source: releases/0.4.0/src/reglookup.c @ 136

Last change on this file since 136 was 96, checked in by tim, 18 years ago

last minute fixes for filter bugs

  • Property svn:keywords set to Id
File size: 24.6 KB
RevLine 
[30]1/*
[42]2 * A utility to read a Windows NT/2K/XP/2K3 registry file, using
3 * Gerald Carter''s regfio interface.
[30]4 *
[81]5 * Copyright (C) 2005-2007 Timothy D. Morgan
[42]6 * Copyright (C) 2002 Richard Sharpe, rsharpe@richardsharpe.com
[30]7 *
8 * This program is free software; you can redistribute it and/or modify
9 * it under the terms of the GNU General Public License as published by
10 * the Free Software Foundation; version 2 of the License.
11 *
12 * This program is distributed in the hope that it will be useful,
13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
15 * GNU General Public License for more details.
16 *
17 * You should have received a copy of the GNU General Public License
18 * along with this program; if not, write to the Free Software
19 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. 
20 *
21 * $Id: reglookup.c 96 2007-03-29 01:41:33Z tim $
22 */
23
24
25#include <stdlib.h>
[88]26#include <sysexits.h>
[30]27#include <stdio.h>
28#include <string.h>
[33]29#include <strings.h>
[42]30#include <time.h>
[61]31#include <iconv.h>
[79]32#include "../include/regfi.h"
[31]33#include "../include/void_stack.h"
[30]34
[40]35/* Globals, influenced by command line parameters */
36bool print_verbose = false;
37bool print_security = false;
[42]38bool print_header = true;
[40]39bool path_filter_enabled = false;
40bool type_filter_enabled = false;
41char* path_filter = NULL;
42int type_filter;
43char* registry_file = NULL;
44
[42]45/* Other globals */
[66]46const char* key_special_chars = ",\"\\/";
47const char* subfield_special_chars = ",\"\\|";
48const char* common_special_chars = ",\"\\";
49
[61]50iconv_t conv_desc;
[40]51
[61]52
[38]53void bailOut(int code, char* message)
54{
55  fprintf(stderr, message);
56  exit(code);
57}
58
59
[41]60/* Returns a newly malloc()ed string which contains original buffer,
61 * except for non-printable or special characters are quoted in hex
62 * with the syntax '\xQQ' where QQ is the hex ascii value of the quoted
[61]63 * character.  A null terminator is added, since only ascii, not binary,
[41]64 * is returned.
65 */
66static char* quote_buffer(const unsigned char* str, 
[44]67                          unsigned int len, const char* special)
[41]68{
[61]69  unsigned int i, added_len;
70  unsigned int num_written = 0;
[41]71
[61]72  unsigned int buf_len = sizeof(char)*(len+1);
73  char* ret_val = malloc(buf_len);
74  char* tmp_buf;
75
[41]76  if(ret_val == NULL)
77    return NULL;
78
79  for(i=0; i<len; i++)
80  {
[61]81    if(buf_len <= (num_written+5))
82    {
83      /* Expand the buffer by the memory consumption rate seen so far
84       * times the amount of input left to process.  The expansion is bounded
85       * below by a minimum safety increase, and above by the maximum possible
[69]86       * output string length.  This should minimize both the number of
87       * reallocs() and the amount of wasted memory.
[61]88       */
89      added_len = (len-i)*num_written/(i+1);
90      if((buf_len+added_len) > (len*4+1))
91        buf_len = len*4+1;
92      else
93      {
94        if (added_len < 5)
95          buf_len += 5;
96        else
97          buf_len += added_len;
98      }
99
100      tmp_buf = realloc(ret_val, buf_len);
101      if(tmp_buf == NULL)
102      {
103        free(ret_val);
104        return NULL;
105      }
106      ret_val = tmp_buf;
107    }
108   
[41]109    if(str[i] < 32 || str[i] > 126 || strchr(special, str[i]) != NULL)
110    {
[61]111      num_written += snprintf(ret_val + num_written, buf_len - num_written,
[41]112                              "\\x%.2X", str[i]);
113    }
114    else
115      ret_val[num_written++] = str[i];
116  }
117  ret_val[num_written] = '\0';
118
119  return ret_val;
120}
121
122
123/* Returns a newly malloc()ed string which contains original string,
124 * except for non-printable or special characters are quoted in hex
125 * with the syntax '\xQQ' where QQ is the hex ascii value of the quoted
126 * character.
