salt->salt_buf[ 8] = oldoffice34->encryptedVerifierHash[0];
16066 salt->salt_buf[ 9] = oldoffice34->encryptedVerifierHash[1];
16067 salt->salt_buf[10] = oldoffice34->encryptedVerifierHash[2];
16068 salt->salt_buf[11] = oldoffice34->encryptedVerifierHash[3];
16069
16070 /**
16071 * digest
16072 */
16073
16074 digest[0] = oldoffice34->rc4key[0];
16075 digest[1] = oldoffice34->rc4key[1];
16076 digest[2] = 0;
16077 digest[3] = 0;
16078
16079 return (PARSER_OK);
16080 }
16081
16082 int radmin2_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
16083 {
16084 if ((input_len < DISPLAY_LEN_MIN_9900) || (input_len > DISPLAY_LEN_MAX_9900)) return (PARSER_GLOBAL_LENGTH);
16085
16086 u32 *digest = (u32 *) hash_buf->digest;
16087
16088 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
16089 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
16090 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
16091 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
16092
16093 digest[0] = byte_swap_32 (digest[0]);
16094 digest[1] = byte_swap_32 (digest[1]);
16095 digest[2] = byte_swap_32 (digest[2]);
16096 digest[3] = byte_swap_32 (digest[3]);
16097
16098 return (PARSER_OK);
16099 }
16100
16101 int djangosha1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
16102 {
16103 if ((input_len < DISPLAY_LEN_MIN_124) || (input_len > DISPLAY_LEN_MAX_124)) return (PARSER_GLOBAL_LENGTH);
16104
16105 if ((memcmp (SIGNATURE_DJANGOSHA1, input_buf, 5)) && (memcmp (SIGNATURE_DJANGOSHA1, input_buf, 5))) return (PARSER_SIGNATURE_UNMATCHED);
16106
16107 u32 *digest = (u32 *) hash_buf->digest;
16108
16109 salt_t *salt = hash_buf->salt;
16110
16111 char *signature_pos = input_buf;
16112
16113 char *salt_pos = strchr (signature_pos, '$');
16114
16115 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16116
16117 u32 signature_len = salt_pos - signature_pos;
16118
16119 if (signature_len != 4) return (PARSER_SIGNATURE_UNMATCHED);
16120
16121 salt_pos++;
16122
16123 char *hash_pos = strchr (salt_pos, '$');
16124
16125 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16126
16127 u32 salt_len = hash_pos - salt_pos;
16128
16129 if (salt_len > 32) return (PARSER_SALT_LENGTH);
16130
16131 hash_pos++;
16132
16133 u32 hash_len = input_len - signature_len - 1 - salt_len - 1;
16134
16135 if (hash_len != 40) return (PARSER_SALT_LENGTH);
16136
16137 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
16138 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
16139 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
16140 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
16141 digest[4] = hex_to_u32 ((const u8 *) &hash_pos[32]);
16142
16143 digest[0] -= SHA1M_A;
16144 digest[1] -= SHA1M_B;
16145 digest[2] -= SHA1M_C;
16146 digest[3] -= SHA1M_D;
16147 digest[4] -= SHA1M_E;
16148
16149 char *salt_buf_ptr = (char *) salt->salt_buf;
16150
16151 memcpy (salt_buf_ptr, salt_pos, salt_len);
16152
16153 salt->salt_len = salt_len;
16154
16155 return (PARSER_OK);
16156 }
16157
16158 int djangopbkdf2_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
16159 {
16160 if ((input_len < DISPLAY_LEN_MIN_10000) || (input_len > DISPLAY_LEN_MAX_10000)) return (PARSER_GLOBAL_LENGTH);
16161
16162 if (memcmp (SIGNATURE_DJANGOPBKDF2, input_buf, 14)) return (PARSER_SIGNATURE_UNMATCHED);
16163
16164 u32 *digest = (u32 *) hash_buf->digest;
16165
16166 salt_t *salt = hash_buf->salt;
16167
16168 pbkdf2_sha256_t *pbkdf2_sha256 = (pbkdf2_sha256_t *) hash_buf->esalt;
16169
16170 /**
16171 * parse line
16172 */
16173
16174 char *iter_pos = input_buf + 14;
16175
16176 const int iter = atoi (iter_pos);
16177
16178 if (iter < 1) return (PARSER_SALT_ITERATION);
16179
16180 salt->salt_iter = iter - 1;
16181
16182 char *salt_pos = strchr (iter_pos, '$');
16183
16184 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16185
16186 salt_pos++;
16187
16188 char *hash_pos = strchr (salt_pos, '$');
16189
16190 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16191
16192 const uint salt_len = hash_pos - salt_pos;
16193
16194 hash_pos++;
16195
16196 char *salt_buf_ptr = (char *) pbkdf2_sha256->salt_buf;
16197
16198 memcpy (salt_buf_ptr, salt_pos, salt_len);
16199
16200 salt->salt_len = salt_len;
16201
16202 salt_buf_ptr[salt_len + 3] = 0x01;
16203 salt_buf_ptr[salt_len + 4] = 0x80;
16204
16205 // add some stuff to normal salt to make sorted happy
16206
16207 salt->salt_buf[0] = pbkdf2_sha256->salt_buf[0];
16208 salt->salt_buf[1] = pbkdf2_sha256->salt_buf[1];
16209 salt->salt_buf[2] = pbkdf2_sha256->salt_buf[2];
16210 salt->salt_buf[3] = pbkdf2_sha256->salt_buf[3];
16211 salt->salt_buf[4] = salt->salt_iter;
16212
16213 // base64 decode hash
16214
16215 u8 tmp_buf[100] = { 0 };
16216
16217 uint hash_len = input_len - (hash_pos - input_buf);
16218
16219 if (hash_len != 44) return (PARSER_HASH_LENGTH);
16220
16221 base64_decode (base64_to_int, (const u8 *) hash_pos, hash_len, tmp_buf);
16222
16223 memcpy (digest, tmp_buf, 32);
16224
16225 digest[0] = byte_swap_32 (digest[0]);
16226 digest[1] = byte_swap_32 (digest[1]);
16227 digest[2] = byte_swap_32 (digest[2]);
16228 digest[3] = byte_swap_32 (digest[3]);
16229 digest[4] = byte_swap_32 (digest[4]);
16230 digest[5] = byte_swap_32 (digest[5]);
16231 digest[6] = byte_swap_32 (digest[6]);
16232 digest[7] = byte_swap_32 (digest[7]);
16233
16234 return (PARSER_OK);
16235 }
16236
16237 int siphash_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
16238 {
16239 if ((input_len < DISPLAY_LEN_MIN_10100) || (input_len > DISPLAY_LEN_MAX_10100)) return (PARSER_GLOBAL_LENGTH);
16240
16241 u32 *digest = (u32 *) hash_buf->digest;
16242
16243 salt_t *salt = hash_buf->salt;
16244
16245 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
16246 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
16247 digest[2] = 0;
16248 digest[3] = 0;
16249
16250 digest[0] = byte_swap_32 (digest[0]);
16251 digest[1] = byte_swap_32 (digest[1]);
16252
16253 if (input_buf[16] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
16254 if (input_buf[18] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
16255 if (input_buf[20] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
16256
16257 char iter_c = input_buf[17];
16258 char iter_d = input_buf[19];
16259
16260 // atm only defaults, let's see if there's more request
16261 if (iter_c != '2') return (PARSER_SALT_ITERATION);
16262 if (iter_d != '4') return (PARSER_SALT_ITERATION);
16263
16264 char *salt_buf = input_buf + 16 + 1 + 1 + 1 + 1 + 1;
16265
16266 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &salt_buf[ 0]);
16267 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &salt_buf[ 8]);
16268 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &salt_buf[16]);
16269 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &salt_buf[24]);
16270
16271 salt->salt_buf[0] = byte_swap_32 (salt->salt_buf[0]);
16272 salt->salt_buf[1] = byte_swap_32 (salt->salt_buf[1]);
16273 salt->salt_buf[2] = byte_swap_32 (salt->salt_buf[2]);
16274 salt->salt_buf[3] = byte_swap_32 (salt->salt_buf[3]);
16275
16276 salt->salt_len = 16;
16277
16278 return (PARSER_OK);
16279 }
16280
16281 int crammd5_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
16282 {
16283 if ((input_len < DISPLAY_LEN_MIN_10200) || (input_len > DISPLAY_LEN_MAX_10200)) return (PARSER_GLOBAL_LENGTH);
16284
16285 if (memcmp (SIGNATURE_CRAM_MD5, input_buf, 10)) return (PARSER_SIGNATURE_UNMATCHED);
16286
16287 u32 *digest = (u32 *) hash_buf->digest;
16288
16289 cram_md5_t *cram_md5 = (cram_md5_t *) hash_buf->esalt;
16290
16291 salt_t *salt = hash_buf->salt;
16292
16293 char *salt_pos = input_buf + 10;
16294
16295 char *hash_pos = strchr (salt_pos, '$');
16296
16297 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16298
16299 uint salt_len = hash_pos - salt_pos;
16300
16301 hash_pos++;
16302
16303 uint hash_len = input_len - 10 - salt_len - 1;
16304
16305 // base64 decode salt
16306
16307 if (salt_len > 133) return (PARSER_SALT_LENGTH);
16308
16309 u8 tmp_buf[100] = { 0 };
16310
16311 salt_len = base64_decode (base64_to_int, (const u8 *) salt_pos, salt_len, tmp_buf);
16312
16313 if (salt_len > 55) return (PARSER_SALT_LENGTH);
16314
16315 tmp_buf[salt_len] = 0x80;
16316
16317 memcpy (&salt->salt_buf, tmp_buf, salt_len + 1);
16318
16319 salt->salt_len = salt_len;
16320
16321 // base64 decode hash
16322
16323 if (hash_len > 133) return (PARSER_HASH_LENGTH);
16324
16325 memset (tmp_buf, 0, sizeof (tmp_buf));
16326
16327 hash_len = base64_decode (base64_to_int, (const u8 *) hash_pos, hash_len, tmp_buf);
16328
16329 if (hash_len < 32 + 1) return (PARSER_SALT_LENGTH);
16330
16331 uint user_len = hash_len - 32;
16332
16333 const u8 *tmp_hash = tmp_buf + user_len;
16334
16335 user_len--; // skip the trailing space
16336
16337 digest[0] = hex_to_u32 (&tmp_hash[ 0]);
16338 digest[1] = hex_to_u32 (&tmp_hash[ 8]);
16339 digest[2] = hex_to_u32 (&tmp_hash[16]);
16340 digest[3] = hex_to_u32 (&tmp_hash[24]);
16341
16342 digest[0] = byte_swap_32 (digest[0]);
16343 digest[1] = byte_swap_32 (digest[1]);
16344 digest[2] = byte_swap_32 (digest[2]);
16345 digest[3] = byte_swap_32 (digest[3]);
16346
16347 // store username for host only (output hash if cracked)
16348
16349 memset (cram_md5->user, 0, sizeof (cram_md5->user));
16350 memcpy (cram_md5->user, tmp_buf, user_len);
16351
16352 return (PARSER_OK);
16353 }
16354
16355 int saph_sha1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
16356 {
16357 if ((input_len < DISPLAY_LEN_MIN_10300) || (input_len > DISPLAY_LEN_MAX_10300)) return (PARSER_GLOBAL_LENGTH);
16358
16359 if (memcmp (SIGNATURE_SAPH_SHA1, input_buf, 10)) return (PARSER_SIGNATURE_UNMATCHED);
16360
16361 u32 *digest = (u32 *) hash_buf->digest;
16362
16363 salt_t *salt = hash_buf->salt;
16364
16365 char *iter_pos = input_buf + 10;
16366
16367 u32 iter = atoi (iter_pos);
16368
16369 if (iter < 1)
16370 {
16371 return (PARSER_SALT_ITERATION);
16372 }
16373
16374 iter--; // first iteration is special
16375
16376 salt->salt_iter = iter;
16377
16378 char *base64_pos = strchr (iter_pos, '}');
16379
16380 if (base64_pos == NULL)
16381 {
16382 return (PARSER_SIGNATURE_UNMATCHED);
16383 }
16384
16385 base64_pos++;
16386
16387 // base64 decode salt
16388
16389 u32 base64_len = input_len - (base64_pos - input_buf);
16390
16391 u8 tmp_buf[100] = { 0 };
16392
16393 u32 decoded_len = base64_decode (base64_to_int, (const u8 *) base64_pos, base64_len, tmp_buf);
16394
16395 if (decoded_len < 24)
16396 {
16397 return (PARSER_SALT_LENGTH);
16398 }
16399
16400 // copy the salt
16401
16402 uint salt_len = decoded_len - 20;
16403
16404 if (salt_len < 4) return (PARSER_SALT_LENGTH);
16405 if (salt_len > 16) return (PARSER_SALT_LENGTH);
16406
16407 memcpy (&salt->salt_buf, tmp_buf + 20, salt_len);
16408
16409 salt->salt_len = salt_len;
16410
16411 // set digest
16412
16413 u32 *digest_ptr = (u32*) tmp_buf;
16414
16415 digest[0] = byte_swap_32 (digest_ptr[0]);
16416 digest[1] = byte_swap_32 (digest_ptr[1]);
16417 digest[2] = byte_swap_32 (digest_ptr[2]);
16418 digest[3] = byte_swap_32 (digest_ptr[3]);
16419 digest[4] = byte_swap_32 (digest_ptr[4]);
16420
16421 return (PARSER_OK);
16422 }
16423
16424 int redmine_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
16425 {
16426 if ((input_len < DISPLAY_LEN_MIN_7600) || (input_len > DISPLAY_LEN_MAX_7600)) return (PARSER_GLOBAL_LENGTH);
16427
16428 u32 *digest = (u32 *) hash_buf->digest;
16429
16430 salt_t *salt = hash_buf->salt;
16431
16432 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
16433 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
16434 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
16435 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
16436 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
16437
16438 if (input_buf[40] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
16439
16440 uint salt_len = input_len - 40 - 1;
16441
16442 char *salt_buf = input_buf + 40 + 1;
16443
16444 char *salt_buf_ptr = (char *) salt->salt_buf;
16445
16446 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
16447
16448 if (salt_len != 32) return (PARSER_SALT_LENGTH);
16449
16450 salt->salt_len = salt_len;
16451
16452 return (PARSER_OK);
16453 }
16454
16455 int pdf11_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
16456 {
16457 if ((input_len < DISPLAY_LEN_MIN_10400) || (input_len > DISPLAY_LEN_MAX_10400)) return (PARSER_GLOBAL_LENGTH);
16458
16459 if ((memcmp (SIGNATURE_PDF, input_buf, 5)) && (memcmp (SIGNATURE_PDF, input_buf, 5))) return (PARSER_SIGNATURE_UNMATCHED);
16460
16461 u32 *digest = (u32 *) hash_buf->digest;
16462
16463 salt_t *salt = hash_buf->salt;
16464
16465 pdf_t *pdf = (pdf_t *) hash_buf->esalt;
16466
16467 /**
16468 * parse line
16469 */
16470
16471 char *V_pos = input_buf + 5;
16472
16473 char *R_pos = strchr (V_pos, '*');
16474
16475 if (R_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16476
16477 u32 V_len = R_pos - V_pos;
16478
16479 R_pos++;
16480
16481 char *bits_pos = strchr (R_pos, '*');
16482
16483 if (bits_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16484
16485 u32 R_len = bits_pos - R_pos;
16486
16487 bits_pos++;
16488
16489 char *P_pos = strchr (bits_pos, '*');
16490
16491 if (P_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16492
16493 u32 bits_len = P_pos - bits_pos;
16494
16495 P_pos++;
16496
16497 char *enc_md_pos = strchr (P_pos, '*');
16498
16499 if (enc_md_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16500
16501 u32 P_len = enc_md_pos - P_pos;
16502
16503 enc_md_pos++;
16504
16505 char *id_len_pos = strchr (enc_md_pos, '*');
16506
16507 if (id_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16508
16509 u32 enc_md_len = id_len_pos - enc_md_pos;
16510
16511 id_len_pos++;
16512
16513 char *id_buf_pos = strchr (id_len_pos, '*');
16514
16515 if (id_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16516
16517 u32 id_len_len = id_buf_pos - id_len_pos;
16518
16519 id_buf_pos++;
16520
16521 char *u_len_pos = strchr (id_buf_pos, '*');
16522
16523 if (u_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16524
16525 u32 id_buf_len = u_len_pos - id_buf_pos;
16526
16527 if (id_buf_len != 32) return (PARSER_SALT_LENGTH);
16528
16529 u_len_pos++;
16530
16531 char *u_buf_pos = strchr (u_len_pos, '*');
16532
16533 if (u_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16534
16535 u32 u_len_len = u_buf_pos - u_len_pos;
16536
16537 u_buf_pos++;
16538
16539 char *o_len_pos = strchr (u_buf_pos, '*');
16540
16541 if (o_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16542
16543 u32 u_buf_len = o_len_pos - u_buf_pos;
16544
16545 if (u_buf_len != 64) return (PARSER_SALT_LENGTH);
16546
16547 o_len_pos++;
16548
16549 char *o_buf_pos = strchr (o_len_pos, '*');
16550
16551 if (o_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16552
16553 u32 o_len_len = o_buf_pos - o_len_pos;
16554
16555 o_buf_pos++;
16556
16557 u32 o_buf_len = input_len - 5 - V_len - 1 - R_len - 1 - bits_len - 1 - P_len - 1 - enc_md_len - 1 - id_len_len - 1 - id_buf_len - 1 - u_len_len - 1 - u_buf_len - 1 - o_len_len - 1;
16558
16559 if (o_buf_len != 64) return (PARSER_SALT_LENGTH);
16560
16561 // validate data
16562
16563 const int V = atoi (V_pos);
16564 const int R = atoi (R_pos);
16565 const int P = atoi (P_pos);
16566
16567 if (V != 1) return (PARSER_SALT_VALUE);
16568 if (R != 2) return (PARSER_SALT_VALUE);
16569
16570 const int enc_md = atoi (enc_md_pos);
16571
16572 if ((enc_md != 0) && (enc_md != 1)) return (PARSER_SALT_VALUE);
16573
16574 const int id_len = atoi (id_len_pos);
16575 const int u_len = atoi (u_len_pos);
16576 const int o_len = atoi (o_len_pos);
16577
16578 if (id_len != 16) return (PARSER_SALT_VALUE);
16579 if (u_len != 32) return (PARSER_SALT_VALUE);
16580 if (o_len != 32) return (PARSER_SALT_VALUE);
16581
16582 const int bits = atoi (bits_pos);
16583
16584 if (bits != 40) return (PARSER_SALT_VALUE);
16585
16586 // copy data to esalt
16587
16588 pdf->V = V;
16589 pdf->R = R;
16590 pdf->P = P;
16591
16592 pdf->enc_md = enc_md;
16593
16594 pdf->id_buf[0] = hex_to_u32 ((const u8 *) &id_buf_pos[ 0]);
16595 pdf->id_buf[1] = hex_to_u32 ((const u8 *) &id_buf_pos[ 8]);
16596 pdf->id_buf[2] = hex_to_u32 ((const u8 *) &id_buf_pos[16]);
16597 pdf->id_buf[3] = hex_to_u32 ((const u8 *) &id_buf_pos[24]);
16598 pdf->id_len = id_len;
16599
16600 pdf->u_buf[0] = hex_to_u32 ((const u8 *) &u_buf_pos[ 0]);
16601 pdf->u_buf[1] = hex_to_u32 ((const u8 *) &u_buf_pos[ 8]);
16602 pdf->u_buf[2] = hex_to_u32 ((const u8 *) &u_buf_pos[16]);
16603 pdf->u_buf[3] = hex_to_u32 ((const u8 *) &u_buf_pos[24]);
16604 pdf->u_buf[4] = hex_to_u32 ((const u8 *) &u_buf_pos[32]);
16605 pdf->u_buf[5] = hex_to_u32 ((const u8 *) &u_buf_pos[40]);
16606 pdf->u_buf[6] = hex_to_u32 ((const u8 *) &u_buf_pos[48]);
16607 pdf->u_buf[7] = hex_to_u32 ((const u8 *) &u_buf_pos[56]);
16608 pdf->u_len = u_len;
16609
16610 pdf->o_buf[0] = hex_to_u32 ((const u8 *) &o_buf_pos[ 0]);
16611 pdf->o_buf[1] = hex_to_u32 ((const u8 *) &o_buf_pos[ 8]);
16612 pdf->o_buf[2] = hex_to_u32 ((const u8 *) &o_buf_pos[16]);
16613 pdf->o_buf[3] = hex_to_u32 ((const u8 *) &o_buf_pos[24]);
16614 pdf->o_buf[4] = hex_to_u32 ((const u8 *) &o_buf_pos[32]);
16615 pdf->o_buf[5] = hex_to_u32 ((const u8 *) &o_buf_pos[40]);
16616 pdf->o_buf[6] = hex_to_u32 ((const u8 *) &o_buf_pos[48]);
16617 pdf->o_buf[7] = hex_to_u32 ((const u8 *) &o_buf_pos[56]);
16618 pdf->o_len = o_len;
16619
16620 pdf->id_buf[0] = byte_swap_32 (pdf->id_buf[0]);
16621 pdf->id_buf[1] = byte_swap_32 (pdf->id_buf[1]);
16622 pdf->id_buf[2] = byte_swap_32 (pdf->id_buf[2]);
16623 pdf->id_buf[3] = byte_swap_32 (pdf->id_buf[3]);
16624
16625 pdf->u_buf[0] = byte_swap_32 (pdf->u_buf[0]);
16626 pdf->u_buf[1] = byte_swap_32 (pdf->u_buf[1]);
16627 pdf->u_buf[2] = byte_swap_32 (pdf->u_buf[2]);
16628 pdf->u_buf[3] = byte_swap_32 (pdf->u_buf[3]);
16629 pdf->u_buf[4] = byte_swap_32 (pdf->u_buf[4]);
16630 pdf->u_buf[5] = byte_swap_32 (pdf->u_buf[5]);
16631 pdf->u_buf[6] = byte_swap_32 (pdf->u_buf[6]);
16632 pdf->u_buf[7] = byte_swap_32 (pdf->u_buf[7]);
16633
16634 pdf->o_buf[0] = byte_swap_32 (pdf->o_buf[0]);
16635 pdf->o_buf[1] = byte_swap_32 (pdf->o_buf[1]);
16636 pdf->o_buf[2] = byte_swap_32 (pdf->o_buf[2]);
16637 pdf->o_buf[3] = byte_swap_32 (pdf->o_buf[3]);
16638 pdf->o_buf[4] = byte_swap_32 (pdf->o_buf[4]);
16639 pdf->o_buf[5] = byte_swap_32 (pdf->o_buf[5]);
16640 pdf->o_buf[6] = byte_swap_32 (pdf->o_buf[6]);
16641 pdf->o_buf[7] = byte_swap_32 (pdf->o_buf[7]);
16642
16643 // we use ID for salt, maybe needs to change, we will see...
