source: releases/0.9.0/lib/regfi.c @ 143

Last change on this file since 143 was 116, checked in by tim, 16 years ago

fixed major bug in reglookup-recover; now recovers much more data
rolled back release version to 0.9.0
added date range checking in regfi's NK parsing for deleted records

  • Property svn:keywords set to Id
File size: 46.4 KB
Line 
1/*
2 * Branched from Samba project Subversion repository, version #7470:
3 *   http://viewcvs.samba.org/cgi-bin/viewcvs.cgi/trunk/source/registry/regfio.c?rev=7470&view=auto
4 *
5 * Unix SMB/CIFS implementation.
6 * Windows NT registry I/O library
7 *
8 * Copyright (C) 2005-2008 Timothy D. Morgan
9 * Copyright (C) 2005 Gerald (Jerry) Carter
10 *
11 * This program is free software; you can redistribute it and/or modify
12 * it under the terms of the GNU General Public License as published by
13 * the Free Software Foundation; version 3 of the License.
14 *
15 * This program is distributed in the hope that it will be useful,
16 * but WITHOUT ANY WARRANTY; without even the implied warranty of
17 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
18 * GNU General Public License for more details.
19 *
20 * You should have received a copy of the GNU General Public License
21 * along with this program; if not, write to the Free Software
22 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. 
23 *
24 * $Id: regfi.c 116 2008-08-03 19:34:27Z tim $
25 */
26
27#include "../include/regfi.h"
28
29
30/* Registry types mapping */
31const unsigned int regfi_num_reg_types = 12;
32static const char* regfi_type_names[] =
33  {"NONE", "SZ", "EXPAND_SZ", "BINARY", "DWORD", "DWORD_BE", "LINK",
34   "MULTI_SZ", "RSRC_LIST", "RSRC_DESC", "RSRC_REQ_LIST", "QWORD"};
35
36
37/* Returns NULL on error */
38const char* regfi_type_val2str(unsigned int val)
39{
40  if(val == REG_KEY)
41    return "KEY";
42 
43  if(val >= regfi_num_reg_types)
44    return NULL;
45 
46  return regfi_type_names[val];
47}
48
49
50/* Returns -1 on error */
51int regfi_type_str2val(const char* str)
52{
53  int i;
54
55  if(strcmp("KEY", str) == 0)
56    return REG_KEY;
57
58  for(i=0; i < regfi_num_reg_types; i++)
59    if (strcmp(regfi_type_names[i], str) == 0) 
60      return i;
61
62  if(strcmp("DWORD_LE", str) == 0)
63    return REG_DWORD_LE;
64
65  return -1;
66}
67
68
69/* Security descriptor parsing functions  */
70
71const char* regfi_ace_type2str(uint8 type)
72{
73  static const char* map[7] 
74    = {"ALLOW", "DENY", "AUDIT", "ALARM", 
75       "ALLOW CPD", "OBJ ALLOW", "OBJ DENY"};
76  if(type < 7)
77    return map[type];
78  else
79    /* XXX: would be nice to return the unknown integer value. 
80     *      However, as it is a const string, it can't be free()ed later on,
81     *      so that would need to change.
82     */
83    return "UNKNOWN";
84}
85
86
87/* XXX: need a better reference on the meaning of each flag. */
88/* For more info, see:
89 *   http://msdn2.microsoft.com/en-us/library/aa772242.aspx
90 */
91char* regfi_ace_flags2str(uint8 flags)
92{
93  static const char* flag_map[32] = 
94    { "OI", /* Object Inherit */
95      "CI", /* Container Inherit */
96      "NP", /* Non-Propagate */
97      "IO", /* Inherit Only */
98      "IA", /* Inherited ACE */
99      NULL,
100      NULL,
101      NULL,
102    };
103
104  char* ret_val = malloc(35*sizeof(char));
105  char* fo = ret_val;
106  uint32 i;
107  uint8 f;
108
109  if(ret_val == NULL)
110    return NULL;
111
112  fo[0] = '\0';
113  if (!flags)
114    return ret_val;
115
116  for(i=0; i < 8; i++)
117  {
118    f = (1<<i);
119    if((flags & f) && (flag_map[i] != NULL))
120    {
121      strcpy(fo, flag_map[i]);
122      fo += strlen(flag_map[i]);
123      *(fo++) = ' ';
124      flags ^= f;
125    }
126  }
127 
128  /* Any remaining unknown flags are added at the end in hex. */
129  if(flags != 0)
130    sprintf(fo, "0x%.2X ", flags);
131
132  /* Chop off the last space if we've written anything to ret_val */
133  if(fo != ret_val)
134    fo[-1] = '\0';
135
136  /* XXX: what was this old VI flag for??
137     XXX: Is this check right?  0xF == 1|2|4|8, which makes it redundant...
138  if (flags == 0xF) {
139    if (some) strcat(flg_output, " ");
140    some = 1;
141    strcat(flg_output, "VI");
142  }
143  */
144
145  return ret_val;
146}
147
148
149char* regfi_ace_perms2str(uint32 perms)
150{
151  uint32 i, p;
152  /* This is more than is needed by a fair margin. */
153  char* ret_val = malloc(350*sizeof(char));
154  char* r = ret_val;
155
156  /* Each represents one of 32 permissions bits.  NULL is for undefined/reserved bits.
157   * For more information, see:
158   *   http://msdn2.microsoft.com/en-gb/library/aa374892.aspx
159   *   http://msdn2.microsoft.com/en-gb/library/ms724878.aspx
160   */
161  static const char* perm_map[32] = 
162    {/* object-specific permissions (registry keys, in this case) */
163      "QRY_VAL",       /* KEY_QUERY_VALUE */
164      "SET_VAL",       /* KEY_SET_VALUE */
165      "CREATE_KEY",    /* KEY_CREATE_SUB_KEY */
166      "ENUM_KEYS",     /* KEY_ENUMERATE_SUB_KEYS */
167      "NOTIFY",        /* KEY_NOTIFY */
168      "CREATE_LNK",    /* KEY_CREATE_LINK - Reserved for system use. */
169      NULL,
170      NULL,
171      "WOW64_64",      /* KEY_WOW64_64KEY */
172      "WOW64_32",      /* KEY_WOW64_32KEY */
173      NULL,
174      NULL,
175      NULL,
176      NULL,
177      NULL,
178      NULL,
179      /* standard access rights */
180      "DELETE",        /* DELETE */
181      "R_CONT",        /* READ_CONTROL */
182      "W_DAC",         /* WRITE_DAC */
183      "W_OWNER",       /* WRITE_OWNER */
184      "SYNC",          /* SYNCHRONIZE - Shouldn't be set in registries */
185      NULL,
186      NULL,
187      NULL,
188      /* other generic */
189      "SYS_SEC",       /* ACCESS_SYSTEM_SECURITY */
190      "MAX_ALLWD",     /* MAXIMUM_ALLOWED */
191      NULL,
192      NULL,
193      "GEN_A",         /* GENERIC_ALL */
194      "GEN_X",         /* GENERIC_EXECUTE */
195      "GEN_W",         /* GENERIC_WRITE */
196      "GEN_R",         /* GENERIC_READ */
197    };
198
199
200  if(ret_val == NULL)
201    return NULL;
202
203  r[0] = '\0';
204  for(i=0; i < 32; i++)
205  {
206    p = (1<<i);
207    if((perms & p) && (perm_map[i] != NULL))
208    {
209      strcpy(r, perm_map[i]);
210      r += strlen(perm_map[i]);
211      *(r++) = ' ';
212      perms ^= p;
213    }
214  }
215 
216  /* Any remaining unknown permission bits are added at the end in hex. */
217  if(perms != 0)
218    sprintf(r, "0x%.8X ", perms);
219
220  /* Chop off the last space if we've written anything to ret_val */
221  if(r != ret_val)
222    r[-1] = '\0';
223
224  return ret_val;
225}
226
227
228char* regfi_sid2str(DOM_SID* sid)
229{
230  uint32 i, size = MAXSUBAUTHS*11 + 24;
231  uint32 left = size;
232  uint8 comps = sid->num_auths;
233  char* ret_val = malloc(size);
234 
235  if(ret_val == NULL)
236    return NULL;
237
238  if(comps > MAXSUBAUTHS)
239    comps = MAXSUBAUTHS;
240
241  left -= sprintf(ret_val, "S-%u-%u", sid->sid_rev_num, sid->id_auth[5]);
242
243  for (i = 0; i < comps; i++) 
244    left -= snprintf(ret_val+(size-left), left, "-%u", sid->sub_auths[i]);
245
246  return ret_val;
247}
248
249
250char* regfi_get_acl(SEC_ACL* acl)