127 */
[44]128static char* quote_string(const char* str, const char* special)
[41]129{
[42]130  unsigned int len;
[41]131
[42]132  if(str == NULL)
133    return NULL;
134
135  len = strlen(str);
136  return quote_buffer((const unsigned char*)str, len, special);
[41]137}
138
139
140/*
[69]141 * Convert from UTF-16LE to ASCII.  Accepts a Unicode buffer, uni, and
142 * it's length, uni_max.  Writes ASCII to the buffer ascii, whose size
143 * is ascii_max.  Writes at most (ascii_max-1) bytes to ascii, and null
144 * terminates the string.  Returns the length of the string stored in
145 * ascii.  On error, returns a negative errno code.
[41]146 */
[61]147static int uni_to_ascii(unsigned char* uni, char* ascii, 
148                        unsigned int uni_max, unsigned int ascii_max)
[41]149{
[61]150  char* inbuf = (char*)uni;
151  char* outbuf = ascii;
[70]152  size_t in_len = (size_t)uni_max;
153  size_t out_len = (size_t)(ascii_max-1);
[61]154  int ret;
[41]155
[61]156  /* Set up conversion descriptor. */
157  conv_desc = iconv_open("US-ASCII", "UTF-16LE");
158
[70]159  ret = iconv(conv_desc, &inbuf, &in_len, &outbuf, &out_len);
[61]160  if(ret == -1)
[41]161  {
[61]162    iconv_close(conv_desc);
[66]163    return -errno;
[41]164  }
[66]165  *outbuf = '\0';
[41]166
[61]167  iconv_close(conv_desc); 
168  return strlen(ascii);
[41]169}
170
171
172/*
[69]173 * Convert a data value to a string for display.  Returns NULL on error,
174 * and the string to display if there is no error, or a non-fatal
175 * error.  On any error (fatal or non-fatal) occurs, (*error_msg) will
176 * be set to a newly allocated string, containing an error message.  If
177 * a memory allocation failure occurs while generating the error
178 * message, both the return value and (*error_msg) will be NULL.  It
179 * is the responsibility of the caller to free both a non-NULL return
180 * value, and a non-NULL (*error_msg).
[41]181 */
[77]182static char* data_to_ascii(unsigned char *datap, uint32 len, uint32 type, 
[69]183                           char** error_msg)
[41]184{
[61]185  char* asciip;
186  char* ascii;
[41]187  unsigned char* cur_str;
[61]188  char* cur_ascii;
[41]189  char* cur_quoted;
[69]190  char* tmp_err;
191  const char* str_type;
[77]192  uint32 i;
193  uint32 cur_str_len;
194  uint32 ascii_max, cur_str_max;
195  uint32 str_rem, cur_str_rem, alen;
[66]196  int ret_err;
[69]197  unsigned short num_nulls;
[41]198
[69]199  *error_msg = NULL;
200
[41]201  switch (type) 
202  {
[66]203  case REG_SZ:
204  case REG_EXPAND_SZ:
[61]205    /* REG_LINK is a symbolic link, stored as a unicode string. */
206  case REG_LINK:
[69]207    ascii_max = sizeof(char)*(len+1);
208    ascii = malloc(ascii_max);
[41]209    if(ascii == NULL)
210      return NULL;
211   
[66]212    /* Sometimes values have binary stored in them.  If the unicode
213     * conversion fails, just quote it raw.