16644
16645 salt->salt_buf[0] = pdf->id_buf[0];
16646 salt->salt_buf[1] = pdf->id_buf[1];
16647 salt->salt_buf[2] = pdf->id_buf[2];
16648 salt->salt_buf[3] = pdf->id_buf[3];
16649 salt->salt_len = pdf->id_len;
16650
16651 digest[0] = pdf->u_buf[0];
16652 digest[1] = pdf->u_buf[1];
16653 digest[2] = pdf->u_buf[2];
16654 digest[3] = pdf->u_buf[3];
16655
16656 return (PARSER_OK);
16657 }
16658
16659 int pdf11cm1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
16660 {
16661 return pdf11_parse_hash (input_buf, input_len, hash_buf);
16662 }
16663
16664 int pdf11cm2_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
16665 {
16666 if ((input_len < DISPLAY_LEN_MIN_10420) || (input_len > DISPLAY_LEN_MAX_10420)) return (PARSER_GLOBAL_LENGTH);
16667
16668 if ((memcmp (SIGNATURE_PDF, input_buf, 5)) && (memcmp (SIGNATURE_PDF, input_buf, 5))) return (PARSER_SIGNATURE_UNMATCHED);
16669
16670 u32 *digest = (u32 *) hash_buf->digest;
16671
16672 salt_t *salt = hash_buf->salt;
16673
16674 pdf_t *pdf = (pdf_t *) hash_buf->esalt;
16675
16676 /**
16677 * parse line
16678 */
16679
16680 char *V_pos = input_buf + 5;
16681
16682 char *R_pos = strchr (V_pos, '*');
16683
16684 if (R_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16685
16686 u32 V_len = R_pos - V_pos;
16687
16688 R_pos++;
16689
16690 char *bits_pos = strchr (R_pos, '*');
16691
16692 if (bits_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16693
16694 u32 R_len = bits_pos - R_pos;
16695
16696 bits_pos++;
16697
16698 char *P_pos = strchr (bits_pos, '*');
16699
16700 if (P_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16701
16702 u32 bits_len = P_pos - bits_pos;
16703
16704 P_pos++;
16705
16706 char *enc_md_pos = strchr (P_pos, '*');
16707
16708 if (enc_md_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16709
16710 u32 P_len = enc_md_pos - P_pos;
16711
16712 enc_md_pos++;
16713
16714 char *id_len_pos = strchr (enc_md_pos, '*');
16715
16716 if (id_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16717
16718 u32 enc_md_len = id_len_pos - enc_md_pos;
16719
16720 id_len_pos++;
16721
16722 char *id_buf_pos = strchr (id_len_pos, '*');
16723
16724 if (id_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16725
16726 u32 id_len_len = id_buf_pos - id_len_pos;
16727
16728 id_buf_pos++;
16729
16730 char *u_len_pos = strchr (id_buf_pos, '*');
16731
16732 if (u_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16733
16734 u32 id_buf_len = u_len_pos - id_buf_pos;
16735
16736 if (id_buf_len != 32) return (PARSER_SALT_LENGTH);
16737
16738 u_len_pos++;
16739
16740 char *u_buf_pos = strchr (u_len_pos, '*');
16741
16742 if (u_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16743
16744 u32 u_len_len = u_buf_pos - u_len_pos;
16745
16746 u_buf_pos++;
16747
16748 char *o_len_pos = strchr (u_buf_pos, '*');
16749
16750 if (o_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16751
16752 u32 u_buf_len = o_len_pos - u_buf_pos;
16753
16754 if (u_buf_len != 64) return (PARSER_SALT_LENGTH);
16755
16756 o_len_pos++;
16757
16758 char *o_buf_pos = strchr (o_len_pos, '*');
16759
16760 if (o_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16761
16762 u32 o_len_len = o_buf_pos - o_len_pos;
16763
16764 o_buf_pos++;
16765
16766 char *rc4key_pos = strchr (o_buf_pos, ':');
16767
16768 if (rc4key_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16769
16770 u32 o_buf_len = rc4key_pos - o_buf_pos;
16771
16772 if (o_buf_len != 64) return (PARSER_SALT_LENGTH);
16773
16774 rc4key_pos++;
16775
16776 u32 rc4key_len = input_len - 5 - V_len - 1 - R_len - 1 - bits_len - 1 - P_len - 1 - enc_md_len - 1 - id_len_len - 1 - id_buf_len - 1 - u_len_len - 1 - u_buf_len - 1 - o_len_len - 1 - o_buf_len - 1;
16777
16778 if (rc4key_len != 10) return (PARSER_SALT_LENGTH);
16779
16780 // validate data
16781
16782 const int V = atoi (V_pos);
16783 const int R = atoi (R_pos);
16784 const int P = atoi (P_pos);
16785
16786 if (V != 1) return (PARSER_SALT_VALUE);
16787 if (R != 2) return (PARSER_SALT_VALUE);
16788
16789 const int enc_md = atoi (enc_md_pos);
16790
16791 if ((enc_md != 0) && (enc_md != 1)) return (PARSER_SALT_VALUE);
16792
16793 const int id_len = atoi (id_len_pos);
16794 const int u_len = atoi (u_len_pos);
16795 const int o_len = atoi (o_len_pos);
16796
16797 if (id_len != 16) return (PARSER_SALT_VALUE);
16798 if (u_len != 32) return (PARSER_SALT_VALUE);
16799 if (o_len != 32) return (PARSER_SALT_VALUE);
16800
16801 const int bits = atoi (bits_pos);
16802
16803 if (bits != 40) return (PARSER_SALT_VALUE);
16804
16805 // copy data to esalt
16806
16807 pdf->V = V;
16808 pdf->R = R;
16809 pdf->P = P;
16810
16811 pdf->enc_md = enc_md;
16812
16813 pdf->id_buf[0] = hex_to_u32 ((const u8 *) &id_buf_pos[ 0]);
16814 pdf->id_buf[1] = hex_to_u32 ((const u8 *) &id_buf_pos[ 8]);
16815 pdf->id_buf[2] = hex_to_u32 ((const u8 *) &id_buf_pos[16]);
16816 pdf->id_buf[3] = hex_to_u32 ((const u8 *) &id_buf_pos[24]);
16817 pdf->id_len = id_len;
16818
16819 pdf->u_buf[0] = hex_to_u32 ((const u8 *) &u_buf_pos[ 0]);
16820 pdf->u_buf[1] = hex_to_u32 ((const u8 *) &u_buf_pos[ 8]);
16821 pdf->u_buf[2] = hex_to_u32 ((const u8 *) &u_buf_pos[16]);
16822 pdf->u_buf[3] = hex_to_u32 ((const u8 *) &u_buf_pos[24]);
16823 pdf->u_buf[4] = hex_to_u32 ((const u8 *) &u_buf_pos[32]);
16824 pdf->u_buf[5] = hex_to_u32 ((const u8 *) &u_buf_pos[40]);
16825 pdf->u_buf[6] = hex_to_u32 ((const u8 *) &u_buf_pos[48]);
16826 pdf->u_buf[7] = hex_to_u32 ((const u8 *) &u_buf_pos[56]);
16827 pdf->u_len = u_len;
16828
16829 pdf->o_buf[0] = hex_to_u32 ((const u8 *) &o_buf_pos[ 0]);
16830 pdf->o_buf[1] = hex_to_u32 ((const u8 *) &o_buf_pos[ 8]);
16831 pdf->o_buf[2] = hex_to_u32 ((const u8 *) &o_buf_pos[16]);
16832 pdf->o_buf[3] = hex_to_u32 ((const u8 *) &o_buf_pos[24]);
16833 pdf->o_buf[4] = hex_to_u32 ((const u8 *) &o_buf_pos[32]);
16834 pdf->o_buf[5] = hex_to_u32 ((const u8 *) &o_buf_pos[40]);
16835 pdf->o_buf[6] = hex_to_u32 ((const u8 *) &o_buf_pos[48]);
16836 pdf->o_buf[7] = hex_to_u32 ((const u8 *) &o_buf_pos[56]);
16837 pdf->o_len = o_len;
16838
16839 pdf->id_buf[0] = byte_swap_32 (pdf->id_buf[0]);
16840 pdf->id_buf[1] = byte_swap_32 (pdf->id_buf[1]);
16841 pdf->id_buf[2] = byte_swap_32 (pdf->id_buf[2]);
16842 pdf->id_buf[3] = byte_swap_32 (pdf->id_buf[3]);
16843
16844 pdf->u_buf[0] = byte_swap_32 (pdf->u_buf[0]);
16845 pdf->u_buf[1] = byte_swap_32 (pdf->u_buf[1]);
16846 pdf->u_buf[2] = byte_swap_32 (pdf->u_buf[2]);
16847 pdf->u_buf[3] = byte_swap_32 (pdf->u_buf[3]);
16848 pdf->u_buf[4] = byte_swap_32 (pdf->u_buf[4]);
16849 pdf->u_buf[5] = byte_swap_32 (pdf->u_buf[5]);
16850 pdf->u_buf[6] = byte_swap_32 (pdf->u_buf[6]);
16851 pdf->u_buf[7] = byte_swap_32 (pdf->u_buf[7]);
16852
16853 pdf->o_buf[0] = byte_swap_32 (pdf->o_buf[0]);
16854 pdf->o_buf[1] = byte_swap_32 (pdf->o_buf[1]);
16855 pdf->o_buf[2] = byte_swap_32 (pdf->o_buf[2]);
16856 pdf->o_buf[3] = byte_swap_32 (pdf->o_buf[3]);
16857 pdf->o_buf[4] = byte_swap_32 (pdf->o_buf[4]);
16858 pdf->o_buf[5] = byte_swap_32 (pdf->o_buf[5]);
16859 pdf->o_buf[6] = byte_swap_32 (pdf->o_buf[6]);
16860 pdf->o_buf[7] = byte_swap_32 (pdf->o_buf[7]);
16861
16862 pdf->rc4key[1] = 0;
16863 pdf->rc4key[0] = 0;
16864
16865 pdf->rc4key[0] |= hex_convert (rc4key_pos[0]) << 28;
16866 pdf->rc4key[0] |= hex_convert (rc4key_pos[1]) << 24;
16867 pdf->rc4key[0] |= hex_convert (rc4key_pos[2]) << 20;
16868 pdf->rc4key[0] |= hex_convert (rc4key_pos[3]) << 16;
16869 pdf->rc4key[0] |= hex_convert (rc4key_pos[4]) << 12;
16870 pdf->rc4key[0] |= hex_convert (rc4key_pos[5]) << 8;
16871 pdf->rc4key[0] |= hex_convert (rc4key_pos[6]) << 4;
16872 pdf->rc4key[0] |= hex_convert (rc4key_pos[7]) << 0;
16873 pdf->rc4key[1] |= hex_convert (rc4key_pos[8]) << 28;
16874 pdf->rc4key[1] |= hex_convert (rc4key_pos[9]) << 24;
16875
16876 pdf->rc4key[0] = byte_swap_32 (pdf->rc4key[0]);
16877 pdf->rc4key[1] = byte_swap_32 (pdf->rc4key[1]);
16878
16879 // we use ID for salt, maybe needs to change, we will see...
16880
16881 salt->salt_buf[0] = pdf->id_buf[0];
16882 salt->salt_buf[1] = pdf->id_buf[1];
16883 salt->salt_buf[2] = pdf->id_buf[2];
16884 salt->salt_buf[3] = pdf->id_buf[3];
16885 salt->salt_buf[4] = pdf->u_buf[0];
16886 salt->salt_buf[5] = pdf->u_buf[1];
16887 salt->salt_buf[6] = pdf->o_buf[0];
16888 salt->salt_buf[7] = pdf->o_buf[1];
16889 salt->salt_len = pdf->id_len + 16;
16890
16891 digest[0] = pdf->rc4key[0];
16892 digest[1] = pdf->rc4key[1];
16893 digest[2] = 0;
16894 digest[3] = 0;
16895
16896 return (PARSER_OK);
16897 }
16898
16899 int pdf14_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
16900 {
16901 if ((input_len < DISPLAY_LEN_MIN_10500) || (input_len > DISPLAY_LEN_MAX_10500)) return (PARSER_GLOBAL_LENGTH);
16902
16903 if ((memcmp (SIGNATURE_PDF, input_buf, 5)) && (memcmp (SIGNATURE_PDF, input_buf, 5))) return (PARSER_SIGNATURE_UNMATCHED);
16904
16905 u32 *digest = (u32 *) hash_buf->digest;
16906
16907 salt_t *salt = hash_buf->salt;
16908
16909 pdf_t *pdf = (pdf_t *) hash_buf->esalt;
16910
16911 /**
16912 * parse line
16913 */
16914
16915 char *V_pos = input_buf + 5;
16916
16917 char *R_pos = strchr (V_pos, '*');
16918
16919 if (R_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16920
16921 u32 V_len = R_pos - V_pos;
16922
16923 R_pos++;
16924
16925 char *bits_pos = strchr (R_pos, '*');
16926
16927 if (bits_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16928
16929 u32 R_len = bits_pos - R_pos;
16930
16931 bits_pos++;
16932
16933 char *P_pos = strchr (bits_pos, '*');
16934
16935 if (P_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16936
16937 u32 bits_len = P_pos - bits_pos;
16938
16939 P_pos++;
16940
16941 char *enc_md_pos = strchr (P_pos, '*');
16942
16943 if (enc_md_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16944
16945 u32 P_len = enc_md_pos - P_pos;
16946
16947 enc_md_pos++;
16948
16949 char *id_len_pos = strchr (enc_md_pos, '*');
16950
16951 if (id_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16952
16953 u32 enc_md_len = id_len_pos - enc_md_pos;
16954
16955 id_len_pos++;
16956
16957 char *id_buf_pos = strchr (id_len_pos, '*');
16958
16959 if (id_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16960
16961 u32 id_len_len = id_buf_pos - id_len_pos;
16962
16963 id_buf_pos++;
16964
16965 char *u_len_pos = strchr (id_buf_pos, '*');
16966
16967 if (u_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16968
16969 u32 id_buf_len = u_len_pos - id_buf_pos;
16970
16971 if ((id_buf_len != 32) && (id_buf_len != 64)) return (PARSER_SALT_LENGTH);
16972
16973 u_len_pos++;
16974
16975 char *u_buf_pos = strchr (u_len_pos, '*');
16976
16977 if (u_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16978
16979 u32 u_len_len = u_buf_pos - u_len_pos;
16980
16981 u_buf_pos++;
16982
16983 char *o_len_pos = strchr (u_buf_pos, '*');
16984
16985 if (o_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16986
16987 u32 u_buf_len = o_len_pos - u_buf_pos;
16988
16989 if (u_buf_len != 64) return (PARSER_SALT_LENGTH);
16990
16991 o_len_pos++;
16992
16993 char *o_buf_pos = strchr (o_len_pos, '*');
16994
16995 if (o_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
16996
16997 u32 o_len_len = o_buf_pos - o_len_pos;
16998
16999 o_buf_pos++;
17000
17001 u32 o_buf_len = input_len - 5 - V_len - 1 - R_len - 1 - bits_len - 1 - P_len - 1 - enc_md_len - 1 - id_len_len - 1 - id_buf_len - 1 - u_len_len - 1 - u_buf_len - 1 - o_len_len - 1;
17002
17003 if (o_buf_len != 64) return (PARSER_SALT_LENGTH);
17004
17005 // validate data
17006
17007 const int V = atoi (V_pos);
17008 const int R = atoi (R_pos);
17009 const int P = atoi (P_pos);
17010
17011 int vr_ok = 0;
17012
17013 if ((V == 2) && (R == 3)) vr_ok = 1;
17014 if ((V == 4) && (R == 4)) vr_ok = 1;
17015
17016 if (vr_ok == 0) return (PARSER_SALT_VALUE);
17017
17018 const int id_len = atoi (id_len_pos);
17019 const int u_len = atoi (u_len_pos);
17020 const int o_len = atoi (o_len_pos);
17021
17022 if ((id_len != 16) && (id_len != 32)) return (PARSER_SALT_VALUE);
17023
17024 if (u_len != 32) return (PARSER_SALT_VALUE);
17025 if (o_len != 32) return (PARSER_SALT_VALUE);
17026
17027 const int bits = atoi (bits_pos);
17028
17029 if (bits != 128) return (PARSER_SALT_VALUE);
17030
17031 int enc_md = 1;
17032
17033 if (R >= 4)
17034 {
17035 enc_md = atoi (enc_md_pos);
17036 }
17037
17038 // copy data to esalt
17039
17040 pdf->V = V;
17041 pdf->R = R;
17042 pdf->P = P;
17043
17044 pdf->enc_md = enc_md;
17045
17046 pdf->id_buf[0] = hex_to_u32 ((const u8 *) &id_buf_pos[ 0]);
17047 pdf->id_buf[1] = hex_to_u32 ((const u8 *) &id_buf_pos[ 8]);
17048 pdf->id_buf[2] = hex_to_u32 ((const u8 *) &id_buf_pos[16]);
17049 pdf->id_buf[3] = hex_to_u32 ((const u8 *) &id_buf_pos[24]);
17050
17051 if (id_len == 32)
17052 {
17053 pdf->id_buf[4] = hex_to_u32 ((const u8 *) &id_buf_pos[32]);
17054 pdf->id_buf[5] = hex_to_u32 ((const u8 *) &id_buf_pos[40]);
17055 pdf->id_buf[6] = hex_to_u32 ((const u8 *) &id_buf_pos[48]);
17056 pdf->id_buf[7] = hex_to_u32 ((const u8 *) &id_buf_pos[56]);
17057 }
17058
17059 pdf->id_len = id_len;
17060
17061 pdf->u_buf[0] = hex_to_u32 ((const u8 *) &u_buf_pos[ 0]);
17062 pdf->u_buf[1] = hex_to_u32 ((const u8 *) &u_buf_pos[ 8]);
17063 pdf->u_buf[2] = hex_to_u32 ((const u8 *) &u_buf_pos[16]);
17064 pdf->u_buf[3] = hex_to_u32 ((const u8 *) &u_buf_pos[24]);
17065 pdf->u_buf[4] = hex_to_u32 ((const u8 *) &u_buf_pos[32]);
17066 pdf->u_buf[5] = hex_to_u32 ((const u8 *) &u_buf_pos[40]);
17067 pdf->u_buf[6] = hex_to_u32 ((const u8 *) &u_buf_pos[48]);
17068 pdf->u_buf[7] = hex_to_u32 ((const u8 *) &u_buf_pos[56]);
17069 pdf->u_len = u_len;
17070
17071 pdf->o_buf[0] = hex_to_u32 ((const u8 *) &o_buf_pos[ 0]);
17072 pdf->o_buf[1] = hex_to_u32 ((const u8 *) &o_buf_pos[ 8]);
17073 pdf->o_buf[2] = hex_to_u32 ((const u8 *) &o_buf_pos[16]);
17074 pdf->o_buf[3] = hex_to_u32 ((const u8 *) &o_buf_pos[24]);
17075 pdf->o_buf[4] = hex_to_u32 ((const u8 *) &o_buf_pos[32]);
17076 pdf->o_buf[5] = hex_to_u32 ((const u8 *) &o_buf_pos[40]);
17077 pdf->o_buf[6] = hex_to_u32 ((const u8 *) &o_buf_pos[48]);
17078 pdf->o_buf[7] = hex_to_u32 ((const u8 *) &o_buf_pos[56]);
17079 pdf->o_len = o_len;
17080
17081 pdf->id_buf[0] = byte_swap_32 (pdf->id_buf[0]);
17082 pdf->id_buf[1] = byte_swap_32 (pdf->id_buf[1]);
17083 pdf->id_buf[2] = byte_swap_32 (pdf->id_buf[2]);
17084 pdf->id_buf[3] = byte_swap_32 (pdf->id_buf[3]);
17085
17086 if (id_len == 32)
17087 {
17088 pdf->id_buf[4] = byte_swap_32 (pdf->id_buf[4]);
17089 pdf->id_buf[5] = byte_swap_32 (pdf->id_buf[5]);
17090 pdf->id_buf[6] = byte_swap_32 (pdf->id_buf[6]);
17091 pdf->id_buf[7] = byte_swap_32 (pdf->id_buf[7]);
17092 }
17093
17094 pdf->u_buf[0] = byte_swap_32 (pdf->u_buf[0]);
17095 pdf->u_buf[1] = byte_swap_32 (pdf->u_buf[1]);
17096 pdf->u_buf[2] = byte_swap_32 (pdf->u_buf[2]);
17097 pdf->u_buf[3] = byte_swap_32 (pdf->u_buf[3]);
17098 pdf->u_buf[4] = byte_swap_32 (pdf->u_buf[4]);
17099 pdf->u_buf[5] = byte_swap_32 (pdf->u_buf[5]);
17100 pdf->u_buf[6] = byte_swap_32 (pdf->u_buf[6]);
17101 pdf->u_buf[7] = byte_swap_32 (pdf->u_buf[7]);
17102
17103 pdf->o_buf[0] = byte_swap_32 (pdf->o_buf[0]);
17104 pdf->o_buf[1] = byte_swap_32 (pdf->o_buf[1]);
17105 pdf->o_buf[2] = byte_swap_32 (pdf->o_buf[2]);
17106 pdf->o_buf[3] = byte_swap_32 (pdf->o_buf[3]);
17107 pdf->o_buf[4] = byte_swap_32 (pdf->o_buf[4]);
17108 pdf->o_buf[5] = byte_swap_32 (pdf->o_buf[5]);
17109 pdf->o_buf[6] = byte_swap_32 (pdf->o_buf[6]);
17110 pdf->o_buf[7] = byte_swap_32 (pdf->o_buf[7]);
17111
17112 // precompute rc4 data for later use
17113
17114 uint padding[8] =
17115 {
17116 0x5e4ebf28,
17117 0x418a754e,
17118 0x564e0064,
17119 0x0801faff,
17120 0xb6002e2e,
17121 0x803e68d0,
17122 0xfea90c2f,
17123 0x7a695364
17124 };
17125
17126 // md5
17127
17128 uint salt_pc_block[32] = { 0 };
17129
17130 char *salt_pc_ptr = (char *) salt_pc_block;
17131
17132 memcpy (salt_pc_ptr, padding, 32);
17133 memcpy (salt_pc_ptr + 32, pdf->id_buf, pdf->id_len);
17134
17135 uint salt_pc_digest[4] = { 0 };
17136
17137 md5_complete_no_limit (salt_pc_digest, salt_pc_block, 32 + pdf->id_len);
17138
17139 pdf->rc4data[0] = salt_pc_digest[0];
17140 pdf->rc4data[1] = salt_pc_digest[1];
17141
17142 // we use ID for salt, maybe needs to change, we will see...
