1/*************************************************
2*           PCRE2 DEMONSTRATION PROGRAM          *
3*************************************************/
4
5/* This is a demonstration program to illustrate a straightforward way of
6using the PCRE2 regular expression library from a C program. See the
7pcre2sample documentation for a short discussion ("man pcre2sample" if you have
8the PCRE2 man pages installed). PCRE2 is a revised API for the library, and is
9incompatible with the original PCRE API.
10
11There are actually three libraries, each supporting a different code unit
12width. This demonstration program uses the 8‐bit library. The default is to
13process each code unit as a separate character, but if the pattern begins with
14"(*UTF)", both it and the subject are treated as UTF‐8 strings, where
15characters may occupy multiple code units.
16
17In Unix‐like environments, if PCRE2 is installed in your standard system
18libraries, you should be able to compile this program using this command:
19
20cc ‐Wall pcre2demo.c ‐lpcre2‐8 ‐o pcre2demo
21
22If PCRE2 is not installed in a standard place, it is likely to be installed
23with support for the pkg‐config mechanism. If you have pkg‐config, you can
24compile this program using this command:
25
26cc ‐Wall pcre2demo.c ‘pkg‐config ‐‐cflags ‐‐libs libpcre2‐8‘ ‐o pcre2demo
27
28If you do not have pkg‐config, you may have to use something like this:
29
30cc ‐Wall pcre2demo.c ‐I/usr/local/include ‐L/usr/local/lib \
31  ‐R/usr/local/lib ‐lpcre2‐8 ‐o pcre2demo
32
33Replace "/usr/local/include" and "/usr/local/lib" with wherever the include and
34library files for PCRE2 are installed on your system. Only some operating
35systems (Solaris is one) use the ‐R option.
36
37Building under Windows:
38
39If you want to statically link this program against a non‐dll .a file, you must
40define PCRE2_STATIC before including pcre2.h, so in this environment, uncomment
41the following line. */
42
43/* #define PCRE2_STATIC */
44
45/* The PCRE2_CODE_UNIT_WIDTH macro must be defined before including pcre2.h.
46For a program that uses only one code unit width, setting it to 8, 16, or 32
47makes it possible to use generic function names such as pcre2_compile(). Note
48that just changing 8 to 16 (for example) is not sufficient to convert this
49program to process 16‐bit characters. Even in a fully 16‐bit environment, where
50string‐handling functions such as strcmp() and printf() work with 16‐bit
51characters, the code for handling the table of named substrings will still need
52to be modified. */
53
54#define PCRE2_CODE_UNIT_WIDTH 8
55
56#include <stdio.h>
57#include <string.h>
58#include <pcre2.h>
59
60
61/**************************************************************************
62* Here is the program. The API includes the concept of "contexts" for     *
63* setting up unusual interface requirements for compiling and matching,   *
64* such as custom memory managers and non‐standard newline definitions.    *
65* This program does not do any of this, so it makes no use of contexts,   *
66* always passing NULL where a context could be given.                     *
67**************************************************************************/
68
69int main(int argc, char **argv)
70{
71pcre2_code *re;
72PCRE2_SPTR pattern;     /* PCRE2_SPTR is a pointer to unsigned code units of */
73PCRE2_SPTR subject;     /* the appropriate width (in this case, 8 bits). */
74PCRE2_SPTR name_table;
75
76int crlf_is_newline;
77int errornumber;
78int find_all;
79int i;
80int rc;
81int utf8;
82
83uint32_t option_bits;
84uint32_t namecount;
85uint32_t name_entry_size;
86uint32_t newline;
87
88PCRE2_SIZE erroroffset;
89PCRE2_SIZE *ovector;
90
91size_t subject_length;
92pcre2_match_data *match_data;
93
94
95
96/**************************************************************************
97* First, sort out the command line. There is only one possible option at  *
98* the moment, "‐g" to request repeated matching to find all occurrences,  *
99* like Perl’s /g option. We set the variable find_all to a non‐zero value *
100* if the ‐g option is present.                                            *
101**************************************************************************/
102
103find_all = 0;
104for (i = 1; i < argc; i++)
105  {
106  if (strcmp(argv[i], "‐g") == 0) find_all = 1;
107  else if (argv[i][0] == ’‐’)
108    {
109    printf("Unrecognised option %s\n", argv[i]);
110    return 1;
111    }
112  else break;
113  }
114
115/* After the options, we require exactly two arguments, which are the pattern,
116and the subject string. */
117
118if (argc ‐ i != 2)
119  {
120  printf("Exactly two arguments required: a regex and a subject string\n");
121  return 1;
122  }
123
124/* As pattern and subject are char arguments, they can be straightforwardly
125cast to PCRE2_SPTR as we are working in 8‐bit code units. */
126
127pattern = (PCRE2_SPTR)argv[i];
128subject = (PCRE2_SPTR)argv[i+1];
129subject_length = strlen((char *)subject);
130
131
132/*************************************************************************
133* Now we are going to compile the regular expression pattern, and handle *
134* any errors that are detected.                                          *
135*************************************************************************/
136
137re = pcre2_compile(
138  pattern,               /* the pattern */
139  PCRE2_ZERO_TERMINATED, /* indicates pattern is zero‐terminated */
140  0,                     /* default options */
141  &errornumber,          /* for error number */
142  &erroroffset,          /* for error offset */
143  NULL);                 /* use default compile context */