251{
252  uint32 i, extra, size = 0;
253  const char* type_str;
254  char* flags_str;
255  char* perms_str;
256  char* sid_str;
257  char* ace_delim = "";
258  char* ret_val = NULL;
259  char* tmp_val = NULL;
260  bool failed = false;
261  char field_delim = ':';
262
263  for (i = 0; i < acl->num_aces && !failed; i++)
264  {
265    sid_str = regfi_sid2str(&acl->ace[i].trustee);
266    type_str = regfi_ace_type2str(acl->ace[i].type);
267    perms_str = regfi_ace_perms2str(acl->ace[i].info.mask);
268    flags_str = regfi_ace_flags2str(acl->ace[i].flags);
269   
270    if(flags_str != NULL && perms_str != NULL 
271       && type_str != NULL && sid_str != NULL)
272    {
273      /* XXX: this is slow */
274      extra = strlen(sid_str) + strlen(type_str) 
275        + strlen(perms_str) + strlen(flags_str)+5;
276      tmp_val = realloc(ret_val, size+extra);
277
278      if(tmp_val == NULL)
279      {
280        free(ret_val);
281        failed = true;
282      }
283      else
284      {
285        ret_val = tmp_val;
286        size += snprintf(ret_val+size, extra, "%s%s%c%s%c%s%c%s",
287                         ace_delim,sid_str,
288                         field_delim,type_str,
289                         field_delim,perms_str,
290                         field_delim,flags_str);
291        ace_delim = "|";
292      }
293    }
294    else
295      failed = true;
296
297    if(sid_str != NULL)
298      free(sid_str);
299    if(sid_str != NULL)
300      free(perms_str);
301    if(sid_str != NULL)
302      free(flags_str);
303  }
304
305  return ret_val;
306}
307
308
309char* regfi_get_sacl(SEC_DESC *sec_desc)
310{
311  if (sec_desc->sacl)
312    return regfi_get_acl(sec_desc->sacl);
313  else
314    return NULL;
315}
316
317
318char* regfi_get_dacl(SEC_DESC *sec_desc)
319{
320  if (sec_desc->dacl)
321    return regfi_get_acl(sec_desc->dacl);
322  else
323    return NULL;
324}
325
326
327char* regfi_get_owner(SEC_DESC *sec_desc)
328{
329  return regfi_sid2str(sec_desc->owner_sid);
330}
331
332
333char* regfi_get_group(SEC_DESC *sec_desc)
334{
335  return regfi_sid2str(sec_desc->grp_sid);
336}
337
338
339/*****************************************************************************
340 * This function is just like read(2), except that it continues to
341 * re-try reading from the file descriptor if EINTR or EAGAIN is received. 
342 * regfi_read will attempt to read length bytes from fd and write them to buf.
343 *
344 * On success, 0 is returned.  Upon failure, an errno code is returned.
345 *
346 * The number of bytes successfully read is returned through the length
347 * parameter by reference.  If both the return value and length parameter are
348 * returned as 0, then EOF was encountered immediately
349 *****************************************************************************/
350uint32 regfi_read(int fd, uint8* buf, uint32* length)
351{
352  uint32 rsize = 0;
353  uint32 rret = 0;
354
355  do
356  {
357    rret = read(fd, buf + rsize, *length - rsize);
358    if(rret > 0)
359      rsize += rret;
360  }while(*length - rsize > 0 
361         && (rret > 0 || (rret == -1 && (errno == EAGAIN || errno == EINTR))));
362 
363  *length = rsize;
364  if (rret == -1 && errno != EINTR && errno != EAGAIN)
365    return errno;
366
367  return 0;
368}
369
370
371/*****************************************************************************
372 *
373 *****************************************************************************/
374bool regfi_parse_cell(int fd, uint32 offset, uint8* hdr, uint32 hdr_len,
375                      uint32* cell_length, bool* unalloc)
376{
377  uint32 length;
378  int32 raw_length;
379  uint8 tmp[4];
380
381  if(lseek(fd, offset, SEEK_SET) == -1)
382    return false;
383
384  length = 4;
385  if((regfi_read(fd, tmp, &length) != 0) || length != 4)
386    return false;
387  raw_length = IVALS(tmp, 0);
388
389  if(raw_length < 0)
390  {
391    (*cell_length) = raw_length*(-1);
392    (*unalloc) = false;
393  }
394  else
395  {
396    (*cell_length) = raw_length;
397    (*unalloc) = true;
398  }
399
400  if(*cell_length - 4 < hdr_len)
401    return false;
402
403  if(hdr_len > 0)
404  {
405    length = hdr_len;
406    if((regfi_read(fd, hdr, &length) != 0) || length != hdr_len)
407      return false;
408  }
409
410  return true;
411}
412
413
414/*******************************************************************
415 * Given an offset and an hbin, is the offset within that hbin?
416 * The offset is a virtual file offset.
417 *******************************************************************/
418static bool regfi_offset_in_hbin(REGF_HBIN* hbin, uint32 offset)
419{
420  if(!hbin)
421    return false;
422
423  if((offset > hbin->first_hbin_off) 
424     && (offset < (hbin->first_hbin_off + hbin->block_size)))
425    return true;
426               
427  return false;
428}
429
430
431
432/*******************************************************************
433 * Given a virtual offset, and receive the correpsonding HBIN
434 * block for it.  NULL if one doesn't exist.
435 *******************************************************************/
436REGF_HBIN* regfi_lookup_hbin(REGF_FILE* file, uint32 offset)
437{
438  return (REGF_HBIN*)range_list_find_data(file->hbins, offset+REGF_BLOCKSIZE);
439}
440
441
442
443/*******************************************************************
444 *******************************************************************/
445REGF_HASH_LIST* regfi_load_hashlist(REGF_FILE* file, uint32 offset, 
446                                    uint32 num_keys, uint32 max_size, 
447                                    bool strict)
448{
449  REGF_HASH_LIST* ret_val;
450  uint32 i, cell_length, length;
451  uint8* hashes;
452  uint8 buf[REGFI_HASH_LIST_MIN_LENGTH];
453  bool unalloc;
454
455  if(!regfi_parse_cell(file->fd, offset, buf, REGFI_HASH_LIST_MIN_LENGTH, 
456                       &cell_length, &unalloc))
457    return NULL;
458
459  ret_val = (REGF_HASH_LIST*)zalloc(sizeof(REGF_HASH_LIST));
460  if(ret_val == NULL)
461    return NULL;
462
463  ret_val->offset = offset;
464  if(cell_length > max_size)
465  {
466    if(strict)
467      return NULL;
468    cell_length = max_size & 0xFFFFFFF8;
469  }
470  ret_val->cell_size = cell_length;
471
472  if((buf[0] != 'l' || buf[1] != 'f') && (buf[0] != 'l' || buf[1] != 'h')
473     && (buf[0] != 'r' || buf[1] != 'i'))
474  {
475    /*printf("DEBUG: lf->header=%c%c\n", buf[0], buf[1]);*/
476    free(ret_val);
477    return NULL;
478  }
479
480  if(buf[0] == 'r' && buf[1] == 'i')
481  {
482    fprintf(stderr, "WARNING: ignoring encountered \"ri\" record.\n");
483    free(ret_val);
484    return NULL;
485  }
486
487  ret_val->magic[0] = buf[0];
488  ret_val->magic[1] = buf[1];
489
490  ret_val->num_keys = SVAL(buf, 0x2);
491  if(num_keys != ret_val->num_keys)
492  {
493    if(strict)
494    {
495      free(ret_val);
496      return NULL;
497    }
498    /* XXX: Not sure which should be authoritative, the number from the
499     *      NK record, or the number in the hash list.  Go with the larger
500     *      of the two to ensure all keys are found.  Note the length checks
501     *      on the cell later ensure that there won't be any critical errors.