17143
17144 salt->salt_buf[0] = pdf->id_buf[0];
17145 salt->salt_buf[1] = pdf->id_buf[1];
17146 salt->salt_buf[2] = pdf->id_buf[2];
17147 salt->salt_buf[3] = pdf->id_buf[3];
17148 salt->salt_buf[4] = pdf->u_buf[0];
17149 salt->salt_buf[5] = pdf->u_buf[1];
17150 salt->salt_buf[6] = pdf->o_buf[0];
17151 salt->salt_buf[7] = pdf->o_buf[1];
17152 salt->salt_len = pdf->id_len + 16;
17153
17154 salt->salt_iter = ROUNDS_PDF14;
17155
17156 digest[0] = pdf->u_buf[0];
17157 digest[1] = pdf->u_buf[1];
17158 digest[2] = 0;
17159 digest[3] = 0;
17160
17161 return (PARSER_OK);
17162 }
17163
17164 int pdf17l3_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
17165 {
17166 int ret = pdf17l8_parse_hash (input_buf, input_len, hash_buf);
17167
17168 if (ret != PARSER_OK)
17169 {
17170 return ret;
17171 }
17172
17173 u32 *digest = (u32 *) hash_buf->digest;
17174
17175 salt_t *salt = hash_buf->salt;
17176
17177 digest[0] -= SHA256M_A;
17178 digest[1] -= SHA256M_B;
17179 digest[2] -= SHA256M_C;
17180 digest[3] -= SHA256M_D;
17181 digest[4] -= SHA256M_E;
17182 digest[5] -= SHA256M_F;
17183 digest[6] -= SHA256M_G;
17184 digest[7] -= SHA256M_H;
17185
17186 salt->salt_buf[2] = 0x80;
17187
17188 return (PARSER_OK);
17189 }
17190
17191 int pdf17l8_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
17192 {
17193 if ((input_len < DISPLAY_LEN_MIN_10600) || (input_len > DISPLAY_LEN_MAX_10600)) return (PARSER_GLOBAL_LENGTH);
17194
17195 if ((memcmp (SIGNATURE_PDF, input_buf, 5)) && (memcmp (SIGNATURE_PDF, input_buf, 5))) return (PARSER_SIGNATURE_UNMATCHED);
17196
17197 u32 *digest = (u32 *) hash_buf->digest;
17198
17199 salt_t *salt = hash_buf->salt;
17200
17201 pdf_t *pdf = (pdf_t *) hash_buf->esalt;
17202
17203 /**
17204 * parse line
17205 */
17206
17207 char *V_pos = input_buf + 5;
17208
17209 char *R_pos = strchr (V_pos, '*');
17210
17211 if (R_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17212
17213 u32 V_len = R_pos - V_pos;
17214
17215 R_pos++;
17216
17217 char *bits_pos = strchr (R_pos, '*');
17218
17219 if (bits_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17220
17221 u32 R_len = bits_pos - R_pos;
17222
17223 bits_pos++;
17224
17225 char *P_pos = strchr (bits_pos, '*');
17226
17227 if (P_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17228
17229 u32 bits_len = P_pos - bits_pos;
17230
17231 P_pos++;
17232
17233 char *enc_md_pos = strchr (P_pos, '*');
17234
17235 if (enc_md_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17236
17237 u32 P_len = enc_md_pos - P_pos;
17238
17239 enc_md_pos++;
17240
17241 char *id_len_pos = strchr (enc_md_pos, '*');
17242
17243 if (id_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17244
17245 u32 enc_md_len = id_len_pos - enc_md_pos;
17246
17247 id_len_pos++;
17248
17249 char *id_buf_pos = strchr (id_len_pos, '*');
17250
17251 if (id_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17252
17253 u32 id_len_len = id_buf_pos - id_len_pos;
17254
17255 id_buf_pos++;
17256
17257 char *u_len_pos = strchr (id_buf_pos, '*');
17258
17259 if (u_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17260
17261 u32 id_buf_len = u_len_pos - id_buf_pos;
17262
17263 u_len_pos++;
17264
17265 char *u_buf_pos = strchr (u_len_pos, '*');
17266
17267 if (u_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17268
17269 u32 u_len_len = u_buf_pos - u_len_pos;
17270
17271 u_buf_pos++;
17272
17273 char *o_len_pos = strchr (u_buf_pos, '*');
17274
17275 if (o_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17276
17277 u32 u_buf_len = o_len_pos - u_buf_pos;
17278
17279 o_len_pos++;
17280
17281 char *o_buf_pos = strchr (o_len_pos, '*');
17282
17283 if (o_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17284
17285 u32 o_len_len = o_buf_pos - o_len_pos;
17286
17287 o_buf_pos++;
17288
17289 char *last = strchr (o_buf_pos, '*');
17290
17291 if (last == NULL) last = input_buf + input_len;
17292
17293 u32 o_buf_len = last - o_buf_pos;
17294
17295 // validate data
17296
17297 const int V = atoi (V_pos);
17298 const int R = atoi (R_pos);
17299
17300 int vr_ok = 0;
17301
17302 if ((V == 5) && (R == 5)) vr_ok = 1;
17303 if ((V == 5) && (R == 6)) vr_ok = 1;
17304
17305 if (vr_ok == 0) return (PARSER_SALT_VALUE);
17306
17307 const int bits = atoi (bits_pos);
17308
17309 if (bits != 256) return (PARSER_SALT_VALUE);
17310
17311 int enc_md = atoi (enc_md_pos);
17312
17313 if (enc_md != 1) return (PARSER_SALT_VALUE);
17314
17315 const uint id_len = atoi (id_len_pos);
17316 const uint u_len = atoi (u_len_pos);
17317 const uint o_len = atoi (o_len_pos);
17318
17319 if (V_len > 6) return (PARSER_SALT_LENGTH);
17320 if (R_len > 6) return (PARSER_SALT_LENGTH);
17321 if (P_len > 6) return (PARSER_SALT_LENGTH);
17322 if (id_len_len > 6) return (PARSER_SALT_LENGTH);
17323 if (u_len_len > 6) return (PARSER_SALT_LENGTH);
17324 if (o_len_len > 6) return (PARSER_SALT_LENGTH);
17325 if (bits_len > 6) return (PARSER_SALT_LENGTH);
17326 if (enc_md_len > 6) return (PARSER_SALT_LENGTH);
17327
17328 if ((id_len * 2) != id_buf_len) return (PARSER_SALT_VALUE);
17329 if ((u_len * 2) != u_buf_len) return (PARSER_SALT_VALUE);
17330 if ((o_len * 2) != o_buf_len) return (PARSER_SALT_VALUE);
17331
17332 // copy data to esalt
17333
17334 if (u_len < 40) return (PARSER_SALT_VALUE);
17335
17336 for (int i = 0, j = 0; i < 8 + 2; i += 1, j += 8)
17337 {
17338 pdf->u_buf[i] = hex_to_u32 ((const u8 *) &u_buf_pos[j]);
17339 }
17340
17341 salt->salt_buf[0] = pdf->u_buf[8];
17342 salt->salt_buf[1] = pdf->u_buf[9];
17343
17344 salt->salt_buf[0] = byte_swap_32 (salt->salt_buf[0]);
17345 salt->salt_buf[1] = byte_swap_32 (salt->salt_buf[1]);
17346
17347 salt->salt_len = 8;
17348 salt->salt_iter = ROUNDS_PDF17L8;
17349
17350 digest[0] = pdf->u_buf[0];
17351 digest[1] = pdf->u_buf[1];
17352 digest[2] = pdf->u_buf[2];
17353 digest[3] = pdf->u_buf[3];
17354 digest[4] = pdf->u_buf[4];
17355 digest[5] = pdf->u_buf[5];
17356 digest[6] = pdf->u_buf[6];
17357 digest[7] = pdf->u_buf[7];
17358
17359 return (PARSER_OK);
17360 }
17361
17362 int pbkdf2_sha256_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
17363 {
17364 if ((input_len < DISPLAY_LEN_MIN_10900) || (input_len > DISPLAY_LEN_MAX_10900)) return (PARSER_GLOBAL_LENGTH);
17365
17366 if (memcmp (SIGNATURE_PBKDF2_SHA256, input_buf, 7)) return (PARSER_SIGNATURE_UNMATCHED);
17367
17368 u32 *digest = (u32 *) hash_buf->digest;
17369
17370 salt_t *salt = hash_buf->salt;
17371
17372 pbkdf2_sha256_t *pbkdf2_sha256 = (pbkdf2_sha256_t *) hash_buf->esalt;
17373
17374 /**
17375 * parse line
17376 */
17377
17378 // iterations
17379
17380 char *iter_pos = input_buf + 7;
17381
17382 u32 iter = atoi (iter_pos);
17383
17384 if (iter < 1) return (PARSER_SALT_ITERATION);
17385 if (iter > 999999) return (PARSER_SALT_ITERATION);
17386
17387 // first is *raw* salt
17388
17389 char *salt_pos = strchr (iter_pos, ':');
17390
17391 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17392
17393 salt_pos++;
17394
17395 char *hash_pos = strchr (salt_pos, ':');
17396
17397 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17398
17399 u32 salt_len = hash_pos - salt_pos;
17400
17401 if (salt_len > 64) return (PARSER_SALT_LENGTH);
17402
17403 hash_pos++;
17404
17405 u32 hash_b64_len = input_len - (hash_pos - input_buf);
17406
17407 if (hash_b64_len > 88) return (PARSER_HASH_LENGTH);
17408
17409 // decode salt
17410
17411 char *salt_buf_ptr = (char *) pbkdf2_sha256->salt_buf;
17412
17413 salt_len = parse_and_store_salt (salt_buf_ptr, salt_pos, salt_len);
17414
17415 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
17416
17417 salt_buf_ptr[salt_len + 3] = 0x01;
17418 salt_buf_ptr[salt_len + 4] = 0x80;
17419
17420 salt->salt_len = salt_len;
17421 salt->salt_iter = iter - 1;
17422
17423 // decode hash
17424
17425 u8 tmp_buf[100] = { 0 };
17426
17427 int hash_len = base64_decode (base64_to_int, (const u8 *) hash_pos, hash_b64_len, tmp_buf);
17428
17429 if (hash_len < 16) return (PARSER_HASH_LENGTH);
17430
17431 memcpy (digest, tmp_buf, 16);
17432
17433 digest[0] = byte_swap_32 (digest[0]);
17434 digest[1] = byte_swap_32 (digest[1]);
17435 digest[2] = byte_swap_32 (digest[2]);
17436 digest[3] = byte_swap_32 (digest[3]);
17437
17438 // add some stuff to normal salt to make sorted happy
17439
17440 salt->salt_buf[0] = pbkdf2_sha256->salt_buf[0];
17441 salt->salt_buf[1] = pbkdf2_sha256->salt_buf[1];
17442 salt->salt_buf[2] = pbkdf2_sha256->salt_buf[2];
17443 salt->salt_buf[3] = pbkdf2_sha256->salt_buf[3];
17444 salt->salt_buf[4] = salt->salt_iter;
17445
17446 return (PARSER_OK);
17447 }
17448
17449 int prestashop_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
17450 {
17451 if ((input_len < DISPLAY_LEN_MIN_11000) || (input_len > DISPLAY_LEN_MAX_11000)) return (PARSER_GLOBAL_LENGTH);
17452
17453 u32 *digest = (u32 *) hash_buf->digest;
17454
17455 salt_t *salt = hash_buf->salt;
17456
17457 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
17458 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
17459 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
17460 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
17461
17462 digest[0] = byte_swap_32 (digest[0]);
17463 digest[1] = byte_swap_32 (digest[1]);
17464 digest[2] = byte_swap_32 (digest[2]);
17465 digest[3] = byte_swap_32 (digest[3]);
17466
17467 if (input_buf[32] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
17468
17469 uint salt_len = input_len - 32 - 1;
17470
17471 char *salt_buf = input_buf + 32 + 1;
17472
17473 char *salt_buf_ptr = (char *) salt->salt_buf;
17474
17475 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
17476
17477 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
17478
17479 salt->salt_len = salt_len;
17480
17481 return (PARSER_OK);
17482 }
17483
17484 int postgresql_auth_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
17485 {
17486 if ((input_len < DISPLAY_LEN_MIN_11100) || (input_len > DISPLAY_LEN_MAX_11100)) return (PARSER_GLOBAL_LENGTH);
17487
17488 if (memcmp (SIGNATURE_POSTGRESQL_AUTH, input_buf, 10)) return (PARSER_SIGNATURE_UNMATCHED);
17489
17490 u32 *digest = (u32 *) hash_buf->digest;
17491
17492 salt_t *salt = hash_buf->salt;
17493
17494 char *user_pos = input_buf + 10;
17495
17496 char *salt_pos = strchr (user_pos, '*');
17497
17498 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17499
17500 salt_pos++;
17501
17502 char *hash_pos = strchr (salt_pos, '*');
17503
17504 hash_pos++;
17505
17506 uint hash_len = input_len - (hash_pos - input_buf);
17507
17508 if (hash_len != 32) return (PARSER_HASH_LENGTH);
17509
17510 uint user_len = salt_pos - user_pos - 1;
17511
17512 uint salt_len = hash_pos - salt_pos - 1;
17513
17514 if (salt_len != 8) return (PARSER_SALT_LENGTH);
17515
17516 /*
17517 * store digest
17518 */
17519
17520 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
17521 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
17522 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
17523 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
17524
17525 digest[0] = byte_swap_32 (digest[0]);
17526 digest[1] = byte_swap_32 (digest[1]);
17527 digest[2] = byte_swap_32 (digest[2]);
17528 digest[3] = byte_swap_32 (digest[3]);
17529
17530 digest[0] -= MD5M_A;
17531 digest[1] -= MD5M_B;
17532 digest[2] -= MD5M_C;
17533 digest[3] -= MD5M_D;
17534
17535 /*
17536 * store salt
17537 */
17538
17539 char *salt_buf_ptr = (char *) salt->salt_buf;
17540
17541 // first 4 bytes are the "challenge"
17542
17543 salt_buf_ptr[0] = hex_to_u8 ((const u8 *) &salt_pos[0]);
17544 salt_buf_ptr[1] = hex_to_u8 ((const u8 *) &salt_pos[2]);
17545 salt_buf_ptr[2] = hex_to_u8 ((const u8 *) &salt_pos[4]);
17546 salt_buf_ptr[3] = hex_to_u8 ((const u8 *) &salt_pos[6]);
17547
17548 // append the user name
17549
17550 user_len = parse_and_store_salt (salt_buf_ptr + 4, user_pos, user_len);
17551
17552 salt->salt_len = 4 + user_len;
17553
17554 return (PARSER_OK);
17555 }
17556
17557 int mysql_auth_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
17558 {
17559 if ((input_len < DISPLAY_LEN_MIN_11200) || (input_len > DISPLAY_LEN_MAX_11200)) return (PARSER_GLOBAL_LENGTH);
17560
17561 if (memcmp (SIGNATURE_MYSQL_AUTH, input_buf, 9)) return (PARSER_SIGNATURE_UNMATCHED);
17562
17563 u32 *digest = (u32 *) hash_buf->digest;
17564
17565 salt_t *salt = hash_buf->salt;
17566
17567 char *salt_pos = input_buf + 9;
17568
17569 char *hash_pos = strchr (salt_pos, '*');
17570
17571 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17572
17573 hash_pos++;
17574
17575 uint hash_len = input_len - (hash_pos - input_buf);
17576
17577 if (hash_len != 40) return (PARSER_HASH_LENGTH);
17578
17579 uint salt_len = hash_pos - salt_pos - 1;
17580
17581 if (salt_len != 40) return (PARSER_SALT_LENGTH);
17582
17583 /*
17584 * store digest
17585 */
17586
17587 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
17588 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
17589 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
17590 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
17591 digest[4] = hex_to_u32 ((const u8 *) &hash_pos[32]);
17592
17593 /*
17594 * store salt
17595 */
17596
17597 char *salt_buf_ptr = (char *) salt->salt_buf;
17598
17599 salt_len = parse_and_store_salt (salt_buf_ptr, salt_pos, salt_len);
17600
17601 salt->salt_len = salt_len;
17602
17603 return (PARSER_OK);
17604 }
17605
17606 int bitcoin_wallet_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
17607 {
17608 if ((input_len < DISPLAY_LEN_MIN_11300) || (input_len > DISPLAY_LEN_MAX_11300)) return (PARSER_GLOBAL_LENGTH);
17609
17610 if (memcmp (SIGNATURE_BITCOIN_WALLET, input_buf, 9)) return (PARSER_SIGNATURE_UNMATCHED);
17611
17612 u32 *digest = (u32 *) hash_buf->digest;
17613
17614 salt_t *salt = hash_buf->salt;
17615
17616 bitcoin_wallet_t *bitcoin_wallet = (bitcoin_wallet_t *) hash_buf->esalt;
17617
17618 /**
17619 * parse line
17620 */
17621
17622 char *cry_master_len_pos = input_buf + 9;
17623
17624 char *cry_master_buf_pos = strchr (cry_master_len_pos, '$');
17625
17626 if (cry_master_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17627
17628 u32 cry_master_len_len = cry_master_buf_pos - cry_master_len_pos;
17629
17630 cry_master_buf_pos++;
17631
17632 char *cry_salt_len_pos = strchr (cry_master_buf_pos, '$');
17633
17634 if (cry_salt_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17635
17636 u32 cry_master_buf_len = cry_salt_len_pos - cry_master_buf_pos;
17637
17638 cry_salt_len_pos++;
17639
17640 char *cry_salt_buf_pos = strchr (cry_salt_len_pos, '$');
17641
17642 if (cry_salt_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17643
17644 u32 cry_salt_len_len = cry_salt_buf_pos - cry_salt_len_pos;
17645
17646 cry_salt_buf_pos++;
17647
17648 char *cry_rounds_pos = strchr (cry_salt_buf_pos, '$');
17649
17650 if (cry_rounds_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17651
17652 u32 cry_salt_buf_len = cry_rounds_pos - cry_salt_buf_pos;
17653
17654 cry_rounds_pos++;
17655
17656 char *ckey_len_pos = strchr (cry_rounds_pos, '$');
17657
17658 if (ckey_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17659
17660 u32 cry_rounds_len = ckey_len_pos - cry_rounds_pos;
17661
17662 ckey_len_pos++;
17663
17664 char *ckey_buf_pos = strchr (ckey_len_pos, '$');
17665
17666 if (ckey_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17667
17668 u32 ckey_len_len = ckey_buf_pos - ckey_len_pos;
17669
17670 ckey_buf_pos++;
17671
17672 char *public_key_len_pos = strchr (ckey_buf_pos, '$');
17673
17674 if (public_key_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17675
17676 u32 ckey_buf_len = public_key_len_pos - ckey_buf_pos;
17677
17678 public_key_len_pos++;
17679
17680 char *public_key_buf_pos = strchr (public_key_len_pos, '$');
17681
17682 if (public_key_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
17683
17684 u32 public_key_len_len = public_key_buf_pos - public_key_len_pos;
17685
17686 public_key_buf_pos++;
17687
17688 u32 public_key_buf_len = input_len - 1 - 7 - 1 - cry_master_len_len - 1 - cry_master_buf_len - 1 - cry_salt_len_len - 1 - cry_salt_buf_len - 1 - cry_rounds_len - 1 - ckey_len_len - 1 - ckey_buf_len - 1 - public_key_len_len - 1;
17689
17690 const uint cry_master_len = atoi (cry_master_len_pos);
17691 const uint cry_salt_len = atoi (cry_salt_len_pos);
17692 const uint ckey_len = atoi (ckey_len_pos);
17693 const uint public_key_len = atoi (public_key_len_pos);
17694
17695 if (cry_master_buf_len != cry_master_len) return (PARSER_SALT_VALUE);
17696 if (cry_salt_buf_len != cry_salt_len) return (PARSER_SALT_VALUE);
17697 if (ckey_buf_len != ckey_len) return (PARSER_SALT_VALUE);
17698 if (public_key_buf_len != public_key_len) return (PARSER_SALT_VALUE);
17699
17700 for (uint i = 0, j = 0; j < cry_master_len; i += 1, j += 8)
17701 {
17702 bitcoin_wallet->cry_master_buf[i] = hex_to_u32 ((const u8 *) &cry_master_buf_pos[j]);
17703
17704 bitcoin_wallet->cry_master_buf[i] = byte_swap_32 (bitcoin_wallet->cry_master_buf[i]);
17705 }
17706
17707 for (uint i = 0, j = 0; j < ckey_len; i += 1, j += 8)
17708 {
17709 bitcoin_wallet->ckey_buf[i] = hex_to_u32 ((const u8 *) &ckey_buf_pos[j]);
17710
17711 bitcoin_wallet->ckey_buf[i] = byte_swap_32 (bitcoin_wallet->ckey_buf[i]);
17712 }
17713
17714 for (uint i = 0, j = 0; j < public_key_len; i += 1, j += 8)
17715 {
17716 bitcoin_wallet->public_key_buf[i] = hex_to_u32 ((const u8 *) &public_key_buf_pos[j]);
17717
17718 bitcoin_wallet->public_key_buf[i] = byte_swap_32 (bitcoin_wallet->public_key_buf[i]);
17719 }
17720
17721 bitcoin_wallet->cry_master_len = cry_master_len / 2;
17722 bitcoin_wallet->ckey_len = ckey_len / 2;
17723 bitcoin_wallet->public_key_len = public_key_len / 2;
17724
17725 /*
17726 * store digest (should be unique enought, hopefully)
17727 */
17728
17729 digest[0] = bitcoin_wallet->cry_master_buf[0];
17730 digest[1] = bitcoin_wallet->cry_master_buf[1];
17731 digest[2] = bitcoin_wallet->cry_master_buf[2];
17732 digest[3] = bitcoin_wallet->cry_master_buf[3];
17733
17734 /*
17735 * store salt
17736 */
17737
17738 if (cry_rounds_len >= 7) return (PARSER_SALT_VALUE);
17739
17740 const uint cry_rounds = atoi (cry_rounds_pos);
17741
17742 salt->salt_iter = cry_rounds - 1;
17743
17744 char *salt_buf_ptr = (char *) salt->salt_buf;
17745
17746 const uint salt_len = parse_and_store_salt (salt_buf_ptr, cry_salt_buf_pos, cry_salt_buf_len);
17747
17748 salt->salt_len = salt_len;
17749
17750 return (PARSER_OK);
17751 }
17752
17753 int sip_auth_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
17754 {
17755 if ((input_len < DISPLAY_LEN_MIN_11400) || (input_len > DISPLAY_LEN_MAX_11400)) return (PARSER_GLOBAL_LENGTH);
17756
17757 if (memcmp (SIGNATURE_SIP_AUTH, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
17758
17759 u32 *digest = (u32 *) hash_buf->digest;
17760
17761 salt_t *salt = hash_buf->salt;
17762
17763 sip_t *sip = (sip_t *) hash_buf->esalt;
17764
17765 // work with a temporary copy of input_buf (s.t. we can manipulate it directly)
17766
17767 char *temp_input_buf = (char *) mymalloc (input_len + 1);
17768
17769 memcpy (temp_input_buf, input_buf, input_len);
17770
17771 // URI_server:
17772
17773 char *URI_server_pos = temp_input_buf + 6;
17774
17775 char *URI_client_pos = strchr (URI_server_pos, '*');
17776
17777 if (URI_client_pos == NULL)
17778 {
17779 myfree (temp_input_buf);
17780
17781 return (PARSER_SEPARATOR_UNMATCHED);
17782 }
17783
17784 URI_client_pos[0] = 0;
17785 URI_client_pos++;
17786
17787 uint URI_server_len = strlen (URI_server_pos);
17788
17789 if (URI_server_len > 512)
17790 {
17791 myfree (temp_input_buf);
17792
17793 return (PARSER_SALT_LENGTH);
17794 }
17795
17796 // URI_client:
17797
17798 char *user_pos = strchr (URI_client_pos, '*');
17799
17800 if (user_pos == NULL)
17801 {
17802 myfree (temp_input_buf);
17803
17804 return (PARSER_SEPARATOR_UNMATCHED);
17805 }
17806
17807 user_pos[0] = 0;
17808 user_pos++;
17809
17810 uint URI_client_len = strlen (URI_client_pos);
17811
17812 if (URI_client_len > 512)
17813 {
17814 myfree (temp_input_buf);
17815
17816 return (PARSER_SALT_LENGTH);
17817 }
17818
17819 // user:
17820
17821 char *realm_pos = strchr (user_pos, '*');
17822
17823 if (realm_pos == NULL)
17824 {
17825 myfree (temp_input_buf);
17826
17827 return (PARSER_SEPARATOR_UNMATCHED);
17828 }
17829
17830 realm_pos[0] = 0;
17831 realm_pos++;
17832
17833 uint user_len = strlen (user_pos);
17834
17835 if (user_len > 116)
17836 {
17837 myfree (temp_input_buf);
17838
17839 return (PARSER_SALT_LENGTH);
17840 }
17841
17842 // realm:
17843
17844 char *method_pos = strchr (realm_pos, '*');
17845
17846 if (method_pos == NULL)
17847 {
17848 myfree (temp_input_buf);
17849
17850 return (PARSER_SEPARATOR_UNMATCHED);
17851 }
17852
17853 method_pos[0] = 0;
17854 method_pos++;
17855
17856 uint realm_len = strlen (realm_pos);
17857
17858 if (realm_len > 116)
17859 {
17860 myfree (temp_input_buf);
17861
17862 return (PARSER_SALT_LENGTH);
17863 }
17864
17865 // method:
17866
17867 char *URI_prefix_pos = strchr (method_pos, '*');
17868
17869 if (URI_prefix_pos == NULL)
17870 {
17871 myfree (temp_input_buf);
17872
17873 return (PARSER_SEPARATOR_UNMATCHED);
17874 }
17875
17876 URI_prefix_pos[0] = 0;
17877 URI_prefix_pos++;
17878
17879 uint method_len = strlen (method_pos);
17880
17881 if (method_len > 246)
17882 {
17883 myfree (temp_input_buf);
17884
17885 return (PARSER_SALT_LENGTH);
17886 }
17887
17888 // URI_prefix:
17889
17890 char *URI_resource_pos = strchr (URI_prefix_pos, '*');
17891
17892 if (URI_resource_pos == NULL)
17893 {
17894 myfree (temp_input_buf);
17895
17896 return (PARSER_SEPARATOR_UNMATCHED);
17897 }
17898
17899 URI_resource_pos[0] = 0;
17900 URI_resource_pos++;
17901
17902 uint URI_prefix_len = strlen (URI_prefix_pos);
17903
17904 if (URI_prefix_len > 245)
17905 {
17906 myfree (temp_input_buf);
17907
17908 return (PARSER_SALT_LENGTH);
17909 }
17910
17911 // URI_resource:
17912
17913 char *URI_suffix_pos = strchr (URI_resource_pos, '*');
17914
17915 if (URI_suffix_pos == NULL)
17916 {
17917 myfree (temp_input_buf);
17918
17919 return (PARSER_SEPARATOR_UNMATCHED);
17920 }
17921
17922 URI_suffix_pos[0] = 0;
17923 URI_suffix_pos++;
17924
17925 uint URI_resource_len = strlen (URI_resource_pos);
17926
17927 if (URI_resource_len < 1 || URI_resource_len > 246)
17928 {
17929 myfree (temp_input_buf);
17930
17931 return (PARSER_SALT_LENGTH);
17932 }
17933
17934 // URI_suffix:
17935
17936 char *nonce_pos = strchr (URI_suffix_pos, '*');
17937
17938 if (nonce_pos == NULL)
17939 {
17940 myfree (temp_input_buf);
17941
17942 return (PARSER_SEPARATOR_UNMATCHED);
17943 }
17944
17945 nonce_pos[0] = 0;
17946 nonce_pos++;
17947
17948 uint URI_suffix_len = strlen (URI_suffix_pos);
17949
17950 if (URI_suffix_len > 245)
17951 {
17952 myfree (temp_input_buf);
17953
17954 return (PARSER_SALT_LENGTH);
17955 }
17956
17957 // nonce:
17958
17959 char *nonce_client_pos = strchr (nonce_pos, '*');
17960
17961 if (nonce_client_pos == NULL)
17962 {
17963 myfree (temp_input_buf);
17964
17965 return (PARSER_SEPARATOR_UNMATCHED);
17966 }
17967
17968 nonce_client_pos[0] = 0;
17969 nonce_client_pos++;
17970
17971 uint nonce_len = strlen (nonce_pos);
17972
17973 if (nonce_len < 1 || nonce_len > 50)
17974 {
17975 myfree (temp_input_buf);
17976
17977 return (PARSER_SALT_LENGTH);
17978 }
17979
17980 // nonce_client:
17981
17982 char *nonce_count_pos = strchr (nonce_client_pos, '*');
17983
17984 if (nonce_count_pos == NULL)
17985 {
17986 myfree (temp_input_buf);
17987
17988 return (PARSER_SEPARATOR_UNMATCHED);
17989 }
17990
17991 nonce_count_pos[0] = 0;
17992 nonce_count_pos++;
17993
17994 uint nonce_client_len = strlen (nonce_client_pos);
17995
17996 if (nonce_client_len > 50)
17997 {
17998 myfree (temp_input_buf);
17999
18000 return (PARSER_SALT_LENGTH);
18001 }
18002
18003 // nonce_count:
18004
18005 char *qop_pos = strchr (nonce_count_pos, '*');
18006
18007 if (qop_pos == NULL)
18008 {
18009 myfree (temp_input_buf);
18010
18011 return (PARSER_SEPARATOR_UNMATCHED);
18012 }
18013
18014 qop_pos[0] = 0;
18015 qop_pos++;
18016
18017 uint nonce_count_len = strlen (nonce_count_pos);
18018
18019 if (nonce_count_len > 50)
18020 {
18021 myfree (temp_input_buf);
18022
18023 return (PARSER_SALT_LENGTH);
18024 }
18025
18026 // qop:
18027
18028 char *directive_pos = strchr (qop_pos, '*');
18029
18030 if (directive_pos == NULL)
18031 {
18032 myfree (temp_input_buf);
18033
18034 return (PARSER_SEPARATOR_UNMATCHED);
18035 }
18036
18037 directive_pos[0] = 0;
18038 directive_pos++;
18039
18040 uint qop_len = strlen (qop_pos);
18041
18042 if (qop_len > 50)
18043 {
18044 myfree (temp_input_buf);
18045
18046 return (PARSER_SALT_LENGTH);
18047 }
18048
18049 // directive
18050
18051 char *digest_pos = strchr (directive_pos, '*');
18052
18053 if (digest_pos == NULL)
18054 {
18055 myfree (temp_input_buf);
18056
18057 return (PARSER_SEPARATOR_UNMATCHED);
18058 }
18059
18060 digest_pos[0] = 0;
18061 digest_pos++;
18062
18063 uint directive_len = strlen (directive_pos);
18064
18065 if (directive_len != 3)
18066 {
18067 myfree (temp_input_buf);
18068
18069 return (PARSER_SALT_LENGTH);
18070 }
18071
18072 if (memcmp (directive_pos, "MD5", 3))
18073 {
18074 log_info ("ERROR: only the MD5 directive is currently supported\n");
18075
18076 myfree (temp_input_buf);
18077
18078 return (PARSER_SIP_AUTH_DIRECTIVE);
18079 }
18080
18081 /*
18082 * first (pre-)compute: HA2 = md5 ($method . ":" . $uri)
18083 */
18084
18085 uint md5_len = 0;
18086
18087 uint md5_max_len = 4 * 64;
18088
18089 uint md5_remaining_len = md5_max_len;
18090
18091 uint tmp_md5_buf[64] = { 0 };
18092
18093 char *tmp_md5_ptr = (char *) tmp_md5_buf;
18094
18095 snprintf (tmp_md5_ptr, md5_remaining_len, "%s:", method_pos);