214     */
215    ret_err = uni_to_ascii(datap, ascii, len, ascii_max);
216    if(ret_err < 0)
[61]217    {
[69]218      tmp_err = strerror(-ret_err);
[78]219      str_type = regfi_type_val2str(type);
[69]220      *error_msg = (char*)malloc(65+strlen(str_type)+strlen(tmp_err)+1);
221      if(*error_msg == NULL)
[71]222      {
223        free(ascii);
[69]224        return NULL;
[71]225      }
[69]226      sprintf(*error_msg, "Unicode conversion failed on %s field; "
227               "printing as binary.  Error: %s", str_type, tmp_err);
228     
[66]229      cur_quoted = quote_buffer(datap, len, common_special_chars);
[61]230    }
[66]231    else
232      cur_quoted = quote_string(ascii, common_special_chars);
[42]233    free(ascii);
[71]234    if(cur_quoted == NULL)
235    {
236      *error_msg = (char*)malloc(27+1);
237      if(*error_msg != NULL)
238        strcpy(*error_msg, "Buffer could not be quoted.");
239    }
[61]240    return cur_quoted;
[41]241    break;
242
243  case REG_DWORD:
[72]244    ascii_max = sizeof(char)*(8+2+1);
[58]245    ascii = malloc(ascii_max);
[41]246    if(ascii == NULL)
247      return NULL;
248
[61]249    snprintf(ascii, ascii_max, "0x%.2X%.2X%.2X%.2X", 
[58]250             datap[0], datap[1], datap[2], datap[3]);
[41]251    return ascii;
252    break;
253
[58]254  case REG_DWORD_BE:
[72]255    ascii_max = sizeof(char)*(8+2+1);
[58]256    ascii = malloc(ascii_max);
257    if(ascii == NULL)
258      return NULL;
259
[61]260    snprintf(ascii, ascii_max, "0x%.2X%.2X%.2X%.2X", 
[58]261             datap[3], datap[2], datap[1], datap[0]);
262    return ascii;
263    break;
264
[72]265  case REG_QWORD:
266    ascii_max = sizeof(char)*(16+2+1);
267    ascii = malloc(ascii_max);
268    if(ascii == NULL)
269      return NULL;
270
271    snprintf(ascii, ascii_max, "0x%.2X%.2X%.2X%.2X%.2X%.2X%.2X%.2X",
272             datap[7], datap[6], datap[5], datap[4],
273             datap[3], datap[2], datap[1], datap[0]);
274    return ascii;
275    break;
276   
277
[42]278  /* XXX: this MULTI_SZ parser is pretty inefficient.  Should be
[54]279   *      redone with fewer malloc calls and better string concatenation.
[42]280   */
[41]281  case REG_MULTI_SZ:
[69]282    ascii_max = sizeof(char)*(len*4+1);
283    cur_str_max = sizeof(char)*(len+1);
[41]284    cur_str = malloc(cur_str_max);
285    cur_ascii = malloc(cur_str_max);
[69]286    ascii = malloc(ascii_max);
[42]287    if(ascii == NULL || cur_str == NULL || cur_ascii == NULL)
[41]288      return NULL;
289
290    /* Reads until it reaches 4 consecutive NULLs,
291     * which is two nulls in unicode, or until it reaches len, or until we
292     * run out of buffer.  The latter should never happen, but we shouldn't
293     * trust our file to have the right lengths/delimiters.
294     */
295    asciip = ascii;
296    num_nulls = 0;
297    str_rem = ascii_max;
298    cur_str_rem = cur_str_max;
299    cur_str_len = 0;
300
301    for(i=0; (i < len) && str_rem > 0; i++)
302    {
303      *(cur_str+cur_str_len) = *(datap+i);
304      if(*(cur_str+cur_str_len) == 0)
305        num_nulls++;
306      else
307        num_nulls = 0;
308      cur_str_len++;
309
310      if(num_nulls == 2)
311      {
[66]312        ret_err = uni_to_ascii(cur_str, cur_ascii, cur_str_len-1, cur_str_max);
313        if(ret_err < 0)
[61]314        {
[69]315          /* XXX: should every sub-field error be enumerated? */
316          if(*error_msg == NULL)
317          {
318            tmp_err = strerror(-ret_err);
319            *error_msg = (char*)malloc(90+strlen(tmp_err)+1);
320            if(*error_msg == NULL)
[71]321            {
322              free(cur_str);
323              free(cur_ascii);
324              free(ascii);
[69]325              return NULL;
[71]326            }
[69]327            sprintf(*error_msg, "Unicode conversion failed on at least one "
328                    "MULTI_SZ sub-field; printing as binary.  Error: %s",
329                    tmp_err);
330          }
[66]331          cur_quoted = quote_buffer(cur_str, cur_str_len-1, 
332                                    subfield_special_chars);
[61]333        }
[66]334        else
335          cur_quoted = quote_string(cur_ascii, subfield_special_chars);
[61]336
337        alen = snprintf(asciip, str_rem, "%s", cur_quoted);
[41]338        asciip += alen;
339        str_rem -= alen;
340        free(cur_quoted);
341
342        if(*(datap+i+1) == 0 && *(datap+i+2) == 0)
343          break;
344        else
345        {
[61]346          if(str_rem > 0)
347          {
348            asciip[0] = '|';
349            asciip[1] = '\0';
350            asciip++;
351            str_rem--;
352          }
[41]353          memset(cur_str, 0, cur_str_max);
354          cur_str_len = 0;
355          num_nulls = 0;
356          /* To eliminate leading nulls in subsequent strings. */
357          i++;
358        }
359      }
360    }
361    *asciip = 0;
[42]362    free(cur_str);
363    free(cur_ascii);
[41]364    return ascii;
365    break;
366
[42]367  /* XXX: Dont know what to do with these yet, just print as binary... */
[77]368  default:
369    fprintf(stderr, "WARNING: Unrecognized registry data type (0x%.8X); quoting as binary.\n", type);
370   
[61]371  case REG_NONE:
[42]372  case REG_RESOURCE_LIST:
373  case REG_FULL_RESOURCE_DESCRIPTOR:
374  case REG_RESOURCE_REQUIREMENTS_LIST:
375
376  case REG_BINARY:
[66]377    return quote_buffer(datap, len, common_special_chars);
[42]378    break;
[71]379  }
[42]380
[41]381  return NULL;
382}
383
384
[83]385/* XXX: Each chunk must be unquoted after it is split out.