502     */
503    if(num_keys < ret_val->num_keys)
504      num_keys = ret_val->num_keys;
505    else
506      ret_val->num_keys = num_keys;
507  }
508
509  if(cell_length - REGFI_HASH_LIST_MIN_LENGTH - sizeof(uint32) 
510     < ret_val->num_keys*sizeof(REGF_HASH_LIST_ELEM))
511    return NULL;
512
513  length = sizeof(REGF_HASH_LIST_ELEM)*ret_val->num_keys;
514  ret_val->hashes = (REGF_HASH_LIST_ELEM*)zalloc(length);
515  if(ret_val->hashes == NULL)
516  {
517    free(ret_val);
518    return NULL;
519  }
520
521  hashes = (uint8*)zalloc(length);
522  if(hashes == NULL)
523  {
524    free(ret_val->hashes);
525    free(ret_val);
526    return NULL;
527  }
528
529  if(regfi_read(file->fd, hashes, &length) != 0
530     || length != sizeof(REGF_HASH_LIST_ELEM)*ret_val->num_keys)
531  {
532    free(ret_val->hashes);
533    free(ret_val);
534    return NULL;
535  }
536
537  for (i=0; i < ret_val->num_keys; i++)
538  {
539    ret_val->hashes[i].nk_off = IVAL(hashes, i*sizeof(REGF_HASH_LIST_ELEM));
540    ret_val->hashes[i].hash = IVAL(hashes, i*sizeof(REGF_HASH_LIST_ELEM)+4);
541  }
542  free(hashes);
543
544  return ret_val;
545}
546
547
548
549/*******************************************************************
550 *******************************************************************/
551REGF_SK_REC* regfi_parse_sk(REGF_FILE* file, uint32 offset, uint32 max_size, bool strict)
552{
553  REGF_SK_REC* ret_val;
554  uint32 cell_length, length;
555  prs_struct ps;
556  uint8 sk_header[REGFI_SK_MIN_LENGTH];
557  bool unalloc = false;
558
559
560  if(!regfi_parse_cell(file->fd, offset, sk_header, REGFI_SK_MIN_LENGTH,
561                       &cell_length, &unalloc))
562    return NULL;
563   
564  if(sk_header[0] != 's' || sk_header[1] != 'k')
565    return NULL;
566 
567  ret_val = (REGF_SK_REC*)zalloc(sizeof(REGF_SK_REC));
568  if(ret_val == NULL)
569    return NULL;
570
571  ret_val->offset = offset;
572  /* XXX: Is there a way to be more conservative (shorter) with
573   *      cell length when cell is unallocated?
574   */
575  ret_val->cell_size = cell_length;
576
577  if(ret_val->cell_size > max_size)
578    ret_val->cell_size = max_size & 0xFFFFFFF8;
579  if((ret_val->cell_size < REGFI_SK_MIN_LENGTH) 
580     || (strict && ret_val->cell_size != (ret_val->cell_size & 0xFFFFFFF8)))
581  {
582    free(ret_val);
583    return NULL;
584  }
585
586  ret_val->magic[0] = sk_header[0];
587  ret_val->magic[1] = sk_header[1];
588
589  /* XXX: Can additional validation be added here? */
590  ret_val->unknown_tag = SVAL(sk_header, 0x2);
591  ret_val->prev_sk_off = IVAL(sk_header, 0x4);
592  ret_val->next_sk_off = IVAL(sk_header, 0x8);
593  ret_val->ref_count = IVAL(sk_header, 0xC);
594  ret_val->desc_size = IVAL(sk_header, 0x10);
595
596  if(ret_val->desc_size + REGFI_SK_MIN_LENGTH > ret_val->cell_size)
597  {
598    free(ret_val);
599    return NULL;
600  }
601
602  /* XXX: need to get rid of this, but currently the security descriptor
603   * code depends on the ps structure.
604   */
605  if(!prs_init(&ps, ret_val->desc_size, NULL, UNMARSHALL))
606  {
607    free(ret_val);
608    return NULL;
609  }
610
611  length = ret_val->desc_size;
612  if(regfi_read(file->fd, (uint8*)ps.data_p, &length) != 0 
613     || length != ret_val->desc_size)
614  {
615    free(ret_val);
616    return NULL;
617  }
618
619  if (!sec_io_desc("sec_desc", &ret_val->sec_desc, &ps, 0))
620  {
621    free(ret_val);
622    return NULL;
623  }
624
625  free(ps.data_p);
626
627  return ret_val;
628}
629
630
631uint32* regfi_parse_valuelist(REGF_FILE* file, uint32 offset, 
632                              uint32 num_values, bool strict)
633{
634  uint32* ret_val;
635  uint32 i, cell_length, length, read_len;
636  bool unalloc;
637
638  if(!regfi_parse_cell(file->fd, offset, NULL, 0, &cell_length, &unalloc))
639    return NULL;
640
641  if(cell_length != (cell_length & 0xFFFFFFF8))
642  {
643    if(strict)
644      return NULL;
645    cell_length = cell_length & 0xFFFFFFF8;
646  }
647  if((num_values * sizeof(uint32)) > cell_length-sizeof(uint32))
648    return NULL;
649
650  read_len = num_values*sizeof(uint32);
651  ret_val = (uint32*)malloc(read_len);
652  if(ret_val == NULL)
653    return NULL;
654
655  length = read_len;
656  if((regfi_read(file->fd, (uint8*)ret_val, &length) != 0) || length != read_len)
657  {
658    free(ret_val);
659    return NULL;
660  }
661 
662  for(i=0; i < num_values; i++)
663  {
664    /* Fix endianness */
665    ret_val[i] = IVAL(&ret_val[i], 0);
666
667    /* Validate the first num_values values to ensure they make sense */
668    if(strict)
669    {
670      if((ret_val[i] + REGF_BLOCKSIZE > file->file_length)
671         || ((ret_val[i] & 0xFFFFFFF8) != ret_val[i]))
672      {
673        free(ret_val);
674        return NULL;
675      }
676    }
677  }
678
679  return ret_val;
680}
681
682
683
684/******************************************************************************
685 * If !strict, the list may contain NULLs, VK records may point to NULL.
686 ******************************************************************************/
687REGF_VK_REC** regfi_load_valuelist(REGF_FILE* file, uint32 offset, 
688                                   uint32 num_values, uint32 max_size, 
689                                   bool strict)
690{
691  REGF_VK_REC** ret_val;
692  REGF_HBIN* hbin;
693  uint32 i, vk_offset, vk_max_length, usable_num_values;
694  uint32* voffsets;
695
696  if((num_values+1) * sizeof(uint32) > max_size)
697  {
698    if(strict)
699      return NULL;
700    usable_num_values = max_size/sizeof(uint32) - sizeof(uint32);
701  }
702  else
703    usable_num_values = num_values;
704
705  voffsets = regfi_parse_valuelist(file, offset, usable_num_values, strict);
706  if(voffsets == NULL)
707    return NULL;
708
709  ret_val = (REGF_VK_REC**)zalloc(sizeof(REGF_VK_REC*) * num_values);
710  if(ret_val == NULL)
711  {
712    free(voffsets);
713    return NULL;
714  }
715 
716  for(i=0; i < usable_num_values; i++)
717  {
718    hbin = regfi_lookup_hbin(file, voffsets[i]);
719    if(!hbin)
720    {
721      free(voffsets);
722      free(ret_val);
723      return NULL;
724    }
725   
726    vk_offset =  voffsets[i] + REGF_BLOCKSIZE;
727    vk_max_length = hbin->block_size - vk_offset + sizeof(uint32);
728    ret_val[i] = regfi_parse_vk(file, vk_offset, vk_max_length, strict);
729    if(ret_val[i] == NULL)
730    { /* If we're being strict, throw out the whole list.