18096
18097 md5_len += method_len + 1;
18098 tmp_md5_ptr += method_len + 1;
18099
18100 if (URI_prefix_len > 0)
18101 {
18102 md5_remaining_len = md5_max_len - md5_len;
18103
18104 snprintf (tmp_md5_ptr, md5_remaining_len + 1, "%s:", URI_prefix_pos);
18105
18106 md5_len += URI_prefix_len + 1;
18107 tmp_md5_ptr += URI_prefix_len + 1;
18108 }
18109
18110 md5_remaining_len = md5_max_len - md5_len;
18111
18112 snprintf (tmp_md5_ptr, md5_remaining_len + 1, "%s", URI_resource_pos);
18113
18114 md5_len += URI_resource_len;
18115 tmp_md5_ptr += URI_resource_len;
18116
18117 if (URI_suffix_len > 0)
18118 {
18119 md5_remaining_len = md5_max_len - md5_len;
18120
18121 snprintf (tmp_md5_ptr, md5_remaining_len + 1, ":%s", URI_suffix_pos);
18122
18123 md5_len += 1 + URI_suffix_len;
18124 }
18125
18126 uint tmp_digest[4] = { 0 };
18127
18128 md5_complete_no_limit (tmp_digest, tmp_md5_buf, md5_len);
18129
18130 tmp_digest[0] = byte_swap_32 (tmp_digest[0]);
18131 tmp_digest[1] = byte_swap_32 (tmp_digest[1]);
18132 tmp_digest[2] = byte_swap_32 (tmp_digest[2]);
18133 tmp_digest[3] = byte_swap_32 (tmp_digest[3]);
18134
18135 /*
18136 * esalt
18137 */
18138
18139 char *esalt_buf_ptr = (char *) sip->esalt_buf;
18140
18141 uint esalt_len = 0;
18142
18143 uint max_esalt_len = sizeof (sip->esalt_buf); // 151 = (64 + 64 + 55) - 32, where 32 is the hexadecimal MD5 HA1 hash
18144
18145 // there are 2 possibilities for the esalt:
18146
18147 if ((strcmp (qop_pos, "auth") == 0) || (strcmp (qop_pos, "auth-int") == 0))
18148 {
18149 esalt_len = 1 + nonce_len + 1 + nonce_count_len + 1 + nonce_client_len + 1 + qop_len + 1 + 32;
18150
18151 if (esalt_len > max_esalt_len)
18152 {
18153 myfree (temp_input_buf);
18154
18155 return (PARSER_SALT_LENGTH);
18156 }
18157
18158 snprintf (esalt_buf_ptr, max_esalt_len, ":%s:%s:%s:%s:%08x%08x%08x%08x",
18159 nonce_pos,
18160 nonce_count_pos,
18161 nonce_client_pos,
18162 qop_pos,
18163 tmp_digest[0],
18164 tmp_digest[1],
18165 tmp_digest[2],
18166 tmp_digest[3]);
18167 }
18168 else
18169 {
18170 esalt_len = 1 + nonce_len + 1 + 32;
18171
18172 if (esalt_len > max_esalt_len)
18173 {
18174 myfree (temp_input_buf);
18175
18176 return (PARSER_SALT_LENGTH);
18177 }
18178
18179 snprintf (esalt_buf_ptr, max_esalt_len, ":%s:%08x%08x%08x%08x",
18180 nonce_pos,
18181 tmp_digest[0],
18182 tmp_digest[1],
18183 tmp_digest[2],
18184 tmp_digest[3]);
18185 }
18186
18187 // add 0x80 to esalt
18188
18189 esalt_buf_ptr[esalt_len] = 0x80;
18190
18191 sip->esalt_len = esalt_len;
18192
18193 /*
18194 * actual salt
18195 */
18196
18197 char *sip_salt_ptr = (char *) sip->salt_buf;
18198
18199 uint salt_len = user_len + 1 + realm_len + 1;
18200
18201 uint max_salt_len = 119;
18202
18203 if (salt_len > max_salt_len)
18204 {
18205 myfree (temp_input_buf);
18206
18207 return (PARSER_SALT_LENGTH);
18208 }
18209
18210 snprintf (sip_salt_ptr, max_salt_len + 1, "%s:%s:", user_pos, realm_pos);
18211
18212 sip->salt_len = salt_len;
18213
18214 /*
18215 * fake salt (for sorting)
18216 */
18217
18218 char *salt_buf_ptr = (char *) salt->salt_buf;
18219
18220 max_salt_len = 55;
18221
18222 uint fake_salt_len = salt_len;
18223
18224 if (fake_salt_len > max_salt_len)
18225 {
18226 fake_salt_len = max_salt_len;
18227 }
18228
18229 snprintf (salt_buf_ptr, max_salt_len + 1, "%s:%s:", user_pos, realm_pos);
18230
18231 salt->salt_len = fake_salt_len;
18232
18233 /*
18234 * digest
18235 */
18236
18237 digest[0] = hex_to_u32 ((const u8 *) &digest_pos[ 0]);
18238 digest[1] = hex_to_u32 ((const u8 *) &digest_pos[ 8]);
18239 digest[2] = hex_to_u32 ((const u8 *) &digest_pos[16]);
18240 digest[3] = hex_to_u32 ((const u8 *) &digest_pos[24]);
18241
18242 digest[0] = byte_swap_32 (digest[0]);
18243 digest[1] = byte_swap_32 (digest[1]);
18244 digest[2] = byte_swap_32 (digest[2]);
18245 digest[3] = byte_swap_32 (digest[3]);
18246
18247 myfree (temp_input_buf);
18248
18249 return (PARSER_OK);
18250 }
18251
18252 int crc32_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
18253 {
18254 if ((input_len < DISPLAY_LEN_MIN_11500) || (input_len > DISPLAY_LEN_MAX_11500)) return (PARSER_GLOBAL_LENGTH);
18255
18256 if (input_buf[8] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
18257
18258 u32 *digest = (u32 *) hash_buf->digest;
18259
18260 salt_t *salt = hash_buf->salt;
18261
18262 // digest
18263
18264 char *digest_pos = input_buf;
18265
18266 digest[0] = hex_to_u32 ((const u8 *) &digest_pos[0]);
18267 digest[1] = 0;
18268 digest[2] = 0;
18269 digest[3] = 0;
18270
18271 // salt
18272
18273 char *salt_buf = input_buf + 8 + 1;
18274
18275 uint salt_len = 8;
18276
18277 char *salt_buf_ptr = (char *) salt->salt_buf;
18278
18279 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
18280
18281 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
18282
18283 salt->salt_len = salt_len;
18284
18285 return (PARSER_OK);
18286 }
18287
18288 int seven_zip_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
18289 {
18290 if ((input_len < DISPLAY_LEN_MIN_11600) || (input_len > DISPLAY_LEN_MAX_11600)) return (PARSER_GLOBAL_LENGTH);
18291
18292 if (memcmp (SIGNATURE_SEVEN_ZIP, input_buf, 4)) return (PARSER_SIGNATURE_UNMATCHED);
18293
18294 u32 *digest = (u32 *) hash_buf->digest;
18295
18296 salt_t *salt = hash_buf->salt;
18297
18298 seven_zip_t *seven_zip = (seven_zip_t *) hash_buf->esalt;
18299
18300 /**
18301 * parse line
18302 */
18303
18304 char *p_buf_pos = input_buf + 4;
18305
18306 char *NumCyclesPower_pos = strchr (p_buf_pos, '$');
18307
18308 if (NumCyclesPower_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18309
18310 u32 p_buf_len = NumCyclesPower_pos - p_buf_pos;
18311
18312 NumCyclesPower_pos++;
18313
18314 char *salt_len_pos = strchr (NumCyclesPower_pos, '$');
18315
18316 if (salt_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18317
18318 u32 NumCyclesPower_len = salt_len_pos - NumCyclesPower_pos;
18319
18320 salt_len_pos++;
18321
18322 char *salt_buf_pos = strchr (salt_len_pos, '$');
18323
18324 if (salt_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18325
18326 u32 salt_len_len = salt_buf_pos - salt_len_pos;
18327
18328 salt_buf_pos++;
18329
18330 char *iv_len_pos = strchr (salt_buf_pos, '$');
18331
18332 if (iv_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18333
18334 u32 salt_buf_len = iv_len_pos - salt_buf_pos;
18335
18336 iv_len_pos++;
18337
18338 char *iv_buf_pos = strchr (iv_len_pos, '$');
18339
18340 if (iv_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18341
18342 u32 iv_len_len = iv_buf_pos - iv_len_pos;
18343
18344 iv_buf_pos++;
18345
18346 char *crc_buf_pos = strchr (iv_buf_pos, '$');
18347
18348 if (crc_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18349
18350 u32 iv_buf_len = crc_buf_pos - iv_buf_pos;
18351
18352 crc_buf_pos++;
18353
18354 char *data_len_pos = strchr (crc_buf_pos, '$');
18355
18356 if (data_len_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18357
18358 u32 crc_buf_len = data_len_pos - crc_buf_pos;
18359
18360 data_len_pos++;
18361
18362 char *unpack_size_pos = strchr (data_len_pos, '$');
18363
18364 if (unpack_size_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18365
18366 u32 data_len_len = unpack_size_pos - data_len_pos;
18367
18368 unpack_size_pos++;
18369
18370 char *data_buf_pos = strchr (unpack_size_pos, '$');
18371
18372 if (data_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18373
18374 u32 unpack_size_len = data_buf_pos - unpack_size_pos;
18375
18376 data_buf_pos++;
18377
18378 u32 data_buf_len = input_len - 1 - 2 - 1 - p_buf_len - 1 - NumCyclesPower_len - 1 - salt_len_len - 1 - salt_buf_len - 1 - iv_len_len - 1 - iv_buf_len - 1 - crc_buf_len - 1 - data_len_len - 1 - unpack_size_len - 1;
18379
18380 const uint iter = atoi (NumCyclesPower_pos);
18381 const uint crc = atoi (crc_buf_pos);
18382 const uint p_buf = atoi (p_buf_pos);
18383 const uint salt_len = atoi (salt_len_pos);
18384 const uint iv_len = atoi (iv_len_pos);
18385 const uint unpack_size = atoi (unpack_size_pos);
18386 const uint data_len = atoi (data_len_pos);
18387
18388 /**
18389 * verify some data
18390 */
18391
18392 if (p_buf != 0) return (PARSER_SALT_VALUE);
18393 if (salt_len != 0) return (PARSER_SALT_VALUE);
18394
18395 if ((data_len * 2) != data_buf_len) return (PARSER_SALT_VALUE);
18396
18397 if (data_len > 384) return (PARSER_SALT_VALUE);
18398
18399 if (unpack_size > data_len) return (PARSER_SALT_VALUE);
18400
18401 /**
18402 * store data
18403 */
18404
18405 seven_zip->iv_buf[0] = hex_to_u32 ((const u8 *) &iv_buf_pos[ 0]);
18406 seven_zip->iv_buf[1] = hex_to_u32 ((const u8 *) &iv_buf_pos[ 8]);
18407 seven_zip->iv_buf[2] = hex_to_u32 ((const u8 *) &iv_buf_pos[16]);
18408 seven_zip->iv_buf[3] = hex_to_u32 ((const u8 *) &iv_buf_pos[24]);
18409
18410 seven_zip->iv_len = iv_len;
18411
18412 memcpy (seven_zip->salt_buf, salt_buf_pos, salt_buf_len); // we just need that for later ascii_digest()
18413
18414 seven_zip->salt_len = 0;
18415
18416 seven_zip->crc = crc;
18417
18418 for (uint i = 0, j = 0; j < data_buf_len; i += 1, j += 8)
18419 {
18420 seven_zip->data_buf[i] = hex_to_u32 ((const u8 *) &data_buf_pos[j]);
18421
18422 seven_zip->data_buf[i] = byte_swap_32 (seven_zip->data_buf[i]);
18423 }
18424
18425 seven_zip->data_len = data_len;
18426
18427 seven_zip->unpack_size = unpack_size;
18428
18429 // real salt
18430
18431 salt->salt_buf[0] = seven_zip->data_buf[0];
18432 salt->salt_buf[1] = seven_zip->data_buf[1];
18433 salt->salt_buf[2] = seven_zip->data_buf[2];
18434 salt->salt_buf[3] = seven_zip->data_buf[3];
18435
18436 salt->salt_len = 16;
18437
18438 salt->salt_sign[0] = iter;
18439
18440 salt->salt_iter = 1 << iter;
18441
18442 /**
18443 * digest
18444 */
18445
18446 digest[0] = crc;
18447 digest[1] = 0;
18448 digest[2] = 0;
18449 digest[3] = 0;
18450
18451 return (PARSER_OK);
18452 }
18453
18454 int gost2012sbog_256_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
18455 {
18456 if ((input_len < DISPLAY_LEN_MIN_11700) || (input_len > DISPLAY_LEN_MAX_11700)) return (PARSER_GLOBAL_LENGTH);
18457
18458 u32 *digest = (u32 *) hash_buf->digest;
18459
18460 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
18461 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
18462 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
18463 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
18464 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
18465 digest[5] = hex_to_u32 ((const u8 *) &input_buf[40]);
18466 digest[6] = hex_to_u32 ((const u8 *) &input_buf[48]);
18467 digest[7] = hex_to_u32 ((const u8 *) &input_buf[56]);
18468
18469 digest[0] = byte_swap_32 (digest[0]);
18470 digest[1] = byte_swap_32 (digest[1]);
18471 digest[2] = byte_swap_32 (digest[2]);
18472 digest[3] = byte_swap_32 (digest[3]);
18473 digest[4] = byte_swap_32 (digest[4]);
18474 digest[5] = byte_swap_32 (digest[5]);
18475 digest[6] = byte_swap_32 (digest[6]);
18476 digest[7] = byte_swap_32 (digest[7]);
18477
18478 return (PARSER_OK);
18479 }
18480
18481 int gost2012sbog_512_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
18482 {
18483 if ((input_len < DISPLAY_LEN_MIN_11800) || (input_len > DISPLAY_LEN_MAX_11800)) return (PARSER_GLOBAL_LENGTH);
18484
18485 u32 *digest = (u32 *) hash_buf->digest;
18486
18487 digest[ 0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
18488 digest[ 1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
18489 digest[ 2] = hex_to_u32 ((const u8 *) &input_buf[ 16]);
18490 digest[ 3] = hex_to_u32 ((const u8 *) &input_buf[ 24]);
18491 digest[ 4] = hex_to_u32 ((const u8 *) &input_buf[ 32]);
18492 digest[ 5] = hex_to_u32 ((const u8 *) &input_buf[ 40]);
18493 digest[ 6] = hex_to_u32 ((const u8 *) &input_buf[ 48]);
18494 digest[ 7] = hex_to_u32 ((const u8 *) &input_buf[ 56]);
18495 digest[ 8] = hex_to_u32 ((const u8 *) &input_buf[ 64]);
18496 digest[ 9] = hex_to_u32 ((const u8 *) &input_buf[ 72]);
18497 digest[10] = hex_to_u32 ((const u8 *) &input_buf[ 80]);
18498 digest[11] = hex_to_u32 ((const u8 *) &input_buf[ 88]);
18499 digest[12] = hex_to_u32 ((const u8 *) &input_buf[ 96]);
18500 digest[13] = hex_to_u32 ((const u8 *) &input_buf[104]);
18501 digest[14] = hex_to_u32 ((const u8 *) &input_buf[112]);
18502 digest[15] = hex_to_u32 ((const u8 *) &input_buf[120]);
18503
18504 digest[ 0] = byte_swap_32 (digest[ 0]);
18505 digest[ 1] = byte_swap_32 (digest[ 1]);
18506 digest[ 2] = byte_swap_32 (digest[ 2]);
18507 digest[ 3] = byte_swap_32 (digest[ 3]);
18508 digest[ 4] = byte_swap_32 (digest[ 4]);
18509 digest[ 5] = byte_swap_32 (digest[ 5]);
18510 digest[ 6] = byte_swap_32 (digest[ 6]);
18511 digest[ 7] = byte_swap_32 (digest[ 7]);
18512 digest[ 8] = byte_swap_32 (digest[ 8]);
18513 digest[ 9] = byte_swap_32 (digest[ 9]);
18514 digest[10] = byte_swap_32 (digest[10]);
18515 digest[11] = byte_swap_32 (digest[11]);
18516 digest[12] = byte_swap_32 (digest[12]);
18517 digest[13] = byte_swap_32 (digest[13]);
18518 digest[14] = byte_swap_32 (digest[14]);
18519 digest[15] = byte_swap_32 (digest[15]);
18520
18521 return (PARSER_OK);
18522 }
18523
18524 int pbkdf2_md5_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
18525 {
18526 if ((input_len < DISPLAY_LEN_MIN_11900) || (input_len > DISPLAY_LEN_MAX_11900)) return (PARSER_GLOBAL_LENGTH);
18527
18528 if (memcmp (SIGNATURE_PBKDF2_MD5, input_buf, 4)) return (PARSER_SIGNATURE_UNMATCHED);
18529
18530 u32 *digest = (u32 *) hash_buf->digest;
18531
18532 salt_t *salt = hash_buf->salt;
18533
18534 pbkdf2_md5_t *pbkdf2_md5 = (pbkdf2_md5_t *) hash_buf->esalt;
18535
18536 /**
18537 * parse line
18538 */
18539
18540 // iterations
18541
18542 char *iter_pos = input_buf + 4;
18543
18544 u32 iter = atoi (iter_pos);
18545
18546 if (iter < 1) return (PARSER_SALT_ITERATION);
18547 if (iter > 999999) return (PARSER_SALT_ITERATION);
18548
18549 // first is *raw* salt
18550
18551 char *salt_pos = strchr (iter_pos, ':');
18552
18553 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18554
18555 salt_pos++;
18556
18557 char *hash_pos = strchr (salt_pos, ':');
18558
18559 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18560
18561 u32 salt_len = hash_pos - salt_pos;
18562
18563 if (salt_len > 64) return (PARSER_SALT_LENGTH);
18564
18565 hash_pos++;
18566
18567 u32 hash_b64_len = input_len - (hash_pos - input_buf);
18568
18569 if (hash_b64_len > 88) return (PARSER_HASH_LENGTH);
18570
18571 // decode salt
18572
18573 char *salt_buf_ptr = (char *) pbkdf2_md5->salt_buf;
18574
18575 salt_len = parse_and_store_salt (salt_buf_ptr, salt_pos, salt_len);
18576
18577 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
18578
18579 salt_buf_ptr[salt_len + 3] = 0x01;
18580 salt_buf_ptr[salt_len + 4] = 0x80;
18581
18582 salt->salt_len = salt_len;
18583 salt->salt_iter = iter - 1;
18584
18585 // decode hash
18586
18587 u8 tmp_buf[100] = { 0 };
18588
18589 int hash_len = base64_decode (base64_to_int, (const u8 *) hash_pos, hash_b64_len, tmp_buf);
18590
18591 if (hash_len < 16) return (PARSER_HASH_LENGTH);
18592
18593 memcpy (digest, tmp_buf, 16);
18594
18595 // add some stuff to normal salt to make sorted happy
18596
18597 salt->salt_buf[0] = pbkdf2_md5->salt_buf[0];
18598 salt->salt_buf[1] = pbkdf2_md5->salt_buf[1];
18599 salt->salt_buf[2] = pbkdf2_md5->salt_buf[2];
18600 salt->salt_buf[3] = pbkdf2_md5->salt_buf[3];
18601 salt->salt_buf[4] = salt->salt_iter;
18602
18603 return (PARSER_OK);
18604 }
18605
18606 int pbkdf2_sha1_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
18607 {
18608 if ((input_len < DISPLAY_LEN_MIN_12000) || (input_len > DISPLAY_LEN_MAX_12000)) return (PARSER_GLOBAL_LENGTH);
18609
18610 if (memcmp (SIGNATURE_PBKDF2_SHA1, input_buf, 5)) return (PARSER_SIGNATURE_UNMATCHED);
18611
18612 u32 *digest = (u32 *) hash_buf->digest;
18613
18614 salt_t *salt = hash_buf->salt;
18615
18616 pbkdf2_sha1_t *pbkdf2_sha1 = (pbkdf2_sha1_t *) hash_buf->esalt;
18617
18618 /**
18619 * parse line
18620 */
18621
18622 // iterations
18623
18624 char *iter_pos = input_buf + 5;
18625
18626 u32 iter = atoi (iter_pos);
18627
18628 if (iter < 1) return (PARSER_SALT_ITERATION);
18629 if (iter > 999999) return (PARSER_SALT_ITERATION);
18630
18631 // first is *raw* salt
18632
18633 char *salt_pos = strchr (iter_pos, ':');
18634
18635 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18636
18637 salt_pos++;
18638
18639 char *hash_pos = strchr (salt_pos, ':');
18640
18641 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18642
18643 u32 salt_len = hash_pos - salt_pos;
18644
18645 if (salt_len > 64) return (PARSER_SALT_LENGTH);
18646
18647 hash_pos++;
18648
18649 u32 hash_b64_len = input_len - (hash_pos - input_buf);
18650
18651 if (hash_b64_len > 88) return (PARSER_HASH_LENGTH);
18652
18653 // decode salt
18654
18655 char *salt_buf_ptr = (char *) pbkdf2_sha1->salt_buf;
18656
18657 salt_len = parse_and_store_salt (salt_buf_ptr, salt_pos, salt_len);
18658
18659 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
18660
18661 salt_buf_ptr[salt_len + 3] = 0x01;
18662 salt_buf_ptr[salt_len + 4] = 0x80;
18663
18664 salt->salt_len = salt_len;
18665 salt->salt_iter = iter - 1;
18666
18667 // decode hash
18668
18669 u8 tmp_buf[100] = { 0 };
18670
18671 int hash_len = base64_decode (base64_to_int, (const u8 *) hash_pos, hash_b64_len, tmp_buf);
18672
18673 if (hash_len < 16) return (PARSER_HASH_LENGTH);
18674
18675 memcpy (digest, tmp_buf, 16);
18676
18677 digest[0] = byte_swap_32 (digest[0]);
18678 digest[1] = byte_swap_32 (digest[1]);
18679 digest[2] = byte_swap_32 (digest[2]);
18680 digest[3] = byte_swap_32 (digest[3]);
18681
18682 // add some stuff to normal salt to make sorted happy
18683
18684 salt->salt_buf[0] = pbkdf2_sha1->salt_buf[0];
18685 salt->salt_buf[1] = pbkdf2_sha1->salt_buf[1];
18686 salt->salt_buf[2] = pbkdf2_sha1->salt_buf[2];
18687 salt->salt_buf[3] = pbkdf2_sha1->salt_buf[3];
18688 salt->salt_buf[4] = salt->salt_iter;
18689
18690 return (PARSER_OK);
18691 }
18692
18693 int pbkdf2_sha512_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
18694 {
18695 if ((input_len < DISPLAY_LEN_MIN_12100) || (input_len > DISPLAY_LEN_MAX_12100)) return (PARSER_GLOBAL_LENGTH);
18696
18697 if (memcmp (SIGNATURE_PBKDF2_SHA512, input_buf, 7)) return (PARSER_SIGNATURE_UNMATCHED);
18698
18699 u64 *digest = (u64 *) hash_buf->digest;
18700
18701 salt_t *salt = hash_buf->salt;
18702
18703 pbkdf2_sha512_t *pbkdf2_sha512 = (pbkdf2_sha512_t *) hash_buf->esalt;
18704
18705 /**
18706 * parse line
18707 */
18708
18709 // iterations
18710
18711 char *iter_pos = input_buf + 7;
18712
18713 u32 iter = atoi (iter_pos);
18714
18715 if (iter < 1) return (PARSER_SALT_ITERATION);
18716 if (iter > 999999) return (PARSER_SALT_ITERATION);
18717
18718 // first is *raw* salt
18719
18720 char *salt_pos = strchr (iter_pos, ':');
18721
18722 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18723
18724 salt_pos++;
18725
18726 char *hash_pos = strchr (salt_pos, ':');
18727
18728 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18729
18730 u32 salt_len = hash_pos - salt_pos;
18731
18732 if (salt_len > 64) return (PARSER_SALT_LENGTH);
18733
18734 hash_pos++;
18735
18736 u32 hash_b64_len = input_len - (hash_pos - input_buf);
18737
18738 if (hash_b64_len > 88) return (PARSER_HASH_LENGTH);
18739
18740 // decode salt
18741
18742 char *salt_buf_ptr = (char *) pbkdf2_sha512->salt_buf;
18743
18744 salt_len = parse_and_store_salt (salt_buf_ptr, salt_pos, salt_len);
18745
18746 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
18747
18748 salt_buf_ptr[salt_len + 3] = 0x01;
18749 salt_buf_ptr[salt_len + 4] = 0x80;
18750
18751 salt->salt_len = salt_len;
18752 salt->salt_iter = iter - 1;
18753
18754 // decode hash
18755
18756 u8 tmp_buf[100] = { 0 };
18757
18758 int hash_len = base64_decode (base64_to_int, (const u8 *) hash_pos, hash_b64_len, tmp_buf);
18759
18760 if (hash_len < 16) return (PARSER_HASH_LENGTH);
18761
18762 memcpy (digest, tmp_buf, 64);
18763
18764 digest[0] = byte_swap_64 (digest[0]);
18765 digest[1] = byte_swap_64 (digest[1]);
18766 digest[2] = byte_swap_64 (digest[2]);
18767 digest[3] = byte_swap_64 (digest[3]);
18768 digest[4] = byte_swap_64 (digest[4]);
18769 digest[5] = byte_swap_64 (digest[5]);
18770 digest[6] = byte_swap_64 (digest[6]);
18771 digest[7] = byte_swap_64 (digest[7]);
18772
18773 // add some stuff to normal salt to make sorted happy
18774
18775 salt->salt_buf[0] = pbkdf2_sha512->salt_buf[0];
18776 salt->salt_buf[1] = pbkdf2_sha512->salt_buf[1];
18777 salt->salt_buf[2] = pbkdf2_sha512->salt_buf[2];
18778 salt->salt_buf[3] = pbkdf2_sha512->salt_buf[3];
18779 salt->salt_buf[4] = salt->salt_iter;
18780
18781 return (PARSER_OK);
18782 }
18783
18784 int ecryptfs_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
18785 {
18786 if ((input_len < DISPLAY_LEN_MIN_12200) || (input_len > DISPLAY_LEN_MAX_12200)) return (PARSER_GLOBAL_LENGTH);
18787
18788 if (memcmp (SIGNATURE_ECRYPTFS, input_buf, 10)) return (PARSER_SIGNATURE_UNMATCHED);
18789
18790 uint *digest = (uint *) hash_buf->digest;
18791
18792 salt_t *salt = hash_buf->salt;
18793
18794 /**
18795 * parse line
18796 */
18797
18798 char *salt_pos = input_buf + 10 + 2 + 2; // skip over "0$" and "1$"
18799
18800 char *hash_pos = strchr (salt_pos, '$');
18801
18802 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18803
18804 u32 salt_len = hash_pos - salt_pos;
18805
18806 if (salt_len != 16) return (PARSER_SALT_LENGTH);
18807
18808 hash_pos++;
18809
18810 u32 hash_len = input_len - 10 - 2 - 2 - salt_len - 1;
18811
18812 if (hash_len != 16) return (PARSER_HASH_LENGTH);
18813
18814 // decode hash
18815
18816 digest[ 0] = hex_to_u32 ((const u8 *) &hash_pos[0]);
18817 digest[ 1] = hex_to_u32 ((const u8 *) &hash_pos[8]);
18818 digest[ 2] = 0;
18819 digest[ 3] = 0;
18820 digest[ 4] = 0;
18821 digest[ 5] = 0;
18822 digest[ 6] = 0;
18823 digest[ 7] = 0;
18824 digest[ 8] = 0;
18825 digest[ 9] = 0;
18826 digest[10] = 0;
18827 digest[11] = 0;
18828 digest[12] = 0;
18829 digest[13] = 0;
18830 digest[14] = 0;
18831 digest[15] = 0;
18832
18833 // decode salt
18834
18835 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &salt_pos[0]);
18836 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &salt_pos[8]);
18837
18838 salt->salt_iter = ROUNDS_ECRYPTFS;
18839 salt->salt_len = 8;
18840
18841 return (PARSER_OK);
18842 }
18843
18844 int bsdicrypt_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
18845 {
18846 if ((input_len < DISPLAY_LEN_MIN_12400) || (input_len > DISPLAY_LEN_MAX_12400)) return (PARSER_GLOBAL_LENGTH);
18847
18848 if (memcmp (SIGNATURE_BSDICRYPT, input_buf, 1)) return (PARSER_SIGNATURE_UNMATCHED);
18849
18850 unsigned char c19 = itoa64_to_int (input_buf[19]);
18851
18852 if (c19 & 3) return (PARSER_HASH_VALUE);
18853
18854 salt_t *salt = hash_buf->salt;
18855
18856 u32 *digest = (u32 *) hash_buf->digest;
18857
18858 // iteration count
18859
18860 salt->salt_iter = itoa64_to_int (input_buf[1])
18861 | itoa64_to_int (input_buf[2]) << 6
18862 | itoa64_to_int (input_buf[3]) << 12
18863 | itoa64_to_int (input_buf[4]) << 18;
18864
18865 // set salt
18866
18867 salt->salt_buf[0] = itoa64_to_int (input_buf[5])
18868 | itoa64_to_int (input_buf[6]) << 6
18869 | itoa64_to_int (input_buf[7]) << 12
18870 | itoa64_to_int (input_buf[8]) << 18;
18871
18872 salt->salt_len = 4;
18873
18874 u8 tmp_buf[100] = { 0 };
18875
18876 base64_decode (itoa64_to_int, (const u8 *) input_buf + 9, 11, tmp_buf);
18877
18878 memcpy (digest, tmp_buf, 8);
18879
18880 uint tt;
18881
18882 IP (digest[0], digest[1], tt);
18883
18884 digest[0] = rotr32 (digest[0], 31);
18885 digest[1] = rotr32 (digest[1], 31);
18886 digest[2] = 0;
18887 digest[3] = 0;
18888
18889 return (PARSER_OK);
18890 }
18891
18892 int rar3hp_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
18893 {
18894 if ((input_len < DISPLAY_LEN_MIN_12500) || (input_len > DISPLAY_LEN_MAX_12500)) return (PARSER_GLOBAL_LENGTH);
18895
18896 if (memcmp (SIGNATURE_RAR3, input_buf, 6)) return (PARSER_SIGNATURE_UNMATCHED);
18897
18898 u32 *digest = (u32 *) hash_buf->digest;
18899
18900 salt_t *salt = hash_buf->salt;
18901
18902 /**
18903 * parse line
18904 */
18905
18906 char *type_pos = input_buf + 6 + 1;
18907
18908 char *salt_pos = strchr (type_pos, '*');
18909
18910 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18911
18912 u32 type_len = salt_pos - type_pos;
18913
18914 if (type_len != 1) return (PARSER_SALT_LENGTH);
18915
18916 salt_pos++;
18917
18918 char *crypted_pos = strchr (salt_pos, '*');
18919
18920 if (crypted_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18921
18922 u32 salt_len = crypted_pos - salt_pos;
18923
18924 if (salt_len != 16) return (PARSER_SALT_LENGTH);
18925
18926 crypted_pos++;
18927
18928 u32 crypted_len = input_len - 6 - 1 - type_len - 1 - salt_len - 1;
18929
18930 if (crypted_len != 32) return (PARSER_SALT_LENGTH);
18931
18932 /**
18933 * copy data
18934 */
18935
18936 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &salt_pos[0]);
18937 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &salt_pos[8]);
18938
18939 salt->salt_buf[0] = byte_swap_32 (salt->salt_buf[0]);
18940 salt->salt_buf[1] = byte_swap_32 (salt->salt_buf[1]);
18941
18942 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &crypted_pos[ 0]);
18943 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &crypted_pos[ 8]);
18944 salt->salt_buf[4] = hex_to_u32 ((const u8 *) &crypted_pos[16]);
18945 salt->salt_buf[5] = hex_to_u32 ((const u8 *) &crypted_pos[24]);
18946
18947 salt->salt_len = 24;
18948 salt->salt_iter = ROUNDS_RAR3;
18949
18950 // there's no hash for rar3. the data which is in crypted_pos is some encrypted data and
18951 // if it matches the value \xc4\x3d\x7b\x00\x40\x07\x00 after decrypt we know that we successfully cracked it.