144
145/* Compilation failed: print the error message and exit. */
146
147if (re == NULL)
148  {
149  PCRE2_UCHAR buffer[256];
150  pcre2_get_error_message(errornumber, buffer, sizeof(buffer));
151  printf("PCRE2 compilation failed at offset %d: %s\n", (int)erroroffset,
152    buffer);
153  return 1;
154  }
155
156
157/*************************************************************************
158* If the compilation succeeded, we call PCRE again, in order to do a     *
159* pattern match against the subject string. This does just ONE match. If *
160* further matching is needed, it will be done below. Before running the  *
161* match we must set up a match_data block for holding the result.        *
162*************************************************************************/
163
164/* Using this function ensures that the block is exactly the right size for
165the number of capturing parentheses in the pattern. */
166
167match_data = pcre2_match_data_create_from_pattern(re, NULL);
168
169rc = pcre2_match(
170  re,                   /* the compiled pattern */
171  subject,              /* the subject string */
172  subject_length,       /* the length of the subject */
173  0,                    /* start at offset 0 in the subject */
174  0,                    /* default options */
175  match_data,           /* block for storing the result */
176  NULL);                /* use default match context */
177
178/* Matching failed: handle error cases */
179
180if (rc < 0)
181  {
182  switch(rc)
183    {
184    case PCRE2_ERROR_NOMATCH: printf("No match\n"); break;
185    /*
186    Handle other special cases if you like
187    */
188    default: printf("Matching error %d\n", rc); break;
189    }
190  pcre2_match_data_free(match_data);   /* Release memory used for the match */
191  pcre2_code_free(re);                 /* data and the compiled pattern. */
192  return 1;
193  }
194
195/* Match succeded. Get a pointer to the output vector, where string offsets are
196stored. */
197
198ovector = pcre2_get_ovector_pointer(match_data);
199printf("Match succeeded at offset %d\n", (int)ovector[0]);
200
201
202/*************************************************************************
203* We have found the first match within the subject string. If the output *
204* vector wasn’t big enough, say so. Then output any substrings that were *
205* captured.                                                              *
206*************************************************************************/
207
208/* The output vector wasn’t big enough. This should not happen, because we used
209pcre2_match_data_create_from_pattern() above. */
210
211if (rc == 0)
212  printf("ovector was not big enough for all the captured substrings\n");
213
214/* We must guard against patterns such as /(?=.\K)/ that use \K in an assertion
215to set the start of a match later than its end. In this demonstration program,
216we just detect this case and give up. */
217
218if (ovector[0] > ovector[1])
219  {
220  printf("\\K was used in an assertion to set the match start after its end.\n"
221    "From end to start the match was: %.*s\n", (int)(ovector[0] ‐ ovector[1]),
222      (char *)(subject + ovector[1]));
223  printf("Run abandoned\n");
224  pcre2_match_data_free(match_data);
225  pcre2_code_free(re);
226  return 1;
227  }
228
229/* Show substrings stored in the output vector by number. Obviously, in a real
230application you might want to do things other than print them. */
231
232for (i = 0; i < rc; i++)
233  {
234  PCRE2_SPTR substring_start = subject + ovector[2*i];
235  size_t substring_length = ovector[2*i+1] ‐ ovector[2*i];
236  printf("%2d: %.*s\n", i, (int)substring_length, (char *)substring_start);
237  }
238
239
240/**************************************************************************
241* That concludes the basic part of this demonstration program. We have    *
242* compiled a pattern, and performed a single match. The code that follows *
243* shows first how to access named substrings, and then how to code for    *
244* repeated matches on the same subject.                                   *
245**************************************************************************/
246
247/* See if there are any named substrings, and if so, show them by name. First
248we have to extract the count of named parentheses from the pattern. */
249
250(void)pcre2_pattern_info(
251  re,                   /* the compiled pattern */
252  PCRE2_INFO_NAMECOUNT, /* get the number of named substrings */
253  &namecount);          /* where to put the answer */
254
255if (namecount == 0) printf("No named substrings\n"); else
256  {
257  PCRE2_SPTR tabptr;
258  printf("Named substrings\n");
259
260  /* Before we can access the substrings, we must extract the table for
261  translating names to numbers, and the size of each entry in the table. */
262
263  (void)pcre2_pattern_info(
264    re,                       /* the compiled pattern */
265    PCRE2_INFO_NAMETABLE,     /* address of the table */
266    &name_table);             /* where to put the answer */
267
268  (void)pcre2_pattern_info(
269    re,                       /* the compiled pattern */
270    PCRE2_INFO_NAMEENTRYSIZE, /* size of each entry in the table */
271    &name_entry_size);        /* where to put the answer */
272
273  /* Now we can scan the table and, for each entry, print the number, the name,
274  and the substring itself. In the 8‐bit library the number is held in two
275  bytes, most significant first. */
276
277  tabptr = name_table;
278  for (i = 0; i < namecount; i++)
279    {
280    int n = (tabptr[0] << 8) | tabptr[1];
281    printf("(%d) %*s: %.*s\n", n, name_entry_size ‐ 3, tabptr + 2,