386 *      Quoting syntax may need to be standardized and pushed into the API
387 *      to deal with this issue and others.
388 */
[81]389char** splitPath(const char* s)
[30]390{
[81]391  char** ret_val;
[38]392  const char* cur = s;
[33]393  char* next = NULL;
[38]394  char* copy;
[81]395  uint32 ret_cur = 0;
[38]396
[81]397  ret_val = (char**)malloc((REGF_MAX_DEPTH+1+1)*sizeof(char**));
398  if (ret_val == NULL)
[38]399    return NULL;
[81]400  ret_val[0] = NULL;
401
402  /* We return a well-formed, 0-length, path even when input is icky. */
[37]403  if (s == NULL)
[81]404    return ret_val;
[38]405 
406  while((next = strchr(cur, '/')) != NULL)
[33]407  {
[38]408    if ((next-cur) > 0)
409    {
410      copy = (char*)malloc((next-cur+1)*sizeof(char));
411      if(copy == NULL)
[88]412        bailOut(EX_OSERR, "ERROR: Memory allocation problem.\n");
[38]413         
414      memcpy(copy, cur, next-cur);
415      copy[next-cur] = '\0';
[81]416      ret_val[ret_cur++] = copy;
417      if(ret_cur < (REGF_MAX_DEPTH+1+1))
418        ret_val[ret_cur] = NULL;
419      else
[88]420        bailOut(EX_DATAERR, "ERROR: Registry maximum depth exceeded.\n");
[38]421    }
422    cur = next+1;
[33]423  }
[81]424
425  /* Grab last element, if path doesn't end in '/'. */
[33]426  if(strlen(cur) > 0)
[38]427  {
428    copy = strdup(cur);
[81]429    ret_val[ret_cur++] = copy;
430    if(ret_cur < (REGF_MAX_DEPTH+1+1))
431      ret_val[ret_cur] = NULL;
432    else
[88]433      bailOut(EX_DATAERR, "ERROR: Registry maximum depth exceeded.\n");
[38]434  }
[33]435
436  return ret_val;
437}
438
[81]439
[83]440void freePath(char** path)
441{
442  uint32 i;
443
444  if(path == NULL)
445    return;
446
447  for(i=0; path[i] != NULL; i++)
448    free(path[i]);
449
450  free(path);
451}
452
453
[81]454/* Returns a quoted path from an iterator's stack */
455/* XXX: Some way should be found to integrate this into regfi's API
456 *      The problem is that the escaping is sorta reglookup-specific.
457 */
458char* iter2Path(REGFI_ITERATOR* i)
[33]459{
[81]460  const REGFI_ITER_POSITION* cur;
[37]461  uint32 buf_left = 127;
462  uint32 buf_len = buf_left+1;
463  uint32 name_len = 0;
464  uint32 grow_amt;
[81]465  char* buf;
[31]466  char* new_buf;
[66]467  char* name;
[81]468  const char* cur_name;
[31]469  void_stack_iterator* iter;
470 
471  buf = (char*)malloc((buf_len)*sizeof(char));
472  if (buf == NULL)
473    return NULL;
[54]474  buf[0] = '\0';
[30]475
[81]476  iter = void_stack_iterator_new(i->key_positions);
[31]477  if (iter == NULL)
[30]478  {
[31]479    free(buf);
480    return NULL;
[30]481  }
482
[33]483  /* skip root element */
[81]484  if(void_stack_size(i->key_positions) < 1)
485  {
486    buf[0] = '/';
487    buf[1] = '\0';
488    return buf;
489  }
[33]490  cur = void_stack_iterator_next(iter);
491
[81]492  do
[31]493  {
[81]494    cur = void_stack_iterator_next(iter);
495    if (cur == NULL)
496      cur_name = i->cur_key->keyname;
497    else
498      cur_name = cur->nk->keyname;
499
[33]500    buf[buf_len-buf_left-1] = '/';
501    buf_left -= 1;
[81]502    name = quote_string(cur_name, key_special_chars);
[66]503    name_len = strlen(name);
[31]504    if(name_len+1 > buf_left)
505    {
[37]506      grow_amt = (uint32)(buf_len/2);
[31]507      buf_len += name_len+1+grow_amt-buf_left;
508      if((new_buf = realloc(buf, buf_len)) == NULL)
509      {
510        free(buf);
511        free(iter);
512        return NULL;
513      }
514      buf = new_buf;
515      buf_left = grow_amt + name_len + 1;
516    }
[66]517    strncpy(buf+(buf_len-buf_left-1), name, name_len);
[31]518    buf_left -= name_len;
519    buf[buf_len-buf_left-1] = '\0';
[66]520    free(name);
[81]521  } while(cur != NULL);
[30]522
[31]523  return buf;
524}
[30]525
[31]526
[84]527void printValue(const REGF_VK_REC* vk, char* prefix)
[31]528{
[66]529  char* quoted_value = NULL;
530  char* quoted_name = NULL;
[69]531  char* conv_error = NULL;
[77]532  const char* str_type = NULL;
533  uint32 size;
534  uint8 tmp_buf[4];
[41]535
[43]536  /* Thanks Microsoft for making this process so straight-forward!!! */
[84]537  /* XXX: this logic should be abstracted  and pushed into the regfi
538   *      interface.  This includes the size limits.