18952
18953 digest[0] = 0xc43d7b00;
18954 digest[1] = 0x40070000;
18955 digest[2] = 0;
18956 digest[3] = 0;
18957
18958 return (PARSER_OK);
18959 }
18960
18961 int rar5_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
18962 {
18963 if ((input_len < DISPLAY_LEN_MIN_13000) || (input_len > DISPLAY_LEN_MAX_13000)) return (PARSER_GLOBAL_LENGTH);
18964
18965 if (memcmp (SIGNATURE_RAR5, input_buf, 1 + 4 + 1)) return (PARSER_SIGNATURE_UNMATCHED);
18966
18967 u32 *digest = (u32 *) hash_buf->digest;
18968
18969 salt_t *salt = hash_buf->salt;
18970
18971 rar5_t *rar5 = (rar5_t *) hash_buf->esalt;
18972
18973 /**
18974 * parse line
18975 */
18976
18977 char *param0_pos = input_buf + 1 + 4 + 1;
18978
18979 char *param1_pos = strchr (param0_pos, '$');
18980
18981 if (param1_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18982
18983 u32 param0_len = param1_pos - param0_pos;
18984
18985 param1_pos++;
18986
18987 char *param2_pos = strchr (param1_pos, '$');
18988
18989 if (param2_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18990
18991 u32 param1_len = param2_pos - param1_pos;
18992
18993 param2_pos++;
18994
18995 char *param3_pos = strchr (param2_pos, '$');
18996
18997 if (param3_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
18998
18999 u32 param2_len = param3_pos - param2_pos;
19000
19001 param3_pos++;
19002
19003 char *param4_pos = strchr (param3_pos, '$');
19004
19005 if (param4_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19006
19007 u32 param3_len = param4_pos - param3_pos;
19008
19009 param4_pos++;
19010
19011 char *param5_pos = strchr (param4_pos, '$');
19012
19013 if (param5_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19014
19015 u32 param4_len = param5_pos - param4_pos;
19016
19017 param5_pos++;
19018
19019 u32 param5_len = input_len - 1 - 4 - 1 - param0_len - 1 - param1_len - 1 - param2_len - 1 - param3_len - 1 - param4_len - 1;
19020
19021 char *salt_buf = param1_pos;
19022 char *iv = param3_pos;
19023 char *pswcheck = param5_pos;
19024
19025 const uint salt_len = atoi (param0_pos);
19026 const uint iterations = atoi (param2_pos);
19027 const uint pswcheck_len = atoi (param4_pos);
19028
19029 /**
19030 * verify some data
19031 */
19032
19033 if (param1_len != 32) return (PARSER_SALT_VALUE);
19034 if (param3_len != 32) return (PARSER_SALT_VALUE);
19035 if (param5_len != 16) return (PARSER_SALT_VALUE);
19036
19037 if (salt_len != 16) return (PARSER_SALT_VALUE);
19038 if (iterations == 0) return (PARSER_SALT_VALUE);
19039 if (pswcheck_len != 8) return (PARSER_SALT_VALUE);
19040
19041 /**
19042 * store data
19043 */
19044
19045 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &salt_buf[ 0]);
19046 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &salt_buf[ 8]);
19047 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &salt_buf[16]);
19048 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &salt_buf[24]);
19049
19050 rar5->iv[0] = hex_to_u32 ((const u8 *) &iv[ 0]);
19051 rar5->iv[1] = hex_to_u32 ((const u8 *) &iv[ 8]);
19052 rar5->iv[2] = hex_to_u32 ((const u8 *) &iv[16]);
19053 rar5->iv[3] = hex_to_u32 ((const u8 *) &iv[24]);
19054
19055 salt->salt_len = 16;
19056
19057 salt->salt_sign[0] = iterations;
19058
19059 salt->salt_iter = ((1 << iterations) + 32) - 1;
19060
19061 /**
19062 * digest buf
19063 */
19064
19065 digest[0] = hex_to_u32 ((const u8 *) &pswcheck[ 0]);
19066 digest[1] = hex_to_u32 ((const u8 *) &pswcheck[ 8]);
19067 digest[2] = 0;
19068 digest[3] = 0;
19069
19070 return (PARSER_OK);
19071 }
19072
19073 int krb5tgs_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
19074 {
19075 if ((input_len < DISPLAY_LEN_MIN_13100) || (input_len > DISPLAY_LEN_MAX_13100)) return (PARSER_GLOBAL_LENGTH);
19076
19077 if (memcmp (SIGNATURE_KRB5TGS, input_buf, 11)) return (PARSER_SIGNATURE_UNMATCHED);
19078
19079 u32 *digest = (u32 *) hash_buf->digest;
19080
19081 salt_t *salt = hash_buf->salt;
19082
19083 krb5tgs_t *krb5tgs = (krb5tgs_t *) hash_buf->esalt;
19084
19085 /**
19086 * parse line
19087 */
19088
19089 /* Skip '$' */
19090 char *account_pos = input_buf + 11 + 1;
19091
19092 char *data_pos;
19093
19094 uint data_len;
19095
19096 if (account_pos[0] == '*')
19097 {
19098 account_pos++;
19099
19100 data_pos = strchr (account_pos, '*');
19101
19102 /* Skip '*' */
19103 data_pos++;
19104
19105 if (data_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19106
19107 uint account_len = data_pos - account_pos + 1;
19108
19109 if (account_len >= 512) return (PARSER_SALT_LENGTH);
19110
19111 /* Skip '$' */
19112 data_pos++;
19113
19114 data_len = input_len - 11 - 1 - account_len - 2;
19115
19116 memcpy (krb5tgs->account_info, account_pos - 1, account_len);
19117 }
19118 else
19119 {
19120 /* assume $krb5tgs$23$checksum$edata2 */
19121 data_pos = account_pos;
19122
19123 memcpy (krb5tgs->account_info, "**", 3);
19124
19125 data_len = input_len - 11 - 1 - 1;
19126 }
19127
19128 if (data_len < ((16 + 32) * 2)) return (PARSER_SALT_LENGTH);
19129
19130 char *checksum_ptr = (char *) krb5tgs->checksum;
19131
19132 for (uint i = 0; i < 16 * 2; i += 2)
19133 {
19134 const char p0 = data_pos[i + 0];
19135 const char p1 = data_pos[i + 1];
19136
19137 *checksum_ptr++ = hex_convert (p1) << 0
19138 | hex_convert (p0) << 4;
19139 }
19140
19141 char *edata_ptr = (char *) krb5tgs->edata2;
19142
19143 krb5tgs->edata2_len = (data_len - 32) / 2 ;
19144
19145 /* skip '$' */
19146 for (uint i = 16 * 2 + 1; i < (krb5tgs->edata2_len * 2) + (16 * 2 + 1); i += 2)
19147 {
19148 const char p0 = data_pos[i + 0];
19149 const char p1 = data_pos[i + 1];
19150 *edata_ptr++ = hex_convert (p1) << 0
19151 | hex_convert (p0) << 4;
19152 }
19153
19154 /* this is needed for hmac_md5 */
19155 *edata_ptr++ = 0x80;
19156
19157 salt->salt_buf[0] = krb5tgs->checksum[0];
19158 salt->salt_buf[1] = krb5tgs->checksum[1];
19159 salt->salt_buf[2] = krb5tgs->checksum[2];
19160 salt->salt_buf[3] = krb5tgs->checksum[3];
19161
19162 salt->salt_len = 32;
19163
19164 digest[0] = krb5tgs->checksum[0];
19165 digest[1] = krb5tgs->checksum[1];
19166 digest[2] = krb5tgs->checksum[2];
19167 digest[3] = krb5tgs->checksum[3];
19168
19169 return (PARSER_OK);
19170 }
19171
19172 int axcrypt_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
19173 {
19174 if ((input_len < DISPLAY_LEN_MIN_13200) || (input_len > DISPLAY_LEN_MAX_13200)) return (PARSER_GLOBAL_LENGTH);
19175
19176 if (memcmp (SIGNATURE_AXCRYPT, input_buf, 11)) return (PARSER_SIGNATURE_UNMATCHED);
19177
19178 u32 *digest = (u32 *) hash_buf->digest;
19179
19180 salt_t *salt = hash_buf->salt;
19181
19182 /**
19183 * parse line
19184 */
19185
19186 /* Skip '*' */
19187 char *wrapping_rounds_pos = input_buf + 11 + 1;
19188
19189 char *salt_pos;
19190
19191 char *wrapped_key_pos;
19192
19193 char *data_pos;
19194
19195 salt->salt_iter = atoi (wrapping_rounds_pos);
19196
19197 salt_pos = strchr (wrapping_rounds_pos, '*');
19198
19199 if (salt_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19200
19201 uint wrapping_rounds_len = salt_pos - wrapping_rounds_pos;
19202
19203 /* Skip '*' */
19204 salt_pos++;
19205
19206 data_pos = salt_pos;
19207
19208 wrapped_key_pos = strchr (salt_pos, '*');
19209
19210 if (wrapped_key_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19211
19212 uint salt_len = wrapped_key_pos - salt_pos;
19213
19214 if (salt_len != 32) return (PARSER_SALT_LENGTH);
19215
19216 /* Skip '*' */
19217 wrapped_key_pos++;
19218
19219 uint wrapped_key_len = input_len - 11 - 1 - wrapping_rounds_len - 1 - salt_len - 1;
19220
19221 if (wrapped_key_len != 48) return (PARSER_SALT_LENGTH);
19222
19223 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &data_pos[ 0]);
19224 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &data_pos[ 8]);
19225 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &data_pos[16]);
19226 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &data_pos[24]);
19227
19228 data_pos += 33;
19229
19230 salt->salt_buf[4] = hex_to_u32 ((const u8 *) &data_pos[ 0]);
19231 salt->salt_buf[5] = hex_to_u32 ((const u8 *) &data_pos[ 8]);
19232 salt->salt_buf[6] = hex_to_u32 ((const u8 *) &data_pos[16]);
19233 salt->salt_buf[7] = hex_to_u32 ((const u8 *) &data_pos[24]);
19234 salt->salt_buf[8] = hex_to_u32 ((const u8 *) &data_pos[32]);
19235 salt->salt_buf[9] = hex_to_u32 ((const u8 *) &data_pos[40]);
19236
19237 salt->salt_len = 40;
19238
19239 digest[0] = salt->salt_buf[0];
19240 digest[1] = salt->salt_buf[1];
19241 digest[2] = salt->salt_buf[2];
19242 digest[3] = salt->salt_buf[3];
19243
19244 return (PARSER_OK);
19245 }
19246
19247 int keepass_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
19248 {
19249 if ((input_len < DISPLAY_LEN_MIN_13400) || (input_len > DISPLAY_LEN_MAX_13400)) return (PARSER_GLOBAL_LENGTH);
19250
19251 if (memcmp (SIGNATURE_KEEPASS, input_buf, 9)) return (PARSER_SIGNATURE_UNMATCHED);
19252
19253 u32 *digest = (u32 *) hash_buf->digest;
19254
19255 salt_t *salt = hash_buf->salt;
19256
19257 keepass_t *keepass = (keepass_t *) hash_buf->esalt;
19258
19259 /**
19260 * parse line
19261 */
19262
19263 char *version_pos;
19264
19265 char *rounds_pos;
19266
19267 char *algorithm_pos;
19268
19269 char *final_random_seed_pos;
19270 u32 final_random_seed_len;
19271
19272 char *transf_random_seed_pos;
19273 u32 transf_random_seed_len;
19274
19275 char *enc_iv_pos;
19276 u32 enc_iv_len;
19277
19278 /* default is no keyfile provided */
19279 char *keyfile_len_pos;
19280 u32 keyfile_len = 0;
19281 u32 is_keyfile_present = 0;
19282 char *keyfile_inline_pos;
19283 char *keyfile_pos;
19284
19285 /* specific to version 1 */
19286 char *contents_len_pos;
19287 u32 contents_len;
19288 char *contents_pos;
19289
19290 /* specific to version 2 */
19291 char *expected_bytes_pos;
19292 u32 expected_bytes_len;
19293
19294 char *contents_hash_pos;
19295 u32 contents_hash_len;
19296
19297 version_pos = input_buf + 8 + 1 + 1;
19298
19299 keepass->version = atoi (version_pos);
19300
19301 rounds_pos = strchr (version_pos, '*');
19302
19303 if (rounds_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19304
19305 rounds_pos++;
19306
19307 salt->salt_iter = (atoi (rounds_pos));
19308
19309 algorithm_pos = strchr (rounds_pos, '*');
19310
19311 if (algorithm_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19312
19313 algorithm_pos++;
19314
19315 keepass->algorithm = atoi (algorithm_pos);
19316
19317 final_random_seed_pos = strchr (algorithm_pos, '*');
19318
19319 if (final_random_seed_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19320
19321 final_random_seed_pos++;
19322
19323 keepass->final_random_seed[0] = hex_to_u32 ((const u8 *) &final_random_seed_pos[ 0]);
19324 keepass->final_random_seed[1] = hex_to_u32 ((const u8 *) &final_random_seed_pos[ 8]);
19325 keepass->final_random_seed[2] = hex_to_u32 ((const u8 *) &final_random_seed_pos[16]);
19326 keepass->final_random_seed[3] = hex_to_u32 ((const u8 *) &final_random_seed_pos[24]);
19327
19328 if (keepass->version == 2)
19329 {
19330 keepass->final_random_seed[4] = hex_to_u32 ((const u8 *) &final_random_seed_pos[32]);
19331 keepass->final_random_seed[5] = hex_to_u32 ((const u8 *) &final_random_seed_pos[40]);
19332 keepass->final_random_seed[6] = hex_to_u32 ((const u8 *) &final_random_seed_pos[48]);
19333 keepass->final_random_seed[7] = hex_to_u32 ((const u8 *) &final_random_seed_pos[56]);
19334 }
19335
19336 transf_random_seed_pos = strchr (final_random_seed_pos, '*');
19337
19338 if (transf_random_seed_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19339
19340 final_random_seed_len = transf_random_seed_pos - final_random_seed_pos;
19341
19342 if (keepass->version == 1 && final_random_seed_len != 32) return (PARSER_SALT_LENGTH);
19343 if (keepass->version == 2 && final_random_seed_len != 64) return (PARSER_SALT_LENGTH);
19344
19345 transf_random_seed_pos++;
19346
19347 keepass->transf_random_seed[0] = hex_to_u32 ((const u8 *) &transf_random_seed_pos[ 0]);
19348 keepass->transf_random_seed[1] = hex_to_u32 ((const u8 *) &transf_random_seed_pos[ 8]);
19349 keepass->transf_random_seed[2] = hex_to_u32 ((const u8 *) &transf_random_seed_pos[16]);
19350 keepass->transf_random_seed[3] = hex_to_u32 ((const u8 *) &transf_random_seed_pos[24]);
19351 keepass->transf_random_seed[4] = hex_to_u32 ((const u8 *) &transf_random_seed_pos[32]);
19352 keepass->transf_random_seed[5] = hex_to_u32 ((const u8 *) &transf_random_seed_pos[40]);
19353 keepass->transf_random_seed[6] = hex_to_u32 ((const u8 *) &transf_random_seed_pos[48]);
19354 keepass->transf_random_seed[7] = hex_to_u32 ((const u8 *) &transf_random_seed_pos[56]);
19355
19356 enc_iv_pos = strchr (transf_random_seed_pos, '*');
19357
19358 if (enc_iv_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19359
19360 transf_random_seed_len = enc_iv_pos - transf_random_seed_pos;
19361
19362 if (transf_random_seed_len != 64) return (PARSER_SALT_LENGTH);
19363
19364 enc_iv_pos++;
19365
19366 keepass->enc_iv[0] = hex_to_u32 ((const u8 *) &enc_iv_pos[ 0]);
19367 keepass->enc_iv[1] = hex_to_u32 ((const u8 *) &enc_iv_pos[ 8]);
19368 keepass->enc_iv[2] = hex_to_u32 ((const u8 *) &enc_iv_pos[16]);
19369 keepass->enc_iv[3] = hex_to_u32 ((const u8 *) &enc_iv_pos[24]);
19370
19371 if (keepass->version == 1)
19372 {
19373 contents_hash_pos = strchr (enc_iv_pos, '*');
19374
19375 if (contents_hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19376
19377 enc_iv_len = contents_hash_pos - enc_iv_pos;
19378
19379 if (enc_iv_len != 32) return (PARSER_SALT_LENGTH);
19380
19381 contents_hash_pos++;
19382
19383 keepass->contents_hash[0] = hex_to_u32 ((const u8 *) &contents_hash_pos[ 0]);
19384 keepass->contents_hash[1] = hex_to_u32 ((const u8 *) &contents_hash_pos[ 8]);
19385 keepass->contents_hash[2] = hex_to_u32 ((const u8 *) &contents_hash_pos[16]);
19386 keepass->contents_hash[3] = hex_to_u32 ((const u8 *) &contents_hash_pos[24]);
19387 keepass->contents_hash[4] = hex_to_u32 ((const u8 *) &contents_hash_pos[32]);
19388 keepass->contents_hash[5] = hex_to_u32 ((const u8 *) &contents_hash_pos[40]);
19389 keepass->contents_hash[6] = hex_to_u32 ((const u8 *) &contents_hash_pos[48]);
19390 keepass->contents_hash[7] = hex_to_u32 ((const u8 *) &contents_hash_pos[56]);
19391
19392 /* get length of contents following */
19393 char *inline_flag_pos = strchr (contents_hash_pos, '*');
19394
19395 if (inline_flag_pos == NULL) return (PARSER_SALT_LENGTH);
19396
19397 contents_hash_len = inline_flag_pos - contents_hash_pos;
19398
19399 if (contents_hash_len != 64) return (PARSER_SALT_LENGTH);
19400
19401 inline_flag_pos++;
19402
19403 u32 inline_flag = atoi (inline_flag_pos);
19404
19405 if (inline_flag != 1) return (PARSER_SALT_LENGTH);
19406
19407 contents_len_pos = strchr (inline_flag_pos, '*');
19408
19409 if (contents_len_pos == NULL) return (PARSER_SALT_LENGTH);
19410
19411 contents_len_pos++;
19412
19413 contents_len = atoi (contents_len_pos);
19414
19415 if (contents_len > 50000) return (PARSER_SALT_LENGTH);
19416
19417 contents_pos = strchr (contents_len_pos, '*');
19418
19419 if (contents_pos == NULL) return (PARSER_SALT_LENGTH);
19420
19421 contents_pos++;
19422
19423 u32 i;
19424
19425 keepass->contents_len = contents_len;
19426
19427 contents_len = contents_len / 4;
19428
19429 keyfile_inline_pos = strchr (contents_pos, '*');
19430
19431 u32 real_contents_len;
19432
19433 if (keyfile_inline_pos == NULL)
19434 real_contents_len = input_len - (contents_pos - input_buf);
19435 else
19436 {
19437 real_contents_len = keyfile_inline_pos - contents_pos;
19438 keyfile_inline_pos++;
19439 is_keyfile_present = 1;
19440 }
19441
19442 if (real_contents_len != keepass->contents_len * 2) return (PARSER_SALT_LENGTH);
19443
19444 for (i = 0; i < contents_len; i++)
19445 keepass->contents[i] = hex_to_u32 ((const u8 *) &contents_pos[i * 8]);
19446 }
19447 else if (keepass->version == 2)
19448 {
19449 expected_bytes_pos = strchr (enc_iv_pos, '*');
19450
19451 if (expected_bytes_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19452
19453 enc_iv_len = expected_bytes_pos - enc_iv_pos;
19454
19455 if (enc_iv_len != 32) return (PARSER_SALT_LENGTH);
19456
19457 expected_bytes_pos++;
19458
19459 keepass->expected_bytes[0] = hex_to_u32 ((const u8 *) &expected_bytes_pos[ 0]);
19460 keepass->expected_bytes[1] = hex_to_u32 ((const u8 *) &expected_bytes_pos[ 8]);
19461 keepass->expected_bytes[2] = hex_to_u32 ((const u8 *) &expected_bytes_pos[16]);
19462 keepass->expected_bytes[3] = hex_to_u32 ((const u8 *) &expected_bytes_pos[24]);
19463 keepass->expected_bytes[4] = hex_to_u32 ((const u8 *) &expected_bytes_pos[32]);
19464 keepass->expected_bytes[5] = hex_to_u32 ((const u8 *) &expected_bytes_pos[40]);
19465 keepass->expected_bytes[6] = hex_to_u32 ((const u8 *) &expected_bytes_pos[48]);
19466 keepass->expected_bytes[7] = hex_to_u32 ((const u8 *) &expected_bytes_pos[56]);
19467
19468 contents_hash_pos = strchr (expected_bytes_pos, '*');
19469
19470 if (contents_hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19471
19472 expected_bytes_len = contents_hash_pos - expected_bytes_pos;
19473
19474 if (expected_bytes_len != 64) return (PARSER_SALT_LENGTH);
19475
19476 contents_hash_pos++;
19477
19478 keepass->contents_hash[0] = hex_to_u32 ((const u8 *) &contents_hash_pos[ 0]);
19479 keepass->contents_hash[1] = hex_to_u32 ((const u8 *) &contents_hash_pos[ 8]);
19480 keepass->contents_hash[2] = hex_to_u32 ((const u8 *) &contents_hash_pos[16]);
19481 keepass->contents_hash[3] = hex_to_u32 ((const u8 *) &contents_hash_pos[24]);
19482 keepass->contents_hash[4] = hex_to_u32 ((const u8 *) &contents_hash_pos[32]);
19483 keepass->contents_hash[5] = hex_to_u32 ((const u8 *) &contents_hash_pos[40]);
19484 keepass->contents_hash[6] = hex_to_u32 ((const u8 *) &contents_hash_pos[48]);