731       * Otherwise, let it be NULL.
732       */
733      if(strict)
734      {
735        free(voffsets);
736        free(ret_val);
737        return NULL;
738      }
739    }
740  }
741
742  free(voffsets);
743  return ret_val;
744}
745
746
747
748/*******************************************************************
749 * XXX: Need to add full key caching using a
750 *      custom cache structure.
751 *******************************************************************/
752REGF_NK_REC* regfi_load_key(REGF_FILE* file, uint32 offset, bool strict)
753{
754  REGF_HBIN* hbin;
755  REGF_HBIN* sub_hbin;
756  REGF_NK_REC* nk;
757  uint32 max_length, off;
758
759  hbin = regfi_lookup_hbin(file, offset-REGF_BLOCKSIZE);
760  if (hbin == NULL) 
761    return NULL;
762
763  /* get the initial nk record */
764  max_length = hbin->block_size + hbin->file_off - offset;
765  if ((nk = regfi_parse_nk(file, offset, max_length, true)) == NULL)
766    return NULL;
767
768  /* fill in values */
769  if(nk->num_values && (nk->values_off!=REGF_OFFSET_NONE)) 
770  {
771    sub_hbin = hbin;
772    if(!regfi_offset_in_hbin(hbin, nk->values_off)) 
773      sub_hbin = regfi_lookup_hbin(file, nk->values_off);
774   
775    if(sub_hbin == NULL)
776    {
777      if(strict)
778      {
779        free(nk);
780        return NULL;
781      }
782      else
783        nk->values = NULL;
784    }
785    else
786    {
787      off = nk->values_off + REGF_BLOCKSIZE;
788      max_length = sub_hbin->block_size + sub_hbin->file_off - off;
789      nk->values = regfi_load_valuelist(file, off, nk->num_values, max_length, 
790                                        true);
791      if(strict && nk->values == NULL)
792      {
793        free(nk);
794        return NULL;
795      }
796    }
797  }
798
799  /* now get subkeys */
800  if(nk->num_subkeys && (nk->subkeys_off != REGF_OFFSET_NONE)) 
801  {
802    sub_hbin = hbin;
803    if(!regfi_offset_in_hbin(hbin, nk->subkeys_off))
804      sub_hbin = regfi_lookup_hbin(file, nk->subkeys_off);
805
806    if (sub_hbin == NULL) 
807    {
808      if(strict)
809      {
810        regfi_key_free(nk);
811        return NULL;
812      }
813      else
814        nk->subkeys = NULL;
815    }
816    else
817    {
818      off = nk->subkeys_off + REGF_BLOCKSIZE;
819      max_length = sub_hbin->block_size + sub_hbin->file_off - off;
820      nk->subkeys = regfi_load_hashlist(file, off, nk->num_subkeys, 
821                                        max_length, true);
822      if(nk->subkeys == NULL)
823      {
824        /* XXX: Temporary hack to get around 'ri' records */
825        nk->num_subkeys = 0;
826      }
827    }
828  }
829
830  return nk;
831}
832
833
834/******************************************************************************
835
836 ******************************************************************************/
837static bool regfi_find_root_nk(REGF_FILE* file, uint32 offset, uint32 hbin_size,
838                               uint32* root_offset)
839{
840  uint8 tmp[4];
841  int32 record_size;
842  uint32 length, hbin_offset = 0;
843  REGF_NK_REC* nk = NULL;
844  bool found = false;
845
846  for(record_size=0; !found && (hbin_offset < hbin_size); )
847  {
848    if(lseek(file->fd, offset+hbin_offset, SEEK_SET) == -1)
849      return false;
850   
851    length = 4;
852    if((regfi_read(file->fd, tmp, &length) != 0) || length != 4)
853      return false;
854    record_size = IVALS(tmp, 0);
855
856    if(record_size < 0)
857    {
858      record_size = record_size*(-1);
859      nk = regfi_parse_nk(file, offset+hbin_offset, hbin_size-hbin_offset, true);
860      if(nk != NULL)
861      {
862        if(nk->key_type == NK_TYPE_ROOTKEY)
863        {
864          found = true;
865          *root_offset = nk->offset;
866        }
867        free(nk);
868      }
869    }
870
871    hbin_offset += record_size;
872  }
873
874  return found;
875}
876
877
878/*******************************************************************
879 * Open the registry file and then read in the REGF block to get the
880 * first hbin offset.
881 *******************************************************************/
882REGF_FILE* regfi_open(const char* filename)
883{
884  REGF_FILE* rb;
885  REGF_HBIN* hbin = NULL;
886  uint32 hbin_off;
887  int fd;
888  bool rla;
889
890  /* open an existing file */
891  if ((fd = open(filename, O_RDONLY)) == -1) 
892  {
893    /* DEBUG(0,("regfi_open: failure to open %s (%s)\n", filename, strerror(errno)));*/
894    return NULL;
895  }
896 
897  /* read in an existing file */
898  if ((rb = regfi_parse_regf(fd, true)) == NULL) 
899  {
900    /* DEBUG(0,("regfi_open: Failed to read initial REGF block\n"));*/
901    close(fd);
902    return NULL;
903  }
904 
905  rb->hbins = range_list_new();
906  if(rb->hbins == NULL)
907  {
908    range_list_free(rb->hbins);
909    close(fd);
910    free(rb);
911    return NULL;
912  }
913 
914  rla = true;
915  hbin_off = REGF_BLOCKSIZE;
916  hbin = regfi_parse_hbin(rb, hbin_off, true);
917  while(hbin && rla)
918  {
919    hbin_off = hbin->file_off + hbin->block_size;
920    rla = range_list_add(rb->hbins, hbin->file_off, hbin->block_size, hbin);
921    hbin = regfi_parse_hbin(rb, hbin_off, true);
922  }
923
924  /* success */
925  return rb;
926}
927
928
929/*******************************************************************
930 *******************************************************************/
931int regfi_close( REGF_FILE *file )
932{
933  int fd;
934  uint32 i;
935
936  /* nothing to do if there is no open file */
937  if ((file == NULL) || (file->fd == -1))
938    return 0;
939
940  fd = file->fd;
941  file->fd = -1;
942  for(i=0; i < range_list_size(file->hbins); i++)
943    free(range_list_get(file->hbins, i)->data);
944  range_list_free(file->hbins);
945
946  free(file);
947
948  return close(fd);
949}
950
951
952/******************************************************************************
953 * There should be only *one* root key in the registry file based
954 * on my experience.  --jerry
955 *****************************************************************************/
956REGF_NK_REC* regfi_rootkey(REGF_FILE *file)
957{
958  REGF_NK_REC* nk = NULL;
959  REGF_HBIN*   hbin;
960  uint32       root_offset, i, num_hbins;
961 
962  if(!file)
963    return NULL;
964
965  /* Scan through the file one HBIN block at a time looking
966     for an NK record with a type == 0x002c.