282      (int)(ovector[2*n+1] ‐ ovector[2*n]), subject + ovector[2*n]);
283    tabptr += name_entry_size;
284    }
285  }
286
287
288/*************************************************************************
289* If the "‐g" option was given on the command line, we want to continue  *
290* to search for additional matches in the subject string, in a similar   *
291* way to the /g option in Perl. This turns out to be trickier than you   *
292* might think because of the possibility of matching an empty string.    *
293* What happens is as follows:                                            *
294*                                                                        *
295* If the previous match was NOT for an empty string, we can just start   *
296* the next match at the end of the previous one.                         *
297*                                                                        *
298* If the previous match WAS for an empty string, we can’t do that, as it *
299* would lead to an infinite loop. Instead, a call of pcre2_match() is    *
300* made with the PCRE2_NOTEMPTY_ATSTART and PCRE2_ANCHORED flags set. The *
301* first of these tells PCRE2 that an empty string at the start of the    *
302* subject is not a valid match; other possibilities must be tried. The   *
303* second flag restricts PCRE2 to one match attempt at the initial string *
304* position. If this match succeeds, an alternative to the empty string   *
305* match has been found, and we can print it and proceed round the loop,  *
306* advancing by the length of whatever was found. If this match does not  *
307* succeed, we still stay in the loop, advancing by just one character.   *
308* In UTF‐8 mode, which can be set by (*UTF) in the pattern, this may be  *
309* more than one byte.                                                    *
310*                                                                        *
311* However, there is a complication concerned with newlines. When the     *
312* newline convention is such that CRLF is a valid newline, we must       *
313* advance by two characters rather than one. The newline convention can  *
314* be set in the regex by (*CR), etc.; if not, we must find the default.  *
315*************************************************************************/
316
317if (!find_all)     /* Check for ‐g */
318  {
319  pcre2_match_data_free(match_data);  /* Release the memory that was used */
320  pcre2_code_free(re);                /* for the match data and the pattern. */
321  return 0;                           /* Exit the program. */
322  }
323
324/* Before running the loop, check for UTF‐8 and whether CRLF is a valid newline
325sequence. First, find the options with which the regex was compiled and extract
326the UTF state. */
327
328(void)pcre2_pattern_info(re, PCRE2_INFO_ALLOPTIONS, &option_bits);
329utf8 = (option_bits & PCRE2_UTF) != 0;
330
331/* Now find the newline convention and see whether CRLF is a valid newline
332sequence. */
333
334(void)pcre2_pattern_info(re, PCRE2_INFO_NEWLINE, &newline);
335crlf_is_newline = newline == PCRE2_NEWLINE_ANY ||
336                  newline == PCRE2_NEWLINE_CRLF ||
337                  newline == PCRE2_NEWLINE_ANYCRLF;
338
339/* Loop for second and subsequent matches */
340
341for (;;)
342  {
343  uint32_t options = 0;                   /* Normally no options */
344  PCRE2_SIZE start_offset = ovector[1];   /* Start at end of previous match */
345
346  /* If the previous match was for an empty string, we are finished if we are
347  at the end of the subject. Otherwise, arrange to run another match at the
348  same point to see if a non‐empty match can be found. */
349
350  if (ovector[0] == ovector[1])
351    {
352    if (ovector[0] == subject_length) break;
353    options = PCRE2_NOTEMPTY_ATSTART | PCRE2_ANCHORED;
354    }
355
356  /* If the previous match was not an empty string, there is one tricky case to
357  consider. If a pattern contains \K within a lookbehind assertion at the
358  start, the end of the matched string can be at the offset where the match
359  started. Without special action, this leads to a loop that keeps on matching
360  the same substring. We must detect this case and arrange to move the start on
361  by one character. The pcre2_get_startchar() function returns the starting
362  offset that was passed to pcre2_match(). */
363
364  else
365    {
366    PCRE2_SIZE startchar = pcre2_get_startchar(match_data);
367    if (start_offset <= startchar)
368      {
369      if (startchar >= subject_length) break;   /* Reached end of subject.   */
370      start_offset = startchar + 1;             /* Advance by one character. */
371      if (utf8)                                 /* If UTF‐8, it may be more  */
372        {                                       /*   than one code unit.     */
373        for (; start_offset < subject_length; start_offset++)
374          if ((subject[start_offset] & 0xc0) != 0x80) break;
375        }
376      }
377    }
378
379  /* Run the next matching operation */
380
381  rc = pcre2_match(
382    re,                   /* the compiled pattern */
383    subject,              /* the subject string */
384    subject_length,       /* the length of the subject */
385    start_offset,         /* starting offset in the subject */
386    options,              /* options */
387    match_data,           /* block for storing the result */
388    NULL);                /* use default match context */
389
390  /* This time, a result of NOMATCH isn’t an error. If the value in "options"
391  is zero, it just means we have found all possible matches, so the loop ends.