19485 keepass->contents_hash[7] = hex_to_u32 ((const u8 *) &contents_hash_pos[56]);
19486
19487 keyfile_inline_pos = strchr (contents_hash_pos, '*');
19488
19489 if (keyfile_inline_pos == NULL)
19490 contents_hash_len = input_len - (int) (contents_hash_pos - input_buf);
19491 else
19492 {
19493 contents_hash_len = keyfile_inline_pos - contents_hash_pos;
19494 keyfile_inline_pos++;
19495 is_keyfile_present = 1;
19496 }
19497 if (contents_hash_len != 64) return (PARSER_SALT_LENGTH);
19498 }
19499
19500 if (is_keyfile_present != 0)
19501 {
19502 keyfile_len_pos = strchr (keyfile_inline_pos, '*');
19503
19504 keyfile_len_pos++;
19505
19506 keyfile_len = atoi (keyfile_len_pos);
19507
19508 keepass->keyfile_len = keyfile_len;
19509
19510 if (keyfile_len != 64) return (PARSER_SALT_LENGTH);
19511
19512 keyfile_pos = strchr (keyfile_len_pos, '*');
19513
19514 if (keyfile_pos == NULL) return (PARSER_SALT_LENGTH);
19515
19516 keyfile_pos++;
19517
19518 u32 real_keyfile_len = input_len - (keyfile_pos - input_buf);
19519
19520 if (real_keyfile_len != 64) return (PARSER_SALT_LENGTH);
19521
19522 keepass->keyfile[0] = hex_to_u32 ((const u8 *) &keyfile_pos[ 0]);
19523 keepass->keyfile[1] = hex_to_u32 ((const u8 *) &keyfile_pos[ 8]);
19524 keepass->keyfile[2] = hex_to_u32 ((const u8 *) &keyfile_pos[16]);
19525 keepass->keyfile[3] = hex_to_u32 ((const u8 *) &keyfile_pos[24]);
19526 keepass->keyfile[4] = hex_to_u32 ((const u8 *) &keyfile_pos[32]);
19527 keepass->keyfile[5] = hex_to_u32 ((const u8 *) &keyfile_pos[40]);
19528 keepass->keyfile[6] = hex_to_u32 ((const u8 *) &keyfile_pos[48]);
19529 keepass->keyfile[7] = hex_to_u32 ((const u8 *) &keyfile_pos[56]);
19530 }
19531
19532 digest[0] = keepass->enc_iv[0];
19533 digest[1] = keepass->enc_iv[1];
19534 digest[2] = keepass->enc_iv[2];
19535 digest[3] = keepass->enc_iv[3];
19536
19537 salt->salt_buf[0] = keepass->transf_random_seed[0];
19538 salt->salt_buf[1] = keepass->transf_random_seed[1];
19539 salt->salt_buf[2] = keepass->transf_random_seed[2];
19540 salt->salt_buf[3] = keepass->transf_random_seed[3];
19541 salt->salt_buf[4] = keepass->transf_random_seed[4];
19542 salt->salt_buf[5] = keepass->transf_random_seed[5];
19543 salt->salt_buf[6] = keepass->transf_random_seed[6];
19544 salt->salt_buf[7] = keepass->transf_random_seed[7];
19545
19546 return (PARSER_OK);
19547 }
19548
19549 int cf10_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
19550 {
19551 if ((input_len < DISPLAY_LEN_MIN_12600) || (input_len > DISPLAY_LEN_MAX_12600)) return (PARSER_GLOBAL_LENGTH);
19552
19553 u32 *digest = (u32 *) hash_buf->digest;
19554
19555 salt_t *salt = hash_buf->salt;
19556
19557 digest[0] = hex_to_u32 ((const u8 *) &input_buf[ 0]);
19558 digest[1] = hex_to_u32 ((const u8 *) &input_buf[ 8]);
19559 digest[2] = hex_to_u32 ((const u8 *) &input_buf[16]);
19560 digest[3] = hex_to_u32 ((const u8 *) &input_buf[24]);
19561 digest[4] = hex_to_u32 ((const u8 *) &input_buf[32]);
19562 digest[5] = hex_to_u32 ((const u8 *) &input_buf[40]);
19563 digest[6] = hex_to_u32 ((const u8 *) &input_buf[48]);
19564 digest[7] = hex_to_u32 ((const u8 *) &input_buf[56]);
19565
19566 if (input_buf[64] != data.separator) return (PARSER_SEPARATOR_UNMATCHED);
19567
19568 uint salt_len = input_len - 64 - 1;
19569
19570 char *salt_buf = input_buf + 64 + 1;
19571
19572 char *salt_buf_ptr = (char *) salt->salt_buf;
19573
19574 salt_len = parse_and_store_salt (salt_buf_ptr, salt_buf, salt_len);
19575
19576 if (salt_len == UINT_MAX) return (PARSER_SALT_LENGTH);
19577
19578 salt->salt_len = salt_len;
19579
19580 /**
19581 * we can precompute the first sha256 transform
19582 */
19583
19584 uint w[16] = { 0 };
19585
19586 w[ 0] = byte_swap_32 (salt->salt_buf[ 0]);
19587 w[ 1] = byte_swap_32 (salt->salt_buf[ 1]);
19588 w[ 2] = byte_swap_32 (salt->salt_buf[ 2]);
19589 w[ 3] = byte_swap_32 (salt->salt_buf[ 3]);
19590 w[ 4] = byte_swap_32 (salt->salt_buf[ 4]);
19591 w[ 5] = byte_swap_32 (salt->salt_buf[ 5]);
19592 w[ 6] = byte_swap_32 (salt->salt_buf[ 6]);
19593 w[ 7] = byte_swap_32 (salt->salt_buf[ 7]);
19594 w[ 8] = byte_swap_32 (salt->salt_buf[ 8]);
19595 w[ 9] = byte_swap_32 (salt->salt_buf[ 9]);
19596 w[10] = byte_swap_32 (salt->salt_buf[10]);
19597 w[11] = byte_swap_32 (salt->salt_buf[11]);
19598 w[12] = byte_swap_32 (salt->salt_buf[12]);
19599 w[13] = byte_swap_32 (salt->salt_buf[13]);
19600 w[14] = byte_swap_32 (salt->salt_buf[14]);
19601 w[15] = byte_swap_32 (salt->salt_buf[15]);
19602
19603 uint pc256[8] = { SHA256M_A, SHA256M_B, SHA256M_C, SHA256M_D, SHA256M_E, SHA256M_F, SHA256M_G, SHA256M_H };
19604
19605 sha256_64 (w, pc256);
19606
19607 salt->salt_buf_pc[0] = pc256[0];
19608 salt->salt_buf_pc[1] = pc256[1];
19609 salt->salt_buf_pc[2] = pc256[2];
19610 salt->salt_buf_pc[3] = pc256[3];
19611 salt->salt_buf_pc[4] = pc256[4];
19612 salt->salt_buf_pc[5] = pc256[5];
19613 salt->salt_buf_pc[6] = pc256[6];
19614 salt->salt_buf_pc[7] = pc256[7];
19615
19616 digest[0] -= pc256[0];
19617 digest[1] -= pc256[1];
19618 digest[2] -= pc256[2];
19619 digest[3] -= pc256[3];
19620 digest[4] -= pc256[4];
19621 digest[5] -= pc256[5];
19622 digest[6] -= pc256[6];
19623 digest[7] -= pc256[7];
19624
19625 return (PARSER_OK);
19626 }
19627
19628 int mywallet_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
19629 {
19630 if ((input_len < DISPLAY_LEN_MIN_12700) || (input_len > DISPLAY_LEN_MAX_12700)) return (PARSER_GLOBAL_LENGTH);
19631
19632 if (memcmp (SIGNATURE_MYWALLET, input_buf, 12)) return (PARSER_SIGNATURE_UNMATCHED);
19633
19634 u32 *digest = (u32 *) hash_buf->digest;
19635
19636 salt_t *salt = hash_buf->salt;
19637
19638 /**
19639 * parse line
19640 */
19641
19642 char *data_len_pos = input_buf + 1 + 10 + 1;
19643
19644 char *data_buf_pos = strchr (data_len_pos, '$');
19645
19646 if (data_buf_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19647
19648 u32 data_len_len = data_buf_pos - data_len_pos;
19649
19650 if (data_len_len < 1) return (PARSER_SALT_LENGTH);
19651 if (data_len_len > 5) return (PARSER_SALT_LENGTH);
19652
19653 data_buf_pos++;
19654
19655 u32 data_buf_len = input_len - 1 - 10 - 1 - data_len_len - 1;
19656
19657 if (data_buf_len < 64) return (PARSER_HASH_LENGTH);
19658
19659 if (data_buf_len % 16) return (PARSER_HASH_LENGTH);
19660
19661 u32 data_len = atoi (data_len_pos);
19662
19663 if ((data_len * 2) != data_buf_len) return (PARSER_HASH_LENGTH);
19664
19665 /**
19666 * salt
19667 */
19668
19669 char *salt_pos = data_buf_pos;
19670
19671 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &salt_pos[ 0]);
19672 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &salt_pos[ 8]);
19673 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &salt_pos[16]);
19674 salt->salt_buf[3] = hex_to_u32 ((const u8 *) &salt_pos[24]);
19675
19676 // this is actually the CT, which is also the hash later (if matched)
19677
19678 salt->salt_buf[4] = hex_to_u32 ((const u8 *) &salt_pos[32]);
19679 salt->salt_buf[5] = hex_to_u32 ((const u8 *) &salt_pos[40]);
19680 salt->salt_buf[6] = hex_to_u32 ((const u8 *) &salt_pos[48]);
19681 salt->salt_buf[7] = hex_to_u32 ((const u8 *) &salt_pos[56]);
19682
19683 salt->salt_len = 32; // note we need to fix this to 16 in kernel
19684
19685 salt->salt_iter = 10 - 1;
19686
19687 /**
19688 * digest buf
19689 */
19690
19691 digest[0] = salt->salt_buf[4];
19692 digest[1] = salt->salt_buf[5];
19693 digest[2] = salt->salt_buf[6];
19694 digest[3] = salt->salt_buf[7];
19695
19696 return (PARSER_OK);
19697 }
19698
19699 int ms_drsr_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
19700 {
19701 if ((input_len < DISPLAY_LEN_MIN_12800) || (input_len > DISPLAY_LEN_MAX_12800)) return (PARSER_GLOBAL_LENGTH);
19702
19703 if (memcmp (SIGNATURE_MS_DRSR, input_buf, 11)) return (PARSER_SIGNATURE_UNMATCHED);
19704
19705 u32 *digest = (u32 *) hash_buf->digest;
19706
19707 salt_t *salt = hash_buf->salt;
19708
19709 /**
19710 * parse line
19711 */
19712
19713 char *salt_pos = input_buf + 11 + 1;
19714
19715 char *iter_pos = strchr (salt_pos, ',');
19716
19717 if (iter_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19718
19719 u32 salt_len = iter_pos - salt_pos;
19720
19721 if (salt_len != 20) return (PARSER_SALT_LENGTH);
19722
19723 iter_pos++;
19724
19725 char *hash_pos = strchr (iter_pos, ',');
19726
19727 if (hash_pos == NULL) return (PARSER_SEPARATOR_UNMATCHED);
19728
19729 u32 iter_len = hash_pos - iter_pos;
19730
19731 if (iter_len > 5) return (PARSER_SALT_LENGTH);
19732
19733 hash_pos++;
19734
19735 u32 hash_len = input_len - 11 - 1 - salt_len - 1 - iter_len - 1;
19736
19737 if (hash_len != 64) return (PARSER_HASH_LENGTH);
19738
19739 /**
19740 * salt
19741 */
19742
19743 salt->salt_buf[0] = hex_to_u32 ((const u8 *) &salt_pos[ 0]);
19744 salt->salt_buf[1] = hex_to_u32 ((const u8 *) &salt_pos[ 8]);
19745 salt->salt_buf[2] = hex_to_u32 ((const u8 *) &salt_pos[16]) & 0xffff0000;
19746 salt->salt_buf[3] = 0x00018000;
19747
19748 salt->salt_buf[0] = byte_swap_32 (salt->salt_buf[0]);
19749 salt->salt_buf[1] = byte_swap_32 (salt->salt_buf[1]);
19750 salt->salt_buf[2] = byte_swap_32 (salt->salt_buf[2]);
19751 salt->salt_buf[3] = byte_swap_32 (salt->salt_buf[3]);
19752
19753 salt->salt_len = salt_len / 2;
19754
19755 salt->salt_iter = atoi (iter_pos) - 1;
19756
19757 /**
19758 * digest buf
19759 */
19760
19761 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
19762 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
19763 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
19764 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
19765 digest[4] = hex_to_u32 ((const u8 *) &hash_pos[32]);
19766 digest[5] = hex_to_u32 ((const u8 *) &hash_pos[40]);
19767 digest[6] = hex_to_u32 ((const u8 *) &hash_pos[48]);
19768 digest[7] = hex_to_u32 ((const u8 *) &hash_pos[56]);
19769
19770 return (PARSER_OK);
19771 }
19772
19773 int androidfde_samsung_parse_hash (char *input_buf, uint input_len, hash_t *hash_buf)
19774 {
19775 if ((input_len < DISPLAY_LEN_MIN_12900) || (input_len > DISPLAY_LEN_MAX_12900)) return (PARSER_GLOBAL_LENGTH);
19776
19777 u32 *digest = (u32 *) hash_buf->digest;
19778
19779 salt_t *salt = hash_buf->salt;
19780
19781 /**
19782 * parse line
19783 */
19784
19785 char *hash_pos = input_buf + 64;
19786 char *salt1_pos = input_buf + 128;
19787 char *salt2_pos = input_buf;
19788
19789 /**
19790 * salt
19791 */
19792
19793 salt->salt_buf[ 0] = hex_to_u32 ((const u8 *) &salt1_pos[ 0]);
19794 salt->salt_buf[ 1] = hex_to_u32 ((const u8 *) &salt1_pos[ 8]);
19795 salt->salt_buf[ 2] = hex_to_u32 ((const u8 *) &salt1_pos[16]);
19796 salt->salt_buf[ 3] = hex_to_u32 ((const u8 *) &salt1_pos[24]);
19797
19798 salt->salt_buf[ 4] = hex_to_u32 ((const u8 *) &salt2_pos[ 0]);
19799 salt->salt_buf[ 5] = hex_to_u32 ((const u8 *) &salt2_pos[ 8]);
19800 salt->salt_buf[ 6] = hex_to_u32 ((const u8 *) &salt2_pos[16]);
19801 salt->salt_buf[ 7] = hex_to_u32 ((const u8 *) &salt2_pos[24]);
19802
19803 salt->salt_buf[ 8] = hex_to_u32 ((const u8 *) &salt2_pos[32]);
19804 salt->salt_buf[ 9] = hex_to_u32 ((const u8 *) &salt2_pos[40]);
19805 salt->salt_buf[10] = hex_to_u32 ((const u8 *) &salt2_pos[48]);
19806 salt->salt_buf[11] = hex_to_u32 ((const u8 *) &salt2_pos[56]);
19807
19808 salt->salt_len = 48;
19809
19810 salt->salt_iter = ROUNDS_ANDROIDFDE_SAMSUNG - 1;
19811
19812 /**
19813 * digest buf
19814 */
19815
19816 digest[0] = hex_to_u32 ((const u8 *) &hash_pos[ 0]);
19817 digest[1] = hex_to_u32 ((const u8 *) &hash_pos[ 8]);
19818 digest[2] = hex_to_u32 ((const u8 *) &hash_pos[16]);
19819 digest[3] = hex_to_u32 ((const u8 *) &hash_pos[24]);
19820 digest[4] = hex_to_u32 ((const u8 *) &hash_pos[32]);
19821 digest[5] = hex_to_u32 ((const u8 *) &hash_pos[40]);
19822 digest[6] = hex_to_u32 ((const u8 *) &hash_pos[48]);
19823 digest[7] = hex_to_u32 ((const u8 *) &hash_pos[56]);
19824
19825 return (PARSER_OK);
19826 }
19827
19828 /**
19829 * parallel running threads
19830 */
19831
19832 #ifdef WIN
19833
19834 BOOL WINAPI sigHandler_default (DWORD sig)
19835 {
19836 switch (sig)
19837 {
19838 case CTRL_CLOSE_EVENT:
19839
19840 /*
19841 * special case see: https://stackoverflow.com/questions/3640633/c-setconsolectrlhandler-routine-issue/5610042#5610042
19842 * if the user interacts w/ the user-interface (GUI/cmd), we need to do the finalization job within this signal handler
19843 * function otherwise it is too late (e.g. after returning from this function)
19844 */
19845
19846 myabort ();
19847
19848 SetConsoleCtrlHandler (NULL, TRUE);
19849
19850 hc_sleep (10);
19851
19852 return TRUE;
19853
19854 case CTRL_C_EVENT:
19855 case CTRL_LOGOFF_EVENT:
19856 case CTRL_SHUTDOWN_EVENT:
19857
19858 myabort ();
19859
19860 SetConsoleCtrlHandler (NULL, TRUE);
19861
19862 return TRUE;
19863 }
19864
19865 return FALSE;
19866 }
19867
19868 BOOL WINAPI sigHandler_benchmark (DWORD sig)
19869 {
19870 switch (sig)
19871 {
19872 case CTRL_CLOSE_EVENT:
19873
19874 myabort ();
19875
19876 SetConsoleCtrlHandler (NULL, TRUE);
19877
19878 hc_sleep (10);
19879
19880 return TRUE;
19881
19882 case CTRL_C_EVENT:
19883 case CTRL_LOGOFF_EVENT:
19884 case CTRL_SHUTDOWN_EVENT:
19885
19886 myquit ();
19887
19888 SetConsoleCtrlHandler (NULL, TRUE);
19889
19890 return TRUE;
19891 }
19892
19893 return FALSE;
19894 }
19895
19896 void hc_signal (BOOL WINAPI (callback) (DWORD))
19897 {
19898 if (callback == NULL)
19899 {
19900 SetConsoleCtrlHandler ((PHANDLER_ROUTINE) callback, FALSE);
19901 }
19902 else
19903 {
19904 SetConsoleCtrlHandler ((PHANDLER_ROUTINE) callback, TRUE);
19905 }
19906 }
19907
19908 #else
19909
19910 void sigHandler_default (int sig)
19911 {
19912 myabort ();
19913
19914 signal (sig, NULL);
19915 }
19916
19917 void sigHandler_benchmark (int sig)
19918 {
19919 myquit ();
19920
19921 signal (sig, NULL);
19922 }
19923
19924 void hc_signal (void (callback) (int))
19925 {
19926 if (callback == NULL) callback = SIG_DFL;
19927
19928 signal (SIGINT, callback);
19929 signal (SIGTERM, callback);
19930 signal (SIGABRT, callback);
19931 }
19932
19933 #endif
19934
19935 void status_display ();
19936
19937 void *thread_keypress (void *p)
19938 {
19939 int benchmark = *((int *) p);
19940
19941 uint quiet = data.quiet;
19942
19943 tty_break();
19944
19945 while ((data.devices_status != STATUS_EXHAUSTED) && (data.devices_status != STATUS_CRACKED) && (data.devices_status != STATUS_ABORTED) && (data.devices_status != STATUS_QUIT))
19946 {
19947 int ch = tty_getchar();
19948
19949 if (ch == -1) break;
19950
19951 if (ch == 0) continue;
19952
19953 //https://github.com/hashcat/oclHashcat/issues/302
19954 //#ifdef _POSIX
19955 //if (ch != '\n')
19956 //#endif
19957
19958 hc_thread_mutex_lock (mux_display);
19959
19960 log_info ("");
19961
19962 switch (ch)
19963 {
19964 case 's':
19965 case '\r':
19966 case '\n':
19967
19968 log_info ("");
19969
19970 status_display ();
19971
19972 log_info ("");
19973
19974 if (quiet == 0) fprintf (stdout, "%s", PROMPT);
19975 if (quiet == 0) fflush (stdout);
19976
19977 break;
19978
19979 case 'b':
19980
19981 log_info ("");
19982
19983 bypass ();
19984
19985 log_info ("");
19986
19987 if (quiet == 0) fprintf (stdout, "%s", PROMPT);
19988 if (quiet == 0) fflush (stdout);
19989
19990 break;
19991
19992 case 'p':
19993
19994 log_info ("");
19995
19996 SuspendThreads ();
19997
19998 log_info ("");
19999
20000 if (quiet == 0) fprintf (stdout, "%s", PROMPT);
20001 if (quiet == 0) fflush (stdout);
20002
20003 break;
20004
20005 case 'r':
20006
20007 log_info ("");
20008
20009 ResumeThreads ();
20010
20011 log_info ("");
20012
20013 if (quiet == 0) fprintf (stdout, "%s", PROMPT);
20014 if (quiet == 0) fflush (stdout);
20015
20016 break;
20017
20018 case 'c':
20019
20020 log_info ("");
20021
20022 if (benchmark == 1) break;
20023
20024 stop_at_checkpoint ();
20025
20026 log_info ("");
20027
20028 if (quiet == 0) fprintf (stdout, "%s", PROMPT);
20029 if (quiet == 0) fflush (stdout);
20030
20031 break;
20032
20033 case 'q':
20034
20035 log_info ("");
20036
20037 if (benchmark == 1)
20038 {
20039 myquit ();
20040 }
20041 else
20042 {
20043 myabort ();
20044 }
20045
20046 break;
20047 }
20048
20049 //https://github.com/hashcat/oclHashcat/issues/302
20050 //#ifdef _POSIX
20051 //if (ch != '\n')
20052 //#endif
20053
20054 hc_thread_mutex_unlock (mux_display);
20055 }
20056
20057 tty_fix();
20058
20059 return (p);
20060 }
20061
20062 /**
20063 * rules common
20064 */
20065
20066 bool class_num (const u8 c)
20067 {
20068 return ((c >= '0') && (c <= '9'));
20069 }
20070
20071 bool class_lower (const u8 c)
20072 {
20073 return ((c >= 'a') && (c <= 'z'));
20074 }
20075
20076 bool class_upper (const u8 c)
20077 {
20078 return ((c >= 'A') && (c <= 'Z'));
20079 }
20080
20081 bool class_alpha (const u8 c)
20082 {
20083 return (class_lower (c) || class_upper (c));
20084 }
20085
20086 int conv_ctoi (const u8 c)
20087 {
20088 if (class_num (c))
20089 {
20090 return c - '0';
20091 }
20092 else if (class_upper (c))
20093 {
20094 return c - 'A' + 10;
20095 }
20096
20097 return -1;
20098 }
20099
20100 int conv_itoc (const u8 c)
20101 {
20102 if (c < 10)
20103 {
20104 return c + '0';
20105 }
20106 else if (c < 37)
20107 {
20108 return c + 'A' - 10;
20109 }
20110
20111 return -1;
20112 }
20113
20114 /**
20115 * device rules
20116 */
20117
20118 #define INCR_POS if (++rule_pos == rule_len) return (-1)
20119 #define SET_NAME(rule,val) (rule)->cmds[rule_cnt] = ((val) & 0xff) << 0
20120 #define SET_P0(rule,val) INCR_POS; (rule)->cmds[rule_cnt] |= ((val) & 0xff) << 8
20121 #define SET_P1(rule,val) INCR_POS; (rule)->cmds[rule_cnt] |= ((val) & 0xff) << 16
20122 #define MAX_KERNEL_RULES 255
20123 #define GET_NAME(rule) rule_cmd = (((rule)->cmds[rule_cnt] >> 0) & 0xff)
20124 #define GET_P0(rule) INCR_POS; rule_buf[rule_pos] = (((rule)->cmds[rule_cnt] >> 8) & 0xff)