967     Normally this is the first nk record in the first hbin
968     block (but I'm not assuming that for now) */
969
970  num_hbins = range_list_size(file->hbins);
971  for(i=0; i < num_hbins; i++)
972  {
973    hbin = (REGF_HBIN*)range_list_get(file->hbins, i)->data;
974    if(regfi_find_root_nk(file, hbin->file_off+HBIN_HEADER_REC_SIZE, 
975                          hbin->block_size-HBIN_HEADER_REC_SIZE, &root_offset))
976    {
977      nk = regfi_load_key(file, root_offset, true);
978      break;
979    }
980  }
981
982  return nk;
983}
984
985
986/******************************************************************************
987 *****************************************************************************/
988void regfi_key_free(REGF_NK_REC* nk)
989{
990  uint32 i;
991 
992  if((nk->values != NULL) && (nk->values_off!=REGF_OFFSET_NONE))
993  {
994    for(i=0; i < nk->num_values; i++)
995    {
996      if(nk->values[i]->valuename != NULL)
997        free(nk->values[i]->valuename);
998      if(nk->values[i]->data != NULL)
999        free(nk->values[i]->data);
1000      free(nk->values[i]);
1001    }
1002    free(nk->values);
1003  }
1004
1005  if(nk->keyname != NULL)
1006    free(nk->keyname);
1007  if(nk->classname != NULL)
1008    free(nk->classname);
1009
1010  /* XXX: not freeing hbin because these are cached.  This needs to be reviewed. */
1011  /* XXX: not freeing sec_desc because these are cached.  This needs to be reviewed. */
1012  free(nk);
1013}
1014
1015
1016/******************************************************************************
1017 *****************************************************************************/
1018REGFI_ITERATOR* regfi_iterator_new(REGF_FILE* fh)
1019{
1020  REGF_NK_REC* root;
1021  REGFI_ITERATOR* ret_val = (REGFI_ITERATOR*)malloc(sizeof(REGFI_ITERATOR));
1022  if(ret_val == NULL)
1023    return NULL;
1024
1025  root = regfi_rootkey(fh);
1026  if(root == NULL)
1027  {
1028    free(ret_val);
1029    return NULL;
1030  }
1031
1032  ret_val->key_positions = void_stack_new(REGF_MAX_DEPTH);
1033  if(ret_val->key_positions == NULL)
1034  {
1035    free(ret_val);
1036    free(root);
1037    return NULL;
1038  }
1039
1040  /* This secret isn't very secret, but we don't need a good one.  This
1041   * secret is just designed to prevent someone from trying to blow our
1042   * caching and make things slow.
1043   */
1044  ret_val->sk_recs = lru_cache_create(127, 0x15DEAD05^time(NULL)
1045                                           ^(getpid()<<16)^(getppid()<<8),
1046                                      true);
1047
1048  ret_val->f = fh;
1049  ret_val->cur_key = root;
1050  ret_val->cur_subkey = 0;
1051  ret_val->cur_value = 0;
1052
1053  return ret_val;
1054}
1055
1056
1057/******************************************************************************
1058 *****************************************************************************/
1059void regfi_iterator_free(REGFI_ITERATOR* i)
1060{
1061  REGFI_ITER_POSITION* cur;
1062
1063  if(i->cur_key != NULL)
1064    regfi_key_free(i->cur_key);
1065
1066  while((cur = (REGFI_ITER_POSITION*)void_stack_pop(i->key_positions)) != NULL)
1067  {
1068    regfi_key_free(cur->nk);
1069    free(cur);
1070  }
1071 
1072  lru_cache_destroy(i->sk_recs);
1073
1074  free(i);
1075}
1076
1077
1078
1079/******************************************************************************
1080 *****************************************************************************/
1081/* XXX: some way of indicating reason for failure should be added. */
1082bool regfi_iterator_down(REGFI_ITERATOR* i)
1083{
1084  REGF_NK_REC* subkey;
1085  REGFI_ITER_POSITION* pos;
1086
1087  pos = (REGFI_ITER_POSITION*)malloc(sizeof(REGFI_ITER_POSITION));
1088  if(pos == NULL)
1089    return false;
1090
1091  subkey = (REGF_NK_REC*)regfi_iterator_cur_subkey(i);
1092  if(subkey == NULL)
1093  {
1094    free(pos);
1095    return false;
1096  }
1097
1098  pos->nk = i->cur_key;
1099  pos->cur_subkey = i->cur_subkey;
1100  if(!void_stack_push(i->key_positions, pos))
1101  {
1102    free(pos);
1103    regfi_key_free(subkey);
1104    return false;
1105  }
1106
1107  i->cur_key = subkey;
1108  i->cur_subkey = 0;
1109  i->cur_value = 0;
1110
1111  return true;
1112}
1113
1114
1115/******************************************************************************
1116 *****************************************************************************/
1117bool regfi_iterator_up(REGFI_ITERATOR* i)
1118{
1119  REGFI_ITER_POSITION* pos;
1120
1121  pos = (REGFI_ITER_POSITION*)void_stack_pop(i->key_positions);
1122  if(pos == NULL)
1123    return false;
1124
1125  regfi_key_free(i->cur_key);
1126  i->cur_key = pos->nk;
1127  i->cur_subkey = pos->cur_subkey;
1128  i->cur_value = 0;
1129  free(pos);
1130
1131  return true;
1132}
1133
1134
1135/******************************************************************************
1136 *****************************************************************************/
1137bool regfi_iterator_to_root(REGFI_ITERATOR* i)
1138{
1139  while(regfi_iterator_up(i))
1140    continue;
1141
1142  return true;
1143}
1144
1145
1146/******************************************************************************
1147 *****************************************************************************/
1148bool regfi_iterator_find_subkey(REGFI_ITERATOR* i, const char* subkey_name)
1149{
1150  REGF_NK_REC* subkey;
1151  bool found = false;
1152  uint32 old_subkey = i->cur_subkey;
1153 
1154  if(subkey_name == NULL)
1155    return false;
1156
1157  /* XXX: this alloc/free of each sub key might be a bit excessive */
1158  subkey = (REGF_NK_REC*)regfi_iterator_first_subkey(i);
1159  while((subkey != NULL) && (found == false))
1160  {
1161    if(subkey->keyname != NULL 
1162       && strcasecmp(subkey->keyname, subkey_name) == 0)
1163      found = true;
1164    else
1165    {
1166      regfi_key_free(subkey);
1167      subkey = (REGF_NK_REC*)regfi_iterator_next_subkey(i);
1168    }
1169  }
1170
1171  if(found == false)
1172  {
1173    i->cur_subkey = old_subkey;
1174    return false;
1175  }
1176
1177  regfi_key_free(subkey);
1178  return true;
1179}
1180
1181
1182/******************************************************************************
1183 *****************************************************************************/
1184bool regfi_iterator_walk_path(REGFI_ITERATOR* i, const char** path)
1185{
1186  uint32 x;
1187  if(path == NULL)
1188    return false;
1189
1190  for(x=0; 
1191      ((path[x] != NULL) && regfi_iterator_find_subkey(i, path[x])
1192       && regfi_iterator_down(i));
1193      x++)
1194  { continue; }
1195
1196  if(path[x] == NULL)
1197    return true;
1198 
1199  /* XXX: is this the right number of times? */
1200  for(; x > 0; x--)
1201    regfi_iterator_up(i);
1202 
1203  return false;
1204}
1205
1206
1207/******************************************************************************
1208 *****************************************************************************/
1209const REGF_NK_REC* regfi_iterator_cur_key(REGFI_ITERATOR* i)
1210{
1211  return i->cur_key;
1212}
1213
1214
1215/******************************************************************************
1216 *****************************************************************************/
1217const REGF_SK_REC* regfi_iterator_cur_sk(REGFI_ITERATOR* i)
1218{
1219  REGF_SK_REC* ret_val;
1220  REGF_HBIN* hbin;