392  Otherwise, it means we have failed to find a non‐empty‐string match at a
393  point where there was a previous empty‐string match. In this case, we do what
394  Perl does: advance the matching position by one character, and continue. We
395  do this by setting the "end of previous match" offset, because that is picked
396  up at the top of the loop as the point at which to start again.
397
398  There are two complications: (a) When CRLF is a valid newline sequence, and
399  the current position is just before it, advance by an extra byte. (b)
400  Otherwise we must ensure that we skip an entire UTF character if we are in
401  UTF mode. */
402
403  if (rc == PCRE2_ERROR_NOMATCH)
404    {
405    if (options == 0) break;                    /* All matches found */
406    ovector[1] = start_offset + 1;              /* Advance one code unit */
407    if (crlf_is_newline &&                      /* If CRLF is a newline & */
408        start_offset < subject_length ‐ 1 &&    /* we are at CRLF, */
409        subject[start_offset] == ’\r’ &&
410        subject[start_offset + 1] == ’\n’)
411      ovector[1] += 1;                          /* Advance by one more. */
412    else if (utf8)                              /* Otherwise, ensure we */
413      {                                         /* advance a whole UTF‐8 */
414      while (ovector[1] < subject_length)       /* character. */
415        {
416        if ((subject[ovector[1]] & 0xc0) != 0x80) break;
417        ovector[1] += 1;
418        }
419      }
420    continue;    /* Go round the loop again */
421    }
422
423  /* Other matching errors are not recoverable. */
424
425  if (rc < 0)
426    {
427    printf("Matching error %d\n", rc);
428    pcre2_match_data_free(match_data);
429    pcre2_code_free(re);
430    return 1;
431    }
432
433  /* Match succeded */
434
435  printf("\nMatch succeeded again at offset %d\n", (int)ovector[0]);
436
437  /* The match succeeded, but the output vector wasn’t big enough. This
438  should not happen. */
439
440  if (rc == 0)
441    printf("ovector was not big enough for all the captured substrings\n");
442
443  /* We must guard against patterns such as /(?=.\K)/ that use \K in an
444  assertion to set the start of a match later than its end. In this
445  demonstration program, we just detect this case and give up. */
446
447  if (ovector[0] > ovector[1])
448    {
449    printf("\\K was used in an assertion to set the match start after its end.\n"
450      "From end to start the match was: %.*s\n", (int)(ovector[0] ‐ ovector[1]),
451        (char *)(subject + ovector[1]));
452    printf("Run abandoned\n");
453    pcre2_match_data_free(match_data);
454    pcre2_code_free(re);
455    return 1;
456    }
457
458  /* As before, show substrings stored in the output vector by number, and then
459  also any named substrings. */
460
461  for (i = 0; i < rc; i++)
462    {
463    PCRE2_SPTR substring_start = subject + ovector[2*i];
464    size_t substring_length = ovector[2*i+1] ‐ ovector[2*i];
465    printf("%2d: %.*s\n", i, (int)substring_length, (char *)substring_start);
466    }
467
468  if (namecount == 0) printf("No named substrings\n"); else
469    {
470    PCRE2_SPTR tabptr = name_table;
471    printf("Named substrings\n");
472    for (i = 0; i < namecount; i++)
473      {
474      int n = (tabptr[0] << 8) | tabptr[1];
475      printf("(%d) %*s: %.*s\n", n, name_entry_size ‐ 3, tabptr + 2,
476        (int)(ovector[2*n+1] ‐ ovector[2*n]), subject + ovector[2*n]);
477      tabptr += name_entry_size;
478      }
479    }
480  }      /* End of loop to find second and subsequent matches */
481
482printf("\n");
483pcre2_match_data_free(match_data);
484pcre2_code_free(re);
485return 0;
486}
487
488/* End of pcre2demo.c */
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