539   */
[43]540  size = (vk->data_size & ~VK_DATA_IN_OFFSET);
541  if(vk->data_size & VK_DATA_IN_OFFSET)
[41]542  {
[43]543    tmp_buf[0] = (uint8)((vk->data_off >> 3) & 0xFF);
544    tmp_buf[1] = (uint8)((vk->data_off >> 2) & 0xFF);
545    tmp_buf[2] = (uint8)((vk->data_off >> 1) & 0xFF);
546    tmp_buf[3] = (uint8)(vk->data_off & 0xFF);
547    if(size > 4)
[90]548    {
549      fprintf(stderr, "WARNING: value stored in offset larger than 4. "
550              "Truncating...\n");
[43]551      size = 4;
[90]552    }
[69]553    quoted_value = data_to_ascii(tmp_buf, 4, vk->type, &conv_error);
[43]554  }
555  else
556  {
[77]557    /* Microsoft's documentation indicates that "available memory" is
558     * the limit on value sizes.  Annoying.  We limit it to 1M which
559     * should rarely be exceeded, unless the file is corrupt or
560     * malicious. For more info, see:
561     *   http://msdn2.microsoft.com/en-us/library/ms724872.aspx
[43]562     */
[77]563    if(size > VK_MAX_DATA_LENGTH)
[41]564    {
[77]565      fprintf(stderr, "WARNING: value data size %d larger than "
566              "%d, truncating...\n", size, VK_MAX_DATA_LENGTH);
567      size = VK_MAX_DATA_LENGTH;
[41]568    }
[61]569
[69]570    quoted_value = data_to_ascii(vk->data, vk->data_size, 
571                                 vk->type, &conv_error);
[43]572  }
573 
574  /* XXX: Sometimes value names can be NULL in registry.  Need to
575   *      figure out why and when, and generate the appropriate output
576   *      for that condition.