1221  uint32 max_length, off;
1222
1223  if(i->cur_key == NULL)
1224    return NULL;
1225 
1226  /* First look if we have already parsed it */
1227  if((i->cur_key->sk_off!=REGF_OFFSET_NONE)
1228     && !(ret_val =(REGF_SK_REC*)lru_cache_find(i->sk_recs, 
1229                                                &i->cur_key->sk_off, 4)))
1230  {
1231    hbin = regfi_lookup_hbin(i->f, i->cur_key->sk_off);
1232
1233    if(hbin == NULL)
1234      return NULL;
1235
1236    off = i->cur_key->sk_off + REGF_BLOCKSIZE;
1237    max_length = hbin->block_size + hbin->file_off - off;
1238    ret_val = regfi_parse_sk(i->f, off, max_length, true);
1239    if(ret_val == NULL)
1240      return NULL;
1241
1242    ret_val->sk_off = i->cur_key->sk_off;
1243    lru_cache_update(i->sk_recs, &i->cur_key->sk_off, 4, ret_val);
1244  }
1245
1246  return ret_val;
1247}
1248
1249
1250
1251/******************************************************************************
1252 *****************************************************************************/
1253const REGF_NK_REC* regfi_iterator_first_subkey(REGFI_ITERATOR* i)
1254{
1255  i->cur_subkey = 0;
1256  return regfi_iterator_cur_subkey(i);
1257}
1258
1259
1260/******************************************************************************
1261 *****************************************************************************/
1262const REGF_NK_REC* regfi_iterator_cur_subkey(REGFI_ITERATOR* i)
1263{
1264  uint32 nk_offset;
1265
1266  /* see if there is anything left to report */
1267  if (!(i->cur_key) || (i->cur_key->subkeys_off==REGF_OFFSET_NONE)
1268      || (i->cur_subkey >= i->cur_key->num_subkeys))
1269    return NULL;
1270
1271  nk_offset = i->cur_key->subkeys->hashes[i->cur_subkey].nk_off;
1272 
1273  return regfi_load_key(i->f, nk_offset+REGF_BLOCKSIZE, true);
1274}
1275
1276
1277/******************************************************************************
1278 *****************************************************************************/
1279/* XXX: some way of indicating reason for failure should be added. */
1280const REGF_NK_REC* regfi_iterator_next_subkey(REGFI_ITERATOR* i)
1281{
1282  const REGF_NK_REC* subkey;
1283
1284  i->cur_subkey++;
1285  subkey = regfi_iterator_cur_subkey(i);
1286
1287  if(subkey == NULL)
1288    i->cur_subkey--;
1289
1290  return subkey;
1291}
1292
1293
1294/******************************************************************************
1295 *****************************************************************************/
1296bool regfi_iterator_find_value(REGFI_ITERATOR* i, const char* value_name)
1297{
1298  const REGF_VK_REC* cur;
1299  bool found = false;
1300
1301  /* XXX: cur->valuename can be NULL in the registry. 
1302   *      Should we allow for a way to search for that?
1303   */
1304  if(value_name == NULL)
1305    return false;
1306
1307  cur = regfi_iterator_first_value(i);
1308  while((cur != NULL) && (found == false))
1309  {
1310    if((cur->valuename != NULL)
1311       && (strcasecmp(cur->valuename, value_name) == 0))
1312      found = true;
1313    else
1314      cur = regfi_iterator_next_value(i);
1315  }
1316
1317  return found;
1318}
1319
1320
1321/******************************************************************************
1322 *****************************************************************************/
1323const REGF_VK_REC* regfi_iterator_first_value(REGFI_ITERATOR* i)
1324{
1325  i->cur_value = 0;
1326  return regfi_iterator_cur_value(i);
1327}
1328
1329
1330/******************************************************************************
1331 *****************************************************************************/
1332const REGF_VK_REC* regfi_iterator_cur_value(REGFI_ITERATOR* i)
1333{
1334  REGF_VK_REC* ret_val = NULL;
1335  if(i->cur_value < i->cur_key->num_values)
1336    ret_val = i->cur_key->values[i->cur_value];
1337
1338  return ret_val;
1339}
1340
1341
1342/******************************************************************************
1343 *****************************************************************************/
1344const REGF_VK_REC* regfi_iterator_next_value(REGFI_ITERATOR* i)
1345{
1346  const REGF_VK_REC* ret_val;
1347
1348  i->cur_value++;
1349  ret_val = regfi_iterator_cur_value(i);
1350  if(ret_val == NULL)
1351    i->cur_value--;
1352
1353  return ret_val;
1354}
1355
1356
1357
1358/*******************************************************************
1359 * Computes the checksum of the registry file header.
1360 * buffer must be at least the size of an regf header (4096 bytes).
1361 *******************************************************************/
1362static uint32 regfi_compute_header_checksum(uint8* buffer)
1363{
1364  uint32 checksum, x;
1365  int i;
1366
1367  /* XOR of all bytes 0x0000 - 0x01FB */
1368
1369  checksum = x = 0;
1370 
1371  for ( i=0; i<0x01FB; i+=4 ) {
1372    x = IVAL(buffer, i );
1373    checksum ^= x;
1374  }
1375 
1376  return checksum;
1377}
1378
1379
1380/*******************************************************************
1381 * XXX: Add way to return more detailed error information.
1382 *******************************************************************/
1383REGF_FILE* regfi_parse_regf(int fd, bool strict)
1384{
1385  uint8 file_header[REGF_BLOCKSIZE];
1386  uint32 length;
1387  uint32 file_length;
1388  struct stat sbuf;
1389  REGF_FILE* ret_val;
1390
1391  /* Determine file length.  Must be at least big enough
1392   * for the header and one hbin.
1393   */
1394  if (fstat(fd, &sbuf) == -1)
1395    return NULL;
1396  file_length = sbuf.st_size;
1397  if(file_length < REGF_BLOCKSIZE+REGF_ALLOC_BLOCK)
1398    return NULL;
1399
1400  ret_val = (REGF_FILE*)zalloc(sizeof(REGF_FILE));
1401  if(ret_val == NULL)
1402    return NULL;
1403
1404  ret_val->fd = fd;
1405  ret_val->file_length = file_length;
1406
1407  length = REGF_BLOCKSIZE;
1408  if((regfi_read(fd, file_header, &length)) != 0 
1409     || length != REGF_BLOCKSIZE)
1410  {
1411    free(ret_val);
1412    return NULL;
1413  }
1414
1415  ret_val->checksum = IVAL(file_header, 0x1FC);
1416  ret_val->computed_checksum = regfi_compute_header_checksum(file_header);
1417  if (strict && (ret_val->checksum != ret_val->computed_checksum))
1418  {
1419    free(ret_val);
1420    return NULL;
1421  }
1422
1423  memcpy(ret_val->magic, file_header, 4);
1424  if(strict && (memcmp(ret_val->magic, "regf", 4) != 0))
1425  {
1426    free(ret_val);
1427    return NULL;
1428  }
1429 
1430  ret_val->unknown1 = IVAL(file_header, 0x4);
1431  ret_val->unknown2 = IVAL(file_header, 0x8);
1432
1433  ret_val->mtime.low = IVAL(file_header, 0xC);
1434  ret_val->mtime.high = IVAL(file_header, 0x10);
1435
1436  ret_val->unknown3 = IVAL(file_header, 0x14);
1437  ret_val->unknown4 = IVAL(file_header, 0x18);
1438  ret_val->unknown5 = IVAL(file_header, 0x1C);
1439  ret_val->unknown6 = IVAL(file_header, 0x20);
1440 
1441  ret_val->data_offset = IVAL(file_header, 0x24);
1442  ret_val->last_block = IVAL(file_header, 0x28);
1443
1444  ret_val->unknown7 = IVAL(file_header, 0x2C);
1445
1446  return ret_val;
1447}
1448
1449
1450
1451/*******************************************************************
1452 * Given real file offset, read and parse the hbin at that location
1453 * along with it's associated cells.
1454 *******************************************************************/
1455/* XXX: Need a way to return types of errors.