20125 #define GET_P1(rule) INCR_POS; rule_buf[rule_pos] = (((rule)->cmds[rule_cnt] >> 16) & 0xff)
20126
20127 #define SET_P0_CONV(rule,val) INCR_POS; (rule)->cmds[rule_cnt] |= ((conv_ctoi (val)) & 0xff) << 8
20128 #define SET_P1_CONV(rule,val) INCR_POS; (rule)->cmds[rule_cnt] |= ((conv_ctoi (val)) & 0xff) << 16
20129 #define GET_P0_CONV(rule) INCR_POS; rule_buf[rule_pos] = conv_itoc (((rule)->cmds[rule_cnt] >> 8) & 0xff)
20130 #define GET_P1_CONV(rule) INCR_POS; rule_buf[rule_pos] = conv_itoc (((rule)->cmds[rule_cnt] >> 16) & 0xff)
20131
20132 int cpu_rule_to_kernel_rule (char *rule_buf, uint rule_len, kernel_rule_t *rule)
20133 {
20134 uint rule_pos;
20135 uint rule_cnt;
20136
20137 for (rule_pos = 0, rule_cnt = 0; rule_pos < rule_len && rule_cnt < MAX_KERNEL_RULES; rule_pos++, rule_cnt++)
20138 {
20139 switch (rule_buf[rule_pos])
20140 {
20141 case ' ':
20142 rule_cnt--;
20143 break;
20144
20145 case RULE_OP_MANGLE_NOOP:
20146 SET_NAME (rule, rule_buf[rule_pos]);
20147 break;
20148
20149 case RULE_OP_MANGLE_LREST:
20150 SET_NAME (rule, rule_buf[rule_pos]);
20151 break;
20152
20153 case RULE_OP_MANGLE_UREST:
20154 SET_NAME (rule, rule_buf[rule_pos]);
20155 break;
20156
20157 case RULE_OP_MANGLE_LREST_UFIRST:
20158 SET_NAME (rule, rule_buf[rule_pos]);
20159 break;
20160
20161 case RULE_OP_MANGLE_UREST_LFIRST:
20162 SET_NAME (rule, rule_buf[rule_pos]);
20163 break;
20164
20165 case RULE_OP_MANGLE_TREST:
20166 SET_NAME (rule, rule_buf[rule_pos]);
20167 break;
20168
20169 case RULE_OP_MANGLE_TOGGLE_AT:
20170 SET_NAME (rule, rule_buf[rule_pos]);
20171 SET_P0_CONV (rule, rule_buf[rule_pos]);
20172 break;
20173
20174 case RULE_OP_MANGLE_REVERSE:
20175 SET_NAME (rule, rule_buf[rule_pos]);
20176 break;
20177
20178 case RULE_OP_MANGLE_DUPEWORD:
20179 SET_NAME (rule, rule_buf[rule_pos]);
20180 break;
20181
20182 case RULE_OP_MANGLE_DUPEWORD_TIMES:
20183 SET_NAME (rule, rule_buf[rule_pos]);
20184 SET_P0_CONV (rule, rule_buf[rule_pos]);
20185 break;
20186
20187 case RULE_OP_MANGLE_REFLECT:
20188 SET_NAME (rule, rule_buf[rule_pos]);
20189 break;
20190
20191 case RULE_OP_MANGLE_ROTATE_LEFT:
20192 SET_NAME (rule, rule_buf[rule_pos]);
20193 break;
20194
20195 case RULE_OP_MANGLE_ROTATE_RIGHT:
20196 SET_NAME (rule, rule_buf[rule_pos]);
20197 break;
20198
20199 case RULE_OP_MANGLE_APPEND:
20200 SET_NAME (rule, rule_buf[rule_pos]);
20201 SET_P0 (rule, rule_buf[rule_pos]);
20202 break;
20203
20204 case RULE_OP_MANGLE_PREPEND:
20205 SET_NAME (rule, rule_buf[rule_pos]);
20206 SET_P0 (rule, rule_buf[rule_pos]);
20207 break;
20208
20209 case RULE_OP_MANGLE_DELETE_FIRST:
20210 SET_NAME (rule, rule_buf[rule_pos]);
20211 break;
20212
20213 case RULE_OP_MANGLE_DELETE_LAST:
20214 SET_NAME (rule, rule_buf[rule_pos]);
20215 break;
20216
20217 case RULE_OP_MANGLE_DELETE_AT:
20218 SET_NAME (rule, rule_buf[rule_pos]);
20219 SET_P0_CONV (rule, rule_buf[rule_pos]);
20220 break;
20221
20222 case RULE_OP_MANGLE_EXTRACT:
20223 SET_NAME (rule, rule_buf[rule_pos]);
20224 SET_P0_CONV (rule, rule_buf[rule_pos]);
20225 SET_P1_CONV (rule, rule_buf[rule_pos]);
20226 break;
20227
20228 case RULE_OP_MANGLE_OMIT:
20229 SET_NAME (rule, rule_buf[rule_pos]);
20230 SET_P0_CONV (rule, rule_buf[rule_pos]);
20231 SET_P1_CONV (rule, rule_buf[rule_pos]);
20232 break;
20233
20234 case RULE_OP_MANGLE_INSERT:
20235 SET_NAME (rule, rule_buf[rule_pos]);
20236 SET_P0_CONV (rule, rule_buf[rule_pos]);
20237 SET_P1 (rule, rule_buf[rule_pos]);
20238 break;
20239
20240 case RULE_OP_MANGLE_OVERSTRIKE:
20241 SET_NAME (rule, rule_buf[rule_pos]);
20242 SET_P0_CONV (rule, rule_buf[rule_pos]);
20243 SET_P1 (rule, rule_buf[rule_pos]);
20244 break;
20245
20246 case RULE_OP_MANGLE_TRUNCATE_AT:
20247 SET_NAME (rule, rule_buf[rule_pos]);
20248 SET_P0_CONV (rule, rule_buf[rule_pos]);
20249 break;
20250
20251 case RULE_OP_MANGLE_REPLACE:
20252 SET_NAME (rule, rule_buf[rule_pos]);
20253 SET_P0 (rule, rule_buf[rule_pos]);
20254 SET_P1 (rule, rule_buf[rule_pos]);
20255 break;
20256
20257 case RULE_OP_MANGLE_PURGECHAR:
20258 return (-1);
20259 break;
20260
20261 case RULE_OP_MANGLE_TOGGLECASE_REC:
20262 return (-1);
20263 break;
20264
20265 case RULE_OP_MANGLE_DUPECHAR_FIRST:
20266 SET_NAME (rule, rule_buf[rule_pos]);
20267 SET_P0_CONV (rule, rule_buf[rule_pos]);
20268 break;
20269
20270 case RULE_OP_MANGLE_DUPECHAR_LAST:
20271 SET_NAME (rule, rule_buf[rule_pos]);
20272 SET_P0_CONV (rule, rule_buf[rule_pos]);
20273 break;
20274
20275 case RULE_OP_MANGLE_DUPECHAR_ALL:
20276 SET_NAME (rule, rule_buf[rule_pos]);
20277 break;
20278
20279 case RULE_OP_MANGLE_SWITCH_FIRST:
20280 SET_NAME (rule, rule_buf[rule_pos]);
20281 break;
20282
20283 case RULE_OP_MANGLE_SWITCH_LAST:
20284 SET_NAME (rule, rule_buf[rule_pos]);
20285 break;
20286
20287 case RULE_OP_MANGLE_SWITCH_AT:
20288 SET_NAME (rule, rule_buf[rule_pos]);
20289 SET_P0_CONV (rule, rule_buf[rule_pos]);
20290 SET_P1_CONV (rule, rule_buf[rule_pos]);
20291 break;
20292
20293 case RULE_OP_MANGLE_CHR_SHIFTL:
20294 SET_NAME (rule, rule_buf[rule_pos]);
20295 SET_P0_CONV (rule, rule_buf[rule_pos]);
20296 break;
20297
20298 case RULE_OP_MANGLE_CHR_SHIFTR:
20299 SET_NAME (rule, rule_buf[rule_pos]);
20300 SET_P0_CONV (rule, rule_buf[rule_pos]);
20301 break;
20302
20303 case RULE_OP_MANGLE_CHR_INCR:
20304 SET_NAME (rule, rule_buf[rule_pos]);
20305 SET_P0_CONV (rule, rule_buf[rule_pos]);
20306 break;
20307
20308 case RULE_OP_MANGLE_CHR_DECR:
20309 SET_NAME (rule, rule_buf[rule_pos]);
20310 SET_P0_CONV (rule, rule_buf[rule_pos]);
20311 break;
20312
20313 case RULE_OP_MANGLE_REPLACE_NP1:
20314 SET_NAME (rule, rule_buf[rule_pos]);
20315 SET_P0_CONV (rule, rule_buf[rule_pos]);
20316 break;
20317
20318 case RULE_OP_MANGLE_REPLACE_NM1:
20319 SET_NAME (rule, rule_buf[rule_pos]);
20320 SET_P0_CONV (rule, rule_buf[rule_pos]);
20321 break;
20322
20323 case RULE_OP_MANGLE_DUPEBLOCK_FIRST:
20324 SET_NAME (rule, rule_buf[rule_pos]);
20325 SET_P0_CONV (rule, rule_buf[rule_pos]);
20326 break;
20327
20328 case RULE_OP_MANGLE_DUPEBLOCK_LAST:
20329 SET_NAME (rule, rule_buf[rule_pos]);
20330 SET_P0_CONV (rule, rule_buf[rule_pos]);
20331 break;
20332
20333 case RULE_OP_MANGLE_TITLE:
20334 SET_NAME (rule, rule_buf[rule_pos]);
20335 break;
20336
20337 default:
20338 return (-1);
20339 break;
20340 }
20341 }
20342
20343 if (rule_pos < rule_len) return (-1);
20344
20345 return (0);
20346 }
20347
20348 int kernel_rule_to_cpu_rule (char *rule_buf, kernel_rule_t *rule)
20349 {
20350 uint rule_cnt;
20351 uint rule_pos;
20352 uint rule_len = HCBUFSIZ - 1; // maximum possible len
20353
20354 char rule_cmd;
20355
20356 for (rule_cnt = 0, rule_pos = 0; rule_pos < rule_len && rule_cnt < MAX_KERNEL_RULES; rule_pos++, rule_cnt++)
20357 {
20358 GET_NAME (rule);
20359
20360 if (rule_cnt > 0) rule_buf[rule_pos++] = ' ';
20361
20362 switch (rule_cmd)
20363 {
20364 case RULE_OP_MANGLE_NOOP:
20365 rule_buf[rule_pos] = rule_cmd;
20366 break;
20367
20368 case RULE_OP_MANGLE_LREST:
20369 rule_buf[rule_pos] = rule_cmd;
20370 break;
20371
20372 case RULE_OP_MANGLE_UREST:
20373 rule_buf[rule_pos] = rule_cmd;
20374 break;
20375
20376 case RULE_OP_MANGLE_LREST_UFIRST:
20377 rule_buf[rule_pos] = rule_cmd;
20378 break;
20379
20380 case RULE_OP_MANGLE_UREST_LFIRST:
20381 rule_buf[rule_pos] = rule_cmd;
20382 break;
20383
20384 case RULE_OP_MANGLE_TREST:
20385 rule_buf[rule_pos] = rule_cmd;
20386 break;
20387
20388 case RULE_OP_MANGLE_TOGGLE_AT:
20389 rule_buf[rule_pos] = rule_cmd;
20390 GET_P0_CONV (rule);
20391 break;
20392
20393 case RULE_OP_MANGLE_REVERSE:
20394 rule_buf[rule_pos] = rule_cmd;
20395 break;
20396
20397 case RULE_OP_MANGLE_DUPEWORD:
20398 rule_buf[rule_pos] = rule_cmd;
20399 break;
20400
20401 case RULE_OP_MANGLE_DUPEWORD_TIMES:
20402 rule_buf[rule_pos] = rule_cmd;
20403 GET_P0_CONV (rule);
20404 break;
20405
20406 case RULE_OP_MANGLE_REFLECT:
20407 rule_buf[rule_pos] = rule_cmd;
20408 break;
20409
20410 case RULE_OP_MANGLE_ROTATE_LEFT:
20411 rule_buf[rule_pos] = rule_cmd;
20412 break;
20413
20414 case RULE_OP_MANGLE_ROTATE_RIGHT:
20415 rule_buf[rule_pos] = rule_cmd;
20416 break;
20417
20418 case RULE_OP_MANGLE_APPEND:
20419 rule_buf[rule_pos] = rule_cmd;
20420 GET_P0 (rule);
20421 break;
20422
20423 case RULE_OP_MANGLE_PREPEND:
20424 rule_buf[rule_pos] = rule_cmd;
20425 GET_P0 (rule);
20426 break;
20427
20428 case RULE_OP_MANGLE_DELETE_FIRST:
20429 rule_buf[rule_pos] = rule_cmd;
20430 break;
20431
20432 case RULE_OP_MANGLE_DELETE_LAST:
20433 rule_buf[rule_pos] = rule_cmd;
20434 break;
20435
20436 case RULE_OP_MANGLE_DELETE_AT:
20437 rule_buf[rule_pos] = rule_cmd;
20438 GET_P0_CONV (rule);
20439 break;
20440
20441 case RULE_OP_MANGLE_EXTRACT:
20442 rule_buf[rule_pos] = rule_cmd;
20443 GET_P0_CONV (rule);
20444 GET_P1_CONV (rule);
20445 break;
20446
20447 case RULE_OP_MANGLE_OMIT:
20448 rule_buf[rule_pos] = rule_cmd;
20449 GET_P0_CONV (rule);
20450 GET_P1_CONV (rule);
20451 break;
20452
20453 case RULE_OP_MANGLE_INSERT:
20454 rule_buf[rule_pos] = rule_cmd;
20455 GET_P0_CONV (rule);
20456 GET_P1 (rule);
20457 break;
20458
20459 case RULE_OP_MANGLE_OVERSTRIKE:
20460 rule_buf[rule_pos] = rule_cmd;
20461 GET_P0_CONV (rule);
20462 GET_P1 (rule);
20463 break;
20464
20465 case RULE_OP_MANGLE_TRUNCATE_AT:
20466 rule_buf[rule_pos] = rule_cmd;
20467 GET_P0_CONV (rule);
20468 break;
20469
20470 case RULE_OP_MANGLE_REPLACE:
20471 rule_buf[rule_pos] = rule_cmd;
20472 GET_P0 (rule);
20473 GET_P1 (rule);
20474 break;
20475
20476 case RULE_OP_MANGLE_PURGECHAR:
20477 return (-1);
20478 break;
20479
20480 case RULE_OP_MANGLE_TOGGLECASE_REC:
20481 return (-1);
20482 break;
20483
20484 case RULE_OP_MANGLE_DUPECHAR_FIRST:
20485 rule_buf[rule_pos] = rule_cmd;
20486 GET_P0_CONV (rule);
20487 break;
20488
20489 case RULE_OP_MANGLE_DUPECHAR_LAST:
20490 rule_buf[rule_pos] = rule_cmd;
20491 GET_P0_CONV (rule);
20492 break;
20493
20494 case RULE_OP_MANGLE_DUPECHAR_ALL:
20495 rule_buf[rule_pos] = rule_cmd;
20496 break;
20497
20498 case RULE_OP_MANGLE_SWITCH_FIRST:
20499 rule_buf[rule_pos] = rule_cmd;
20500 break;
20501
20502 case RULE_OP_MANGLE_SWITCH_LAST:
20503 rule_buf[rule_pos] = rule_cmd;
20504 break;
20505
20506 case RULE_OP_MANGLE_SWITCH_AT:
20507 rule_buf[rule_pos] = rule_cmd;
20508 GET_P0_CONV (rule);
20509 GET_P1_CONV (rule);
20510 break;
20511
20512 case RULE_OP_MANGLE_CHR_SHIFTL:
20513 rule_buf[rule_pos] = rule_cmd;
20514 GET_P0_CONV (rule);
20515 break;
20516
20517 case RULE_OP_MANGLE_CHR_SHIFTR:
20518 rule_buf[rule_pos] = rule_cmd;
20519 GET_P0_CONV (rule);
20520 break;
20521
20522 case RULE_OP_MANGLE_CHR_INCR:
20523 rule_buf[rule_pos] = rule_cmd;
20524 GET_P0_CONV (rule);
20525 break;
20526
20527 case RULE_OP_MANGLE_CHR_DECR:
20528 rule_buf[rule_pos] = rule_cmd;
20529 GET_P0_CONV (rule);
20530 break;
20531
20532 case RULE_OP_MANGLE_REPLACE_NP1:
20533 rule_buf[rule_pos] = rule_cmd;
20534 GET_P0_CONV (rule);
20535 break;
20536
20537 case RULE_OP_MANGLE_REPLACE_NM1:
20538 rule_buf[rule_pos] = rule_cmd;
20539 GET_P0_CONV (rule);
20540 break;
20541
20542 case RULE_OP_MANGLE_DUPEBLOCK_FIRST:
20543 rule_buf[rule_pos] = rule_cmd;
20544 GET_P0_CONV (rule);
20545 break;
20546
20547 case RULE_OP_MANGLE_DUPEBLOCK_LAST:
20548 rule_buf[rule_pos] = rule_cmd;
20549 GET_P0_CONV (rule);
20550 break;
20551
20552 case RULE_OP_MANGLE_TITLE:
20553 rule_buf[rule_pos] = rule_cmd;
20554 break;
20555
20556 case 0:
20557 return rule_pos - 1;
20558 break;
20559
20560 default:
20561 return (-1);
20562 break;
20563 }
20564 }
20565
20566 if (rule_cnt > 0)
20567 {
20568 return rule_pos;
20569 }
20570
20571 return (-1);
20572 }
20573
20574 /**
20575 * CPU rules : this is from hashcat sources, cpu based rules
20576 */
20577
20578 #define NEXT_RULEPOS(rp) if (++(rp) == rule_len) return (RULE_RC_SYNTAX_ERROR)
20579 #define NEXT_RPTOI(r,rp,up) if (((up) = conv_ctoi ((r)[(rp)])) == -1) return (RULE_RC_SYNTAX_ERROR)
20580
20581 #define MANGLE_TOGGLE_AT(a,p) if (class_alpha ((a)[(p)])) (a)[(p)] ^= 0x20
20582 #define MANGLE_LOWER_AT(a,p) if (class_upper ((a)[(p)])) (a)[(p)] ^= 0x20
20583 #define MANGLE_UPPER_AT(a,p) if (class_lower ((a)[(p)])) (a)[(p)] ^= 0x20
20584
20585 /* #define MANGLE_SWITCH(a,l,r) { char c = (l); arr[(r)] = arr[(l)]; arr[(l)] = c; } */
20586 /* #define MANGLE_SWITCH(a,l,r) { char c = (l); (a)[(r)] = (a)[(l)]; (a)[(l)] = c; } */
20587 #define MANGLE_SWITCH(a,l,r) { char c = (a)[(r)]; (a)[(r)] = (a)[(l)]; (a)[(l)] = c; }
20588
20589 int mangle_lrest (char arr[BLOCK_SIZE], int arr_len)
20590 {
20591 int pos;
20592
20593 for (pos = 0; pos < arr_len; pos++) MANGLE_LOWER_AT (arr, pos);
20594
20595 return (arr_len);
20596 }
20597
20598 int mangle_urest (char arr[BLOCK_SIZE], int arr_len)
20599 {
20600 int pos;
20601
20602 for (pos = 0; pos < arr_len; pos++) MANGLE_UPPER_AT (arr, pos);
20603
20604 return (arr_len);
20605 }
20606
20607 int mangle_trest (char arr[BLOCK_SIZE], int arr_len)
20608 {
20609 int pos;
20610
20611 for (pos = 0; pos < arr_len; pos++) MANGLE_TOGGLE_AT (arr, pos);
20612
20613 return (arr_len);
20614 }
20615
20616 int mangle_reverse (char arr[BLOCK_SIZE], int arr_len)
20617 {
20618 int l;
20619 int r;
20620
20621 for (l = 0; l < arr_len; l++)
20622 {
20623 r = arr_len - 1 - l;
20624
20625 if (l >= r) break;
20626
20627 MANGLE_SWITCH (arr, l, r);
20628 }
20629
20630 return (arr_len);
20631 }
20632
20633 int mangle_double (char arr[BLOCK_SIZE], int arr_len)
20634 {
20635 if ((arr_len * 2) >= BLOCK_SIZE) return (arr_len);
20636
20637 memcpy (&arr[arr_len], arr, (size_t) arr_len);
20638
20639 return (arr_len * 2);
20640 }
20641
20642 int mangle_double_times (char arr[BLOCK_SIZE], int arr_len, int times)
20643 {
20644 if (((arr_len * times) + arr_len) >= BLOCK_SIZE) return (arr_len);
20645
20646 int orig_len = arr_len;
20647
20648 int i;
20649
20650 for (i = 0; i < times; i++)
20651 {
20652 memcpy (&arr[arr_len], arr, orig_len);
20653
20654 arr_len += orig_len;
20655 }
20656
20657 return (arr_len);
20658 }
20659
20660 int mangle_reflect (char arr[BLOCK_SIZE], int arr_len)
20661 {
20662 if ((arr_len * 2) >= BLOCK_SIZE) return (arr_len);
20663
20664 mangle_double (arr, arr_len);
20665
20666 mangle_reverse (arr + arr_len, arr_len);
20667
20668 return (arr_len * 2);
20669 }
20670
20671 int mangle_rotate_left (char arr[BLOCK_SIZE], int arr_len)
20672 {
20673 int l;
20674 int r;
20675
20676 for (l = 0, r = arr_len - 1; r > 0; r--)
20677 {
20678 MANGLE_SWITCH (arr, l, r);
20679 }
20680
20681 return (arr_len);
20682 }
20683
20684 int mangle_rotate_right (char arr[BLOCK_SIZE], int arr_len)
20685 {
20686 int l;
20687 int r;
20688
20689 for (l = 0, r = arr_len - 1; l < r; l++)
20690 {
20691 MANGLE_SWITCH (arr, l, r);
20692 }
20693
20694 return (arr_len);
20695 }
20696
20697 int mangle_append (char arr[BLOCK_SIZE], int arr_len, char c)
20698 {
20699 if ((arr_len + 1) >= BLOCK_SIZE) return (arr_len);
20700
20701 arr[arr_len] = c;
20702
20703 return (arr_len + 1);
20704 }
20705
20706 int mangle_prepend (char arr[BLOCK_SIZE], int arr_len, char c)
20707 {
20708 if ((arr_len + 1) >= BLOCK_SIZE) return (arr_len);
20709
20710 int arr_pos;
20711
20712 for (arr_pos = arr_len - 1; arr_pos > -1; arr_pos--)
20713 {
20714 arr[arr_pos + 1] = arr[arr_pos];
20715 }
20716
20717 arr[0] = c;
20718
20719 return (arr_len + 1);
20720 }
20721
20722 int mangle_delete_at (char arr[BLOCK_SIZE], int arr_len, int upos)
20723 {
20724 if (upos >= arr_len) return (arr_len);
20725
20726 int arr_pos;
20727
20728 for (arr_pos = upos; arr_pos < arr_len - 1; arr_pos++)
20729 {
20730 arr[arr_pos] = arr[arr_pos + 1];
20731 }
20732
20733 return (arr_len - 1);
20734 }
20735
20736 int mangle_extract (char arr[BLOCK_SIZE], int arr_len, int upos, int ulen)
20737 {
20738 if (upos >= arr_len) return (arr_len);
20739
20740 if ((upos + ulen) > arr_len) return (arr_len);
20741
20742 int arr_pos;
20743
20744 for (arr_pos = 0; arr_pos < ulen; arr_pos++)
20745 {
20746 arr[arr_pos] = arr[upos + arr_pos];
20747 }
20748
20749 return (ulen);
20750 }
20751
20752 int mangle_omit (char arr[BLOCK_SIZE], int arr_len, int upos, int ulen)
20753 {
20754 if (upos >= arr_len) return (arr_len);
20755
20756 if ((upos + ulen) >= arr_len) return (arr_len);
20757
20758 int arr_pos;
20759
20760 for (arr_pos = upos; arr_pos < arr_len - ulen; arr_pos++)
20761 {
20762 arr[arr_pos] = arr[arr_pos + ulen];
20763 }
20764
20765 return (arr_len - ulen);
20766 }
20767
20768 int mangle_insert (char arr[BLOCK_SIZE], int arr_len, int upos, char c)
20769 {
20770 if (upos >= arr_len) return (arr_len);
20771
20772 if ((arr_len + 1) >= BLOCK_SIZE) return (arr_len);
20773
20774 int arr_pos;
20775
20776 for (arr_pos = arr_len - 1; arr_pos > upos - 1; arr_pos--)
20777 {
20778 arr[arr_pos + 1] = arr[arr_pos];
20779 }
20780
20781 arr[upos] = c;
20782
20783 return (arr_len + 1);
20784 }
20785
20786 int mangle_insert_multi (char arr[BLOCK_SIZE], int arr_len, int arr_pos, char arr2[BLOCK_SIZE], int arr2_len, int arr2_pos, int arr2_cpy)
20787 {
20788 if ((arr_len + arr2_cpy) > BLOCK_SIZE) return (RULE_RC_REJECT_ERROR);
20789
20790 if (arr_pos > arr_len) return (RULE_RC_REJECT_ERROR);
20791
20792 if (arr2_pos > arr2_len) return (RULE_RC_REJECT_ERROR);
20793
20794 if ((arr2_pos + arr2_cpy) > arr2_len) return (RULE_RC_REJECT_ERROR);
20795
20796 if (arr2_cpy < 1) return (RULE_RC_SYNTAX_ERROR);
20797
20798 memcpy (arr2, arr2 + arr2_pos, arr2_len - arr2_pos);
20799
20800 memcpy (arr2 + arr2_cpy, arr + arr_pos, arr_len - arr_pos);
20801
20802 memcpy (arr + arr_pos, arr2, arr_len - arr_pos + arr2_cpy);
20803
20804 return (arr_len + arr2_cpy);
20805 }
20806
20807 int mangle_overstrike (char arr[BLOCK_SIZE], int arr_len, int upos, char c)
20808 {
20809 if (upos >= arr_len) return (arr_len);
20810
20811 arr[upos] = c;
20812
20813 return (arr_len);
20814 }
20815
20816 int mangle_truncate_at (char arr[BLOCK_SIZE], int arr_len, int upos)
20817 {
20818 if (upos >= arr_len) return (arr_len);