577   */
[66]578  quoted_name = quote_string(vk->valuename, common_special_chars);
[88]579  if (quoted_name == NULL)
580  {
581    quoted_name = malloc(1*sizeof(char));
582    if(quoted_name == NULL)
583      bailOut(EX_OSERR, "ERROR: Could not allocate sufficient memory.\n");
584    quoted_name[0] = '\0';
585  }
[69]586
587  if(quoted_value == NULL)
588  {
589    if(conv_error == NULL)
[71]590      fprintf(stderr, "WARNING: Could not quote value for '%s/%s'.  "
[69]591              "Memory allocation failure likely.\n", prefix, quoted_name);
592    else
[71]593      fprintf(stderr, "WARNING: Could not quote value for '%s/%s'.  "
[69]594              "Returned error: %s\n", prefix, quoted_name, conv_error);
595  }
596  /* XXX: should these always be printed? */
597  else if(conv_error != NULL && print_verbose)
598      fprintf(stderr, "VERBOSE: While quoting value for '%s/%s', "
599              "warning returned: %s\n", prefix, quoted_name, conv_error);
600
[78]601  str_type = regfi_type_val2str(vk->type);
[43]602  if(print_security)
[77]603  {
604    if(str_type == NULL)
605      printf("%s/%s,0x%.8X,%s,,,,,\n", prefix, quoted_name,
606             vk->type, quoted_value);
607    else
608      printf("%s/%s,%s,%s,,,,,\n", prefix, quoted_name,
609             str_type, quoted_value);
610  }
[43]611  else
[77]612  {
613    if(str_type == NULL)
614      printf("%s/%s,0x%.8X,%s,\n", prefix, quoted_name,
615             vk->type, quoted_value);
616    else
617      printf("%s/%s,%s,%s,\n", prefix, quoted_name,
618             str_type, quoted_value);
619  }
620
[43]621  if(quoted_value != NULL)
622    free(quoted_value);
623  if(quoted_name != NULL)
624    free(quoted_name);
[69]625  if(conv_error != NULL)
626    free(conv_error);
[32]627}
628
629
[81]630void printValueList(REGFI_ITERATOR* i, char* prefix)
[32]631{
[84]632  const REGF_VK_REC* value;
[80]633
634  value = regfi_iterator_first_value(i);
635  while(value != NULL)
[81]636  {
637    if(!type_filter_enabled || (value->type == type_filter))
[80]638      printValue(value, prefix);
[81]639    value = regfi_iterator_next_value(i);
640  }
[33]641}
642
[37]643
[84]644void printKey(const REGF_NK_REC* k, char* full_path)
[33]645{
[43]646  static char empty_str[1] = "";
[42]647  char* owner = NULL;
648  char* group = NULL;
649  char* sacl = NULL;
650  char* dacl = NULL;
651  char mtime[20];
652  time_t tmp_time[1];
653  struct tm* tmp_time_s = NULL;
654
[43]655  *tmp_time = nt_time_to_unix(&k->mtime);
656  tmp_time_s = gmtime(tmp_time);
657  strftime(mtime, sizeof(mtime), "%Y-%m-%d %H:%M:%S", tmp_time_s);
658
659  if(print_security)
660  {
[78]661    owner = regfi_get_owner(k->sec_desc->sec_desc);
662    group = regfi_get_group(k->sec_desc->sec_desc);
663    sacl = regfi_get_sacl(k->sec_desc->sec_desc);
664    dacl = regfi_get_dacl(k->sec_desc->sec_desc);
[43]665    if(owner == NULL)
666      owner = empty_str;
667    if(group == NULL)
668      group = empty_str;
669    if(sacl == NULL)
670      sacl = empty_str;
671    if(dacl == NULL)
672      dacl = empty_str;
673
[66]674    printf("%s,KEY,,%s,%s,%s,%s,%s\n", full_path, mtime, 
[43]675           owner, group, sacl, dacl);
676
677    if(owner != empty_str)
678      free(owner);
679    if(group != empty_str)
680      free(group);
681    if(sacl != empty_str)
682      free(sacl);
683    if(dacl != empty_str)
684      free(dacl);
685  }
686  else
[66]687    printf("%s,KEY,,%s\n", full_path, mtime);
[43]688}
689
690
[81]691void printKeyTree(REGFI_ITERATOR* iter)
[43]692{
[84]693  const REGF_NK_REC* root = NULL;
694  const REGF_NK_REC* cur = NULL;
695  const REGF_NK_REC* sub = NULL;
[43]696  char* path = NULL;
[78]697  int key_type = regfi_type_str2val("KEY");
[81]698  bool print_this = true;
699
700  root = cur = regfi_iterator_cur_key(iter);
701  sub = regfi_iterator_first_subkey(iter);
[43]702 
[81]703  if(root == NULL)
[88]704    bailOut(EX_DATAERR, "ERROR: root cannot be NULL.\n");
[81]705 
706  do
[31]707  {
[81]708    if(print_this)
[54]709    {
[81]710      path = iter2Path(iter);
711      if(path == NULL)
[88]712        bailOut(EX_OSERR, "ERROR: Could not construct iterator's path.\n");
[81]713     
714      if(!type_filter_enabled || (key_type == type_filter))
715        printKey(cur, path);
716      if(!type_filter_enabled || (key_type != type_filter))
717        printValueList(iter, path);
718     
719      free(path);
[54]720    }
[66]721   
[81]722    if(sub == NULL)
[31]723    {
[81]724      if(cur != root)
[31]725      {
[81]726        /* We're done with this sub-tree, going up and hitting other branches. */
727        if(!regfi_iterator_up(iter))
[88]728          bailOut(EX_DATAERR, "ERROR: could not traverse iterator upward.\n");
[81]729       
730        cur = regfi_iterator_cur_key(iter);
731        if(cur == NULL)
[88]732          bailOut(EX_DATAERR, "ERROR: unexpected NULL for key.\n");
[81]733       
734        sub = regfi_iterator_next_subkey(iter);
[66]735      }
[81]736      print_this = false;
[31]737    }
[81]738    else
739    { /* We have unexplored sub-keys. 