1456 */
1457REGF_HBIN* regfi_parse_hbin(REGF_FILE* file, uint32 offset, bool strict)
1458{
1459  REGF_HBIN *hbin;
1460  uint8 hbin_header[HBIN_HEADER_REC_SIZE];
1461  uint32 length;
1462 
1463  if(offset >= file->file_length)
1464    return NULL;
1465
1466  if(lseek(file->fd, offset, SEEK_SET) == -1)
1467    return NULL;
1468
1469  length = HBIN_HEADER_REC_SIZE;
1470  if((regfi_read(file->fd, hbin_header, &length) != 0) 
1471     || length != HBIN_HEADER_REC_SIZE)
1472    return NULL;
1473
1474
1475  if(lseek(file->fd, offset, SEEK_SET) == -1)
1476    return NULL;
1477
1478  if(!(hbin = (REGF_HBIN*)zalloc(sizeof(REGF_HBIN)))) 
1479    return NULL;
1480  hbin->file_off = offset;
1481
1482  memcpy(hbin->magic, hbin_header, 4);
1483  if(strict && (memcmp(hbin->magic, "hbin", 4) != 0))
1484  {
1485    free(hbin);
1486    return NULL;
1487  }
1488
1489  hbin->first_hbin_off = IVAL(hbin_header, 0x4);
1490  hbin->block_size = IVAL(hbin_header, 0x8);
1491  /* this should be the same thing as hbin->block_size but just in case */
1492  hbin->next_block = IVAL(hbin_header, 0x1C);
1493
1494
1495  /* Ensure the block size is a multiple of 0x1000 and doesn't run off
1496   * the end of the file.
1497   */
1498  /* XXX: This may need to be relaxed for dealing with
1499   *      partial or corrupt files.
1500   */
1501  if((offset + hbin->block_size > file->file_length)
1502     || (hbin->block_size & 0xFFFFF000) != hbin->block_size)
1503  {
1504    free(hbin);
1505    return NULL;
1506  }
1507
1508  return hbin;
1509}
1510
1511
1512
1513REGF_NK_REC* regfi_parse_nk(REGF_FILE* file, uint32 offset, 
1514                            uint32 max_size, bool strict)
1515{
1516  uint8 nk_header[REGFI_NK_MIN_LENGTH];
1517  REGF_NK_REC* ret_val;
1518  uint32 length;
1519  uint32 cell_length;
1520  bool unalloc = false;
1521
1522  if(!regfi_parse_cell(file->fd, offset, nk_header, REGFI_NK_MIN_LENGTH,
1523                       &cell_length, &unalloc))
1524     return NULL;
1525 
1526  /* A bit of validation before bothering to allocate memory */
1527  if((nk_header[0x0] != 'n') || (nk_header[0x1] != 'k'))
1528  {
1529    /* XXX: Deal with subkey-lists that reference other subkey-lists
1530     *      (e.g. 'ri' records).
1531     */
1532    return NULL;
1533  }
1534
1535  ret_val = (REGF_NK_REC*)zalloc(sizeof(REGF_NK_REC));
1536  if(ret_val == NULL)
1537    return NULL;
1538
1539  ret_val->offset = offset;
1540  ret_val->cell_size = cell_length;
1541
1542  if(ret_val->cell_size > max_size)
1543    ret_val->cell_size = max_size & 0xFFFFFFF8;
1544  if((ret_val->cell_size < REGFI_NK_MIN_LENGTH) 
1545     || (strict && ret_val->cell_size != (ret_val->cell_size & 0xFFFFFFF8)))
1546  {
1547    free(ret_val);
1548    return NULL;
1549  }
1550
1551  ret_val->magic[0] = nk_header[0x0];
1552  ret_val->magic[1] = nk_header[0x1];
1553  ret_val->key_type = SVAL(nk_header, 0x2);
1554  if((ret_val->key_type != NK_TYPE_NORMALKEY)
1555     && (ret_val->key_type != NK_TYPE_ROOTKEY) 
1556     && (ret_val->key_type != NK_TYPE_LINKKEY)
1557     && (ret_val->key_type != NK_TYPE_UNKNOWN1))
1558  {
1559    free(ret_val);
1560    return NULL;
1561  }
1562
1563  ret_val->mtime.low = IVAL(nk_header, 0x4);
1564  ret_val->mtime.high = IVAL(nk_header, 0x8);
1565  /* If the key is unallocated and the MTIME is earlier than Jan 1, 1990
1566   * or later than Jan 1, 2290, we consider this a bad key.  This helps
1567   * weed out some false positives during deleted data recovery.
1568   */
1569  if(unalloc
1570     && ((ret_val->mtime.high < REGFI_MTIME_MIN_HIGH
1571          && ret_val->mtime.low < REGFI_MTIME_MIN_LOW)
1572         || (ret_val->mtime.high > REGFI_MTIME_MAX_HIGH
1573             && ret_val->mtime.low > REGFI_MTIME_MAX_LOW)))
1574    return NULL;
1575
1576  ret_val->unknown1 = IVAL(nk_header, 0xC);
1577  ret_val->parent_off = IVAL(nk_header, 0x10);
1578  ret_val->num_subkeys = IVAL(nk_header, 0x14);
1579  ret_val->unknown2 = IVAL(nk_header, 0x18);
1580  ret_val->subkeys_off = IVAL(nk_header, 0x1C);
1581  ret_val->unknown3 = IVAL(nk_header, 0x20);
1582  ret_val->num_values = IVAL(nk_header, 0x24);
1583  ret_val->values_off = IVAL(nk_header, 0x28);
1584  ret_val->sk_off = IVAL(nk_header, 0x2C);
1585  /* XXX: currently we do nothing with class names.  Need to investigate. */
1586  ret_val->classname_off = IVAL(nk_header, 0x30);
1587
1588  ret_val->max_bytes_subkeyname = IVAL(nk_header, 0x34);
1589  ret_val->max_bytes_subkeyclassname = IVAL(nk_header, 0x38);
1590  ret_val->max_bytes_valuename = IVAL(nk_header, 0x3C);
1591  ret_val->max_bytes_value = IVAL(nk_header, 0x40);
1592  ret_val->unk_index = IVAL(nk_header, 0x44);
1593
1594  ret_val->name_length = SVAL(nk_header, 0x48);
1595  ret_val->classname_length = SVAL(nk_header, 0x4A);
1596
1597  if(ret_val->name_length + REGFI_NK_MIN_LENGTH > ret_val->cell_size)
1598  {
1599    if(strict)
1600    {
1601      free(ret_val);
1602      return NULL;
1603    }
1604    else
1605      ret_val->name_length = ret_val->cell_size - REGFI_NK_MIN_LENGTH;
1606  }
1607  else if (unalloc)
1608  { /* Truncate cell_size if it's much larger than the apparent total record length. */
1609    /* Round up to the next multiple of 8 */
1610    length = (ret_val->name_length + REGFI_NK_MIN_LENGTH) & 0xFFFFFFF8;
1611    if(length < ret_val->name_length + REGFI_NK_MIN_LENGTH)
1612      length+=8;
1613
1614    /* If cell_size is still greater, truncate. */
1615    if(length < ret_val->cell_size)
1616      ret_val->cell_size = length;
1617  }
1618
1619  ret_val->keyname = (char*)zalloc(sizeof(char)*(ret_val->name_length+1));
1620  if(ret_val->keyname == NULL)
1621  {
1622    free(ret_val);
1623    return NULL;
1624  }
1625
1626  /* Don't need to seek, should be at the right offset */
1627  length = ret_val->name_length;
1628  if((regfi_read(file->fd, (uint8*)ret_val->keyname, &length) != 0)
1629     || length != ret_val->name_length)
1630  {
1631    free(ret_val->keyname);
1632    free(ret_val);
1633    return NULL;
1634  }
1635  ret_val->keyname[ret_val->name_length] = '\0';
1636
1637  return ret_val;
1638}
1639
1640
1641
1642/*******************************************************************
1643 *******************************************************************/
1644REGF_VK_REC* regfi_parse_vk(REGF_FILE* file, uint32 offset, 
1645                            uint32 max_size, bool strict)
1646{
1647  REGF_VK_REC* ret_val;
1648  uint8 vk_header[REGFI_VK_MIN_LENGTH];