20819
20820 memset (arr + upos, 0, arr_len - upos);
20821
20822 return (upos);
20823 }
20824
20825 int mangle_replace (char arr[BLOCK_SIZE], int arr_len, char oldc, char newc)
20826 {
20827 int arr_pos;
20828
20829 for (arr_pos = 0; arr_pos < arr_len; arr_pos++)
20830 {
20831 if (arr[arr_pos] != oldc) continue;
20832
20833 arr[arr_pos] = newc;
20834 }
20835
20836 return (arr_len);
20837 }
20838
20839 int mangle_purgechar (char arr[BLOCK_SIZE], int arr_len, char c)
20840 {
20841 int arr_pos;
20842
20843 int ret_len;
20844
20845 for (ret_len = 0, arr_pos = 0; arr_pos < arr_len; arr_pos++)
20846 {
20847 if (arr[arr_pos] == c) continue;
20848
20849 arr[ret_len] = arr[arr_pos];
20850
20851 ret_len++;
20852 }
20853
20854 return (ret_len);
20855 }
20856
20857 int mangle_dupeblock_prepend (char arr[BLOCK_SIZE], int arr_len, int ulen)
20858 {
20859 if (ulen > arr_len) return (arr_len);
20860
20861 if ((arr_len + ulen) >= BLOCK_SIZE) return (arr_len);
20862
20863 char cs[100] = { 0 };
20864
20865 memcpy (cs, arr, ulen);
20866
20867 int i;
20868
20869 for (i = 0; i < ulen; i++)
20870 {
20871 char c = cs[i];
20872
20873 arr_len = mangle_insert (arr, arr_len, i, c);
20874 }
20875
20876 return (arr_len);
20877 }
20878
20879 int mangle_dupeblock_append (char arr[BLOCK_SIZE], int arr_len, int ulen)
20880 {
20881 if (ulen > arr_len) return (arr_len);
20882
20883 if ((arr_len + ulen) >= BLOCK_SIZE) return (arr_len);
20884
20885 int upos = arr_len - ulen;
20886
20887 int i;
20888
20889 for (i = 0; i < ulen; i++)
20890 {
20891 char c = arr[upos + i];
20892
20893 arr_len = mangle_append (arr, arr_len, c);
20894 }
20895
20896 return (arr_len);
20897 }
20898
20899 int mangle_dupechar_at (char arr[BLOCK_SIZE], int arr_len, int upos, int ulen)
20900 {
20901 if ( arr_len == 0) return (arr_len);
20902 if ((arr_len + ulen) >= BLOCK_SIZE) return (arr_len);
20903
20904 char c = arr[upos];
20905
20906 int i;
20907
20908 for (i = 0; i < ulen; i++)
20909 {
20910 arr_len = mangle_insert (arr, arr_len, upos, c);
20911 }
20912
20913 return (arr_len);
20914 }
20915
20916 int mangle_dupechar (char arr[BLOCK_SIZE], int arr_len)
20917 {
20918 if ( arr_len == 0) return (arr_len);
20919 if ((arr_len + arr_len) >= BLOCK_SIZE) return (arr_len);
20920
20921 int arr_pos;
20922
20923 for (arr_pos = arr_len - 1; arr_pos > -1; arr_pos--)
20924 {
20925 int new_pos = arr_pos * 2;
20926
20927 arr[new_pos] = arr[arr_pos];
20928
20929 arr[new_pos + 1] = arr[arr_pos];
20930 }
20931
20932 return (arr_len * 2);
20933 }
20934
20935 int mangle_switch_at_check (char arr[BLOCK_SIZE], int arr_len, int upos, int upos2)
20936 {
20937 if (upos >= arr_len) return (arr_len);
20938 if (upos2 >= arr_len) return (arr_len);
20939
20940 MANGLE_SWITCH (arr, upos, upos2);
20941
20942 return (arr_len);
20943 }
20944
20945 int mangle_switch_at (char arr[BLOCK_SIZE], int arr_len, int upos, int upos2)
20946 {
20947 MANGLE_SWITCH (arr, upos, upos2);
20948
20949 return (arr_len);
20950 }
20951
20952 int mangle_chr_shiftl (char arr[BLOCK_SIZE], int arr_len, int upos)
20953 {
20954 if (upos >= arr_len) return (arr_len);
20955
20956 arr[upos] <<= 1;
20957
20958 return (arr_len);
20959 }
20960
20961 int mangle_chr_shiftr (char arr[BLOCK_SIZE], int arr_len, int upos)
20962 {
20963 if (upos >= arr_len) return (arr_len);
20964
20965 arr[upos] >>= 1;
20966
20967 return (arr_len);
20968 }
20969
20970 int mangle_chr_incr (char arr[BLOCK_SIZE], int arr_len, int upos)
20971 {
20972 if (upos >= arr_len) return (arr_len);
20973
20974 arr[upos] += 1;
20975
20976 return (arr_len);
20977 }
20978
20979 int mangle_chr_decr (char arr[BLOCK_SIZE], int arr_len, int upos)
20980 {
20981 if (upos >= arr_len) return (arr_len);
20982
20983 arr[upos] -= 1;
20984
20985 return (arr_len);
20986 }
20987
20988 int mangle_title (char arr[BLOCK_SIZE], int arr_len)
20989 {
20990 int upper_next = 1;
20991
20992 int pos;
20993
20994 for (pos = 0; pos < arr_len; pos++)
20995 {
20996 if (arr[pos] == ' ')
20997 {
20998 upper_next = 1;
20999
21000 continue;
21001 }
21002
21003 if (upper_next)
21004 {
21005 upper_next = 0;
21006
21007 MANGLE_UPPER_AT (arr, pos);
21008 }
21009 else
21010 {
21011 MANGLE_LOWER_AT (arr, pos);
21012 }
21013 }
21014
21015 return (arr_len);
21016 }
21017
21018 int generate_random_rule (char rule_buf[RP_RULE_BUFSIZ], u32 rp_gen_func_min, u32 rp_gen_func_max)
21019 {
21020 u32 rp_gen_num = get_random_num (rp_gen_func_min, rp_gen_func_max);
21021
21022 u32 j;
21023
21024 u32 rule_pos = 0;
21025
21026 for (j = 0; j < rp_gen_num; j++)
21027 {
21028 u32 r = 0;
21029 u32 p1 = 0;
21030 u32 p2 = 0;
21031 u32 p3 = 0;
21032
21033 switch ((char) get_random_num (0, 9))
21034 {
21035 case 0:
21036 r = get_random_num (0, sizeof (grp_op_nop));
21037 rule_buf[rule_pos++] = grp_op_nop[r];
21038 break;
21039
21040 case 1:
21041 r = get_random_num (0, sizeof (grp_op_pos_p0));
21042 rule_buf[rule_pos++] = grp_op_pos_p0[r];
21043 p1 = get_random_num (0, sizeof (grp_pos));
21044 rule_buf[rule_pos++] = grp_pos[p1];
21045 break;
21046
21047 case 2:
21048 r = get_random_num (0, sizeof (grp_op_pos_p1));
21049 rule_buf[rule_pos++] = grp_op_pos_p1[r];
21050 p1 = get_random_num (1, 6);
21051 rule_buf[rule_pos++] = grp_pos[p1];
21052 break;
21053
21054 case 3:
21055 r = get_random_num (0, sizeof (grp_op_chr));
21056 rule_buf[rule_pos++] = grp_op_chr[r];
21057 p1 = get_random_num (0x20, 0x7e);
21058 rule_buf[rule_pos++] = (char) p1;
21059 break;
21060
21061 case 4:
21062 r = get_random_num (0, sizeof (grp_op_chr_chr));
21063 rule_buf[rule_pos++] = grp_op_chr_chr[r];
21064 p1 = get_random_num (0x20, 0x7e);
21065 rule_buf[rule_pos++] = (char) p1;
21066 p2 = get_random_num (0x20, 0x7e);
21067 while (p1 == p2)
21068 p2 = get_random_num (0x20, 0x7e);
21069 rule_buf[rule_pos++] = (char) p2;
21070 break;
21071
21072 case 5:
21073 r = get_random_num (0, sizeof (grp_op_pos_chr));
21074 rule_buf[rule_pos++] = grp_op_pos_chr[r];
21075 p1 = get_random_num (0, sizeof (grp_pos));
21076 rule_buf[rule_pos++] = grp_pos[p1];
21077 p2 = get_random_num (0x20, 0x7e);
21078 rule_buf[rule_pos++] = (char) p2;
21079 break;
21080
21081 case 6:
21082 r = get_random_num (0, sizeof (grp_op_pos_pos0));
21083 rule_buf[rule_pos++] = grp_op_pos_pos0[r];
21084 p1 = get_random_num (0, sizeof (grp_pos));
21085 rule_buf[rule_pos++] = grp_pos[p1];
21086 p2 = get_random_num (0, sizeof (grp_pos));
21087 while (p1 == p2)
21088 p2 = get_random_num (0, sizeof (grp_pos));
21089 rule_buf[rule_pos++] = grp_pos[p2];
21090 break;
21091
21092 case 7:
21093 r = get_random_num (0, sizeof (grp_op_pos_pos1));
21094 rule_buf[rule_pos++] = grp_op_pos_pos1[r];
21095 p1 = get_random_num (0, sizeof (grp_pos));
21096 rule_buf[rule_pos++] = grp_pos[p1];
21097 p2 = get_random_num (1, sizeof (grp_pos));
21098 while (p1 == p2)
21099 p2 = get_random_num (1, sizeof (grp_pos));
21100 rule_buf[rule_pos++] = grp_pos[p2];
21101 break;
21102
21103 case 8:
21104 r = get_random_num (0, sizeof (grp_op_pos1_pos2_pos3));
21105 rule_buf[rule_pos++] = grp_op_pos1_pos2_pos3[r];
21106 p1 = get_random_num (0, sizeof (grp_pos));
21107 rule_buf[rule_pos++] = grp_pos[p1];
21108 p2 = get_random_num (1, sizeof (grp_pos));
21109 rule_buf[rule_pos++] = grp_pos[p1];
21110 p3 = get_random_num (0, sizeof (grp_pos));
21111 rule_buf[rule_pos++] = grp_pos[p3];
21112 break;
21113 }
21114 }
21115
21116 return (rule_pos);
21117 }
21118
21119 int _old_apply_rule (char *rule, int rule_len, char in[BLOCK_SIZE], int in_len, char out[BLOCK_SIZE])
21120 {
21121 char mem[BLOCK_SIZE] = { 0 };
21122
21123 if (in == NULL) return (RULE_RC_REJECT_ERROR);
21124
21125 if (out == NULL) return (RULE_RC_REJECT_ERROR);
21126
21127 if (in_len < 1 || in_len > BLOCK_SIZE) return (RULE_RC_REJECT_ERROR);
21128
21129 if (rule_len < 1) return (RULE_RC_REJECT_ERROR);
21130
21131 int out_len = in_len;
21132 int mem_len = in_len;
21133
21134 memcpy (out, in, out_len);
21135
21136 int rule_pos;
21137
21138 for (rule_pos = 0; rule_pos < rule_len; rule_pos++)
21139 {
21140 int upos, upos2;
21141 int ulen;
21142
21143 switch (rule[rule_pos])
21144 {
21145 case ' ':
21146 break;
21147
21148 case RULE_OP_MANGLE_NOOP:
21149 break;
21150
21151 case RULE_OP_MANGLE_LREST:
21152 out_len = mangle_lrest (out, out_len);
21153 break;
21154
21155 case RULE_OP_MANGLE_UREST:
21156 out_len = mangle_urest (out, out_len);
21157 break;
21158
21159 case RULE_OP_MANGLE_LREST_UFIRST:
21160 out_len = mangle_lrest (out, out_len);
21161 if (out_len) MANGLE_UPPER_AT (out, 0);
21162 break;
21163
21164 case RULE_OP_MANGLE_UREST_LFIRST:
21165 out_len = mangle_urest (out, out_len);
21166 if (out_len) MANGLE_LOWER_AT (out, 0);
21167 break;
21168
21169 case RULE_OP_MANGLE_TREST:
21170 out_len = mangle_trest (out, out_len);
21171 break;
21172
21173 case RULE_OP_MANGLE_TOGGLE_AT:
21174 NEXT_RULEPOS (rule_pos);
21175 NEXT_RPTOI (rule, rule_pos, upos);
21176 if (upos < out_len) MANGLE_TOGGLE_AT (out, upos);
21177 break;
21178
21179 case RULE_OP_MANGLE_REVERSE:
21180 out_len = mangle_reverse (out, out_len);
21181 break;
21182
21183 case RULE_OP_MANGLE_DUPEWORD:
21184 out_len = mangle_double (out, out_len);
21185 break;
21186
21187 case RULE_OP_MANGLE_DUPEWORD_TIMES:
21188 NEXT_RULEPOS (rule_pos);
21189 NEXT_RPTOI (rule, rule_pos, ulen);
21190 out_len = mangle_double_times (out, out_len, ulen);
21191 break;
21192
21193 case RULE_OP_MANGLE_REFLECT:
21194 out_len = mangle_reflect (out, out_len);
21195 break;
21196
21197 case RULE_OP_MANGLE_ROTATE_LEFT:
21198 mangle_rotate_left (out, out_len);
21199 break;
21200
21201 case RULE_OP_MANGLE_ROTATE_RIGHT:
21202 mangle_rotate_right (out, out_len);
21203 break;
21204
21205 case RULE_OP_MANGLE_APPEND:
21206 NEXT_RULEPOS (rule_pos);
21207 out_len = mangle_append (out, out_len, rule[rule_pos]);
21208 break;
21209
21210 case RULE_OP_MANGLE_PREPEND:
21211 NEXT_RULEPOS (rule_pos);
21212 out_len = mangle_prepend (out, out_len, rule[rule_pos]);
21213 break;
21214
21215 case RULE_OP_MANGLE_DELETE_FIRST:
21216 out_len = mangle_delete_at (out, out_len, 0);
21217 break;
21218
21219 case RULE_OP_MANGLE_DELETE_LAST:
21220 out_len = mangle_delete_at (out, out_len, (out_len) ? out_len - 1 : 0);
21221 break;
21222
21223 case RULE_OP_MANGLE_DELETE_AT:
21224 NEXT_RULEPOS (rule_pos);
21225 NEXT_RPTOI (rule, rule_pos, upos);
21226 out_len = mangle_delete_at (out, out_len, upos);
21227 break;
21228
21229 case RULE_OP_MANGLE_EXTRACT:
21230 NEXT_RULEPOS (rule_pos);
21231 NEXT_RPTOI (rule, rule_pos, upos);
21232 NEXT_RULEPOS (rule_pos);
21233 NEXT_RPTOI (rule, rule_pos, ulen);
21234 out_len = mangle_extract (out, out_len, upos, ulen);
21235 break;
21236
21237 case RULE_OP_MANGLE_OMIT:
21238 NEXT_RULEPOS (rule_pos);
21239 NEXT_RPTOI (rule, rule_pos, upos);
21240 NEXT_RULEPOS (rule_pos);
21241 NEXT_RPTOI (rule, rule_pos, ulen);
21242 out_len = mangle_omit (out, out_len, upos, ulen);
21243 break;
21244
21245 case RULE_OP_MANGLE_INSERT:
21246 NEXT_RULEPOS (rule_pos);
21247 NEXT_RPTOI (rule, rule_pos, upos);
21248 NEXT_RULEPOS (rule_pos);
21249 out_len = mangle_insert (out, out_len, upos, rule[rule_pos]);
21250 break;
21251
21252 case RULE_OP_MANGLE_OVERSTRIKE:
21253 NEXT_RULEPOS (rule_pos);
21254 NEXT_RPTOI (rule, rule_pos, upos);
21255 NEXT_RULEPOS (rule_pos);
21256 out_len = mangle_overstrike (out, out_len, upos, rule[rule_pos]);
21257 break;
21258
21259 case RULE_OP_MANGLE_TRUNCATE_AT:
21260 NEXT_RULEPOS (rule_pos);
21261 NEXT_RPTOI (rule, rule_pos, upos);
21262 out_len = mangle_truncate_at (out, out_len, upos);
21263 break;
21264
21265 case RULE_OP_MANGLE_REPLACE:
21266 NEXT_RULEPOS (rule_pos);
21267 NEXT_RULEPOS (rule_pos);
21268 out_len = mangle_replace (out, out_len, rule[rule_pos - 1], rule[rule_pos]);
21269 break;
21270
21271 case RULE_OP_MANGLE_PURGECHAR:
21272 NEXT_RULEPOS (rule_pos);
21273 out_len = mangle_purgechar (out, out_len, rule[rule_pos]);
21274 break;
21275
21276 case RULE_OP_MANGLE_TOGGLECASE_REC:
21277 /* todo */
21278 break;
21279
21280 case RULE_OP_MANGLE_DUPECHAR_FIRST:
21281 NEXT_RULEPOS (rule_pos);
21282 NEXT_RPTOI (rule, rule_pos, ulen);
21283 out_len = mangle_dupechar_at (out, out_len, 0, ulen);
21284 break;
21285
21286 case RULE_OP_MANGLE_DUPECHAR_LAST:
21287 NEXT_RULEPOS (rule_pos);
21288 NEXT_RPTOI (rule, rule_pos, ulen);
21289 out_len = mangle_dupechar_at (out, out_len, out_len - 1, ulen);
21290 break;
21291
21292 case RULE_OP_MANGLE_DUPECHAR_ALL:
21293 out_len = mangle_dupechar (out, out_len);
21294 break;
21295
21296 case RULE_OP_MANGLE_DUPEBLOCK_FIRST:
21297 NEXT_RULEPOS (rule_pos);
21298 NEXT_RPTOI (rule, rule_pos, ulen);
21299 out_len = mangle_dupeblock_prepend (out, out_len, ulen);
21300 break;
21301
21302 case RULE_OP_MANGLE_DUPEBLOCK_LAST:
21303 NEXT_RULEPOS (rule_pos);
21304 NEXT_RPTOI (rule, rule_pos, ulen);
21305 out_len = mangle_dupeblock_append (out, out_len, ulen);
21306 break;
21307
21308 case RULE_OP_MANGLE_SWITCH_FIRST:
21309 if (out_len >= 2) mangle_switch_at (out, out_len, 0, 1);
21310 break;
21311
21312 case RULE_OP_MANGLE_SWITCH_LAST:
21313 if (out_len >= 2) mangle_switch_at (out, out_len, out_len - 1, out_len - 2);
21314 break;
21315
21316 case RULE_OP_MANGLE_SWITCH_AT:
21317 NEXT_RULEPOS (rule_pos);
21318 NEXT_RPTOI (rule, rule_pos, upos);
21319 NEXT_RULEPOS (rule_pos);
21320 NEXT_RPTOI (rule, rule_pos, upos2);
21321 out_len = mangle_switch_at_check (out, out_len, upos, upos2);
21322 break;
21323
21324 case RULE_OP_MANGLE_CHR_SHIFTL:
21325 NEXT_RULEPOS (rule_pos);
21326 NEXT_RPTOI (rule, rule_pos, upos);
21327 mangle_chr_shiftl (out, out_len, upos);
21328 break;
21329
21330 case RULE_OP_MANGLE_CHR_SHIFTR:
21331 NEXT_RULEPOS (rule_pos);
21332 NEXT_RPTOI (rule, rule_pos, upos);
21333 mangle_chr_shiftr (out, out_len, upos);
21334 break;
21335
21336 case RULE_OP_MANGLE_CHR_INCR:
21337 NEXT_RULEPOS (rule_pos);
21338 NEXT_RPTOI (rule, rule_pos, upos);
21339 mangle_chr_incr (out, out_len, upos);
21340 break;
21341
21342 case RULE_OP_MANGLE_CHR_DECR:
21343 NEXT_RULEPOS (rule_pos);
21344 NEXT_RPTOI (rule, rule_pos, upos);
21345 mangle_chr_decr (out, out_len, upos);
21346 break;
21347
21348 case RULE_OP_MANGLE_REPLACE_NP1:
21349 NEXT_RULEPOS (rule_pos);
21350 NEXT_RPTOI (rule, rule_pos, upos);
21351 if ((upos >= 0) && ((upos + 1) < out_len)) mangle_overstrike (out, out_len, upos, out[upos + 1]);
21352 break;
21353
21354 case RULE_OP_MANGLE_REPLACE_NM1:
21355 NEXT_RULEPOS (rule_pos);
21356 NEXT_RPTOI (rule, rule_pos, upos);
21357 if ((upos >= 1) && ((upos + 0) < out_len)) mangle_overstrike (out, out_len, upos, out[upos - 1]);
21358 break;
21359
21360 case RULE_OP_MANGLE_TITLE:
21361 out_len = mangle_title (out, out_len);
21362 break;
21363
21364 case RULE_OP_MANGLE_EXTRACT_MEMORY:
21365 if (mem_len < 1) return (RULE_RC_REJECT_ERROR);
21366 NEXT_RULEPOS (rule_pos);
21367 NEXT_RPTOI (rule, rule_pos, upos);
21368 NEXT_RULEPOS (rule_pos);
21369 NEXT_RPTOI (rule, rule_pos, ulen);
21370 NEXT_RULEPOS (rule_pos);
21371 NEXT_RPTOI (rule, rule_pos, upos2);
21372 if ((out_len = mangle_insert_multi (out, out_len, upos2, mem, mem_len, upos, ulen)) < 1) return (out_len);
21373 break;
21374
21375 case RULE_OP_MANGLE_APPEND_MEMORY:
21376 if (mem_len < 1) return (RULE_RC_REJECT_ERROR);
21377 if ((out_len + mem_len) > BLOCK_SIZE) return (RULE_RC_REJECT_ERROR);
21378 memcpy (out + out_len, mem, mem_len);
21379 out_len += mem_len;
21380 break;
21381
21382 case RULE_OP_MANGLE_PREPEND_MEMORY:
21383 if (mem_len < 1) return (RULE_RC_REJECT_ERROR);
21384 if ((mem_len + out_len) > BLOCK_SIZE) return (RULE_RC_REJECT_ERROR);
21385 memcpy (mem + mem_len, out, out_len);
21386 out_len += mem_len;
21387 memcpy (out, mem, out_len);
21388 break;
21389
21390 case RULE_OP_MEMORIZE_WORD:
21391 memcpy (mem, out, out_len);
21392 mem_len = out_len;
21393 break;
21394
21395 case RULE_OP_REJECT_LESS:
21396 NEXT_RULEPOS (rule_pos);
21397 NEXT_RPTOI (rule, rule_pos, upos);
21398 if (out_len > upos) return (RULE_RC_REJECT_ERROR);
21399 break;
21400
21401 case RULE_OP_REJECT_GREATER:
21402 NEXT_RULEPOS (rule_pos);
21403 NEXT_RPTOI (rule, rule_pos, upos);
21404 if (out_len < upos) return (RULE_RC_REJECT_ERROR);
21405 break;
21406
21407 case RULE_OP_REJECT_CONTAIN:
21408 NEXT_RULEPOS (rule_pos);
21409 if (strchr (out, rule[rule_pos]) != NULL) return (RULE_RC_REJECT_ERROR);
21410 break;
21411
21412 case RULE_OP_REJECT_NOT_CONTAIN:
21413 NEXT_RULEPOS (rule_pos);
21414 if (strchr (out, rule[rule_pos]) == NULL) return (RULE_RC_REJECT_ERROR);
21415 break;
21416
21417 case RULE_OP_REJECT_EQUAL_FIRST:
21418 NEXT_RULEPOS (rule_pos);
21419 if (out[0] != rule[rule_pos]) return (RULE_RC_REJECT_ERROR);
21420 break;
21421
21422 case RULE_OP_REJECT_EQUAL_LAST:
21423 NEXT_RULEPOS (rule_pos);
21424 if (out[out_len - 1] != rule[rule_pos]) return (RULE_RC_REJECT_ERROR);
21425 break;
21426
21427 case RULE_OP_REJECT_EQUAL_AT:
21428 NEXT_RULEPOS (rule_pos);
21429 NEXT_RPTOI (rule, rule_pos, upos);
21430 if ((upos + 1) > out_len) return (RULE_RC_REJECT_ERROR);
21431 NEXT_RULEPOS (rule_pos);
21432 if (out[upos] != rule[rule_pos]) return (RULE_RC_REJECT_ERROR);
21433 break;
21434
21435 case RULE_OP_REJECT_CONTAINS:
21436 NEXT_RULEPOS (rule_pos);
21437 NEXT_RPTOI (rule, rule_pos, upos);
21438 if ((upos + 1) > out_len) return (RULE_RC_REJECT_ERROR);
21439 NEXT_RULEPOS (rule_pos);
21440 int c; int cnt; for (c = 0, cnt = 0; c < out_len; c++) if (out[c] == rule[rule_pos]) cnt++;
21441 if (cnt < upos) return (RULE_RC_REJECT_ERROR);
21442 break;
21443
21444 case RULE_OP_REJECT_MEMORY:
21445 if ((out_len == mem_len) && (memcmp (out, mem, out_len) == 0)) return (RULE_RC_REJECT_ERROR);
21446 break;
21447
21448 default:
21449 return (RULE_RC_SYNTAX_ERROR);
21450 break;
21451 }
21452 }
21453
21454 memset (out + out_len, 0, BLOCK_SIZE - out_len);
21455
21456 return (out_len);
21457 }
Hashcat additions to support pwdhash