740       * Let's move down and print this first sub-tree out.
741       */
742      if(!regfi_iterator_down(iter))
[88]743        bailOut(EX_DATAERR, "ERROR: could not traverse iterator downward.\n");
[81]744
745      cur = sub;
746      sub = regfi_iterator_first_subkey(iter);
747      print_this = true;
748    }
749  } while(!((cur == root) && (sub == NULL)));
750
[54]751  if(print_verbose)
752    fprintf(stderr, "VERBOSE: Finished printing key tree.\n");
[30]753}
754
[81]755
[33]756/*
[80]757 * Returns 0 if path was not found.
758 * Returns 1 if path was found as value.
759 * Returns 2 if path was found as key.
[33]760 * Returns less than 0 on other error.
761 */
[80]762int retrievePath(REGFI_ITERATOR* iter, char** path)
[33]763{
[84]764  const REGF_VK_REC* value;
[81]765  char* tmp_path_joined;
766  const char** tmp_path;
[80]767  uint32 i;
768 
769  if(path == NULL)
[33]770    return -1;
771
[80]772  /* One extra for any value at the end, and one more for NULL */
[81]773  tmp_path = (const char**)malloc(sizeof(const char**)*(REGF_MAX_DEPTH+1+1));
[80]774  if(tmp_path == NULL)
[33]775    return -2;
776
[80]777  /* Strip any potential value name at end of path */
778  for(i=0; 
779      (path[i] != NULL) && (path[i+1] != NULL) 
780        && (i < REGF_MAX_DEPTH+1+1);
781      i++)
782    tmp_path[i] = path[i];
[33]783
[80]784  tmp_path[i] = NULL;
785
[54]786  if(print_verbose)
[80]787    fprintf(stderr, "VERBOSE: Attempting to retrieve specified path: %s\n",
[54]788            path_filter);
789
[82]790  /* Special check for '/' path filter */
791  if(path[0] == NULL)
792  {
793    if(print_verbose)
794      fprintf(stderr, "VERBOSE: Found final path element as root key.\n");
795    return 2;
796  }
797
[80]798  if(!regfi_iterator_walk_path(iter, tmp_path))
[33]799  {
[80]800    free(tmp_path);
801    return 0;
[33]802  }
803
[80]804  if(regfi_iterator_find_value(iter, path[i]))
805  {
806    if(print_verbose)
807      fprintf(stderr, "VERBOSE: Found final path element as value.\n");
[33]808
[80]809    value = regfi_iterator_cur_value(iter);
[81]810    tmp_path_joined = iter2Path(iter);
[54]811
[80]812    if((value == NULL) || (tmp_path_joined == NULL))
[88]813      bailOut(EX_OSERR, "ERROR: Unexpected error before printValue.\n");
[54]814
[80]815    printValue(value, tmp_path_joined);
[54]816
[80]817    free(tmp_path);
818    free(tmp_path_joined);
819    return 1;
[33]820  }
[80]821  else if(regfi_iterator_find_subkey(iter, path[i]))
[33]822  {
[80]823    if(print_verbose)
824      fprintf(stderr, "VERBOSE: Found final path element as key.\n");
[82]825
826    if(!regfi_iterator_down(iter))
[88]827      bailOut(EX_DATAERR, "ERROR: Unexpected error on traversing path filter key.\n");
[82]828
[80]829    return 2;
[33]830  }
831
[54]832  if(print_verbose)
833    fprintf(stderr, "VERBOSE: Could not find last element of path.\n");
834
[80]835  return 0;
[33]836}
837
838
[37]839static void usage(void)
840{
[61]841  fprintf(stderr, "Usage: reglookup [-v] [-s]"
[40]842          " [-p <PATH_FILTER>] [-t <TYPE_FILTER>]"
[39]843          " <REGISTRY_FILE>\n");
[85]844  fprintf(stderr, "Version: 0.4.0\n");
[39]845  fprintf(stderr, "Options:\n");
846  fprintf(stderr, "\t-v\t sets verbose mode.\n");
[47]847  fprintf(stderr, "\t-h\t enables header row. (default)\n");
848  fprintf(stderr, "\t-H\t disables header row.\n");
[44]849  fprintf(stderr, "\t-s\t enables security descriptor output.\n");
850  fprintf(stderr, "\t-S\t disables security descriptor output. (default)\n");
[40]851  fprintf(stderr, "\t-p\t restrict output to elements below this path.\n");