1649  uint32 raw_data_size, length, cell_length;
1650  bool unalloc = false;
1651
1652  if(!regfi_parse_cell(file->fd, offset, vk_header, REGFI_VK_MIN_LENGTH,
1653                       &cell_length, &unalloc))
1654    return NULL;
1655
1656  ret_val = (REGF_VK_REC*)zalloc(sizeof(REGF_VK_REC));
1657  if(ret_val == NULL)
1658    return NULL;
1659
1660  ret_val->offset = offset;
1661  ret_val->cell_size = cell_length;
1662
1663  if(ret_val->cell_size > max_size)
1664    ret_val->cell_size = max_size & 0xFFFFFFF8;
1665  if((ret_val->cell_size < REGFI_VK_MIN_LENGTH) 
1666     || ret_val->cell_size != (ret_val->cell_size & 0xFFFFFFF8))
1667  {
1668    free(ret_val);
1669    return NULL;
1670  }
1671
1672  ret_val->magic[0] = vk_header[0x0];
1673  ret_val->magic[1] = vk_header[0x1];
1674  if((ret_val->magic[0] != 'v') || (ret_val->magic[1] != 'k'))
1675  {
1676    free(ret_val);
1677    return NULL;
1678  }
1679
1680  ret_val->name_length = SVAL(vk_header, 0x2);
1681  raw_data_size = IVAL(vk_header, 0x4);
1682  ret_val->data_size = raw_data_size & ~VK_DATA_IN_OFFSET;
1683  ret_val->data_in_offset = (bool)(raw_data_size & VK_DATA_IN_OFFSET);
1684  ret_val->data_off = IVAL(vk_header, 0x8);
1685  ret_val->type = IVAL(vk_header, 0xC);
1686  ret_val->flag = SVAL(vk_header, 0x10);
1687  ret_val->unknown1 = SVAL(vk_header, 0x12);
1688
1689  if(ret_val->flag & VK_FLAG_NAME_PRESENT)
1690  {
1691    if(ret_val->name_length + REGFI_VK_MIN_LENGTH + 4 > ret_val->cell_size)
1692    {
1693      if(strict)
1694      {
1695        free(ret_val);
1696        return NULL;
1697      }
1698      else
1699        ret_val->name_length = ret_val->cell_size - REGFI_VK_MIN_LENGTH - 4;
1700    }
1701
1702    /* Round up to the next multiple of 8 */
1703    cell_length = (ret_val->name_length + REGFI_VK_MIN_LENGTH + 4) & 0xFFFFFFF8;
1704    if(cell_length < ret_val->name_length + REGFI_VK_MIN_LENGTH + 4)
1705      cell_length+=8;
1706
1707    ret_val->valuename = (char*)zalloc(sizeof(char)*(ret_val->name_length+1));
1708    if(ret_val->valuename == NULL)
1709    {
1710      free(ret_val);
1711      return NULL;
1712    }
1713
1714    length = ret_val->name_length;
1715    if((regfi_read(file->fd, (uint8*)ret_val->valuename, &length) != 0)
1716       || length != ret_val->name_length)
1717    {
1718      free(ret_val->valuename);
1719      free(ret_val);
1720      return NULL;
1721    }
1722    ret_val->valuename[ret_val->name_length] = '\0';
1723  }
1724  else
1725    cell_length = REGFI_VK_MIN_LENGTH + 4;
1726
1727  if(unalloc)
1728  {
1729    /* If cell_size is still greater, truncate. */
1730    if(cell_length < ret_val->cell_size)
1731      ret_val->cell_size = cell_length;
1732  }
1733
1734  if(ret_val->data_size == 0)
1735    ret_val->data = NULL;
1736  else
1737  {
1738    ret_val->data = regfi_parse_data(file, ret_val->data_off+REGF_BLOCKSIZE,
1739                                     raw_data_size, strict);
1740    if(strict && (ret_val->data == NULL))
1741    {
1742      free(ret_val->valuename);
1743      free(ret_val);
1744      return NULL;
1745    }
1746  }
1747
1748  return ret_val;
1749}
1750
1751
1752uint8* regfi_parse_data(REGF_FILE* file, uint32 offset, uint32 length, bool strict)
1753{
1754  uint8* ret_val;
1755  uint32 read_length, cell_length;
1756  uint8 i;
1757  bool unalloc;
1758
1759  /* The data is stored in the offset if the size <= 4 */
1760  if (length & VK_DATA_IN_OFFSET)
1761  {
1762    length = length & ~VK_DATA_IN_OFFSET;
1763    if(length > 4)
1764      return NULL;
1765
1766    if((ret_val = (uint8*)zalloc(sizeof(uint8)*length)) == NULL)
1767      return NULL;
1768
1769    offset = offset - REGF_BLOCKSIZE;
1770    for(i = 0; i < length; i++)
1771      ret_val[i] = (uint8)((offset >> i*8) & 0xFF);
1772  }
1773  else
1774  {
1775    if(!regfi_parse_cell(file->fd, offset, NULL, 0,
1776                         &cell_length, &unalloc))
1777      return NULL;
1778
1779    if((cell_length & 0xFFFFFFF8) != cell_length)
1780      return NULL;
1781
1782    if(cell_length - 4 < length)
1783    {
1784      /* XXX: This strict condition has been triggered in multiple registries.
1785       *      Not sure the cause, but the data length values are very large,
1786       *      such as 53392.
1787       */
1788      if(strict)
1789        return NULL;
1790      else
1791        length = cell_length - 4;
1792    }
1793
1794    /* XXX: There is currently no check to ensure the data
1795     *      cell doesn't cross HBIN boundary.
1796     */
1797
1798    if((ret_val = (uint8*)zalloc(sizeof(uint8)*length)) == NULL)
1799      return NULL;
1800
1801    read_length = length;
1802    if((regfi_read(file->fd, ret_val, &read_length) != 0) 
1803       || read_length != length)
1804    {
1805      free(ret_val);
1806      return NULL;
1807    }
1808  }
1809
1810  return ret_val;
1811}
1812
1813
1814range_list* regfi_parse_unalloc_cells(REGF_FILE* file)
1815{
1816  range_list* ret_val;
1817  REGF_HBIN* hbin;
1818  const range_list_element* hbins_elem;
1819  uint32 i, num_hbins, curr_off, cell_len;
1820  bool is_unalloc;
1821
1822  ret_val = range_list_new();
1823  if(ret_val == NULL)
1824    return NULL;
1825
1826  num_hbins = range_list_size(file->hbins);
1827  for(i=0; i<num_hbins; i++)
1828  {
1829    hbins_elem = range_list_get(file->hbins, i);
1830    if(hbins_elem == NULL)
1831      break;
1832    hbin = (REGF_HBIN*)hbins_elem->data;
1833
1834    curr_off = HBIN_HEADER_REC_SIZE;
1835    while(curr_off < hbin->block_size)
1836    {
1837      if(!regfi_parse_cell(file->fd, hbin->file_off+curr_off, NULL, 0,
1838                           &cell_len, &is_unalloc))
1839        break;
1840     
1841      if((cell_len == 0) || ((cell_len & 0xFFFFFFF8) != cell_len))
1842        /* XXX: should report an error here. */
1843        break;
1844     
1845      /* for some reason the record_size of the last record in
1846         an hbin block can extend past the end of the block
1847         even though the record fits within the remaining
1848         space....aaarrrgggghhhhhh */ 
1849      if(curr_off + cell_len >= hbin->block_size)
1850        cell_len = hbin->block_size - curr_off;
1851     
1852      if(is_unalloc)
1853        range_list_add(ret_val, hbin->file_off+curr_off, 
1854                       cell_len, NULL);
1855     
1856      curr_off = curr_off+cell_len;
1857    }
1858  }
1859
1860  return ret_val;
1861}
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