852  fprintf(stderr, "\t-t\t restrict results to this specific data type.\n");
[37]853  fprintf(stderr, "\n");
854}
855
856
[30]857int main(int argc, char** argv)
858{
[80]859  char** path = NULL;
[31]860  REGF_FILE* f;
[80]861  REGFI_ITERATOR* iter;
[33]862  int retr_path_ret;
[44]863  uint32 argi, arge;
[31]864
[37]865  /* Process command line arguments */
[30]866  if(argc < 2)
867  {
[37]868    usage();
[88]869    bailOut(EX_USAGE, "ERROR: Requires at least one argument.\n");
[30]870  }
[37]871 
[44]872  arge = argc-1;
873  for(argi = 1; argi < arge; argi++)
[37]874  {
[40]875    if (strcmp("-p", argv[argi]) == 0)
[37]876    {
[44]877      if(++argi >= arge)
[37]878      {
879        usage();
[88]880        bailOut(EX_USAGE, "ERROR: '-p' option requires parameter.\n");
[37]881      }
[40]882      if((path_filter = strdup(argv[argi])) == NULL)
[88]883        bailOut(EX_OSERR, "ERROR: Memory allocation problem.\n");
[38]884
[40]885      path_filter_enabled = true;
[37]886    }
887    else if (strcmp("-t", argv[argi]) == 0)
888    {
[44]889      if(++argi >= arge)
[37]890      {
891        usage();
[88]892        bailOut(EX_USAGE, "ERROR: '-t' option requires parameter.\n");
[37]893      }
[78]894      if((type_filter = regfi_type_str2val(argv[argi])) < 0)
[40]895      {
896        fprintf(stderr, "ERROR: Invalid type specified: %s.\n", argv[argi]);
[88]897        bailOut(EX_USAGE, "");
[40]898      }
[37]899      type_filter_enabled = true;
900    }
[47]901    else if (strcmp("-h", argv[argi]) == 0)
902      print_header = true;
903    else if (strcmp("-H", argv[argi]) == 0)
904      print_header = false;
[37]905    else if (strcmp("-s", argv[argi]) == 0)
906      print_security = true;
[44]907    else if (strcmp("-S", argv[argi]) == 0)
908      print_security = false;
[37]909    else if (strcmp("-v", argv[argi]) == 0)
910      print_verbose = true;
[44]911    else
[37]912    {
[38]913      usage();
[37]914      fprintf(stderr, "ERROR: Unrecognized option: %s\n", argv[argi]);
[88]915      bailOut(EX_USAGE, "");
[37]916    }
917  }
[44]918  if((registry_file = strdup(argv[argi])) == NULL)
[88]919    bailOut(EX_OSERR, "ERROR: Memory allocation problem.\n");
[30]920
[78]921  f = regfi_open(registry_file);
[37]922  if(f == NULL)
923  {
924    fprintf(stderr, "ERROR: Couldn't open registry file: %s\n", registry_file);
[88]925    bailOut(EX_NOINPUT, "");
[37]926  }
[38]927
[80]928  iter = regfi_iterator_new(f);
929  if(iter == NULL)
[88]930    bailOut(EX_OSERR, "ERROR: Couldn't create registry iterator.\n");
[30]931
[81]932  if(print_header)
933  {
934    if(print_security)
935      printf("PATH,TYPE,VALUE,MTIME,OWNER,GROUP,SACL,DACL\n");
936    else
937      printf("PATH,TYPE,VALUE,MTIME\n");
938  }
939
[80]940  if(path_filter_enabled && path_filter != NULL)
941    path = splitPath(path_filter);
[81]942
[80]943  if(path != NULL)
[33]944  {
[80]945    retr_path_ret = retrievePath(iter, path);
[83]946    freePath(path);
947
[80]948    if(retr_path_ret == 0)
949      fprintf(stderr, "WARNING: specified path not found.\n");
950    else if (retr_path_ret == 2)
[81]951      printKeyTree(iter);
[96]952    else if(retr_path_ret < 0)
953    {
954      fprintf(stderr, "ERROR: retrievePath() returned %d.\n", 
955              retr_path_ret);
956      bailOut(EX_DATAERR,"ERROR: Unknown error occurred in retrieving path.\n");
957    }
[33]958  }
[37]959  else
[81]960    printKeyTree(iter);
[31]961
[80]962  regfi_iterator_free(iter);
[78]963  regfi_close(f);
[30]964
965  return 0;
966}
Note: See TracBrowser for help on using the repository browser.